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Strepsirrhini

April 22, 2024

For an explanation of very similar terms, see Adapiformes and Lemuriformes.

Strepsirrhini or Strepsirhini (/ˌstrɛpsəˈrni/ ; STREP-sə-RY-nee) is a suborder of primates that includes the lemuriform primates, which consist of the lemurs of Madagascar, galagos ("bushbabies") and pottos from Africa, and the lorises from India and southeast Asia.[a] Collectively they are referred to as strepsirrhines. Also belonging to the suborder are the extinct adapiform primates which thrived during the Eocene in Europe, North America, and Asia, but disappeared from most of the Northern Hemisphere as the climate cooled. Adapiforms are sometimes referred to as being "lemur-like", although the diversity of both lemurs and adapiforms does not support this comparison.

Strepsirrhini
Temporal range: 55.8–0 Ma Early Eocene to Present[1]
A sample of strepsirrhine diversity; eight biological genera are depicted (from top, left to right): Lemur, Propithecus, Daubentonia, Varecia, Microcebus, Darwinius, Loris, Otolemur
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Primates
Suborder: Strepsirrhini
É. Geoffroy, 1812
Infraorders

Adapiformes
Lemuriformes[a] (See text)

sister: Haplorhini

Eocene-Miocene fossil sites
     Range of extant strepsirrhine primates

Strepsirrhines are defined by their "wet" (moist) rhinarium (the tip of the snout) – hence the colloquial but inaccurate term "wet-nosed" – similar to the rhinaria of canines and felines. They also have a smaller brain than comparably sized simians, large olfactory lobes for smell, a vomeronasal organ to detect pheromones, and a bicornuate uterus with an epitheliochorial placenta. Their eyes contain a reflective layer to improve their night vision, and their eye sockets include a ring of bone around the eye, but they lack a wall of thin bone behind it. Strepsirrhine primates produce their own vitamin C, whereas haplorhine primates must obtain it from their diets. Lemuriform primates are characterized by a toothcomb, a specialized set of teeth in the front, lower part of the mouth mostly used for combing fur during grooming.

Many of today's living strepsirrhines are endangered due to habitat destruction, hunting for bushmeat, and live capture for the exotic pet trade. Both living and extinct strepsirrhines are behaviorally diverse, although all are primarily arboreal (tree-dwelling). Most living lemuriforms are nocturnal, while most adapiforms were diurnal. Both living and extinct groups primarily fed on fruit, leaves, and insects.

Etymology edit

The taxonomic name Strepsirrhini derives from the Greek στρέψις strepsis "a turning round" and ῥίς rhis "nose, snout, (in pl.) nostrils" (GEN ῥινός rhinos),[5] which refers to the appearance of the sinuous (comma-shaped) nostrils on the rhinarium or wet nose.[6][7] The name was first used by French naturalist Étienne Geoffroy Saint-Hilaire in 1812 as a subordinal rank comparable to Platyrrhini (New World monkeys) and Catarrhini (Old World monkeys).[8] In his description, he mentioned "Les narines terminales et sinueuses" ("Nostrils terminal and winding").[9]

When British zoologist Reginald Innes Pocock revived Strepsirrhini and defined Haplorhini in 1918, he omitted the second[10] "r" from both ("Strepsirhini" and "Haplorhini" instead of "Strepsirrhini" and "Haplorrhini"),[11][12] although he did not remove the second "r" from Platyrrhini or Catarrhini, both of which were also named by É. Geoffroy in 1812. Following Pocock, many researchers continued to spell Strepsirrhini with a single "r" until primatologists Paulina Jenkins and Prue Napier pointed out the error in 1987.[13]

Evolutionary history edit

Strepsirrhines include the extinct adapiforms and the lemuriform primates, which include lemurs and lorisoids (lorises, pottos, and galagos).[14] Strepsirrhines diverged from the haplorhine primates near the beginning of the primate radiation between 55 and 90 mya. Older divergence dates are based on genetic analysis estimates, while younger dates are based on the scarce fossil record. Lemuriform primates may have evolved from either cercamoniines or sivaladapids, both of which were adapiforms that may have originated in Asia. They were once thought to have evolved from adapids, a more specialized and younger branch of adapiform primarily from Europe.

Primate phylogeny
 Euarchonta 

Scandentia (treeshrews)

 Primatomorpha 

Dermoptera (colugos)

 Primates 

Plesiadapiformes

 Euprimates 
 Haplorhini 
 Strepsirrhini 

Adapiformes

 Lemuriformes 
Strepsirrhines and haplorhines diverged shortly after the emergence of the first true primates (euprimates). The relationship between euprimates, treeshrews, colugos, and plesiadapiforms is less certain. Sometimes plesiadapiforms are grouped with the euprimates under the order Primates, colugos are grouped with primates under Primatomorpha, and all four are grouped under Euarchonta.[15]

Lemurs rafted from Africa to Madagascar between 47 and 54 mya, whereas the lorises split from the African galagos around 40 mya and later colonized Asia. The lemuriforms, and particularly the lemurs of Madagascar, are often portrayed inappropriately as "living fossils" or as examples of "basal", or "inferior" primates.[16][17][18] These views have historically hindered the understanding of mammalian evolution and the evolution of strepsirrhine traits,[16] such as their reliance on smell (olfaction), characteristics of their skeletal anatomy, and their brain size, which is relatively small. In the case of lemurs, natural selection has driven this isolated population of primates to diversify significantly and fill a rich variety of ecological niches, despite their smaller and less complex brains compared to simians.[17][18]

Unclear origin edit

The divergence between strepsirrhines, simians, and tarsiers likely followed almost immediately after primates first evolved.[19] Although few fossils of living primate groups – lemuriforms, tarsiers, and simians – are known from the Early to Middle Eocene,[20][21][22] evidence from genetics and recent fossil finds both suggest they may have been present during the early adaptive radiation.[23]

The origin of the earliest primates that the simians and tarsiers both evolved from is a mystery. Both their place of origin and the group from which they emerged are uncertain. Although the fossil record demonstrating their initial radiation across the Northern Hemisphere is very detailed,[24] the fossil record from the tropics (where primates most likely first developed) is very sparse, particularly around the time that primates and other major clades[b] of eutherian mammals first appeared.

Lacking detailed tropical fossils, geneticists and primatologists have used genetic analyses to determine the relatedness between primate lineages and the amount of time since they diverged. Using this molecular clock, divergence dates for the major primate lineages have suggested that primates evolved more than 80–90 mya, nearly 40 million years before the first examples appear in the fossil record.[25]

The early primates include both nocturnal and diurnal small-bodied species,[26] and all were arboreal, with hands and feet specially adapted for maneuvering on small branches.[27] Plesiadapiforms from the early Paleocene are sometimes considered "archaic primates", because their teeth resembled those of early primates and because they possessed adaptations to living in trees, such as a divergent big toe (hallux). Although plesiadapiforms were closely related to primates, they may represent a paraphyletic group from which primates may or may not have directly evolved,[28] and some genera may have been more closely related to colugos,[c] which are thought to be more closely related to primates.[29]

 
Early primates possessed adaptations for arboreal locomotion that enabled maneuvering along fine branches, as seen in this slender loris.

The first true primates (euprimates) do not appear in the fossil record until the early Eocene (~55 mya), at which point they radiated across the Northern Hemisphere during a brief period of rapid global warming known as the Paleocene–Eocene Thermal Maximum.[23] These first primates included Cantius, Donrussellia, Altanius, and Teilhardina on the northern continents,[30] as well as the more questionable (and fragmentary) fossil Altiatlasius from Paleocene Africa.[19] These earliest fossil primates are often divided into two groups, adapiforms[d] and omomyiforms.[e] Both appeared suddenly in the fossil record without transitional forms to indicate ancestry,[31] and both groups were rich in diversity and were widespread throughout the Eocene.

The last branch to develop were the adapiforms, a diverse and widespread group that thrived during the Eocene (56 to 34 million years ago [mya]) in Europe, North America, and Asia. They disappeared from most of the Northern Hemisphere as the climate cooled: The last of the adapiforms died out at the end of the Miocene (~7 mya).

Adapiform evolution edit

 
Notharctus, a type of North American adapiform, resembled lemurs but did not give rise to them.

Adapiform primates are extinct strepsirrhines that shared many anatomical similarities with lemurs.[32] They are sometimes referred to as lemur-like primates, although the diversity of both lemurs and adapiforms do not support this analogy.[33]

Like the living strepsirrhines, adapiforms were extremely diverse,[16] with at least 30 genera and 80 species known from the fossil record as of the early 2000s.[34][35] They diversified across Laurasia during the Eocene,[32] some reaching North America via a land bridge.[36]They were among the most common mammals found in the fossil beds from that time. A few rare species have also been found in northern Africa.[32] The most basal of the adapiforms include the genera Cantius from North America and Europe and Donrussellia from Europe. The latter bears the most ancestral traits, so it is often considered a sister group or stem group of the other adapiforms.[37]

Adapiforms are often divided into three major groups:

  • Adapids were most commonly found in Europe, although the oldest specimens (Adapoides from middle Eocene China) indicate that they most likely evolved in Asia and immigrated. They died out in Europe during the Grande Coupure, part of a significant extinction event at the end of the Eocene.[38]
  • Notharctids, which most closely resembled some of Madagascar's lemurs, come from Europe and North America. The European branch is often referred to as cercamoniines.[39] The North American branch thrived during the Eocene, but did not survive into the Oligocene.[40][41] Like the adapids, the European branch were also extinct by the end of the Eocene.[36]
  • Sivaladapids of southern and eastern Asia are best known from the Miocene, and the only adapiforms to survive past the Eocene/Oligocene boundary (~34 mya). Their relationship to the other adapiforms remains unclear.[42] They had vanished before the end of the Miocene (~7 mya).[32]

The relationship between adapiform and lemuriform primates has not been clearly demonstrated, so the position of adapiforms as a paraphyletic stem group is questionable. Both molecular clock data and new fossil finds suggest that the lemuriform divergence from the other primates and the subsequent lemur-lorisoid split both predate the appearance of adapiforms in the early Eocene.[31] New calibration methods may reconcile the discrepancies between the molecular clock and the fossil record, favoring more recent divergence dates.[43] The fossil record suggests that the strepsirrhine adapiforms and the haplorhine omomyiforms had been evolving independently before the early Eocene, although their most basal members share enough dental similarities to suggest that they diverged during the Paleocene (66–55 mya).[32]

Lemuriform evolution edit

See also: Evolution of lemurs

Lemuriform origins are unclear and debated. American paleontologist Philip Gingerich proposed that lemuriform primates evolved from one of several genera of European adapids based on similarities between the front lower teeth of adapids and the toothcomb of extant lemuriforms; however, this view is not strongly supported due to a lack of clear transitional fossils.[44] Instead, lemuriforms may be descended from a very early branch of Asian cercamoniines or sivaladapids that migrated to northern Africa.[22][45]

Until discoveries of three 40 million-year-old fossil lorisoids (Karanisia, Saharagalago, and Wadilemur) in the El Fayum deposits of Egypt between 1997 and 2005, the oldest known lemuriforms had come from the early Miocene (~20 mya) of Kenya and Uganda. These newer finds demonstrate that lemuriform primates were present during the middle Eocene in Afro-Arabia and that the lemuriform lineage and all other strepsirrhine taxa had diverged before then.[46][47][48] Djebelemur from Tunisia dates to the late early or early middle Eocene (52 to 46 mya) and has been considered a cercamoniine,[49] but also may have been a stem lemuriform.[22] Azibiids from Algeria date to roughly the same time and may be a sister group of the djebelemurids. Together with Plesiopithecus from the late Eocene Egypt, the three may qualify as the stem lemuriforms from Africa.[45]

Molecular clock estimates indicate that lemurs and the lorisoids diverged in Africa during the Paleocene, approximately 62 mya. Between 47 and 54 mya, lemurs dispersed to Madagascar by rafting.[47] In isolation, the lemurs diversified and filled the niches often filled by monkeys and apes today.[50] In Africa, the lorises and galagos diverged during the Eocene, approximately 40 mya.[47] Unlike the lemurs in Madagascar, they have had to compete with monkeys and apes, as well as other mammals.[17]

History of classification edit

 
The suborder Strepsirrhini was proposed by É. Geoffroy in 1812.

The taxonomy of strepsirrhines is controversial and has a complicated history. Confused taxonomic terminology and oversimplified anatomical comparisons have created misconceptions about primate and strepsirrhine phylogeny, illustrated by the media attention surrounding the single "Ida" fossil in 2009.

Strepsirrhine primates were first grouped under the genus Lemur by Swedish taxonomist Carl Linnaeus in the 10th edition of Systema Naturae published in 1758. At the time, only three species were recognized, one of which (the colugo) is no longer recognized as a primate.[51] In 1785, Dutch naturalist Pieter Boddaert divided the genus Lemur into two genera: Prosimia for the lemurs, colugos, and tarsiers and Tardigradus for the lorises.[52] Ten years later, É. Geoffroy and Georges Cuvier grouped the tarsiers and galagos due to similarities in their hindlimb morphology, a view supported by German zoologist Johann Karl Wilhelm Illiger, who placed them in the family Macrotarsi while placing the lemurs and tarsiers in the family Prosimia (Prosimii) in 1811. The use of the tarsier-galago classification continued for many years until 1898, when Dutch zoologist Ambrosius Hubrecht demonstrated two different types of placentation (formation of a placenta) in the two groups.[53]

English comparative anatomist William Henry Flower created the suborder Lemuroidea in 1883 to distinguish these primates from the simians, which were grouped under English biologist St. George Jackson Mivart's suborder Anthropoidea (=Simiiformes). According to Flower, the suborder Lemuroidea contained the families Lemuridae (lemurs, lorises, and galagos), Chiromyidae (aye-aye), and Tarsiidae (tarsiers). Lemuroidea was later replaced by Illiger's suborder Prosimii.[53] Many years earlier, in 1812, É. Geoffroy first named the suborder Strepsirrhini, in which he included the tarsiers.[54] This taxonomy went unnoticed until 1918, when Pocock compared the structure of the nose and reinstated the use of the suborder Strepsirrhini, while also moving the tarsiers and the simians into a new suborder, Haplorhini.[11][53] It was not until 1953, when British anatomist William Charles Osman Hill wrote an entire volume on strepsirrhine anatomy, that Pocock's taxonomic suggestion became noticed and more widely used. Since then, primate taxonomy has shifted between Strepsirrhini-Haplorhini and Prosimii-Anthropoidea multiple times.[53]

Most of the academic literature provides a basic framework for primate taxonomy, usually including several potential taxonomic schemes.[55] Although most experts agree upon phylogeny,[56] many disagree about nearly every level of primate classification.[55]

Competing strepsirrhine taxonomic nomenclature
2 infraorders[3] 3 infraorders[4]
  • Suborder Strepsirrhini
    • Infraorder Adapiformes
      • Superfamily Adapoidea
        • Family Adapidae
        • Family Notharctidae
        • Family Sivaladapidae
    • Infraorder Lemuriformes
      • Superfamily Lemuroidea
        • Family Archaeolemuridae
        • Family Cheirogaleidae
        • Family Daubentoniidae
        • Family Indriidae
        • Family Lemuridae
        • Family Lepilemuridae
        • Family Megaladapidae
        • Family Palaeopropithecidae
    • Infraorder Lorisiformes
      • Superfamily Lorisoidea
        • Family Lorisidae
        • Family Galagidae

Controversies edit

The most commonly recurring debate in primatology during the 1970s, 1980s, and early 2000s concerned the phylogenetic position of tarsiers compared to both simians and the other prosimians.[57][58] Tarsiers are most often placed in either the suborder Haplorhini with the simians or in the suborder Prosimii with the strepsirrhines.[50] Prosimii is one of the two traditional primate suborders and is based on evolutionary grades (groups united by anatomical traits) rather than phylogenetic clades, while the Strepsirrhini-Haplorrhini taxonomy was based on evolutionary relationships.[7] Yet both systems persist because the Prosimii-Anthropoidea taxonomy is familiar and frequently seen in the research literature and textbooks.[25]

Strepsirrhines are traditionally characterized by several symplesiomorphic (ancestral) traits not shared with the simians, particularly the rhinarium.[f][50][60] Other symplesiomorphies include long snouts, convoluted maxilloturbinals, relatively large olfactory bulbs, and smaller brains. The toothcomb is a synapomorphy (shared, derived trait) seen among lemuriforms,[50] although it is frequently and incorrectly used to define the strepsirrhine clade.[g] Strepsirrhine primates are also united in possessing an epitheliochorial placenta.[50] Unlike the tarsiers and simians, strepsirrhines are capable of producing their own vitamin C and do not need it supplied in their diet.[62] Further genetic evidence for the relationship between tarsiers and simians as a haplorhine clade is the shared possession of three SINE markers.[63]

Because of their historically mixed assemblages which included tarsiers and close relatives of primates, both Prosimii and Strepsirrhini have been considered wastebasket taxa for "lower primates".[64][65] Regardless, the strepsirrhine and haplorrhine clades are generally accepted and viewed as the preferred taxonomic division. Yet tarsiers still closely resemble both strepsirrhines and simians in different ways,[25] and since the early split between strepsirrhines, tarsiers and simians is ancient and hard to resolve,[66] a third taxonomic arrangement with three suborders is sometimes used: Prosimii, Tarsiiformes, and Anthropoidea.[14] More often, the term "prosimian" is no longer used in official taxonomy,[67] but is still used to illustrate the behavioral ecology of tarsiers relative to the other primates.[60]

In addition to the controversy over tarsiers, the debate over the origins of simians once called the strepsirrhine clade into question. Arguments for an evolutionary link between adapiforms and simians made by paleontologists Gingerich, Elwyn L. Simons, Tab Rasmussen, and others could have potentially excluded adapiforms from Strepsirrhini.[68][69] In 1975, Gingerich proposed a new suborder, Simiolemuriformes,[70] to suggest that strepsirrhines are more closely related to simians than tarsiers.[71] However, no clear relationship between the two had been demonstrated by the early 2000s.[69] The idea reemerged briefly in 2009 during the media attention surrounding Darwinius masillae (dubbed "Ida"), a cercamoniine from Germany that was touted as a "missing link between humans and earlier primates" (simians and adapiforms).[72] However, the cladistic analysis was flawed and the phylogenetic inferences and terminology were vague.[72] Although the authors noted that Darwinius was not a "fossil lemur", they did emphasize the absence of a toothcomb,[73] which adapiforms did not possess.[37]

Infraordinal classification and clade terminology edit

 
The media attention over "Ida" played upon confused terminology and misconceptions about strepsirrhines.
Strepsirrhini phylogeny[45]

Adapiformes

stem lemuriforms

lemuriforms or
 crown strepsirrhines 
 lemuroid clade 

Daubentoniidae

other lemurs

 lorisoid clade 

lorises

galagos

Within Strepsirrhini, two common classifications include either two infraorders (Adapiformes and Lemuriformes)[74] or three infraorders (Adapiformes, Lemuriformes, Lorisiformes).[75] A less common taxonomy places the aye-aye (Daubentoniidae) in its own infraorder, Chiromyiformes.[76] In some cases, plesiadapiforms are included within the order Primates, in which case Euprimates is sometimes treated as a suborder, with Strepsirrhini becoming an infraorder, and the Lemuriformes and others become parvorders.[14] Regardless of the infraordinal taxonomy, Strepsirrhini is composed of three ranked superfamilies and 14 families, seven of which are extinct.[74] Three of these extinct families included the recently extinct giant lemurs of Madagascar,[77] many of which died out within the last 1,000 years following human arrival on the island.[78]

When Strepsirrhini is divided into two infraorders, the clade containing all toothcombed primates can be called "lemuriforms".[74] When it is divided into three infraorders, the term "lemuriforms" refers only to Madagascar's lemurs,[50] and the toothcombed primates are referred to as either "crown strepsirrhines"[42] or "extant strepsirrhines".[7] Confusion of this specific terminology with the general term "strepsirrhine", along with oversimplified anatomical comparisons and vague phylogenetic inferences, can lead to misconceptions about primate phylogeny and misunderstandings about primates from the Eocene, as seen with the media coverage of Darwinius.[72] Because the skeletons of adapiforms share strong similarities with those of lemurs and lorises, researchers have often referred to them as "primitive" strepsirrhines,[79] lemur ancestors, or a sister group to the living strepsirrhines. They are included in Strepsirrhini,[7] and are considered basal members of the clade.[80] Although their status as true primates is not questioned, the questionable relationship between adapiforms and other living and fossil primates leads to multiple classifications within Strepsirrhini. Often, adapiforms are placed in their own infraorder due to anatomical differences with lemuriforms and their unclear relationship. When shared traits with lemuriforms (which may or may not be synapomorphic) are emphasized, they are sometimes reduced to families within the infraorder Lemuriformes (or superfamily Lemuroidea).[32]

The first fossil primate described was the adapiform Adapis parisiensis by French naturalist Georges Cuvier in 1821,[49] who compared it to a hyrax ("le Daman"), then considered a member of a now obsolete group called pachyderms.[81] It was not recognized as a primate until it was reevaluated in the early 1870s.[34][49] Originally, adapiforms were all included under the family Adapidae, which was divided into two or three subfamilies: Adapinae, Notharctinae, and sometimes Sivaladapinae. All North American adapiforms were lumped under Notharctinae, while the Old World forms were usually assigned to Adapinae. Around the 1990s, two distinct groups of European "adapids" began to emerge, based on differences in the postcranial skeleton and the teeth. One of these two European forms was identified as cercamoniines, which were allied with the notharctids found mostly in North America, while the other group falls into the traditional adapid classification.[37] The three major adapiform divisions are now typically regarded as three families within Adapiformes (Notharctidae, Adapidae and Sivaladapidae), but other divisions ranging from one to five families are used as well.[34]

Anatomy and physiology edit

Grooming apparatus edit

 
Strepsirrhines have a reflective layer in the eye, called a tapetum lucidum, that helps them see better at night.

All lemuriforms possess a specialized dental structure called a "toothcomb",[7][82] with the exception of the aye-aye, in which the structure has been modified into two continually growing (hypselodont) incisors (or canine teeth), similar to those of rodents. Often, the toothcomb is incorrectly used to characterize all strepsirrhines. Instead, it is unique to lemuriforms and is not seen among adapiforms.

Lemuriforms groom orally, and also possess a grooming claw on the second toe of each foot for scratching in areas that are inaccessible to the mouth and tongue.[7][82][83] Adapiforms may have had a grooming claw,[37] but there is little evidence of this.[84] The toothcomb consists of either two or four procumbent lower incisors and procumbent lower canine teeth followed by a canine-shaped premolar.[85] It is used to comb the fur during oral grooming. Shed hairs that accumulate between the teeth of the toothcomb are removed by the sublingua or "under-tongue".[83] Adapiforms did not possess a toothcomb. Instead, their lower incisors varied in orientation – from somewhat procumbent to somewhat vertical – and the lower canines were projected upwards and were often prominent.

Eyes edit

Like all primates, strepsirrhine orbits (eye sockets) have a postorbital bar, a protective ring of bone created by a connection between the frontal and zygomatic bones.[86] Both living and extinct strepsirrhines lack a thin wall of bone behind the eye, referred to as postorbital closure, which is only seen in haplorhine primates.[86][87] Although the eyes of strepsirrhines point forward, giving stereoscopic vision,[86] the orbits do not face fully forward.[87] Among living strepsirrhines, most or all species are thought to possess a reflective layer behind the retina of the eye, called a tapetum lucidum (consisting of riboflavin crystals[88]), which improves vision in low light,[89][82] but they lack a fovea, which improves day vision. This differs from tarsiers, which lack a tapetum lucidum but possess a fovea.[90]

Skull edit

 
Strepsirrhines are characterized by a typically longer snout and wet nose compared to haplorhine primates.

Strepsirrhine primates have a brain relatively comparable to or slightly larger in size than most mammals.[16][50] Compared to simians, however, they have a relatively small brain-to-body size ratio.[87] Strepsirrhines are also traditionally noted for their unfused mandibular symphysis (two halves of the lower jaw),[87] however, fusion of the mandibular symphysis was common in adapiforms,[91] notably Notharctus.[92] Also, several extinct giant lemurs exhibited a fused mandibular symphysis.[93]

Ears edit

Many nocturnal species have large, independently movable ears,[94][95] although there are significant differences in sizes and shapes of the ear between species.[96] The structure of the middle and inner ear of strepsirrhines differs between the lemurs and lorisoids. In lemurs, the tympanic cavity, which surrounds the middle ear, is expanded. This leaves the ectotympanic ring, which supports the eardrum, free within the auditory bulla.[97] This trait is also seen in adapiforms.[91] In lorisoids, however, the tympanic cavity is smaller and the ectotympanic ring becomes attached to the edge of the auditory bulla. The tympanic cavity in lorisoids also has two accessory air spaces, which are not present in lemurs.

Neck arteries edit

Both lorisoids and cheirogaleid lemurs have replaced the internal carotid artery with an enlarged ascending pharyngeal artery.[97]

Ankle bones edit

Strepsirrhines also possess distinctive features in their tarsus (ankle bones) that differentiate them from haplorhines, such as a sloping talo-fibular facet (the face where the talus bone and fibula meet) and a difference in the location of the position of the flexor fibularis tendon on the talus.[98] These differences give strepsirrhines the ability to make more complex rotations of the ankle and indicate that their feet are habitually inverted, or turned inward, an adaptation for grasping vertical supports.[99]

Sex characteristics edit

Sexual dichromatism (different coloration patterns between males and females) can be seen in most brown lemur species,[100] but otherwise lemurs show very little if any difference in body size or weight between sexes. This lack of sexual dimorphism is not characteristic of all strepsirrhines.[101] Some adapiforms were sexually dimorphic, with males bearing a larger sagittal crest (a ridge of bone on the top of the skull to which jaw muscles attach) and canine teeth.[102] Lorisoids exhibit some sexual dimorphism,[101] but males are typically no more than 20 percent larger than females.[103]

Rhinarium and olfaction edit

 
The noses of five prosimian primates:
(A) through (D) possess a rhinarium and are strepsirrhines, whereas (E) does not and is a haplorhine.

Strepsirrhines have a long snout that ends in a moist and touch-sensitive rhinarium, similar to that of dogs and many other mammals. The rhinarium is surrounded by vibrissae that are also sensitive to touch. Convoluted maxilloturbinals on the inside of their nose filter, warm, and moisten the incoming air, while olfactory receptors of the main olfactory system lining the ethmoturbinals detect airborne smells.[50][104] The olfactory bulbs of lemurs are comparable in size to those of other arboreal mammals.[50]

The surface of the rhinarium does not have any olfactory receptors, so it is not used for smell in terms of detecting volatile substances. Instead, it has sensitive touch receptors (Merkel cells). The rhinarium, upper lip, and gums are tightly connected by a fold of mucous membrane called the philtrum, which runs from the tip of the nose to the mouth.[105] The upper lip is constrained by this connection and has fewer nerves to control movement, which leaves it less mobile than the upper lips of simians.[106][107] The philtrum creates a gap (diastema) between the roots of the first two upper incisors.[105][108]

The strepsirrhine rhinarium can collect relatively non-volatile, fluid-based chemicals (traditionally categorized as pheromones) and transmit them to the vomeronasal organ (VNO),[109] which is located below and in front of the nasal cavity, above the mouth.[110] The VNO is an encased duct-like structure made of cartilage[111] and is isolated from the air passing through the nasal cavity.[112] The VNO is connected to the mouth through nasopalatine ducts (which communicate via the incisive foramen), which pass through the hard palate at the top, front of the mouth.[110] Fluids traveling from the rhinarium to the mouth and then up the nasopalatine ducts to the VNO are detected, and information is relayed to the accessory olfactory bulb, which is relatively large in strepsirrhines.[113] From the accessory olfactory bulb, information is sent to the amygdala, which handles emotions, and then to the hypothalamus, which handles basic body functions and metabolic processes. This neural pathway differs from that used by the main olfactory system.[114]

All lemuriforms have a VNO, as do tarsiers and some New World monkeys.[115] Adapiforms exhibit the gap between the upper incisors, which indicates the presence of a VNO, but there is some disagreement over whether or not they possessed a rhinarium.[116]

Reproductive physiology edit

Extant strepsirrhines have an epitheliochorial placenta,[50] where the maternal blood does not come in direct contact with the fetal chorion like it does in the hemochorial placenta of haplorhines. The strepsirrhine uterus has two distinct chambers (bicornuate).[106] Despite having similar gestation periods to comparably sized haplorhines, fetal growth rates are generally slower in strepsirrhines, which results in newborn offspring that are as little as one-third the size of haplorhine newborns.[106][117] Extant strepsirrhines also have a lower basal metabolic rate, which elevates in females during gestation, putting greater demands on the mother.[118]

Most primates have two mammary glands,[119] but the number and positions vary between species within strepsirrhines.[120] Lorises have two pairs,[121] while others, like the ring-tailed lemur, have one pair on the chest (pectoral).[122] The aye-aye also has two mammary glands, but they are located near the groin (inguinal).[123] In females, the clitoris is sometimes enlarged and pendulous, resembling the male penis, which can make sex identification difficult for human observers.[124] The clitoris may also have a bony structure in it, similar to the baculum (penis bone) in males.[125] Most male primates have a baculum, but it is typically larger in strepsirrhines and usually forked at the tip.[126]

Behavior edit

 
Like other primates, strepsirrhinid infants often cling to their mother's fur.

Approximately three-quarters of all extant strepsirrhine species are nocturnal, sleeping in nests made from dead leaves or tree hollows during the day.[127] All of the lorisoids from continental Africa and Asia are nocturnal, a circumstance that minimizes their competition with the simian primates of the region, which are diurnal. The lemurs of Madagascar, living in the absence of simians, are more variable in their activity cycles. The aye-aye, mouse lemurs, woolly lemurs, and sportive lemurs are nocturnal, while ring-tailed lemurs and most of their kin, sifakas, and indri are diurnal.[80] Yet some or all of the brown lemurs (Eulemur) are cathemeral, which means that they may be active during the day or night, depending on factors such as temperature and predation.[128] Many extant strepsirrhines are well adapted for nocturnal activity due to their relatively large eyes; large, movable ears; sensitive tactile hairs; strong sense of smell; and the tapetum lucidum behind the retina.[95] Among the adapiforms, most are considered diurnal, with the exception of Pronycticebus and Godinotia from Middle Eocene Europe, both of which had large orbits that suggest nocturnality.[80][91]

Reproduction in most strepsirrhine species tends to be seasonal, particularly in lemurs. Key factors that affect seasonal reproduction include the length of the wet season, subsequent food availability, and the maturation time of the species.[129] Like other primates, strepsirrhines are relatively slow breeders compared to other mammals. Their gestation period and interbirth intervals are usually long, and the young develop slowly, just like in haplorhine primates.[106][117] Unlike simians, some strepsirrhines produce two or three offspring, although some produce only a single offspring. Those that produce multiple offspring tend to build nests for their young. These two traits are thought to be plesiomorphic (ancestral) for primates.[106] The young are precocial (relatively mature and mobile) at birth, but not as coordinated as ungulates (hoofed mammals).[50] Infant care by the mother is relatively prolonged compared to many other mammals, and in some cases, the infants cling to the mother's fur with their hands and feet.[106]

Despite their relatively smaller brains compared to other primates, lemurs have demonstrated levels of technical intelligence in problem solving that are comparable to those seen in simians. However, their social intelligence differs, often emphasizing within-group competition over cooperation, which may be due to adaptations for their unpredictable environment.[130] Although lemurs have not been observed using objects as tools in the wild, they can be trained to use objects as tools in captivity and demonstrate a basic understanding about the functional properties of the objects they are using.[131]

Social systems and communication edit

The nocturnal strepsirrhines have been traditionally described as "solitary", although this term is no longer favored by the researchers who study them.[132] Many are considered "solitary foragers", but many exhibit complex and diverse social organization, often overlapping home ranges, initiating social contact at night, and sharing sleeping sites during the day. Even the mating systems are variable, as seen in woolly lemurs, which live in monogamous breeding pairs.[133] Because of this social diversity among these solitary but social primates, whose level of social interaction is comparable to that of diurnal simians,[132] alternative classifications have been proposed to emphasize their gregarious, dispersed, or solitary nature.[134]

Among extant strepsirrhines, only the diurnal and cathemeral lemurs have evolved to live in multi-male/multi-female groups, comparable to most living simians.[133][135] This social trait, seen in two extant lemur families (Indriidae and Lemuridae), is thought to have evolved independently.[136] Group sizes are smaller in social lemurs than in simians, and despite the similarities, the community structures differ.[137] Female dominance, which is rare in simians, is fairly common in lemurs.[138] Strepsirrhines spend a considerable amount of time grooming each other (allogrooming).[139] When lemuriform primates groom, they lick the fur and then comb it with their toothcomb. They also use their grooming claw to scratch places they cannot reach with their mouth.[83]

Like New World monkeys, strepsirrhines rely on scent marking for much of their communication. This involves smearing secretions from epidermal scent glands on tree branches, along with urine and feces. In some cases, strepsirrhines may anoint themselves with urine (urine washing). Body postures and gestures may be used, although the long snout, non-mobile lips, and reduced facial enervation restrict the use of facial expressions in strepsirrhines. Short-range calls, long-range calls, and alarm calls are also used.[140] Nocturnal species are more constrained by the lack of light, so their communication systems differ from those of diurnal species, often using long-range calls to claim their territory.[141]

Locomotion edit

 
 
Dwarf lemurs (top) are arboreal quadrupeds while galagos (bottom) favor vertical clinging and leaping.

Living strepsirrhines are predominantly arboreal, with only the ring-tailed lemur spending considerable time on the ground.[142] Most species move around quadrupedally (on four legs) in the trees, including five genera of smaller, nocturnal lemurs.[127][142] Galagos, indriids, sportive lemurs, and bamboo lemurs leap from vertical surfaces,[142] and the indriids are highly specialized for vertical clinging and leaping.[127] Lorises are slow-moving, deliberate climbers.[142]

Analyses of extinct adapiforms postcranial skeletons suggest a variety of locomotor behavior.[142] The European adapids Adapis, Palaeolemur, and Leptadapis shared adaptations for slow climbing like the lorises, although they may have been quadrupedal runners like small New World monkeys. Both Notharctus and Smilodectes from North America and Europolemur from Europe exhibit limb proportions and joint surfaces comparable to vertical clinging and leaping lemurs, but were not as specialized as indriids for vertical clinging, suggesting that they ran along branches and did not leap as much.[91][142] Notharctids Cantius and Pronycticebus appear to have been agile arboreal quadrupeds, with adaptations comparable to the brown lemurs.[142]

Diet edit

Primates primarily feed on fruits (including seeds), leaves (including flowers), and animal prey (arthropods, small vertebrates, and eggs). Diets vary markedly between strepsirrhine species. Like other leaf-eating (folivorous) primates, some strepsirrhines can digest cellulose and hemicellulose.[143] Some strepsirrhines, such as the galagos, slender lorises, and angwantibos, are primarily insectivorous. Other species, such as fork-marked lemurs and needle-clawed bushbabies, specialize on tree gum, while indriids, sportive lemurs, and bamboo lemurs are folivores. Many strepsirrhines are frugivores (fruit eaters), and others, like the ring-tailed lemur and mouse lemurs, are omnivores, eating a mix of fruit, leaves, and animal matter.[144]

Among the adapiforms, frugivory seems to have been the most common diet, particularly for medium-sized to large species, such as Cantius, Pelycodus and Cercamonius.[144] Folivory was also common among the medium and large-sized adapiforms, including Smilodectes, Notharctus, Adapis and Leptadapis. Sharp cusps on the teeth of some of the smaller adapiforms, such as Anchomomys and Donrussellia, indicate that they were either partly or primarily insectivorous.[91][144]

Distribution and habitat edit

The now extinct adapiform primates were primarily found across North America, Asia, and Europe, with a few species in Africa. They flourished during the Eocene when those regions were more tropical in nature, and they disappeared when the climate became cooler and drier.[36] Today, the lemuriforms are confined in the tropics,[145] ranging between 28° S to 26° N latitude.[16] Lorises are found both in equatorial Africa and Southeast Asia, while the galagos are limited to the forests and woodlands of sub-Saharan Africa.[17][97] Lemurs are endemic to Madagascar, although much of their diversity and habitat has been lost due to recent human activity.[17][50]

As with nearly all primates, strepsirrhines typically reside in tropical rainforests. These habitats allow strepsirrhines and other primates to evolve diverse communities of sympatric species. In the eastern rainforests of Madagascar, as many as 11 or 12 species share the same forests, and prior to human arrival, some forests had nearly double that diversity.[145] Several species of lemur are found in drier, seasonal forests, including the spiny forest on the southern tip of the island, although the lemur communities in these regions are not as rich.[146]

Conservation edit

 
Strepsirrhines are threatened by deforestation in tropical regions.
See also: Conservation of slow lorises and Lemur § Conservation

Like all other non-human primates, strepsirrhines face an elevated risk of extinction due to human activity, particularly deforestation in tropical regions. Much of their habitat has been converted for human use, such as agriculture and pasture.[27] The threats facing strepsirrhine primates fall into three main categories: habitat destruction, hunting (for bushmeat or traditional medicine), and live capture for export or local exotic pet trade. Although hunting is often prohibited, the laws protecting them are rarely enforced. In Madagascar, local taboos known as fady sometimes help protect lemur species, although some are still hunted for traditional medicine.[147]

In 2012, the International Union for Conservation of Nature (IUCN) announced that lemurs were the "most endangered mammals", due largely to elevated illegal logging and hunting following a political crisis in 2009.[148] In Southeast Asia, slow lorises are threatened by the exotic pet trade and traditional medicine, in addition to habitat destruction.[149][150] Both lemurs and slow lorises are protected from commercial international trade under CITES Appendix I.[151]

Explanatory notes edit

  1. ^ a b Although the monophyletic relationship between lemurs and lorisoids is widely accepted, their clade name is not. The term lemuriform is used here because it derives from one popular taxonomy that clumps the clade of toothcombed primates into one infraorder and the extinct, non-toothcombed adapiforms into another, both within the suborder Strepsirrhini.[2][3] However, another popular alternative taxonomy places the lorisoids in their own infraorder, Lorisiformes.[4]
  2. ^ A "clade" is a group made up of an ancestor and all its descendants.
  3. ^ Colugos are also called dermopterans and flying lemurs.
  4. ^ Adapiforms are sometimes called adapids or adapoids.
  5. ^ The omomyiformes or omomyids are suspected to have been closely related to the tarsiers.
  6. ^ Since they are thought to be close relatives of tarsiers, omomyiforms are classified as haplorhines. However, the spacing of the roots of their upper incisors suggests that they may have had a rhinarium, like the strepsirrhines.[37][59]
  7. ^ Frequent mentions of a "strepsirrhine toothcomb" or references to Strepsirrhini as being "toothcombed primates" can be found in the literature.[7][50] However, one group of strepsirrhines lacks the toothcomb – the adapiforms. The toothcomb is therefore the primary hallmark of the lemuriforms,[37] although at least one family only retains it in modified form.[61]

References edit

Citations edit

  1. ^ "Strepsirrhini". paleobiodb.org. Retrieved 2021-07-22.
  2. ^ Szalay & Delson 1980, p. 149.
  3. ^ a b Cartmill 2010, p. 15.
  4. ^ a b Hartwig 2011, pp. 20–21.
  5. ^ στρέψις, ῥίς. Liddell, Henry George; Scott, Robert; A Greek–English Lexicon at the Perseus Project.
  6. ^ Ankel-Simons 2007, p. 394.
  7. ^ a b c d e f g Vaughan, Ryan & Czaplewski 2011, p. 169.
  8. ^ Osman Hill 1953, p. 39.
  9. ^ Geoffroy Saint-Hilaire 1812, p. 156.
  10. ^ Greek rho ⟨ρ⟩ r is written with a spiritus asper when word-initial, i.e. ⟨ῥ⟩ rh, and often gets doubled to ⟨ῤῥ⟩ rrh (also spelled ⟨ρρ⟩) when such a word constitutes the second part of a compound word. See Ancient Greek phonology#Liquids, #Doubled consonants and #Consonant spelling.
  11. ^ a b Groves 2008, p. 166.
  12. ^ Pocock 1918, p. 51.
  13. ^ Jenkins & Napier 1987, p. 1.
  14. ^ a b c Rose 2006, p. 166.
  15. ^ Rose 2006, pp. 157 & 165–167.
  16. ^ a b c d e Whitten & Brockman 2001, p. 322.
  17. ^ a b c d e Hartwig 2011, p. 29.
  18. ^ a b Fichtel & Kappeler 2009, p. 397.
  19. ^ a b Hartwig 2011, pp. 28–29.
  20. ^ Beard 2002, p. 133.
  21. ^ Simons 2003, pp. 15–17.
  22. ^ a b c Godinot 2006, p. 446.
  23. ^ a b Rose 2006, p. 343.
  24. ^ Rose 2006, pp. 168–169.
  25. ^ a b c Hartwig 2011, p. 22.
  26. ^ Hartwig 2011, p. 24.
  27. ^ a b Cartmill & Smith 2011, p. 84.
  28. ^ Rose 2006, p. 169.
  29. ^ Rose 2006, p. 165.
  30. ^ Miller, Gunnell & Martin 2005, p. 67.
  31. ^ a b Rose 2006, pp. 178–179.
  32. ^ a b c d e f Rose 2006, p. 179.
  33. ^ Covert 2002, pp. 15–16.
  34. ^ a b c Gebo 2002, p. 21.
  35. ^ Covert 2002, p. 14.
  36. ^ a b c Gebo 2002, p. 35.
  37. ^ a b c d e f Rose 2006, p. 182.
  38. ^ Rose 2006, pp. 185–186.
  39. ^ Rose 2006, pp. 182–185.
  40. ^ Godinot 1998, p. 239.
  41. ^ Gunnell, Rose & Rasmussen 2008, p. 257.
  42. ^ a b Rose 2006, p. 186.
  43. ^ Steiper & Seiffert 2012, p. 6006.
  44. ^ Rose 2006, p. 182 & 186.
  45. ^ a b c Tabuce et al. 2009, pp. 4091–4092.
  46. ^ Hartwig 2011, pp. 24–25.
  47. ^ a b c Vaughan, Ryan & Czaplewski 2011, pp. 170–171.
  48. ^ Rose 2006, p. 187.
  49. ^ a b c Rose 2006, p. 185.
  50. ^ a b c d e f g h i j k l m Cartmill & Smith 2011, p. 89.
  51. ^ Groves 2008, pp. 89–90 & 96.
  52. ^ Groves 2008, p. 103.
  53. ^ a b c d Schwartz 2003, pp. 53–54.
  54. ^ Groves 2008, pp. 113–114.
  55. ^ a b Hartwig 2011, pp. 20 & 22.
  56. ^ Sussman 2003, p. 45.
  57. ^ Schwartz 2003, p. 54.
  58. ^ Ankel-Simons 2007, p. 96.
  59. ^ Beard 1988, p. 92.
  60. ^ a b Hartwig 2011, p. 28.
  61. ^ Ankel-Simons 2007, p. 257.
  62. ^ Schwartz 2003, p. 71.
  63. ^ Ankel-Simons 2007, p. 32.
  64. ^ Cartmill 2010, pp. 16–17.
  65. ^ Rasmussen & Nekaris 1998, p. 252.
  66. ^ Ankel-Simons 2007, pp. 31–32.
  67. ^ Groves 1998, p. 13.
  68. ^ Rose 2006, p. 167.
  69. ^ a b Beard 2002, pp. 146–147.
  70. ^ Gingerich 1975, p. 164.
  71. ^ Yoder 2003, pp. 161–162.
  72. ^ a b c Williams et al. 2010, p. 567.
  73. ^ Franzen et al. 2009, p. e5723.
  74. ^ a b c Cartmill & Smith 2011, p. 90.
  75. ^ Hartwig 2011, p. 20.
  76. ^ Groves 2005, p. 121.
  77. ^ Godfrey & Jungers 2002, p. 106.
  78. ^ Godfrey & Jungers 2002, p. 97.
  79. ^ Rose 2006, p. 181.
  80. ^ a b c Covert 2002, p. 18.
  81. ^ Dunkel, Zijlstra & Groves 2012, p. 68.
  82. ^ a b c Mittermeier, Rylands & Konstant 1999, p. 4.
  83. ^ a b c Osman Hill 1953, p. 96.
  84. ^ Gebo 2002, p. 39.
  85. ^ Cuozzo & Yamashita 2006, p. 73.
  86. ^ a b c Rose 2006, pp. 166–167.
  87. ^ a b c d Tattersall 2006, p. 7.
  88. ^ Ollivier et al. 2004.
  89. ^ Ankel-Simons 2007, p. 458.
  90. ^ Mittermeier, Rylands & Konstant 1999, p. 6.
  91. ^ a b c d e Rose 2006, p. 180.
  92. ^ Rose 2006, p. 184.
  93. ^ Godfrey & Jungers 2002, pp. 106 & 112.
  94. ^ Ankel-Simons 2007, p. 429.
  95. ^ a b Mittermeier, Rylands & Konstant 1999, pp. 4–5.
  96. ^ Ankel-Simons 2007, p. 431.
  97. ^ a b c Cartmill & Smith 2011, p. 91.
  98. ^ Dagosto 1988, pp. 47–48.
  99. ^ Dagosto 1988, p. 49.
  100. ^ Ankel-Simons 2007, p. 68.
  101. ^ a b Whitten & Brockman 2001, p. 323.
  102. ^ Rose 2006, pp. 168 & 180.
  103. ^ Plavcan 2004, p. 239.
  104. ^ Ankel-Simons 2007, p. 400.
  105. ^ a b Ankel-Simons 2007, pp. 392–394.
  106. ^ a b c d e f Mittermeier, Rylands & Konstant 1999, pp. 24–25.
  107. ^ Ankel-Simons 2007, p. 396.
  108. ^ Beard 1988, p. 85.
  109. ^ Ankel-Simons 2007, pp. 392–393 & 400–401.
  110. ^ a b Ankel-Simons 2007, pp. 392–393.
  111. ^ Ankel-Simons 2007, p. 402.
  112. ^ Ankel-Simons 2007, p. 410.
  113. ^ Ankel-Simons 2007, p. 401.
  114. ^ Ankel-Simons 2007, pp. 410–411.
  115. ^ Mittermeier, Rylands & Konstant 1999, p. 26.
  116. ^ Rose 2006, pp. 181–182.
  117. ^ a b Whitten & Brockman 2001, pp. 325–326.
  118. ^ Whitten & Brockman 2001, pp. 330–331.
  119. ^ Cartmill & Smith 2011, p. 88.
  120. ^ Osman Hill 1953, p. 81.
  121. ^ Osman Hill 1953, p. 93.
  122. ^ Osman Hill 1953, p. 391.
  123. ^ Osman Hill 1953, p. 672.
  124. ^ Ankel-Simons 2007, p. 523.
  125. ^ Ankel-Simons 2007, p. 522.
  126. ^ Ankel-Simons 2007, p. 521.
  127. ^ a b c Mittermeier, Rylands & Konstant 1999, pp. 4–6.
  128. ^ Mittermeier, Rylands & Konstant 1999, p. 5.
  129. ^ Whitten & Brockman 2001, pp. 325 & 335.
  130. ^ Fichtel & Kappeler 2009, pp. 395–396.
  131. ^ Fichtel & Kappeler 2009, pp. 401–402.
  132. ^ a b Nekaris & Bearder 2011, p. 51.
  133. ^ a b Mittermeier, Rylands & Konstant 1999, pp. 26–27.
  134. ^ Gould, Sauther & Cameron 2011, p. 74.
  135. ^ Fichtel & Kappeler 2009, pp. 395 & 397.
  136. ^ Fichtel & Kappeler 2009, p. 398.
  137. ^ Mittermeier, Rylands & Konstant 1999, pp. 15–16.
  138. ^ Overdorff & Tecot 2006, p. 247.
  139. ^ Cloninger & Kedia 2011, p. 86.
  140. ^ Mittermeier, Rylands & Konstant 1999, pp. 25–26.
  141. ^ Mittermeier, Rylands & Konstant 1999, pp. 5 & 26.
  142. ^ a b c d e f g Covert 2002, pp. 16–17.
  143. ^ Mittermeier, Rylands & Konstant 1999, pp. 22–24.
  144. ^ a b c Covert 2002, p. 16.
  145. ^ a b Mittermeier, Rylands & Konstant 1999, p. 14.
  146. ^ Mittermeier, Rylands & Konstant 1999, p. 19.
  147. ^ Mittermeier, Rylands & Konstant 1999, pp. 32–34.
  148. ^ "Lemurs found to be 'most threatened mammals' in the world". CNN. 13 July 2012. from the original on 21 August 2012. Retrieved 28 September 2012.
  149. ^ Fitch-Snyder & Livingstone 2008.
  150. ^ Nekaris et al. 2010, p. 878.
  151. ^ "Appendices I, II and III". Convention on International Trade in Endangered Species of Wild Fauna and Flora. 25 September 2012. from the original on 9 October 2012. Retrieved 1 October 2012.

Literature cited edit

  • Ankel-Simons, F. (2007). Primate Anatomy (3rd ed.). Academic Press. ISBN 978-0-12-372576-9.
  • Beard, K.C. (1988). "The phylogenetic significance of strepsirhinism in Paleogene primates". International Journal of Primatology. 9 (2): 83–96. doi:10.1007/BF02735730. S2CID 32127974.
  • Campbell, C.J.; Fuentes, A.; MacKinnon, K.C.; Bearder, S.K.; Stumpf, R. M, eds. (2011). Primates in Perspective (2nd ed.). Oxford University Press. ISBN 978-0-19-539043-8.
    • Gould, L.; Sauther, M.; Cameron, A. "Chapter 5: Lemuriformes". In Campbell et al. (2011), pp. 55–79.
    • Hartwig, W. "Chapter 3: Primate evolution". In Campbell et al. (2011), pp. 19–31.
    • Nekaris, N.A.I.; Bearder, S.K. "Chapter 4: The lorisiform primates of Asia and mainland Africa: Diversity shrouded in darkness". In Campbell et al. (2011), pp. 34–54.
  • Cartmill, M. (2010). "Primate Classification and Diversity". In Platt, M.; Ghazanfar, A. (eds.). Primate Neuroethology. Oxford University Press. pp. 10–30. ISBN 978-0-19-532659-8.
  • Cartmill, M.; Smith, F.H. (2011). The Human Lineage. John Wiley & Sons. ISBN 978-1-118-21145-8.
  • Cloninger, C.R.; Kedia, S. (2011). "Chapter 5: The phylogenesis of human personality: Identifying the precursors of cooperation, altruism, and well-being". In Sussman, R.W.; Cloninger, C.R. (eds.). Origins of Altruism and Cooperation. Springer. ISBN 978-1-4419-9519-3.
  • Dagosto, M. (1988). "Implications of postcranial evidence for the origin of euprimates". Journal of Human Evolution. 17 (1–2): 35–77. doi:10.1016/0047-2484(88)90048-6.
  • Dunkel, A.R.; Zijlstra, J.S.; Groves, C.P. (2012). (PDF). Lemur News. 16: 64–70. ISSN 1608-1439. Archived from the original (PDF) on 2016-11-06. Retrieved 2012-09-28.
  • Fitch-Snyder, H.; Livingstone, K. (2008). "Lorises: The surprise primate". Zoonooz. pp. 10–14. ISSN 0044-5282.
  • Fichtel, C.; Kappeler, P.M. (2009). "Chapter 19: Human universals and primate symplesiomorphies: Establishing the lemur baseline". In Kappeler, P.M.; Silk, J.B. (eds.). Mind the Gap: Tracing the origins of human universals. Springer. pp. 395–426. ISBN 978-3-642-02724-6.
  • Franzen, J.L.; Gingerich, P.D.; Habersetzer, J.; Hurum, J.H.; von Koenigswald, W.; Smith, B.H. (2009). "Complete primate skeleton from the Middle Eocene of Messel in Germany: Morphology and paleobiology". PLOS ONE. 4 (5): e5723. Bibcode:2009PLoSO...4.5723F. doi:10.1371/journal.pone.0005723. PMC 2683573. PMID 19492084.
  • Geoffroy Saint-Hilaire, É. (1812). "Suite au tableau des quadrumanes. Seconde famille. Lemuriens. Strepsirrhini". Annales du Muséum d'Histoire Naturelle (in French). 19: 156–170.
  • Gingerich, P.D. (1975). "A new genus of Adapidae (Mammalia, Primates) from the Late Eocene of Southern France, and its significance for the origin of higher primates". Contributions from the Museum of Paleontology. 24 (15). University of Michigan: 163–170. hdl:2027.42/48482.
  • Godinot, M. (1998). "A summary of adapiform systematics and phylogeny". Folia Primatologica. 69 (Suppl. 1): 218–249. doi:10.1159/000052715. S2CID 84469830.
  • Godinot, M. (2006). "Lemuriform origins as viewed from the fossil record". Folia Primatologica. 77 (6): 446–464. doi:10.1159/000095391. PMID 17053330. S2CID 24163044.
  • Gould, L.; Sauther, M.L., eds. (2006). Lemurs: Ecology and adaptation. Springer. ISBN 978-0-387-34585-7.
    • Cuozzo, F.P.; Yamashita, N. "Chapter 4: Impact of ecology on the teeth of extant lemurs: A review of dental adaptations, function, and life history". In Gould & Sauther (2006), pp. 67–96.
    • Tattersall, I. "Chapter 1: Origin of the Malagasy Strepsirhine primates". In Gould & Sauther (2006), pp. 3–18.
  • Groves, C.P. (1998). "Systematics of tarsiers and lorises". Primates. 39 (1): 13–27. doi:10.1007/BF02557740. S2CID 10869981.
  • Groves, C. P. (2005). "Strepsirrhini". In Wilson, D. E.; Reeder, D. M. (eds.). Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Baltimore: Johns Hopkins University Press. p. 111. ISBN 0-801-88221-4. OCLC 62265494.
  • Groves, C.P. (2008). Extended Family: Long lost cousins: A personal look at the history of primatology. Conservation International. ISBN 978-1-934151-25-9.
  • Gunnell, G.F.; Rose, K.D.; Rasmussen, D.T. (2008). "Euprimates". In Janis, C.M.; Gunnell, G.F.; Uhen, M.D. (eds.). Small Mammals, Xenarthrans, and Marine Mammals. Evolution of Tertiary Mammals of North America. Vol. 2. Cambridge, England; New York: Cambridge University Press. pp. 239–262. ISBN 978-0-521-78117-6.
  • Hartwig, W.C., ed. (2002). The Primate Fossil Record. Cambridge University Press. ISBN 978-0-521-66315-1.
    • Beard, K.C. "Chapter 9: Basal anthropoids". In Hartwig (2002), pp. 133–149.
    • Covert, H.H. "Chapter 3: The earliest fossil primates and the evolution of prosimians: Introduction". In Hartwig (2002), pp. 13–20.
    • Gebo, D.L. "Chapter 4: Adapiformes: Phylogeny and adaptation". In Hartwig (2002), pp. 21–44.
    • Godfrey, L.R.; Jungers, W.L. "Chapter 7: Quaternary fossil lemurs". In Hartwig (2002), pp. 97–121.
  • Jenkins, P.D.; Napier, P.H. (1987). Suborder Strepsirrhini, including the subfossil Madagascan lemurs and family Tarsiidae. Catalogue of Primates in the British Museum (Natural History) and elsewhere in the British Isles. Vol. Part 4. British Museum (Natural History). ISBN 978-0-565-01008-9.
  • Miller, E.R.; Gunnell, G.F.; Martin, R.D. (2005). "Deep time and the search for anthropoid origins" (PDF). American Journal of Physical Anthropology. 128: 60–95. doi:10.1002/ajpa.20352. PMID 16369958.
  • Mittermeier, R.A.; Rylands, A.B.; Konstant, W.R. (1999). "Primates of the world: An introduction". In Nowak, R.M. (ed.). Walker's Mammals of the World (6th ed.). Johns Hopkins University Press. pp. 1–52. ISBN 978-0-8018-6251-9.
  • Nekaris, K.A.I.; Shepherd, C.R.; Starr, C.R.; Nijman, V. (2010). "Exploring cultural drivers for wildlife trade via an ethnoprimatological approach: A case study of slender and slow lorises (Loris and Nycticebus) in South and Southeast Asia". American Journal of Primatology. 72 (10): 877–886. doi:10.1002/ajp.20842. PMID 20806336. S2CID 21711250.
  • Ollivier, F.J.; Samuelson, D.A.; Brooks, D.E.; Lewis, P.A.; Kallberg, M.E.; Komaromy, A.M. (2004). "Comparative morphology of the tapetum lucidum (among selected species)". Veterinary Ophthalmology. 7 (1): 11–22. doi:10.1111/j.1463-5224.2004.00318.x. PMID 14738502. S2CID 15419778.
  • Osman Hill, W.C. (1953). "I – Strepsirhini". Primates Comparative Anatomy and Taxonomy. Edinburgh Univ. Pubs. Science & Maths. Vol. 3. Edinburgh University Press. OCLC 500576914.
  • Overdorff, D.J.; Tecot, S.R. (2006). "Chapter 11: Social pair-bonding and resource defense in wild red-bellied lemurs (Eulemur rubriventer)". In Gould, L.; Sauther, M.L. (eds.). Lemurs: Ecology and adaptation. Springer. pp. 235–254. doi:10.1007/978-0-387-34586-4_11. ISBN 978-0-387-34585-7. S2CID 85613386.
  • Plavcan, J.M. (2004). "Chapter 13: Sexual selection, measures of sexual selection, and sexual dimorphism in primates". In Kappeler, P.M.; van Schaik, C.P. (eds.). Sexual Selection in Primates: New and comparative perspectives. Cambridge University Press. pp. 230–252. ISBN 978-0-521-53738-4.
  • Pocock, R.I. (1918). "On the external characters of the lemurs and of Tarsius". Proceedings of the Zoological Society of London. 1918 (1–2): 19–53. doi:10.1111/j.1096-3642.1918.tb02076.x.
  • Rasmussen, D.T.; Nekaris, K.A.I. (1998). "Evolutionary history of lorisiform primates" (PDF). Folia Primatologica. 69 (Suppl. 1) (7): 250–285. doi:10.1159/000052716. PMID 9595692. S2CID 14113728.
  • Rose, K.D. (2006). The Beginning of the Age of Mammals. Johns Hopkins University Press. ISBN 978-0-8018-8472-6.
  • Steiper, M.E.; Seiffert, E.R. (2012). "Evidence for a convergent slowdown in primate molecular rates and its implications for the timing of early primate evolution". Proceedings of the National Academy of Sciences. 109 (16): 6006–6011. Bibcode:2012PNAS..109.6006S. doi:10.1073/pnas.1119506109. PMC 3341044. PMID 22474376.
  • Sussman, R.W. (2003). Primate Ecology and Social Structure. Pearson Custom Publishing. ISBN 978-0-536-74363-3.
  • Szalay, F.S.; Delson, E. (1980). Evolutionary History of the Primates. Academic Press. ISBN 978-0-12-680150-7. OCLC 893740473.
  • Tabuce, R.; Marivaux, L.; Lebrun, R.; Adaci, M.; Bensalah, M.; Fabre, P.-H.; et al. (2009). "Anthropoid versus strepsirhine status of the African Eocene primates Algeripithecus and Azibius: Craniodental evidence". Proceedings of the Royal Society B: Biological Sciences. 276 (1676): 4087–4094. doi:10.1098/rspb.2009.1339. PMC 2821352. PMID 19740889.
    • "African Origin Of Anthropoid Primates Called Into Question With New Fossil Discovery". Science Daily (Press release). 17 September 2009.
  • Vaughan, T.; Ryan, J.; Czaplewski, N. (2011). "Chapter 12: Primates". Mammalogy (5th ed.). Jones & Bartlett Learning. ISBN 978-0-7637-6299-5.
  • Whitten, P.L.; Brockman, D.K. (2001). "Chapter 14: Strepsirrhine reproductive ecology". In Ellison, P.T. (ed.). Reproductive Ecology and Human Evolution. Transaction Publishers. pp. 321–350. ISBN 978-0-202-30658-2.
  • Williams, B.A.; Kay, R.F.; Christopher Kirk, E.; Ross, C.F. (2010). (PDF). Journal of Human Evolution. 59 (5): 567–573, discussion 573–579. doi:10.1016/j.jhevol.2010.01.003. PMID 20188396. Archived from the original (PDF) on 17 May 2013.
  • Wright, Patricia C.; Simons, Elwyn L., eds. (2003). Tarsiers: Past, present, and future. Rutgers University Press. ISBN 978-0-8135-3236-3.
    • Schwartz, J.H. "Chapter 3: How close are the similarities between Tarsius and other primates?". In Wright & Simons (2003), pp. 50–96.
    • Simons, E.L. "Chapter 1: The fossil record of tarsier evolution". In Wright & Simons (2003), pp. 9–34.
    • Yoder, A.D. "Chapter 7: The phylogenetic position of the genus Tarsius: Whose side are you on?". In Wright & Simons (2003), pp. 161–175.

External links edit

  •   Media related to Strepsirrhini at Wikimedia Commons
  •   Data related to Strepsirrhini at Wikispecies

April 22, 2024
strepsirrhini, explanation, very, similar, terms, adapiformes, lemuriformes, strepsirhini, strep, suborder, primates, that, includes, lemuriform, primates, which, consist, lemurs, madagascar, galagos, bushbabies, pottos, from, africa, lorises, from, india, sou. For an explanation of very similar terms see Adapiformes and Lemuriformes Strepsirrhini or Strepsirhini ˌ s t r ɛ p s e ˈ r aɪ n i STREP se RY nee is a suborder of primates that includes the lemuriform primates which consist of the lemurs of Madagascar galagos bushbabies and pottos from Africa and the lorises from India and southeast Asia a Collectively they are referred to as strepsirrhines Also belonging to the suborder are the extinct adapiform primates which thrived during the Eocene in Europe North America and Asia but disappeared from most of the Northern Hemisphere as the climate cooled Adapiforms are sometimes referred to as being lemur like although the diversity of both lemurs and adapiforms does not support this comparison StrepsirrhiniTemporal range 55 8 0 Ma PreꞒ Ꞓ O S D C P T J K Pg N Early Eocene to Present 1 A sample of strepsirrhine diversity eight biological genera are depicted from top left to right Lemur Propithecus Daubentonia Varecia Microcebus Darwinius Loris Otolemur Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Class Mammalia Order Primates Suborder StrepsirrhiniE Geoffroy 1812 Infraorders AdapiformesLemuriformes a See text sister Haplorhini Eocene Miocene fossil sites Range of extant strepsirrhine primates Strepsirrhines are defined by their wet moist rhinarium the tip of the snout hence the colloquial but inaccurate term wet nosed similar to the rhinaria of canines and felines They also have a smaller brain than comparably sized simians large olfactory lobes for smell a vomeronasal organ to detect pheromones and a bicornuate uterus with an epitheliochorial placenta Their eyes contain a reflective layer to improve their night vision and their eye sockets include a ring of bone around the eye but they lack a wall of thin bone behind it Strepsirrhine primates produce their own vitamin C whereas haplorhine primates must obtain it from their diets Lemuriform primates are characterized by a toothcomb a specialized set of teeth in the front lower part of the mouth mostly used for combing fur during grooming Many of today s living strepsirrhines are endangered due to habitat destruction hunting for bushmeat and live capture for the exotic pet trade Both living and extinct strepsirrhines are behaviorally diverse although all are primarily arboreal tree dwelling Most living lemuriforms are nocturnal while most adapiforms were diurnal Both living and extinct groups primarily fed on fruit leaves and insects Contents 1 Etymology 2 Evolutionary history 2 1 Unclear origin 2 2 Adapiform evolution 2 3 Lemuriform evolution 3 History of classification 3 1 Controversies 3 2 Infraordinal classification and clade terminology 4 Anatomy and physiology 4 1 Grooming apparatus 4 2 Eyes 4 3 Skull 4 4 Ears 4 5 Neck arteries 4 6 Ankle bones 4 7 Sex characteristics 4 8 Rhinarium and olfaction 4 9 Reproductive physiology 5 Behavior 5 1 Social systems and communication 5 2 Locomotion 5 3 Diet 6 Distribution and habitat 7 Conservation 8 Explanatory notes 9 References 9 1 Citations 9 2 Literature cited 10 External linksEtymology editThe taxonomic name Strepsirrhini derives from the Greek strepsis strepsis a turning round and ῥis rhis nose snout in pl nostrils GEN ῥinos rhinos 5 which refers to the appearance of the sinuous comma shaped nostrils on the rhinarium or wet nose 6 7 The name was first used by French naturalist Etienne Geoffroy Saint Hilaire in 1812 as a subordinal rank comparable to Platyrrhini New World monkeys and Catarrhini Old World monkeys 8 In his description he mentioned Les narines terminales et sinueuses Nostrils terminal and winding 9 When British zoologist Reginald Innes Pocock revived Strepsirrhini and defined Haplorhini in 1918 he omitted the second 10 r from both Strepsirhini and Haplorhini instead of Strepsirrhini and Haplorrhini 11 12 although he did not remove the second r from Platyrrhini or Catarrhini both of which were also named by E Geoffroy in 1812 Following Pocock many researchers continued to spell Strepsirrhini with a single r until primatologists Paulina Jenkins and Prue Napier pointed out the error in 1987 13 Evolutionary history editStrepsirrhines include the extinct adapiforms and the lemuriform primates which include lemurs and lorisoids lorises pottos and galagos 14 Strepsirrhines diverged from the haplorhine primates near the beginning of the primate radiation between 55 and 90 mya Older divergence dates are based on genetic analysis estimates while younger dates are based on the scarce fossil record Lemuriform primates may have evolved from either cercamoniines or sivaladapids both of which were adapiforms that may have originated in Asia They were once thought to have evolved from adapids a more specialized and younger branch of adapiform primarily from Europe Primate phylogeny Euarchonta Scandentia treeshrews Primatomorpha Dermoptera colugos Primates Plesiadapiformes Euprimates Haplorhini Simians Tarsiers Omomyiformes Strepsirrhini Adapiformes Lemuriformes Lorisoids Lemurs Strepsirrhines and haplorhines diverged shortly after the emergence of the first true primates euprimates The relationship between euprimates treeshrews colugos and plesiadapiforms is less certain Sometimes plesiadapiforms are grouped with the euprimates under the order Primates colugos are grouped with primates under Primatomorpha and all four are grouped under Euarchonta 15 Lemurs rafted from Africa to Madagascar between 47 and 54 mya whereas the lorises split from the African galagos around 40 mya and later colonized Asia The lemuriforms and particularly the lemurs of Madagascar are often portrayed inappropriately as living fossils or as examples of basal or inferior primates 16 17 18 These views have historically hindered the understanding of mammalian evolution and the evolution of strepsirrhine traits 16 such as their reliance on smell olfaction characteristics of their skeletal anatomy and their brain size which is relatively small In the case of lemurs natural selection has driven this isolated population of primates to diversify significantly and fill a rich variety of ecological niches despite their smaller and less complex brains compared to simians 17 18 Unclear origin edit The divergence between strepsirrhines simians and tarsiers likely followed almost immediately after primates first evolved 19 Although few fossils of living primate groups lemuriforms tarsiers and simians are known from the Early to Middle Eocene 20 21 22 evidence from genetics and recent fossil finds both suggest they may have been present during the early adaptive radiation 23 The origin of the earliest primates that the simians and tarsiers both evolved from is a mystery Both their place of origin and the group from which they emerged are uncertain Although the fossil record demonstrating their initial radiation across the Northern Hemisphere is very detailed 24 the fossil record from the tropics where primates most likely first developed is very sparse particularly around the time that primates and other major clades b of eutherian mammals first appeared Lacking detailed tropical fossils geneticists and primatologists have used genetic analyses to determine the relatedness between primate lineages and the amount of time since they diverged Using this molecular clock divergence dates for the major primate lineages have suggested that primates evolved more than 80 90 mya nearly 40 million years before the first examples appear in the fossil record 25 The early primates include both nocturnal and diurnal small bodied species 26 and all were arboreal with hands and feet specially adapted for maneuvering on small branches 27 Plesiadapiforms from the early Paleocene are sometimes considered archaic primates because their teeth resembled those of early primates and because they possessed adaptations to living in trees such as a divergent big toe hallux Although plesiadapiforms were closely related to primates they may represent a paraphyletic group from which primates may or may not have directly evolved 28 and some genera may have been more closely related to colugos c which are thought to be more closely related to primates 29 nbsp Early primates possessed adaptations for arboreal locomotion that enabled maneuvering along fine branches as seen in this slender loris The first true primates euprimates do not appear in the fossil record until the early Eocene 55 mya at which point they radiated across the Northern Hemisphere during a brief period of rapid global warming known as the Paleocene Eocene Thermal Maximum 23 These first primates included Cantius Donrussellia Altanius and Teilhardina on the northern continents 30 as well as the more questionable and fragmentary fossil Altiatlasius from Paleocene Africa 19 These earliest fossil primates are often divided into two groups adapiforms d and omomyiforms e Both appeared suddenly in the fossil record without transitional forms to indicate ancestry 31 and both groups were rich in diversity and were widespread throughout the Eocene The last branch to develop were the adapiforms a diverse and widespread group that thrived during the Eocene 56 to 34 million years ago mya in Europe North America and Asia They disappeared from most of the Northern Hemisphere as the climate cooled The last of the adapiforms died out at the end of the Miocene 7 mya Adapiform evolution edit nbsp Notharctus a type of North American adapiform resembled lemurs but did not give rise to them Adapiform primates are extinct strepsirrhines that shared many anatomical similarities with lemurs 32 They are sometimes referred to as lemur like primates although the diversity of both lemurs and adapiforms do not support this analogy 33 Like the living strepsirrhines adapiforms were extremely diverse 16 with at least 30 genera and 80 species known from the fossil record as of the early 2000s 34 35 They diversified across Laurasia during the Eocene 32 some reaching North America via a land bridge 36 They were among the most common mammals found in the fossil beds from that time A few rare species have also been found in northern Africa 32 The most basal of the adapiforms include the genera Cantius from North America and Europe and Donrussellia from Europe The latter bears the most ancestral traits so it is often considered a sister group or stem group of the other adapiforms 37 Adapiforms are often divided into three major groups Adapids were most commonly found in Europe although the oldest specimens Adapoides from middle Eocene China indicate that they most likely evolved in Asia and immigrated They died out in Europe during the Grande Coupure part of a significant extinction event at the end of the Eocene 38 Notharctids which most closely resembled some of Madagascar s lemurs come from Europe and North America The European branch is often referred to as cercamoniines 39 The North American branch thrived during the Eocene but did not survive into the Oligocene 40 41 Like the adapids the European branch were also extinct by the end of the Eocene 36 Sivaladapids of southern and eastern Asia are best known from the Miocene and the only adapiforms to survive past the Eocene Oligocene boundary 34 mya Their relationship to the other adapiforms remains unclear 42 They had vanished before the end of the Miocene 7 mya 32 The relationship between adapiform and lemuriform primates has not been clearly demonstrated so the position of adapiforms as a paraphyletic stem group is questionable Both molecular clock data and new fossil finds suggest that the lemuriform divergence from the other primates and the subsequent lemur lorisoid split both predate the appearance of adapiforms in the early Eocene 31 New calibration methods may reconcile the discrepancies between the molecular clock and the fossil record favoring more recent divergence dates 43 The fossil record suggests that the strepsirrhine adapiforms and the haplorhine omomyiforms had been evolving independently before the early Eocene although their most basal members share enough dental similarities to suggest that they diverged during the Paleocene 66 55 mya 32 Lemuriform evolution edit See also Evolution of lemurs Lemuriform origins are unclear and debated American paleontologist Philip Gingerich proposed that lemuriform primates evolved from one of several genera of European adapids based on similarities between the front lower teeth of adapids and the toothcomb of extant lemuriforms however this view is not strongly supported due to a lack of clear transitional fossils 44 Instead lemuriforms may be descended from a very early branch of Asian cercamoniines or sivaladapids that migrated to northern Africa 22 45 Until discoveries of three 40 million year old fossil lorisoids Karanisia Saharagalago and Wadilemur in the El Fayum deposits of Egypt between 1997 and 2005 the oldest known lemuriforms had come from the early Miocene 20 mya of Kenya and Uganda These newer finds demonstrate that lemuriform primates were present during the middle Eocene in Afro Arabia and that the lemuriform lineage and all other strepsirrhine taxa had diverged before then 46 47 48 Djebelemur from Tunisia dates to the late early or early middle Eocene 52 to 46 mya and has been considered a cercamoniine 49 but also may have been a stem lemuriform 22 Azibiids from Algeria date to roughly the same time and may be a sister group of the djebelemurids Together with Plesiopithecus from the late Eocene Egypt the three may qualify as the stem lemuriforms from Africa 45 Molecular clock estimates indicate that lemurs and the lorisoids diverged in Africa during the Paleocene approximately 62 mya Between 47 and 54 mya lemurs dispersed to Madagascar by rafting 47 In isolation the lemurs diversified and filled the niches often filled by monkeys and apes today 50 In Africa the lorises and galagos diverged during the Eocene approximately 40 mya 47 Unlike the lemurs in Madagascar they have had to compete with monkeys and apes as well as other mammals 17 History of classification edit nbsp The suborder Strepsirrhini was proposed by E Geoffroy in 1812 The taxonomy of strepsirrhines is controversial and has a complicated history Confused taxonomic terminology and oversimplified anatomical comparisons have created misconceptions about primate and strepsirrhine phylogeny illustrated by the media attention surrounding the single Ida fossil in 2009 Strepsirrhine primates were first grouped under the genus Lemur by Swedish taxonomist Carl Linnaeus in the 10th edition of Systema Naturae published in 1758 At the time only three species were recognized one of which the colugo is no longer recognized as a primate 51 In 1785 Dutch naturalist Pieter Boddaert divided the genus Lemur into two genera Prosimia for the lemurs colugos and tarsiers and Tardigradus for the lorises 52 Ten years later E Geoffroy and Georges Cuvier grouped the tarsiers and galagos due to similarities in their hindlimb morphology a view supported by German zoologist Johann Karl Wilhelm Illiger who placed them in the family Macrotarsi while placing the lemurs and tarsiers in the family Prosimia Prosimii in 1811 The use of the tarsier galago classification continued for many years until 1898 when Dutch zoologist Ambrosius Hubrecht demonstrated two different types of placentation formation of a placenta in the two groups 53 English comparative anatomist William Henry Flower created the suborder Lemuroidea in 1883 to distinguish these primates from the simians which were grouped under English biologist St George Jackson Mivart s suborder Anthropoidea Simiiformes According to Flower the suborder Lemuroidea contained the families Lemuridae lemurs lorises and galagos Chiromyidae aye aye and Tarsiidae tarsiers Lemuroidea was later replaced by Illiger s suborder Prosimii 53 Many years earlier in 1812 E Geoffroy first named the suborder Strepsirrhini in which he included the tarsiers 54 This taxonomy went unnoticed until 1918 when Pocock compared the structure of the nose and reinstated the use of the suborder Strepsirrhini while also moving the tarsiers and the simians into a new suborder Haplorhini 11 53 It was not until 1953 when British anatomist William Charles Osman Hill wrote an entire volume on strepsirrhine anatomy that Pocock s taxonomic suggestion became noticed and more widely used Since then primate taxonomy has shifted between Strepsirrhini Haplorhini and Prosimii Anthropoidea multiple times 53 Most of the academic literature provides a basic framework for primate taxonomy usually including several potential taxonomic schemes 55 Although most experts agree upon phylogeny 56 many disagree about nearly every level of primate classification 55 Competing strepsirrhine taxonomic nomenclature 2 infraorders 3 3 infraorders 4 Suborder Strepsirrhini Infraorder Adapiformes Superfamily Adapoidea Family Adapidae Family Notharctidae Family Sivaladapidae Infraorder Lemuriformes Superfamily Lemuroidea Family Archaeolemuridae Family Cheirogaleidae Family Daubentoniidae Family Indriidae Family Lemuridae Family Lepilemuridae Family Megaladapidae Family Palaeopropithecidae Superfamily Lorisoidea Family Lorisidae Family Galagidae Suborder Strepsirrhini Infraorder Adapiformes Superfamily Adapoidea Family Adapidae Family Notharctidae Family Sivaladapidae Infraorder Lemuriformes Superfamily Lemuroidea Family Archaeolemuridae Family Cheirogaleidae Family Daubentoniidae Family Indriidae Family Lemuridae Family Lepilemuridae Family Megaladapidae Family Palaeopropithecidae Infraorder Lorisiformes Superfamily Lorisoidea Family Lorisidae Family Galagidae Controversies edit The most commonly recurring debate in primatology during the 1970s 1980s and early 2000s concerned the phylogenetic position of tarsiers compared to both simians and the other prosimians 57 58 Tarsiers are most often placed in either the suborder Haplorhini with the simians or in the suborder Prosimii with the strepsirrhines 50 Prosimii is one of the two traditional primate suborders and is based on evolutionary grades groups united by anatomical traits rather than phylogenetic clades while the Strepsirrhini Haplorrhini taxonomy was based on evolutionary relationships 7 Yet both systems persist because the Prosimii Anthropoidea taxonomy is familiar and frequently seen in the research literature and textbooks 25 Strepsirrhines are traditionally characterized by several symplesiomorphic ancestral traits not shared with the simians particularly the rhinarium f 50 60 Other symplesiomorphies include long snouts convoluted maxilloturbinals relatively large olfactory bulbs and smaller brains The toothcomb is a synapomorphy shared derived trait seen among lemuriforms 50 although it is frequently and incorrectly used to define the strepsirrhine clade g Strepsirrhine primates are also united in possessing an epitheliochorial placenta 50 Unlike the tarsiers and simians strepsirrhines are capable of producing their own vitamin C and do not need it supplied in their diet 62 Further genetic evidence for the relationship between tarsiers and simians as a haplorhine clade is the shared possession of three SINE markers 63 Because of their historically mixed assemblages which included tarsiers and close relatives of primates both Prosimii and Strepsirrhini have been considered wastebasket taxa for lower primates 64 65 Regardless the strepsirrhine and haplorrhine clades are generally accepted and viewed as the preferred taxonomic division Yet tarsiers still closely resemble both strepsirrhines and simians in different ways 25 and since the early split between strepsirrhines tarsiers and simians is ancient and hard to resolve 66 a third taxonomic arrangement with three suborders is sometimes used Prosimii Tarsiiformes and Anthropoidea 14 More often the term prosimian is no longer used in official taxonomy 67 but is still used to illustrate the behavioral ecology of tarsiers relative to the other primates 60 In addition to the controversy over tarsiers the debate over the origins of simians once called the strepsirrhine clade into question Arguments for an evolutionary link between adapiforms and simians made by paleontologists Gingerich Elwyn L Simons Tab Rasmussen and others could have potentially excluded adapiforms from Strepsirrhini 68 69 In 1975 Gingerich proposed a new suborder Simiolemuriformes 70 to suggest that strepsirrhines are more closely related to simians than tarsiers 71 However no clear relationship between the two had been demonstrated by the early 2000s 69 The idea reemerged briefly in 2009 during the media attention surrounding Darwinius masillae dubbed Ida a cercamoniine from Germany that was touted as a missing link between humans and earlier primates simians and adapiforms 72 However the cladistic analysis was flawed and the phylogenetic inferences and terminology were vague 72 Although the authors noted that Darwinius was not a fossil lemur they did emphasize the absence of a toothcomb 73 which adapiforms did not possess 37 Infraordinal classification and clade terminology edit nbsp The media attention over Ida played upon confused terminology and misconceptions about strepsirrhines Strepsirrhini phylogeny 45 Adapiformes stem lemuriforms lemuriforms or crown strepsirrhines lemuroid clade Daubentoniidae other lemurs lorisoid clade lorises galagos Within Strepsirrhini two common classifications include either two infraorders Adapiformes and Lemuriformes 74 or three infraorders Adapiformes Lemuriformes Lorisiformes 75 A less common taxonomy places the aye aye Daubentoniidae in its own infraorder Chiromyiformes 76 In some cases plesiadapiforms are included within the order Primates in which case Euprimates is sometimes treated as a suborder with Strepsirrhini becoming an infraorder and the Lemuriformes and others become parvorders 14 Regardless of the infraordinal taxonomy Strepsirrhini is composed of three ranked superfamilies and 14 families seven of which are extinct 74 Three of these extinct families included the recently extinct giant lemurs of Madagascar 77 many of which died out within the last 1 000 years following human arrival on the island 78 When Strepsirrhini is divided into two infraorders the clade containing all toothcombed primates can be called lemuriforms 74 When it is divided into three infraorders the term lemuriforms refers only to Madagascar s lemurs 50 and the toothcombed primates are referred to as either crown strepsirrhines 42 or extant strepsirrhines 7 Confusion of this specific terminology with the general term strepsirrhine along with oversimplified anatomical comparisons and vague phylogenetic inferences can lead to misconceptions about primate phylogeny and misunderstandings about primates from the Eocene as seen with the media coverage of Darwinius 72 Because the skeletons of adapiforms share strong similarities with those of lemurs and lorises researchers have often referred to them as primitive strepsirrhines 79 lemur ancestors or a sister group to the living strepsirrhines They are included in Strepsirrhini 7 and are considered basal members of the clade 80 Although their status as true primates is not questioned the questionable relationship between adapiforms and other living and fossil primates leads to multiple classifications within Strepsirrhini Often adapiforms are placed in their own infraorder due to anatomical differences with lemuriforms and their unclear relationship When shared traits with lemuriforms which may or may not be synapomorphic are emphasized they are sometimes reduced to families within the infraorder Lemuriformes or superfamily Lemuroidea 32 The first fossil primate described was the adapiform Adapis parisiensis by French naturalist Georges Cuvier in 1821 49 who compared it to a hyrax le Daman then considered a member of a now obsolete group called pachyderms 81 It was not recognized as a primate until it was reevaluated in the early 1870s 34 49 Originally adapiforms were all included under the family Adapidae which was divided into two or three subfamilies Adapinae Notharctinae and sometimes Sivaladapinae All North American adapiforms were lumped under Notharctinae while the Old World forms were usually assigned to Adapinae Around the 1990s two distinct groups of European adapids began to emerge based on differences in the postcranial skeleton and the teeth One of these two European forms was identified as cercamoniines which were allied with the notharctids found mostly in North America while the other group falls into the traditional adapid classification 37 The three major adapiform divisions are now typically regarded as three families within Adapiformes Notharctidae Adapidae and Sivaladapidae but other divisions ranging from one to five families are used as well 34 Anatomy and physiology editGrooming apparatus edit nbsp Strepsirrhines have a reflective layer in the eye called a tapetum lucidum that helps them see better at night All lemuriforms possess a specialized dental structure called a toothcomb 7 82 with the exception of the aye aye in which the structure has been modified into two continually growing hypselodont incisors or canine teeth similar to those of rodents Often the toothcomb is incorrectly used to characterize all strepsirrhines Instead it is unique to lemuriforms and is not seen among adapiforms Lemuriforms groom orally and also possess a grooming claw on the second toe of each foot for scratching in areas that are inaccessible to the mouth and tongue 7 82 83 Adapiforms may have had a grooming claw 37 but there is little evidence of this 84 The toothcomb consists of either two or four procumbent lower incisors and procumbent lower canine teeth followed by a canine shaped premolar 85 It is used to comb the fur during oral grooming Shed hairs that accumulate between the teeth of the toothcomb are removed by the sublingua or under tongue 83 Adapiforms did not possess a toothcomb Instead their lower incisors varied in orientation from somewhat procumbent to somewhat vertical and the lower canines were projected upwards and were often prominent Eyes edit Like all primates strepsirrhine orbits eye sockets have a postorbital bar a protective ring of bone created by a connection between the frontal and zygomatic bones 86 Both living and extinct strepsirrhines lack a thin wall of bone behind the eye referred to as postorbital closure which is only seen in haplorhine primates 86 87 Although the eyes of strepsirrhines point forward giving stereoscopic vision 86 the orbits do not face fully forward 87 Among living strepsirrhines most or all species are thought to possess a reflective layer behind the retina of the eye called a tapetum lucidum consisting of riboflavin crystals 88 which improves vision in low light 89 82 but they lack a fovea which improves day vision This differs from tarsiers which lack a tapetum lucidum but possess a fovea 90 Skull edit nbsp Strepsirrhines are characterized by a typically longer snout and wet nose compared to haplorhine primates Strepsirrhine primates have a brain relatively comparable to or slightly larger in size than most mammals 16 50 Compared to simians however they have a relatively small brain to body size ratio 87 Strepsirrhines are also traditionally noted for their unfused mandibular symphysis two halves of the lower jaw 87 however fusion of the mandibular symphysis was common in adapiforms 91 notably Notharctus 92 Also several extinct giant lemurs exhibited a fused mandibular symphysis 93 Ears edit Many nocturnal species have large independently movable ears 94 95 although there are significant differences in sizes and shapes of the ear between species 96 The structure of the middle and inner ear of strepsirrhines differs between the lemurs and lorisoids In lemurs the tympanic cavity which surrounds the middle ear is expanded This leaves the ectotympanic ring which supports the eardrum free within the auditory bulla 97 This trait is also seen in adapiforms 91 In lorisoids however the tympanic cavity is smaller and the ectotympanic ring becomes attached to the edge of the auditory bulla The tympanic cavity in lorisoids also has two accessory air spaces which are not present in lemurs Neck arteries edit Both lorisoids and cheirogaleid lemurs have replaced the internal carotid artery with an enlarged ascending pharyngeal artery 97 Ankle bones edit Strepsirrhines also possess distinctive features in their tarsus ankle bones that differentiate them from haplorhines such as a sloping talo fibular facet the face where the talus bone and fibula meet and a difference in the location of the position of the flexor fibularis tendon on the talus 98 These differences give strepsirrhines the ability to make more complex rotations of the ankle and indicate that their feet are habitually inverted or turned inward an adaptation for grasping vertical supports 99 Sex characteristics edit Sexual dichromatism different coloration patterns between males and females can be seen in most brown lemur species 100 but otherwise lemurs show very little if any difference in body size or weight between sexes This lack of sexual dimorphism is not characteristic of all strepsirrhines 101 Some adapiforms were sexually dimorphic with males bearing a larger sagittal crest a ridge of bone on the top of the skull to which jaw muscles attach and canine teeth 102 Lorisoids exhibit some sexual dimorphism 101 but males are typically no more than 20 percent larger than females 103 Rhinarium and olfaction edit nbsp The noses of five prosimian primates A dwarf lemur B greater galago C lesser galago D aye aye E tarsier A through D possess a rhinarium and are strepsirrhines whereas E does not and is a haplorhine Strepsirrhines have a long snout that ends in a moist and touch sensitive rhinarium similar to that of dogs and many other mammals The rhinarium is surrounded by vibrissae that are also sensitive to touch Convoluted maxilloturbinals on the inside of their nose filter warm and moisten the incoming air while olfactory receptors of the main olfactory system lining the ethmoturbinals detect airborne smells 50 104 The olfactory bulbs of lemurs are comparable in size to those of other arboreal mammals 50 The surface of the rhinarium does not have any olfactory receptors so it is not used for smell in terms of detecting volatile substances Instead it has sensitive touch receptors Merkel cells The rhinarium upper lip and gums are tightly connected by a fold of mucous membrane called the philtrum which runs from the tip of the nose to the mouth 105 The upper lip is constrained by this connection and has fewer nerves to control movement which leaves it less mobile than the upper lips of simians 106 107 The philtrum creates a gap diastema between the roots of the first two upper incisors 105 108 The strepsirrhine rhinarium can collect relatively non volatile fluid based chemicals traditionally categorized as pheromones and transmit them to the vomeronasal organ VNO 109 which is located below and in front of the nasal cavity above the mouth 110 The VNO is an encased duct like structure made of cartilage 111 and is isolated from the air passing through the nasal cavity 112 The VNO is connected to the mouth through nasopalatine ducts which communicate via the incisive foramen which pass through the hard palate at the top front of the mouth 110 Fluids traveling from the rhinarium to the mouth and then up the nasopalatine ducts to the VNO are detected and information is relayed to the accessory olfactory bulb which is relatively large in strepsirrhines 113 From the accessory olfactory bulb information is sent to the amygdala which handles emotions and then to the hypothalamus which handles basic body functions and metabolic processes This neural pathway differs from that used by the main olfactory system 114 All lemuriforms have a VNO as do tarsiers and some New World monkeys 115 Adapiforms exhibit the gap between the upper incisors which indicates the presence of a VNO but there is some disagreement over whether or not they possessed a rhinarium 116 Reproductive physiology edit Extant strepsirrhines have an epitheliochorial placenta 50 where the maternal blood does not come in direct contact with the fetal chorion like it does in the hemochorial placenta of haplorhines The strepsirrhine uterus has two distinct chambers bicornuate 106 Despite having similar gestation periods to comparably sized haplorhines fetal growth rates are generally slower in strepsirrhines which results in newborn offspring that are as little as one third the size of haplorhine newborns 106 117 Extant strepsirrhines also have a lower basal metabolic rate which elevates in females during gestation putting greater demands on the mother 118 Most primates have two mammary glands 119 but the number and positions vary between species within strepsirrhines 120 Lorises have two pairs 121 while others like the ring tailed lemur have one pair on the chest pectoral 122 The aye aye also has two mammary glands but they are located near the groin inguinal 123 In females the clitoris is sometimes enlarged and pendulous resembling the male penis which can make sex identification difficult for human observers 124 The clitoris may also have a bony structure in it similar to the baculum penis bone in males 125 Most male primates have a baculum but it is typically larger in strepsirrhines and usually forked at the tip 126 Behavior edit nbsp Like other primates strepsirrhinid infants often cling to their mother s fur Approximately three quarters of all extant strepsirrhine species are nocturnal sleeping in nests made from dead leaves or tree hollows during the day 127 All of the lorisoids from continental Africa and Asia are nocturnal a circumstance that minimizes their competition with the simian primates of the region which are diurnal The lemurs of Madagascar living in the absence of simians are more variable in their activity cycles The aye aye mouse lemurs woolly lemurs and sportive lemurs are nocturnal while ring tailed lemurs and most of their kin sifakas and indri are diurnal 80 Yet some or all of the brown lemurs Eulemur are cathemeral which means that they may be active during the day or night depending on factors such as temperature and predation 128 Many extant strepsirrhines are well adapted for nocturnal activity due to their relatively large eyes large movable ears sensitive tactile hairs strong sense of smell and the tapetum lucidum behind the retina 95 Among the adapiforms most are considered diurnal with the exception of Pronycticebus and Godinotia from Middle Eocene Europe both of which had large orbits that suggest nocturnality 80 91 Reproduction in most strepsirrhine species tends to be seasonal particularly in lemurs Key factors that affect seasonal reproduction include the length of the wet season subsequent food availability and the maturation time of the species 129 Like other primates strepsirrhines are relatively slow breeders compared to other mammals Their gestation period and interbirth intervals are usually long and the young develop slowly just like in haplorhine primates 106 117 Unlike simians some strepsirrhines produce two or three offspring although some produce only a single offspring Those that produce multiple offspring tend to build nests for their young These two traits are thought to be plesiomorphic ancestral for primates 106 The young are precocial relatively mature and mobile at birth but not as coordinated as ungulates hoofed mammals 50 Infant care by the mother is relatively prolonged compared to many other mammals and in some cases the infants cling to the mother s fur with their hands and feet 106 Despite their relatively smaller brains compared to other primates lemurs have demonstrated levels of technical intelligence in problem solving that are comparable to those seen in simians However their social intelligence differs often emphasizing within group competition over cooperation which may be due to adaptations for their unpredictable environment 130 Although lemurs have not been observed using objects as tools in the wild they can be trained to use objects as tools in captivity and demonstrate a basic understanding about the functional properties of the objects they are using 131 Social systems and communication edit The nocturnal strepsirrhines have been traditionally described as solitary although this term is no longer favored by the researchers who study them 132 Many are considered solitary foragers but many exhibit complex and diverse social organization often overlapping home ranges initiating social contact at night and sharing sleeping sites during the day Even the mating systems are variable as seen in woolly lemurs which live in monogamous breeding pairs 133 Because of this social diversity among these solitary but social primates whose level of social interaction is comparable to that of diurnal simians 132 alternative classifications have been proposed to emphasize their gregarious dispersed or solitary nature 134 Among extant strepsirrhines only the diurnal and cathemeral lemurs have evolved to live in multi male multi female groups comparable to most living simians 133 135 This social trait seen in two extant lemur families Indriidae and Lemuridae is thought to have evolved independently 136 Group sizes are smaller in social lemurs than in simians and despite the similarities the community structures differ 137 Female dominance which is rare in simians is fairly common in lemurs 138 Strepsirrhines spend a considerable amount of time grooming each other allogrooming 139 When lemuriform primates groom they lick the fur and then comb it with their toothcomb They also use their grooming claw to scratch places they cannot reach with their mouth 83 Like New World monkeys strepsirrhines rely on scent marking for much of their communication This involves smearing secretions from epidermal scent glands on tree branches along with urine and feces In some cases strepsirrhines may anoint themselves with urine urine washing Body postures and gestures may be used although the long snout non mobile lips and reduced facial enervation restrict the use of facial expressions in strepsirrhines Short range calls long range calls and alarm calls are also used 140 Nocturnal species are more constrained by the lack of light so their communication systems differ from those of diurnal species often using long range calls to claim their territory 141 Locomotion edit nbsp nbsp Dwarf lemurs top are arboreal quadrupeds while galagos bottom favor vertical clinging and leaping Living strepsirrhines are predominantly arboreal with only the ring tailed lemur spending considerable time on the ground 142 Most species move around quadrupedally on four legs in the trees including five genera of smaller nocturnal lemurs 127 142 Galagos indriids sportive lemurs and bamboo lemurs leap from vertical surfaces 142 and the indriids are highly specialized for vertical clinging and leaping 127 Lorises are slow moving deliberate climbers 142 Analyses of extinct adapiforms postcranial skeletons suggest a variety of locomotor behavior 142 The European adapids Adapis Palaeolemur and Leptadapis shared adaptations for slow climbing like the lorises although they may have been quadrupedal runners like small New World monkeys Both Notharctus and Smilodectes from North America and Europolemur from Europe exhibit limb proportions and joint surfaces comparable to vertical clinging and leaping lemurs but were not as specialized as indriids for vertical clinging suggesting that they ran along branches and did not leap as much 91 142 Notharctids Cantius and Pronycticebus appear to have been agile arboreal quadrupeds with adaptations comparable to the brown lemurs 142 Diet edit Primates primarily feed on fruits including seeds leaves including flowers and animal prey arthropods small vertebrates and eggs Diets vary markedly between strepsirrhine species Like other leaf eating folivorous primates some strepsirrhines can digest cellulose and hemicellulose 143 Some strepsirrhines such as the galagos slender lorises and angwantibos are primarily insectivorous Other species such as fork marked lemurs and needle clawed bushbabies specialize on tree gum while indriids sportive lemurs and bamboo lemurs are folivores Many strepsirrhines are frugivores fruit eaters and others like the ring tailed lemur and mouse lemurs are omnivores eating a mix of fruit leaves and animal matter 144 Among the adapiforms frugivory seems to have been the most common diet particularly for medium sized to large species such as Cantius Pelycodus and Cercamonius 144 Folivory was also common among the medium and large sized adapiforms including Smilodectes Notharctus Adapis and Leptadapis Sharp cusps on the teeth of some of the smaller adapiforms such as Anchomomys and Donrussellia indicate that they were either partly or primarily insectivorous 91 144 Distribution and habitat editThe now extinct adapiform primates were primarily found across North America Asia and Europe with a few species in Africa They flourished during the Eocene when those regions were more tropical in nature and they disappeared when the climate became cooler and drier 36 Today the lemuriforms are confined in the tropics 145 ranging between 28 S to 26 N latitude 16 Lorises are found both in equatorial Africa and Southeast Asia while the galagos are limited to the forests and woodlands of sub Saharan Africa 17 97 Lemurs are endemic to Madagascar although much of their diversity and habitat has been lost due to recent human activity 17 50 As with nearly all primates strepsirrhines typically reside in tropical rainforests These habitats allow strepsirrhines and other primates to evolve diverse communities of sympatric species In the eastern rainforests of Madagascar as many as 11 or 12 species share the same forests and prior to human arrival some forests had nearly double that diversity 145 Several species of lemur are found in drier seasonal forests including the spiny forest on the southern tip of the island although the lemur communities in these regions are not as rich 146 Conservation edit nbsp Strepsirrhines are threatened by deforestation in tropical regions See also Conservation of slow lorises and Lemur Conservation Like all other non human primates strepsirrhines face an elevated risk of extinction due to human activity particularly deforestation in tropical regions Much of their habitat has been converted for human use such as agriculture and pasture 27 The threats facing strepsirrhine primates fall into three main categories habitat destruction hunting for bushmeat or traditional medicine and live capture for export or local exotic pet trade Although hunting is often prohibited the laws protecting them are rarely enforced In Madagascar local taboos known as fady sometimes help protect lemur species although some are still hunted for traditional medicine 147 In 2012 the International Union for Conservation of Nature IUCN announced that lemurs were the most endangered mammals due largely to elevated illegal logging and hunting following a political crisis in 2009 148 In Southeast Asia slow lorises are threatened by the exotic pet trade and traditional medicine in addition to habitat destruction 149 150 Both lemurs and slow lorises are protected from commercial international trade under CITES Appendix I 151 Explanatory notes edit a b Although the monophyletic relationship between lemurs and lorisoids is widely accepted their clade name is not The term lemuriform is used here because it derives from one popular taxonomy that clumps the clade of toothcombed primates into one infraorder and the extinct non toothcombed adapiforms into another both within the suborder Strepsirrhini 2 3 However another popular alternative taxonomy places the lorisoids in their own infraorder Lorisiformes 4 A clade is a group made up of an ancestor and all its descendants Colugos are also called dermopterans and flying lemurs Adapiforms are sometimes called adapids or adapoids The omomyiformes or omomyids are suspected to have been closely related to the tarsiers Since they are thought to be close relatives of tarsiers omomyiforms are classified as haplorhines However the spacing of the roots of their upper incisors suggests that they may have had a rhinarium like the strepsirrhines 37 59 Frequent mentions of a strepsirrhine toothcomb or references to Strepsirrhini as being toothcombed primates can be found in the literature 7 50 However one group of strepsirrhines lacks the toothcomb the adapiforms The toothcomb is therefore the primary hallmark of the lemuriforms 37 although at least one family only retains it in modified form 61 References editCitations edit Strepsirrhini paleobiodb org Retrieved 2021 07 22 Szalay amp Delson 1980 p 149 a b Cartmill 2010 p 15 a b Hartwig 2011 pp 20 21 strepsis ῥis Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project Ankel Simons 2007 p 394 a b c d e f g Vaughan Ryan amp Czaplewski 2011 p 169 Osman Hill 1953 p 39 Geoffroy Saint Hilaire 1812 p 156 Greek rho r r is written with a spiritus asper when word initial i e ῥ rh and often gets doubled to ῤῥ rrh also spelled rr when such a word constitutes the second part of a compound word See Ancient Greek phonology Liquids Doubled consonants and Consonant spelling a b Groves 2008 p 166 Pocock 1918 p 51 Jenkins amp Napier 1987 p 1 a b c Rose 2006 p 166 Rose 2006 pp 157 amp 165 167 a b c d e Whitten amp Brockman 2001 p 322 a b c d e Hartwig 2011 p 29 a b Fichtel amp Kappeler 2009 p 397 a b Hartwig 2011 pp 28 29 Beard 2002 p 133 Simons 2003 pp 15 17 a b c Godinot 2006 p 446 a b Rose 2006 p 343 Rose 2006 pp 168 169 a b c Hartwig 2011 p 22 Hartwig 2011 p 24 a b Cartmill amp Smith 2011 p 84 Rose 2006 p 169 Rose 2006 p 165 Miller Gunnell amp Martin 2005 p 67 a b Rose 2006 pp 178 179 a b c d e f Rose 2006 p 179 Covert 2002 pp 15 16 a b c Gebo 2002 p 21 Covert 2002 p 14 a b c Gebo 2002 p 35 a b c d e f Rose 2006 p 182 Rose 2006 pp 185 186 Rose 2006 pp 182 185 Godinot 1998 p 239 Gunnell Rose amp Rasmussen 2008 p 257 a b Rose 2006 p 186 Steiper amp Seiffert 2012 p 6006 Rose 2006 p 182 amp 186 a b c Tabuce et al 2009 pp 4091 4092 Hartwig 2011 pp 24 25 a b c Vaughan Ryan amp Czaplewski 2011 pp 170 171 Rose 2006 p 187 a b c Rose 2006 p 185 a b c d e f g h i j k l m Cartmill amp Smith 2011 p 89 Groves 2008 pp 89 90 amp 96 Groves 2008 p 103 a b c d Schwartz 2003 pp 53 54 Groves 2008 pp 113 114 a b Hartwig 2011 pp 20 amp 22 Sussman 2003 p 45 Schwartz 2003 p 54 Ankel Simons 2007 p 96 Beard 1988 p 92 a b Hartwig 2011 p 28 Ankel Simons 2007 p 257 Schwartz 2003 p 71 Ankel Simons 2007 p 32 Cartmill 2010 pp 16 17 Rasmussen amp Nekaris 1998 p 252 Ankel Simons 2007 pp 31 32 Groves 1998 p 13 Rose 2006 p 167 a b Beard 2002 pp 146 147 Gingerich 1975 p 164 Yoder 2003 pp 161 162 a b c Williams et al 2010 p 567 Franzen et al 2009 p e5723 a b c Cartmill amp Smith 2011 p 90 Hartwig 2011 p 20 Groves 2005 p 121 Godfrey amp Jungers 2002 p 106 Godfrey amp Jungers 2002 p 97 Rose 2006 p 181 a b c Covert 2002 p 18 Dunkel Zijlstra amp Groves 2012 p 68 a b c Mittermeier Rylands amp Konstant 1999 p 4 a b c Osman Hill 1953 p 96 Gebo 2002 p 39 Cuozzo amp Yamashita 2006 p 73 a b c Rose 2006 pp 166 167 a b c d Tattersall 2006 p 7 Ollivier et al 2004 Ankel Simons 2007 p 458 Mittermeier Rylands amp Konstant 1999 p 6 a b c d e Rose 2006 p 180 Rose 2006 p 184 Godfrey amp Jungers 2002 pp 106 amp 112 Ankel Simons 2007 p 429 a b Mittermeier Rylands amp Konstant 1999 pp 4 5 Ankel Simons 2007 p 431 a b c Cartmill amp Smith 2011 p 91 Dagosto 1988 pp 47 48 Dagosto 1988 p 49 Ankel Simons 2007 p 68 a b Whitten amp Brockman 2001 p 323 Rose 2006 pp 168 amp 180 Plavcan 2004 p 239 Ankel Simons 2007 p 400 a b Ankel Simons 2007 pp 392 394 a b c d e f Mittermeier Rylands amp Konstant 1999 pp 24 25 Ankel Simons 2007 p 396 Beard 1988 p 85 Ankel Simons 2007 pp 392 393 amp 400 401 a b Ankel Simons 2007 pp 392 393 Ankel Simons 2007 p 402 Ankel Simons 2007 p 410 Ankel Simons 2007 p 401 Ankel Simons 2007 pp 410 411 Mittermeier Rylands amp Konstant 1999 p 26 Rose 2006 pp 181 182 a b Whitten amp Brockman 2001 pp 325 326 Whitten amp Brockman 2001 pp 330 331 Cartmill amp Smith 2011 p 88 Osman Hill 1953 p 81 Osman Hill 1953 p 93 Osman Hill 1953 p 391 Osman Hill 1953 p 672 Ankel Simons 2007 p 523 Ankel Simons 2007 p 522 Ankel Simons 2007 p 521 a b c Mittermeier Rylands amp Konstant 1999 pp 4 6 Mittermeier Rylands amp Konstant 1999 p 5 Whitten amp Brockman 2001 pp 325 amp 335 Fichtel amp Kappeler 2009 pp 395 396 Fichtel amp Kappeler 2009 pp 401 402 a b Nekaris amp Bearder 2011 p 51 a b Mittermeier Rylands amp Konstant 1999 pp 26 27 Gould Sauther amp Cameron 2011 p 74 Fichtel amp Kappeler 2009 pp 395 amp 397 Fichtel amp Kappeler 2009 p 398 Mittermeier Rylands amp Konstant 1999 pp 15 16 Overdorff amp Tecot 2006 p 247 Cloninger amp Kedia 2011 p 86 Mittermeier Rylands amp Konstant 1999 pp 25 26 Mittermeier Rylands amp Konstant 1999 pp 5 amp 26 a b c d e f g Covert 2002 pp 16 17 Mittermeier Rylands amp Konstant 1999 pp 22 24 a b c Covert 2002 p 16 a b Mittermeier Rylands amp Konstant 1999 p 14 Mittermeier Rylands amp Konstant 1999 p 19 Mittermeier Rylands amp Konstant 1999 pp 32 34 Lemurs found to be most threatened mammals in the world CNN 13 July 2012 Archived from the original on 21 August 2012 Retrieved 28 September 2012 Fitch Snyder amp Livingstone 2008 Nekaris et al 2010 p 878 Appendices I II and III Convention on International Trade in Endangered Species of Wild Fauna and Flora 25 September 2012 Archived from the original on 9 October 2012 Retrieved 1 October 2012 Literature cited edit Ankel Simons F 2007 Primate Anatomy 3rd ed Academic Press ISBN 978 0 12 372576 9 Beard K C 1988 The phylogenetic significance of strepsirhinism in Paleogene primates International Journal of Primatology 9 2 83 96 doi 10 1007 BF02735730 S2CID 32127974 Campbell C J Fuentes A MacKinnon K C Bearder S K Stumpf R M eds 2011 Primates in Perspective 2nd ed Oxford University Press ISBN 978 0 19 539043 8 Gould L Sauther M Cameron A Chapter 5 Lemuriformes In Campbell et al 2011 pp 55 79 Hartwig W Chapter 3 Primate evolution In Campbell et al 2011 pp 19 31 Nekaris N A I Bearder S K Chapter 4 The lorisiform primates of Asia and mainland Africa Diversity shrouded in darkness In Campbell et al 2011 pp 34 54 Cartmill M 2010 Primate Classification and Diversity In Platt M Ghazanfar A eds Primate Neuroethology Oxford University Press pp 10 30 ISBN 978 0 19 532659 8 Cartmill M Smith F H 2011 The Human Lineage John Wiley amp Sons ISBN 978 1 118 21145 8 Cloninger C R Kedia S 2011 Chapter 5 The phylogenesis of human personality Identifying the precursors of cooperation altruism and well being In Sussman R W Cloninger C R eds Origins of Altruism and Cooperation Springer ISBN 978 1 4419 9519 3 Dagosto M 1988 Implications of postcranial evidence for the origin of euprimates Journal of Human Evolution 17 1 2 35 77 doi 10 1016 0047 2484 88 90048 6 Dunkel A R Zijlstra J S Groves C P 2012 Giant rabbits marmosets and British comedies Etymology of lemur names part 1 PDF Lemur News 16 64 70 ISSN 1608 1439 Archived from the original PDF on 2016 11 06 Retrieved 2012 09 28 Fitch Snyder H Livingstone K 2008 Lorises The surprise primate Zoonooz pp 10 14 ISSN 0044 5282 Fichtel C Kappeler P M 2009 Chapter 19 Human universals and primate symplesiomorphies Establishing the lemur baseline In Kappeler P M Silk J B eds Mind the Gap Tracing the origins of human universals Springer pp 395 426 ISBN 978 3 642 02724 6 Franzen J L Gingerich P D Habersetzer J Hurum J H von Koenigswald W Smith B H 2009 Complete primate skeleton from the Middle Eocene of Messel in Germany Morphology and paleobiology PLOS ONE 4 5 e5723 Bibcode 2009PLoSO 4 5723F doi 10 1371 journal pone 0005723 PMC 2683573 PMID 19492084 Geoffroy Saint Hilaire E 1812 Suite au tableau des quadrumanes Seconde famille Lemuriens Strepsirrhini Annales du Museum d Histoire Naturelle in French 19 156 170 Gingerich P D 1975 A new genus of Adapidae Mammalia Primates from the Late Eocene of Southern France and its significance for the origin of higher primates Contributions from the Museum of Paleontology 24 15 University of Michigan 163 170 hdl 2027 42 48482 Godinot M 1998 A summary of adapiform systematics and phylogeny Folia Primatologica 69 Suppl 1 218 249 doi 10 1159 000052715 S2CID 84469830 Godinot M 2006 Lemuriform origins as viewed from the fossil record Folia Primatologica 77 6 446 464 doi 10 1159 000095391 PMID 17053330 S2CID 24163044 Gould L Sauther M L eds 2006 Lemurs Ecology and adaptation Springer ISBN 978 0 387 34585 7 Cuozzo F P Yamashita N Chapter 4 Impact of ecology on the teeth of extant lemurs A review of dental adaptations function and life history In Gould amp Sauther 2006 pp 67 96 Tattersall I Chapter 1 Origin of the Malagasy Strepsirhine primates In Gould amp Sauther 2006 pp 3 18 Groves C P 1998 Systematics of tarsiers and lorises Primates 39 1 13 27 doi 10 1007 BF02557740 S2CID 10869981 Groves C P 2005 Strepsirrhini In Wilson D E Reeder D M eds Mammal Species of the World A Taxonomic and Geographic Reference 3rd ed Baltimore Johns Hopkins University Press p 111 ISBN 0 801 88221 4 OCLC 62265494 Groves C P 2008 Extended Family Long lost cousins A personal look at the history of primatology Conservation International ISBN 978 1 934151 25 9 Gunnell G F Rose K D Rasmussen D T 2008 Euprimates In Janis C M Gunnell G F Uhen M D eds Small Mammals Xenarthrans and Marine Mammals Evolution of Tertiary Mammals of North America Vol 2 Cambridge England New York Cambridge University Press pp 239 262 ISBN 978 0 521 78117 6 Hartwig W C ed 2002 The Primate Fossil Record Cambridge University Press ISBN 978 0 521 66315 1 Beard K C Chapter 9 Basal anthropoids In Hartwig 2002 pp 133 149 Covert H H Chapter 3 The earliest fossil primates and the evolution of prosimians Introduction In Hartwig 2002 pp 13 20 Gebo D L Chapter 4 Adapiformes Phylogeny and adaptation In Hartwig 2002 pp 21 44 Godfrey L R Jungers W L Chapter 7 Quaternary fossil lemurs In Hartwig 2002 pp 97 121 Jenkins P D Napier P H 1987 Suborder Strepsirrhini including the subfossil Madagascan lemurs and family Tarsiidae Catalogue of Primates in the British Museum Natural History and elsewhere in the British Isles Vol Part 4 British Museum Natural History ISBN 978 0 565 01008 9 Miller E R Gunnell G F Martin R D 2005 Deep time and the search for anthropoid origins PDF American Journal of Physical Anthropology 128 60 95 doi 10 1002 ajpa 20352 PMID 16369958 Mittermeier R A Rylands A B Konstant W R 1999 Primates of the world An introduction In Nowak R M ed Walker s Mammals of the World 6th ed Johns Hopkins University Press pp 1 52 ISBN 978 0 8018 6251 9 Nekaris K A I Shepherd C R Starr C R Nijman V 2010 Exploring cultural drivers for wildlife trade via an ethnoprimatological approach A case study of slender and slow lorises Loris and Nycticebus in South and Southeast Asia American Journal of Primatology 72 10 877 886 doi 10 1002 ajp 20842 PMID 20806336 S2CID 21711250 Ollivier F J Samuelson D A Brooks D E Lewis P A Kallberg M E Komaromy A M 2004 Comparative morphology of the tapetum lucidum among selected species Veterinary Ophthalmology 7 1 11 22 doi 10 1111 j 1463 5224 2004 00318 x PMID 14738502 S2CID 15419778 Osman Hill W C 1953 I Strepsirhini Primates Comparative Anatomy and Taxonomy Edinburgh Univ Pubs Science amp Maths Vol 3 Edinburgh University Press OCLC 500576914 Overdorff D J Tecot S R 2006 Chapter 11 Social pair bonding and resource defense in wild red bellied lemurs Eulemur rubriventer In Gould L Sauther M L eds Lemurs Ecology and adaptation Springer pp 235 254 doi 10 1007 978 0 387 34586 4 11 ISBN 978 0 387 34585 7 S2CID 85613386 Plavcan J M 2004 Chapter 13 Sexual selection measures of sexual selection and sexual dimorphism in primates In Kappeler P M van Schaik C P eds Sexual Selection in Primates New and comparative perspectives Cambridge University Press pp 230 252 ISBN 978 0 521 53738 4 Pocock R I 1918 On the external characters of the lemurs and of Tarsius Proceedings of the Zoological Society of London 1918 1 2 19 53 doi 10 1111 j 1096 3642 1918 tb02076 x Rasmussen D T Nekaris K A I 1998 Evolutionary history of lorisiform primates PDF Folia Primatologica 69 Suppl 1 7 250 285 doi 10 1159 000052716 PMID 9595692 S2CID 14113728 Rose K D 2006 The Beginning of the Age of Mammals Johns Hopkins University Press ISBN 978 0 8018 8472 6 Steiper M E Seiffert E R 2012 Evidence for a convergent slowdown in primate molecular rates and its implications for the timing of early primate evolution Proceedings of the National Academy of Sciences 109 16 6006 6011 Bibcode 2012PNAS 109 6006S doi 10 1073 pnas 1119506109 PMC 3341044 PMID 22474376 Sussman R W 2003 Primate Ecology and Social Structure Pearson Custom Publishing ISBN 978 0 536 74363 3 Szalay F S Delson E 1980 Evolutionary History of the Primates Academic Press ISBN 978 0 12 680150 7 OCLC 893740473 Tabuce R Marivaux L Lebrun R Adaci M Bensalah M Fabre P H et al 2009 Anthropoid versus strepsirhine status of the African Eocene primates Algeripithecus and Azibius Craniodental evidence Proceedings of the Royal Society B Biological Sciences 276 1676 4087 4094 doi 10 1098 rspb 2009 1339 PMC 2821352 PMID 19740889 African Origin Of Anthropoid Primates Called Into Question With New Fossil Discovery Science Daily Press release 17 September 2009 Vaughan T Ryan J Czaplewski N 2011 Chapter 12 Primates Mammalogy 5th ed Jones amp Bartlett Learning ISBN 978 0 7637 6299 5 Whitten P L Brockman D K 2001 Chapter 14 Strepsirrhine reproductive ecology In Ellison P T ed Reproductive Ecology and Human Evolution Transaction Publishers pp 321 350 ISBN 978 0 202 30658 2 Williams B A Kay R F Christopher Kirk E Ross C F 2010 Darwinius masillae is a strepsirrhine a reply to Franzen et al 2009 PDF Journal of Human Evolution 59 5 567 573 discussion 573 579 doi 10 1016 j jhevol 2010 01 003 PMID 20188396 Archived from the original PDF on 17 May 2013 Wright Patricia C Simons Elwyn L eds 2003 Tarsiers Past present and future Rutgers University Press ISBN 978 0 8135 3236 3 Schwartz J H Chapter 3 How close are the similarities between Tarsius and other primates In Wright amp Simons 2003 pp 50 96 Simons E L Chapter 1 The fossil record of tarsier evolution In Wright amp Simons 2003 pp 9 34 Yoder A D Chapter 7 The phylogenetic position of the genus Tarsius Whose side are you on In Wright amp Simons 2003 pp 161 175 External links edit nbsp Media related to Strepsirrhini at Wikimedia Commons nbsp Data related to Strepsirrhini at Wikispecies Retrieved from https en wikipedia org w index php title Strepsirrhini amp oldid 1217682702, wikipedia, wiki, book, books, library,

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