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Oreopithecus

November 26, 2023

Oreopithecus (from the Greek ὄρος, oros and πίθηκος, pithekos, meaning "hill-ape") is an extinct genus of hominoid primate from the Miocene epoch whose fossils have been found in today's Tuscany and Sardinia in Italy.[1] It existed nine to seven million years ago in the Tusco-Sardinian area when this region was an isolated island in a chain of islands stretching from central Europe to northern Africa in what was becoming the Mediterranean Sea.[a]

Oreopithecus
Temporal range: Miocene
Oreopithecus bambolii fossil
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Primates
Suborder: Haplorhini
Infraorder: Simiiformes
Superfamily: Hominoidea
Genus: Oreopithecus
Gervais, 1872
Type species
Oreopithecus bambolii
Gervais, 1872

Oreopithecus was one of many European immigrants that settled this area in the VallesianTurolian transition and one of few hominoids, together with Sivapithecus in Asia, to survive the so-called Vallesian Crisis.[2] To date, dozens of individuals have been discovered at the Tuscan localities of Montebamboli, Montemassi, Casteani, Ribolla, and, most notably, in the fossil-rich lignite mine in the Baccinello Basin,[2] making it one of the best-represented fossil apes.

Evolutionary history edit

Oreopithecus bambolii was first described by French paleontologist Paul Gervais in 1872,[3][4] after the discovery of a juvenile mandible by Professor Igino Cocchi in a lignite mine at Montebamboli in 1862. In 1890, nearly a dozen new specimens were reported by Guiseppe Ristori, among them an upper jaw.[5] In 1898, a left lower jaw was described by Felice Ottolenghi.[6] In 1907, Giuseppe Merciai reported four maxillae and a lower jaw from the Grosseto mine at Ribolla.[7] During this period there was no consensus whether Oreopithecus was a monkey or an ape.[8]

From 1949 onwards, Swiss paleontologist Johannes Hürzeler began to restudy the known material.[9][10] In 1954, 1955, 1956 and 1958 he claimed Oreopithecus were a true hominin—based on its premolars, short jaws and reduced canines, at the time considered diagnostic of the hominin family.[11][12][13] This hypothesis was immediately hotly discussed by his fellow palaeontologists.[14][15][16][17][18] When he toured the world to give a series of lectures, his views generated an enormous press coverage, often being presented as a challenge to the Darwinian descent of man from apes.[19] After Hürzeler was invited to give a lecture in New York in March 1956, the Wenner-Gren Foundation decided to finance excavations in Italy, with the cooperation of the Italian paleontologist Alberto Carlo Blanc. On 2 August 1958, Hürzeler's views seemed to be confirmed when he discovered a complete skeleton in Baccinello,[20] which in 1960 he interpreted as a biped because of the short pelvis was closer to those of hominins than those of chimpanzees and gorillas.[21] Hominin affinities claimed for Oreopithecus remained controversial for decades until new analyses in the 1990s reasserted that Oreopithecus was directly related to Dryopithecus. The peculiar cranial and dental features were explained as consequences of insular isolation.

This new evidence confirmed that Oreopithecus was bipedal but also revealed that its peculiar form of bipedalism was much different from that of Australopithecus. The hallux formed a 100° angle with the other toes, which enabled the foot to act as a tripod in erect posture, but prevented Oreopithecus from developing a fast bipedal stride. When a land bridge broke the isolation of the Tusco-Sardinian area 6.5 million years ago, large predators such as Machairodus and Metailurus were present among the new generation of European immigrants and Oreopithecus faced quick extinction together with other endemic genera.[2][b]

Taxonomic classification edit

Known as the "enigmatic hominoid", Oreopithecus can dramatically rewrite the palaeontological map depending on whether it is a descendant of the European ape Dryopithecus or an African anthropoid.[2] Some have suggested the unique locomotory behavior of Oreopithecus requires a revision of the current consensus on the timing of bipedality in human developmental history, but there is limited agreement on this point among paleontologists.

Simons (1960) considered Oreopithecus closely related to the early Oligocene Apidium, a small arboreal anthropoid that lived nearly 34 million years ago in Egypt.[22] Oreopithecus shows strong links to modern apes in its postcranium and, in this respect, it is the most modern Miocene ape below the neck, with closest similarities to the postcranial elements of Dryopithecus, but its dentition is adapted to a leafy diet and a close link is uncertain. Others claim it to be either the sister taxon to Cercopithecoidea or an even direct human ancestor, but it is usually placed in its own subfamily within Hominidae. It could instead be added to the same subfamily as Dryopithecus, perhaps as a distinct tribe (Oreopithecini).[23] A cladistic analysis of Nyanzapithecus alesi recovers Oreopithecus as a member of the proconsulid subfamily Nyanzapithecinae.[24] A 2023 phylogenetic analysis suggested found a close relationship with gibbons, though the author suggested that this was likely due to having a similar climbing lifestyle and retained plesiomorphies, rather than a real close relationsip, but suggested that it was unlikely that Oreopithecus was a member of Hominidae.[25]

Physical characteristics edit

Oreopithecus bambolii is estimated to have weighed 30–35 kg (66–77 lb). It possessed a relatively short snout, elevated nasal bones, small and globular neurocranium, vertical orbital plane, and gracile facial bones. The shearing crests on its molars suggest a diet specializing in plant leaves. The very robust lower face, with a large attachment surface for the masseter muscle and a sagittal crest for attachment of the temporal muscle, indicates a heavy masticatory apparatus.

Its teeth were small relative to body size. The lack of a diastema (gap) between the second incisor and first premolar of the mandible indicates that Oreopithecus had canines of size comparable to the rest of its dentition. In many primates, small canines correlate with reduced inter-male competition for access to mates and less sexual dimorphism.

Positional behavior edit

Its habitat appears to have been swampy, and not savanna or forest. The postcranial anatomy of Oreopithecus features adaptations for suspensory arborealism. Functional traits related to suspensory locomotion include its broad thorax, short trunk, high intermembral index, long and slender digits, and extensive mobility in virtually all joints. Its fingers and arms seem to show adaptations for climbing and swinging.

Its foot has been described as chimp-like, but is different from those of extant primates. The habitual line of leverage of the primate foot is parallel to the third metatarsal bone. In Oreopithecus, the lateral metatarsals are permanently abducted so that this line falls between the first and second metatarsals instead. Furthermore, the shape of the tarsus indicate loads on the foot were transmitted to the medial side of the foot instead of the lateral, like in other primates.[26] The metatarsals are short and straight, but have a lateral orientation increase. Its foot proportions are close to the unusual proportions of Gorilla and Homo but are distinct from those found in specialized climbers. The lack of predators and the limitation of space and resources in Oreopithecus' insular environment favored a locomotor system optimized for low energy expenditure rather than speed and mobility.[26]

Oreopithecus has been claimed to exhibit features that are adaptations to upright walking, such as the presence of a lumbar curve, in distinction to otherwise similar species known from the same period. Since the fossils have been dated to about 8 million years ago, this would represent an unusually early appearance of upright posture.[26] However, a reevaluation of the spine from a skeleton of Oreopithecus has led to the conclusion that it lacked adaptations for habitual bipedality.[27][28]

Semicircular canals edit

The semicircular canals of the inner ear serves as a sense organ for balance and controls the reflex for gaze stabilization. The inner ear has three canals on each side of the head, and each of the six canals encloses a membranous duct that forms an endolymph-filled circuit. Hair cells in the duct's auditory ampulla pick up endolymph disturbances caused by movement, which register as rotatory head movement. They respond to body sway of frequencies greater than 0.1 Hz and trigger the vestibulocollic (neck) reflex and vestibuloocular (eye) reflex to recover balance and gaze stability. The bony semicircular canals allow estimates of duct arc length and orientation with respect to the sagittal plane.

Across species, the semicircular canals of agile animals have larger arcs than those of slower ones. For example, the rapid leaper Tarsius bancanus has semicircular canals much bigger than the slow-climbing Nycticebus coucang. The semicircular canals of brachiating gibbons are bigger than those of arboreal and terrestrial quadrupedal great apes. As a rule of thumb, arc size of the ducts decreases with body mass and consequently slower angular head motions. Arc size increases with greater agility and thus more rapid head motions. Modern humans have bigger arcs on their anterior and posterior canals, which reflect greater angular motion along the sagittal plane. The lateral canal has a smaller arc size, corresponding to reduced head movement from side to side. [29]

Allometric measurements on the bony labyrinth of BAC-208, a fragmentary cranium that preserves a complete, undeformed petrosal bone suggest that Oreopithecus moved with agility comparable to extant great apes. Its anterior and lateral semicircular canal sizes fall within the range for great apes. [30] Its relatively large posterior arc implies that Oreopithecus was more proficient at stabilizing angular head motion along the sagittal plane.

Dexterity edit

Oreopithecus had hominin-like hand proportions that allowed a firm, pad-to-pad precision grip. Features present in the hands of neither non-human-extant nor fossil apes include hand length, relative thumb length, a deep and large insertion for the flexor pollicis longus, and the shape of the carpometacarpal joint between the metacarpal bone of the index finger and the capitate bone. [31] At the base of the second metacarpal bone, the facet for the capitate is oriented transversally, as in hominins. The capitate, on the other hand, lacks the waisting associated with apes and climbing, and still present in Australopithecus. Oreopithecus share the specialised orientation at the carpometacarpal joint with A. afarenis and the marked groove for the flexor pollicis longus with A. africanus. It is thus likely that the hand morphology of Oreopithecus is derived for apes and convergent for early hominins. [31]

See also edit

Explanations edit

  1. ^ In what remained of the Tethys Sea, or what was becoming the Mediterranean Sea; see Geology and paleoclimatology of the Mediterranean Basin; see also Messinian salinity crisis.
  2. ^ A parallel to the Great American Interchange two million years later.

Notes edit

  1. ^ Osbourne, Hannah (23 December 2019). "Strange swamp-dwelling prehistroic ape that counldn't walk on two legs or climb trees poses evolutionary puzzle". Newsweek. Retrieved 23 December 2019.
  2. ^ a b c d Agustí & Antón 2002, pp. Prefix ix, 174–175, 193, 197–199
  3. ^ Paul Gervais, 1872, "Sur un singe fossile, d'espèce non encore décrite, qui a été decouvert au Monte-Bamboli (Italie)", Comptes rendus de l’Académie des sciences. 74: 1217–1223
  4. ^ Gervais, P. 1872. "Coup d'oeil sur les mammifères d'Ialie, suivie de la description d'une espèce nouvelle de singe provenant des lignites du Monte Bamboli". Journal de Zoologie 1: 219-235
  5. ^ Ristori, G. 1890. "Le Scimmie fossile italiane". Bollettino del Reale Comitato geologico d'Italia. 21: 178-196, 225-234
  6. ^ Ottolenghi F. 1898. "Nota sopra una scimmia fossile italiana". Atti della Società Ligustica di Scienze Naturali e Geografiche, 9: 399-403
  7. ^ Merciai G. 1907. "Sopra alcuni resti di vertebrati miocenici delle ligniti di Ribolla". Atti della Società Toscana di Scienze Naturali, Memorie, Serie A, 23: 79-86
  8. ^ Delson, E. 1986. "An anthropoid enigma: historical introduction to the study of Oreopithecus bambolii". Journal of Human Evolution 15: 523–531
  9. ^ Hürzeler J. 1949. "Neubeschreibung von Oreopithecus bambolii Gervais". Schweizerische Paläontologische Abhandlungen, 66: 1-20
  10. ^ Hürzeler, J. 1952. "Contribution à l'étude de la dentition de lait d' Oreopithecus bambolii Gervais". Eclogae Geologicae Helvetiae 44: 404-411
  11. ^ Hürzeler J. 1954. "Zur systematischen Stellung von Oreopithecus". Verhandlungen der Naturforschenden Gesellschaft (Basel) 65: 88–95
  12. ^ Hürzeler, J. 1956. "Oreopithecus, un point de repère pour l'histoire de l'humanité a l'ère Tertiare". Problèmes Actuels de Paléontologie, pp. 115-121. Paris: CNRS
  13. ^ Johannes Hürzeler, 1958, "Oreopithecus bambolii Gervais: a preliminary report", Verhandlungen der Naturforschenden Gesellschaft Basel. 69: 1–47
  14. ^ Koenigswald, G.H.R. von, I955, "Remarks on Oreopithecus". Rivista di Scienze Preistoriche. 10: 1-11
  15. ^ Viret, J. 1955. "A propos de l'Oreopithèque". Mammalia 19: 320-324
  16. ^ Remane, A. 1955. "Ist Oreopithecus ein Hominide?" Abhandlungen der Mathematisch-naturwissenschaftlichen Klasse, Akademie der Wissenschaften und der Literatur zu Mainz 12: 467-497
  17. ^ Loren C. Eiseley, 1956, "Oreopithecus: Humunculus or Monkey?", Scientific American 194(6): 91-104
  18. ^ Straus W.L. Jr. 1957. "Oreopithecus bambolii". Science 126: 345-346
  19. ^ Clara Florensa, 2016, "‘Darwin was Wrong.’ The International Media Coverage of the Oreopithecus’ Reinterpretation (1956–1959)", Centaurus 58(3): 219-238
  20. ^ Straus W.L. Jr. 1958. "A new Oreopithecus skeleton". Science 128: 523
  21. ^ Hürzeler, J. 1960. "The significance of Oreopithecus in the genealogy of man". Triangle 4: 164-175
  22. ^ Simons 1960
  23. ^ Delson, Tattersall & Van Couvering 2000, p. 465
  24. ^ Nengo, Isaiah; Tafforeau, Paul; Gilbert, Christopher C.; Fleagle, John G.; Miller, Ellen R.; Feibel, Craig; et al. (2017). "New infant cranium from the African Miocene sheds light on ape evolution" (PDF). Nature. 548 (7666): 169–174. Bibcode:2017Natur.548..169N. doi:10.1038/nature23456. PMID 28796200. S2CID 4397839.
  25. ^ Pugh, Kelsey D. (April 2022). "Phylogenetic analysis of Middle-Late Miocene apes". Journal of Human Evolution. 165: 103140. doi:10.1016/j.jhevol.2021.103140.
  26. ^ a b c Köhler & Moyà-Solà 1997
  27. ^ Ghose, Tia (5 August 2013). "Strange ancient ape walked on all fours". LiveScience.Com. TechMedia Network. Retrieved 7 August 2013.
  28. ^ Russo, G.A.; Shapiro, L.J. (23 July 2013). "Reevaluation of the lumbosacral region of Oreopithecus bambolii". Journal of Human Evolution. 65 (3): 253–265. doi:10.1016/j.jhevol.2013.05.004. PMID 23891006.
  29. ^ Spoor 2003, pp. 96–97
  30. ^ Rook et al. 2004, p. 355
  31. ^ a b Moyà-Solà, Köhler & Rook 1999

References edit

  • Agustí, Jordi; Antón, Mauricio (2002). Mammoths, Sabertooths, and Hominids: 65 million years of mammalian evolution in Europe. New York: Columbia University Press. ISBN 978-0-231-11640-4.
  • Carnieri, E. & Mallegni, F. (2003). "A new specimen and dental microwear in Oreopithecus bambolii". Homo. 54 (1): 29–35. doi:10.1078/0018-442X-00056. PMID 12968421.
  • Delson, Eric; Tattersall, Ian; Van Couvering, John A. (2000). "Dryopithecinae". Encyclopedia of human evolution and prehistory. Taylor & Francis. pp. 464–466. ISBN 978-0-8153-1696-1.
  • Harrison, Terry (1990). "The implications of Oreopithecus for the origins of bipedalism". In Coppens, Y.; Senut, B. (eds.). Origine(s) de la Bipédie chez les Hominidés [Origin(s) of Bipedalism in Hominids] (PDF) (in French). Paris: Museum National d’Histoire Naturelle.
  • Köhler, Meike; Moyà-Solà, Salvador (October 14, 1997). "Ape-like or hominid-like? The positional behavior of Oreopithecus bambolii reconsidered". PNAS. 94 (21): 11747–11750. Bibcode:1997PNAS...9411747K. doi:10.1073/pnas.94.21.11747. PMC 23630. PMID 9326682.
  • Moyà-Solà, Salvador; Köhler, Meike; Rook, Lorenzo (5 January 1999). "Evidence of hominid-like precision grip capability in the hand of the Miocene ape Oreopithecus". PNAS. 96 (1): 313–317. Bibcode:1999PNAS...96..313M. doi:10.1073/pnas.96.1.313. PMC 15136. PMID 9874815.
  • Rook, Lorenzo; Bondioli, Luca; Casali, Franco; Rossi, Massimo; Köhler, Meike; Moyà-Solà, Salvador; Macchiarelli, Roberto (2004). (PDF). Journal of Human Evolution. 46 (3): 347–354. doi:10.1016/j.jhevol.2004.01.001. PMID 14984788. Archived from the original (PDF) on 15 March 2012.
  • Rook, Lorenzo; Bondioli, Luca; Köhler, Meike; Moyà-Solà, Salvador; Macchiarelli, Roberto (20 July 1999). "Oreopithecus was a bipedal ape after all: Evidence from the iliac cancellous architecture". PNAS. 96 (15): 8795–8799. Bibcode:1999PNAS...96.8795R. doi:10.1073/pnas.96.15.8795. PMC 17596. PMID 10411955.
  • Rook, L.; Harrison, T.; Engesser, B. (1996). "The taxonomic status and biochronological implications of new finds of Oreopithecus from Baccinello (Tuscany, Italy)" (PDF). Journal of Human Evolution. 30: 3–27. doi:10.1006/jhev.1996.0002.
  • Simons, Elwyn L. (4 June 1960). "Apidium and Oreopithecus". Nature. 186 (4727): 824–826. Bibcode:1960Natur.186..824S. doi:10.1038/186824a0. S2CID 4184784.
  • Spoor, Fred (2003). "The semicircular canal system and locomotor behavior, with special reference to hominin evolution" (PDF). In Franzen, Jens Lorenz; Köhler, Meike; Moyà-Solà, Salvador (eds.). Walking Upright: Results of the 13th International Senckenberg Conference at the Werner Reimers Foundation. E. Schweitzerbart'sche Verlagsbuchhandlung. ISBN 978-3-510-61357-1.

External links edit

  Media related to Oreopithecus at Wikimedia Commons

  • Fitzpatrick-Matthews, Keith. "A child's jaw in coal?". Bad Archaeology. Retrieved 16 December 2016. — A photo of an Oreopithecus bamboli jaw
  • . Mikko's Phylogeny Archive. Archived from the original on 11 January 2008. Retrieved 15 November 2010.

November 26, 2023
oreopithecus, from, greek, ὄρος, oros, πίθηκος, pithekos, meaning, hill, extinct, genus, hominoid, primate, from, miocene, epoch, whose, fossils, have, been, found, today, tuscany, sardinia, italy, existed, nine, seven, million, years, tusco, sardinian, area, . Oreopithecus from the Greek ὄros oros and pi8hkos pithekos meaning hill ape is an extinct genus of hominoid primate from the Miocene epoch whose fossils have been found in today s Tuscany and Sardinia in Italy 1 It existed nine to seven million years ago in the Tusco Sardinian area when this region was an isolated island in a chain of islands stretching from central Europe to northern Africa in what was becoming the Mediterranean Sea a OreopithecusTemporal range MioceneOreopithecus bambolii fossilScientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass MammaliaOrder PrimatesSuborder HaplorhiniInfraorder SimiiformesSuperfamily HominoideaGenus OreopithecusGervais 1872Type speciesOreopithecus bamboliiGervais 1872Oreopithecus was one of many European immigrants that settled this area in the Vallesian Turolian transition and one of few hominoids together with Sivapithecus in Asia to survive the so called Vallesian Crisis 2 To date dozens of individuals have been discovered at the Tuscan localities of Montebamboli Montemassi Casteani Ribolla and most notably in the fossil rich lignite mine in the Baccinello Basin 2 making it one of the best represented fossil apes Contents 1 Evolutionary history 1 1 Taxonomic classification 2 Physical characteristics 2 1 Positional behavior 2 1 1 Semicircular canals 2 2 Dexterity 3 See also 4 Explanations 5 Notes 6 References 7 External linksEvolutionary history editOreopithecus bambolii was first described by French paleontologist Paul Gervais in 1872 3 4 after the discovery of a juvenile mandible by Professor Igino Cocchi in a lignite mine at Montebamboli in 1862 In 1890 nearly a dozen new specimens were reported by Guiseppe Ristori among them an upper jaw 5 In 1898 a left lower jaw was described by Felice Ottolenghi 6 In 1907 Giuseppe Merciai reported four maxillae and a lower jaw from the Grosseto mine at Ribolla 7 During this period there was no consensus whether Oreopithecus was a monkey or an ape 8 From 1949 onwards Swiss paleontologist Johannes Hurzeler began to restudy the known material 9 10 In 1954 1955 1956 and 1958 he claimed Oreopithecus were a true hominin based on its premolars short jaws and reduced canines at the time considered diagnostic of the hominin family 11 12 13 This hypothesis was immediately hotly discussed by his fellow palaeontologists 14 15 16 17 18 When he toured the world to give a series of lectures his views generated an enormous press coverage often being presented as a challenge to the Darwinian descent of man from apes 19 After Hurzeler was invited to give a lecture in New York in March 1956 the Wenner Gren Foundation decided to finance excavations in Italy with the cooperation of the Italian paleontologist Alberto Carlo Blanc On 2 August 1958 Hurzeler s views seemed to be confirmed when he discovered a complete skeleton in Baccinello 20 which in 1960 he interpreted as a biped because of the short pelvis was closer to those of hominins than those of chimpanzees and gorillas 21 Hominin affinities claimed for Oreopithecus remained controversial for decades until new analyses in the 1990s reasserted that Oreopithecus was directly related to Dryopithecus The peculiar cranial and dental features were explained as consequences of insular isolation This new evidence confirmed that Oreopithecus was bipedal but also revealed that its peculiar form of bipedalism was much different from that of Australopithecus The hallux formed a 100 angle with the other toes which enabled the foot to act as a tripod in erect posture but prevented Oreopithecus from developing a fast bipedal stride When a land bridge broke the isolation of the Tusco Sardinian area 6 5 million years ago large predators such as Machairodus and Metailurus were present among the new generation of European immigrants and Oreopithecus faced quick extinction together with other endemic genera 2 b Taxonomic classification edit Known as the enigmatic hominoid Oreopithecus can dramatically rewrite the palaeontological map depending on whether it is a descendant of the European ape Dryopithecus or an African anthropoid 2 Some have suggested the unique locomotory behavior of Oreopithecus requires a revision of the current consensus on the timing of bipedality in human developmental history but there is limited agreement on this point among paleontologists Simons 1960 considered Oreopithecus closely related to the early Oligocene Apidium a small arboreal anthropoid that lived nearly 34 million years ago in Egypt 22 Oreopithecus shows strong links to modern apes in its postcranium and in this respect it is the most modern Miocene ape below the neck with closest similarities to the postcranial elements of Dryopithecus but its dentition is adapted to a leafy diet and a close link is uncertain Others claim it to be either the sister taxon to Cercopithecoidea or an even direct human ancestor but it is usually placed in its own subfamily within Hominidae It could instead be added to the same subfamily as Dryopithecus perhaps as a distinct tribe Oreopithecini 23 A cladistic analysis of Nyanzapithecus alesi recovers Oreopithecus as a member of the proconsulid subfamily Nyanzapithecinae 24 A 2023 phylogenetic analysis suggested found a close relationship with gibbons though the author suggested that this was likely due to having a similar climbing lifestyle and retained plesiomorphies rather than a real close relationsip but suggested that it was unlikely that Oreopithecus was a member of Hominidae 25 Physical characteristics editOreopithecus bambolii is estimated to have weighed 30 35 kg 66 77 lb It possessed a relatively short snout elevated nasal bones small and globular neurocranium vertical orbital plane and gracile facial bones The shearing crests on its molars suggest a diet specializing in plant leaves The very robust lower face with a large attachment surface for the masseter muscle and a sagittal crest for attachment of the temporal muscle indicates a heavy masticatory apparatus Its teeth were small relative to body size The lack of a diastema gap between the second incisor and first premolar of the mandible indicates that Oreopithecus had canines of size comparable to the rest of its dentition In many primates small canines correlate with reduced inter male competition for access to mates and less sexual dimorphism Positional behavior edit Its habitat appears to have been swampy and not savanna or forest The postcranial anatomy of Oreopithecus features adaptations for suspensory arborealism Functional traits related to suspensory locomotion include its broad thorax short trunk high intermembral index long and slender digits and extensive mobility in virtually all joints Its fingers and arms seem to show adaptations for climbing and swinging Its foot has been described as chimp like but is different from those of extant primates The habitual line of leverage of the primate foot is parallel to the third metatarsal bone In Oreopithecus the lateral metatarsals are permanently abducted so that this line falls between the first and second metatarsals instead Furthermore the shape of the tarsus indicate loads on the foot were transmitted to the medial side of the foot instead of the lateral like in other primates 26 The metatarsals are short and straight but have a lateral orientation increase Its foot proportions are close to the unusual proportions of Gorilla and Homo but are distinct from those found in specialized climbers The lack of predators and the limitation of space and resources in Oreopithecus insular environment favored a locomotor system optimized for low energy expenditure rather than speed and mobility 26 Oreopithecus has been claimed to exhibit features that are adaptations to upright walking such as the presence of a lumbar curve in distinction to otherwise similar species known from the same period Since the fossils have been dated to about 8 million years ago this would represent an unusually early appearance of upright posture 26 However a reevaluation of the spine from a skeleton of Oreopithecus has led to the conclusion that it lacked adaptations for habitual bipedality 27 28 Semicircular canals edit The semicircular canals of the inner ear serves as a sense organ for balance and controls the reflex for gaze stabilization The inner ear has three canals on each side of the head and each of the six canals encloses a membranous duct that forms an endolymph filled circuit Hair cells in the duct s auditory ampulla pick up endolymph disturbances caused by movement which register as rotatory head movement They respond to body sway of frequencies greater than 0 1 Hz and trigger the vestibulocollic neck reflex and vestibuloocular eye reflex to recover balance and gaze stability The bony semicircular canals allow estimates of duct arc length and orientation with respect to the sagittal plane Across species the semicircular canals of agile animals have larger arcs than those of slower ones For example the rapid leaper Tarsius bancanus has semicircular canals much bigger than the slow climbing Nycticebus coucang The semicircular canals of brachiating gibbons are bigger than those of arboreal and terrestrial quadrupedal great apes As a rule of thumb arc size of the ducts decreases with body mass and consequently slower angular head motions Arc size increases with greater agility and thus more rapid head motions Modern humans have bigger arcs on their anterior and posterior canals which reflect greater angular motion along the sagittal plane The lateral canal has a smaller arc size corresponding to reduced head movement from side to side 29 Allometric measurements on the bony labyrinth of BAC 208 a fragmentary cranium that preserves a complete undeformed petrosal bone suggest that Oreopithecus moved with agility comparable to extant great apes Its anterior and lateral semicircular canal sizes fall within the range for great apes 30 Its relatively large posterior arc implies that Oreopithecus was more proficient at stabilizing angular head motion along the sagittal plane Dexterity edit Oreopithecus had hominin like hand proportions that allowed a firm pad to pad precision grip Features present in the hands of neither non human extant nor fossil apes include hand length relative thumb length a deep and large insertion for the flexor pollicis longus and the shape of the carpometacarpal joint between the metacarpal bone of the index finger and the capitate bone 31 At the base of the second metacarpal bone the facet for the capitate is oriented transversally as in hominins The capitate on the other hand lacks the waisting associated with apes and climbing and still present in Australopithecus Oreopithecus share the specialised orientation at the carpometacarpal joint with A afarenis and the marked groove for the flexor pollicis longus with A africanus It is thus likely that the hand morphology of Oreopithecus is derived for apes and convergent for early hominins 31 See also edit nbsp Paleontology portalList of fossil sites List of human evolution fossils with images Explanations edit In what remained of the Tethys Sea or what was becoming the Mediterranean Sea see Geology and paleoclimatology of the Mediterranean Basin see also Messinian salinity crisis A parallel to the Great American Interchange two million years later Notes edit Osbourne Hannah 23 December 2019 Strange swamp dwelling prehistroic ape that counldn t walk on two legs or climb trees poses evolutionary puzzle Newsweek Retrieved 23 December 2019 a b c d Agusti amp Anton 2002 pp Prefix ix 174 175 193 197 199 Paul Gervais 1872 Sur un singe fossile d espece non encore decrite qui a ete decouvert au Monte Bamboli Italie Comptes rendus de l Academie des sciences 74 1217 1223 Gervais P 1872 Coup d oeil sur les mammiferes d Ialie suivie de la description d une espece nouvelle de singe provenant des lignites du Monte Bamboli Journal de Zoologie 1 219 235 Ristori G 1890 Le Scimmie fossile italiane Bollettino del Reale Comitato geologico d Italia 21 178 196 225 234 Ottolenghi F 1898 Nota sopra una scimmia fossile italiana Atti della Societa Ligustica di Scienze Naturali e Geografiche 9 399 403 Merciai G 1907 Sopra alcuni resti di vertebrati miocenici delle ligniti di Ribolla Atti della Societa Toscana di Scienze Naturali Memorie Serie A 23 79 86 Delson E 1986 An anthropoid enigma historical introduction to the study of Oreopithecus bambolii Journal of Human Evolution 15 523 531 Hurzeler J 1949 Neubeschreibung von Oreopithecus bambolii Gervais Schweizerische Palaontologische Abhandlungen 66 1 20 Hurzeler J 1952 Contribution a l etude de la dentition de lait d Oreopithecus bambolii Gervais Eclogae Geologicae Helvetiae 44 404 411 Hurzeler J 1954 Zur systematischen Stellung von Oreopithecus Verhandlungen der Naturforschenden Gesellschaft Basel 65 88 95 Hurzeler J 1956 Oreopithecus un point de repere pour l histoire de l humanite a l ere Tertiare Problemes Actuels de Paleontologie pp 115 121 Paris CNRS Johannes Hurzeler 1958 Oreopithecus bambolii Gervais a preliminary report Verhandlungen der Naturforschenden Gesellschaft Basel 69 1 47 Koenigswald G H R von I955 Remarks on Oreopithecus Rivista di Scienze Preistoriche 10 1 11 Viret J 1955 A propos de l Oreopitheque Mammalia 19 320 324 Remane A 1955 Ist Oreopithecus ein Hominide Abhandlungen der Mathematisch naturwissenschaftlichen Klasse Akademie der Wissenschaften und der Literatur zu Mainz 12 467 497 Loren C Eiseley 1956 Oreopithecus Humunculus or Monkey Scientific American 194 6 91 104 Straus W L Jr 1957 Oreopithecus bambolii Science 126 345 346 Clara Florensa 2016 Darwin was Wrong The International Media Coverage of the Oreopithecus Reinterpretation 1956 1959 Centaurus 58 3 219 238 Straus W L Jr 1958 A new Oreopithecus skeleton Science 128 523 Hurzeler J 1960 The significance of Oreopithecus in the genealogy of man Triangle 4 164 175 Simons 1960 Delson Tattersall amp Van Couvering 2000 p 465 Nengo Isaiah Tafforeau Paul Gilbert Christopher C Fleagle John G Miller Ellen R Feibel Craig et al 2017 New infant cranium from the African Miocene sheds light on ape evolution PDF Nature 548 7666 169 174 Bibcode 2017Natur 548 169N doi 10 1038 nature23456 PMID 28796200 S2CID 4397839 Pugh Kelsey D April 2022 Phylogenetic analysis of Middle Late Miocene apes Journal of Human Evolution 165 103140 doi 10 1016 j jhevol 2021 103140 a b c Kohler amp Moya Sola 1997 Ghose Tia 5 August 2013 Strange ancient ape walked on all fours LiveScience Com TechMedia Network Retrieved 7 August 2013 Russo G A Shapiro L J 23 July 2013 Reevaluation of the lumbosacral region of Oreopithecus bambolii Journal of Human Evolution 65 3 253 265 doi 10 1016 j jhevol 2013 05 004 PMID 23891006 Spoor 2003 pp 96 97 Rook et al 2004 p 355 a b Moya Sola Kohler amp Rook 1999References editAgusti Jordi Anton Mauricio 2002 Mammoths Sabertooths and Hominids 65 million years of mammalian evolution in Europe New York Columbia University Press ISBN 978 0 231 11640 4 Carnieri E amp Mallegni F 2003 A new specimen and dental microwear in Oreopithecus bambolii Homo 54 1 29 35 doi 10 1078 0018 442X 00056 PMID 12968421 Delson Eric Tattersall Ian Van Couvering John A 2000 Dryopithecinae Encyclopedia of human evolution and prehistory Taylor amp Francis pp 464 466 ISBN 978 0 8153 1696 1 Harrison Terry 1990 The implications of Oreopithecus for the origins of bipedalism In Coppens Y Senut B eds Origine s de la Bipedie chez les Hominides Origin s of Bipedalism in Hominids PDF in French Paris Museum National d Histoire Naturelle Kohler Meike Moya Sola Salvador October 14 1997 Ape like or hominid like The positional behavior of Oreopithecus bambolii reconsidered PNAS 94 21 11747 11750 Bibcode 1997PNAS 9411747K doi 10 1073 pnas 94 21 11747 PMC 23630 PMID 9326682 Moya Sola Salvador Kohler Meike Rook Lorenzo 5 January 1999 Evidence of hominid like precision grip capability in the hand of the Miocene ape Oreopithecus PNAS 96 1 313 317 Bibcode 1999PNAS 96 313M doi 10 1073 pnas 96 1 313 PMC 15136 PMID 9874815 Rook Lorenzo Bondioli Luca Casali Franco Rossi Massimo Kohler Meike Moya Sola Salvador Macchiarelli Roberto 2004 The bony labyrinth of Oreopithecus bambolii PDF Journal of Human Evolution 46 3 347 354 doi 10 1016 j jhevol 2004 01 001 PMID 14984788 Archived from the original PDF on 15 March 2012 Rook Lorenzo Bondioli Luca Kohler Meike Moya Sola Salvador Macchiarelli Roberto 20 July 1999 Oreopithecus was a bipedal ape after all Evidence from the iliac cancellous architecture PNAS 96 15 8795 8799 Bibcode 1999PNAS 96 8795R doi 10 1073 pnas 96 15 8795 PMC 17596 PMID 10411955 Rook L Harrison T Engesser B 1996 The taxonomic status and biochronological implications of new finds of Oreopithecus from Baccinello Tuscany Italy PDF Journal of Human Evolution 30 3 27 doi 10 1006 jhev 1996 0002 Simons Elwyn L 4 June 1960 Apidium and Oreopithecus Nature 186 4727 824 826 Bibcode 1960Natur 186 824S doi 10 1038 186824a0 S2CID 4184784 Spoor Fred 2003 The semicircular canal system and locomotor behavior with special reference to hominin evolution PDF In Franzen Jens Lorenz Kohler Meike Moya Sola Salvador eds Walking Upright Results of the 13th International Senckenberg Conference at the Werner Reimers Foundation E Schweitzerbart sche Verlagsbuchhandlung ISBN 978 3 510 61357 1 External links edit nbsp Media related to Oreopithecus at Wikimedia Commons Fitzpatrick Matthews Keith A child s jaw in coal Bad Archaeology Retrieved 16 December 2016 A photo of an Oreopithecus bamboli jaw Oreopithecidae Mikko s Phylogeny Archive Archived from the original on 11 January 2008 Retrieved 15 November 2010 Retrieved from https en wikipedia org w index php title Oreopithecus amp oldid 1184174900, wikipedia, wiki, book, books, library,

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