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Feather

February 15, 2024

For other uses, see Feather (disambiguation).

Feathers are epidermal growths that form a distinctive outer covering, or plumage, on both avian (bird) and some non-avian dinosaurs and other archosaurs. They are the most complex integumentary structures found in vertebrates[1][2] and a premier example of a complex evolutionary novelty.[3] They are among the characteristics that distinguish the extant birds from other living groups.[4]

Feather variations

Although feathers cover most of the bird's body, they arise only from certain well-defined tracts on the skin. They aid in flight, thermal insulation, and waterproofing. In addition, coloration helps in communication and protection.[5] The study of feathers is called plumology (or plumage science).[6][7]

People use feathers in many ways that are practical, cultural, and religious. Feathers are both soft and excellent at trapping heat; thus, they are sometimes used in high-class bedding, especially pillows, blankets, and mattresses. They are also used as filling for winter clothing and outdoor bedding, such as quilted coats and sleeping bags. Goose and eider down have great loft, the ability to expand from a compressed, stored state to trap large amounts of compartmentalized, insulating air.[8] Feathers of large birds (most often geese) have been and are used to make quill pens. Historically, the hunting of birds for decorative and ornamental feathers has endangered some species and helped to contribute to the extinction of others.[9] Today, feathers used in fashion and in military headdresses and clothes are obtained as a waste product of poultry farming, including chickens, geese, turkeys, pheasants, and ostriches. These feathers are dyed and manipulated to enhance their appearance, as poultry feathers are naturally often dull in appearance compared to the feathers of wild birds.

Etymology

Feather derives from the Old English "feþer", which is of Germanic origin; related to Dutch "veer" and German "Feder", from an Indo-European root shared by Sanskrit's "patra" meaning 'wing', Latin's "penna" meaning 'feather', and Greek's "pteron", "pterux" meaning 'wing'.

Because of feathers being an integral part of quills, which were early pens used for writing, the word pen itself is derived from the Latin penna, meaning feather.[10] The French word plume can mean feather, quill, or pen.

Structures and characteristics

 
Parts of a feather:
  1. Vane
  2. Shaft, rachis
  3. Barb
  4. Aftershaft, afterfeather
  5. Quill, calamus
 
Feather structure of a blue-and-yellow macaw
 
Anterior region of a contour feather from a rock pigeon, visualized using scanning electron microscopy. Interlocking barbules are clearly seen in the middle image.

Feathers are among the most complex integumentary appendages found in vertebrates and are formed in tiny follicles in the epidermis, or outer skin layer, that produce keratin proteins. The β-keratins in feathers, beaks and claws – and the claws, scales and shells of reptiles – are composed of protein strands hydrogen-bonded into β-pleated sheets, which are then further twisted and crosslinked by disulfide bridges into structures even tougher than the α-keratins of mammalian hair, horns and hooves.[11][12] The exact signals that induce the growth of feathers on the skin are not known, but it has been found that the transcription factor cDermo-1 induces the growth of feathers on skin and scales on the leg.[13]

 
Feather microstructure showing interlocking barbules

Classification

See also: Pennaceous feather and Down feather

There are two basic types of feather: vaned feathers which cover the exterior of the body, and down feathers which are underneath the vaned feathers. The pennaceous feathers are vaned feathers. Also called contour feathers, pennaceous feathers arise from tracts and cover the entire body. A third rarer type of feather, the filoplume, is hairlike and are closely associated with pennaceous feathers and are often entirely hidden by them, with one or two filoplumes attached and sprouting from near the same point of the skin as each pennaceous feather, at least on a bird's head, neck and trunk.[14][15] Filoplumes are entirely absent in ratites.[16] In some passerines, filoplumes arise exposed beyond the pennaceous feathers on the neck.[1] The remiges, or flight feathers of the wing, and rectrices, or flight feathers of the tail, are the most important feathers for flight. A typical vaned feather features a main shaft, called the rachis. Fused to the rachis are a series of branches, or barbs; the barbs themselves are also branched and form the barbules. These barbules have minute hooks called barbicels for cross-attachment. Down feathers are fluffy because they lack barbicels, so the barbules float free of each other, allowing the down to trap air and provide excellent thermal insulation. At the base of the feather, the rachis expands to form the hollow tubular calamus (or quill) which inserts into a follicle in the skin. The basal part of the calamus is without vanes. This part is embedded within the skin follicle and has an opening at the base (proximal umbilicus) and a small opening on the side (distal umbilicus).[17]

Hatchling birds of some species have a special kind of natal down feathers (neossoptiles) which are pushed out when the normal feathers (teleoptiles) emerge.[1]

Flight feathers are stiffened so as to work against the air in the downstroke but yield in other directions. It has been observed that the orientation pattern of β-keratin fibers in the feathers of flying birds differs from that in flightless birds: the fibers are better aligned along the shaft axis direction towards the tip,[18][19] and the lateral walls of rachis region show structure of crossed fibers.[20][21]

Functions

Feathers insulate birds from water and cold temperatures. They may also be plucked to line the nest and provide insulation to the eggs and young. The individual feathers in the wings and tail play important roles in controlling flight.[20] Some species have a crest of feathers on their heads. Although feathers are light, a bird's plumage weighs two or three times more than its skeleton, since many bones are hollow and contain air sacs. Color patterns serve as camouflage against predators for birds in their habitats, and serve as camouflage for predators looking for a meal. As with fish, the top and bottom colors may be different, in order to provide camouflage during flight. Striking differences in feather patterns and colors are part of the sexual dimorphism of many bird species and are particularly important in the selection of mating pairs. In some cases, there are differences in the UV reflectivity of feathers across sexes even though no differences in color are noted in the visible range.[22] The wing feathers of male club-winged manakins Machaeropterus deliciosus have special structures that are used to produce sounds by stridulation.[23]

 
A contour feather from a Guinea fowl

Some birds have a supply of powder down feathers that grow continuously, with small particles regularly breaking off from the ends of the barbules. These particles produce a powder that sifts through the feathers on the bird's body and acts as a waterproofing agent and a feather conditioner. Powder down has evolved independently in several taxa and can be found in down as well as in pennaceous feathers. They may be scattered in plumage as in the pigeons and parrots or in localized patches on the breast, belly, or flanks, as in herons and frogmouths. Herons use their bill to break the powder down feathers and to spread them, while cockatoos may use their head as a powder puff to apply the powder.[24] Waterproofing can be lost by exposure to emulsifying agents due to human pollution. Feathers can then become waterlogged, causing the bird to sink. It is also very difficult to clean and rescue birds whose feathers have been fouled by oil spills. The feathers of cormorants soak up water and help to reduce buoyancy, thereby allowing the birds to swim submerged.[25]

 
Rictal bristles of a white-cheeked barbet

Bristles are stiff, tapering feathers with a large rachis but few barbs. Rictal bristles are found around the eyes and bill. They may serve a similar purpose to eyelashes and vibrissae in mammals. Although there is as yet no clear evidence, it has been suggested that rictal bristles have sensory functions and may help insectivorous birds to capture prey.[26] In one study, willow flycatchers (Empidonax traillii) were found to catch insects equally well before and after removal of the rictal bristles.[27]

Grebes are peculiar in their habit of ingesting their own feathers and feeding them to their young. Observations on their diet of fish and the frequency of feather eating suggest that ingesting feathers, particularly down from their flanks, aids in forming easily ejectable pellets.[28]

Distribution

 
Feather tracts or pterylae and their naming

Contour feathers are not uniformly distributed on the skin of the bird except in some groups such as the penguins, ratites and screamers.[29] In most birds the feathers grow from specific tracts of skin called pterylae; between the pterylae there are regions which are free of feathers called apterylae (or apteria). Filoplumes and down may arise from the apterylae. The arrangement of these feather tracts, pterylosis or pterylography, varies across bird families and has been used in the past as a means for determining the evolutionary relationships of bird families.[30][31] Species that incubate their own eggs often lose their feathers on a region of their belly, forming a brooding patch.[32]

Coloration

 
Colors resulting from different feather pigments
Left: turacin (red) and turacoverdin (green, with some structural blue iridescence at lower end) on the wing of Tauraco bannermani
Right: carotenoids (red) and melanins (dark) on belly/wings of Ramphocelus bresilius

The colors of feathers are produced by pigments, by microscopic structures that can refract, reflect, or scatter selected wavelengths of light, or by a combination of both.

Most feather pigments are melanins (brown and beige pheomelanins, black and grey eumelanins) and carotenoids (red, yellow, orange); other pigments occur only in certain taxa – the yellow to red psittacofulvins[33] (found in some parrots) and the red turacin and green turacoverdin (porphyrin pigments found only in turacos).

Structural coloration[5][34][35] is involved in the production of blue colors, iridescence, most ultraviolet reflectance and in the enhancement of pigmentary colors. Structural iridescence has been reported[36] in fossil feathers dating back 40 million years. White feathers lack pigment and scatter light diffusely; albinism in birds is caused by defective pigment production, though structural coloration will not be affected (as can be seen, for example, in blue-and-white budgerigars).

 
A feather with no pigment

The blues and bright greens of many parrots are produced by constructive interference of light reflecting from different layers of structures in feathers. In the case of green plumage, in addition to yellow, the specific feather structure involved is called by some the Dyck texture.[37][38] Melanin is often involved in the absorption of light; in combination with a yellow pigment, it produces a dull olive-green.

 
Emperor Pedro II of Brazil wearing a wide collar of orange toucan feathers around his shoulders and elements of the Imperial Regalia. Detail from a painting by Pedro Américo

In some birds, feather colors may be created, or altered, by secretions from the uropygial gland, also called the preen gland. The yellow bill colors of many hornbills are produced by such secretions. It has been suggested that there are other color differences that may be visible only in the ultraviolet region,[24] but studies have failed to find evidence.[39] The oil secretion from the uropygial gland may also have an inhibitory effect on feather bacteria.[40]

The reds, orange and yellow colors of many feathers are caused by various carotenoids. Carotenoid-based pigments might be honest signals of fitness because they are derived from special diets and hence might be difficult to obtain,[41][42] and/or because carotenoids are required for immune function and hence sexual displays come at the expense of health.[43]

A bird's feathers undergo wear and tear and are replaced periodically during the bird's life through molting. New feathers, known when developing as blood, or pin feathers, depending on the stage of growth, are formed through the same follicles from which the old ones were fledged. The presence of melanin in feathers increases their resistance to abrasion.[44] One study notes that melanin based feathers were observed to degrade more quickly under bacterial action, even compared to unpigmented feathers from the same species, than those unpigmented or with carotenoid pigments.[45] However, another study the same year compared the action of bacteria on pigmentations of two song sparrow species and observed that the darker pigmented feathers were more resistant; the authors cited other research also published in 2004 that stated increased melanin provided greater resistance. They observed that the greater resistance of the darker birds confirmed Gloger's rule.[46]

Although sexual selection plays a major role in the development of feathers, in particular, the color of the feathers it is not the only conclusion available. New studies are suggesting that the unique feathers of birds are also a large influence on many important aspects of avian behavior, such as the height at which different species build their nests. Since females are the prime caregivers, evolution has helped select females to display duller colors down so that they may blend into the nesting environment. The position of the nest and whether it has a greater chance of being under predation has exerted constraints on female birds' plumage.[47] A species of bird that nests on the ground, rather than the canopy of the trees, will need to have much duller colors in order not to attract attention to the nest. The height study found that birds that nest in the canopies of trees often have many more predator attacks due to the brighter color of feathers that the female displays.[47] Another influence of evolution that could play a part in why feathers of birds are so colorful and display so many patterns could be due to that birds developed their bright colors from the vegetation and flowers that thrive around them. Birds develop their bright colors from living around certain colors. Most bird species often blend into their environment, due to some degree of camouflage, so if the species habitat is full of colors and patterns, the species would eventually evolve to blend in to avoid being eaten. Birds' feathers show a large range of colors, even exceeding the variety of many plants, leaf, and flower colors.[48]

Parasites

The feather surface is the home for some ectoparasites, notably feather lice (Phthiraptera) and feather mites. Feather lice typically live on a single host and can move only from parents to chicks, between mating birds, and, occasionally, by phoresy. This life history has resulted in most of the parasite species being specific to the host and coevolving with the host, making them of interest in phylogenetic studies.[49]

Feather holes are chewing traces of lice (most probably Brueelia spp. lice) on the wing and tail feathers. They were described on barn swallows, and because of easy countability, many evolutionary, ecological, and behavioral publications use them to quantify the intensity of infestation.

Parasitic cuckoos which grow up in the nests of other species also have host-specific feather lice and these seem to be transmitted only after the young cuckoos leave the host nest.[50]

Birds maintain their feather condition by preening and bathing in water or dust. It has been suggested that a peculiar behavior of birds, anting, in which ants are introduced into the plumage, helps to reduce parasites, but no supporting evidence has been found.[51]

Human usage

Utilitarian

 
Pomo fully feathered basket curated at the Jesse Peter Multicultural Museum, Santa Rosa College
 
Female model with feathers

Bird feathers have long been used for fletching arrows. Colorful feathers such as those belonging to pheasants have been used to decorate fishing lures.

Feathers are also valuable in aiding the identification of species in forensic studies, particularly in bird strikes to aircraft. The ratios of hydrogen isotopes in feathers help in determining the geographic origins of birds.[52] Feathers may also be useful in the non-destructive sampling of pollutants.[53]

The poultry industry produces a large amount of feathers as waste, which, like other forms of keratin, are slow to decompose. Feather waste has been used in a number of industrial applications as a medium for culturing microbes,[54] biodegradable polymers,[55] and production of enzymes.[56] Feather proteins have been tried as an adhesive for wood board.[57]

Some groups of Native people in Alaska have used ptarmigan feathers as temper (non-plastic additives) in pottery manufacture since the first millennium BC in order to promote thermal shock resistance and strength.[58]

In religion and culture

 
Mexican featherwork painting of Isidore the Laborer made from duck, hummingbird, and canary feathers. This style of painting, popular during the Novohispanic era, integrates featherwork of pre-Hispanic origin with Christian iconography. 18th century, Museo Soumaya

Eagle feathers have great cultural and spiritual value to American Indians in the US and First Nations peoples in Canada as religious objects. In the United States, the religious use of eagle and hawk feathers is governed by the eagle feather law, a federal law limiting the possession of eagle feathers to certified and enrolled members of federally recognized Native American tribes.

In South America, brews made from the feathers of condors are used in traditional medications.[59] In India, feathers of the Indian peacock have been used in traditional medicine for snakebite, infertility, and coughs.[60][61]

Members of Scotland's Clan Campbell are known to wear feathers on their bonnets to signify authority within the clan. Clan chiefs wear three, chieftains wear two and an armiger wears one. Any member of the clan who does not meet the criteria is not authorized to wear feathers as part of traditional garb and doing so is considered presumptuous.[62]

During the 18th, 19th, and early 20th centuries, there was a booming international trade in plumes for extravagant women's hats and other headgear (including in Victorian fashion). Frank Chapman noted in 1886 that feathers of as many as 40 species of birds were used in about three-fourths of the 700 ladies' hats that he observed in New York City.[63] For instance, South American hummingbird feathers were used in the past to dress some of the miniature birds featured in singing bird boxes. This trade caused severe losses to bird populations (for example, egrets and whooping cranes). Conservationists led a major campaign against the use of feathers in hats. This contributed to passage of the Lacey Act in 1900, and to changes in fashion. The ornamental feather market then largely collapsed.[64][65]

More recently, rooster plumage has become a popular trend as a hairstyle accessory, with feathers formerly used as fishing lures now being used to provide color and style to hair.[66]

Feather products manufacturing in Europe has declined in the last 60 years, mainly due to competition from Asia. Feathers have adorned hats at many prestigious events such as weddings and Ladies Day at racecourses (Royal Ascot).

Evolution

Main article: Origin of avian flight
 
Late Jurassic fossil feather of an unidentified dinosaur, once thought to be Archaeopteryx.
 
Rachis-dominated feathers inside mid-Cretaceous Burmese amber

Functional considerations

The functional view on the evolution of feathers has traditionally focused on insulation, flight and display. Discoveries of non-flying Late Cretaceous feathered dinosaurs in China,[67] however, suggest that flight could not have been the original primary function as the feathers simply would not have been capable of providing any form of lift.[68][69] There have been suggestions that feathers may have had their original function in thermoregulation, waterproofing, or even as sinks for metabolic wastes such as sulphur.[70] Recent discoveries are argued to support a thermoregulatory function, at least in smaller dinosaurs.[71][72] Some researchers even argue that thermoregulation arose from bristles on the face that were used as tactile sensors.[73] While feathers have been suggested as having evolved from reptilian scales, there are numerous objections to that idea, and more recent explanations have arisen from the paradigm of evolutionary developmental biology.[2] Theories of the scale-based origins of feathers suggest that the planar scale structure was modified for development into feathers by splitting to form the webbing; however, that developmental process involves a tubular structure arising from a follicle and the tube splitting longitudinally to form the webbing.[1][2] The number of feathers per unit area of skin is higher in smaller birds than in larger birds, and this trend points to their important role in thermal insulation, since smaller birds lose more heat due to the relatively larger surface area in proportion to their body weight.[5] The miniaturization of birds also played a role in the evolution of powered flight.[74] The coloration of feathers is believed to have evolved primarily in response to sexual selection. In fossil specimens of the paravian Anchiornis huxleyi and the pterosaur Tupandactylus imperator, the features are so well preserved that the melanosome (pigment cells) structure can be observed. By comparing the shape of the fossil melanosomes to melanosomes from extant birds, the color and pattern of the feathers on Anchiornis and Tupandactylus could be determined.[75][76] Anchiornis was found to have black-and-white-patterned feathers on the forelimbs and hindlimbs, with a reddish-brown crest. This pattern is similar to the coloration of many extant bird species, which use plumage coloration for display and communication, including sexual selection and camouflage. It is likely that non-avian dinosaur species utilized plumage patterns for similar functions as modern birds before the origin of flight. In many cases, the physiological condition of the birds (especially males) is indicated by the quality of their feathers, and this is used (by the females) in mate choice.[77][78] Additionally, when comparing different Ornithomimus edmontonicus specimens, older individuals were found to have a pennibrachium (a wing-like structure consisting of elongate feathers), while younger ones did not. This suggests that the pennibrachium was a secondary sex characteristic and likely had a sexual function.[79]

Molecular evolution

Several genes have been found to determine feather development. They will be key to understand the evolution of feathers. For instance, some genes convert scales into feathers or feather-like structures when expressed or induced in bird feet, such as the scale-feather converters Sox2, Zic1, Grem1, Spry2, and Sox18.[80]

Feathers and scales are made up of two distinct forms of keratin, and it was long thought that each type of keratin was exclusive to each skin structure (feathers and scales). However, feather keratin is also present in the early stages of development of American alligator scales. This type of keratin, previously thought to be specific to feathers, is suppressed during embryological development of the alligator and so is not present in the scales of mature alligators. The presence of this homologous keratin in both birds and crocodilians indicates that it was inherited from a common ancestor.[81]

This may suggest that crocodilian scales, bird and dinosaur feathers, and pterosaur pycnofibres are all developmental expressions of the same primitive archosaur skin structures; suggesting that feathers and pycnofibers could be homologous.[82] Molecular dating methods in 2011 show that the subfamily of feather β-keratins found in extant birds started to diverge 143 million years ago, suggesting the pennaceous feathers of Anchiornis were not made of the feather β-keratins present in extant birds.[83] However, a study of fossil feathers from the dinosaur Sinosauropteryx and other fossils revealed traces of beta-sheet proteins, using infrared spectroscopy and sulfur-X-ray spectroscopy. The presence of abundant alpha-proteins in some fossil feathers was shown to be an artefact of the fossilization process, as beta-protein structures are readily altered to alpha-helices during thermal degradation.[84] In 2019, scientists found that genes for the production of feathers evolved at the base of archosauria, supporting that feathers were present at early ornithodirans and is consistent with the fossil record.[85]

Feathered dinosaurs

Main article: Feathered dinosaurs
 
Archaeopteryx lithographica (Berlin specimen)

Several non-avian dinosaurs had feathers on their limbs that would not have functioned for flight.[67][2] One theory suggests that feathers originally evolved on dinosaurs due to their insulation properties; then, small dinosaur species which grew longer feathers may have found them helpful in gliding, leading to the evolution of proto-birds like Archaeopteryx and Microraptor zhaoianus. Another theory posits that the original adaptive advantage of early feathers was their pigmentation or iridescence, contributing to sexual preference in mate selection.[86] Dinosaurs that had feathers or protofeathers include Pedopenna daohugouensis[87] and Dilong paradoxus, a tyrannosauroid which is 60 to 70 million years older than Tyrannosaurus rex.[88]

The majority of dinosaurs known to have had feathers or protofeathers are theropods, however featherlike "filamentous integumentary structures" are also known from the ornithischian dinosaurs Tianyulong and Psittacosaurus.[89] The exact nature of these structures is still under study. However, it is believed that the stage-1 feathers (see Evolutionary stages section below) such as those seen in these two ornithischians likely functioned in display.[90] In 2014, the ornithischian Kulindadromeus was reported as having structures resembling stage-3 feathers.[91] The likelihood of scales evolving on early dinosaur ancestors are high. However, this was by assuming that primitive pterosaurs were scaly.[92][93] A 2016 study analyzes the pulp morphology of the tail bristles of Psittacosaurus and finds they are similar to feathers but notes that they are also similar to the bristles on the head of the Congo peafowl, the beard of the turkey, and the spine on the head of the horned screamer.[94] A reestimation of maximum likelihoods by paleontologist Thomas Holtz finds that filaments were more likely to be the ancestral state of dinosaurs.[95]

In 2010, a carcharodontosaurid named Concavenator corcovatus was found to have remiges on the ulna suggesting it might have had quill-like structures on the ams.[96] However, Foth et al. 2014 disagress with the publication where they point out that the bumps on the ulna of Concavenator are on the anterolateral which is unlike remiges which are in a posterolateral on the ulna of some birds, they consider it more likely that these are attachments for interosseous ligaments.[97] This was refuted by Cuesta Fidalgo and her colleagues, they pointed out that these bumps on the ulna are posterolateral which is unlike that of interosseous ligaments.[98]

Since the 1990s, dozens of feathered dinosaurs have been discovered in the clade Maniraptora, which includes the clade Avialae and the recent common ancestors of birds, Oviraptorosauria and Deinonychosauria. In 1998, the discovery of a feathered oviraptorosaurian, Caudipteryx zoui, challenged the notion of feathers as a structure exclusive to Avialae.[99] Buried in the Yixian Formation in Liaoning, China, C. zoui lived during the Early Cretaceous Period. Present on the forelimbs and tails, their integumentary structure has been accepted[by whom?] as pennaceous vaned feathers based on the rachis and herringbone pattern of the barbs. In the clade Deinonychosauria, the continued divergence of feathers is also apparent in the families Troodontidae and Dromaeosauridae. Branched feathers with rachis, barbs, and barbules were discovered in many members including Sinornithosaurus millenii, a dromaeosaurid found in the Yixian formation (124.6 MYA).[100]

Previously, a temporal paradox existed in the evolution of feathers—theropods with highly derived bird-like characteristics occurred at a later time than Archaeopteryx—suggesting that the descendants of birds arose before the ancestor. However, the discovery of Anchiornis huxleyi in the Late Jurassic Tiaojishan Formation (160 MYA) in western Liaoning in 2009[101][102] resolved this paradox. By predating Archaeopteryx, Anchiornis proves the existence of a modernly feathered theropod ancestor, providing insight into the dinosaur-bird transition. The specimen shows distribution of large pennaceous feathers on the forelimbs and tail, implying that pennaceous feathers spread to the rest of the body at an earlier stage in theropod evolution.[103] The development of pennaceous feathers did not replace earlier filamentous feathers. Filamentous feathers are preserved alongside modern-looking flight feathers – including some with modifications found in the feathers of extant diving birds – in 80 million year old amber from Alberta.[104]

Two small wings trapped in amber dating to 100 mya show plumage existed in some bird predecessors. The wings most probably belonged to enantiornithes, a diverse group of avian dinosaurs.[105][106]

A large phylogenetic analysis of early dinosaurs by Matthew Baron, David B. Norman and Paul Barrett (2017) found that Theropoda is actually more closely related to Ornithischia, to which it formed the sister group within the clade Ornithoscelida. The study also suggested that if the feather-like structures of theropods and ornithischians are of common evolutionary origin then it would be possible that feathers were restricted to Ornithoscelida. If so, then the origin of feathers would have likely occurred as early as the Middle Triassic,[107] though this has been disagreed upon.[108][109] The lack of feathers present in large sauropods and ankylosaurs could be that feathers were suppressed by genomic regulators.[110]

Evolutionary stages

 
Diagram illustrating stages of evolution

Several studies of feather development in the embryos of modern birds, coupled with the distribution of feather types among various prehistoric bird precursors, have allowed scientists to attempt a reconstruction of the sequence in which feathers first evolved and developed into the types found on modern birds.

Feather evolution was broken down into the following stages by Xu and Guo in 2009:[90]

  1. Single filament
  2. Multiple filaments joined at their base
  3. Multiple filaments joined at their base to a central filament
  4. Multiple filaments along the length of a central filament
  5. Multiple filaments arising from the edge of a membranous structure
  6. Pennaceous feather with vane of barbs and barbules and central rachis
  7. Pennaceous feather with an asymmetrical rachis
  8. Undifferentiated vane with central rachis

However, Foth (2011) showed that some of these purported stages (stages 2 and 5 in particular) are likely simply artifacts of preservation caused by the way fossil feathers are crushed and the feather remains or imprints are preserved. Foth re-interpreted stage 2 feathers as crushed or misidentified feathers of at least stage 3, and stage 5 feathers as crushed stage 6 feathers.[111]

The following simplified diagram of dinosaur relationships follows these results, and shows the likely distribution of plumaceous (downy) and pennaceous (vaned) feathers among dinosaurs and prehistoric birds. The diagram follows one presented by Xu and Guo (2009)[90] modified with the findings of Foth (2011)[111] The numbers accompanying each name refer to the presence of specific feather stages. Note that 's' indicates the known presence of scales on the body.

In pterosaurs

Pterosaurs were long known to have filamentous fur-like structures covering their body known as pycnofibres, which were generally considered distinct from the "true feathers" of birds and their dinosaur kin. However, a 2018 study of two small, well-preserved pterosaur fossils from the Jurassic of Inner Mongolia, China indicated that pterosaurs were covered in an array of differently-structured pycnofibres (rather than just filamentous ones), with several of these structures displaying diagnostic features of feathers, such as non-veined grouped filaments and bilaterally branched filaments, both of which were originally thought to be exclusive to birds and other maniraptoran dinosaurs. Given these findings, it is possible that feathers have deep evolutionary origins in ancestral archosaurs, though there is also a possibility that these structures independently evolved to resemble bird feathers via convergent evolution.[112] Mike Benton, the study's senior author, lent credence to the former theory, stating "We couldn't find any anatomical evidence that the four pycnofiber types are in any way different from the feathers of birds and dinosaurs. Therefore, because they are the same, they must share an evolutionary origin, and that was about 250 million years ago, long before the origin of birds."[113][114][115][116] But the integumentary structures of the anurognathid specimens is still based gross morphology as Liliana D'Alba pointed out. The pycnofibres of the two anurognathid specimens might not be homologous with the filamentous appendages on dinosaurs.[117] Paul M. Barrett suspects that during the integumentary evolution of pterosaurs, pterosaurs primitively lost scales and pycnofibers started to appear.[93]

Cascocauda was almost entirely covered in an extensive coat of pycnofibres, which appear to have come in two types. The first are simple, curved filaments that range in length from 3.5–12.8 mm long. These filaments cover most of the animal, including the head, neck, body, limbs and tail. The second type consists of tufts of filaments joined near the base, similar to the branching down feathers of birds and other coelurosaurian dinosaurs, around 2.5–8.0 mm long and only cover the wing membranes. Studies of sampled pycnofibres revealed the presence of microbodies within the filaments, resembling the melanosome pigments identified in other fossil integuments, specifically phaeomelanosomes. Furthermore, infrared spectral analysis of these pycnofibres show similar absorption spectra to red human hair. These pycnofibres likely provided both insulation and may have helped streamline the body and wings during flight.[118] The identity of these branching structures as pycnofibres or feathers was challenged by Unwin & Martill (2020), who interpreted them as bunched-up and degraded aktinofibrils–stiffening fibres found in the wing membrane of pterosaurs–and attributed the melanosomes and keratin to skin rather than filaments.[119] These claims were refuted by Yang and colleagues, who argue that Unwin and Martill's interpretations are inconsistent with the specimen's preservation. Namely, they argue that the consistent structure, regular spacing, and extension of the filaments beyond the wing membrane support their identification as pycnofibres. Further, they argue that the restriction of melanosomes and keratin to the fibres, as occurs in fossil dinosaur feathers, supports the case they are filaments and is not consistent with contamination from preserved skin.[120] Protofeathers likely evolved in early archosaurs, not long after the P-T extinction event during the time metabolic rates of early archosaurs and synapsids were increasing, postures becoming erect, and sustained activity.[85]

See also

References

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Further reading

External links

 
Wikimedia Commons has media related to Feather.
 
Look up pluma or calamus in Wiktionary, the free dictionary.
  • McGraw, K. J. 2005. Polly want a pigment? Cracking the chemical code to red coloration in parrots. Australian Birdkeeper Magazine 18:608–611.
  • DeMeo, Antonia M. Access to Eagles and Eagle Parts: Environmental Protection v. Native American Free Exercise of Religion (1995)
  • U.S. v. Thirty Eight Golden Eagles (1986)
  • Documentary on the evolution of feathers
  • Federn.org

February 15, 2024
feather, other, uses, disambiguation, epidermal, growths, that, form, distinctive, outer, covering, plumage, both, avian, bird, some, avian, dinosaurs, other, archosaurs, they, most, complex, integumentary, structures, found, vertebrates, premier, example, com. For other uses see Feather disambiguation Feathers are epidermal growths that form a distinctive outer covering or plumage on both avian bird and some non avian dinosaurs and other archosaurs They are the most complex integumentary structures found in vertebrates 1 2 and a premier example of a complex evolutionary novelty 3 They are among the characteristics that distinguish the extant birds from other living groups 4 Feather variationsAlthough feathers cover most of the bird s body they arise only from certain well defined tracts on the skin They aid in flight thermal insulation and waterproofing In addition coloration helps in communication and protection 5 The study of feathers is called plumology or plumage science 6 7 People use feathers in many ways that are practical cultural and religious Feathers are both soft and excellent at trapping heat thus they are sometimes used in high class bedding especially pillows blankets and mattresses They are also used as filling for winter clothing and outdoor bedding such as quilted coats and sleeping bags Goose and eider down have great loft the ability to expand from a compressed stored state to trap large amounts of compartmentalized insulating air 8 Feathers of large birds most often geese have been and are used to make quill pens Historically the hunting of birds for decorative and ornamental feathers has endangered some species and helped to contribute to the extinction of others 9 Today feathers used in fashion and in military headdresses and clothes are obtained as a waste product of poultry farming including chickens geese turkeys pheasants and ostriches These feathers are dyed and manipulated to enhance their appearance as poultry feathers are naturally often dull in appearance compared to the feathers of wild birds Contents 1 Etymology 2 Structures and characteristics 2 1 Classification 2 2 Functions 2 3 Distribution 2 4 Coloration 3 Parasites 4 Human usage 4 1 Utilitarian 4 2 In religion and culture 5 Evolution 5 1 Functional considerations 5 2 Molecular evolution 5 3 Feathered dinosaurs 5 4 Evolutionary stages 5 5 In pterosaurs 6 See also 7 References 8 Further reading 9 External linksEtymologyFeather derives from the Old English fether which is of Germanic origin related to Dutch veer and German Feder from an Indo European root shared by Sanskrit s patra meaning wing Latin s penna meaning feather and Greek s pteron pterux meaning wing Because of feathers being an integral part of quills which were early pens used for writing the word pen itself is derived from the Latin penna meaning feather 10 The French word plume can mean feather quill or pen Structures and characteristics nbsp Parts of a feather VaneShaft rachisBarbAftershaft afterfeatherQuill calamus nbsp Feather structure of a blue and yellow macaw nbsp Anterior region of a contour feather from a rock pigeon visualized using scanning electron microscopy Interlocking barbules are clearly seen in the middle image Feathers are among the most complex integumentary appendages found in vertebrates and are formed in tiny follicles in the epidermis or outer skin layer that produce keratin proteins The b keratins in feathers beaks and claws and the claws scales and shells of reptiles are composed of protein strands hydrogen bonded into b pleated sheets which are then further twisted and crosslinked by disulfide bridges into structures even tougher than the a keratins of mammalian hair horns and hooves 11 12 The exact signals that induce the growth of feathers on the skin are not known but it has been found that the transcription factor cDermo 1 induces the growth of feathers on skin and scales on the leg 13 nbsp Feather microstructure showing interlocking barbulesClassification See also Pennaceous feather and Down feather There are two basic types of feather vaned feathers which cover the exterior of the body and down feathers which are underneath the vaned feathers The pennaceous feathers are vaned feathers Also called contour feathers pennaceous feathers arise from tracts and cover the entire body A third rarer type of feather the filoplume is hairlike and are closely associated with pennaceous feathers and are often entirely hidden by them with one or two filoplumes attached and sprouting from near the same point of the skin as each pennaceous feather at least on a bird s head neck and trunk 14 15 Filoplumes are entirely absent in ratites 16 In some passerines filoplumes arise exposed beyond the pennaceous feathers on the neck 1 The remiges or flight feathers of the wing and rectrices or flight feathers of the tail are the most important feathers for flight A typical vaned feather features a main shaft called the rachis Fused to the rachis are a series of branches or barbs the barbs themselves are also branched and form the barbules These barbules have minute hooks called barbicels for cross attachment Down feathers are fluffy because they lack barbicels so the barbules float free of each other allowing the down to trap air and provide excellent thermal insulation At the base of the feather the rachis expands to form the hollow tubular calamus or quill which inserts into a follicle in the skin The basal part of the calamus is without vanes This part is embedded within the skin follicle and has an opening at the base proximal umbilicus and a small opening on the side distal umbilicus 17 Hatchling birds of some species have a special kind of natal down feathers neossoptiles which are pushed out when the normal feathers teleoptiles emerge 1 Flight feathers are stiffened so as to work against the air in the downstroke but yield in other directions It has been observed that the orientation pattern of b keratin fibers in the feathers of flying birds differs from that in flightless birds the fibers are better aligned along the shaft axis direction towards the tip 18 19 and the lateral walls of rachis region show structure of crossed fibers 20 21 Functions Feathers insulate birds from water and cold temperatures They may also be plucked to line the nest and provide insulation to the eggs and young The individual feathers in the wings and tail play important roles in controlling flight 20 Some species have a crest of feathers on their heads Although feathers are light a bird s plumage weighs two or three times more than its skeleton since many bones are hollow and contain air sacs Color patterns serve as camouflage against predators for birds in their habitats and serve as camouflage for predators looking for a meal As with fish the top and bottom colors may be different in order to provide camouflage during flight Striking differences in feather patterns and colors are part of the sexual dimorphism of many bird species and are particularly important in the selection of mating pairs In some cases there are differences in the UV reflectivity of feathers across sexes even though no differences in color are noted in the visible range 22 The wing feathers of male club winged manakins Machaeropterus deliciosus have special structures that are used to produce sounds by stridulation 23 nbsp A contour feather from a Guinea fowlSome birds have a supply of powder down feathers that grow continuously with small particles regularly breaking off from the ends of the barbules These particles produce a powder that sifts through the feathers on the bird s body and acts as a waterproofing agent and a feather conditioner Powder down has evolved independently in several taxa and can be found in down as well as in pennaceous feathers They may be scattered in plumage as in the pigeons and parrots or in localized patches on the breast belly or flanks as in herons and frogmouths Herons use their bill to break the powder down feathers and to spread them while cockatoos may use their head as a powder puff to apply the powder 24 Waterproofing can be lost by exposure to emulsifying agents due to human pollution Feathers can then become waterlogged causing the bird to sink It is also very difficult to clean and rescue birds whose feathers have been fouled by oil spills The feathers of cormorants soak up water and help to reduce buoyancy thereby allowing the birds to swim submerged 25 nbsp Rictal bristles of a white cheeked barbetBristles are stiff tapering feathers with a large rachis but few barbs Rictal bristles are found around the eyes and bill They may serve a similar purpose to eyelashes and vibrissae in mammals Although there is as yet no clear evidence it has been suggested that rictal bristles have sensory functions and may help insectivorous birds to capture prey 26 In one study willow flycatchers Empidonax traillii were found to catch insects equally well before and after removal of the rictal bristles 27 Grebes are peculiar in their habit of ingesting their own feathers and feeding them to their young Observations on their diet of fish and the frequency of feather eating suggest that ingesting feathers particularly down from their flanks aids in forming easily ejectable pellets 28 Distribution nbsp Feather tracts or pterylae and their namingContour feathers are not uniformly distributed on the skin of the bird except in some groups such as the penguins ratites and screamers 29 In most birds the feathers grow from specific tracts of skin called pterylae between the pterylae there are regions which are free of feathers called apterylae or apteria Filoplumes and down may arise from the apterylae The arrangement of these feather tracts pterylosis or pterylography varies across bird families and has been used in the past as a means for determining the evolutionary relationships of bird families 30 31 Species that incubate their own eggs often lose their feathers on a region of their belly forming a brooding patch 32 Coloration nbsp Colors resulting from different feather pigmentsLeft turacin red and turacoverdin green with some structural blue iridescence at lower end on the wing of Tauraco bannermaniRight carotenoids red and melanins dark on belly wings of Ramphocelus bresiliusThe colors of feathers are produced by pigments by microscopic structures that can refract reflect or scatter selected wavelengths of light or by a combination of both Most feather pigments are melanins brown and beige pheomelanins black and grey eumelanins and carotenoids red yellow orange other pigments occur only in certain taxa the yellow to red psittacofulvins 33 found in some parrots and the red turacin and green turacoverdin porphyrin pigments found only in turacos Structural coloration 5 34 35 is involved in the production of blue colors iridescence most ultraviolet reflectance and in the enhancement of pigmentary colors Structural iridescence has been reported 36 in fossil feathers dating back 40 million years White feathers lack pigment and scatter light diffusely albinism in birds is caused by defective pigment production though structural coloration will not be affected as can be seen for example in blue and white budgerigars nbsp A feather with no pigmentThe blues and bright greens of many parrots are produced by constructive interference of light reflecting from different layers of structures in feathers In the case of green plumage in addition to yellow the specific feather structure involved is called by some the Dyck texture 37 38 Melanin is often involved in the absorption of light in combination with a yellow pigment it produces a dull olive green nbsp Emperor Pedro II of Brazil wearing a wide collar of orange toucan feathers around his shoulders and elements of the Imperial Regalia Detail from a painting by Pedro AmericoIn some birds feather colors may be created or altered by secretions from the uropygial gland also called the preen gland The yellow bill colors of many hornbills are produced by such secretions It has been suggested that there are other color differences that may be visible only in the ultraviolet region 24 but studies have failed to find evidence 39 The oil secretion from the uropygial gland may also have an inhibitory effect on feather bacteria 40 The reds orange and yellow colors of many feathers are caused by various carotenoids Carotenoid based pigments might be honest signals of fitness because they are derived from special diets and hence might be difficult to obtain 41 42 and or because carotenoids are required for immune function and hence sexual displays come at the expense of health 43 A bird s feathers undergo wear and tear and are replaced periodically during the bird s life through molting New feathers known when developing as blood or pin feathers depending on the stage of growth are formed through the same follicles from which the old ones were fledged The presence of melanin in feathers increases their resistance to abrasion 44 One study notes that melanin based feathers were observed to degrade more quickly under bacterial action even compared to unpigmented feathers from the same species than those unpigmented or with carotenoid pigments 45 However another study the same year compared the action of bacteria on pigmentations of two song sparrow species and observed that the darker pigmented feathers were more resistant the authors cited other research also published in 2004 that stated increased melanin provided greater resistance They observed that the greater resistance of the darker birds confirmed Gloger s rule 46 Although sexual selection plays a major role in the development of feathers in particular the color of the feathers it is not the only conclusion available New studies are suggesting that the unique feathers of birds are also a large influence on many important aspects of avian behavior such as the height at which different species build their nests Since females are the prime caregivers evolution has helped select females to display duller colors down so that they may blend into the nesting environment The position of the nest and whether it has a greater chance of being under predation has exerted constraints on female birds plumage 47 A species of bird that nests on the ground rather than the canopy of the trees will need to have much duller colors in order not to attract attention to the nest The height study found that birds that nest in the canopies of trees often have many more predator attacks due to the brighter color of feathers that the female displays 47 Another influence of evolution that could play a part in why feathers of birds are so colorful and display so many patterns could be due to that birds developed their bright colors from the vegetation and flowers that thrive around them Birds develop their bright colors from living around certain colors Most bird species often blend into their environment due to some degree of camouflage so if the species habitat is full of colors and patterns the species would eventually evolve to blend in to avoid being eaten Birds feathers show a large range of colors even exceeding the variety of many plants leaf and flower colors 48 ParasitesThe feather surface is the home for some ectoparasites notably feather lice Phthiraptera and feather mites Feather lice typically live on a single host and can move only from parents to chicks between mating birds and occasionally by phoresy This life history has resulted in most of the parasite species being specific to the host and coevolving with the host making them of interest in phylogenetic studies 49 Feather holes are chewing traces of lice most probably Brueelia spp lice on the wing and tail feathers They were described on barn swallows and because of easy countability many evolutionary ecological and behavioral publications use them to quantify the intensity of infestation Parasitic cuckoos which grow up in the nests of other species also have host specific feather lice and these seem to be transmitted only after the young cuckoos leave the host nest 50 Birds maintain their feather condition by preening and bathing in water or dust It has been suggested that a peculiar behavior of birds anting in which ants are introduced into the plumage helps to reduce parasites but no supporting evidence has been found 51 Human usageUtilitarian nbsp Pomo fully feathered basket curated at the Jesse Peter Multicultural Museum Santa Rosa College nbsp Female model with feathersBird feathers have long been used for fletching arrows Colorful feathers such as those belonging to pheasants have been used to decorate fishing lures Feathers are also valuable in aiding the identification of species in forensic studies particularly in bird strikes to aircraft The ratios of hydrogen isotopes in feathers help in determining the geographic origins of birds 52 Feathers may also be useful in the non destructive sampling of pollutants 53 The poultry industry produces a large amount of feathers as waste which like other forms of keratin are slow to decompose Feather waste has been used in a number of industrial applications as a medium for culturing microbes 54 biodegradable polymers 55 and production of enzymes 56 Feather proteins have been tried as an adhesive for wood board 57 Some groups of Native people in Alaska have used ptarmigan feathers as temper non plastic additives in pottery manufacture since the first millennium BC in order to promote thermal shock resistance and strength 58 In religion and culture nbsp Mexican featherwork painting of Isidore the Laborer made from duck hummingbird and canary feathers This style of painting popular during the Novohispanic era integrates featherwork of pre Hispanic origin with Christian iconography 18th century Museo SoumayaEagle feathers have great cultural and spiritual value to American Indians in the US and First Nations peoples in Canada as religious objects In the United States the religious use of eagle and hawk feathers is governed by the eagle feather law a federal law limiting the possession of eagle feathers to certified and enrolled members of federally recognized Native American tribes In South America brews made from the feathers of condors are used in traditional medications 59 In India feathers of the Indian peacock have been used in traditional medicine for snakebite infertility and coughs 60 61 Members of Scotland s Clan Campbell are known to wear feathers on their bonnets to signify authority within the clan Clan chiefs wear three chieftains wear two and an armiger wears one Any member of the clan who does not meet the criteria is not authorized to wear feathers as part of traditional garb and doing so is considered presumptuous 62 During the 18th 19th and early 20th centuries there was a booming international trade in plumes for extravagant women s hats and other headgear including in Victorian fashion Frank Chapman noted in 1886 that feathers of as many as 40 species of birds were used in about three fourths of the 700 ladies hats that he observed in New York City 63 For instance South American hummingbird feathers were used in the past to dress some of the miniature birds featured in singing bird boxes This trade caused severe losses to bird populations for example egrets and whooping cranes Conservationists led a major campaign against the use of feathers in hats This contributed to passage of the Lacey Act in 1900 and to changes in fashion The ornamental feather market then largely collapsed 64 65 More recently rooster plumage has become a popular trend as a hairstyle accessory with feathers formerly used as fishing lures now being used to provide color and style to hair 66 Feather products manufacturing in Europe has declined in the last 60 years mainly due to competition from Asia Feathers have adorned hats at many prestigious events such as weddings and Ladies Day at racecourses Royal Ascot EvolutionMain article Origin of avian flight nbsp Late Jurassic fossil feather of an unidentified dinosaur once thought to be Archaeopteryx nbsp Rachis dominated feathers inside mid Cretaceous Burmese amber Functional considerations The functional view on the evolution of feathers has traditionally focused on insulation flight and display Discoveries of non flying Late Cretaceous feathered dinosaurs in China 67 however suggest that flight could not have been the original primary function as the feathers simply would not have been capable of providing any form of lift 68 69 There have been suggestions that feathers may have had their original function in thermoregulation waterproofing or even as sinks for metabolic wastes such as sulphur 70 Recent discoveries are argued to support a thermoregulatory function at least in smaller dinosaurs 71 72 Some researchers even argue that thermoregulation arose from bristles on the face that were used as tactile sensors 73 While feathers have been suggested as having evolved from reptilian scales there are numerous objections to that idea and more recent explanations have arisen from the paradigm of evolutionary developmental biology 2 Theories of the scale based origins of feathers suggest that the planar scale structure was modified for development into feathers by splitting to form the webbing however that developmental process involves a tubular structure arising from a follicle and the tube splitting longitudinally to form the webbing 1 2 The number of feathers per unit area of skin is higher in smaller birds than in larger birds and this trend points to their important role in thermal insulation since smaller birds lose more heat due to the relatively larger surface area in proportion to their body weight 5 The miniaturization of birds also played a role in the evolution of powered flight 74 The coloration of feathers is believed to have evolved primarily in response to sexual selection In fossil specimens of the paravian Anchiornis huxleyi and the pterosaur Tupandactylus imperator the features are so well preserved that the melanosome pigment cells structure can be observed By comparing the shape of the fossil melanosomes to melanosomes from extant birds the color and pattern of the feathers on Anchiornis and Tupandactylus could be determined 75 76 Anchiornis was found to have black and white patterned feathers on the forelimbs and hindlimbs with a reddish brown crest This pattern is similar to the coloration of many extant bird species which use plumage coloration for display and communication including sexual selection and camouflage It is likely that non avian dinosaur species utilized plumage patterns for similar functions as modern birds before the origin of flight In many cases the physiological condition of the birds especially males is indicated by the quality of their feathers and this is used by the females in mate choice 77 78 Additionally when comparing different Ornithomimus edmontonicus specimens older individuals were found to have a pennibrachium a wing like structure consisting of elongate feathers while younger ones did not This suggests that the pennibrachium was a secondary sex characteristic and likely had a sexual function 79 Molecular evolution Several genes have been found to determine feather development They will be key to understand the evolution of feathers For instance some genes convert scales into feathers or feather like structures when expressed or induced in bird feet such as the scale feather converters Sox2 Zic1 Grem1 Spry2 and Sox18 80 Feathers and scales are made up of two distinct forms of keratin and it was long thought that each type of keratin was exclusive to each skin structure feathers and scales However feather keratin is also present in the early stages of development of American alligator scales This type of keratin previously thought to be specific to feathers is suppressed during embryological development of the alligator and so is not present in the scales of mature alligators The presence of this homologous keratin in both birds and crocodilians indicates that it was inherited from a common ancestor 81 This may suggest that crocodilian scales bird and dinosaur feathers and pterosaur pycnofibres are all developmental expressions of the same primitive archosaur skin structures suggesting that feathers and pycnofibers could be homologous 82 Molecular dating methods in 2011 show that the subfamily of feather b keratins found in extant birds started to diverge 143 million years ago suggesting the pennaceous feathers of Anchiornis were not made of the feather b keratins present in extant birds 83 However a study of fossil feathers from the dinosaur Sinosauropteryx and other fossils revealed traces of beta sheet proteins using infrared spectroscopy and sulfur X ray spectroscopy The presence of abundant alpha proteins in some fossil feathers was shown to be an artefact of the fossilization process as beta protein structures are readily altered to alpha helices during thermal degradation 84 In 2019 scientists found that genes for the production of feathers evolved at the base of archosauria supporting that feathers were present at early ornithodirans and is consistent with the fossil record 85 Feathered dinosaurs Main article Feathered dinosaurs nbsp Archaeopteryx lithographica Berlin specimen Several non avian dinosaurs had feathers on their limbs that would not have functioned for flight 67 2 One theory suggests that feathers originally evolved on dinosaurs due to their insulation properties then small dinosaur species which grew longer feathers may have found them helpful in gliding leading to the evolution of proto birds like Archaeopteryx and Microraptor zhaoianus Another theory posits that the original adaptive advantage of early feathers was their pigmentation or iridescence contributing to sexual preference in mate selection 86 Dinosaurs that had feathers or protofeathers include Pedopenna daohugouensis 87 and Dilong paradoxus a tyrannosauroid which is 60 to 70 million years older than Tyrannosaurus rex 88 The majority of dinosaurs known to have had feathers or protofeathers are theropods however featherlike filamentous integumentary structures are also known from the ornithischian dinosaurs Tianyulong and Psittacosaurus 89 The exact nature of these structures is still under study However it is believed that the stage 1 feathers see Evolutionary stages section below such as those seen in these two ornithischians likely functioned in display 90 In 2014 the ornithischian Kulindadromeus was reported as having structures resembling stage 3 feathers 91 The likelihood of scales evolving on early dinosaur ancestors are high However this was by assuming that primitive pterosaurs were scaly 92 93 A 2016 study analyzes the pulp morphology of the tail bristles of Psittacosaurus and finds they are similar to feathers but notes that they are also similar to the bristles on the head of the Congo peafowl the beard of the turkey and the spine on the head of the horned screamer 94 A reestimation of maximum likelihoods by paleontologist Thomas Holtz finds that filaments were more likely to be the ancestral state of dinosaurs 95 In 2010 a carcharodontosaurid named Concavenator corcovatus was found to have remiges on the ulna suggesting it might have had quill like structures on the ams 96 However Foth et al 2014 disagress with the publication where they point out that the bumps on the ulna of Concavenator are on the anterolateral which is unlike remiges which are in a posterolateral on the ulna of some birds they consider it more likely that these are attachments for interosseous ligaments 97 This was refuted by Cuesta Fidalgo and her colleagues they pointed out that these bumps on the ulna are posterolateral which is unlike that of interosseous ligaments 98 Since the 1990s dozens of feathered dinosaurs have been discovered in the clade Maniraptora which includes the clade Avialae and the recent common ancestors of birds Oviraptorosauria and Deinonychosauria In 1998 the discovery of a feathered oviraptorosaurian Caudipteryx zoui challenged the notion of feathers as a structure exclusive to Avialae 99 Buried in the Yixian Formation in Liaoning China C zoui lived during the Early Cretaceous Period Present on the forelimbs and tails their integumentary structure has been accepted by whom as pennaceous vaned feathers based on the rachis and herringbone pattern of the barbs In the clade Deinonychosauria the continued divergence of feathers is also apparent in the families Troodontidae and Dromaeosauridae Branched feathers with rachis barbs and barbules were discovered in many members including Sinornithosaurus millenii a dromaeosaurid found in the Yixian formation 124 6 MYA 100 Previously a temporal paradox existed in the evolution of feathers theropods with highly derived bird like characteristics occurred at a later time than Archaeopteryx suggesting that the descendants of birds arose before the ancestor However the discovery of Anchiornis huxleyi in the Late Jurassic Tiaojishan Formation 160 MYA in western Liaoning in 2009 101 102 resolved this paradox By predating Archaeopteryx Anchiornis proves the existence of a modernly feathered theropod ancestor providing insight into the dinosaur bird transition The specimen shows distribution of large pennaceous feathers on the forelimbs and tail implying that pennaceous feathers spread to the rest of the body at an earlier stage in theropod evolution 103 The development of pennaceous feathers did not replace earlier filamentous feathers Filamentous feathers are preserved alongside modern looking flight feathers including some with modifications found in the feathers of extant diving birds in 80 million year old amber from Alberta 104 Two small wings trapped in amber dating to 100 mya show plumage existed in some bird predecessors The wings most probably belonged to enantiornithes a diverse group of avian dinosaurs 105 106 A large phylogenetic analysis of early dinosaurs by Matthew Baron David B Norman and Paul Barrett 2017 found that Theropoda is actually more closely related to Ornithischia to which it formed the sister group within the clade Ornithoscelida The study also suggested that if the feather like structures of theropods and ornithischians are of common evolutionary origin then it would be possible that feathers were restricted to Ornithoscelida If so then the origin of feathers would have likely occurred as early as the Middle Triassic 107 though this has been disagreed upon 108 109 The lack of feathers present in large sauropods and ankylosaurs could be that feathers were suppressed by genomic regulators 110 Evolutionary stages nbsp Diagram illustrating stages of evolutionSeveral studies of feather development in the embryos of modern birds coupled with the distribution of feather types among various prehistoric bird precursors have allowed scientists to attempt a reconstruction of the sequence in which feathers first evolved and developed into the types found on modern birds Feather evolution was broken down into the following stages by Xu and Guo in 2009 90 Single filament Multiple filaments joined at their base Multiple filaments joined at their base to a central filament Multiple filaments along the length of a central filament Multiple filaments arising from the edge of a membranous structure Pennaceous feather with vane of barbs and barbules and central rachis Pennaceous feather with an asymmetrical rachis Undifferentiated vane with central rachisHowever Foth 2011 showed that some of these purported stages stages 2 and 5 in particular are likely simply artifacts of preservation caused by the way fossil feathers are crushed and the feather remains or imprints are preserved Foth re interpreted stage 2 feathers as crushed or misidentified feathers of at least stage 3 and stage 5 feathers as crushed stage 6 feathers 111 The following simplified diagram of dinosaur relationships follows these results and shows the likely distribution of plumaceous downy and pennaceous vaned feathers among dinosaurs and prehistoric birds The diagram follows one presented by Xu and Guo 2009 90 modified with the findings of Foth 2011 111 The numbers accompanying each name refer to the presence of specific feather stages Note that s indicates the known presence of scales on the body Dinosauria Ornithischia Heterodontosauridae 1 Thyreophora s Ornithopoda s Psittacosauridae s 1 Ceratopsidae s Saurischia Sauropodomorpha s Aucasaurus s Carnotaurus s Ceratosaurus s Coelurosauria Dilong 3 Other tyrannosauroids s 1 Juravenator s 3 Sinosauropteryx 3 Maniraptora Therizinosauria 1 3 Alvarezsauridae 3 Oviraptorosauria 4 6 Paraves Troodontidae 3 6 Other dromaeosauridsSinornithosaurus 3 6 Microraptor 3 6 7 Scansoriopterygidae 3 6 8 Archaeopterygidae 3 6 7 Jeholornis 6 7 Confuciusornis 4 6 7 8 Enantiornithes 4 6 7 8 Neornithes 4 6 7 8 In pterosaurs Pterosaurs were long known to have filamentous fur like structures covering their body known as pycnofibres which were generally considered distinct from the true feathers of birds and their dinosaur kin However a 2018 study of two small well preserved pterosaur fossils from the Jurassic of Inner Mongolia China indicated that pterosaurs were covered in an array of differently structured pycnofibres rather than just filamentous ones with several of these structures displaying diagnostic features of feathers such as non veined grouped filaments and bilaterally branched filaments both of which were originally thought to be exclusive to birds and other maniraptoran dinosaurs Given these findings it is possible that feathers have deep evolutionary origins in ancestral archosaurs though there is also a possibility that these structures independently evolved to resemble bird feathers via convergent evolution 112 Mike Benton the study s senior author lent credence to the former theory stating We couldn t find any anatomical evidence that the four pycnofiber types are in any way different from the feathers of birds and dinosaurs Therefore because they are the same they must share an evolutionary origin and that was about 250 million years ago long before the origin of birds 113 114 115 116 But the integumentary structures of the anurognathid specimens is still based gross morphology as Liliana D Alba pointed out The pycnofibres of the two anurognathid specimens might not be homologous with the filamentous appendages on dinosaurs 117 Paul M Barrett suspects that during the integumentary evolution of pterosaurs pterosaurs primitively lost scales and pycnofibers started to appear 93 Cascocauda was almost entirely covered in an extensive coat of pycnofibres which appear to have come in two types The first are simple curved filaments that range in length from 3 5 12 8 mm long These filaments cover most of the animal including the head neck body limbs and tail The second type consists of tufts of filaments joined near the base similar to the branching down feathers of birds and other coelurosaurian dinosaurs around 2 5 8 0 mm long and only cover the wing membranes Studies of sampled pycnofibres revealed the presence of microbodies within the filaments resembling the melanosome pigments identified in other fossil integuments specifically phaeomelanosomes Furthermore infrared spectral analysis of these pycnofibres show similar absorption spectra to red human hair These pycnofibres likely provided both insulation and may have helped streamline the body and wings during flight 118 The identity of these branching structures as pycnofibres or feathers was challenged by Unwin amp Martill 2020 who interpreted them as bunched up and degraded aktinofibrils stiffening fibres found in the wing membrane of pterosaurs and attributed the melanosomes and keratin to skin rather than filaments 119 These claims were refuted by Yang and colleagues who argue that Unwin and Martill s interpretations are inconsistent with the specimen s preservation Namely they argue that the consistent structure regular spacing and extension of the filaments beyond the wing membrane 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September 2011 Archived from the original on 15 September 2011 Rare Dinosaur Era Bird Wings Found Trapped in Amber 28 June 2016 Archived from the original on 28 June 2016 Retrieved 28 June 2016 Xing Lida McKellar Ryan C Wang Min Bai Ming O Connor Jingmai K Benton Michael J Zhang Jianping Wang Yan Tseng Kuowei 28 June 2016 Mummified precocial bird wings in mid Cretaceous Burmese amber Nature Communications 7 12089 Bibcode 2016NatCo 712089X doi 10 1038 ncomms12089 PMC 4931330 PMID 27352215 Baron M G Norman D B Barrett P M 2017 A new hypothesis of dinosaur relationships and early dinosaur evolution Nature 543 7646 501 506 Bibcode 2017Natur 543 501B doi 10 1038 nature21700 PMID 28332513 S2CID 205254710 Yang Zixiao Jiang Baoyu McNamara Maria E Kearns Stuart L Pittman Michael Kaye Thomas G Orr Patrick J Xu Xing Benton Michael J 17 December 2018 Pterosaur integumentary structures with complex feather like branching PDF Nature Ecology amp Evolution 3 1 24 30 doi 10 1038 s41559 018 0728 7 hdl 1983 1f7893a1 924d 4cb3 a4bf c4b1592356e9 ISSN 2397 334X PMID 30568282 S2CID 56480710 Langer Max C Ezcurra Martin D Rauhut Oliver W M Benton Michael J Knoll Fabien McPhee Blair W Novas Fernando E Pol Diego Brusatte Stephen L 2 November 2017 Untangling the dinosaur family tree PDF Nature 551 7678 E1 E3 Bibcode 2017Natur 551E 1L doi 10 1038 nature24011 hdl 1983 d088dae2 c7fa 4d41 9fa2 aeebbfcd2fa3 ISSN 1476 4687 PMID 29094688 S2CID 205260354 Benton Michael J Dhouailly Danielle Jiang Baoyu McNamara Maria 1 September 2019 The Early Origin of Feathers PDF Trends in Ecology amp Evolution 34 9 856 869 doi 10 1016 j tree 2019 04 018 hdl 10468 8068 ISSN 0169 5347 PMID 31164250 S2CID 174811556 a b Foth C 2011 On the identification of feather structures in stem line representatives of birds evidence from fossils and actuopalaeontology Palaontologische Zeitschrift 86 91 102 doi 10 1007 s12542 011 0111 3 S2CID 86362907 Unwin David M Martill David M December 2020 No protofeathers on pterosaurs Nature Ecology amp Evolution 4 12 1590 1591 doi 10 1038 s41559 020 01308 9 ISSN 2397 334X PMID 32989266 S2CID 222168569 Yang Zixiao Jiang Baoyu McNamara Maria E Kearns Stuart L Pittman Michael Kaye Thomas G Orr Patrick J Xu Xing Benton Michael J January 2019 Pterosaur integumentary structures with complex feather like branching PDF Nature Ecology amp Evolution 3 1 24 30 doi 10 1038 s41559 018 0728 7 hdl 1983 1f7893a1 924d 4cb3 a4bf c4b1592356e9 ISSN 2397 334X PMID 30568282 S2CID 56480710 Pterosaurs Had Four Types of Feathers New Study Shows Paleontology Sci News com Breaking Science News Sci News com 18 December 2018 Retrieved 19 December 2018 St Fleur Nicholas 17 December 2018 Feathers and Fur Fly Over Pterosaur Fossil Finding An analysis of two fossils would push back the origins of feathers by about 70 million years but more specimens may be needed for confirmation The New York Times Retrieved 19 December 2018 Briggs Helen 17 December 2018 Fur flies over new pterosaur fossils BBC News Retrieved 19 December 2018 D Alba Liliana 2019 Pterosaur plumage Nature Ecology amp Evolution 3 1 12 13 doi 10 1038 s41559 018 0767 0 ISSN 2397 334X PMID 30568284 S2CID 56480834 Zixiao Yang Baoyu Jiang Maria E McNamara Stuart L Kearns Michael Pittman Thomas G Kaye Patrick J Orr Xing Xu Michael J Benton 2019 Pterosaur integumentary structures with complex feather like branching Nature Ecology amp Evolution 3 1 24 30 doi 10 1038 s41559 018 0728 7 hdl 1983 1f7893a1 924d 4cb3 a4bf c4b1592356e9 PMID 30568282 S2CID 56480710 Unwin D M Martill D M 2020 No protofeathers on pterosaurs Nature Ecology amp Evolution 4 12 1590 1591 doi 10 1038 s41559 020 01308 9 PMID 32989266 S2CID 222168569 Yang Z Jiang B McNamara M E Kearns S L Pittman M Kaye T G Orr P J Xu X Benton M J 2020 Reply to No protofeathers on pterosaurs Nature Ecology amp Evolution 4 12 1592 1593 doi 10 1038 s41559 020 01309 8 hdl 10468 11874 PMID 32989267 S2CID 222163211 Further readingHanson Thor 2011 Feathers The Evolution of a Natural Miracle New York Basic Books ISBN 978 0 465 02013 3 Lucas Alfred M Stettenheim Peter R 1972 Structure of feathers Avian Anatomy Integument Vol Part 1 Washington D C US Department of Agriculture pp 235 276 External links nbsp Wikimedia Commons has media related to Feather nbsp Look up pluma or calamus in Wiktionary the free dictionary McGraw K J 2005 Polly want a pigment Cracking the chemical code to red coloration in parrots Australian Birdkeeper Magazine 18 608 611 DeMeo Antonia M Access to Eagles and Eagle Parts Environmental Protection v Native American Free Exercise of Religion 1995 Electronic Code of Federal Regulations e CFR Title 50 Wildlife and Fisheries PART 22 EAGLE PERMITS U S v Thirty Eight Golden Eagles 1986 Mechanical structure of feathers Documentary on the evolution of feathers Lecture notes on the avian integument U S National Fish and Wildlife Forensics Laboratory s Feather Atlas Federn org Retrieved from https en wikipedia org w index php title Feather amp 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