The cladogram shows that birds did not evolve from dinosaurs.
Click to enlarge.
See Comments for taxa and characters.
This site presents the idea that birds developed from flying pterosaurs. This is a credible alternative to the current, mainstream idea that birds developed from land-based dinosaurs.
The cladogram shows that birds did not evolve from dinosaurs.
Click to enlarge.
Various studies analyze dinosaurs (including birds that they think evolved from dinosaurs).
And other studies analyze pterosaurs.
But no studies include both dinosaurs and pterosaurs scored on the same characteristics.
The one exception is the 2022 study which includes the analysis of one character - feather type, for both pterosaurs and dinosaurs.
https://zenodo.org/record/6122213#.YqC5YP_MKcx
See tab 4 of spreadsheet.
Notice that Tupandactylus is scored as feather type 5.
Consider the short tailed pterosaurs (eg. tupandactylus) and the short tailed scansoriopterygids (eg epidexipteryx).
Pterosaurs like birds, were capable of powered flight. It seems that command of the skies is not the only thing that these two types of vertebrate had in common. Thanks to a remarkable series of discoveries from the remote Turpan-Hami Basin located in the Xinjiang Uygur Autonomous Region (north-western China), palaeontologists have learned that Pterosaurs, like many living birds nested in colonies, that they had preferred nesting sites and when young, Pterosaurs needed a degree of parental care, just like many species of birds today.
Significantly, the number of eggs discovered are far too many to have been laid by a single female. This suggests that these flying reptiles nested in colonies and furthermore, the overlaying of multiple clutches of eggs indicates that Pterosaurs, like many birds today, returned to the same nesting sites each year. As the authors conclude, “the similarity between these groups goes beyond wings”.
The study:
https://www.science.org/doi/10.1126/science.aan2329
The scientific paper: “Egg Accumulation with 3D Embryos Provides Insight into the Life History of a Pterosaur”
Here is a summary of the basic ideas of this site:
Birds developed in a lineage from short bony tailed pterosaurs to short bony tailed scansoriopterygidae that developed into basal pygostylia birds that developed into modern birds. A side lineage earlier developed from the long tailed pterosaurs to long bony tailed scansoriopterygidae. That linage went extinct.
https://biblio.ugent.be/publication/8752596/file/8752597.pdf
Some feather morphologies are shared (that is, monofilaments, brush-like and tufted feathers and feathers with along-rachis branching), but others are not—for example, feathers with midpoint branching in pterosaurs and all feathers with barbules in theropods. Barbules are thus a unique innovation of theropod feathers.
This would be more accurate to say:
all feathers with barbules in
theropods[Paraves]. Barbules are thus a unique innovation oftheropod[Paraves] feathers.
Paraves* did not develop from any dinosaurs.
" including secondarily flightless oviraptorids and secondarily flightless ornithomimosaurs
Similar skull openings of pterodactylid and scansoriopterygid:
https://en.wikipedia.org/wiki/File:Epidexipteryx.jpg
High level similarities:
Pterosaur pterodactylid (eg tupandactylus):
Membrane wing
Longest 4th finger
Stage IIIa feathers
Short bony tail
Paraves scansoriopterygid (eg epidexipteryx):
Membrane wing
Longest 4th finger
Stage IIIa feathers
Short bony tail
Significant evidence that short bony tailed pterodactylid developed into short bony tailed scansoriopterygid.
https://biblio.ugent.be/publication/8752596/file/8752597.pdf
To our knowledge, stage IIIa feathers have not previously been reported in pterosaurs. The Tupandactylus branched structures resemble those in the dromaeosaurid dinosaur Sinornithosaurus millenii27, which are considered homologous to avian feathers28, and differ from the three types of branched feathers described in anurognathid pterosaurs2 .
This mode of branching is directly comparable to that in stage IIIa feathers19,20 of extant birds, that is, with barbs branching from a central rachis. This is strong evidence that the fossil branched structures are feathers comprising a rachis and barbs.
In other words the pterosaur Tupandactylus stage IIIa feathers resembled those in Sinornithosaurus (paraves/dromaeosauridae) which are considered homologous to avian feathers.
This is exceptional support for the pterosaur to bird theory.
https://biblio.ugent.be/publication/8752596/file/8752597.pdf (2022)
The genotypic and phenotypic characters could both be ancestral to avemetatarsalians; alternatively, both evolved independently in theropods and pterosaurs, or the genes are ancestral and the phenotypic expression occurred independently in the two groups. Our ancestral-state estimations (Extended Data Fig. 9e) reveal that the most parsimonious scenario is that feathers in the avemetatarsalian ancestor had melanosomes with different geometries. This is consistent with a single, deep evolutionary origin for this feature, whereby critical shifts in the genetic machinery facilitating plasticity in melanosome shape occurred in the common ancestor of pterosaurs and birds. Key genomic controls on melanin-based colouration that define the plumage colours of theropods and fossil and extant birds were therefore already in place in early-diverging avemetatarsalians in the Middle to Late Triassic.
Data availability
Additional data on melanosome geometry and the character matrix used in the phylogenetic analyses are available in the Zenodo.org data repository at https://doi.org/10.5281/zenodo.6122213. SEM images and samples are available from the corresponding authors on request.
https://biblio.ugent.be/publication/8752596/file/8752597.pdf (2022)
Remarkably well-preserved soft tissues in Mesozoic fossils have yielded substantial insights into the evolution of feathers(1). New evidence of branched feathers in pterosaurs suggests that feathers originated in the avemetatarsalian ancestor of pterosaurs and dinosaurs in the Early Triassic(2), but the homology of these pterosaur structures with feathers is controversial(3,4). Reports of pterosaur feathers with homogeneous ovoid melanosome geometries(2,5) suggest that they exhibited limited variation in colour, supporting hypotheses that early feathers functioned primarily in thermoregulation(6). Here we report the presence of diverse melanosome geometries in the skin and simple and branched feathers of a tapejarid pterosaur from the Early Cretaceous found in Brazil. The melanosomes form distinct populations in different feather types and the skin, a feature previously known only in theropod dinosaurs, including birds. These tissue-specific melanosome geometries in pterosaurs indicate that manipulation of feather colour-and thus functions of feathers in visual communication-has deep evolutionary origins. These features show that genetic regulation of melanosome chemistry and shape(7-9) was active early in feather evolution.
Developmental Model of the Origin and Diversification of Feathers
A predicted transition series of feather follicles based on the hypothesized series of evolutionary novelties in feather developmental mechanisms (Figure 4) from Prum (1999). Stage I—Origin of an undifferentiated tubular collar yields the first feather, a hollow cylinder. Stage II—Origin of a collar with differentiated barb ridges results in a mature feather with a tuft of unbranched barbs and a basal calamus emerging from a superficial sheath. Stage IIIa—Origin of helical displacement of barb ridges and the new barb locus results in a pinnate feather with an indeterminate number of unbranched barbs fused to a central rachis. Stage IIIb—Origin of peripheral barbule plates within barb ridges yields a feather with numerous branched barbs attached to a basal calamus. Stages IIIaIIIb—Origin of a feather with both a rachis and barbs with barbules creates a bipinnate, open pennaceous structure.
Morphotype 5 is only known in Epidexipteryx. It consists of parallel barbs arising from the edge of a membrane structure (Zhang et al., 2008b).
Video from Maria McNamara:
https://www.youtube.com/watch?v=Bmm3IyyjcS0
Difference between feather (with no barbules) and down:
https://www.youtube.com/watch?v=5rcwajqH0Dc&t=1s
http://link.springer.com/article/10.1007/s10336-014-1098-9/fulltext.html (2014)
Jurassic archosaur is a non-dinosaurian bird
Stephen A. Czerkas, Alan Feduccia
Re-examination utilizing Keyence 3D digital microscopy and low angled illumination of the fossil Scansoriopteryx, a problematic sparrow-size pre-Archaeopteryx specimen from the Jurassic Daohugou Biotas, provides new evidence which challenges the widely accepted hypothesis that birds are derived from dinosaurs in which avian flight originated from cursorial forms. Contrary to previous interpretations in which Scansoriopteryx was considered to be a coelurosaurian theropod dinosaur, the absence of fundamental dinosaurian characteristics demonstrates that it was not derived from a dinosaurian ancestry and should not be considered as a theropod dinosaur.
I am suggesting the following:
Long bony tailed rhamphorhynchid --> Long bony tailed scansoriopterygid (eg scansoriopteryx) --> Derived long bony tailed Paraves (eg Anchiornithids) --> Extinction
Long bony tailed rhamphorhynchid --> Short bony tailed pterodactylid --> Short bony tailed scansoriopterygid (eg epidexipteryx) --> Pygostylia --> Modern birds.
To this point I have focussed on the development from long bony tailed pterosaurs (rhamphorhynchids) to long bony tailed scansoriopterygids (eg scansoriopteryx).
I have not followed on from there to whether long bony tailed Paraves became short bony tailed pygostylia. I suggest they did not.
And I have not talked about the short tailed pterodactylids.
I suggest they are related. Short tailed pterosaurs (eg pterodactylids) developed into short bony tailed scansoriopterygids (eg epidexipteryx). Which then developed into pygostylia.
Nature experimented with various forms of flight. A big challenge was transitioning from long bony tail to short bony tail. This was accomplished WITHIN pterosaur lineage.
https://en.wikipedia.org/wiki/Pterodactyloidea
"Pterodactyloidea is traditionally considered to be the group of short-tailed pterosaurs with long wrists (metacarpus), compared with the relatively long tails and short wrist bones of basal pterosaurs ("rhamphorhynchoids")."
https://en.wikipedia.org/wiki/Scansoriopterygidae
"Epidexipteryx had a short tail (70% the length of the torso), anchoring long tail feathers, while Scansoriopteryx had a very long tail (over three times as long as the torso) with a short spray of feathers at the tip."
Some long bony tailed pterosaurs (eg rhamphorhynchids) developed into long bony tailed scansoriopterygids. And some of those long bony tailed scansoriopterygids developed into other more derived long bony tailed members of Paraves. Then they went extinct.
But there are two paths. One from long bony tailed pterosaurs and the other from (later) short bony tailed pterosaurs (eg pterodactylids)
Some short bony tailed pterosaurs (eg pterodactylids) developed into short bony tailed scansoriopterygids. And some of the short bony tailed scansoriopterygids developed into pygostylia.
This means that later stage feathers (after stage IIIa) developed in both lines.
This suggests there was greater experimentation with wing-assisted locomotion before theropod flight evolved than previously appreciated. This study adds invaluable support for multiple origins of powered flight potential in theropods (≥3 times), which we now know was from ancestors already nearing associated thresholds, and provides a framework for its further study
One important dinosaurian synapomorphy is the perforate [completely open] acetabulum, simply a "hip bone" (actually three connected bones, together called the pelvis) with a hole in the center where the head of the femur ("thigh bone") sits. This construction of the hip joint makes an erect stance (hindlimbs located directly beneath the body) necessary — like most mammals, but unlike other reptiles which have a less erect and more sprawling posture. Dinosaurs are unique among all tetrapods in having this perforate [completely open] acetabulum.
Yi qi, which has membranous wings—a flight apparatus that was previously unknown among theropods but that is used by both the pterosaur and bat lineages6. This observation was not universally accepted7. Here we describe a newly identified scansoriopterygid —which we name Ambopteryx longibrachium, gen. et sp. nov.—from the Upper Jurassic period. This specimen provides support for the widespread existence of membranous wings and the styliform element in the ScansoriopterygidaeThe scansoriopterygids (including Ambopteryx) are members of basal Paraves. With their wing skin membrane and longest outermost finger, they are a candidate transitional between pterosaur and later Paraves. They fit right into the pterosaur to bird theory.
A 2009 study showed that pterosaurs had a lung-air sac system and a precisely controlled skeletal breathing pump, which supports a flow-through pulmonary ventilation model in pterosaurs, analogous to that of birds.But the parsimonious conclusion is that basal Paraves evolved FROM pterosaurs.
Pterosaur integumentary structures with complex feather-like branching
Pterosaurs were the first vertebrates to achieve true flapping flight, but in the absence of living representatives, many questions concerning their biology and lifestyle remain unresolved. Pycnofibres—the integumentary coverings of pterosaurs—are particularly enigmatic: although many reconstructions depict fur-like coverings composed of pycnofibres, their affinities and function are not fully understood. Here, we report the preservation in two anurognathid pterosaur specimens of morphologically diverse pycnofibres that show diagnostic features of feathers, including non-vaned grouped filaments and bilaterally branched filaments, hitherto considered unique to maniraptoran dinosaurs, and preserved melanosomes with diverse geometries. These findings could imply that feathers had deep evolutionary origins in ancestral archosaurs, or that these structures arose independently in pterosaurs. The presence of feather-like structures suggests that anurognathids, and potentially other pterosaurs, possessed a dense filamentous covering that probably functioned in thermoregulation, tactile sensing, signalling and aerodynamics.
Dr. Unwin and Professor Martill propose that the branched pycnofibers in pterosaurs are not protofeathers at all, but tough fibers which form part of the internal structure of the pterosaur’s wing membrane, and that the ‘branching’ effect may simply be the result of these fibers decaying and unraveling.
Reply:
https://www.researchgate.net/publication/344413424_Reply_to_No_protofeathers_on_pterosaurs
In our paper1, we explored the morphology, ultrastructure and chemistry of the dermal structures of pterosaurs and showed that they probably had a common evolutionary origin with the integu-mentary structures seen widely in dinosaurs (including birds), their close relatives. Our study of two Middle Jurassic anurognathid pterosaurs from China showed that the whisker-like pycnofibres of the pterosaurs include at least four distinct morphologies, rather than one as had been assumed, and that three of these show branch-ing, a key characteristic of feathers. Further, all four pycnofibre types are morphologically identical to structures already described in birds and non-avialan dinosaurs, not only in terms of gross mor-phology but also in their ultrastructure and chemistry, including melanosomes and chemical evidence for keratin; collectively, these features are consistent with feathers.
QuoteScansoriopteryx (Paraves)Temporal range: Callovian to Kimmeridgian, 165-156 MaQuoteSerikornis (Paraves)Temporal range: Middle Jurassic, 165-162 Ma
ProceratosaurusQuoteProceratosaurus (basal Tyrannoraptora)Temporal range: Middle Jurassic, 165 Ma
Proceratosaurus is a genus of small-sized (~3 metres (9.8 ft) long) carnivorous theropod dinosaur from the Middle Jurassic (Bathonian) of England.[1] It was originally thought to be an ancestor of Ceratosaurus, due to the similar small crest on its snout.[2] Now, however, it is considered a coelurosaur, specifically one of the earliest known members of Tyrannosauroidea,[3] the clade of basal relatives of the tyrannosaurs.[4]So the actual fossil evidence has paravians and the type of dinosaur they are thought to have evolved from appearing in the fossil record beginning at the same time.