Friday, May 4, 2018

The Step-wise Bird: Andrea Cau on Bird Evolution

Above: WIP reconstrcution of one potential Connecticut River Valley trackmaker, the bird-like reptile Anchisaurus polyzelus. By M. Martyniuk, all rights reserved.
This morning saw the publication of a new paper by Andrea Cau, titled Assembly of the Avian Body Plan, and what a mammoth (dinosaurian?) work it is! Cau does an amazing job of synthesizing the step-wise nature of bird evolution that is so often hidden behind imprecise or muddy nomenclature. Far from a dichotomy between "non-avian" and "avian" dinosaurs, the important features we associate with modern birds gradually accumulated in a particular lineage of stem-birds ever since the early Triassic period. I should have a lot more to say on the nitty-gritty of this paper this weekend after I've had a chance to fully digest this important work on avian origins. In the mean time, I wanted to share a brief excerpt from (one of) my upcoming book(s), this one dealing with the struggles to interpret some of the earliest known dinosaur remains in an era before the nature of dinosaurs as weird transitional members of the bird lineage was fully understood. The chapter this comes from is discussing Edward Hitchcock's work in the early-mid 1800s on bird-like footprints found in the Connecticut River Valley. The footprints date to the early Jurassic (Cau's "Huxleyan stage" of bird evolution).

Several, more prominent, scientists of the time criticized Hitchcock’s interpretation of the footprints as having been made by birds. He was ridiculed for imagining huge birds that must have been many times the size of the largest living bird, the ostrich. Soon, the rediscovery of giant extinct birds like the moa granted him some level of vindication. But more serious criticisms followed. The sandstone of the Connecticut River Valley was simply too old, other scientists argued. Birds, being “higher” life forms in the ranked scheme of life most believed in at the time, must have also been newer, having developed fully only after the so-called “age of reptiles”. Some scientists went so far as to argue that the three-toed tracks belonged to giant frogs, and that only the large, strong hind limbs left impressions while the lighter forelimbs often did not. And, indeed, one fact which was very inconvenient to Hitchcock’s explanation was that some of the tracks preserved light forelimb impressions, and some were found along with tail drag marks.

What could Hitchcock do to save his bird hypothesis from the facts? By 1861, the discovery of an archaic proto-bird named Archaeopteryx lithographica provided the answer. Here was an example of a “bird” with primitive, reptilian features and a long tail. Perhaps, Hitchcock suggested, his sandstone prints were not made by giant moa-like birds, but giant Archaeopteryx-like birds. And what of the occasional forelimb impressions? Hitchcock actually suggested that, along with its primitive skeletal anatomy, the Archaeopteryx may have been a facultative quadruped! In his view, the Archaeopteryx was halfway between birds and reptiles in both anatomy and gait. Hitchcock had, rather unscientifically, crafted his hypothesis to be immune to all criticism. His peers weren’t buying it.

By the time of Hitchcock’s death in 1864, the bipedal, bird-like nature of many Mesozoic reptiles like Hadrosaurus and Compsognathus had been discovered. For most scientists, these creatures provided a more plausible explanation for Hitchcock’s “sandstone bird” tracks than actual birds. By the late 1800s, the tracks were universally accepted as having been made by prehistoric reptiles, though intriguingly bird-like ones. Today, we know that these ancestrally bipedal reptiles, the dinosaurs and their kin, did indeed have more in common with modern birds than with any of the modern reptile groups, and in fact included the evolutionary ancestors of true birds.

In the end, it turns out that Hitchcock was half-right. His sandstone bird tracks were made by creatures in many ways more like Archaeopteryx than any modern bird or reptile, some of which were partly or fully quadrupedal, with great sweeping tails and enormous body sizes compared to any birds alive today. Many of them even had feathers and feather-like filaments covering parts of their bodies. What Hitchcock had actually discovered were the bird-like reptiles, creatures descended from the same ancestors as crocodiles and turtles, but which had evolved a wide array of uniquely avian features. At a time when most mainstream scientists envisioned dinosaurs as huge, quadrupedal, mammal-like reptiles (in appearance and gait if not lineage), Hitchcock was able to use the traces they made in life to arrive at a conclusion that was actually much closer to the truth in many ways. The Mesozoic was not an “age of reptiles”, at least not on land. It was an age dominated by the bizarre, archaic relatives of birds.

I think the above is a good example of Cau's thesis that a false, dichotomous paradigm, like "bird" vs. "reptile", or "non-avian dinosaur" vs. "bird", and focusing mainly on "key" specimens like Archaeopteryx, can actively mask the reality behind fossil evidence. What do you think?

Sunday, April 30, 2017

Review: Dino-Riders Struthiomimus by TycOMG IT HAS FEATHERS

Quick Facts
1988 Dino-Riders Struthiomimus action figure WITH FEATHERS. IN 1988.
Size: 20cm of feathered glory.
Scale: Scales on the feet, feathers up top. Also, 1:12.
Sculpted by: The wokest of all 1980s dinosaur toy sculptors.
Produced by: Tyco (obviously with a lot of help from Bob Bakker).

No need to adjust your TV sets folks, this is a mass-produced dinosaur toy made in 1988 that is covered in feathers. Not like lame, Primal Carnage, Jurassic Park 3, cool-guy dragon with a mohawk. Natural looking feathers.

This is why Dino-Riders was the best thing about the '80s (sorry, He-Man). Dino-Riders gave us aliens from the future riding armored mind-controlled dinosaurs blasting a thousand lasers at other armored dinosaurs who were not mind controlled but who were just in it because they cared about justice, and the toy versions of these things looked more naturalistic and scientifically accurate (for the time) than anything in Jurassic World.

I'm going to use this particular review to drop some history.

Wednesday, April 12, 2017

You're Doing It Wrong: Pteranodon Bills

Your bill's looking a little puny, there, buddy.
(Painting by Heinrich Harder, 1912, public domain).
Everybody knows Pteranodon. Quick, stop to imagine it! It's easy, because it's the most often-illustrated and well known pterosaur to the general public (though today's marketing departments often call it a pterodactyl, following it's original, century-out-of-date classification).

But hold on. That image you have in your head right now, of a big pterosaur with a long crest and a mid-length pointy beak? That's likely wrong, and may be just as much a hybrid as those Flintstones-style creatures with pteranodont crests and Rhamphorhynchus tails.

How do we know? Let's talk about Dawndraco.

Wednesday, April 5, 2017

Review: Dino-Riders Pterodactyl by Tyco

Quick Facts
1987 Dino-Riders Pterodactyl action figure
Size: 20cm (wingspan)
Scale: 1:3 or 1:4
Sculpted by: unknown
Produced by: Tyco

Pterodactylus antiquus has a special place in history as one of the first ever prehistoric reptiles to be subjected to scientific study. It's one of the best known pterosaurs, with many complete specimens known to science, and it ended up lending its name to the entire group of pterosaurs to which it belongs (Pterodactyloidea). In fact, "pterodactyl" has become a common nickname for all pterosaurs, thanks in part to the fact that nearly all pterosaurs were considered species of Pterodactylus during the 19th century.

Despite the importance of pterodactyls, very few toy versions of them have been produced (in fact I don't know of any other than this one and one made by Starlux - if you know of more, let me know in the comments!). Sure, there are lots and lots (and LOTS) of toys out there claiming to be "pterodactyls", but the vast majority of these are actually other species of pterosaur, most often Pteranodon. A lot of older "pterodactyl" toys from the 1950s - 1980s are weird hybrids of the Pterosaurs' Greatest Hits, like pteranodonts with teeth, or with Rhamphorhynchus tails. But almost none of them are the classic, the original, the one and only pterodactyl. That's probably not a coincidence or a mistake - like the "velociraptors" in Jurassic Park that were really Deinonychus, pterodactyls have a cool name attached to a somewhat wimpy animal. Most pterodactyl fossils are tiny, with wingspans of only a few feet. Larger specimens do exist, but these skin-winged critters don't seem to have grown any bigger than a large seagull. Personally, I think that's part of their charm - I can't help but picture flocks of them squabbling over dead squids any time I watch gulls at the beach. But in terms of raw awesomeness, they certainly can't compete with 20 foot beasts like Pteranodon.

One of the very few pterodactyl toys that's actually a REAL pterodactyl is this one from Tyco. Produced in 1987 and released in 1988 at part of the Dino-Riders line, this pterodactyl came with a 2" action figure and a little hang glider accessory, but I won't be worrying about those here. Despite it's age, this is still one of my favorite pterosaur toys and holds up reasonably well even today. Let's get into some details...

Monday, July 18, 2016

Playing with Saurian's Genericometer

There's a dinosaur game in development called Saurian. Have you heard of it? You should really check out! It's shaping up to be super cool and extremely rigorous when it comes to science and coming up with accurate portrayals of an extinct ecosystem. Check out their page!*

*Full disclosure: I may be involved in this game's development in some small capacity. There will be birds.

The Saurian developers have made a somewhat controversial choice when it comes to the name of the Hell Creek Formation hadrosaurid. Yes, boys and girls, a video game company has dipped its toe into the boiling caldera that is dinosaur nomenclature.  Many fans (and keep in mind these are people who know enough to be early backers of a game priding itself on scientific accuracy and technical minutiae) were a little shocked to see the announcement of the Saurian hadrosaurid. Not just at the unbelievably painstaking level the devs went to in order to research and create the character - everything from life history and growth trajectories to mapping out the actual pattern of scales found on an infamous fossil mummy. People were also a little put off by the fact it was named Anatosaurus annectens rather than Edmontosaurus annectens.

I'm not going to re-hash the long and convoluted history of everybody's favorite "trachodont" (Wikipedia does a pretty good job of that). For the purposes of this post, it's enough to understand that these two species of dinosaurs, Anatosaurus annectens and Edomontosaurus regalis, are fairly similar. So similar that for the past 25 years or so, most scientists have "lumped" them together under the same group of species, the genus Edmontosaurus, making the binomial of the Hell Creek Formation species Edmontosaurus annectens and relegating the name Anatosaurus to the trash heap of history.

But, a few years ago something changed. See, there was a second Hell Creek hadrosaurid, a bigger and much more different looking beast named Anatotitan copei. During the same 25 year period, mostly everybody has agreed this dinosaur was different enough from its relatives to deserve its own genus name. Recently, studies have demonstrated that those differences aren't necessarily due to being more distantly related, but just being... older. Anatotitan, it turns out, is just a mature version of Anatosaurus/Edmontosaurus annectens that had built up more unique features with age. It's not just a similar species to annectens, like Edmontosaurus reglais is, it's the same species. So onto the trash heap with Anatotitan.

But wait! Anatosaurus was thrown out because it was too similar to Edmontosaurus. Now, it turns out, it was actually different--different enough that its adult form was given its own genus for all those years. So shouldn't Anatosaurus be a genus again?

Well, that depends on what you mean by "genus". There is no universally recognized rationale for what makes something "different enough" to be a genus, and the concept varies wildly between fields of biology. Each scientist has their own opinion, their own gut feeling based on tradition and intuition, not science, of what a genus should be. If you asked an entomologist to re-classify all dinosaurs based on her own personal "genericometer" settings, we'd end up with one single genus of dinosaur, and it would include every bird that ever lived. Probably crocodiles too. We'd be left arguing, based on page priority or something, if the star of Jurassic Park should be called Passer rex, Vultur rex, or Crocodylus rex. On the flip side, if you had a ceratopsian worker reclassify the beetles, we'd end up with a hundred billion new genera of beetle.*

*I'm not 100% sure that's the correct number, but it'd be something with a lot of zeroes.

Some people have attempted to bring some science to the art of taxonomy, and quantify genera. Recently and most famously, Emanuel Tschopp and colleagues published their precise genericometer settings, and used those settings to reclassify the diplodocid sauropods. This resulted in bringing back the old, previously-junked genus name Brontosaurus (you may have heard of it). This is a great thing to try, but the method was only designed to apply to diplodocids. It might wreak havoc with names in other dinosaur groups, and would certainly result in an entomologist revolt if anybody ever tried to use it on bugs.

To their credit, the Saurian team have been up front with their genericometer settings used in the game. Rather than base their concept of genus completely on anatomical similarity, they've made the very intriguing choice of combining evolutionary relationships with a chronological component. Basically, if species B is the closest relative of species A, and if species B is known from fossils that can be dated to within one million years of species A fossils, then species A and B are to be classified in the same genus.

I thought it would be fun to try out these genericometer settings and see how it compares to the current traditional consensus, and to some other more widely criticized attempts to re-genericize dinosaurs, like the classification used by Greg Paul in his Princeton Field Guide to Dinosaurs.

Edmontosaurus vs. Anatosaurus.

We'll start with Anatosaurus. If we take Anatotitan to be its synonym, then according to most recent phylogenies, its closest relative is Edmontosaurus regalis, which lived more than a million years earlier. This is why Saurian chose to split Anatosaurus back off into its own genus. But right here, we immediately need to note how highly dependent on the vagaries of phylogenetic analysis this method is. Ugrunaaluk is a very similar hadrosaurid that actually lived in between Edmontosaurus and Anatosaurus, and was originally thought to represent specimens of Edmontosaurus. According to the (very few) phylogenetic analysis on its relationships, Ugrunaaluk is actually outside the Anatosaurus+Edmontosaurus clade. But, given its chronological position, it's always possible more analysis will show that it is transitional between them. Ugrunaaluk is still too old to connect Anatosaurus to Edmontosaurus by a million years or less, but only slightly. Ugrunaaluk lived about 69 Ma ago, and the earliest Anatosaurus fossils are about 67 Ma old. All it would take would be one slightly younger Ugrunaaluk specimen, in that case, to pull the whole shebang back into Edmontosaurus.

Following this cladogram for the sake of argument, let's look at the next outgrip to Edmontosaurus, which is the clade Saurolophini. Now we reach the sticky question of what counts as the next closest relative of Edmontosaurus, moving down the tree. So lets start at the tip of the next branch, with Saurolophus. S. osborni lived between about 69-68 Ma ago, slightly later than the last Edmontosaurus, but still within a million years. S. angustirostris lived about 70 Ma ago, during the time Edmontosaurus was alive. Prosaurolophus lived up until around 74 Ma ago, which predates Saurolophus but sits just barely within a million years of the lower range of Edmontosaurus. Since both Saurolophus and Prosaurolophus lived within a million years of the upper and lower range of Edmontosaurus, following these genricometer settings, they should all be lumped into a single genus. Because of the rules of priority, that means Edmontosaurus itself goes on the trash heap and Saurolophus regalis becomes the correct name for that species. Same for the next closest relative to the Saurolophus + Edmontosaurus group, Gryposaurus, which is within a million years of Prosaurolophus. Ditto Kritosaurus. It's not until the Brachylophosaurini clade that we finally get a break from all this lumping, but already, half of the short-crested hadrosaurids are now Saurolophus.

Obviously, I'm taking this a little far on purpose, just to test it out as a general-use genericometer for dinosaurs. You could easily tweak these settings to produce more traditional genera, like adding a rule against paraphyly (both Anatosaurus and Kerberosaurus would fall within a clade formed by members of Saurolophus in the above example; though in my opinion this is a feature rather than a bug, since some genera had to have evolved from others anyway, it's a little silly trying to rigidly keep them monophyletic). We could also add a stipulation that the time component is relative to the type species or, even better, type specimen, to allow for inevitable evolutionary grades from one form to another. This would, in effect, place a sort of million-year "radius" around a species that is not ever-expanding. So anything up-tree or down-tree of E. regalis, like Ugrunaaluk, gets caught in its gravity well, but we don't then jump to anything within a million years of Ugrunaluuk, too. I have to think this is probably the real intent of the Saurian team's method.

A variety of ceratopsid genera, by Danny Cicchetti (CC-By-SA).
"These are all different GENERA? That's hilarious," --Entomologists.

Using this type-restricted genericometer method could still do some fun things in the one part of the dinosaur tree that everybody sort of secretly thinks is horribly over-split but doesn't say so out loud because nobody really wants to rain on those guys' big ol' naming party: the ceratopsids.

The Saurian team stated that, if they were to include Torosaurus as a distinct species in the game, it would be as a species of Triceratops, per the genericometer settings described above. Following this cladogram and a type-restricted interpretation of Saurian's method, Torosaurus does become a species of Triceratops, the holotype of which is from about 67 million years ago. Nedoceratops has to go as well. Now, the Triceratops party ends there based on this particular cladogram, but I find the placement of the Titanoceratops a little er... iffy. Titanoceratops is really, really similar to Pentaceratops from almost the same time and place, so finding it in between a bunch of species that look basically identical to Triceratops is odd. I'm not saying it's wrong, but let's just ignore it for the moment. If we do, then Ojoceratops, Eotriceratops, and Regaliceratops all become species of Triceratops, too. So the entire clade Triceratopsini = Triceratops.

Further down the tree, we have Anchiceratops and Arrhinoceratops becoming synonyms. Kosmoceratops and Vagaceratops, too. Chasmosaurus subsumes Mojoceratops, Agujaceratops, Utahceratops, and Pentaceratops. Coahuiloceratops and Bravoceratops are both safe, and form the sister clade to the big Chasmosaurus complex.

On the centrosaurine side of the tree, Achelousaurus becomes Einiosaurus, unless paraphyly is invoked. Centrosaurus gobbles up Coronosaurus, Spinops, and Styracosaurus (again, unless paraphyly is invoked, in which case Styracosaurus remains valid but includes Rubeosaurus ovatus; this was the plan for one of the unmet Saurian Kickstarter stretch goals that would have included Styracosaurus ovatus).

Overall, this system produces a classification that is similar to, but not nearly as extensively lumped, as the one used by Greg Paul. I kind of like it, especially with the type species stipulation in play. I think that if you are going to use genera, and not just convert all genus names to species praenomen as some people have suggested, it's a good idea to have some kind of standard metric. The problem is, of course, that nobody will ever agree to one standard. Even within dinosaurs. Nobody specializes in all dinosaur groups. We have ceratopsian workers, tyrannosaur workers, avialan workers, sauropod workers, etc., all with their own traditions and personal metrics. This is why it tends to be the science popularizers, like the Saurian devs or Greg Paul or even Bob Bakker, who are the ones coming up with what all the professionals view as highly idiosyncratic classifications. They're attempting to take all these disparate fields within dinosaur paleontology and apply a single metric to all of them, which is bound to change a few things away from the consensus.

At the end of the day, the consensus is what it is. I'm glad people are exploring ways to apply consistency and standards to science-related minutiae like taxonomy. But it's equally important that those efforts be transparent, so we can compare each metric to the others and see which produces the results we like the best. Because at the end of the day, all of this splitting and lumping of genera comes down to just that: a matter of opinion.

Saturday, May 28, 2016

You're Doing It Wrong: Microraptor Tails and Mini-Wings

Type specimen of Zhenyuanlong, doing its best Archaeopteryx impression.
Just a short PSA today, and once again, it's about a paleoart meme that has outstayed its welcome.

Microraptor was the first time we got a good look at the feather pattern of dromaeosaurids. This is a big problem for two reasons. One, microraptors were small. That means that artists who were looking at them to extrapolate for bigger, more famous "raptors" could easily and somewhat justifiably write off their huge wings as a product of their size. Sure, we thought, microraptors had big wings, but they're tiny animals. Surely the bigger, more terrestrial dromaeosaurids didn't need such big wings. They probably still had wings, but they'd be smaller. Why would Velociraptor need such proportionately huge wings if it couldn't fly or glide?

Meme number two: that tail. I admit to being one of the first to go overboard when I fell, head over heels, for the "puff tailed dromeosaur" fossil (now the holotype of Cryptovolans, a synonym or close relative of the Microraptor) back around 2000. This was the first evidence we had of the tail feather style in dromeosaurids (or evidence that they even had remixes and rectrices at all. Remember When Dinosaurs Ruled America? That was plausible at the time it was being made). Naturally, having Microraptor plus Caudipteryx showed that the ancestral condition of pennaraptorans was a fan of feathers at the tip of the tail, not a fuzzy Sinosauropteryx like tail or a fully-vaned Archaeopteryx like tail. So artists ever since have been drawing dromeosaurids and troodontids and oviraptorosaurs with microraptor tails.

But that turned out to be wrong! It's an accident of history. We're now learning that Microraptor and Caudipteryx are weirdos.

Sunday, May 1, 2016

The First Feathered Dinosaurs (In Art)

The first illustration of a hypothetical "pro-avis" by Pycraft, 1906
Feathered non-avialan dinosaurs seem commonplace now, and it's hard to believe that there was a time, in living memory for some of us, when they were purely speculative. It makes sense, of course: once scientists realized (then realized again) that dinosaurs were the closest fossil relatives of birds, it was only natural to suggest that feathers had appeared in dinosaurs before they showed up in birds. To have a new type of animal, like Archaeopteryx, appear more or less fully formed with flight and feathers occurring simultaneously makes little sense in terms of evolution. Obviously, even if Archaeopteryx was considered the "first bird" or could fly in some rudimentary manner, it couldn't have been the first animal with feathers or feather-like integument. Feather-like structures had to have been present in the archaeopteryx's closest relatives. But what were those? For most of the 20th century, the answer would not have been dinosaurs.

Nopcsa's 1907 feathered, Compsognathus-like
"pro-avis" model at the Grant Museum, London.
Speculative bird ancestors with feathers or feather-like scales had been hypothesized and illustrated long before the first true feathered dinosaurs appeared in paleoart. These hypothetical "pro-aves", as they were generally termed, were first imagined by William Pycraft in 1906. Pro-aves were usually considered arboreal, gliding animals with elongated, feather-like scales, and Pycraft's illustration provided the template followed by many later illustrators, like Heilmann's 1916 version, and Burian's gorgeous but even more lizard-like 1960 rendition. Not all pro-avis illustrations followed this template, though. In 1907, Baron Nopcsa invented his own pro-avis, illustrating his hypothesis of a running, "ground-up" origin of bird flight. In addition to his illustration, Nopcsa created a wax model. Nopcsa thought birds might have evolved from quadrupedal reptiles which became more and more bipedal as their running speed increased, passing through a phase similar to Compsognathus, though not necessarily dinosaurian.

Beebe's "tetrapteryx", 1915.
There were also creatures like the "tetrapteryx", a speculative stage in the evolution of avian flight proposed by William Beebe in 1915. Beebe illustrated an Archaeopteryx-like creature with smaller wings as well as hind wings on splayed legs, reminiscent of early (but incorrect) illustrations of Microraptor. Other than the posture, the general anatomy of this hypothetical creature ended up being prescient by accident. His rationale for this hypothesis was the observation that some bird embryos develop and then lose feather quills on their legs. Heilmann, however, rejected this hypothesis after failing to find evidence among other bird embryos. New evidence to support this hypothesis was discovered in species like Microraptor, Anchiornis, and Sapeornis, which had various degrees of airfoils present on their hind legs, a line of evidence independent of the one supposed by Beebe. Though dinosaur-like in appearance, both Beebe and Heilmann considered the ancestors of birds to be "thecodont" grade archosaurs, not dinosaurs, so these hypothetical feathered thecodonts predated the first feathered dinosaurs in art.
Speculative reconstruction of a Triassic "carnavian" dinosaur
leaving feather traces in its trackway, from Ellenberger 1974.

The thecodont origin of birds did not truly give way to a dinosaur origin until the 1970s, after John Ostrom described the similarities between Archaeopteryx and Deinonychus. If dinosaurs were the new closest relatives of birds, then at least the most bird-like among them should be depicted with feathers (Ostrom himself disagreed with this though, and, according to Bakker, he fought the idea that Deinonychus should be feathered). Of course, which dinosaurs were most closely related to birds, and just how much of a gap remained between them and Archaeopteryx, allowed for considerable wiggle room and speculation.

A "carnavian" track maker
parachuting, from Ellenberger 1974.
In 1974, Ellenberger identified what he considered to be trace evidence for feathered dinosaurs from Lesotho, in the form of possible feather imprints and footprints which could have been made by small animals parachuting from trees, dragging their tail feathers in mud, etc. He illustrated a small bipedal dinosaur with feathers in the accompanying paper, along with totally speculative skeletal restoration of a new type of animal, nested within theropod dinosaurs, which he called "carnavians." Molnar, in 1985, dismissed the suggestion that these were feather imprints. Still, Ellenberger had become the first person to ever illustrate a non-avialan dinosaur, however hypothetical the species, with feathers.

Landry's influential 1975 restoration of "Syntarsus".
The next year, in 1975, a more famous feathered dinosaur illustration of a much better-known species was provided by Sarah B. Landry, drawn under the direction of Bob Bakker for his seminal article in Scientific American, "The Dinosaur Renaissance." Landry and Bakker depicted the small theropod "Syntarsus" (=Coelophysis) covered in overlapping feather-like scales or scale-like feathers, similar to Heilmann's "proavis", and a long tuft of feathers on the head. The choice of species was not a coincidence. Michael Raath, who had described Syntarsus in 1969 (the same year as Deinonychus), was quick to tout how bird-like it was in popular books and articles, and he suggested several times that it may have been feathered.

"Syntarsus" by Stout, 1976.

To understand the impact of this "first" feathered dinosaur, just look at the rest of the 1970s and early 1980s. It was Syntarsus, not Deinonychus, which was consistently drawn with feathers from then on. Many of these later reconstructions even directly aped Bakker and Landry's style of feather crest (or slightly modified it), making "Syntarsus with feather crest" a bona fide paleoart meme. Many of these left out the more subtle body feathers of the original, unfortunately, possibly influencing decades of "half-arsed" theropods with feather mohawks, up to including the dinosaurs in the 2001 film Jurassic Park III more than 20 years later. (One notable exception to the Syntarsus trend was also a watershed moment for paleoart. After reading Bakker's article, a paleoartist named Gregory S. Paul drew his first feathered dinosaur: an Allosaurus).

One of my favorite derivatives of Landry's Syntarsus illustration is one made in 1976 by William Stout and reproduced in Don Glut's 1982 edition of The New Dinosaur Dictionary. Though Glut pointed out that the feathers were speculative, they're probably less inaccurate than the legless snake it's eating! Also included in Glut's revised dictionary was one of the first illustrations of the theropod Kakuru, by Mark Hallett. Though just as speculative as Ellenberger's drawing (Kakuru is known only from two limb bones), it has more of a modern feel. The reclining theropod is decked out in long, filamentous feathers, rather than the broad, scale-like feathers of Landry's Syntarsus. It's worth noting that all of these early drawings of feathered dinosaurs had bare or scaly faces. This method of emphasizing the transitional character of early feathered theropods was probably inspired by traditional portrayals of Archaeopteryx, a "bird" with the head of a "reptile."

Feathered ornithischians, by Lorene Bjorklund, from
The Warm-Blooded Dinosaurs, 1979.
Many bird-like dinosaurs actually had feathers covering some or all of the face as well as the body, though some kind of "modular evolution" did occur to a degree in a few lineages (here's looking' at you, Darwinopterus). And some Mesozoic dinosaurs, most famously Kulindadromeus, seem to have feathers restricted to certain body segments with abrupt transitions between feathery and scaly regions. So, this much-maligned meme isn't necessarily out of the question, at least in early feathered lineages.

A few very early books featuring extremely prescient feathered dinosaurs came in 1978 and 1979. First, Julian May brought us perhaps the first renaissance-era dinosaur book for kids, The Warm-Blooded Dinosaurs, which featured not only a feathered Struthiomimus by Lorene Bjorklund on the cover, but several feathered ornithischians inside. An Iguanodon looks sort of ambiguously feathered (it might just be the crosshatched style), and interestingly, has a abrupt transition to a croc-scutes tail very similar to Kulindadromeus. There's also a skeletal of Microvenator with a fuzzy, Greg Paul style silhouette outline. The next year, Archosauria: A New Look at the Old Dinosaur by John McLoughlin includes some species with feathered faces for the first time, like his amazing, feathered Coelurus. It's odd as a modern reader to see that in both of these books, it's the more basal dinosaurs shown with feathers. Primitive ornithopods and "coelurosaurs" (considered a paraphyletic grade of early, ancestral dinosaurs at the time) like Syntarsus, Coelurus, and Saltopus are given feathers while deinonychosaurs like Saurornithoides and Deinonychus are not. The influence of the thecodont theory was still going strong, with birds thought to have evolved from the earliest dinosaurs rather than deinonychosaurs, which were exclusively known from the Cretaceous at that time.

Kakuru by Mark Hallett, from Glut 1982.

Ironically, Deinonychus, which out of all these dinosaurs was most similar to Archaeopteryx, did not become consistently or even frequently depicted with feathers until the at least the late 1980s. This was also probably due, in part, to artistic inertia. The original illustration of Deinonychus that accompanied Ostrom's description was so iconic that it was being copied well into the '90s. One of the first depictions of a feathered Deinonychus was a statuette produced by sculptor and founding father of Neopaganism Otter Zell (aka Oberon Zell). If anybody who owns a copy of this statuette wants to trade it for my right arm, please let me know.

After Syntarsus, the next non-avialan to become consistently depicted with feathers was Avimimus. From its first discovery, Avimimus was interpreted (and in some cases, like the supposed lack of a tail, misinterpreted) as being as birdlike or more than Archaeopteryx. Though commonly misreported online as having quill knobs, Avimimus actually had a flat ridge on the ulna which has been interpreted as a similar kind of support for the soft tissue of a feathered wing. Though not the same kind of direct evidence as quill knobs would be, most paleoartists ran with the suggestion, and most early Avimimus illustrations did portray it with feathers. John Sibbick restored it that way for David Norman's 1985 Illustrated Encyclopedia of Dinosaurs, and his version is a down-right throwback to the "pro-aves" of the early 1900s, with long, scale-like feathers on the outstretched arms and tail.
The first(?) feathered Deinonychus,
a statuette by Otter Zell, 1984.

1986 saw the publication of Bakker's The Dinosaur Heresies, filled with his own illustrations of feathered dinosaurs, including Deinonychus. (Stout and Paul had both continued to illustrate feathered dinosaurs up to this time, though not all were published or widely distributed at the time). Bakker's book opened up the door to more mainstream portrayals of this controversial subject, and it's no coincidence that many other artists were working the occasional feathered dinos into books and articles in the years that followed. Most notable among these were Paul's Predatory Dinosaurs of the World in 1988, and children's books inspired by it like The News About Dinosaurs. From then on, every "renaissance" era dinosaur book worth its salt included at least one speculative feathered theropod. Some books were bold enough to become the first to put "Feathers On Bloody Everything" (to quote the lament of some current-day feather detractors), theropods and ornithischians alike, as in 1988's speculative evolution book The New Dinosaurs by Dougal Dixon.

Two early restorations of Avimimus. Left: by Sergai Kurzanov, looking very bird-y.
Right: By John Sibbick from Norman's Encyclopedia, looking very much like Heilmann's "pro-avis."
By the time the first actual feathered dinosaur was announced in 1996, dinosaur fans, if not the general public, had been well prepared and had even come to expect such a find to be inevitable. The fact that this first find was Sinosauropteryx unfortunately reinforced some stereotypes that had been perpetuated by early renaissance era paleoart, such as short, fur-like feathers, naked legs and bellied, and half-feathered faces. Paul essentially invented the latter meme in an attempt to make his theropods look more bird like (by suggesting a sort of beak), and while this was his own personal speculation, many later artists ran with it, including in early drawings of Sinosauropteryx. The fossil appeared to support the hypothesis, which would have been an incredibly lucky guess for Paul if not for the fact that the snout past the eyes on that specimen had not even been fully prepared out of the rock (maybe, just maybe, because the scientists themselves were so influenced by Paul that they didn't expect any feathers to be found there!).

A modern feathered dinosaur:
 Tianyulong sculpture by Jason Brougham, 2016.
In a way, modern paleoart is still struggling to shed the memes and conventions generated by this pre-evidence feathered dinosaur artwork. Many artists are starting to critically examine just how far-off much of that early art really was, and to realize that it was, of course, just pure speculation about what may be, not informed speculation based on fossil evidence. Many dinosaurs, especially non-avialan coelurosaurs, had a feather covering that was much more Archaeopteryx-like than any of those pioneering artists could imagine. It's only recently that many of the best artists have been going back for inspiration not to Landry and Paul and Bakker, but to the earlier artists who were drawing Archaeopteryx and the various "pro-aves". This new era of paleoart, part of what Tom Holtz has dubbed the "Dinosaur Enlightenment," will no doubt generate its own set of tropes which will need to be overcome by the next generation of artists. We're already seeing that with the dogmatic insistence from some quarters on a certain standard of feathering for all dinosaurs when the fossils are starting to suggest much more variety. With any luck, the internet will allow this new generation to push forward and more widely and rapidly share new ideas and possibilities about what feathered dinosaurs can be.