Ororhynchus and Lapidoscelis

The hills and ranges of Ryl Madol are often pockmarked with holes and burrows, created by the various fossorial reptiles and amphibians. Many of them are inhbaited by Ororhnychus marmotaoides, which in some ways is an oddity on this island, despite its very conservative anatomy. Like Iniasaurus and Nothocadborus, Ororhnychus and its relatives are creatures that are decidedly Triassic in character, as opposed to most of the other fauna on the island, which traces its origins back to the Paleozoic. It is a rhynchosaur, a group of bizarre archosauromorph reptiles, which once used to thrive in the arid wastes of Pangaea before their dinosaur-cousins began to ecologically dominate Earth. However, most phylogenetic studies indicate that rhynchosaurs have an early origin somewhen during the Latest Permian, so their presence here is not as anomalous as, say, Cynocetus.

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Rhynchosaurs as a whole are abundant on Ryl Madol, though usually in a form no longer reminiscent of the Triassic taxa, such as the arboreal Sciururhnychia and the flying Celaenosauria. These are usually grouped together into the Neorhynchosauria (though some workers consider this clade to be polyphyletic). Even among these rylian rhynchosaurs, Ororhnychus stands out due to how archaic it appears, being the only extant species that does not seem to be part of Neorhynchosauria. Instead, it phylogenetically groups closely with classic Triassic forms like Hyperodapedon and Fodonyx. It still walks on all fours, in a semi-erect stance, and has strong digging feet. Its head is a powerful piece of primeval engineering, with huge jaw-closing muscles and rows of interlocking teeth, as well as tooth plates on the floor and roof of the jaw, which all slide into each other like a pen-knife. In essence an extreme version of the jaws of a tuatara. The upper jaw terminates into a sharp, downward-pointing beak, which fits into a bifurcated beak on the tip of the lower jaw. With this arrangement it efficiently clips, chews and grinds the abundant seed ferns which green the edges of the island, such as Kainodicroidium. A living fossil on an island of living fossils.

Ororhynchus live largely solitary lives, browsing for leaves or digging for tubers for most of the day and sleeping during the night in large burrows they dug out themselves with their strong claws and beaks. If an Ororhnychus dies or abandons their burrow, it usually becomes a shelter or home for various other animals that cannot dig themselves, making these rhynchosaurs important cornerstones of the upland ecosystems, mirroring in some ways the Castorosaurus of the lowlands.

Only during mating season do two Ororhnychus form a mating pair in order to care for and protect their eggs. But after the hatchlings are grown up enough to leave the burrow and live on their own, the pairs break up again to live on their own. That said, long-term observation has revealed that former pairs are more likely to hook up again in subsequent seasons than complete strangers. This is intriguing and suggests that these animals, despite their primitive demeanour, do have some degree of personal long-term memory and can maybe even have favourite partners. This is further supported by the fact that Ororhynchus have been observed leaving their dung in very specific spots where others have defecated too, so-called communal latrines, which are usually located in a central area between multiple burrows. In many other animals which exhibit this behaviour, communal latrines are used as a sort of message board, the pheromones and other smells in the dung allowing the animals to communicate through time, informing each other about their presence, territory, health and mood. Despite being outwardly loners, these animals still seem to value keeping in touch with each other and so have amusingly been described as “long-distance social”.

Unlike the aptly named Armatosaurus it shares its habitat with, Ororhnychus lacks dermal armour and may therefore appear as an easy prey for predators. Though again, appearances may be deceiving, as the reptile has strong natural weapons instead of defenses. Its jaw, adapted for crushing and grinding hard plant matter, could easily break a human’s arms if given the chance. The tusk-like beak itself is also sharp like that of a huge snapping turtle and can also be used as a stabbing weapon. The approaching Lapidoscelis triceros, who seems to have wandered off from its usual lowland habitat, is about to find this out the hard way, if it does not back off.

This is another ancient relic, this time from the primordial coal swamps of the Carboniferous. Its differentiated teeth, especially the long incisors and dog-like skull shape are vaguely reminiscent of the synapsid predators which roam this island, but it is actually something even more primeval. What gives it away is the slit-ear, high on the skull placed inside an otic notch, a trait not found in amniotes. Like many other creatures on the island, it is an “anthracosaur” or anamniote, an “amphibian” close to the origin of reptiles and synapsids without yet being one itself. In many ways Lapidoscelis is remarkably similar to the ancient fossil Limnoscelis, to whom it is most likely closely related. The main differences are ornamental, such as the three bone crests atop the skull, giving it its species name, as well as the basilisk-like sail on its tail. Both of these are likely used for social display, especially the red-coloured nose-crest.

Despite being mainly a quadruped, the animal is intriguingly capable of rearing onto its hindlegs and even clumsily walking that way over short distances. Facultative bipedalism is a trait that is strangely shared by many anamniotes across the island, apparently having evolved separately on multiple occasions. The same convergent tendency towards increased bipedalism is also seen in many of the reptiles and synapsids, creating a whole array of creatures that look like pseudo-dinosaurs.

What evolutionary pressures drove all of these creatures to evolve varying degrees of bipedalism remains a mystery. One tentative hypothesis is that the original driver may have been the extensive wetlands of the island, forcing many animals to evolve strong tails and longer hindlegs than forelegs for paddling and swimming first. This then served as a pre-adaptation for bipedal wading through shallow, cluttered water (something indeed observed in incipient bipeds like Lapidoscelis), which in turn served as a pre-adaptation for bipedal walking on dry land. Outside of Ryl Madol, the same hypothesis has also been used to explain the convergent evolution of bipedalism in many Triassic archosaurs, including the dinosaurs. While this idea makes a lot of sense in the amphibious anamniotes, the hypothesis cannot explain each case. The lycaenoraptors for example seem to have never had an aquatic phase in their evolution, while the bolosaurs were already bipedal all the way back in the Paleozoic, presumably before arriving on Ryl Madol.

Aistoconstrictor

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There are no snakes on Ryl Madol. In their stead slither other, more ancient creatures through the underbrush. Most numerous among these legless vertebrates are aistopods, an ancient lineage of stegocephalians. These were the very first tetrapods to completely lose all of their limbs and in these primeval jungles they have further converged on the serpents that replaced them elsewhere in the world.

Largest among them is Aistoconstrictor latagnathus, which, it has been reported, can grow up to nine or ten metres long, larger than any anaconda. Most individuals are smaller though, usually maxing out at around six or seven metres. Despite technically being an amphibian (in the classic paraphyletic sense), Aistoconstrictor shares many characteristics with actual constricting snakes, such as boas. It kills and captures small prey, such as lystrodos, by biting their head and then ensnaring them with its body, crushing the poor victim under its weight.

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Looking at the skull we can see a combination of both old and new. Overall, the cranium still bears great resemblance to ancient aistopods such as Phlegethontia, with large orbits, large fenestrae and a light construction at the back of the skull that gives the jaw-joints a larger range of movement. Differing from ancient aistopods, the “aistoboids” evolved an extra jaw-joint in their lower jaw, allowing the dentary to articulate with the surangular bone. Like in constricting snakes this allows the predator to “shove” prey down its gullet with its teeth by moving the lower jaw back and forth. Unlike in snakes, the mandibles are still connected at the tips, so they cannot open as widely.

Click to enlarge. Life stages are not drawn to scale.

Being a stegocephalian, likely of the reptiliomorph variety, Aistoconstrictor develops from an aquatic larval stage. It does not raise its young on land in burrows like a giant caecilian, as older textbooks have often wrongly stated. After internal fertilization, the eggs are instead laid into a breeding pond, which the mother often guards until hatching, as some toads are known to do. Upon hatching, the larvae emerge as little eel-like creatures with surprisingly long external gills. At this stage they bear a great resemblance to the larvae of caecilians, though this is surely a coincidence. These aistoboid larvae feed on aquatic insects and algal scum before they grow in size and enter the next life stage, the “spade eel”, named after the shape of its snout. Its gills have shrunk and become covered by a soft skin-flap, while its swim-bladder has expanded into a simple lung, allowing it to breathe both in and out of water. The spade eel lives much like a predatory fish, feeding on many smaller vertebrates by use of ambush attacks. They are also surprisingly gregarious, often swimming in small swarms for protection. Unlike the sub-adult stages of some other Rylian reptiliomorphs, spade eels cannot become reproductively active and are always destined to grow into fully adult “aistoboids” once they lose their gills and live on land.

As a human can in some ways resemble other bipedal animals on Ryl Madol like the lystrodos or eubolosaurs, it may not come as a surprise that stalkers and other explorers are frequently attacked by Aistoconstrictor and relatives, whose coloration conceals it behind the underbrush or lianas. While the creatures are capable of killing people through constriction, human shoulders are usually too wide to fit through the jaws, so the beasts tend to give up after the head and just leave behind a mangled corpse for the scavengers.

Eurhinocaulus

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Eurhinocaulus is an amphibian predator that lurks in most rivers of Ryl Madol. It often lies at the bottom, sometimes even half-buried in the sand, its head facing against the current, where it lies in wait for prey. Once an unsuspecting fish or amphibian swims above it, it only has to raise its head slightly and the “headwings” supported by skin-membranes already create uplift in the current, dragging the animal upwards towards its victim. Quick slashes and strikes with the swordfish-like snout then incapacitate the surprised prey.

The exact classification of Eurhinocaulus remains ambiguous. Its name is based on its similarity to Permian Diplocaulus, with which it shares the headwings. The general assumption is that it indeed is some type of lepospondyl anamniote from the diplocaulid group. However, this morphology has evolved separate times among different tetrapods, especially among temnospondyls like Gerrothorax. Close study of the animal for further answers has proven difficult, as it is prone to slash with its sawblade-nose at any researcher trying to pick it up.