Following the extinction of non-avian dinosaurs, the largest Cainozoic continental predator was neither a Mammal nor a Bird, but the Giant Caiman Purussaurus. This animal exceeded 10 m long and inhabited South America during the middle and late Miocene (about 13–6 million years ago), when a system of wetlands flourished in northwestern Amazonia. Several lignitic localities of the Pebas Formation near the Peruvian city of Iquitos have yielded geological and palaeontological data regarding the life within this vast complex of lakes and swamps, named the Pebas Mega-Wetland System. The record includes a plethora of fossil evidence, among which Crocodylians showed notable disparity and diversity.
In October 2004, a mission to the Napo River discovered new lignitic Miocene bonebeds (about 13 million years ago), particularly near Iquitos City. The Na069 bonebed preserves dysoxic swamp deposits bearing a diverse aquatic and terrestrial Vertebrate assemblage, particularly rich in Fish, Turtle, Reptile and Mammal remains. Among them, a severely damaged tibia of a Mammal was discovered and collected by François Pujos of the Instituto Argentino de Nivología, Glaciología y Ciencias Ambientales. Preparation of the specimen revealed multiple bite marks that were inflicted prior to fossilisation.
In a paper published in the journal Biology Letters on 26 August 2020, François Pujos and Rodolfo Salas-Gismondi of the BioGeoCiencias Lab at the Universidad Peruana Cayetano Heredia, and the Departamento de Paleontología de Vertebrados at the Museo de Historia Natural-Universidad Nacional Mayor de San Marcos, describe and interpret the origin of the bite marks preserved on a 13-million-years-old Mammalian long bone. They point to the putative perpetrator of the attack and its victim and discuss this uncommon evidence of predator–prey interaction from proto-Amazonian times.
The left tibia (MUSM 1587) belongs to a middle-sized ground sloth (Xenarthra, Folivora), as indicated by the femoral facets, the medial being concave and the lateral being convex. The epiphyses are completely fused to the diaphysis, indicating that this specimen belonged to an adult individual. This tibia is attributed to the Mylodontid Sloth Pseudoprepotherium based on a robust diaphysis with concave lateral side and convex proximomedial side with a well-marked tuberosity; sharp intercondylar eminence; medial condyle anteroposteriorly extended; and odontoid and discoid facets strongly concave and subequal in size. Pseudoprepotherium was previously recognized in the middle Miocene of Colombia and late Miocene of Brazil and Venezuela. The body weight of the Sloth is estimated in 78.5 kg, equivalent to a large Capybara.
Forty-six tooth marks are identified on the shaft of the tibia. Highly tooth-marked bones probably represent grasping elements during capturing or dismembering. Five are large punctures that reached the trabecular bone, 36 are shallow pits and four are wide scores. Pits and punctures vary in diameter from 3 (#44) to 15 mm (#30). Most often they are round, but some are clearly bisected (e.g. #1, 5 and 30). Bisected pits and punctures are produced by carinated crown teeth of Crocodylians and are not recorded in bones modified by Mammals. Most of the tooth marks present on the anterior side of the tibia are relatively small and shallow pits. Large punctures are restricted to the posterior side. Some punctures (#30, 40 and ?45) and pits (#31, 34 and ?37) of the posterior surface comprise a0 serial marking (i.e. multiple marks inflicted by adjacent teeth in one bite) along the shaft. The serial marking was produced by a violent, powerful bite that simultaneously fractured and depressed large areas of the surrounding cortical bone. On the anterior surface, at least two serial pits (#1 and 5) are identified. The four scores represent only 8.9% of the total number of bite marks. Scavenging usually produces abundant scores and comparatively few scores are rare. They are flat-bottomed, roughly parallel between them and transverse to the main axis of the diaphysis. Parallel scores suggest grasping and dragging but also attempted disarticulation. Hook scores (i.e. parabolic depressions) were not observed. These particular marks are usually associated with dismemberment of the carcass by ‘death rolling’ or inertial feeding.
Thirteen million years ago, South America was an island continent; Placental Carnivorans has not yet reached its shores, and Borhyaenid Marsupials occupied niches of large carnivores. The bisected pits and punctures observed in the tibia does not match with the heterodont dentition of Borhyaenids. Instead, they are typical in bones dispatched by Crocodylians. In the lignitic bone beds of the Pebas Formation, up to seven sympatric Crocodylian taxa have been previously identified: the Blunt-snouted Caimanines Gnatusuchus pebasensis, Kuttanacaiman iquitosensis and Caiman wannlangstoni; the Smooth-fronted Caiman Paleosuchus sp.; the Gavialoid Gryposuchus pachakamue; and two large Caimanines, the ‘Duck-faced’ Mourasuchus atopus and the giant Purussaurus neivensis. The first three are characterised by a posterior crushing dentition suited to feeding on Clams, with Gnatusuchus additionally bearing a highly modified mandible and anterior dentition attributed to head-burrowing. Because the dentition of Kuttanacaiman and Caiman wannlangstoni is relatively close to that of living Caimans, they might had been able to feed upon a wider range of prey than Gnatusuchus. However, these Animals were far too small as adults (approximately 1.7–2.3 m) to inflict the large punctures documented in MUSM 1587. Paleosuchus sp. was also a Caiman of similar small size, but with gracile, sharply pointed teeth that instead would have produced minute and narrow scores, shown to be absent. Gryposuchus pachakamue, as typically in gavialoids, possesses a long and slender snout with sharp teeth and probably fed upon small and rapid prey. Mourasuchus atopus had a long, flat and wide rostrum and bore multiple thin teeth that progressively decrease in size towards the back of the mouth. Mourasuchus was a relatively large animal (approximately 4–5 m) but probably fed upon small organisms by any kind of filtering strategy. Finally, the feeding anatomy of Purussaurus neivensis, the top predator of the Pebas System, is consistent with the bite marks observed in the tibia.
Purussaurus possesses a broad, massive skull and robust jaws, typical in Crocodylians of the macro-generalist ecomorph. The dentition comprises large, conical anterior teeth particularly at the symphyseal jaw, and small, blunt to globular teeth posterior to the sixth alveoli in the dentaries and the maxillae. Conical teeth are circular to oval in cross-section and the tip of the crown is blunt. Distinct mesial and distal carinae are present in all teeth but the carinae are attenuated at the tip. In correspondence with the conical and blunt teeth of Purussaurus, pits in the tibia are round and relatively shallow. The attenuation of the carinae toward the crown apex is revealed by the absence of marks with sharp borders and the few bisected pits and punctures.
Based on the largest and deepest puncture (#30: 15 mm) and the distance between pits and punctures of the serial marking (27–32 mm), Pujos and Salas-Gismondi estimated the body length of the perpetrator. These tooth marks roughly match with the anterior dentition of individuals of approximately 50–60 cm of dorsal skull length, slightly larger than IGM DHL45, a skull of a young Purussaurus neivensis. This individual is equivalent in size to an adult Black Caiman, Melanosuchus niger (e.g. MUSM CR). For the dorsal skull length of IGM DHL45, the estimated total body length is approximately 3.86 m. A fully grown Purussaurus neivensis (e.g. UCMP 39704) provides much larger dentition measures and might have reached approximately 6.18 m of body length. Thus, the attack was most likely perpetrated by an approximately 4 m long young or sub-adult Purussaurus.
Neontological and palaeontological data have shown that large to giant crocodyliforms (approximately 3–10 m) have a wide range of prey, such as Invertebrates, Fish, Mammals (including Hominids) and even Dinosaurs. Regarding Purussaurus, previous evidence attributed to its feeding behaviour is based on a large shell of the aquatic Turtle Podocnemis (late Miocene, Peruvian Amazonia) bearing a huge bite of approximately 60 cm. As a result of this attack, the Turtle lost several peripheral and pleural bones of the posterior left side of the carapace, and presumably, the corresponding hind limb was amputated. Bone regeneration lining the bite is testament that the victim survived and healed. The sinuosity observed along the healed margin suggests that the bite marks were inflicted by serial teeth. Both the carapace bone thickness at this region reaching approximately 15 mm and the size of the bite out imply a giant perpetrator, possibly as big as an adult size of Purussaurus brasiliensis (greater than 10 m in total length). It seems to be that Giant Crocodylians with broad snouts and robust, blunt teeth, such as Purussaurus and the North American Cretaceous Alligatoroid Deinosuchus, commonly prey on large Turtles at adulthood.
The toothed-marked tibia of the Ground Sloth reveals that Purussaurus also fed upon terrestrial Mammals within the proto-Amazonian swamps. In 2004, lignite and coquina localities at Napo River yielded numerous Fish and aquatic Turtle remains along with teeth and bones of Rodents and Ground Sloths. These lignite deposits depict dysoxic and shallow wetlands, where lurking Crocodylians were abundant and terrestrial Mammals were ambushed or scavenged. Beside Ground Sloths and Rodents, a wide array of native Ungulates (i.e. Astrapotheres, Notoungulates, Litopterns) documented with Purussaurus species in Miocene localities might have represented prey items for large to giant individuals.
If living Crocodylian species show substantial changes in bite force and diet throughout their ontogeny, it is reasonable to think that the notable increase in the bite force during the development of giant, extinct species have driven extreme shifts in feeding behaviour. Bite forces recorded from the developmental series of Alligator mississippiensis range from 12 to 9452 N (about 1 ton-force), almost 800-fold increase from hatchling to a total body length of 3.71 m. This increase in bite force is accompanied by other anatomical changes and reflects the transition from eating Insects, Spiders and small Vertebrates to large Mammals and Turtles. Because bite force does not differ significantly across same-sized Brevirostrine taxa (Alligatoroids and Crocodyloids), Purussaurus, Alligator and Crocodylus individuals of similar size might be capable of chasing comparable prey items. Thus, a young Purussaurus, of about 3.5–4 m of body length, feeding upon Ground Sloths (around the size of a Capybara) might have been predicted by this conservative bite-force scaling hypothesis.
Instead, adult size Purussaurus species have no ecological analogues in the living world. The bite force of a giant individual of Purussaurus brasiliensis have been estimated in 69 039.2 N (approximately 7 tons-force), a value that largely exceeds that of the strongest bite ever measured in the Animal kingdom (i.e. 16 143 N in Crocodylus porosus). With this powerful bite and a macro-generalist morphotype, giant individuals were able to incorporate into their diet larger and solidly shielded prey items (e.g. giant Mammals and large Turtles).
Purussaurus neivensis was the only Caiman of high trophic level found in the rich bonebeds of the Pebas Formation. Bite marks in the tibia are consistent with the blunt-tipped, carinated and robust crown teeth of a juvenile to sub-adult Purussaurus. The tibia of the Pseudoprepotherium was trapped by the anterior upper and lower teeth during a powerful bite that fractured and depressed large portions of cortical bone. The presence of few scores is unusual in bones altered during scavenging, yet our understanding on scavenging versus predation mark patterning is still insufficient or controversial to distinguish between these sources of toothmarking. Predation is here favoured because the Ground Sloth is largely within the expected prey size of the macro-generalist ecomorph of Purussaurus. In present day Africa when a large Nile Crocodile attacks a Wildebeest or a Zebra from the river, it tends to direct its attack to the neck or the hind limbs before dragging its prey into the water. In Miocene proto-Amazonian wetlands, whereas giant individuals fed upon massive Mammals and Turtles, an immature Purussaurus gripped a Capybara-sized Ground Sloth from the lower hind limb.
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