Function of edentulous rostrum s of a
Taniwhasaurus skull, with the
ophthalmic nerve (
ramus ophthalmicus) in red Russell (1967) first speculated the elongated rostrum was used to "stun" prey or defend against sharks, though provided no further explanation. This combat hypothesis was further elaborated in Lingham-Soliar's (1992) review of
Tylosaurus biomechanics. He observed that the internarial bar was unusually robust for a mosasaur, and sutured to the frontal with deep
interdigitations such that there is a large interfacial
shear area. This probably allowed for greater resistance to bending, shearing, and breaking forces though more effective shock absorption and stress transfer from a blunt force to the rostrum. and
orcas to attack prey. Lingham-Soliar (1998) would later suggest possible evidence of a ram-attack in action in the skull of a subadult
Mosasaurus whose braincase was fractured in life by a concentrated force, which he argued was rammed by a
T. bernardi due to lack of damage elsewhere in the skull that would indicate other causes of injury. This pattern was later found in preliminary CT scans of a
T. nepaeolicus skull by Paulina-Carabajal et al. (2023), which similarly observed profuse branching of the ophthalmic nerve inside the premaxilla exiting through many foramina on the dorsal tip of the rostrum. The high concentration of sensory nerves within the edentulous portion of the rostrum suggests that it housed a
mechanosensory or
electrosensory organ. Similar adaptations were previously found in plesiosaurs and ichthyosaurs. Several insights have been made nonetheless. Mosasaurs like
Tylosaurus likely
gave birth to live young. The youngest known
Tylosaurus individual (FHSM VP-14845) is a newborn (
neonate) estimated to have measured in skull length and in total length, about 17.2% the size of Bunker and 24.8–27.9% of the estimated maximum lengths for
T. nepaeolicus. The premaxilla of this specimen lacked an edentulous elongation of the rostrum; this trait already appears in juvenile specimens only slightly larger than FHSM VP-14845, including
T. nepaeolicus and
T. proriger specimens with estimated skull lengths of and respectively.
Metabolism Nearly all squamates are characterized by their cold-blooded
ectothermic metabolism, but mosasaurs like
Tylosaurus are unique in that they were likely
endothermic, or warm-blooded. The only other known lizard with such a trait is the
Argentine black and white tegu, though only partially. Endothermy in
Tylosaurus was demonstrated in a 2016 study by Harrell, Pérez‐Huerta, and Suarez by examining
δ18O isotopes in
Tylosaurus bones.
δ18O levels can be used to calculate the internal body temperature of animals, and by comparing such calculated temperatures between coexisting cold-blooded and warm-blooded animals, the type of metabolism can be inferred. The study used the body temperatures of the cold-blooded fish
Enchodus and sea turtle
Toxochelys (correlated with ocean temperatures) and warm-blooded seabird
Ichthyornis from the Mooreville Chalk as a proxy. Analyzing the isotope levels of eleven
Tylosaurus specimens an average internal body temperature of was calculated. This was much higher than the body temperature of
Enchodus and
Toxochelys ( and respectively) and similar to that of
Ichthyornis (). Harrell, Pérez‐Huerta, and Suarez also calculated the body temperatures of
Platecarpus and
Clidastes with similar numbers, and respectively. The fact that the other mosasaurs were much smaller in size than
Tylosaurus and yet maintained similar body temperatures made it unlikely that
Tylosauruss body temperature was the result of another metabolic type like
gigantothermy. Endothermy would have provided several advantages to
Tylosaurus such as increased stamina for foraging larger areas and pursuing prey, the ability to access colder waters, and better adaptation to withstand the gradual cooling of global temperatures during the Late Cretaceous. This is corroborated by a statistical reconstruction of the tail fin by Song and Lindgren (2025), which predicted an outline resembling those in carangiform sharks. A
BS thesis by Jesse Carpenter published in 2017 examined the vertebral mobility of
T. proriger spinal columns and found that the dorsal vertebrae were relatively rigid but the cervical, pygal, and caudal vertebrae were more liberal in movement, indicating flexibility in the neck, hip, and tail regions. This contrasted with more derived mosasaurs like
Plotosaurus, whose vertebral column was stiff up to the hip. Interestingly, an examination of a juvenile
T. proriger found that its cervical and dorsal vertebrae were much stiffer than those in adult specimens. This may have been an evolutionary adaptation among young individuals; a more rigid tail-based locomotion is associated with faster speed, and this would allow vulnerable juveniles to better escape predators or catch prey. Older individuals would see their spine grow in flexibility as predator evasion becomes less important for survival.
Feeding One of the largest marine carnivores of its time,
Tylosaurus was an
apex predator that exploited the wide variety of species in the marine fauna of its ecosystem. Stomach contents are well documented in the genus, which includes other mosasaurs, plesiosaurs, turtles, birds, bony fish, and sharks. Additional evidence from bite marks suggests the animal also preyed on giant squid and ammonites. The enormous and varied appetite of
Tylosaurus can be demonstrated in a 1987 find that identified fossils of a mosasaur measuring or longer, the diving bird
Hesperornis, a
Bananogmius fish, and possibly a shark all within the stomach of a single
T. proriger skeleton (SDSM 10439) recovered from the
Pierre Shale of South Dakota. Other records of stomach contents include a sea turtle in a
T. bernardi-like species, Puncture marks on fossils of ammonites, Garvey (2020) criticized the lack of conclusive evidence to support this hypothesis and ruled out
T. proriger as a possible culprit, given that the species did not appear until the Santonian and is exclusive to the Western Interior Seaway.
Social behavior The behavior of
Tylosaurus towards each other may have been mostly aggressive, evidenced by fossils with injuries inflicted by another of their own kind. Such remains were frequently reported by fossil hunters during the late 19th and early 20th centuries, but few examples reside as specimens in scientific collections. Many of these fossils consist of healed bite marks and wounds that are concentrated around or near the head region, implying that there were the result of non-lethal interaction, but the motives of such contact remain speculative. In 1993, Bruce M. Rothschild and Larry D. Martin noted that some modern lizards affectionately bite their mate's head during
courtship, which can sometimes result in injuries. Alternatively, they also observed that some males lizards also employ head-biting as territorial behavior against rivals in a show of dominance by grappling the head to turn over the other on its back. It is possible that
Tylosaurus behaved in similar ways. Carlsen (2017) posited that
Tylosaurus gained avascular necrosis because it lacked the necessary adaptations for deep or repetitive diving, although noted that the genus had well-developed eardrums that could protect themselves from rapid changes in pressure. Unnatural fusion of some vertebrae in the tail has been reported in some
Tylosaurus skeletons. A variation of these fusions may concentrate near the end of the tail to form a single mass of multiple fused vertebrae called a "club tail." Rothschild and Everhart (2015) surveyed 23 North American
Tylosaurus skeletons and one
T. bernardi skeleton and found that five of the North American skeletons exhibited fused tail vertebrae. The condition was not found in
T. bernardi, but this does not rule out its presence due to the low sample size. Vertebral fusion occurs when the bones
remodel themselves after damage from trauma or disease. However, the cause of such events can vary between individuals and/or remain hypothetical. One juvenile specimen with the club tail condition was found with a shark tooth embedded in the fusion, which confirms that at least some cases were caused by infections inflicted by predator attacks. The majority of vertebral fusion cases in
Tylosaurus were caused by bone infections, but some cases may have alternatively been caused by any type of
joint disease such as
arthritis. However, evidence of joint disease was rare in
Tylosaurus when compared to mosasaurs such as
Plioplatecarpus and
Clidastes. Similar amassing of remodeled bone is also documented in bone fractures in other body parts. One
T. kansasensis specimen possesses two fractured ribs that fully healed. Another
T. proriger skull shows a fractured snout, probably caused by ramming into a hard object such as a rock. Presence of some healing indicates that the individual survived for some extended time before death, albeit under extreme pain. ==Paleoecology==