Bite '' has the proportionally longest canines of any gorgonopsian. The elongated canines have generally been thought to have been instrumental in their hunting tactics. The gorgonopsian
jaw hinge was double jointed and made up of somewhat mobile and rotatable bones, which would have allowed them to open their mouths incredibly wide—perhaps in excess of 90°—without having to unhinge the jaw. It has alternatively been suggested (first in 2002 by biologists Blaire Van Valkenburgh and Tyson Secco, though in reference to cats) that sabres evolved primarily due to
sexual selection as a form of mating
display. This is exhibited in some modern deer species, but is difficult to test given the lack of living sabre-toothed synapsid predators. In sabre-toothed cats, long-sabred ("dirk-toothed") taxa are thought to have been
pursuit hunters, whereas short-toothed ("scimitar-toothed") taxa are thought to have been
ambush predators. Among the dirk-toothed cats, these predators are suggested to have killed with a well-placed slash to the throat after grappling prey, but gorgonopsians may have been less precise with bite placement, armed with reptilian jaws and tooth arrangements. Instead, gorgonopsians possibly used a bite-and-retreat tactic: the predator would ambush its quarry and take a sizable and debilitating bite out of it, and then follow as the prey tried to escape before succumbing to its injury, whereupon the gorgonopsian would deliver a killing bite. Because the postcanines are reduced or entirely absent, meat would have been forcibly torn away from the carcass and swallowed whole. Unlike mammalian carnivores, gorgonopsians (and therocephalians) had reduced or completely lacked postcanines, and the jaw likely could not exert shearing pressure necessary for crushing bones open to access the
bone marrow. It has largely been unclear if bone marrow had even evolved yet in Permian synapsids (fish and many amphibians lack this in present day), but in 2021 it was shown that the Early Permian amphibians
Seymouria and
Discosauriscus likely had
haematopoietic (red blood cell-producing) bone marrow in their limbs.
Locomotion '' walking with a sprawling gait Gorgonopsians are considered to have been strictly
terrestrial. They are thought to have been able to move with an erect gait similar to that used by crocodilians, the limbs positioned almost vertically as opposed to horizontally as in the sprawling gait of lizards. The
glenoid cavity on the shoulder blade is strongly angled tailwards, so the limbs had limited forward movement, and they may have had a short stride length. Lizards often move their spines side to side to increase stride length, but the more vertically orientated
facet joints connecting the vertebrae in gorgonopsians would have made the spine more rigid and stable, encumbering such movement. These adaptations may have made gorgonopsians swifter and more agile than their prey.
Senses '' with proportionally large
scleral rings Unlike eutheriodonts, but like some ectothermic creatures today, all gorgonopsians possessed a
pineal eye on the top of the head, which is used to detect daylight (and thus, the optimal temperature to be active). It is possible that other theriodonts lost this due to the evolution of either endothermy,
intrinsically photosensitive retinal ganglion cells in the eyes—in tandem with the loss of colour vision and a shift to nocturnal life—or both.
Nocturnal behaviour has long been assumed to have originated in mammals (
nocturnal bottleneck), but the large orbit size and presence of
scleral rings in many early synapsids, stretching as far back as the Carboniferous, would suggest that the ability to venture out in low-light conditions evolved much earlier. Based on these aspects, the specimen SAM-PK-K10034 may have had
mesopic vision, and
Cyonosaurus scotopic or
photopic vision. The diameters of the scleral rings for the small
Viatkogorgon are proportionally large, with an inner diameter of and outer diameter of , compared to a diameter of for the orbit itself, which suggests it made predominantly nocturnal excursions. Early theriodonts (including gorgonopsians) may have possessed an
eardrum, unlike earlier pelycosaurs, indicated by the reduction of the connection between the
quadrate bone (at the jaw hinge) and the
pterygoid bone (at the
palate), allowing the quadrate to independently vibrate to a degree. This may have allowed the detection of air-borne sounds with a low
amplitude of less than , but the eardrum would have been supported by
cartilage or
ligaments instead of bone. If correct, then the
postdentary bones (which in early mammals form the
middle ear bones) would have needed to become detached from the dentary (jawbone); the gorgonopsian fossil record seems to indicate the postdentary-dentary connection was reduced. Though, given the specialisations required for biting, the condition of an isolating quadrate in gorgonopsians could alternatively be explained as
streptostyly (rotatable quadrate) in order to widen the gape rather than facilitate hearing.
Thermoregulation A major anatomical shift occurred between earlier pelycosaurs and therapsids, which is postulated to have been related to an increasing
metabolism and the origins of
homeothermy (maintenance of a high body temperature). The evolution of a secondary palate, and the separation of the mouth from the nasal cavity, may have increased ventilation efficiency associated with high levels of
aerobic activity; gorgonopsians did not have a bony secondary palate, but possibly had one of soft tissue. Nonetheless, the secondary palate could have instead aided in eating large quantities of food at once rather than in ventilation. The reorganisation of the skeleton (from a sprawling to a parasagittal gait) has been postulated to be indicative of the presence of a
diaphragm, and thus also enhanced ventilation for aerobic activity; but it could have instead been to increase acceleration or agility, which does not necessarily equate to intense aerobic activity, much like in crocodiles. Fibrous lamellar cortical bone, which all early therapsids had, would indicate an increased growth rate, but this may not be linked to metabolic rate. Modern large reptiles naturally give off body heat at a slower rate than smaller ones, and are considered "inertial homeotherms", but they maintain a low body temperature of . If therapsids required a higher body temperature of , they would either have needed to have been
endotherms (generating their own body heat) or have had greater control over heat loss (that is, better homeothermy). The parasagittal gait may have aided the latter, as it would have kept most of the body off the ground as well as allowed blood to stay in the abdomen instead of having to circulate through the appendages, both of which would reduce heat transfer to the ground and stabilise
core temperature. The reduced tail would have also reduced the total surface area of the animal, further minimising heat loss. Among therapsids, only eutheriodonts (not gorgonopsians) have respiratory
nasal turbinates, which help retain moisture while breathing in large quantities of air, and its evolution is typically associated with the beginning of "mammalian" oxygen consumption rates and the origins of endothermy. If gorgonopsians were inertial homeotherms, it is not impossible that they had hair. The snout is typically riddled with
foramina (small holes which confer with blood vessels), which could potentially point to the existence of loose skin (as opposed to scales), hair, various
skin glands (such as
sweat glands), and
whiskers; however, some reptiles present a similar patterning of foramina, which are instead related to dental development rather than skin. Analysis on inner ear biomechanics found that gorgonopsians probably had a body temperature , suggesting the clade was
ectothermic.
Palaeopathology The anterolateral aspect of the left
radius (a forearm bone) of the gorgonopsian specimen NHCC LB396 presents a circular bony lesion, featuring irregular-to-
radial spikes made of cortical bone surrounded by a thin layer of
subperiosteal bone, which grew rapidly over a single growing season. This is consistent with
periostitis most likely stemming from subperiosteal
haematoma. This specific condition as well as the fast growth rate are more reminiscent of mammals and dinosaurs than crocodilians or
monitor lizards. Among early synapsids, the only other pathology noted is
osteomyelitis in several pelycosaur groups. The labial (lip/cheek) side of the tooth root of a functional canine of RB382 presents as many as 8 lesions, clustering along the midline of the tooth, which resemble miniature teeth with a
pulp,
dentine, and a thin
enamel coating. They are roughly circular—with diameters varying from —though they become less circular at around the middle point of the root until passing the
cervix of the tooth. This is roughly consistent with the human ailment
odontoma, the most frequent type of
odontogenic tumour, which previously only extended a few million years back in the fossil record. At 255 million years old, RB382 presents the oldest-known case of odontoma. The adult snout SAM-PK-11490 from an indeterminate Middle Permian gorgonopsian species has an imbedded tooth from an unidentifiable animal. The bone developed a callus around the tooth, indicating it healed and the individual survived the attack. It either came from a predator—namely a
biarmosuchian, a therocephalian, or another gorgonopsian—or intraspecific face biting as is commonly exhibited in social predators—such as big cats or monitor lizards, and it has been suggested for several extinct lineages such as theropods, aquatic reptiles, and saber-toothed cats. Social biting is intended to assert dominance or facilitate breeding, and, if correct, suggests at least some Middle Permian gorgonopsians were social carnivores. The tooth was initially overlooked so it is unclear how common this pathology actually is. ==Palaeoecology==