Saber-toothed predator

[[File:Saber tooth 2.jpg|thumb|

Gallery of a variety of sabertoothed predators. Top left: Inostrancevia (Gorgonopsia), Top right: Hoplophoneus (Nimravidae), Centre left: Barbourofelis (Barbourofelinae), Centre right: Smilodon (Machairodontinae), Bottom left: Machaeroides (Oxyaenidae) Bottom right: Thylacosmilus (Sparassodonta)]]

A saber-tooth (alternatively spelled sabre-tooth) is any member of various extinct groups of predatory therapsids, predominantly carnivoran mammals, that are characterized by long, curved saber-shaped canine teeth which protruded from the mouth when closed.

Among the earliest animals that can be described as "sabertooths" were groups non-mammalian therapsids known as the gorgonopsians and basal therocephalians (lycosuchids and scylacisaurids). Among those three lineages, gorgonopsians were the oldest, potentially evolving during Kungurian or Artinskian stages of the Early Permian. One of the best-known genera is the "saber-toothed cat" Smilodon, the species of which, especially S. fatalis, are popularly referred to as "saber-toothed tigers", although they are not closely related to tigers (Panthera), and are instead members of the extinct cat subfamily Machairodontinae (the true saber-toothed cats), most members of which had saber-teeth of varying lengths.

Despite some similarities, not all mammalian saber-tooths were closely related to saber-toothed cats or felids in-general. For example, many members are classified into different family of Feliformia, the Nimravidae; or from a separate order such as Machaeroides and Apataelurus, which are members of the order Oxyaenodonta, and one extinct lineage of metatherian mammals (related to marsupials), represented by the thylacosmilids of the order Sparassodonta. In this regard, these saber-toothed mammals can be viewed as examples of convergent evolution. This convergence is remarkable due not only to the development of elongated canines, but also a suite of other characteristics, such as a wide gape and bulky forelimbs, which is so consistent that it has been termed the "saber-tooth suite."

Among the feliform sabertooth lineages, the family Nimravidae is the oldest, with the oldest fossils dated to 42 Ma of the Eocene. Some sabertooth predators have been known to have lived in the same habitats as seen with basal therocephalians and gorgonopsians in Middle-Late Permian,

Evolution

The different groups of saber-toothed predators evolved their saber-toothed characteristics entirely independently. They are most known for having maxillary canines which extended down from the mouth when the mouth was closed.

left|thumb|DA21/17-01-01, a [[Gorgonopsia|gorgonopsian specimen from the Permian Port des Canonge Formation of Mallorca, currently the oldest known member of the clade ]]

The first saber-tooths to appear were non-mammalian synapsids, the gorgonopsians; they were one of the first groups of animals within Synapsida to experience the specialization of saber teeth, and many had long canines.

The second and third instances of sabertooth predators were presented by basal therocephalians (scylacosaurids and lycosuchids). The oldest known scylacosaurids, Ictidosaurus and Glanosuchus, were found in the Eodicynodon Assemblage Zone, which dates to the Wordian stage. While earliest lycosuchid fossils were found in the Tapinocephalus Assemblage Zone of the Capitanian stage of the Middle Permian,

Gorgonopsians were subordinate to the dinocephalians and basal therocephalians, However, all dinocephalians and most basal therocephalians would later go extinct during the primary phase of the Capitanian mass extinction event, which may have been caused by volcanism that originated from the Emeishan Traps. While some basal therocephalians, such as Lycosuchus and Glanosuchus, survived the primary phase, they would later go extinct during the secondary wave of extinction.

During Wuchiapingian-Changhsingian stages of the Late Permian, many gorgonopsians began to go extinct in Africa and Eastern Europe. The cause of the gorgonopsians extinction in Eastern Europe was the inability to adapt to the changing temperature and humidity and were replaced by archosauriforms and large therocephalians. In Africa, majority of the large-bodied rubidgeines died out early in the Daptocephalus Assemblage Zone. Rubidgea, the last rubidgeine, went extinct during a turnover event that separates the lower and upper subzones, being replaced by Inostrancevia. The extinction of the gorgonopsians marked the start of the sabertooth hiatus that lasted for 200 million years.

thumb|Skull of [[Machaeroides|Machaeroides eothen, one of the most basal machaeroidines]]

The fourth instance of saber-teeth is from machaeroidines of the extinct order Oxyaenodonta. The earliest known machaeroidine was Machaeroides simpsoni, which first appeared in the Early Eocene. The last macheroidines died out in the middle Eocene, which was linked to the significant faunal overturn during the transition period between the middle and late Eocene. Some experts hypothesized that their extinction was the result of competition with nimravids, as the excellent North American fossil record indicates oxyaenids were declining before the appearance of the replacement taxa such as nimravids.

Instead, their extinction was likely due to the changing climate. The oldest known nimravid was found in the Lushi and Dongjun formations of China, which dated to the middle Eocene. The next oldest nimravid was Maofelis middle of the Eocene epoch, about 41.03 Ma. The earliest record of nimravids in North America was represented by Pangurban, which first appeared around 40 Ma. Nimravids made their first appearance in Europe during the early Oligocene following the Grand Coupre. Nimravids also saw their greatest diversity during the early Oligocene with 13 contemporary species. The extinction of North American nimravids started the infamous cat gap, a 7 million year period when no cat-like predators were present in North America. Barbourofelines probably evolved from Nimravinae dispersing into Africa during the early Miocene. The presence of large hyaenodonts prevented them from reaching a large size but were able to carve a niche due to their dental morphology. Eventually, they dispersed from Africa into Eurasia around 18 Ma and later North America around 12 Ma.

The arrival of barbourofelines in North America was thought to have placed a role in the decline and extinction of hesperocyonines. Over course of the Late Miocene, barbourofelines declined in diversity, going extinct in Europe and East Asia around 9.1 and 8.5 Ma respectively. Some experts hypothesized the cause of their extinction was the result of competition with machairodonts. although a suspected origin within the Eocene-Oligocene boundary has been hypothesized for the family. The last member of the family, Thylacosmilus, went extinct during the Pliocene, around 3 Ma. Originally, it was hypothesized that Thylacosmilus was outcompeted by carnivorans such as Smilodon. Although more recent evidence found no evidence of temporal or niche overlap between the two predators, instead extinction of Thylacosmilus and other sparassodonts was the result of the environmental changes. Machairodonts probably evolved from the basal felid Pseudaelurus quadridentatus showed a trend towards elongated upper canines, and is believed to be at the base of the machairodontine evolution. The earliest known machairodont was Miomachairodus from the late Middle Miocene. The earliest known homothere, Machairodus, first appeared in the fossil record around 12 Ma in Africa, before appearing in Europe around 10.4 Ma. The genus would later evolve into Amphimachairodus, which evolved around 9.8 Ma in East Asia. It would later make an appearance in Europe during the early Turolian replacing Machairodus. It would also disperse into North America during the Hemphillian stage, with the oldest fossils being found in Withlacoochee River 4A of Florida. Amphimachairodus was initially rarer than Nimravides, another homothere part of distinct linage, however it would later replace it as grasslands began to expand in North America. The genus is also noted to have a pan-African distribution, and may have been the ancestor of Homotherium. The earliest Homotherium fossils were found in Africa roughly 4.35 Ma, with the earliest Eurasian fossils dating to 4.2 Ma. The genus would make its first appearance in North America during the Late Pliocene between 3.6 and 2.6 Ma. A homothere, which has been attributed to Xenosmilus or Homotherium, were found in South America dating from the Early to Middle Pleistocene, roughly 1.0-0.5 Ma.

Smilodontin first appeared in the Late Miocene with Promegantereon being the oldest known genus of the tribe, it would later be replaced by Paramachaerodus during the Turolian.' Megantereon was another member of the tribe, with the oldest possible fossils associated to the genus being found in the Late Miocene Africa around 7 Ma. The oldest confirmed fossils of Megantereon were found in Kenya, dating to the Late Pliocene roughly 3.5-3.0 Ma, with possible older records dating to the Early Pliocene. In Eurasia, the oldest confirmed fossils were found in the Les Etouaries (France), which has been dated to 2.78 Ma. Smilodon first appears in South America during the Ensenadan stage of the Early Pleistocene.

Machairodonts began to decline during Late Miocene, with the decline of North American machairodonts coinciding with the decline of horses. This decline would persist into the Pleistocene, This has been contested by some experts, which argued that the expansion of grasslands and loss of forest covers were more detrimental to the large carnivorans as well the decline of megaherbivores. Additionally, evidence for anthropogenic extinctions by pre-erectus hominins to have been inconclusive, as it would suggest australopiths and early Homo were stealing prey from large carnivorans long before visible archaeological or anatomical evidence of carnivory among hominins. However, this contradicts zooarcheological evidence that suggests by 2.6 Ma, homininins were targeting medium sized prey, which has a larger impact on larger carnivores compared to smaller carnivores. Due to their specialization on consuming flesh, megapredators were more vulnerable to ancient anthropogenic extinctions. Additionally, there's little evidence of megapredators relying on megaherbivores.

In Europe, the extinction of Megantereon coincided with the expansion of grasslands, while Homotherium went extinct because of competition with early humans and Panthera fossilis. Homotherium and Smilodon were the last known members of the subfamily by the Late Pleistocene. The youngest Homotherium fossil was recovered in Alberta, Canada, and was dated to 12,715–12,655 years before the present. On the other hand, the youngest Smilodon fatalis fossil was recovered in the La Brea and was dated to 13,000 years ago. The extinction of Homotherium and Smilodon fatalis was contemporary with the wave of extinctions of most large animals across the Americas. The last known sabertooth predator was Smilodon populator, which was able to persist into the early Holocene, with the youngest fossils from the Jirau Paleontological Site being dated to 8,189–9,079 years before the present, likely going extinct because of the combination of climatic changes and human activity.

File:Rubidgea.JPG|1st saber-tooth instance: Gorgonopsia (Theriodontia, Therapsida, Sphenacodontia) – Rubidgea atrox skull

File:Specimens of Glanosuchus from above.jpg|2nd saber-tooth instance: Scylacosauridae (Scylacosauria, Therocephalia, Eutheriodontia) – Glanosuchus skull

File:Lycosuchus.jpg|3rd saber-tooth instance: Lycosuchidae (Therocephalia, Eutheriodontia, Theriodontia) – Lycosuchus skull

File:Machaeroides eothen.JPG|4th saber-tooth instance: Machaeroidinae (Oxyaenidae, Oxyaenodonta) – Machaeroides skull

File:Barbourofelis fricki.JPG|5th saber-tooth instance: Nimravidae (Feliformia, Carnivora) – Barbourofelis fricki skull

File:Thylacosmilus Atrox.jpg|6th saber-tooth instance: Thylacosmilidae (Borhyaenoidea, Sparassodonta) – Thylacosmilus atrox skull

File:Smilodon head.jpg|7th saber-tooth instance: Machairodontinae (Felidae, Feliformia, Carnivora) – Smilodon skull and upper cervical vertebrae

</gallery>

Morphology

Size

thumb|Size comparison of multiple sabertooth predators

Sabertooth predators vary widely in size, with some of the smallest known sabertooth predators, such as Eofelis edwardsii, Eusmilus cerebralis, and Lycaenops omatus, only being about the size of a bobcat or medium sized dog.

But many sabertooth predators have been noted to have reached larger sizes. Thylacosmilids were some of the largest metatherian predators with the smallest genus, Anachlysictis, weighing between . Thylacosmilus was the largest known thylacosmilid, standing at the shoulders and weighing based on various regressions. Among machairodonts, Smilodon fatalis was estimated to have stood at the shoulders and weighed , while Homotherium stood at the shoulders and weighed . Barbourofelis fricki, the largest known nimravid, was hypothesized to been a lion-sized predator, standing at the shoulders and weighing . <sup>Including supplementary materials</sup>

One of the largest gorgonopsians, Inostrancevia latifrons is estimated to have measured in length and could've weighed . The largest machairodonts were of some of the largest known felids. Smilodon populator was estimated to have stood at the shoulders and typically weighed . In addition, the largest species within the genus, Amphimachairodus kabir, was estimated to have weighed .

Paleobiology

left|thumb|Restoration of two [[Inostrancevia latifrons chasing a Scutosaurus]]

Diet

All sabertooth predators are hypercarnivores with their dentition specialized for only consuming flesh and lost the ability to consume other items such as plants and bone. Large gorgonopsians, such as Inostrancevia, were thought to have hunted large contemporary tetrapods, such as dicynodonts and pareiasaurs. Due to the robustness of its forelimbs, it was hypothesized that Barbourofelis loverum could've hunted prey larger than itself, such as Teleoceras and Gomphotherium. Based on regressions, it has been hypothesized that a Smilodon populator was capable of taking on prey up to , with a pack potentially being capable of taking down fully grown megaherbivores such as Megatherium and Notiomastodon.

Isotopic analysis has been done on multiple sabertooth predators, which have recovered their preferred prey. Within the Quehué and Salinas Grandes de Hidalgo localities, Thylacosmilus preyed upon grazers, such notoungulates in C3 open areas, The Turkana Basin of Kenya also found evidence of machairodonts hunting in different habitats. Megantereon hunted in woody habitats and focused on prey weighing ; which included the antelopes Aepyceros, Antidorcas recki, Megalotragus, Kobus sigmoidalis and Tragelaphus, the swines Kolpochoerus limnetes and Metridiochoerus andrewsi, and the three-toed equine Eurygnathohippus ethiopicum. On the other, Homotherium hunted in open habitats focusing on prey weighing ; which included antelopes such as Megalotragus, Kobus sigmoidalis, and Tragelaphus, swines Kolpochoerus limnetes, Nyanzachoerus kanamensis, and Metridiochoerus andrewsi, the three-toed equine Eurygnathohippus ethiopicum, and the extinct giraffe Giraffa pygmaea.

Predatory behavior

It was initially hypothesized that sabertooth predators were more adapted for hunting relatively larger prey, including megaherbivores. However, this hypothesis has been questioned by experts. Andersson et al. (2011) found that for saber-tooth cats, the depth of the killing bite decreases dramatically with increasing prey size. The extended gape of saber-toothed cats results in a considerable increase in bite depth when biting into prey with a radius of less than 10 cm. For the saber-tooth, this size-reversed functional advantage suggests predation on species within a similar size range to those attacked by present-day carnivorans, rather than megaherbivores as previously believed.

Antón (2013) pointed out that the prey of the large gorgonopsians were smaller than them, not ten times larger. Additionally, given their large sizes, they weren't the most abundant potential prey in most of their ecosystems. In comparison, medium-sized prey, such as ungulates (e.g. bovids and horses), were more plentiful and were the more ideal prey for sabertooth predators. Large cats use both the upper and lower jaw to bite down and bring down the prey. The strong bite of the jaw is accredited to the strong temporalis muscle that attach from the skull to the coronoid process of the jaw. The larger the coronoid process, the larger the muscle that attaches there, so the stronger the bite. As C.K. Brain points out, the saber-toothed cats had a greatly reduced coronoid process and therefore a disadvantageously weak bite. The cat did, however, have an enlarged mastoid process, a muscle attachment at the base of the skull, which attaches to neck muscles. According to C.K. Brain, the saber-tooth would use a "downward thrust of the head, powered by the neck muscles" to drive the large upper canines into the prey. This technique was "more efficient than those of true cats". note that it took around 8 million years for a new type of saber-toothed cat to fill the niche of an extinct predecessor in a similar ecological role; this has happened at least four times with different families of animals developing this adaptation. Although the adaptation of the saber-like canines made these creatures successful, it seems that the shift to obligate carnivorism, along with co-evolution with large prey animals, led the saber-toothed cats of each time period to extinction. As per Van Valkenburgh, the adaptations that made saber-toothed cats successful also made the creatures vulnerable to extinction. In her example, trends toward an increase in size, along with greater specialization, acted as a "macro-evolutionary ratchet": when large prey became scarce or extinct, these creatures would be unable to adapt to smaller prey or consume other sources of food, and would be unable to reduce their size so as to need less food.

More recently, it has been suggested that Thylacosmilus differed radically from its placental counterparts in possessing differently shaped canines and lacking incisors. This suggests that it was not ecologically analogous to other saber-teeth and possibly an entrail specialist. Another study has found that other saber toothed species similarly had diverse lifestyles and that superficial anatomical similarities obscure them.

A gorgonopsian, comparable to Eriphostoma microdon in size, showed signs of a healed bite mark with an embedded tooth in its snout. Based on mammalian healing capabilities, the specimen was bitten 2-9 weeks before its death. The absence of a drainage channel for pus or any other trace of infection suggests the bite wasn't the cause of death. Experts hypothesized it was an example of social biting, meant to signal dominance and power within the hierarchy. Machairodonts, such as Megantereon and Promegantereon, were thought to have been solitary predators. In the case of Promegantereon, it was due to the lack of cubs found in the predator traps. However, given its level of sexual dimorphism, adults had a higher degree of tolerance for one another and young adults would've inhabited their mothers' territory after maturing. However, some experts have questioned the evidence of Smilodon being gregarious. Kiffner (2009) questioned Carbone et al. (2009) as their analysis other factors such as body mass (heavier animals are more likely to get stuck than lighter ones), intelligence (some social animals, like the American lion, may have avoided the tar because they were better able to recognize the hazard), lack of visual and olfactory lures, the type of audio lure, and the length of the distress calls (the actual distress calls of the trapped prey animals would have lasted longer than the calls used in the study). Additionally, solitary felids, such as tigers and cougars, been known to aggregate around carcasses.

Pathological analysis has also been used as evidence to support gregariousness in Smilodon, although experts have questioned this as cats can recover quickly from even severe bone damage and an injured Smilodon could survive if it had access to water. Additionally, a Smilodon specimen was suffering from hip dysplasia at a young age but managed survived to adulthood. This suggests that it could not have survived to adulthood without aid from a social group, as this individual was unable to hunt or defend its territory due to the severity of its congenital issue. Two Smilodon populator skulls from Argentina show seemingly fatal, unhealed wounds which appear to have been caused by the canines of another Smilodon (though it cannot be ruled out they were caused by kicking prey). If caused by intraspecific fighting, it may also indicate that they had social behavior which could lead to death, as seen in some modern felines (as well as indicating that the canines could penetrate bone).

thumb|A pair of [[Amphimachairodus hezhengensis confronting a pair of Dinocrocuta gigantea]]

Amphimachairodus hezhengensis was believed to have been gregarious due to its adaptation of living in open environments such as stereo vision, which would've aided in prey identification and cooperative hunting. Additionally, evidence of healed pathological forepaw suggests evidence of partner care, and the abundant of large carnivorans present in Linxia Basin, which likely prove the rapid morphological evolution and gregariousness. Pathological analysis also found that Machairodus aphanistus was likely gregarious due to specimens surviving severe injuries such as a broken jaw. Solitary felids with high levels of sexual dimorphism such as leopards typically die before severe injuries managed to heal, being unable to hunt for themselves or sustain themselves on carrion long-term. Lions, however, have a greater chance of survival, due to living in prides. Considering the high levels of sexual dimorphism in this species of Machairodus, this would likely indicate higher levels of intolerance to other individuals within their territory. This would suggest males likely formed coalitions of two or three individuals, while females were solitary predators. Homotherium was thought to have been a gregarious animal based on its anatomy, as well as fossil and genetic evidence.

Phylogeny of feliform saber-tooths

The following cladogram shows the relationships between the feliform saber-tooths, including the Nimravidae, Barbourofelidae and Machairodontinae. Saber-toothed groups are marked with background colors.

Saber-tooth genera

{| class="sortable wikitable"

! Genus Name !! Species !! Appeared<br />(Ma BP) !! Died out<br />(Ma BP) !! Regions !! Canine size

| Smilodon

| style="text-align:center;"| 3

|align="right"|

|align="right"| 0.0082

| North and South America

| style="text-align:center;"|17–30 cm

| Hoplophoneus

| style="text-align:center;"| 3

|align="right"| 35.7

|align="right"| 30.5

| North America and Asia

| Eusmilus

| style="text-align:center;"| 6

|align="right"| 34.7

|align="right"| 29.5

| Eurasia and North America

| Dinictis

| style="text-align:center;"| 1

|align="right"| 35.7

|align="right"| 29.5

| North America

| Dinaelurus

| style="text-align:center;"| 1

| style="text-align:center;"| 32.6

| style="text-align:center;"| 27.2

| North America

| Dinailurictis

| style="text-align:center;"| 1

| style="text-align:center;"| 32.6

| style="text-align:center;"| 27.2

| Europe

| Eofelis

| style="text-align:center;"| 2

| style="text-align:center;"| ?

| ?

| Nimravides

| style="text-align:center;"| 3

| style="text-align:center;"| 11

| style="text-align:center;"| 6.5

| North America

| Nimravus

| style="text-align:center;"| 6

|align="right"| 35.3

|align="right"| 27.1

| Eurasia and North America

| Pogonodon

| style="text-align:center;" | 2

| align="right" | 32

| align="right" | 25.9

| North America

| Quercylurus

| style="text-align:center;" | 1

| style="text-align:center;" | 28.8

| style="text-align:center;" | 27.2

| Europe

| Albanosmilus

| style="text-align:center;" | 2

| align="right" | 12

| align="right" | 7

| Eurasia and North America

| Afrosmilus

| style="text-align:center;" | 3

| align="right" | 17.8

| align="right" | 16

| Africa and Europe

| Barbourofelis

| style="text-align:center;" | 5

| align="right" | 12

| align="right" | 7

| Eurasia and North America

| Ginsburgsmilus

| style="text-align:center;" | 1

| align="right" | 20

| align="right" | 19

| Africa

| Prosansanosmilus

| style="text-align:center;" | 2

| align="right" | 18

| align="right" | 15.97

| Eurasia and Africa

| Sansanosmilus

| style="text-align:center;" | 3

| align="right" | 16

| align="right" | 11.4

| Eurasia and Africa

| Syrtosmilus

| style="text-align:center;"| 1

|align="right"| 23

|align="right"|

| Africa

| Vampyrictis

| style="text-align:center;"| 1

|align="right"| 15

|align="right"|

| Eurasia and Africa

| Vishnusmilus

| style="text-align:center;"| 1

| style="text-align:center;"| ?

| ?

| Homotherium

| style="text-align:center;"| 3

|align="right"| 4.

|align="right"| 0.01

| Eurasia, Africa, North America, South America

| Thylacosmilus

| style="text-align:center;"| 1

|align="right"| 9

|align="right"| 3

| South America

| style="text-align:center;"| over 30 cm

| Metailurus

| style="text-align:center;"| 5

|align="right"| 8.7

|align="right"|

| Eurasia

| Adelphailurus

| style="text-align:center;"| 1

|align="right"| 23

|align="right"|

| North America

| Paramachairodus

| style="text-align:center;"| 3

|align="right"| 20–15

|align="right"|

| Europe

| Machairodus

| style="text-align:center;"| 4

|align="right"| 12.5

|align="right"| 8.7

| Eurasia, Africa, North America

| Miomachairodus

| style="text-align:center;"| 1

| style="text-align:center;"| 13.65

| style="text-align:center;"| 5.33

| Eurasia, Africa, North America

| Amphimachairodus

| style="text-align:center;"| 6-8

| style="text-align:center;"| 9.8

| style="text-align:center;"| 4.4

| Eurasia, North Africa, North America

| Hemimachairodus

| style="text-align:center;"| 1

| style="text-align:center;"| Pleistocene

| Java

| Lokotunjailurus

| style="text-align:center;"| 1

| style="text-align:center;"| late Miocene

| Africa

| Megantereon

| style="text-align:center;"| 2-7

|align="right"| 7

|align="right"| 0.4

| Eurasia, Africa, North America

| Dinofelis

| style="text-align:center;"| 6

|align="right"|

| Eurasia, Africa, North America

| Therailurus

| style="text-align:center;"| 1

|align="right"|

| Eurasia, Africa, North America

| Pontosmilus

| style="text-align:center;"| 4

|align="right"| 20

|align="right"|

| Eurasia

| Proailurus

| style="text-align:center;"| 2

|align="right"| 30

|align="right"| 20

| Europe and North America

| Xenosmilus

| style="text-align:center;" | 1

| align="right" | 2

| align="right" |

| North America

| Stenailurus

| style="text-align:center;"| 1

| style="text-align:center;"| ?

| ?

| Epimachairodus

| style="text-align:center;"| 1

| style="text-align:center;"| ?

| ?

| Hemimachairodus

| style="text-align:center;"| 1

| style="text-align:center;"| ?

| ?

</div>

Saber-tooth taxonomy

All saber-toothed mammals lived between 33.7 million and 9,000 years ago, but the evolutionary lines that led to the various saber-tooth genera started to diverge much earlier. It is thus a polyphyletic grouping.

The lineage that led to Thylacosmilus was the first to split off, in the late Cretaceous. It is a metatherian, and thus more closely related to kangaroos and opossums than the felines. Followed by Oxyaenids, and then the nimravids, before the diversification of the truly feline saber-tooths.

Clade Therapsida
Clade: †Gorgonopsia
†Inostrancevia
†Smilesaurus
Class: Mammalia
Clade: Metatheria (diverged ?, in the Cretaceous)
Order: †Sparassodonta (an extinct group of metatherian carnivores)
Family: †Thylacosmilidae
†Patagosmilus
†Anachlysictis
†Thylacosmilus
Subclass: Placentalia
Order: †Oxyaenodonta
Family: †Oxyaenidae
Subfamily: †Machaeroidinae
Genus: †Apataelurus
Genus: †Machaeroides
Order Carnivora
Suborder Feliformia ('cat-like' carnivores)
Family †Nimravidae (diverged from the feliforms 48–55 Ma BP, in the late Eocene)
Subfamily †Nimravinae (Dinictis)
Subfamily †Hoplophoninae
Subfamily †Barbourofelinae
Family Felidae (true cats)
Subfamily †Machairodontinae (true saber-toothed cats)
Tribe †Homotherini
Tribe †Metailurini
Tribe †Smilodontini

</div>

References

External links

Saber-toothed Cats at the Illinois State Museum
Saber-toothed Cats at the UC Berkeley Museum of Paleontology
Prehistoric cats and prehistoric cat-like creatures

Saber-toothed predator

Evolution

Morphology

Size

Paleobiology

Diet

Predatory behavior

Phylogeny of feliform saber-tooths

Saber-tooth genera

Saber-tooth taxonomy

References

Further reading

External links

See also

Evolution

Morphology

Size

Paleobiology

Diet

Predatory behavior

Social behavior

Phylogeny of feliform saber-tooths

Saber-tooth genera

Saber-tooth taxonomy

References

Further reading

External links

See also