Creodonta

Creodonta Temporal range: 63.3–8.8  Ma PreꞒ Ꞓ O S D C P T J K Pg N Early Paleocene to Late Miocene
Various creodonts of the Eocene of Colorado, United States. From top: Tritemnodon, Patriofelis, Machaeroides, and Sinopa
Scientific classification
Domain:	Eukaryota
Kingdom:	Animalia
Phylum:	Chordata
Class:	Mammalia
Mirorder:	Ferae
Order:	†Creodonta Cope, 1875[1]
Families
†Hyaenodontidae †Oxyaenidae
Synonyms
list of synonyms: Creodontia Creodontidae (Winkler, 1893)[2] Creodontiformes (Kinman, 1994)[3] Creodontina (Pearse, 1936)[4] Creophaga (Kretzoi, 1945)[5] Hyaenodontia (Romer, 1966)[6] Paracarnivora (Kretzoi, 1929)[7] Pseudocreodi (Matthew, 1909)[8] Subdidelphia (Trouessart, 1879)[9]

Creodonta ("meat teeth") is a former

Creodonts were the dominant carnivorous mammals from 55 to 35 million years ago, peaking in diversity and prevalence during the Eocene.^[11] The first large, obviously carnivorous mammals appeared with the radiation of the oxyaenids in the late Paleocene.^[12] During the Paleogene, "creodont" species were the most abundant terrestrial carnivores in the Old World.^[13] In Oligocene Africa, hyaenodonts were the dominant group of large flesh-eaters, persisting until the middle of the Miocene.

"Creodont" groups had an extensive range, both geographically and temporally. They are known from the late Paleocene through the late Oligocene in North America, the early Eocene through late Oligocene in Europe, from the late Paleocene through late Miocene in Asia, and from the late Paleocene to the late Miocene in Africa.^[14] While most were small-to-medium sized mammals, among their number was Sarkastodon, one of the largest mammalian land predators of all time, weighing an estimated 800 kg.^[15]

The decline of the hyaenodonts coincides in time with the rise of the Carnivora, but it is unclear whether these events were related (i.e., carnivorans outcompeted "creodonts") or whether they are two separate results of environmental factors. The last genus, Dissopsalis, became extinct about 11.1 million years ago.

Most modern paleontologists agree both "creodont" families are related to Carnivora, but are not their direct ancestors. It is still unclear how closely the two families are related to each other. In general, classification is complicated by the fact that relationships among fossil mammals are usually decided by similarities in the teeth, but the teeth of hypercarnivorous species may evolve similar shapes through convergent evolution, to deal with the mechanics of eating meat.^[16]

"Creodonts" share with the Carnivora, and many other predatory mammal clades, the

Systematics and history

"Creodonta" was coined by Edward Drinker Cope in 1875.^[1] Cope included the oxyaenids and the viverravid Didymictis but omitted the Hyaenodontidae. In 1880. he expanded the term to include families Miacidae (including Viverravidae), Arctocyonidae, Leptictidae (now Pseudorhyncocyonidae), Oxyaenidae, Ambloctonidae and Mesonychidae.^[17] Cope originally placed creodonts within the Insectivora. In 1884, however, he regarded them as a basal group from which both carnivorans and insectivorans arose.^[18]

Hyaenodontidae was not included among the creodonts until 1909.^[19] William Diller Matthew regarded Creodonta as a suborder of order Carnivora, divided in three groups:

• "Inadaptive Creodonta" (Creodonta inadaptiva), group that includes "Pseudocreodi" (oxyaenids and hyaenodontids) and the mesonychids,
• "Adaptive Creodonta" (Creodonta adaptiva), made up of the miacids and the taxa included in the wastebasket "Arctocyonidae",
• and "Primitive Creodonta" (Creodonta primitiva), made up of Oxyclaenidae.

Over time, various groups and species were removed from this order. It stabilized in the mid-20th century as representing oxyaenids, hyaenodonts, mesonychids, and arctocyonids,^[20] which were understood as the major groups of flesh-eating placental mammals that were not members of the Carnivora. It became increasingly clear that arctocyonids were a wastebasket taxon and mesonychids might be more closely related to ungulates. By 1969, Creodonta contained only the oxyaenids and the hyaenodontids.^[21]

More recently, "Creodonta" had been considered to be a nonvalid

The limnocyonids had the following features according to Gunnell: M3/m3 were reduced or absent, other teeth were unreduced. The rostrum was elongated. The animals themselves were small to medium-sized.^[14]

Morphology

Dentition

Among primitive creodonts the dental formula is 3.1.4.33.1.4.3, but later forms often had reduced numbers of incisors, premolars and/or molars.^[32] The canines are always large and pointed. The lateral incisors are large, while the medial incisors are usually small.^[14] Premolars are primitive, with one primary cusp and various secondary cusps.^[13]

Creodonts have two or three pairs of carnassial teeth. One pair performed the largest cutting function (either M1/m2 or M2/m3).^[14] This arrangement is unlike modern carnivorans, which use P4 and m1 for carnassials.^[33] This difference suggests convergent evolution among meat-eaters, with a separate evolutionary history and an order-level distinction,^[34] given that different teeth evolved as the carnassials both between creodonts and carnivorans, and between oxyaenids and hyaenodonts. Carnassials are also known in other flesh-eating mammal clades, such as in the extinct bat Necromantis, as well as highly unrelated taxa such as the flesh-eating marsupial Thylacoleo.

Different molars were involved in the two major groups of creodonts. In the Oxyaenidae, M1 and m2 that form the carnassials. Among the hyaenodontids, it is M2 and m3. Unlike most modern carnivorans, in which the carnassials are the sole shearing teeth, other creodont molars have a subordinate shearing functions.^[19] The difference in which teeth form the carnassials is a major argument for the polyphyly of Creodonta.

Comparison of carnassial teeth of wolf and typical hyaenodontid and oxyaenid

Upper teeth of creodonts from Middle Eocene Bridger Basin, Wyoming

Sinopa fossils: (1) Right upper cheek teeth, P2-M2; (2) Left ramus of mandible (p2-m2); (3) Right ramus of mandible (c-m2)

Cranium

Creodonts had long, narrow skulls with small brains. The skull narrowed considerably behind the eyes, producing a distinct

Skull of oxyaenid Machaeroides eothen

Lateral outline and front view of skull of Sarkastodon mongoliensis

Head of Sarkastodon mongoliensis

Lateral (A) and dorsal (B) views of the skull of the hyaenodontid Apterodon macrognathus by Henry Fairfield Osborn

Skull of Hyaenodon horridus

Skull of Limnocyon verus

Postcranial skeleton

Creodonts had generalized postcranial skeletons. Their limbs were mesaxonic (with the axis of the foot provided by the middle of their five digits). Their method of locomotion ranged from plantigrade to digitigrade. The terminal phalanges were fused claws.^[14]

Mount of oxyaenid Patriofelis ferox from the American Museum of Natural History

Reconstruction of Patriofelis ferox

Mounted skeleton of the hyaenodontid Sinopa rapax from Bridger Basin

Size

Creodonts ranged in size from the size of a small cat to the 800-kilogram (1,800 lb) Sarkastodon. The larger animals, however, were not known until late in the Paleocene with the radiation of the oxyaenids,^[12] such as the puma-sized Dipsalidictis and the probably bone-crushing scavenger Dipsalodon.^[35]

Certain creodonts (

The largest North American creodont is Patriofelis. A specimen of P. ferox collected in the Bridger Basin of southern Wyoming was the size of a full-grown black bear with a head almost the size of an adult male lion.^[37]

During the Central Asia Expedition of 1930 by the American Museum of Natural History, the largest creodont ever discovered was collected: Sarkastodon mongoliensis. Its dimensions were described as 50% greater than the Patriofelis to which it bore many similarities.^[38] It has been estimated that Sarkastodon attained the body mass of twice the largest American lion.^[15]

Biology

Diet and feeding

Early creodonts (both oxyaenids and hyaenodontids) displayed the tribosphenic molars common for basal

viverrids.^[32] Larger forms had greater shearing capacity and the capacity increased over time. Arfia, one of the most common carnivorous mammals in early Eocene North America, developed a more open trigonid on M3 over the course of the Early Eocene, increasing the shearing ability of the carnassials.^[39] A similar development can be seen by comparing Oxyaena, Prototomus and Limnocyon with the smaller, more generalized feeders among the creodonts.^[14]

Extinction

Several theories have suggested that hyaenodonts and oxyaenids became extinct because they were outcompeted by the newly-evolved Carnivora. However, there is no direct evidence that the existence of large Carnivora caused the extinction of these taxa, and in many cases (in Africa throughout the Early and Middle Miocene, and in North America and Eurasia during much of the Oligocene), hyaenodonts thrived in environments in which large carnivorans such as nimravids and (later) larger amphicyonids were also present as competitors. Theories that suggest they were outcompeted by the Carnivora include that their smaller brains limited their intelligence, but carnivoran brain sizes have not always been consistently large throughout their evolution, and the importance of brain size as a factor in intelligence has been vastly overestimated in the past when these ideas were published. Other speculations focus on their limb structure, which limited leg movement to a vertical plane, as in ungulates; they were unable to turn their wrists and forearms inward to trip, slash, or grab prey as some modern carnivores can. Creodonts had to depend entirely on their jaws to capture prey, which may be why creodonts generally had a larger head size in relation to their bodies than carnivores of similar stature. However, many carnivorans, such as large canids, are also dependent on their jaws alone to capture prey yet do so effectively even in situations where they must tackle large prey alone, so this also fails to provide a satisfactory explanation.

In the Carnivora, the last upper premolar and the first lower molar are the carnassials, allowing the rearmost molar teeth to evolve adaptations for feeding on non-meat foods. In creodonts, either the first upper and second lower molars, or the second upper and third lower molars, were the primary carnassials, and the rear teeth formed a carnassial series. This structure committed them to eating meat almost exclusively, which may have limited their ability to exploit mesocarnivore and omnivore ecological niches. These differences may have caused environmental changes to affect hyaenodonts and oxyaenids differently than they did many carnivorans, as the former would have been restricted to largely or entirely faunivorous diets, while many (though not all) carnivoran lineages were/are able to subsist on plant matter as well.

References

1. ^ ^{a b} Cope, Edward Drinker (1875). On the Supposed Carnivora of the Eocene of the Rocky Mountains. Vol. 27. pp. 444–449. {{cite book}}: |work= ignored (help)
2. ^ T. C. Winkler (1893.) "De Gewervelde Dieren van Het Verleden." Palaeontologische Studiën in Telyer's Museum 1-291
3. ^ Kenneth E. Kinman (1994.) "The Kinman System: Toward a Stable Cladisto-Eclectic Classification of Organisms: Living and Extinct, 48 Phyla, 269 Classes, 1,719 Orders", Hays, Kan. (P. O. Box 1377, Hays 67601), 88 pages
4. ^ Arthur Sperry Pearse, (1936) "Zoological names. A list of phyla, classes, and orders, prepared for section F, American Association for the Advancement of Science" American Association for the Advancement of Science
5. ^ Miklos Kretzoi (1945) "Bemerkungen über das Raubtiersystem." Annales Historico-Naturales Musei Nationalis Hungarici, Budapest, vol. 38, pp. 59-83.
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7. ^ Kretzoi, N. (1929.) "Materialien zur phylogenetischen Klassifikation der Aeluroïdeen. X Congres International de Zoologie, Budapest 1927., 2, 1293–1355.
8. ^ W. D. Matthew (1909.) "The Carnivora and Insectivora of the Bridger Basin, middle Eocene." Memoirs of the American Museum of Natural History 9:289-567
9. ^ Trouessart, E. L. (1879.) "Catalogue des mammifères vivants et fossiles. III. Insectivora." Rev. Mag. Zool. 3è ser. 7: 219 – 285.
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Further reading

Wikimedia Commons has media related to Creodonta.

Wikispecies has information related to Creodonta.

• Macdonald, David (January 1992). The Velvet Claw: A Natural History of the Carnivores.
  ISBN 978-0-563-20844-0
  .