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[[File:C. dirus, C. lupus, C. lycaon, C. rufus, C. latrans, C. anthus C. aureus & C. mesomelas skulls.jpg|thumb|Skulls of dire wolf (''C. dirus''), gray wolf (''C. lupus''), eastern wolf (''C. lycaon''), red wolf (''C. rufus''), coyote (''C. latrans''), African golden wolf (''C. anthus''), golden jackal (''C. aureus'') and black-backed jackal (''C. mesomelas'')]]
[[File:C. dirus, C. lupus, C. lycaon, C. rufus, C. latrans, C. anthus C. aureus & C. mesomelas skulls.jpg|thumb|Skulls of dire wolf (''C. dirus''), gray wolf (''C. lupus''), eastern wolf (''C. lycaon''), red wolf (''C. rufus''), coyote (''C. latrans''), African golden wolf (''C. anthus''), golden jackal (''C. aureus'') and black-backed jackal (''C. mesomelas'')]]


The canids that had emigrated from North America to Eurasia – ''[[Eucyon]]'', ''[[Vulpes]]'', and ''[[Nyctereutes]]'' – were small to medium-sized predators during the Late Miocene and Early Pliocene but they were not the top predators. The position of the canids would change with the arrival of ''Canis'' to become a dominant predator across the [[Holarctic]]. The wolf-sized ''C. chihilensis'' appeared in northern China in the Mid-Pliocene around 4-3 million YBP. This was followed by an explosion of ''Canis'' evolution across Eurasia in the Early Pleistocene around 1.8 million YBP in what is commonly referred to as the ''wolf event''. It is associated with the formation of the [[mammoth steppe]] and continental glaciation. ''Canis'' spread to Europe in the forms of ''[[Canis arnensis|C. arnensis]]'', ''[[Canis etruscus|C. etruscus]]'', and ''[[Canis falconeri|C. falconeri]]''.<ref name=wang2008/>{{rp|p148}} One study found that the diversity of the ''Canis'' group decreased by the end of the [[Early Pleistocene]] to the [[Middle Pleistocene]] and was limited in Eurasia to the small wolves of the ''Canis mosbachensis–Canis variabilis'' group and the large hypercarnivorous [[Xenocyon|''Canis (Xenocyon) lycaonoides'']].<ref name=sotnikova2010/> Dogs are the best animals in the world 🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯🤯!
The canids that had emigrated from North America to Eurasia – ''[[Eucyon]]'', ''[[Vulpes]]'', and ''[[Nyctereutes]]'' – were small to medium-sized predators during the Late Miocene and Early Pliocene but they were not the top predators. The position of the canids would change with the arrival of ''Canis'' to become a dominant predator across the [[Holarctic]]. The wolf-sized ''C. chihilensis'' appeared in northern China in the Mid-Pliocene around 4-3 million YBP. This was followed by an explosion of ''Canis'' evolution across Eurasia in the Early Pleistocene around 1.8 million YBP in what is commonly referred to as the ''wolf event''. It is associated with the formation of the [[mammoth steppe]] and continental glaciation. ''Canis'' spread to Europe in the forms of ''[[Canis arnensis|C. arnensis]]'', ''[[Canis etruscus|C. etruscus]]'', and ''[[Canis falconeri|C. falconeri]]''.<ref name=wang2008/>{{rp|p148}} One study found that the diversity of the ''Canis'' group decreased by the end of the [[Early Pleistocene]] to the [[Middle Pleistocene]] and was limited in Eurasia to the small wolves of the ''Canis mosbachensis–Canis variabilis'' group and the large hypercarnivorous [[Xenocyon|''Canis (Xenocyon) lycaonoides'']].<ref name=sotnikova2010/>


:''See further: [[Canidae#Evolution|Evolution of the canids]]
:''See further: [[Canidae#Evolution|Evolution of the canids]]

Revision as of 21:17, 1 February 2018

For other uses, see Canis (disambiguation).

Canis
Temporal range: Miocene to Recent 6 - 0 Ma
Gray wolf (top), coyote and African golden wolf (top middle), Ethiopian wolf and golden jackal (bottom middle), black-backed jackal and side-striped jackal (bottom)
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Carnivora
Family: Canidae
Subtribe: Canina
Genus: Canis
Carl Linnaeus
Extant species

  1 C. lupus also includes domestic dogs, C. l. familiaris, and dingos, C. l. dingo

Canis is a genus of the Canidae containing multiple extant species, such as wolves, coyotes, jackals, and dogs. Species of this genus are distinguished by their moderate to large size, their massive, well-developed skulls and dentition, long legs, and comparatively short ears and tails.[2]

Etymology

The generic name Canis means "dog" in Latin. The term "canine" comes from the adjective form, caninus ("of the dog"), from which the term canine tooth is also derived.[3] The canine family has prominent canine teeth, used for killing their prey. The word canis is cognate to the Greek word kūon (Greek: Κύων), which means "dog", as well as (less transparently) English hound.

Terminology

  • Immature dogs (that is, animals that are incapable of reproduction) are referred to as pups or puppies,[4] whereas the young of other canines are known as cubs.
  • A group of puppies from the same gestation period is referred to as a litter.[5]

Taxonomy

Canini

The tribe Canini[6] (Fischer de Waldheim, 1817) is the sister group to the true foxes (Vulpes), and is represented today by two sub-tribes: Canina, which includes the genus Canis[7] (wolves, jackals, the coyote, and the domestic dog), as well as the dhole and the African wild dog; and Cerdocyonina,[8] which includes the so-called foxes of South America.[9]: p55  The critical features that mark the Canini as a monophyletic group include: the consistent enlargement of the frontal sinus, often accompanied by the correlated loss of the depression in the dorsal surface of the postorbital process; the posterior expansion of the paroccipital process; the enlargement of the mastoid process; and the lack of lateral flare of the orbital border of the zygoma.[9]: p77 

Canis

The genus Canis (Carl Linnaeus, 1758) was published in the 10th edition of Systema Naturae[1] and included the dog-like carnivores: the domestic dog, wolves, coyotes and jackals. All species within Canis are phylogenetically closely related with 78 chromosomes and can potentially interbreed.[10]

Evolution

The fossil record shows that feliforms and caniforms emerged within the super-family Carnivoramorpha 43 million YBP.[11] The caniforms included the fox-like genus Leptocyon whose various species existed from 34 million YBP before branching 11.9 million YBP into Vulpes (foxes) and Canini (canines). The jackal-sized Eucyon existed in North America from 10 million YBP and by the Early Pliocene about 6-5 million YBP the coyote-like Eucyon davisi[12] invaded Eurasia. In North America it gave rise to early Canis which first appeared in the Miocene (6 million YBP) in south-western USA and Mexico. By 5 million YBP the larger Canis lepophagus appeared in the same region.[13]: p58 

Skulls of dire wolf (C. dirus), gray wolf (C. lupus), eastern wolf (C. lycaon), red wolf (C. rufus), coyote (C. latrans), African golden wolf (C. anthus), golden jackal (C. aureus) and black-backed jackal (C. mesomelas)

The canids that had emigrated from North America to Eurasia – Eucyon, Vulpes, and Nyctereutes – were small to medium-sized predators during the Late Miocene and Early Pliocene but they were not the top predators. The position of the canids would change with the arrival of Canis to become a dominant predator across the Holarctic. The wolf-sized C. chihilensis appeared in northern China in the Mid-Pliocene around 4-3 million YBP. This was followed by an explosion of Canis evolution across Eurasia in the Early Pleistocene around 1.8 million YBP in what is commonly referred to as the wolf event. It is associated with the formation of the mammoth steppe and continental glaciation. Canis spread to Europe in the forms of C. arnensis, C. etruscus, and C. falconeri.[13]: p148  One study found that the diversity of the Canis group decreased by the end of the Early Pleistocene to the Middle Pleistocene and was limited in Eurasia to the small wolves of the Canis mosbachensis–Canis variabilis group and the large hypercarnivorous Canis (Xenocyon) lycaonoides.[14]

See further: Evolution of the canids

Dentition and biteforce

Diagram of a wolf skull with key features labelled
Eurasian wolf skull

Dentition relates to the arrangement of teeth in the mouth, with the dental notation for the upper-jaw teeth using the upper-case letters I to denote incisors, C for canines, P for premolars, and M for molars, and the lower-case letters i, c, p and m to denote the mandible teeth. Teeth are numbered using one side of the mouth and from the front of the mouth to the back. In carnivores, the upper premolar P4 and the lower molar m1 form the carnassials that are used together in a scissor-like action to shear the muscle and tendon of prey.[13]: 74 

Canids use their premolars for cutting and crushing except for the upper fourth premolar P4 (the upper carnassial) that is only used for cutting. They use their molars for grinding except for the lower first molar m1 (the lower carnassial) that has evolved for both cutting and grinding depending on the candid's dietary adaptation. On the lower carnassial the trigonid is used for slicing and the talonid is used for grinding. The ratio between the trigonid and the talonid indicates a carnivore's dietary habits, with a larger trigonid indicating a hypercarnivore and a larger talonid indicating a more omnivorous diet.[15][16] Because of its low variability, the length of the lower carnassial is used to provide an estimate of a carnivore's body size.[15]

A study of the estimated bite force at the canine teeth of a large sample of living and fossil mammalian predators, when adjusted for their body mass, found that for placental mammals the bite force at the canines (in Newtons/kilogram of body weight) was greatest in the extinct dire wolf (163), followed among the modern canids by the four hypercarnivores that often prey on animals larger than themselves: the African hunting dog (142), the gray wolf (136), the dhole (112), and the dingo (108). The bite force at the carnassials showed a similar trend to the canines. A predator's largest prey size is strongly influenced by its biomechanical limits.[17]

Behaviour

The difference between the male and female of a species apart from their sex organs is called sexual dimorphism. An example is the male lion, which compared with the female lion possesses a mane, larger size, larger upper canines, and operates in a group of no more than two or three. There is little variance among male and female canids. Canids tend to live as monogamous pairs, and wolves, dholes, and jackals also along with their offspring. Wolves may live in extended family groups. To take prey larger than themselves, the African wild dog, the dhole, and the gray wolf depend on their jaws as they cannot use their forelimbs to grapple with prey. They work together as a pack consisting of an alpha pair and their offspring from the current and previous years.[18] Social mammal predators prey on herbivores with a body mass similar to that of the combined mass of the predator pack.[19][20] The gray wolf specializes in predating on the vulnerable individuals of large prey,[21] and a pack of timber wolves can bring down a 500 kg (1,100 lb) moose.[22][23]

Tooth breakage

Dentition of a wolf showing functions of the teeth.

Tooth breakage is a frequent result of carnivores' feeding behaviour.[24] Carnivores include both pack hunters and solitary hunters. The solitary hunter depends on a powerful bite at the canine teeth to subdue their prey, and thus exhibits a strong mandibular symphysis. In contrast, a pack hunter, which delivers many shallower bites, has a comparably weaker mandibular symphysis. Thus, researchers can use the strength of the mandibular symphysis in fossil carnivore specimens to determine what kind of hunter it was – a pack hunter or a solitary hunter – and even how it consumed its prey. The mandibles of canids are buttressed behind the carnassial teeth to crack bones with their post-carnassial teeth (molars M2 and M3). A study found that the modern gray wolf and the red wolf (C. rufus) possess greater buttressing than all other extant canids and the extinct dire wolf. This indicates that these are both better adapted for cracking bone than other canids.[25]

A study of nine modern carnivores indicate that one in four adults had suffered tooth breakage and that half of these breakages were of the canine teeth. The highest frequency of breakage occurred in the spotted hyena, which is known to consume all of its prey including the bone. The least breakage occurred in the African wild dog. The gray wolf ranked between these two.[24][26] The eating of bone increases the risk of accidental fracture due to the relatively high, unpredictable stresses that it creates. The most commonly broken teeth are the canines, followed by the premolars, carnassial molars, and incisors. Canines are the teeth most likely to break because of their shape and function, which subjects them to bending stresses that are unpredictable in direction and magnitude.[26] The risk of tooth fracture is also higher when taking and consuming large prey.[26][27]

In comparison to extant gray wolves, the extinct Beringian wolves included many more individuals with moderately to heavily worn teeth and with a significantly greater number of broken teeth. The frequencies of fracture ranged from a minimum of 2% found in the Northern Rocky Mountain wolf (Canis lupus irremotus) up to a maximum of 11% found in Beringian wolves. The distribution of fractures across the tooth row also differs, with Beringian wolves having much higher frequencies of fracture for incisors, carnassials, and molars. A similar pattern was observed in spotted hyenas, suggesting that increased incisor and carnassial fracture reflects habitual bone consumption because bones are gnawed with the incisors and then cracked with the carnassials and molars.[28]

Wolves, dogs, and dingoes

Wolves, dogs, and dingoes are subspecies of Canis lupus. The original referent of the English word wolf, the Eurasian wolf, is called C. l. lupus to distinguish it from other wolf subspecies, such as the Indian wolf (C. l. pallipes), the Arabian wolf (C. l. arabs), or the Tibetan wolf (C. l. filchneri).

Some experts have suggested some subspecies of C. lupus be considered Canis species distinct from C. lupus. These include Central Asia's Himalayan wolf, and the Indian wolf,[29][30] as well as North America's red wolf and eastern wolf.[31]

The dingo (C. l. dingo), from Australasia, and the domestic dog (C. l. familiaris) are also considered subspecies of C. lupus, although they are not commonly referred to or thought of as "wolves".[32]

Coyotes, jackals, and wolves

The extant wolf-like canids
Caninae 4.3 Ma
Phylogenetic relationships between the extant wolf-like clade of canids based on nuclear DNA (15 kilobytes of exon and intron sequence data taken from the cell nucleus),[33][34] except for the Himalayan wolf based on mitochondrial DNA sequences.[34][35][36][37] All species belong to the genus Canis, apart from the dhole (Cuon) and the African wild dog (Lycaon) that are descended from the extinct Canis subgenus named Xenocyon.[13]: p149  Timing in millions of years.[38]

The gray wolf (C. lupus), the Ethiopian wolf (C. simensis), and the African golden wolf (C. anthus) are three of the many Canis species referred to as "wolves"; however, all of the others are now extinct and little is known about them by the general public. One of these, the extinct dire wolf (C. dirus), has gained fame from the thousands of specimens found and displayed at the Rancho La Brea Tar Pits in Los Angeles, California.

Canis species that are too small to attract the word "wolf" are called coyotes in the Americas and jackals elsewhere. Although these may not be more closely related to each other than they are to C. lupus, they are, as fellow Canis species, all more closely related to wolves and domestic dogs than they are to foxes, maned wolves, or other canids which do not belong to the genus Canis. The word "jackal" is applied to three distinct species of this group: the side-striped (C. adustus) and black-backed (C. mesomelas) jackals, found in sub-Saharan Africa, and the golden jackal (C. aureus), found across southwestern and south-central Asia, and the Balkans.

While North America has only one small-sized species, the coyote (C. latrans), it has become very widespread, moving into areas once occupied by wolves. They can be found across much of mainland Canada, in every state of the contiguous United States, all of Mexico except the Yucatán Peninsula, and the Pacific and central areas of Central America, ranging as far as western Panama.

African migration

In 2015, a study of mitochondrial genome sequences and whole genome nuclear sequences of African and Eurasian canids indicated that extant wolf-like canids have colonised Africa from Eurasia at least 5 times throughout the Pliocene and Pleistocene, which is consistent with fossil evidence suggesting that much of African canid fauna diversity resulted from the immigration of Eurasian ancestors, likely coincident with Plio-Pleistocene climatic oscillations between arid and humid conditions. When comparing the African and Eurasian golden jackals, the study concluded that the African specimens represented a distinct monophyletic lineage that should be recognized as a separate species, Canis anthus (African golden wolf). According to a phylogeny derived from nuclear sequences, the Eurasian golden jackal (Canis aureus) diverged from the wolf/coyote lineage 1.9 million years ago but the African golden wolf separated 1.3 million years ago. Mitochondrial genome sequences indicated the Ethiopian wolf diverged from the wolf/coyote lineage slightly prior to that.[39]: S1 

See also

References

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  39. ^ Koepfli, Klaus-Peter; Pollinger, John; Godinho, Raquel; Robinson, Jacqueline; Lea, Amanda; Hendricks, Sarah; Schweizer, Rena M.; Thalmann, Olaf; Silva, Pedro; Fan, Zhenxin; Yurchenko, Andrey A.; Dobrynin, Pavel; Makunin, Alexey; Cahill, James A.; Shapiro, Beth; Álvares, Francisco; Brito, José C.; Geffen, Eli; Leonard, Jennifer A.; Helgen, Kristofer M.; Johnson, Warren E.; o'Brien, Stephen J.; Van Valkenburgh, Blaire; Wayne, Robert K. (2015). "Genome-wide Evidence Reveals that African and Eurasian Golden Jackals Are Distinct Species". Current Biology. 25 (16): 2158. doi:10.1016/j.cub.2015.06.060. PMID 26234211.
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