Bear

Bears are carnivoran mammals of the family Ursidae. They are classified as caniforms, or doglike carnivorans. Although only eight species of bears are extant, they are widespread, appearing in a wide variety of habitats throughout the Northern Hemisphere and partially in the Southern Hemisphere. Bears are found on the continents of North America, South America, Europe, and Asia. Common characteristics of modern bears include large bodies with stocky legs, long snouts, small rounded ears, shaggy hair, plantigrade paws with five nonretractile claws, and short tails.

Bears
Temporal range: 38–0 Ma Late Eocene – Recent
Images of a few members of the family Ursidae (clockwise from top right) consisting of the brown bear, the giant panda, the polar bear and the Asian black bear, and the American black bear, the sun bear, the spectacled bear and the sloth bear.
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Carnivora
Infraorder: Arctoidea
Family: Ursidae
G. Fischer de Waldheim, 1817
Subfamilies

Amphicynodontinae
Hemicyoninae
Ursavinae
Agriotheriinae
Ailuropodinae
Tremarctinae
Ursinae

While the polar bear is mostly carnivorous, and the giant panda feeds almost entirely on bamboo, the remaining six species are omnivorous with varied diets. With the exception of courting individuals and mothers with their young, bears are typically solitary animals. They may be diurnal or nocturnal and have an excellent sense of smell. Despite their heavy build and awkward gait, they are adept runners, climbers, and swimmers. Bears use shelters, such as caves and logs, as their dens; most species occupy their dens during the winter for a long period of hibernation, up to 100 days.

Bears have been hunted since prehistoric times for their meat and fur; they have been used for bear-baiting and other forms of entertainment, such as being made to dance. With their powerful physical presence, they play a prominent role in the arts, mythology, and other cultural aspects of various human societies. In modern times, bears have come under pressure through encroachment on their habitats and illegal trade in bear parts, including the Asian bile bear market. The IUCN lists six bear species as vulnerable or endangered, and even least concern species, such as the brown bear, are at risk of extirpation in certain countries. The poaching and international trade of these most threatened populations are prohibited, but still ongoing.

Etymology

The English word "bear" comes from Old English bera and belongs to a family of names for the bear in Germanic languages, such as Swedish björn, also used as a first name. This form is conventionally said to be related to a Proto-Indo-European word for "brown", so that "bear" would mean "the brown one".[1][2] However, Ringe notes that while this etymology is semantically plausible, a word meaning "brown" of this form cannot be found in Proto-Indo-European. He suggests instead that "bear" is from the Proto-Indo-European word *ǵʰwḗr- ~ *ǵʰwér "wild animal".[3] This terminology for the animal originated as a taboo avoidance term: proto-Germanic tribes replaced their original word for bear—arkto—with this euphemistic expression out of fear that speaking the animal's true name might cause it to appear.[4][5] According to author Ralph Keyes, this is the oldest known euphemism.[6]

Bear taxon names such as Arctoidea and Helarctos come from the ancient Greek ἄρκτος (arktos), meaning bear,[7] as do the names "arctic" and "antarctic", via the name of the constellation Ursa Major, the "Great Bear", prominent in the northern sky.[8]

Bear taxon names such as Ursidae and Ursus come from Latin Ursus/Ursa, he-bear/she-bear.[8] The female first name "Ursula", originally derived from a Christian saint's name, means "little she-bear" (diminutive of Latin ursa). In Switzerland, the male first name "Urs" is especially popular, while the name of the canton and city of Bern is derived from Bär, German for bear. The Germanic name Bernard (including Bernhardt and similar forms) means "bear-brave", "bear-hardy", or "bold bear".[9][10] The Old English name Beowulf is a kenning, "bee-wolf", for bear, in turn meaning a brave warrior.[11]

Taxonomy

The family Ursidae is one of nine families in the suborder Caniformia, or "doglike" carnivorans, within the order Carnivora. Bears' closest living relatives are the pinnipeds, canids, and musteloids.[12] Modern bears comprise eight species in three subfamilies: Ailuropodinae (monotypic with the giant panda), Tremarctinae (monotypic with the spectacled bear), and Ursinae (containing six species divided into one to three genera, depending on the authority). Nuclear chromosome analysis show that the karyotype of the six ursine bears is nearly identical, with each having 74 chromosomes (see Ursid hybrid), whereas the giant panda has 42 chromosomes and the spectacled bear 52. These smaller numbers can be explained by the fusing of some chromosomes, and the banding patterns on these match those of the ursine species, but differ from those of procyonids, which supports the inclusion of these two species in Ursidae rather than in Procyonidae, where they had been placed by some earlier authorities.[13]

Evolution

Plithocyon armagnacensis skull, a member of the extinct subfamily Hemicyoninae from the Miocene

The earliest members of Ursidae belong to the extinct subfamily Amphicynodontinae, including Parictis (late Eocene to early middle Miocene, 38–18 Mya) and the slightly younger Allocyon (early Oligocene, 34–30 Mya), both from North America. These animals looked very different from today's bears, being small and raccoon-like in overall appearance, with diets perhaps more similar to that of a badger. Parictis does not appear in Eurasia and Africa until the Miocene.[14] It is unclear whether late-Eocene ursids were also present in Eurasia, although faunal exchange across the Bering land bridge may have been possible during a major sea level low stand as early as the late Eocene (about 37 Mya) and continuing into the early Oligocene.[15] European genera morphologically very similar to Allocyon, and to the much younger American Kolponomos (about 18 Mya),[16] are known from the Oligocene, including Amphicticeps and Amphicynodon.[15] There has been various morphological evidence linking amphicynodontines with pinnipeds, as both groups were semi-aquatic, otter-like mammals.[17][18][19] In addition to the support of the pinniped–amphicynodontine clade, other morphological and some molecular evidence supports bears being the closet living relatives to pinnipeds.[20][21][22][18][23][19]

Life restoration of Arctotherium bonariense

The raccoon-sized, dog-like Cephalogale is the oldest-known member of the subfamily Hemicyoninae, which first appeared during the middle Oligocene in Eurasia about 30 Mya.[15] The subfamily includes the younger genera Phoberocyon (20–15 Mya), and Plithocyon (15–7 Mya). A Cephalogale-like species gave rise to the genus Ursavus during the early Oligocene (30–28 Mya); this genus proliferated into many species in Asia and is ancestral to all living bears. Species of Ursavus subsequently entered North America, together with Amphicynodon and Cephalogale, during the early Miocene (21–18 Mya). Members of the living lineages of bears diverged from Ursavus between 15 and 20 Mya,[24][25] likely via the species Ursavus elmensis. Based on genetic and morphological data, the Ailuropodinae (pandas) were the first to diverge from other living bears about 19 Mya, although no fossils of this group have been found before about 5 Mya.[26]

The New World short-faced bears (Tremarctinae) differentiated from Ursinae following a dispersal event into North America during the mid-Miocene (about 13 Mya).[26] They invaded South America (≈2.5 or 1.2 Ma) following formation of the Isthmus of Panama.[27] Their earliest fossil representative is Plionarctos in North America (c. 10–2 Ma). This genus is probably the direct ancestor to the North American short-faced bears (genus Arctodus), the South American short-faced bears (Arctotherium), and the spectacled bears, Tremarctos, represented by both an extinct North American species (T. floridanus), and the lone surviving representative of the Tremarctinae, the South American spectacled bear (T. ornatus).[15]

Fossil of the cave bear (Ursus spelaeus), a relative of the brown bear and polar bear from the Pleistocene epoch in Europe

The subfamily Ursinae experienced a dramatic proliferation of taxa about 5.3–4.5 Mya, coincident with major environmental changes; the first members of the genus Ursus appeared around this time.[26] The sloth bear is a modern survivor of one of the earliest lineages to diverge during this radiation event (5.3 Mya); it took on its peculiar morphology, related to its diet of termites and ants, no later than by the early Pleistocene. By 3–4 Mya, the species Ursus minimus appears in the fossil record of Europe; apart from its size, it was nearly identical to today's Asian black bear. It is likely ancestral to all bears within Ursinae, perhaps aside from the sloth bear. Two lineages evolved from U. minimus: the black bears (including the sun bear, the Asian black bear, and the American black bear); and the brown bears (which includes the polar bear). Modern brown bears evolved from U. minimus via Ursus etruscus, which itself is ancestral to the extinct Pleistocene cave bear. Species of Ursinae have migrated repeatedly into North America from Eurasia as early as 4 Mya during the early Pliocene.[28][29] The polar bear is the most recently evolved species and descended from a population of brown bears that became isolated in northern latitudes by glaciation 400,000 years ago.[30]

Phylogeny

The bears form a clade within the Carnivora. The cladogram is based on molecular phylogeny of six genes in Flynn, 2005.[31]

Carnivora

Feliformia

   Caniformia   

Canidae

   Arctoidea   
   

Hemicyonidae

Ursidae

Pinnipedia

Musteloidea

Ailuridae

Procyonidae

Mustelidae

Note that although they are called "bears" in some languages, red pandas and raccoons and their close relatives are not bears, but rather musteloids.[31]

There are two phylogenetic hypotheses on the relationships among extant and fossil bear species. One is all species of bears are classified in seven subfamilies as adopted here and related articles: Amphicynodontinae, Hemicyoninae, Ursavinae, Agriotheriinae, Ailuropodinae, Tremarctinae, and Ursinae.[32][33][34][35] Below is a cladogram of the subfamilies of bears after McLellan and Reiner (1992)[32] and Qiu et al. (2014):[35]

Ursidae

Amphicynodontinae

Hemicyoninae

Ursavinae

Agriotheriinae

Ailuropodinae

Tremarctinae

Ursinae

The second alternative phylogenetic hypothesis was implemented by McKenna et al. (1997) is to classify all the bear species into the superfamily Ursoidea, with Hemicyoninae and Agriotheriinae being classified in the family "Hemicyonidae".[36] Amphicynodontinae under this classification were classified as stem-pinnipeds in the superfamily Phocoidea.[36] In the McKenna and Bell classification both bears and pinnipeds in a parvorder of carnivoran mammals known as Ursida, along with the extinct bear dogs of the family Amphicyonidae.[36] Below is the cladogram based on McKenna and Bell (1997) classification:[36]

Ursida

Amphicyonidae

Phocoidea

Amphicynodontidae

Pinnipedia

Ursoidea

Hemicyoninae

Agriotheriinae

Ursidae

Ursavinae

Ailuropodinae

Tremarctinae

Ursinae

The phylogeny of extant bear species is shown in a cladogram based on complete mitochondrial DNA sequences from Yu et al. (2007)[37] The giant panda, followed by the spectacled bear are clearly the oldest species. The relationships of the other species are not very well resolved, though the polar bear and the brown bear form a close grouping.[13]

Ursidae
Ursinae

Brown bear

Polar bear

Asian black bear

American black bear

Sun bear

Sloth bear

Spectacled bear

Giant panda

Physical characteristics

Size

Polar bear (left) and sun bear, the largest and smallest species respectively, on average

The bear family includes the most massive extant terrestrial members of the order Carnivora.[lower-alpha 1] The polar bear is considered to be the largest extant species,[39] with adult males weighing 350–700 kilograms (770–1,500 pounds) and measuring 2.4–3 metres (7 ft 10 in–9 ft 10 in) in total length.[40] The smallest species is the sun bear, which ranges 25–65 kg (55–145 lb) in weight and 100–140 cm (40–55 in) in length.[41] Prehistoric North and South American short-faced bears were the largest species known to have lived. The latter estimated to have weighed 1,600 kg (3,500 lb) and stood 3.4 m (11 ft 2 in) tall.[42][43] Body weight varies throughout the year in bears of temperate and arctic climates, as they build up fat reserves in the summer and autumn and lose weight during the winter.[44]

Morphology

Unlike most other carnivorans, bears have plantigrade feet. Drawing by Richard Owen, 1866.

Bears are generally bulky and robust animals with short tails. They are sexually dimorphic with regard to size, with males typically being larger.[45][46] Larger species tend to show increased levels of sexual dimorphism in comparison to smaller species.[46] Relying as they do on strength rather than speed, bears have relatively short limbs with thick bones to support their bulk. The shoulder blades and the pelvis are correspondingly massive. The limbs are much straighter than those of the big cats as there is no need for them to flex in the same way due to the differences in their gait. The strong forelimbs are used to catch prey, to excavate dens, to dig out burrowing animals, to turn over rocks and logs to locate prey, and to club large creatures.[44]

Despite being quadrupeds, bears can stand and sit as humans do.

Unlike most other land carnivorans, bears are plantigrade. They distribute their weight toward the hind feet, which makes them look lumbering when they walk. They are capable of bursts of speed but soon tire, and as a result mostly rely on ambush rather than the chase. Bears can stand on their hind feet and sit up straight with remarkable balance. Their front paws are flexible enough to grasp fruit and leaves. Bears' non-retractable claws are used for digging, climbing, tearing, and catching prey. The claws on the front feet are larger than those on the back and may be a hindrance when climbing trees; black bears are the most arboreal of the bears, and have the shortest claws. Pandas are unique in having a bony extension on the wrist of the front feet which acts as a thumb, and is used for gripping bamboo shoots as the animals feed.[44]

Most mammals have agouti hair, with each individual hair shaft having bands of color corresponding to two different types of melanin pigment. Bears however have a single type of melanin and the hairs have a single color throughout their length, apart from the tip which is sometimes a different shade. The coat consists of long guard hairs, which form a protective shaggy covering, and short dense hairs which form an insulating layer trapping air close to the skin. The shaggy coat helps maintain body heat during winter hibernation and is shed in the spring leaving a shorter summer coat. Polar bears have hollow, translucent guard hairs which gain heat from the sun and conduct it to the dark-colored skin below. They have a thick layer of blubber for extra insulation, and the soles of their feet have a dense pad of fur.[44] While bears tend to be uniform in color, some species may have markings on the chest or face and the giant panda has a bold black-and-white pelage.[47]

Bears have small rounded ears so as to minimize heat loss, but neither their hearing or sight are particularly acute. Unlike many other carnivorans they have color vision, perhaps to help them distinguish ripe nuts and fruits. They are unique among carnivorans in not having touch-sensitive whiskers on the muzzle; however, they have an excellent sense of smell, better than that of the dog, or possibly any other mammal. They use smell for signalling to each other (either to warn off rivals or detect mates) and for finding food. Smell is the principal sense used by bears to locate most of their food, and they have excellent memories which helps them to relocate places where they have found food before.[44]

Brown bear skull

The skulls of bears are massive, providing anchorage for the powerful masseter and temporal jaw muscles. The canine teeth are large but mostly used for display, and the molar teeth flat and crushing. Unlike most other members of the Carnivora, bears have relatively undeveloped carnassial teeth, and their teeth are adapted for a diet that includes a significant amount of vegetable matter.[44] Considerable variation occurs in dental formula even within a given species. This may indicate bears are still in the process of evolving from a mainly meat-eating diet to a predominantly herbivorous one. Polar bears appear to have secondarily re-evolved carnassial-like cheek teeth, as their diets have switched back towards carnivory.[48] Sloth bears lack lower central incisors and use their protusible lips for sucking up the termites on which they feed.[44] The general dental formula for living bears is: 3.1.2–4.23.1.2–4.3.[44] The structure of the larynx of bears appears to be the most basal of the caniforms.[49] They possess air pouches connected to the pharynx which may amplify their vocalizations.[50]

Bears have a fairly simple digestive system typical for carnivorans, with a single stomach, short undifferentiated intestines and no cecum.[51][52] Even the herbivorous giant panda still has the digestive system of a carnivore, as well as carnivore-specific genes. Its ability to digest cellulose is ascribed to the microbes in its gut.[53] Bears must spend much of their time feeding in order to gain enough nutrition from foliage. The panda, in particular, spends 12–15 hours a day feeding.[54]

Distribution and habitat

The spectacled bear is the only species found in South America.[55]

Extant bears are found in sixty countries primarily in the Northern Hemisphere and are concentrated in Asia, North America, and Europe. An exception is the spectacled bear; native to South America, it inhabits the Andean region.[55] The sun bear's range extends below the equator in Southeast Asia.[56] The Atlas bear, a subspecies of the brown bear was distributed in North Africa from Morocco to Libya, but it became extinct around the 1870s.[57]

The most widespread species is the brown bear, which occurs from Western Europe eastwards through Asia to the western areas of North America. The American black bear is restricted to North America, and the polar bear is restricted to the Arctic Sea. All the remaining species of bear are Asian.[55] They occur in a range of habitats which include tropical lowland rainforest, both coniferous and broadleaf forests, prairies, steppes, montane grassland, alpine scree slopes, Arctic tundra and in the case of the polar bear, ice floes.[55][58] Bears may dig their dens in hillsides or use caves, hollow logs and dense vegetation for shelter.[58]

Behavior and ecology

American black bear tracks at Superior National Forest, Minnesota, the United States of America

Brown and American black bears are generally diurnal, meaning that they are active for the most part during the day, though they may forage substantially by night.[59] Other species may be nocturnal, active at night, though female sloth bears with cubs may feed more at daytime to avoid competition from conspecifics and nocturnal predators.[60] Bears are overwhelmingly solitary and are considered to be the most asocial of all the Carnivora. The only times bears are encountered in groups are mothers with young or occasional seasonal bounties of rich food (such as salmon runs).[61][62] Fights between males can occur and older individuals may have extensive scarring, which suggests that maintaining dominance can be intense.[63] With their acute sense of smell, bears can locate carcasses from several kilometres away. They use olfaction to locate other foods, encounter mates, avoid rivals and recognize their cubs.[44]

Feeding

Most bears are opportunistic omnivores and consume more plant than animal matter. They eat anything from leaves, roots, and berries to insects, carrion, fresh meat, and fish, and have digestive systems and teeth adapted to such a diet.[55] At the extremes are the almost entirely herbivorous giant panda and the mostly carnivorous polar bear. However, all bears feed on any food source that becomes seasonally available.[54] For example, Asiatic black bears in Taiwan consume large numbers of acorns when these are most common, and switch to ungulates at other times of the year.[64]

When foraging for plants, bears choose to eat them at the stage when they are at their most nutritious and digestible, typically avoiding older grasses, sedges and leaves.[52][54] Hence, in more northern temperate areas, browsing and grazing is more common early in spring and later becomes more restricted.[65] Knowing when plants are ripe for eating is a learned behavior.[54] Berries may be foraged in bushes or at the tops of trees, and bears try to maximize the number of berries consumed versus foliage.[65] In autumn, some bear species forage large amounts of naturally fermented fruits, which affects their behavior.[66] Smaller bears climb trees to obtain mast (edible reproductive parts, such as acorns).[67] Such masts can be very important to the diets of these species, and mast failures may result in long-range movements by bears looking for alternative food sources.[68] Brown bears, with their powerful digging abilities, commonly eat roots.[65] The panda's diet is over 99% bamboo,[69] of 30 different species. Its strong jaws are adapted for crushing the tough stems of these plants, though they prefer to eat the more nutritious leaves.[70][71] Bromeliads can make up to 50% of the diet of the spectacled bear, which also has strong jaws to bite them open.[72]

Brown bear feeding on infrequent, but predictable, salmon migrations in Alaska

The sloth bear, though not as specialized as polar bears and the panda, has lost several front teeth usually seen in bears, and developed a long, suctioning tongue to feed on the ants, termites, and other burrowing insects they favour. At certain times of the year, these insects can make up 90% of their diets.[73] Some species may raid the nests of wasps and bees for the honey and immature insects, in spite of stinging from the adults.[74] Sun bears use their long tongues to lick up both insects and honey.[75] Fish are an important source of food for some species, and brown bears in particular gather in large numbers at salmon runs. Typically, a bear plunges into the water and seizes a fish with its jaws or front paws. The preferred parts to eat are the brain and eggs. Small burrowing mammals like rodents may be dug out and eaten.[76][65]

Polar bear feeding on a seal on an ice floe north of Svalbard, Norway. It is the most carnivorous species.

The brown bear and both species of black bears sometimes take large ungulates, such as deer and bovids, mostly the young and weak.[64][77][76] These animals may be taken by a short rush and ambush, though hiding young may be stiffed out and pounced on.[65][78] The polar bear mainly preys on seals, stalking them from the ice or breaking into their dens. They primarily eat the highly digestible blubber.[79][76] Large mammalian prey is typically killed by a bite to the head or neck, or (in the case of young) simply pinned down and mauled.[65][80] Predatory behavior in bears is typically taught to the young by the mother.[76]

Bears are prolific scavengers and kleptoparasites, stealing food caches from rodents, and carcasses from other predators.[52][81] For hibernating species, weight gain is important as it provides nourishment during winter dormancy. A brown bear can eat 41 kg (90 lb) of food and gain 2–3 kg (4–7 lb) of fat a day prior to entering its den.[82]

Communication

Captive Asian black bears during an aggressive encounter

Bears produce a number of vocal and non-vocal sounds. Tongue-clicking, grunting or chuffing many be made in cordial situations, such as between mothers and cubs or courting couples, while moaning, huffing, snorting or blowing air is made when an individual is stressed. Barking is produced during times of alarm, excitement or to give away the animal's position. Warning sounds include jaw-clicking and lip-popping, while teeth-chatters, bellows, growls, roars and pulsing sounds are made in aggressive encounters. Cubs may squeal, bawl, bleat or scream when in distress and make motor-like humming when comfortable or nursing.[49][83][84][85][86][87]

Sloth bear rubbing against a tree at Nagarhole Tiger Reserve, India

Bears sometimes communicate with visual displays such as standing upright, which exaggerates the individual's size. The chest markings of some species may add to this intimidating display. Staring is an aggressive act and the facial markings of spectacled bears and giant pandas may help draw attention to the eyes during agonistic encounters.[47] Individuals may approach each other by stiff-legged walking with the head lowered. Dominance between bears is asserted by making a frontal orientation, showing the canine teeth, muzzle twisting and neck stretching. A subordinate may respond with a lateral orientation, by turning away and dropping the head and by sitting or lying down.[62][88]

Bears may mark territory by rubbing against trees and other objects which may serve to spread their scent. This is usually accompanied by clawing and biting the object. Bark may be spread around to draw attention to the marking post.[89] Pandas are known to mark objects with urine and a waxy substance from their anal glands.[90] Polar bears leave behind their scent in their tracks which allow individuals to keep track of one another in the vast Arctic wilderness.[91]

Reproduction and development

American black bears mating at the North American Bear Center

The mating system of bears has variously been described as a form of polygyny, promiscuity and serial monogamy.[92][93][94] During the breeding season, males take notice of females in their vicinity and females become more tolerant of males. A male bear may visit a female continuously over a period of several days or weeks, depending on the species, to test her reproductive state. During this time period, males try to prevent rivals from interacting with their mate. Courtship may be brief, although in some Asian species, courting pairs may engage in wrestling, hugging, mock fighting and vocalizing. Ovulation is induced by mating, which can last up to 30 minutes depending on the species.[93]

Gestation typically lasts 6–9 months, including delayed implantation, and litter size numbers up to four cubs.[95] Giant pandas may give birth to twins but they can only suckle one young and the other is left to die.[96] In northern living species, birth takes place during winter dormancy. Cubs are born blind and helpless with at most a thin layer of hair, relying on their mother for warmth. The milk of the female bear is rich in fat and antibodies and cubs may suckle for up to a year after they are born. By 2–3 months, cubs can follow their mother outside the den. They usually follow her on foot, but sloth bear cubs may ride on their mother's back.[95][58] Male bears play no role in raising young. Infanticide, where an adult male kills the cubs of another, has been recorded in polar bears, brown bears and American black bears but not in other species.[97] Males kill young to bring the female into estrus.[98] Cubs may flee and the mother defends them even at the cost of her life.[99][100][101]

In some species, offspring may become independent around the next spring, through some may stay until the female successfully mates again. Bears reach sexual maturity shortly after they disperse; at around 3–6 years depending on the species. Male Alaskan brown bears and polar bears may continue to grow until they are 11 years old.[95] Lifespan may also vary between species. The brown bear can live an average of 25 years.[102]

Hibernation

Bears of northern regions, including the American black bear and the grizzly bear, hibernate in the winter.[103][104] During hibernation, the bear's metabolism slows down, its body temperature decreases slightly, and its heart rate slows from a normal value of 55 to just 9 beats per minute.[105] Bears normally do not wake during their hibernation, and can go the entire period without eating, drinking, urinating, or defecating.[44] A fecal plug is formed in the colon, and is expelled when the bear wakes in the spring.[106] If they have stored enough body fat, their muscles remain in good condition, and their protein maintenance requirements are met from recycling waste urea.[44] Female bears give birth during the hibernation period, and are roused when doing so.[104]

Mortality

Hunters with shot bear, Sweden, early 20th century. This photograph is in the Nordic Museum.

Bears do not have many predators. The most important are humans, and as they started cultivating crops, they increasingly came in conflict with the bears that raided them. Since the invention of firearms, people have been able to kill bears with greater ease.[107] Felids like the tiger may also prey on bears,[108][109] particularly cubs, which may also be threatened by canids.[13][94]

Bears are parasitized by eighty species of parasites, including single-celled protozoans and gastro-intestinal worms, and nematodes and flukes in their heart, liver, lungs and bloodstream. Externally they have ticks, fleas and lice. A study of American black bears found seventeen species of endoparasite including the protozoan Sarcocystis, the parasitic worm Diphyllobothrium mansonoides, and the nematodes Dirofilaria immitis, Capillaria aerophila, Physaloptera sp., Strongyloides sp. and others. Of these, D. mansonoides and adult C. aerophila were causing pathological symptoms.[110] By contrast, polar bears have few parasites; many parasitic species need a secondary, usually terrestrial, host, and the polar bear's life style is such that few alternative hosts exist in their environment. The protozoan Toxoplasma gondii has been found in polar bears, and the nematode Trichinella nativa can cause a serious infection and decline in older polar bears.[111] Bears in North America are sometimes infected by a Morbillivirus similar to the canine distemper virus.[112] They are susceptible to infectious canine hepatitis (CAV-1), with free-living black bears dying rapidly of encephalitis and hepatitis.[113]

Relationship with humans

Conservation

A barrel trap in Grand Teton National Park, Wyoming used to relocate bears away from where they might attack humans.

In modern times, bears have come under pressure through encroachment on their habitats[114] and illegal trade in bear parts, including the Asian bile bear market, though hunting is now banned, largely replaced by farming.[115] The IUCN lists six bear species as vulnerable;[116] even the two least concern species, the brown bear and the American black bear,[116] are at risk of extirpation in certain areas. In general these two species inhabit remote areas with little interaction with humans, and the main non-natural causes of mortality are hunting, trapping, road-kill and depredation.[117]

Laws have been passed in many areas of the world to protect bears from habitat destruction. Public perception of bears is often positive, as people identify with bears due to their omnivorous diets, their ability to stand on two legs, and their symbolic importance.[118] Support for bear protection is widespread, at least in more affluent societies.[119] The giant panda has become a worldwide symbol of conservation. The Sichuan Giant Panda Sanctuaries, which are home to around 30% of the wild panda population, gained a UNESCO World Heritage Site designation in 2006.[120] Where bears raid crops or attack livestock, they may come into conflict with humans.[121][122] In poorer rural regions, attitudes may be more shaped by the dangers posed by bears, and the economic costs they cause to farmers and ranchers.[121]

Attacks

Several bear species are dangerous to humans, especially in areas where they have become used to people; elsewhere, they generally avoid humans. Injuries caused by bears are rare, but are widely reported.[123] Bears may attack humans in response to being startled, in defense of young or food, or even for predatory reasons.[124]

Entertainment, hunting, food and folk medicine

The dancing bear by William Frederick Witherington, 1822

Bears in captivity have for centuries been used for entertainment. They have been trained to dance,[125] and were kept for baiting in Europe at least since the 16th century. There were five bear-baiting gardens in Southwark, London at that time; archaeological remains of three of these have survived.[126] Across Europe, nomadic Romani bear handlers called Ursari lived by busking with their bears from the 12th century.[127]

A nomadic ursar, a Romani bear-busker. Drawing by Theodor Aman, 1888

Bears have been hunted for sport, food, and folk medicine. Their meat is dark and stringy, like a tough cut of beef. In Cantonese cuisine, bear paws are considered a delicacy. Bear meat should be cooked thoroughly, as it can be infected with the parasite Trichinella spiralis.[128][129]

The peoples of eastern Asia use bears' body parts and secretions (notably their gallbladders and bile) as part of traditional Chinese medicine. More than 12,000 bears are thought to be kept on farms in China, Vietnam, and South Korea for the production of bile. Trade in bear products is prohibited under CITES, but bear bile has been detected in shampoos, wine and herbal medicines sold in Canada, the United States and Australia.[130]

Cultural depictions

"The Three Bears", Arthur Rackham's illustration to English Fairy Tales, by Flora Annie Steel, 1918

Bears have been popular subjects in art, literature, folklore and mythology. The image of the mother bear was prevalent throughout societies in North America and Eurasia, based on the female's devotion and protection of her cubs.[131] In many Native American cultures, the bear is a symbol of rebirth because of its hibernation and re-emergence.[132] A widespread belief among cultures of North America and northern Asia associated bears with shaman; this may be based on the solitary nature of both. Bears have thus been thought to predict the future and shaman were believed to have been capable of transforming into bears.[133]

There is evidence of prehistoric bear worship, though this is disputed by archaeologists.[134] It is possible that bear worship existed in early Chinese and Ainu cultures.[135] The prehistoric Finns,[136] Siberian peoples[137] and more recently Koreans considered the bear as the spirit of their forefathers.[138] Artio (Dea Artio in the Gallo-Roman religion) was a Celtic bear goddess. Evidence of her worship has notably been found at Bern, itself named for the bear. Her name is derived from the Celtic word for "bear", artos.[139] In ancient Greece, the archaic cult of Artemis in bear form survived into Classical times at Brauron, where young Athenian girls passed an initiation right as arktai "she bears".[140]

The constellation of Ursa Major as depicted in Urania's Mirror, c. 1825

The constellations of Ursa Major and Ursa Minor, the great and little bears, are named for their supposed resemblance to bears, from the time of Ptolemy.[lower-alpha 2][8] The nearby star Arcturus means "guardian of the bear", as if it were watching the two constellations.[142] Ursa Major has been associated with a bear for as much as 13,000 years since Paleolithic times, in the widespread Cosmic Hunt myths. These are found on both sides of the Bering land bridge, which was lost to the sea some 11,000 years ago.[143]

Bears are popular in children's stories, including Winnie the Pooh,[144] Paddington Bear,[145] Gentle Ben[146] and "The Brown Bear of Norway".[147] An early version of "Goldilocks and the Three Bears",[148] was published as "The Three Bears" in 1837 by Robert Southey, many times retold, and illustrated in 1918 by Arthur Rackham.[149] The Hanna-Barbera character Yogi Bear has appeared in numerous comic books, animated television shows and films.[150][151] The Care Bears began as greeting cards in 1982, and were featured as toys, on clothing and in film.[152] Around the world, many children—and some adults—have teddy bears, stuffed toys in the form of bears, named after the American statesman Theodore Roosevelt when in 1902 he had refused to shoot an American black bear tied to a tree.[153]

Bears, like other animals, may symbolize nations. The Russian Bear has been a common national personification for Russia from the 16th century onward.[154] Smokey Bear has become a part of American culture since his introduction in 1944, with his message "Only you can prevent forest fires".[155]

Organizations

Juvenile pandas at the Chengdu Research Base of Giant Panda Breeding

The International Association for Bear Research & Management, also known as the International Bear Association, and the Bear Specialist Group of the Species Survival Commission, a part of the International Union for Conservation of Nature focus on the natural history, management, and conservation of bears. Bear Trust International works for wild bears and other wildlife through four core program initiatives, namely Conservation Education, Wild Bear Research, Wild Bear Management, and Habitat Conservation.[156]

Specialty organizations for each of the eight species of bears worldwide include:

  • Vital Ground, for the brown bear[157]
  • Moon Bears, for the Asiatic black bear[158]
  • Black Bear Conservation Coalition, for the North American black bear[159]
  • Polar Bears International, for the polar bear[160]
  • Bornean Sun Bear Conservation Centre, for the sun bear[161]
  • Wildlife SOS, for the sloth bear[162]
  • Andean Bear Conservation Project, for the Andean bear[163]
  • Chengdu Research Base of Giant Panda Breeding, for the giant panda[164]

See also

Notes

  1. Treating pinnipeds[38] as marine mammals
  2. Ptolemy named the constellations in Greek: Ἄρκτος μεγάλη (Arktos Megale) and Ἄρκτος μικρά (Arktos Mikra), the great and little bears.[141]

References

  1. Mallory, J. P.; Adams, Douglas Q. (2006). The Oxford Iintroduction to Proto Indo European and the Proto Indo European World. New York: Oxford University Press. p. 333. ISBN 9781429471046. OCLC 139999117.
  2. Fortson, Benjamin W. (2011). Indo-European Language and Culture: An Introduction (2nd ed.). Hoboken: John Wiley & Sons. p. 31. ISBN 9781444359688. OCLC 778339290.
  3. Ringe, Don (2017). From Proto-Indo-European to Proto-Germanic. A Linguistic History of English. 1 (2nd ed.). Oxford: Oxford University Press. p. 128. ISBN 9780192511188.
  4. "bear (n.)". Online Etymology Dictionary. Archived from the original on 2017-02-02. Retrieved 22 January 2017.
  5. Postma, Laura. "The word for "bear"". University of Pittsburgh Slovak Studies Program. Archived from the original on 2017-11-22. Retrieved 21 March 2018.
  6. Silver, Alexandra (10 January 2011). "Hooking Up and Using the John: Why Do We Use So Many Euphemisms?". Time. Retrieved 4 April 2019.
  7. Liddell, Henry George; Scott, Robert. "Arktos". A Greek-English Lexicon. Perseus Digital Library.
  8. "The Great Bear Constellation Ursa Major". Archived from the original on 30 November 2010. Retrieved 12 January 2017.
  9. "Ursa Major – the Greater Bear". constellationsofwords.com. Archived from the original on 2015-03-14. Retrieved 11 March 2015.
  10. "Bernhard Family History". ancestry.com. Archived from the original on 2015-04-02. Retrieved 11 March 2015.
  11. Sweet, Henry (1884) Anglo-Saxon Reader in Prose and Verse. The Clarendon Press, p. 202.
  12. Wesley-Hunt, G.D.; Flynn, J.J. (2005). "Phylogeny of the Carnivora: Basal relationships among the Carnivoramorphans, and assessment of the position of 'Miacoidea' relative to Carnivora". Journal of Systematic Palaeontology. 3 (1): 1–28. doi:10.1017/S1477201904001518. S2CID 86755875.
  13. Servheen, C.; Herrero, S.; Peyton, B. (1999). Bears: Status Survey and Conservation Action Plan (PDF). IUCN. pp. 26–30. ISBN 978-2-8317-0462-3.
  14. Kemp, T.S. (2005). The Origin and Evolution of Mammals. Oxford University Press. p. 260. ISBN 978-0-19-850760-4.
  15. Banyue, Wang; Zhanxiang, Qiu (2005). "Notes on Early Oligocene Ursids (Carnivora, Mammalia) from Saint Jacques, Nei Mongol, China" (PDF). Bulletin of the American Museum of Natural History. 279 (279): 116–124. doi:10.1206/0003-0090(2003)279<0116:C>2.0.CO;2. Archived (PDF) from the original on 2009-03-26.
  16. Tedford, R.H.; Barnes, L.G.; Ray, C.E. (1994). "The early Miocene littoral ursoid carnivoran Kolponomos: Systematics and mode of life" (PDF). Proceedings of the San Diego Society of Natural History. 29: 11–32. Archived from the original (PDF) on 22 September 2012.
  17. Tedford, R.H.; Barnes, L.G.; Ray, C.E. (1994). "The early Miocene littoral ursoid carnivoran Kolponomos: Systematics and mode of life" (PDF). Proceedings of the San Diego Society of Natural History. 29: 11–32. Archived from the original (PDF) on 22 September 2012. Retrieved 24 July 2010.
  18. Rybczynski, N.; Dawson, M.R.; Tedford, R.H. (2009). "A semi-aquatic Arctic mammalian carnivore from the Miocene epoch and origin of Pinnipedia". Nature. 458 (7241): 1021–1024. Bibcode:2009Natur.458.1021R. doi:10.1038/nature07985. PMID 19396145. S2CID 4371413.
  19. Berta, A.; Morgan, C.; Boessenecker, R.W. (2018). "The Origin and Evolutionary Biology of Pinnipeds: Seals, Sea Lions, and Walruses". Annual Review of Earth and Planetary Sciences. 46: 203–228. Bibcode:2018AREPS..46..203B. doi:10.1146/annurev-earth-082517-010009.
  20. Hunt, R.M. Jr.; Barnes, L.G. (1994). "Basicranial evidence for ursid affinity of the oldest pinnipeds" (PDF). Proceedings of the San Diego Society of Natural History. 29: 57–67.
  21. Lento, G.M.; Hickson, R.E.; Chambers, G.K.; Penny, D. (1995). "Use of spectral analysis to test hypotheses on the origin of pinnipeds". Molecular Biology and Evolution. 12 (1): 28–52. doi:10.1093/oxfordjournals.molbev.a040189. PMID 7877495. Archived from the original on 7 October 2008. Retrieved 3 April 2018.
  22. Wang, X.; McKenna, M.C.; Dashzeveg, D. (2005). "Amphicticeps and Amphicynodon (Arctoidea, Carnivora) from Hsanda Gol Formation, central Mongolia and phylogeny of basal arctoids with comments on zoogeography". American Museum Novitates. 483 (3483): 216. doi:10.1206/0003-0082(2005)483[0001:AAAACF]2.0.CO;2. hdl:2246/5674.
  23. Higdon, J.W.; Bininda-Emonds, O.R.; Beck, R.M.; Ferguson, S.H. (2007). "Phylogeny and divergence of the pinnipeds (Carnivora: Mammalia) assessed using a multigene dataset". BMC Evolutionary Biology. 7: 216. doi:10.1186/1471-2148-7-216. PMC 2245807. PMID 17996107.
  24. Waits, Lisette (1999). "Rapid radiation events in the family Ursidae indicated by likelihood phylogenetic estimation from multiple fragments of mtDNA" (PDF). Molecular Phylogenetics and Evolution. 13 (1): 82–92. doi:10.1006/mpev.1999.0637. PMID 10508542. Archived from the original (PDF) on 3 September 2015.
  25. Pàges, Marie (2008). "Combined analysis of fourteen nuclear genes refines the Ursidae phylogeny". Molecular Phylogenetics and Evolution. 47 (1): 73–83. doi:10.1016/j.ympev.2007.10.019. PMID 18328735.
  26. Krause, J.; Unger, T.; Noçon, A.; Malaspinas, A.; Kolokotronis, S.; Stiller, M.; et al. (2008). "Mitochondrial genomes reveal an explosive radiation of extinct and extant bears near the Miocene-Pliocene boundary". BMC Evolutionary Biology. 8 (220): 220. doi:10.1186/1471-2148-8-220. PMC 2518930. PMID 18662376.
  27. Soibelzon, L. H.; Tonni, E.P.; Bond, M. (2005). "The fossil record of South American short-faced bears (Ursidae, Tremarctinae)" (PDF). Journal of South American Earth Sciences. 20 (1–2): 105–113. Bibcode:2005JSAES..20..105S. doi:10.1016/j.jsames.2005.07.005. hdl:10915/5366.
  28. Qiu Zhanxiang (2003). "Dispersals of Neogene Carnivorans between Asia and North America" (PDF). Bulletin of the American Museum of Natural History. 279 (279): 18–31. doi:10.1206/0003-0090(2003)279<0018:C>2.0.CO;2. Archived (PDF) from the original on 26 March 2009.
  29. Ward and Kynaston, pp. 74–77
  30. Liu, Shiping; Lorenzen, Eline D.; Fumagalli, Matteo; Li, Bo; Harris, Kelley; Xiong, Zijun; et al. (2014). "Population genomics reveal recent speciation and rapid evolutionary adaptation in Polar Bears". Cell. 157 (4): 785–794. doi:10.1016/j.cell.2014.03.054. PMC 4089990. PMID 24813606.
  31. Flynn, J.J.; Finarelli, J.A.; Zehr, S.; Hsu, J.; Nedbal, M.A. (2005). "Molecular phylogeny of the Carnivora (Mammalia): Assessing the impact of increased sampling on resolving enigmatic relationships". Systematic Biology. 54 (2): 317–337. doi:10.1080/10635150590923326. PMID 16012099.
  32. McLellan, B.; Reiner, D.C. (1992). "A review of bear evolution". International Association for Bear Research and Management. 9 (1): 85–96. doi:10.2307/3872687. JSTOR 3872687. S2CID 91124592.
  33. de Bonis, L. (2011). "A new species of Adelpharctos (Mammalia, Carnivora, Ursidae) from the late Oligocene of the "Phosphorites du Quercy" (France)". Estudios Geológicos. 67 (2): 179–186. doi:10.3989/egeol.40553.181.
  34. Louis De Bonis (2013). "Ursidae (Mammalia, Carnivora) from the Late Oligocene of the "Phosphorites du Quercy" (France) and a reappraisal of the genus Cephalogale Geoffroy, 1862". Geodiversitas. 35 (4): 787–814. doi:10.5252/g2013n4a4. S2CID 131561629.
  35. Qiu, Zhan-Xiang; et al. (2014). "A Late Miocene Ursavus skull from Guanghe, Gansu, China". Vertebrata PalAsiatica. 52 (3): 265–302.
  36. McKenna, M.C.; Bell, S. (1997). Classification of nammals above the species level. New York: Columbia University Press.
  37. Yu, Li; Li, Yi-Wei; Ryder, Oliver A.; Zhang, Ya-Ping (2007). "Analysis of complete mitochondrial genome sequences increases phylogenetic resolution of bears (Ursidae), a mammalian family that experienced rapid speciation". BMC Evolutionary Biology. 7 (198): 198. doi:10.1186/1471-2148-7-198. PMC 2151078. PMID 17956639.
  38. Illiger, J. K. W. (1811). Prodromus Systematis Mammalium et Avium (in Latin). Sumptibus C. Salfeld. pp. 138–39.
  39. Ward and Kynaston, p. 61
  40. Hemstock, Annie (1999). The Polar Bear. Manakato, MN: Capstone Press. p. 4. ISBN 978-0-7368-0031-0.
  41. Fitzgerald, C. S.; Krausman, P. S. (2002). "Helarctos malayanus". Mammalian Species. 696: 1–5. doi:10.1644/1545-1410(2002)696<0001:HM>2.0.CO;2.
  42. Dell'Amore, C. (February 3, 2011), Biggest Bear Ever Found, National Geographic News, archived from the original on 2017-10-17
  43. Soibelzon, L. H.; Schubert, B. W. (January 2011). "The Largest Known Bear, Arctotherium angustidens, from the Early Pleistocene Pampean Region of Argentina: With a Discussion of Size and Diet Trends in Bears". Journal of Paleontology. 85 (1): 69–75. doi:10.1666/10-037.1. S2CID 129585554. Archived from the original on 2011-03-10. Retrieved 2011-06-01.
  44. Anon (2010). Mammal Anatomy: An Illustrated Guide. Marshall Cavendish. pp. 104–123. ISBN 978-0-7614-7882-9.
  45. Derocher, Andrew E.; Andersen, Magnus; Wiig, Øystein (2005). "Sexual dimorphism of polar bears" (PDF). Journal of Mammalogy. 86 (5): 895–901. doi:10.1644/1545-1542(2005)86[895:SDOPB]2.0.CO;2. Archived from the original (PDF) on 2014-02-02.
  46. Hunt, R. M. Jr. (1998). "Ursidae". In Janis, Christine M.; Scott, Kathleen M.; Jacobs, Louis L. (eds.). Evolution of Tertiary Mammals of North America, volume 1: Terrestrial carnivores, ungulates, and ungulatelike mammals. Cambridge, England: Cambridge University Press. pp. 174–195. ISBN 978-0-521-35519-3.
  47. Ward and Kynaston, pp. 124–125
  48. Bunnell, Fred (1984). Macdonald, D. (ed.). The Encyclopedia of Mammals. Facts on File. p. 87. ISBN 978-0-87196-871-5.
  49. Ward and Kynaston, pp. 117–121
  50. Weissengruber, G. E.; Forstenpointner, G.; Kübber-Heiss, A.; Riedelberger, K.; Schwammer, H.; Ganzberger, K. (2001). "Occurrence and structure of epipharyngeal pouches in bears (Ursidae)". Journal of Anatomy. 198 (3): 309–14. doi:10.1046/j.1469-7580.2001.19830309.x. PMC 1468220. PMID 11322723.
  51. Schwartz, C. C.; Miller, S. D.; Haroldson, M. A. (2003-11-19). "Grizzly Bear". In Feldhamer, G.; Thompson, B.; Chapman, J. (eds.). Wild Mammals of North America; biology, management and conservation. Johns Hopkins University Press. p. 562. ISBN 978-0-8018-7416-1.
  52. "Food Habits of Grizzly Bears and Black Bears in the Yellowstone Ecosystem". National Park Service. Archived from the original on 2017-01-28. Retrieved 18 January 2017.
  53. Ruiqiang Li; Fan, Wei; Tian, Geng; Zhu, Hongmei; He, Lin; Cai, Jing; Huang, Quanfei; Cai, Qingle; Li, Bo; Bai, Yinqi; Zhang, Zhihe; Zhang, Yaping; Wang, Wen; Li, Jun; Wei, Fuwen; Li, Heng; Jian, Min; Li, Jianwen; Zhang, Zhaolei; Nielsen, Rasmus; Li, Dawei; Gu, Wanjun; Yang, Zhentao; Xuan, Zhaoling; Ryder, Oliver A.; Leung, Frederick Chi-Ching; Zhou, Yan; Cao, Jianjun; Sun, Xiao; et al. (2010). "The sequence and de novo assembly of the giant panda genome". Nature. 463 (21): 311–317. Bibcode:2010Natur.463..311L. doi:10.1038/nature08696. PMC 3951497. PMID 20010809.
  54. Ward and Kynaston, p. 83
  55. Servheen, C.; Herrero, S.; Peyton, B. (1999). Bears: Status Survey and Conservation Action Plan. IUCN. pp. 5–10. ISBN 978-2-8317-0462-3. They are opportunistic omnivores whose diet varies from plant foliage, roots, and fruits; insect adults, larvae, and eggs; animal matter from carrion; animal matter from predation; and fish. Their dentition and digestive system reflects this varied diet.
  56. Ward and Kynaston, p.52
  57. Hamdine, Watik; Thévenot, Michel; Michaux, Jacques (1998). "Histoire récente de l'ours brun au Maghreb". Comptes Rendus de l'Académie des Sciences (in French). 321 (7): 565–570. Bibcode:1998CRASG.321..565H. doi:10.1016/S0764-4469(98)80458-7. PMID 10877599.
  58. Nowak, R. M. (2005). Walker's Carnivores of the World. Johns Hopkins University Press. p. 114. ISBN 978-0-8018-8032-2.
  59. Klinka, D. R.; Reimchen, T. E. (2002). "Nocturnal and diurnal foraging behaviour of brown bears ( Ursus arctos ) on a salmon stream in coastal British Columbia" (PDF). Canadian Journal of Zoology. 80 (8): 1317–1322. doi:10.1139/Z02-123. Archived (PDF) from the original on 2017-08-12. Retrieved 2017-01-07.
  60. Ward and Kynaston, 99
  61. Sandell, M. (1989). "The mating tactics and spacing patterns of solitary carnivores". Carnivore behavior, ecology, and evolution. Springer. pp. 164–182. doi:10.1007/978-1-4613-0855-3_7. ISBN 978-1-4613-0855-3.
  62. Stonorov, D.; Stokes, A. W. (1972). "Social behavior of the Alaska brown bear" (PDF). Bears: Their Biology and Management. 2: 232–242. doi:10.2307/3872587. JSTOR 3872587. Archived (PDF) from the original on 2013-07-22. Retrieved 2017-01-11.
  63. Ward and Kynaston, p. 130
  64. Hwang, Mei-Hsiu (2002). "Diets of Asiatic black bears in Taiwan, with Methodological and Geographical Comparisons" (PDF). Ursus. 13: 111–125. Archived (PDF) from the original on 2013-07-23. Retrieved 2012-12-22.
  65. Mattson, David. "Foraging Behavior of North American Bears" (PDF). Southwest Biological Science Center. Archived from the original (PDF) on 11 July 2007.
  66. Rue, Leonard Lee (1981). Furbearing Animals of North America. Crown Publishers. p. 129. ISBN 978-0-517-53942-2.
  67. Mattson, David J. (1998). "Diet and Morphology of Extant and Recently Extinct Northern Bears". Ursus, A Selection of Papers from the Tenth International Conference on Bear Research and Management, Fairbanks, Alaska, July 1995, and Mora, Sweden, September 1995. 10: 479–496. JSTOR 3873160.
  68. Ryan, Christopher; Pack, James C.; Igo, William K.; Billings, Anthony (2007). "Influence of mast production on black bear non-hunting mortalities in West Virginia". Ursus. 18 (1): 46–53. doi:10.2192/1537-6176(2007)18[46:IOMPOB]2.0.CO;2.
  69. Lumpkin, Susan; Seidensticker, John (2007). Giant Pandas. Collins. p. 63. ISBN 978-0-06-120578-1.
  70. Ward and Kynaston, pp. 89–92
  71. Dolberg, Frands (1 August 1992). "Progress in the utilization of urea-ammonia treated crop residues: biological and socio-economic aspects of animal production and application of the technology on small farms". University of Arhus. Archived from the original on 2011-07-07. Retrieved 10 August 2010.
  72. Ward and Kynaston, p. 87
  73. Joshi, Anup; Garshelis, David L.; Smith, James L. D. (1997). "Seasonal and Habitat-Related Diets of Sloth Bears in Nepal". Journal of Mammalogy. 1978 (2): 584–597. doi:10.2307/1382910. JSTOR 1382910.
  74. "What do bears like to eat in a beehive?". North American Bear Center. Archived from the original on 2017-04-06. Retrieved 5 April 2017.
  75. Ward and Kynaston, p. 89
  76. Ward and Kynaston, pp. 93–98
  77. Zager, Peter; Beecham, John (2006). "The role of American black bears and brown bears as predators on ungulates in North America". Ursus. 17 (2): 95–108. doi:10.2192/1537-6176(2006)17[95:TROABB]2.0.CO;2.
  78. "Animal Protein". North American bear Center. Archived from the original on 2017-03-23. Retrieved 22 March 2017.
  79. Ward and Kynaston, p. 92
  80. French, S. P.; French, M. G. (1990). "Predatory behavior of grizzly bears feeding on elk calves in Yellowstone National Park, 1986–1988" (PDF). International Conf. Bear Res. And Manage. 8: 335–341. doi:10.2307/3872937. JSTOR 3872937. Archived (PDF) from the original on 2013-07-22. Retrieved 2017-04-04.
  81. COSEWIC. Canadian Wildlife Service (2002). "Assessment and Update Status Report on the Grizzly Bear (Ursus arctos)" (PDF). Environment Canada. Retrieved 8 April 2007.
  82. Ward and Kynaston, p. 104
  83. Naughton, D. (2014). The Natural History of Canadian Mammals: Opossums and Carnivores. University of Toronto Press. pp. 218–219, 236, 251–252. ISBN 978-1-4426-4483-0.
  84. "Vocalizations and Body Language". North American Bear Center. Archived from the original on 2016-12-23. Retrieved 7 January 2017.
  85. Masterson, Linda (2016). Living With Bears Handbook: Expanded 2nd Edition. PixyJack Press. pp. 215–16. ISBN 978-1-936555-61-1.
  86. Peters, G.; Owen, M.; Rogers, L. (2007). "Humming in bears: a peculiar sustained mammalian vocalization". Acta Theriologica. 52 (4): 379–389. doi:10.1007/BF03194236. S2CID 24886480. Archived (PDF) from the original on 2014-02-03. Retrieved 2017-09-08.
  87. Laurie, A.; Seidensticker, J. (1977). "Behavioural ecology of the Sloth bear (Melursus ursinus)". Journal of Zoology. 182 (2): 187–204. doi:10.1111/j.1469-7998.1977.tb04155.x. Archived (PDF) from the original on 2017-03-27. Retrieved 2017-03-26.
  88. Jordan, R. H. (1976). "Threat behavior of the black bear (Ursus americanus)". Bears: Their Biology and Management. 40: 57–63. doi:10.2307/3872754. JSTOR 3872754. S2CID 89660730.
  89. Ward and Kynaston, p. 122
  90. Nie, Y.; Swaisgood, R. R.; Zhang, Z.; Hu, Y.; Ma, Y.; Wei, F. (2012). "Giant panda scent-marking strategies in the wild: role of season, sex and marking surface". Animal Behaviour. 84 (1): 39–44. doi:10.1016/j.anbehav.2012.03.026. S2CID 53256022.
  91. Owen, M. A.; Swaisgood, R. R.; Slocomb, C.; Amstrup, S. C.; Durner, G. M.; Simac, K.; Pessier, A. P. (2014). "An experimental investigation of chemical communication in the polar bear". Journal of Zoology. 295 (1): 36–43. doi:10.1111/jzo.12181.
  92. Eide, S.; Miller, S. "Brown Bear" (PDF). Alaska Department of Fish and Game. Archived (PDF) from the original on 2013-03-03. Retrieved 14 January 2016.
  93. Ward and Kynaston, pp. 138–141
  94. Lariviere, S. (2001). "Ursus americanus" (PDF). Mammalian Species. 647: 1–11. doi:10.1644/1545-1410(2001)647<0001:ua>2.0.co;2. Archived from the original (PDF) on 2016-03-16.
  95. Ward and Kynaston, pp. 144–148
  96. "Panda Facts". Pandas International. Archived from the original on 24 September 2015. Retrieved 26 August 2015.
  97. Ward and Kynaston, p. 132
  98. Bellemain, Eva; Swenson, Jon E.; Taberlet, Pierre (2006). "Mating Strategies in Relation to Sexually Selected Infanticide in a Non-Social Carnivore: The Brown Bear" (PDF). Ethology. 112 (3): 238–246. doi:10.1111/j.1439-0310.2006.01152.x. Archived (PDF) from the original on 2016-12-21. Retrieved 2017-05-02.
  99. Bellemain, E.; Zedrosser, A.; Manel, S.; Waits, L. P.; Taberlet, P.; Swenson, J. E. (2005). "The dilemma of female mate selection in the brown bear, a species with sexually selected infanticide". Proceedings of the Royal Society of London B: Biological Sciences. 273 (1584): 283–291. doi:10.1098/rspb.2005.3331. PMC 1560043. PMID 16543170.
  100. Swenson, J. E.; Dahle, B.; Sandegren, F. (2001). "Intraspecific predation in Scandinavian brown bears older than cubs-of-the-year". Ursus. 12: 81–91. JSTOR 3873233. Archived from the original on 2017-11-16. Retrieved 2017-01-14.
  101. Mörner, T.; Eriksson, H.; Bröjer, C.; Nilsson, K.; Uhlhorn, H.; Ågren, E.; af Segerstad, C.H.; Jansson, D.S.; Gavier-Widén, D. (2005). "Diseases and mortality in free-ranging brown bear (Ursus arctos), gray wolf (Canis lupus), and wolverine (Gulo gulo) in Sweden". Journal of Wildlife Diseases. 41 (2): 298–303. doi:10.7589/0090-3558-41.2.298. PMID 16107663.
  102. "Grizzly Bear". National Geographic.com. Archived from the original on 2017-04-21. Retrieved 29 April 2017.
  103. Gerhard Heldmeier (2011). "Life on low flame in hibernation". Science. 331 (6019): 866–867. Bibcode:2011Sci...331..866H. doi:10.1126/science.1203192. PMID 21330523. S2CID 31514297.
  104. Shimozuru, M.; et al. (2013). "Pregnancy during hibernation in Japanese black bears: effects on body temperature and blood biochemical profiles". Journal of Mammalogy. 94 (3): 618–627. doi:10.1644/12-MAMM-A-246.1. S2CID 86174817.
  105. Tøien, Ø.; et al. (2011). "Hibernation in Black Bears: Independence of Metabolic Suppression from Body Temperature". Science. 331 (6019): 906–909. Bibcode:2011Sci...331..906T. doi:10.1126/science.1199435. PMID 21330544. S2CID 20829847.
  106. Biel, M; Gunther, K. "Denning and Hibernation Behavior". Yellowstone National Park. National Park Service. Archived from the original on 2016-11-18. Retrieved 18 November 2016.
  107. McTaggart Cowan, I. (1972). "The Status and Conservation of Bears (Ursidae) of the World: 1970". Bears: Their Biology and Management. 2: 343–367. CiteSeerX 10.1.1.483.1402. doi:10.2307/3872596. JSTOR 3872596.
  108. Seryodkin, Ivan (2006). The ecology, behavior, management and conservation status of brown bears in Sikhote-Alin (in Russian). Far Eastern National University, Vladivostok, Russia. pp. 1–252. Archived from the original on 2013-12-24.
  109. Seryodkin; et al. (2003). "Denning ecology of brown bears and Asiatic black bears in the Russian Far East". Ursus. 14 (2): 159. Archived from the original on 2011-08-17. Retrieved 2014-10-05.
  110. Crum, James M.; Nettles, Victor F.; Davidson, William R. (1978). "Studies on endoparasites of the black bear (Ursus americanus) in the southeastern United States". Journal of Wildlife Diseases. 14 (2): 178–186. doi:10.7589/0090-3558-14.2.178. PMID 418189.
  111. Derocher, Andrew E. (2012). Polar Bears: A Complete Guide to Their Biology and Behavior. JHU Press. p. 212. ISBN 978-1-4214-0305-2.
  112. Emergence and Control of Zoonotic Ortho- and Paramyxovirus Diseases. John Libbey Eurotext. p. 167. ISBN 978-2-7420-0392-1.
  113. Williams, Elizabeth S.; Barker, Ian K. (2008). Infectious Diseases of Wild Mammals. John Wiley & Sons. p. 203. ISBN 978-0-470-34481-1.
  114. "Brown Bear – Threats Grizzlies: Found in 2% of their former range". WWF. Archived from the original on 2016-12-21. Retrieved 16 January 2017.
  115. Bacon, Heather (12 May 2008). "Implications of bear bile farming". Vet Times. Archived from the original on 2017-01-18. Retrieved 16 January 2017.
  116. "Keyword search: "Ursidae", Exact phrase, The entire database". IUCN. Archived from the original on 2011-08-05. Retrieved 16 January 2017.
  117. Pelton, Michael R.; Coley, Alex B.; Eason, Thomas H.; Doan Martinez; Diana L.; Pederson, Joel A.; van Manen, Frank T.; Weaver, Keith M. (1999). Chapter 8. American Black Bear Conservation Action Plan. IUCN. pp. 144–156. ISBN 978-2-8317-0462-3.
  118. Kellert, Stephen (1994). "Public Attitudes toward Bears and Their Conservation". Bears: Their Biology and Management. 9 (1): 43–50. doi:10.2307/3872683. JSTOR 3872683. S2CID 39632061.
  119. Andersone, Žanete; Ozolinš, Jānis (2004). "Public perception of large carnivores in Latvia". Ursus. 15 (2): 181–187. doi:10.2192/1537-6176(2004)015<0181:PPOLCI>2.0.CO;2.
  120. "Pandas gain world heritage status". BBC News. Retrieved 2019-08-22.
  121. Goldstein, Isaac; Paisley, Susanna; Wallace, Robert; Jorgenson, Jeffrey P.; Cuesta, Francisc; Castellanos, Armando (2006). "Andean bear–livestock conflicts: a review". Ursus. 17 (1): 8–15. doi:10.2192/1537-6176(2006)17[8:ABCAR]2.0.CO;2.
  122. Fredriksson, Gabriella (2005). "Human–sun bear conflicts in East Kalimantan, Indonesian Borneo". Ursus. 16 (1): 130–137. doi:10.2192/1537-6176(2005)016[0130:HBCIEK]2.0.CO;2.
  123. Clark, Douglas (2003). "Polar Bear–Human Interactions in Canadian National Parks, 1986–2000" (PDF). Ursus. 14 (1): 65–71. Archived (PDF) from the original on 2013-07-22. Retrieved 2012-12-22.
  124. Than, K. (2013). "Maulings by Bears: What's Behind the Recent Attacks?". National Geographic.com. Archived from the original on 2017-01-28. Retrieved 16 January 2017.
  125. Findeizen, Nikolai (2008). History of Music in Russia from Antiquity to 1800, Vol. 1: From Antiquity to the Beginning of the Eighteenth Century. Indiana University Press. p. 201. ISBN 978-0-253-02637-8.
  126. "Elizabethan Playhouses and Bear Baiting Arenas Given Protection". Historic England. 26 September 2016. Archived from the original on 2017-01-04. Retrieved 4 January 2017.
  127. Fraser, Angus M. (1995). The Gypsies. Blackwell. pp. 45–48, 226. ISBN 978-0-631-19605-1.
  128. "Trichinellosis Associated with Bear Meat". Archived from the original on 30 September 2006. Retrieved 4 October 2006.
  129. "Bear meat poisoning in Siberia". BBC News. 21 December 1997. Archived from the original on 2008-12-11. Retrieved 4 October 2006.
  130. Black, Richard (11 June 2007). "BBC Test kit targets cruel bear trade". BBC News. Archived from the original on 15 January 2009. Retrieved 1 January 2010.
  131. Ward and Kynaston, pp. 12–13
  132. Ward and Kynaston, p. 17
  133. Ward and Kynaston, pp. 20–21
  134. Wunn, Ina (2000). "Beginning of Religion". Numen. 47 (4): 417–452. doi:10.1163/156852700511612. S2CID 53595088.
  135. Kindaichi, Kyōsuke; Yoshida, Minori (Winter 1949). "The Concepts behind the Ainu Bear Festival (Kumamatsuri)". Southwestern Journal of Anthropology. 5 (4): 345–350. doi:10.1086/soutjanth.5.4.3628594. JSTOR 3628594. S2CID 155380619.
  136. Bonser, Wilfrid (1928). "The mythology of the Kalevala, with notes on bear-worship among the Finns". Folklore. 39 (4): 344–358. doi:10.1080/0015587x.1928.9716794. JSTOR 1255969.
  137. Chaussonnet, Valerie (1995). Native Cultures of Alaska and Siberia. Washington, D.C.: Arctic Studies Center. p. 112. ISBN 978-1-56098-661-4.
  138. Lee, Jung Young (1981). Korean Shamanistic Rituals. Mouton De Gruyter. pp. 14, 20. ISBN 978-90-279-3378-2.
  139. Room, Adrian (2006). Placenames of the World: Origins and Meanings of the Names for 6,600 Countries, Cities, Territories, Natural Features, and Historic Sites. McFarland. p. 57. ISBN 9780786422487.
  140. Burkert, Walter, Greek Religion, 1985:263.
  141. Ridpath, Ian. "Ptolemy's Almagest First printed edition, 1515". Retrieved 13 January 2017.
  142. Liddell, Henry George; Scott, Robert. "Ἀρκτοῦρος". A Greek-English Lexicon. Perseus. Archived from the original on 2017-03-07. Retrieved 23 January 2017.
  143. Schaefer, Bradley E. (November 2006). "The Origin of the Greek Constellations: Was the Great Bear constellation named before hunter nomads first reached the Americas more than 13,000 years ago?". Scientific American, reviewed at Brown, Miland (30 October 2006). "The Origin of the Greek Constellations". World History Blog. Archived from the original on 2017-04-01. Retrieved 9 April 2017; Berezkin, Yuri (2005). "The cosmic hunt: variants of a Siberian – North-American myth". Folklore. 31: 79–100. doi:10.7592/FEJF2005.31.berezkin.
  144. "Pooh celebrates his 80th birthday". BBC News. 24 December 2005. Archived from the original on 2006-04-25. Retrieved 23 January 2017.
  145. "About". Paddington.com. Archived from the original on 17 August 2016. Retrieved 19 January 2017.
  146. "Walt Morey, 84; Author of 'Gentle Ben'". Associated Press. 14 January 1992. Archived from the original on 2016-10-23. Retrieved 6 April 2017.
  147. Kennedy, Patrick, ed. (1866). "The Brown Bear of Norway". Legendary Fictions of the Irish Celts. Macmillan. pp. 57–67.
  148. Elms, Alan C. (July–September 1977). ""The Three Bears": Four Interpretations". The Journal of American Folklore. 90 (357): 257–273. doi:10.2307/539519. JSTOR 539519.
  149. Ashliman, D. L. (2004). Folk and Fairy Tales: A Handbook. Greenwood Publishing Group. pp. 114–115. ISBN 978-0-313-32810-7.
  150. Mallory, Michael (1998). Hanna-Barbera Cartoons. Hugh Lauter Levin. p. 44. ISBN 978-0-88363-108-9.
  151. Browne, Ray B.; Browne, Pat (2001). The Guide to United States Popular Culture. Popular Press. p. 944. ISBN 978-0-87972-821-2.
  152. Holmes, Elizabeth (9 February 2007). "Care Bears Receive a (Gentle) Makeover". The Wall Street Journal. Archived from the original on 2018-01-18. Retrieved 27 January 2017.
  153. Cannadine, David (1 February 2013). "A Point of View: The grownups with teddy bears". BBC. Archived from the original on 2017-04-25. Retrieved 21 January 2017.
  154. "What the West thinks about Russia is not necessarily true". Telegraph. 23 April 2009. Archived from the original on 2015-12-06. Retrieved 3 January 2017.
  155. "Forest Fire Prevention – Smokey Bear (1944–Present)". Ad Council. 1944-08-09. Archived from the original on 2010-12-02. Retrieved 2010-10-16.
  156. "Vision and Mission". Bear Trust International. 2002–2012. Archived from the original on 2014-02-26. Retrieved 8 March 2014.
  157. "Vital Ground". Archived from the original on 2019-01-20. Retrieved 2019-02-05.
  158. "Moon Bears". Archived from the original on 2014-03-09. Retrieved 2014-03-09.
  159. "Black Bear Conservation Coalition". Archived from the original on 2014-01-03. Retrieved 2014-03-09.
  160. "Polar Bears International". Archived from the original on 2014-03-08. Retrieved 2014-03-09.
  161. "Bornean Sun Bear Conservation Centre". Archived from the original on 2014-02-18.
  162. "Wildlife SOS".
  163. "Andean Bear Conservation Project". Archived from the original on 2014-02-18. Retrieved 2014-03-09.
  164. "Chengdu Research Base of Giant Panda Breeding". Archived from the original on 2014-03-15. Retrieved 2014-03-09.

Bibliography

Further reading

  • Domico, Terry; Newman, Mark (1988). Bears of the World. Facts on File, Inc. ISBN 978-0-8160-1536-8.
  • Faulkner, William (1942). The Bear. Curley Publishing. ISBN 978-0-7927-0537-6.
  • Brunner, Bernd (2007). Bears: A Brief History. Yale University Press. ISBN 978-0-300-12299-2.
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