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Mule deer

February 15, 2024

The mule deer (Odocoileus hemionus) is a deer indigenous to western North America; it is named for its ears, which are large like those of the mule. Two subspecies of mule deer are grouped into the black-tailed deer.[1][5][6][7][8][9]

Mule deer
Male (buck) near Elk Creek, Oregon
Female (doe) near Swall Meadows, California
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Artiodactyla
Family: Cervidae
Subfamily: Capreolinae
Genus: Odocoileus
Species:
O. hemionus
Binomial name
Odocoileus hemionus
Subspecies

10, but some disputed (see text)

Distribution map of subspecies:
  Sitka black-tailed deer (O. h. sitkensis)
  Columbian black-tailed deer (O. h. columbianus)
  California mule deer (O. h. californicus)
  southern mule deer (O. h. fuliginatus)
  peninsular mule deer (O. h. peninsulae)
  desert mule deer (O. h. eremicus)
  Rocky Mountain mule deer (O. h. hemionus)
Synonyms[3][4]
  • Cervus hemionus Rafinesque, 1817
  • Cervus auritus Warden, 1820
  • Cervus macrotis Say, 1823
  • Cervus lewisii Peale, 1848
  • Cariacus punctulatus Gray, 1852
  • Cervus richardsoni Audubon & Bahman, 1848
  • Eucervus pusilla Gray, 1873
  • Dorcelaphus crooki Mearns, 1897
  • Cariacus virgultus Hallock, 1899

Unlike the related white-tailed deer (Odocoileus virginianus), which is found throughout most of North America east of the Rocky Mountains and in the valleys of the Rocky Mountains from Idaho and Wyoming northward, mule deer are only found on the western Great Plains, in the Rocky Mountains, in the southwest United States, and on the west coast of North America. Mule deer have also been introduced to Argentina and Kauai, Hawaii.[5]

Taxonomy edit

Mule deer can be divided into two main groups: the mule deer (sensu stricto) and the black-tailed deer. The first group includes all subspecies, except O. h. columbianus and O. h. sitkensis, which are in the black-tailed deer group.[5] The two main groups have been treated as separate species, but they hybridize, and virtually all recent authorities treat the mule deer and black-tailed deer as conspecific.[1][5][6][7][9][10] Mule deer apparently evolved from the black-tailed deer.[9] Despite this, the mtDNA of the white-tailed deer and mule deer is similar, but differs from that of the black-tailed deer.[9] This may be the result of introgression, although hybrids between the mule deer and white-tailed deer are rare in the wild (apparently more common locally in West Texas), and the hybrid survival rate is low even in captivity.[8][9] Many claims of observations of wild hybrids are not legitimate, as identification based on external features is complicated.[8]

Subspecies edit

Some authorities have recognized O. h. crooki as a senior synonym of O. h. eremicus, but the type specimen of the former is a hybrid between the mule deer and white-tailed deer, so the name O. h. crooki is invalid.[5][11] Additionally, the validity of O. h. inyoensis has been questioned, and the two insular O. h. cerrosensis and O. h. sheldoni may be synonyms of O. h. eremicus or O. h. peninsulae.[10]

The 10 valid subspecies, based on the third edition of Mammal Species of the World, are:[5]

Description edit

 
Small herd of mule deer in the Sulphur Springs Valley of southern Arizona
 
Stotting mule deer
 
Female desert/burro mule deer (O. h. eremicus) in Truth or Consequences, New Mexico

The most noticeable differences between white-tailed and mule deer are ear size, tail color, and antler configuration. In many cases, body size is also a key difference. The mule deer's tail is black-tipped, whereas the white-tailed deer's is not. Mule deer antlers are bifurcated; they "fork" as they grow, rather than branching from a single main beam, as is the case with white-tails.

Each spring, a buck's antlers start to regrow almost immediately after the old antlers are shed. Shedding typically takes place in mid-February, with variations occurring by locale.

Although capable of running, mule deer are often seen stotting (also called pronking), with all four feet coming down together.

The mule deer is the larger of the three Odocoileus species on average, with a height of 80–106 cm (31–42 in) at the shoulders and a nose-to-tail length ranging from 1.2 to 2.1 m (3.9 to 6.9 ft). Of this, the tail may comprise 11.6 to 23 cm (4.6 to 9.1 in). Adult bucks normally weigh 55–150 kg (121–331 lb), averaging around 92 kg (203 lb), although trophy specimens may weigh up to 210 kg (460 lb). Does (female deer) are smaller and typically weigh from 43 to 90 kg (95 to 198 lb), with an average of around 68 kg (150 lb).[12][13][14][15]

Unlike the white-tailed, the mule deer does not generally show marked size variation across its range, although environmental conditions can cause considerable weight fluctuations in any given population. An exception to this is the Sitka deer subspecies (O. h. sitkensis). This race is markedly smaller than other mule deer, with an average weight of 54.5 kg (120 lb) and 36 kg (79 lb) in males and females, respectively.[16]

Seasonal behaviors edit

In addition to movements related to available shelter and food, the breeding cycle is important in understanding deer behavior. The rut or mating season usually begins in the fall as does go into estrus for a period of a few days, and males become more aggressive, competing for mates. Does may mate with more than one buck and go back into estrus within a month if they did not become pregnant. The gestation period is about 190–200 days, with fawns born in the spring.[17] The survival rate of the fawns during labor is about 50%.[18] Fawns stay with their mothers during the summer and are weaned in the fall after about 60–75 days. Mule deer females usually give birth to two fawns, although if it is their first time having a fawn, they often have just one.[17]

A buck's antlers fall off during the winter, then grow again in preparation for the next season's rut. The annual cycle of antler growth is regulated by changes in the length of the day.[17][19]

The size of mule deer groups follows a marked seasonal pattern. Groups are smallest during fawning season (June and July in Saskatchewan and Alberta) and largest in early gestation (winter; February and March in Saskatchewan and Alberta).[19]

Besides humans, the three leading predators of mule deer are coyotes, wolves, and cougars. Bobcats, Canada lynx, wolverines, American black bears, and grizzly bears may prey upon adult deer, but most often only attack fawns or infirm specimens, or eat a deer after it has died naturally. Bears and smaller-sized carnivores are typically opportunistic feeders and pose little threat to a strong, healthy mule deer.[13]

Diet and foraging behaviors edit

In 99 studies of mule deer diets, some 788 species of plants were eaten by mule deer, and their diets vary greatly depending on the season, geographic region, year, and elevation.[20] The studies[21] gave these data for Rocky Mountain mule deer diets:[22]

Shrubs and trees Forbs Grasses and grass-like plants
Winter 74% 15% 11% (varies 0–53%)
Spring 49% 25% 26% (varies 4–64%)
Summer 49% 46% (varies 3–77%) 3% (varies 0–22%)
Fall 60% 30% (varies 2–78%) 9% (varies 0–24%)

The diets of mule deer are very similar to those of white-tailed deer in areas where they coexist.[23][20] Mule deer are intermediate feeders rather than pure browsers or grazers; they predominantly browse but also eat forb vegetation, small amounts of grass and, where available, tree or shrub fruits such as beans, pods, nuts (including acorns), and berries.[20][22]

Mule deer readily adapt to agricultural products and landscape plantings.[24][25] In the Sierra Nevada range, mule deer depend on the lichen Bryoria fremontii as a winter food source.[26]

The most common plant species consumed by mule deer are the following:

Mule deer have also been known to eat ricegrass, gramagrass, and needlegrass, as well as bearberry, bitter cherry, black oak, California buckeye, ceanothus, cedar, cliffrose, cottonwood, creek dogwood, creeping barberry, dogwood, Douglas fir, elderberry, Fendlera species, goldeneye, holly-leaf buckthorn, jack pine, knotweed, Kohleria species, manzanita, mesquite, pine, rabbitbrush, ragweed, redberry, scrub oak, serviceberry (including Pacific serviceberry), Sierra juniper, silktassel, snowberry, stonecrop, sunflower, tesota, thimbleberry, turbinella oak, velvet elder, western chokecherry, wild cherry, and wild oats.[27] Where available, mule deer also eat a variety of wild mushrooms, which are most abundant in late summer and fall in the southern Rocky Mountains; mushrooms provide moisture, protein, phosphorus, and potassium.[20][27]

Humans sometimes engage in supplemental feeding efforts in severe winters in an attempt to help mule deer avoid starvation. Wildlife agencies discourage such efforts, which cause harm to mule deer populations by spreading disease (such as tuberculosis and chronic wasting disease) when deer congregate for feed, disrupting migratory patterns, causing overpopulation of local mule deer populations, and causing habitat destruction from overbrowsing of shrubs and forbs. Supplemental feeding efforts might be appropriate when carefully conducted under limited circumstances, but to be successful, the feeding must begin early in the severe winter (before poor range conditions and severe weather cause malnourishment or starvation) and must be continued until range conditions can support the herd.[28]

Mule deer are variably gregarious, with a large proportion of solitary individuals (35 to 64%) and small groups (groups with ≤5 deer, 50 to 78%).[29][30] Reported mean group size measurements are three to five and typical group size (i.e., crowding) is about seven.[19][31]

Nutrition edit

Mule deer are ruminants, meaning they employ a nutrient acquisition strategy of fermenting plant material before digesting it. Deer consuming high-fiber, low-starch diets require less food than those consuming high-starch, low-fiber diets. Rumination time also increases when deer consume high-fiber, low-starch diets, which allows for increased nutrient acquisition due to greater length of fermentation.[32] Because some of the subspecies of mule deer are migratory, they encounter variable habitats and forage quality throughout the year.[33] Forages consumed in the summer are higher in digestible components (i.e. proteins, starches, sugars, and hemicellulose) than those consumed in the winter. The average gross energy content of the consumed forage material is 4.5 kcal/g.[34]

Due to fluctuations in forage quality and availability, mule deer fat storage varies throughout the year, with the most fat stored in October, which is depleted throughout the winter to the lowest levels of fat storage in March. Changes in hormone levels are indications of physiological adjustments to the changes in the habitat. Total body fat is a measure of the individual's energy reserves, while thyroid hormone concentrations are a metric to determine the deer's ability to use the fat reserves. Triiodothyronine (T3) hormone is directly involved with basal metabolic rate and thermoregulation.[35]

Migration edit

 
The Grand Canyon, Mule Deer diorama at the Milwaukee Public Museum

Mule deer migrate from low elevation winter ranges to high elevation summer ranges.[36] Although not all individuals in populations migrate, some will travel long distances between summer and winter ranges.[37] Researchers discovered the longest mule deer migration in Wyoming spanning 150 miles from winter to summer range[36] Multiple US states track mule deer migrations.[38][39][40][41]

Mule deer migrate in fall to avoid harsh winter conditions like deep snow that covers up food resources, and in spring follow the emergence of new growth northwards.[42][43] There is evidence to suggest that mule deer migrate based on cognitive memory, meaning they use the same path year after year even if the availability of resources has changed. This contradicts the idea that animals will go to the areas with the best available resources, which makes migratory paths crucial for survival.[43]

Risks edit

There are many risks that mule deer face during migration including climate change and human disturbance. Climate change impacts on seasonal growth patterns constitute a risk for migrating mule deer by invalidating historic or learned migration paths.[44][45]

Human activities such as natural resource extraction, highways, fencing, and urban development all have an impact on mule deer populations and migrations through habitat degradation and fragmentation.[46][47][48][49] Natural gas extraction has been found to have varying negative effects on mule deer behavior and can even cause them to avoid areas they use to migrate.[46] Highways not only cause injury and death to mule deer, but they can also serve as a barrier to migration.[50] As traffic volumes increase, the more mule deer tend to avoid those areas and abandon their typical migration routes. It has also been found that fencing can alter deer behavior, acting as a barrier, and potentially changing mule deer migration patterns.[51] In addition, urban development has replaced mule deer habitat with subdivisions, and human activity has increased. As a result of this, researchers have seen a decline in mule deer populations. This is especially prominent in Colorado where the human population has grown by over 2.2 million since 1980.[49]

Management edit

Protecting migration corridors edit

Protecting migrations corridors is essential to maintain healthy mule deer populations. One thing everyone can do is help slow the increase in climate change by using greener energy sources and reducing the amount of waste in our households.[52] In addition, managers and researchers can assess the risks listed above and take the proper steps to mitigate any adverse impacts those risk have on mule deer populations. Not only will populations benefit from these efforts but so will many other wildlife species.[53]

Highways edit

One way to help protect deer from getting hit on roadways is to install high fence wildlife fencing with escape routes.[54] This helps keep deer off the road, preventing vehicle collisions and allowing animals that are trapped between the road and the fence a way to escape to safety.[54] However, to maintain migration routes that cross busy highways, managers have also implemented natural, vegetated, overpasses and underpasses to allow animals, like mule deer, to migrate and move safely across highways.[55]

Natural resource extraction edit

Approaches to mitigating the impact of drilling and mining operations include regulating the time of year when active drilling and heavy traffic to sites are taking place, and using well-informed planning to protect critical deer habitat and using barriers to mitigate the activity, noise, light at the extraction sites.[56]

Urban development edit

The increase in urbanization has impacted mule deer migrations and there is evidence to show it also disrupts gene flow among mule deer populations.[57] One clear option is to not build houses in critical mule deer habitat; however, build near mule deer habitat has resulted in some deer becoming accustom to humans and the resources, such as food and water.[58] Rather than migrate through urban areas some deer tend to stay close to those urban developments, potentially for resources and to avoid the obstacles in urban areas.[59] Suggested measures by property owners to protect mule deer genetic diversity and migration paths include planting deer-resistant plants, placing scare devices such as noise-makers, and desisting from feeding deer.[58]

Disease edit

Wildlife officials in Utah announced that a November–December 2021 field study had detected the first case of SARS-CoV-2 in mule deer. Several deer possessed apparent SARS-CoV-2 antibodies, however a female deer in Morgan County had an active Delta variant infection.[60] White-tailed deer, which are able to hybridize with mule deer and which have shown high rates of SARS-CoV-2 infection, have migrated into Morgan County and other traditional mule deer habitats since at least the early 2000s.[61][62]

References edit

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Further reading edit

  • Woodman, Neal (2015). "Who invented the mule deer (Odocoileus hemionus)? On the authorship of the fraudulent 1812 journal of Charles Le Raye". Archives of Natural History. 42 (1): 39–50. doi:10.3366/anh.2015.0277.

External links edit

 
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February 15, 2024
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The mule deer Odocoileus hemionus is a deer indigenous to western North America it is named for its ears which are large like those of the mule Two subspecies of mule deer are grouped into the black tailed deer 1 5 6 7 8 9 Mule deerMale buck near Elk Creek OregonFemale doe near Swall Meadows CaliforniaConservation statusLeast Concern IUCN 3 1 1 Scientific classificationDomain EukaryotaKingdom AnimaliaPhylum ChordataClass MammaliaOrder ArtiodactylaFamily CervidaeSubfamily CapreolinaeGenus OdocoileusSpecies O hemionusBinomial nameOdocoileus hemionusRafinesque 1817 2 Subspecies10 but some disputed see text Distribution map of subspecies Sitka black tailed deer O h sitkensis Columbian black tailed deer O h columbianus California mule deer O h californicus southern mule deer O h fuliginatus peninsular mule deer O h peninsulae desert mule deer O h eremicus Rocky Mountain mule deer O h hemionus Synonyms 3 4 Cervus hemionus Rafinesque 1817Cervus auritus Warden 1820Cervus macrotis Say 1823Cervus lewisii Peale 1848Cariacus punctulatus Gray 1852Cervus richardsoni Audubon amp Bahman 1848Eucervus pusilla Gray 1873Dorcelaphus crooki Mearns 1897Cariacus virgultus Hallock 1899Unlike the related white tailed deer Odocoileus virginianus which is found throughout most of North America east of the Rocky Mountains and in the valleys of the Rocky Mountains from Idaho and Wyoming northward mule deer are only found on the western Great Plains in the Rocky Mountains in the southwest United States and on the west coast of North America Mule deer have also been introduced to Argentina and Kauai Hawaii 5 Contents 1 Taxonomy 1 1 Subspecies 2 Description 3 Seasonal behaviors 4 Diet and foraging behaviors 5 Nutrition 6 Migration 6 1 Risks 6 2 Management 6 2 1 Protecting migration corridors 6 2 2 Highways 6 2 3 Natural resource extraction 6 2 4 Urban development 7 Disease 8 References 9 Further reading 10 External linksTaxonomy editMule deer can be divided into two main groups the mule deer sensu stricto and the black tailed deer The first group includes all subspecies except O h columbianus and O h sitkensis which are in the black tailed deer group 5 The two main groups have been treated as separate species but they hybridize and virtually all recent authorities treat the mule deer and black tailed deer as conspecific 1 5 6 7 9 10 Mule deer apparently evolved from the black tailed deer 9 Despite this the mtDNA of the white tailed deer and mule deer is similar but differs from that of the black tailed deer 9 This may be the result of introgression although hybrids between the mule deer and white tailed deer are rare in the wild apparently more common locally in West Texas and the hybrid survival rate is low even in captivity 8 9 Many claims of observations of wild hybrids are not legitimate as identification based on external features is complicated 8 Subspecies edit Some authorities have recognized O h crooki as a senior synonym of O h eremicus but the type specimen of the former is a hybrid between the mule deer and white tailed deer so the name O h crooki is invalid 5 11 Additionally the validity of O h inyoensis has been questioned and the two insular O h cerrosensis and O h sheldoni may be synonyms of O h eremicus or O h peninsulae 10 The 10 valid subspecies based on the third edition of Mammal Species of the World are 5 Mule deer sensu stricto group O h californicus California mule deer O h cerrosensis Cedros Cerros Island mule deer named after Cedros Island the only place the subspecies is found O h eremicus desert burro mule deer found in the Lower Colorado River Valley northwestern Mexico southeastern California and Arizona O h fuliginatus southern mule deer found in southernmost California and Baja California O h hemionus Rocky Mountain mule deer found in western and central North America O h inyoensis Inyo mule deer named after Inyo County California and found in the Sierra Nevada mountain range in California O h peninsulae peninsular mule deer found in Baja California Sur O h sheldoni Tiburon Island mule deer found on Tiburon Island Black tailed deer group O h columbianus Columbian black tailed deer found in the Pacific Northwest and Northern California regions O h sitkensis Sitka deer named after Sitka Alaska and found in the coastal area and islands off western British ColumbiaDescription edit nbsp Small herd of mule deer in the Sulphur Springs Valley of southern Arizona nbsp Stotting mule deer nbsp Female desert burro mule deer O h eremicus in Truth or Consequences New MexicoThe most noticeable differences between white tailed and mule deer are ear size tail color and antler configuration In many cases body size is also a key difference The mule deer s tail is black tipped whereas the white tailed deer s is not Mule deer antlers are bifurcated they fork as they grow rather than branching from a single main beam as is the case with white tails Each spring a buck s antlers start to regrow almost immediately after the old antlers are shed Shedding typically takes place in mid February with variations occurring by locale Although capable of running mule deer are often seen stotting also called pronking with all four feet coming down together The mule deer is the larger of the three Odocoileus species on average with a height of 80 106 cm 31 42 in at the shoulders and a nose to tail length ranging from 1 2 to 2 1 m 3 9 to 6 9 ft Of this the tail may comprise 11 6 to 23 cm 4 6 to 9 1 in Adult bucks normally weigh 55 150 kg 121 331 lb averaging around 92 kg 203 lb although trophy specimens may weigh up to 210 kg 460 lb Does female deer are smaller and typically weigh from 43 to 90 kg 95 to 198 lb with an average of around 68 kg 150 lb 12 13 14 15 Unlike the white tailed the mule deer does not generally show marked size variation across its range although environmental conditions can cause considerable weight fluctuations in any given population An exception to this is the Sitka deer subspecies O h sitkensis This race is markedly smaller than other mule deer with an average weight of 54 5 kg 120 lb and 36 kg 79 lb in males and females respectively 16 Seasonal behaviors editIn addition to movements related to available shelter and food the breeding cycle is important in understanding deer behavior The rut or mating season usually begins in the fall as does go into estrus for a period of a few days and males become more aggressive competing for mates Does may mate with more than one buck and go back into estrus within a month if they did not become pregnant The gestation period is about 190 200 days with fawns born in the spring 17 The survival rate of the fawns during labor is about 50 18 Fawns stay with their mothers during the summer and are weaned in the fall after about 60 75 days Mule deer females usually give birth to two fawns although if it is their first time having a fawn they often have just one 17 A buck s antlers fall off during the winter then grow again in preparation for the next season s rut The annual cycle of antler growth is regulated by changes in the length of the day 17 19 The size of mule deer groups follows a marked seasonal pattern Groups are smallest during fawning season June and July in Saskatchewan and Alberta and largest in early gestation winter February and March in Saskatchewan and Alberta 19 Besides humans the three leading predators of mule deer are coyotes wolves and cougars Bobcats Canada lynx wolverines American black bears and grizzly bears may prey upon adult deer but most often only attack fawns or infirm specimens or eat a deer after it has died naturally Bears and smaller sized carnivores are typically opportunistic feeders and pose little threat to a strong healthy mule deer 13 Diet and foraging behaviors editIn 99 studies of mule deer diets some 788 species of plants were eaten by mule deer and their diets vary greatly depending on the season geographic region year and elevation 20 The studies 21 gave these data for Rocky Mountain mule deer diets 22 Shrubs and trees Forbs Grasses and grass like plantsWinter 74 15 11 varies 0 53 Spring 49 25 26 varies 4 64 Summer 49 46 varies 3 77 3 varies 0 22 Fall 60 30 varies 2 78 9 varies 0 24 The diets of mule deer are very similar to those of white tailed deer in areas where they coexist 23 20 Mule deer are intermediate feeders rather than pure browsers or grazers they predominantly browse but also eat forb vegetation small amounts of grass and where available tree or shrub fruits such as beans pods nuts including acorns and berries 20 22 Mule deer readily adapt to agricultural products and landscape plantings 24 25 In the Sierra Nevada range mule deer depend on the lichen Bryoria fremontii as a winter food source 26 The most common plant species consumed by mule deer are the following Among trees and shrubs Artemisia tridentata big sagebrush Cercocarpus ledifolius curlleaf mountain mahogany Cercocarpus montanus true mountain mahogany Cowania mexicana Mexican cliffrose Populus tremuloides quaking aspen Purshia tridentata antelope bitterbrush Quercus gambelii Gambel oak and Rhus trilobata skunkbush sumac 22 Among forbs Achillea millefolium western yarrow Antennaria pussytoes species Artemisia frigida fringed sagebrush Artemisia ludoviciana Louisiana sagewort Aster species Astragalus milkvetch species Balsamorhiza sagittata arrowleaf balsamroot Cirsium thistle species Erigeron fleabane species Geranium species Lactuca serriola prickly lettuce Lupinus lupine species alfalfa Penstemon species Phlox species Polygonum knotweed smartweed species Potentilla cinquefoil species Taraxacum officinale dandelion Tragopogon dubius western salsify clover and Vicia americana American vetch 22 Among grasses and grasslike species Agropyron Elymus wheatgrasses Elytrigia Pascopyrum species wheatgrasses Pseudoroegneria spicatum bluebunch wheatgrass Bromus tectorum cheatgrass Carex sedge species Festuca idahoensis Idaho fescue Poa fendleriana muttongrass Poa pratensis Kentucky bluegrass and other Poa bluegrass species 22 Mule deer have also been known to eat ricegrass gramagrass and needlegrass as well as bearberry bitter cherry black oak California buckeye ceanothus cedar cliffrose cottonwood creek dogwood creeping barberry dogwood Douglas fir elderberry Fendlera species goldeneye holly leaf buckthorn jack pine knotweed Kohleria species manzanita mesquite pine rabbitbrush ragweed redberry scrub oak serviceberry including Pacific serviceberry Sierra juniper silktassel snowberry stonecrop sunflower tesota thimbleberry turbinella oak velvet elder western chokecherry wild cherry and wild oats 27 Where available mule deer also eat a variety of wild mushrooms which are most abundant in late summer and fall in the southern Rocky Mountains mushrooms provide moisture protein phosphorus and potassium 20 27 Humans sometimes engage in supplemental feeding efforts in severe winters in an attempt to help mule deer avoid starvation Wildlife agencies discourage such efforts which cause harm to mule deer populations by spreading disease such as tuberculosis and chronic wasting disease when deer congregate for feed disrupting migratory patterns causing overpopulation of local mule deer populations and causing habitat destruction from overbrowsing of shrubs and forbs Supplemental feeding efforts might be appropriate when carefully conducted under limited circumstances but to be successful the feeding must begin early in the severe winter before poor range conditions and severe weather cause malnourishment or starvation and must be continued until range conditions can support the herd 28 Mule deer are variably gregarious with a large proportion of solitary individuals 35 to 64 and small groups groups with 5 deer 50 to 78 29 30 Reported mean group size measurements are three to five and typical group size i e crowding is about seven 19 31 source source source source source source source source Mule deer foraging on a late winter morning at Okanagan Mountain Provincial Park nbsp Male Rocky Mountain mule deer O h hemionus in Zion National Park nbsp Male O h hemionus near Leavenworth Washington nbsp Female Columbian black tailed deer O h columbianus in Olympic National Park nbsp Female mule deer in Garden of the Gods Colorado Springs Colorado USA Nutrition editMule deer are ruminants meaning they employ a nutrient acquisition strategy of fermenting plant material before digesting it Deer consuming high fiber low starch diets require less food than those consuming high starch low fiber diets Rumination time also increases when deer consume high fiber low starch diets which allows for increased nutrient acquisition due to greater length of fermentation 32 Because some of the subspecies of mule deer are migratory they encounter variable habitats and forage quality throughout the year 33 Forages consumed in the summer are higher in digestible components i e proteins starches sugars and hemicellulose than those consumed in the winter The average gross energy content of the consumed forage material is 4 5 kcal g 34 Due to fluctuations in forage quality and availability mule deer fat storage varies throughout the year with the most fat stored in October which is depleted throughout the winter to the lowest levels of fat storage in March Changes in hormone levels are indications of physiological adjustments to the changes in the habitat Total body fat is a measure of the individual s energy reserves while thyroid hormone concentrations are a metric to determine the deer s ability to use the fat reserves Triiodothyronine T3 hormone is directly involved with basal metabolic rate and thermoregulation 35 Migration edit nbsp The Grand Canyon Mule Deer diorama at the Milwaukee Public MuseumMule deer migrate from low elevation winter ranges to high elevation summer ranges 36 Although not all individuals in populations migrate some will travel long distances between summer and winter ranges 37 Researchers discovered the longest mule deer migration in Wyoming spanning 150 miles from winter to summer range 36 Multiple US states track mule deer migrations 38 39 40 41 Mule deer migrate in fall to avoid harsh winter conditions like deep snow that covers up food resources and in spring follow the emergence of new growth northwards 42 43 There is evidence to suggest that mule deer migrate based on cognitive memory meaning they use the same path year after year even if the availability of resources has changed This contradicts the idea that animals will go to the areas with the best available resources which makes migratory paths crucial for survival 43 Risks edit There are many risks that mule deer face during migration including climate change and human disturbance Climate change impacts on seasonal growth patterns constitute a risk for migrating mule deer by invalidating historic or learned migration paths 44 45 Human activities such as natural resource extraction highways fencing and urban development all have an impact on mule deer populations and migrations through habitat degradation and fragmentation 46 47 48 49 Natural gas extraction has been found to have varying negative effects on mule deer behavior and can even cause them to avoid areas they use to migrate 46 Highways not only cause injury and death to mule deer but they can also serve as a barrier to migration 50 As traffic volumes increase the more mule deer tend to avoid those areas and abandon their typical migration routes It has also been found that fencing can alter deer behavior acting as a barrier and potentially changing mule deer migration patterns 51 In addition urban development has replaced mule deer habitat with subdivisions and human activity has increased As a result of this researchers have seen a decline in mule deer populations This is especially prominent in Colorado where the human population has grown by over 2 2 million since 1980 49 Management edit Protecting migration corridors edit Protecting migrations corridors is essential to maintain healthy mule deer populations One thing everyone can do is help slow the increase in climate change by using greener energy sources and reducing the amount of waste in our households 52 In addition managers and researchers can assess the risks listed above and take the proper steps to mitigate any adverse impacts those risk have on mule deer populations Not only will populations benefit from these efforts but so will many other wildlife species 53 Highways edit One way to help protect deer from getting hit on roadways is to install high fence wildlife fencing with escape routes 54 This helps keep deer off the road preventing vehicle collisions and allowing animals that are trapped between the road and the fence a way to escape to safety 54 However to maintain migration routes that cross busy highways managers have also implemented natural vegetated overpasses and underpasses to allow animals like mule deer to migrate and move safely across highways 55 Natural resource extraction edit Approaches to mitigating the impact of drilling and mining operations include regulating the time of year when active drilling and heavy traffic to sites are taking place and using well informed planning to protect critical deer habitat and using barriers to mitigate the activity noise light at the extraction sites 56 Urban development edit The increase in urbanization has impacted mule deer migrations and there is evidence to show it also disrupts gene flow among mule deer populations 57 One clear option is to not build houses in critical mule deer habitat however build near mule deer habitat has resulted in some deer becoming accustom to humans and the resources such as food and water 58 Rather than migrate through urban areas some deer tend to stay close to those urban developments potentially for resources and to avoid the obstacles in urban areas 59 Suggested measures by property owners to protect mule deer genetic diversity and migration paths include planting deer resistant plants placing scare devices such as noise makers and desisting from feeding deer 58 Disease editWildlife officials in Utah announced that a November December 2021 field study had detected the first case of SARS CoV 2 in mule deer Several deer possessed apparent SARS CoV 2 antibodies however a female deer in Morgan County had an active Delta variant infection 60 White tailed deer which are able to hybridize with mule deer and which have shown high rates of SARS CoV 2 infection have migrated into Morgan County and other traditional mule deer habitats since at least the early 2000s 61 62 References edit a b c Sanchez Rojas G Gallina Tessaro S 2016 Odocoileus hemionus IUCN Red List of Threatened Species 2016 e T42393A22162113 doi 10 2305 IUCN UK 2016 1 RLTS T42393A22162113 en Retrieved 12 November 2021 Odocoileus hemionus Integrated Taxonomic Information System Retrieved 23 March 2006 Anderson Allen E Wallmo Olof C 27 April 1984 Odocoileus hemionus Mammalian Species 219 1 9 doi 10 2307 3504024 JSTOR 3504024 Rafinesque Constantine Samuel 1817 Extracts from the Journal of Mr Charles Le Raye relating to some new Quadrupeds of the Missouri Region with Notes The American Monthly Magazine and Critical Review 1 6 436 hdl 2027 mdp 39015073310313 a b c d e f Wilson D E Reeder D M eds 2005 Mammal Species of the World A Taxonomic and Geographic Reference 3rd ed Johns Hopkins University Press ISBN 978 0 8018 8221 0 OCLC 62265494 a b Nowak Ronald M 7 April 1999 Walker s Mammals of the World JHU Press ISBN 978 0 8018 5789 8 via Internet Archive a b Reid Fiona A 15 November 2006 Peterson Field Guide to Mammals of North America 4th ed Houghton Mifflin Harcourt ISBN 0 547 34553 4 a b c Heffelfinger J March 2011 Tails with a Dark Side The truth about whitetail mule deer hybrids Coues Whitetail Archived from the original on 9 February 2014 Retrieved 8 January 2014 a b c d e Geist Valerius January 1998 Deer of the World Their Evolution Behaviour and Ecology Stackpole Books ISBN 978 0 8117 0496 0 a b Feldhamer George A Thompson Bruce C Chapman Joseph A 19 November 2003 Wild Mammals of North America Biology Management and Conservation JHU Press ISBN 978 0 8018 7416 1 Heffelfinger J 11 April 2000 Status of the name Odocoileus hemionus crooki Mammalia Cervidae PDF Proceedings of the Biological Society of Washington 113 1 319 333 Archived PDF from the original on 15 September 2020 Petersen David 1 November 1985 North American Deer Mule Whitetail and Coastal Blacktail Deer Mother Earth News Ogden Publications Archived from the original on 15 March 2012 Retrieved 4 January 2012 a b Misuraca Michael 1999 Odocoileus hemionus mule deer Animal Diversity Web University of Michigan Museum of Zoology Archived from the original on 15 September 2020 Burnie David 1 September 2011 Animal The Definitive Visual Guide to the World s Wildlife Dorling Kindersley Limited ISBN 978 1 4053 6233 7 Timm Robert M Slade Norman A Pisani George R Mule Deer Odocoileus hemionus Rafinesque Mammals of Kansas Archived from the original on 1 July 2015 Retrieved 8 January 2014 Sitka Black tailed Deer Hunting Information Alaska Department of Fish and Game 2014 Archived from the original on 23 January 2016 Retrieved 8 January 2014 a b c Animal Fact Sheet Mule Deer Arizona Sonora Desert Museum 2008 Archived from the original on 15 September 2020 Retrieved 22 May 2012 Anderson Mike 5 March 2019 DWR Biologists Use Helicopter Rides Ultrasound To Check on Deer Pregnancies KSL TV Cache County UT Bonneville International Archived from the original on 4 February 2020 Retrieved 13 March 2019 a b c Mejia Salazar Maria Fernanda Waldner Cheryl Stookey Joseph Bollinger Trent K 23 March 2016 Infectious Disease and Grouping Patterns in Mule Deer PLOS One 11 3 e0150830 Bibcode 2016PLoSO 1150830M doi 10 1371 journal pone 0150830 ISSN 1932 6203 PMC 4805189 PMID 27007808 a b c d Heffelfinger Jim September 2006 Deer of the Southwest A Complete Guide to the Natural History Biology and Management of Southwestern Mule Deer and White tailed Deer Texas A amp M University Press pp 97 111 ISBN 1585445150 Kufeld Roland C Wallmo O C Feddema Charles July 1973 Foods of the Rocky Mountain Mule Deer Report USDA Forest Service OL 14738499M via Internet Archive a b c d e Colorado Natural Resources Conservation Service March 2000 Mule Deer Odocoileus hemionus Fact Sheet PDF USDA Archived PDF from the original on 15 September 2020 Anthony Robert G Smith Norman S February 1977 Ecological Relationships between Mule Deer and White Tailed Deer in Southeastern Arizona Ecological Monographs 47 3 255 277 doi 10 2307 1942517 hdl 10150 287962 JSTOR 1942517 Armstrong David M 19 June 2012 Species Profile Deer Colorado Division of Wildlife Archived from the original on 8 January 2014 Retrieved 8 January 2014 Martin Alexander Campbell Zim Herbert Spencer Nelson Arnold L 1961 American Wildlife amp Plants A Guide to Wildlife Food Habits The Use of Trees Shrubs Weeds and Herbs by Birds and Mammals of the United States Dover Publications ISBN 978 0 486 20793 3 via Internet Archive McCune Bruce Grenon Jill Mutch Linda S Martin Erin P 2007 Lichens in relation to management issues in the Sierra Nevada national parks North American Fungi 2 2 4 doi 10 2509 pnwf 2007 002 003 a b Rue Leonard Lee III October 1997 The Deer of North America Lyons Press pp 499 502 ISBN 1558215778 Mule Deer Changing Landscapes Changing Perspectives Supplemental Feeding Just Say No PDF Report Western Association of Fish and Wildlife Agencies Mule Deer Working Group pp 25 26 Archived PDF from the original on 29 May 2020 via Utah Division of Wildlife Resources Kucera Thomas E 21 August 1978 Social Behavior and Breeding System of the Desert Mule Deer Journal of Mammalogy 59 3 463 476 doi 10 2307 1380224 ISSN 0022 2372 JSTOR 1380224 Bowyer R Terry McCullough Dale R Belovsky G E Causes and consequences of sociality in mule deer PDF Alces 37 2 371 402 Archived PDF from the original on 15 September 2020 Reiczigel Jeno Mejia Salazar Maria Fernanda Bollinger Trent K Rozsa Lajos 1 December 2015 Comparing radio tracking and visual detection methods to quantify group size measures European Journal of Ecology 1 2 1 4 doi 10 1515 eje 2015 0011 S2CID 52990318 McCusker S Shipley L A Tollefson T N Griffin M Koutsos E A 3 July 2011 Effects of starch and fibre in pelleted diets on nutritional status of mule deer Odocoileus hemionus fawns Journal of Animal Physiology and Animal Nutrition 95 4 489 498 doi 10 1111 j 1439 0396 2010 01076 x PMID 21091543 deCalesta David S Nagy Julius G Bailey James A October 1975 Starving and Refeeding Mule Deer The Journal of Wildlife Management 39 4 663 doi 10 2307 3800224 JSTOR 3800224 Wallmo O C Carpenter L H Regelin W L Gill R B Baker D L March 1977 Evaluation of Deer Habitat on a Nutritional Basis Journal of Range Management 30 2 122 doi 10 2307 3897753 hdl 10150 646885 JSTOR 3897753 Bergman Eric J Doherty Paul F Bishop Chad J Wolfe Lisa L Banulis Bradley A Kaltenboeck Bernhard 3 September 2014 Herbivore Body Condition Response in Altered Environments Mule Deer and Habitat Management PLOS One 9 9 e106374 Bibcode 2014PLoSO 9j6374B doi 10 1371 journal pone 0106374 PMC 4153590 PMID 25184410 a b Red Desert to Hoback Migration Assessment Wyoming Migration Initiative migrationinitiative org Retrieved 25 February 2021 Aug 20 Emily Benson Now 2018 From the print edition Like Tweet Email Print Subscribe Donate 20 August 2018 The long strange trip of Deer 255 www hcn org Retrieved 25 February 2021 a href Template Cite web html title Template Cite web cite web a CS1 maint numeric names authors list link Colorado Parks amp Wildlife Species Data Mule Deer Migration Corridors Colorado GeoLibrary geo colorado edu Retrieved 25 February 2021 New big game studies in Montana aimed at declining numbers disease goHUNT Archived from the original on 22 October 2020 Retrieved 25 February 2021 Mule Deer Initiative Idaho Fish and Game 19 September 2016 Retrieved 25 February 2021 Lewis Gary Central Oregon mule deer migrations in crisis The Bulletin Retrieved 25 February 2021 UNDERSTANDING MULE DEER MIGRATIONFact Sheet 12 PDF Mule Deer Working Group Fact Sheet a b New study Migrating mule deer don t need directions EurekAlert Retrieved 15 March 2021 Impacts of climate change on migrating mule deer ScienceDaily Retrieved 6 April 2021 Aikens Ellen O Monteith Kevin L Merkle Jerod A Dwinnell Samantha P H Fralick Gary L Kauffman Matthew J August 2020 Drought reshuffles plant phenology and reduces the foraging benefit of green wave surfing for a migratory ungulate Global Change Biology 26 8 4215 4225 Bibcode 2020GCBio 26 4215A doi 10 1111 gcb 15169 ISSN 1354 1013 PMID 32524724 S2CID 219586821 a b Sawyer Hall Kauffman Matthew J Nielson Ryan M September 2009 Influence of Well Pad Activity on Winter Habitat Selection Patterns of Mule Deer Journal of Wildlife Management 73 7 1052 1061 doi 10 2193 2008 478 ISSN 0022 541X S2CID 26214504 Coe Priscilla K Nielson Ryan M Jackson Dewaine H Cupples Jacqueline B Seidel Nigel E Johnson Bruce K Gregory Sara C Bjornstrom Greg A Larkins Autumn N Speten David A June 2015 Identifying migration corridors of mule deer threatened by highway development Mule Deer Migration and Highways Wildlife Society Bulletin 39 2 256 267 doi 10 1002 wsb 544 Abandoned Fencing Is Detrimental to Mule Deer and Other Wildlife John In The Wild 9 May 2019 Retrieved 6 April 2021 a b New Study Finds That Expanding Development Is Associated With Declining Deer Recruitment Across Western Colorado newsroom wcs org Retrieved 6 April 2021 Sawyer Hall Kauffman Matthew J Middleton Arthur D Morrison Thomas A Nielson Ryan M Wyckoff Teal B 5 December 2012 A framework for understanding semi permeable barrier effects on migratory ungulates Journal of Applied Ecology 50 1 68 78 doi 10 1111 1365 2664 12013 ISSN 0021 8901 New study reveals how fences hinder migratory wildlife in Western US ScienceDaily Retrieved 6 April 2021 July 17 Denchak 2017 Melissa How You Can Stop Global Warming NRDC Retrieved 6 April 2021 a href Template Cite web html title Template Cite web cite web a CS1 maint numeric names authors list link Protecting big game migration corridors NFWF Retrieved 6 April 2021 a b Siemers Jeremy L Wilson Kenneth R Baruch Mordo Sharon May 2015 MONITORING WILDLIFE VEHICLE COLLISIONS ANALYSIS AND COST BENEFIT OF ESCAPE RAMPS FOR DEER AND ELK ON U S HIGHWAY 550 Colorado Department of Transportation Applied Research and Innovation Branch staff the Star Tribune Wyoming wildlife crossings labeled success Casper Star Tribune Online Retrieved 7 April 2021 Study quantifies natural gas development impacts on mule deer SOURCE 12 August 2015 Retrieved 7 April 2021 Fraser Devaughn L Ironside Kirsten Wayne Robert K Boydston Erin E May 2019 Connectivity of mule deer Odocoileus hemionus populations in a highly fragmented urban landscape Landscape Ecology 34 5 1097 1115 doi 10 1007 s10980 019 00824 9 ISSN 0921 2973 S2CID 145022000 a b URBAN MULE DEER ISSUES Fact Sheet 9 PDF Mule Deer Working Group Fact Sheet July 2014 UNDERSTANDING MULE DEER MIGRATION Fact Sheet 12 PDF Mule Deer Working Group July 2014 Harkins Paighten 29 March 2022 Utah mule deer is 1st in U S to test positive for COVID 19 The Salt Lake Tribune Archived from the original on 29 March 2022 Retrieved 29 March 2022 Prettyman Brett 19 October 2008 Hunting Whitetail deer influx brings mixed reaction The Salt Lake Tribune Archived from the original on 29 March 2022 Jacobs Andrew 2 November 2021 Widespread Coronavirus Infection Found in Iowa Deer New Study Says The New York Times Archived from the original on 2 November 2021 Retrieved 5 November 2021 Further reading editWoodman Neal 2015 Who invented the mule deer Odocoileus hemionus On the authorship of the fraudulent 1812 journal of Charles Le Raye Archives of Natural History 42 1 39 50 doi 10 3366 anh 2015 0277 External links edit nbsp Wikimedia Commons has media related to Odocoileus hemionus nbsp Wikispecies has information related to Odocoileus hemionus Mule Deer Odocoileus hemionus Rafinesque 1817 at the Encyclopedia of Life Retrieved from https en wikipedia org w index php title Mule deer amp oldid 1185441539, wikipedia, wiki, book, books, library,

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