White-footed mouse

Species of mammal

White-footed mouse
Conservation status

Least Concern  (IUCN 3.1)[1]
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Rodentia
Family: Cricetidae
Subfamily: Neotominae
Genus: Peromyscus
Species:
P. leucopus
Binomial name
Peromyscus leucopus
(Rafinesque, 1818)

The white-footed mouse (Peromyscus leucopus) is a rodent native to North America from Ontario, Quebec, Labrador, and the Maritime Provinces (excluding the island of Newfoundland) to the southwestern United States and Mexico.[1] In the Maritimes, its only location is a disjunct population in southern Nova Scotia.[2] It is also known as the woodmouse, particularly in Texas.

Description

Adults are 90–100 mm (3.5–3.9 in) in length, not counting the tail, which can add another 63–97 mm (2.5–3.8 in). A young adult weighs 20–30 g (0.7–1.1 oz). While their maximum lifespan is 96 months, the mean life expectancy for the species is 45.5 months for females and 47.5 for males. In northern climates, the average life expectancy is 12–24 months.[3] The species is similar to Peromyscus maniculatus.[4]

Behavior and diet

White-footed mice are omnivorous, and eat seeds and insects. They are particularly voracious predators of the pupal stage of the invasive spongy moth (formerly termed the gypsy moth).[5] They are timid and generally avoid humans, but they occasionally take up residence in ground-floor walls of homes and apartments, where they build nests and store food.[6] White-footed mice spend substantial time in trees and bushes, sometimes taking unoccupied old bird nests and building roofs on them.[7]

Female with sucklings

Diseases

Like the North American deer mouse, this species may carry hantaviruses, which can cause severe illness in humans. It has also been found to be a competent reservoir for the Lyme disease–causing spirochete, Borrelia burgdorferi.[8] The white-footed mouse is the favored host for the parasitic botfly Cuterebra fontinella.[9]

Interactions with humans

The white-footed mouse is one of the most common mouse species used as laboratory mice after the house mouse, and their domesticated version is called Peromyscus leucopus linville.[10] Such domesticated mice are also kept as pets[11][12] and have been bred to have many different colors.[13]

Adaptations to urbanization in New York City

Native populations of P. leucopus in New York city are isolated by dense human infrastructure and are largely confined to small urban forest islands such as Prospect Park and Central Park.[14] The limited gene flow caused by human activities and coupled with a bottleneck event in urban populations has been powerful enough to lead to evolutionary divergence of urban white-footed mice.[14][15]

Metabolism

New York City mice exhibit local adaptations to diet-mediated selective pressures of urban habitats. Being opportunistic feeders, urban P. leucopus populations subsist on food discarded by humans as a readily available source of nutriment, thereby consuming a lot more fat and carbohydrates than rural populations.[16] Results of a landscape genomics study showed evidence of positive selection in mitochondrial genes of urban mice that are responsible for lipid and carbohydrate breakdown and digestion.[16] Isolated P. leucopus populations inhabiting NYC parks show signs of molecular-level adaptation to urban food resources.[16] The differential evolution of metabolic processes in urban P. leucopus populations is thought to contribute to their success and survival in NYC urban forests.[16] Furthermore, the morphology of urban white-footed mice may be changing to adapt to alternative food sources. For instance, the teeth of white-footed mice in New York City are shorter than the teeth of rural mice.[16] This change in physical traits could be explained by the availability of higher-quality food sources in urban forests, which negates the need for long, powerful teeth.[16]

Detoxification

Urban populations of P. leucopus may be under unique selective pressures due to increased routine exposure to pollutants and toxins. A comparative transcriptome study found evidence of positive selection acting on the genes of urban mice that play major roles in detoxification and xenobiotic metabolism.[17] The genes under positive selection pressure include CYPA1A and Hsp90, which are known to be involved in the metabolism of foreign substances and drugs.[18] High concentrations of heavy metals such as lead and mercury in NYC park soils pose a unique selective pressure that likely led urban populations of P. leucopus to develop metabolic adaptations to the toxicity of urban forest environments.[17] Furthermore, exposure of pollutants is known to induce hypermethylation of DNA.[18] A study showed that in urban white-footed mice, a gene coding for a demethylase enzyme is under positive selection.[18] This means that urban populations of white-footed mice that live in highly polluted environments uniquely benefit from an active demethylase enzyme that removes methyl groups from DNA.[18]

Reproduction

City-dwelling white-footed mouse populations are densely concentrated in isolated urban parks, which makes sperm competition a particularly powerful source of selection in urban environments.[19] Genetic studies have identified signs of molecular-level evolution of reproductive processes in urban white-footed mouse populations. Genes associated with spermatogenesis, sperm locomotion, and sperm-egg interactions in urban mice show a divergent pattern of regulation compared to their rural counterparts.[19] Therefore, the intensified sperm competition of dense mouse populations in urban forests has driven them to develop faster, more efficient sperm than that of rural mice.

Immunity

Urban environments are saturated with large numbers of novel and familiar pathogens that are introduced by transportation, traffic, and trade.[20] The elevated occurrence of pathogens is a driver of directional selection in which genetic variants that more efficiently resist infection are favored. The outcome of this selection can be seen in genetic divergence between urban and rural P. leucopus populations at loci that regulate the innate immune response and inflammation.[21] Furthermore, a study has found evidence of positive selection acting on genes that modulate pathogen recognition in urban mice.[21] Immunoregulatory proteins that are found on T lymphocytes are overexpressed in urban mice when compared to rural populations.[21] These findings suggest that the immune systems of NYC white-footed mice may be evolving to recognize and respond to pathogens more efficiently. The divergence between rural and urban white-footed mice is especially prominent due to impeded gene flow between these populations, which is caused by landscape barriers including roads, highways, and pedestrian sidewalks.[22] Monitoring the strength of immune defenses in P. leucopus is of special importance because they are commonly infected with dangerous pathogens such as hantaviruses and Borrelia burgdorferi.[22]

See also

References

  1. ^ a b Linzey, A.V.; Matson, J. & Timm, R. (2008). "Peromyscus leucopus". IUCN Red List of Threatened Species. 2008. Retrieved 5 February 2010.old-form url
  2. ^ Atlantic Interior, The Natural History of Nova Scotia
  3. ^ Mammalian models for research on aging (1981) ISBN 978-0-309-03094-6
  4. ^ RR5109-Front Cover-Hantavirus.p65
  5. ^ Ostfeld, Richard S. (2023-07-31). "I'm a tick biologist whose body seems to kill off ticks". STAT. Retrieved 2023-08-01.
  6. ^ "WHITE-FOOTED AND DEER MICE". The Internet Center for Wildlife Damage Management. Retrieved 9 June 2016.
  7. ^ "White-footed Deermouse | Tennessee Wildlife Resources Agency". www.tn.gov. Retrieved 2022-10-09.
  8. ^ Donahue JG, Piesman J, Spielman A (January 1987). "Reservoir competence of white-footed mice for Lyme disease spirochetes". The American Journal of Tropical Medicine and Hygiene. 36 (1): 92–6. doi:10.4269/ajtmh.1987.36.92. PMID 3812887.
  9. ^ Jennison CA, Rodas LR, Barrett GW (2006). "Cuterebra fontinella parasitism on Peromyscus leucopus and Ochrotomys nuttalli". Southeastern Naturalist. 5 (1): 157–168. doi:10.1656/1528-7092(2006)5[157:CFPOPL]2.0.CO;2. S2CID 87286185.
  10. ^ Sun Y, Desierto MJ, Ueda Y, Kajigaya S, Chen J, Young NS (2014). "Peromyscus leucopus mice: a potential animal model for haematological studies". International Journal of Experimental Pathology. 95 (5): 342–50. doi:10.1111/iep.12091. PMC 4209926. PMID 25116892.
  11. ^ "White-Footed & Deer Mice Care Sheet by Ann Vole".
  12. ^ Clive Roots; Domestication - page: 105
  13. ^ "Deer Mice and White-footed Mice". 2010-06-03.
  14. ^ a b Harris, Stephen E.; Xue, Alexander T.; Alvarado-Serrano, Diego; Boehm, Joel T.; Joseph, Tyler; Hickerson, Michael J.; Munshi-South, Jason (2016-04-01). "Urbanization shapes the demographic history of a native rodent (the white-footed mouse, Peromyscus leucopus ) in New York City". Biology Letters. 12 (4): 20150983. doi:10.1098/rsbl.2015.0983. ISSN 1744-9561. PMC 4881337. PMID 27072402.
  15. ^ Harris, Stephen E.; Munshi-South, Jason (2017-10-05). "Signatures of positive selection and local adaptation to urbanization in white-footed mice ( Peromyscus leucopus )". Molecular Ecology. 26 (22): 6336–6350. doi:10.1111/mec.14369. ISSN 0962-1083. PMC 5716853. PMID 28980357.
  16. ^ a b c d e f Harris, Stephen E.; Munshi-South, Jason (2017-10-05). "Signatures of positive selection and local adaptation to urbanization in white-footed mice ( Peromyscus leucopus )". Molecular Ecology. 26 (22): 6336–6350. doi:10.1111/mec.14369. ISSN 0962-1083. PMC 5716853. PMID 28980357.
  17. ^ a b Harris, Stephen E.; Munshi-South, Jason; Obergfell, Craig; O’Neill, Rachel (2013-08-28). Johnson, Norman (ed.). "Signatures of Rapid Evolution in Urban and Rural Transcriptomes of White-Footed Mice (Peromyscus leucopus) in the New York Metropolitan Area". PLOS ONE. 8 (8): e74938. doi:10.1371/journal.pone.0074938. ISSN 1932-6203. PMC 3756007. PMID 24015321.
  18. ^ a b c d Harris, Stephen E.; Munshi-South, Jason (2017-10-05). "Signatures of positive selection and local adaptation to urbanization in white-footed mice ( Peromyscus leucopus )". Molecular Ecology. 26 (22): 6336–6350. doi:10.1111/mec.14369. ISSN 0962-1083. PMC 5716853. PMID 28980357.
  19. ^ a b Harris, Stephen E.; Munshi-South, Jason; Obergfell, Craig; O’Neill, Rachel (2013-08-28). Johnson, Norman (ed.). "Signatures of Rapid Evolution in Urban and Rural Transcriptomes of White-Footed Mice (Peromyscus leucopus) in the New York Metropolitan Area". PLOS ONE. 8 (8): e74938. doi:10.1371/journal.pone.0074938. ISSN 1932-6203. PMC 3756007. PMID 24015321.
  20. ^ Bradley, Catherine A.; Altizer, Sonia (2007-02-01). "Urbanization and the ecology of wildlife diseases". Trends in Ecology & Evolution. 22 (2): 95–102. doi:10.1016/j.tree.2006.11.001. ISSN 0169-5347. PMC 7114918. PMID 17113678.
  21. ^ a b c Harris, Stephen (2015-09-30). "Population Genomics of White-Footed Mice (Peromyscus leucopus) in New York City". Dissertations, Theses, and Capstone Projects.
  22. ^ a b André, A.; Millien, V.; Galan, M.; Ribas, A.; Michaux, J. R. (2017-10-01). "Effects of parasite and historic driven selection on the diversity and structure of a MHC-II gene in a small mammal species (Peromyscus leucopus) undergoing range expansion". Evolutionary Ecology. 31 (5): 785–801. doi:10.1007/s10682-017-9898-z. hdl:2445/127939. ISSN 1573-8477. S2CID 254469373.
A captive white-footed mouse. She is at least 3 years and 8 months old.

General references

  • Anderson JF, Johnson RC, Magnarelli LA (1987). "Seasonal prevalence of Borrelia burgdorferi in natural populations of white-footed mice, Peromyscus leucopus". Journal of Clinical Microbiology. 25 (8): 1564–1566. doi:10.1128/JCM.25.8.1564-1566.1987. PMC 269274. PMID 3624451.
  • Rogic A, Tessier N, Legendre P, Lapointe FJ, Millien V (2013). "Genetic structure of the white-footed mouse in the context of the emergence of Lyme disease in southern Québec". Ecology and Evolution. 3 (7): 2075–2088. doi:10.1002/ece3.620. PMC 3728948. PMID 23919153.
  • Barthold SW, Persing DH, Armstrong AL, Peeples RA (1991). "Kinetics of Borrelia burgdorferi dissemination and evolution of disease after intradermal inoculation of mice". The American Journal of Pathology. 139 (2): 263–273. PMC 1886084. PMID 1867318.
  • Bunikis J, Tsao J, Luke CJ, Luna MG, et al. (2004). "Borrelia burgdorferi infection in a natural population of Peromyscus leucopus mice: a longitudinal study in an area where Lyme borreliosis is highly endemic". The Journal of Infectious Diseases. 189 (8): 1515–1523. doi:10.1086/382594. PMID 15073690.
  • Brunner JL, LoGiudice K, Ostfeld RS (2008). "Estimating reservoir competence of Borrelia burgdorferi hosts: prevalence and infectivity, sensitivity, and specificity". Journal of Medical Entomology. 45 (1): 139–147. doi:10.1603/0022-2585(2008)45[139:ercobb]2.0.co;2. PMID 18283955. S2CID 10702776.
  • Burgess EC, French JB Jr, Gendron-Fitzpatrick A (1990). "Systemic disease in Peromyscus leucopus associated with Borrelia burgdorferi infection". The American Journal of Tropical Medicine and Hygiene. 42 (3): 254–259. doi:10.4269/ajtmh.1990.42.254. PMID 2316794.
  • Goodwin BJ, Ostfeld RS, Schauber EM (2001). "Spatiotemporal variation in a Lyme disease host and vector: black-legged ticks on white-footed mice". Vector-Borne and Zoonotic Diseases. 1 (2): 129–138. doi:10.1089/153036601316977732. PMID 12653143.
  • Hofmeister EK, Ellis BA, Glass GE, Childs JE (1999). "Longitudinal study of infection with Borrelia burgdorferi in a population of Peromyscus leucopus at a Lyme disease-enzootic site in Maryland". The American Journal of Tropical Medicine and Hygiene. 60 (4): 598–609. doi:10.4269/ajtmh.1999.60.598. PMID 10348235.
  • Horka H, Cerna-kyckovaa K, Kallova A, Kopecky J (2009). "Tick saliva affects both proliferation and distribution of Borrelia burgdoferi spirochetes in mouse organs an increases transmission of spirochetes by ticks". International Journal of Medical Microbiology. 299 (5): 373–380. doi:10.1016/j.ijmm.2008.10.009. PMID 19147403.
  • Martin LB, Weil ZM, Kuhlman JR, Nelson RJ (2006). "Trade-offs within the immune systems of female white-footed mice, Peromyscus leucopus". Functional Ecology. 20 (4): 630–636. doi:10.1111/j.1365-2435.2006.01138.x.
  • Martin LB, Weil ZM, Nelson RJ (2007). "Immune defense and reproductive pace of life in Peromyscus mice". Ecology. 88 (10): 2516–2528. doi:10.1890/07-0060.1. PMC 7204533. PMID 18027755.
  • Ostfeld RS, Miller MC & Hazler KR (1996) Causes and consequences of tick (Ixodes scapularis) burdens on white-footed mice (Peromyscus leucopus). J Mammal ; 77:266–273.
  • Ostfeld RS, Schauber EM, Canham CD, Keesing F & al. (2001) Effects of acorn production and mouse abundance on abundance and Borrelia burgdorferi infection prevalence of nymphal Ixodes scapularis ticks. Vector Borne Zoonot Dis ; 1:55–63
  • Pederson AB, Grieves TJ (2008) 'he interaction of parasites and resource cause crashes in wild mouse population. J Anim Ecol ; 77:370–377
  • Schwan, TG, Burgdorfer, W, Schrumpf, ME, Karstens, RH. (1988) The urinary bladder, a consistent source of Borrelia burgdorferi in experimentally infected white-footed mice (Peromyscus leucopus). J Clin Microbiol ; 26:893–895
  • Schwan TG, Kime KK, Schrumpf ME, Coe JE, et al. (1989). "Antibody response in white-footed mice (Peromyscus leucopus) experimental infected with the Lyme disease spirochete (Borrelia burgdorferi)". Infection and Immunity. 57 (11): 3445–3451. doi:10.1128/IAI.57.11.3445-3451.1989. PMC 259851. PMID 2807530.
  • Schwanz LE, Voordouw MJ, Brisson D, Ostfeld RS (2011). "Borrelia burgdorferi has minimal impact on the Lyme disease reservoir host Peromyscus leucopus" (PDF). Vector-Borne and Zoonotic Diseases. 11 (2): 117–124. doi:10.1089/vbz.2009.0215. PMID 20569016. Archived from the original (PDF) on 2016-09-21. Retrieved 2014-04-24.

External links

  • White-footed Mouse, State University of New York, College of Environmental Science and Forestry
  • White-footed Mouse, CanadianFauna.com
  • White-footed Mouse, Canadian Biodiversity Website
  • "Deer-mouse" . Encyclopedia Americana. 1920.
  • v
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Extant species of subfamily Neotominae
Baiomyini
Baiomys
(Pygmy mice)
  • Southern pygmy mouse (B. musculus)
  • Northern pygmy mouse (B. taylori)
Scotinomys
(Brown mice)
  • Alston's brown mouse (S. teguina)
  • Chiriqui brown mouse (S. xerampelinus)
Neotomini
Neotoma
(Pack rats)
  • Subgenus Neotoma: White-throated woodrat (N. albigula)
  • Tamaulipan woodrat (N. angustapalata)
  • Bryant's woodrat (N. bryanti)
  • Nicaraguan woodrat (N. chrysomelas)
  • Arizona woodrat (N. devia)
  • Eastern woodrat (N. floridana )
  • Goldman's woodrat (N. goldmani)
  • Angel de la Guarda woodrat (N. insularis)
  • Desert woodrat (N. lepida )
  • White-toothed woodrat (N. leucodon)
  • Big-eared woodrat (N. macrotis)
  • Allegheny woodrat (N. magister)
  • Mexican woodrat (N. mexicana)
  • Southern Plains woodrat (N. micropus)
  • Nelson's woodrat (N. nelsoni)
  • Bolaños woodrat(N. palatina)
  • Stephens' woodrat (N. stephensi)
  • Subgenus Teanopus: Sonoran woodrat (N. phenax)
  • Subgenus Teonoma: Bushy-tailed woodrat (N. cinerea)
  • Dusky-footed woodrat (N. fuscipes)
Xenomys
  • Magdalena rat (X. nelsoni)
Hodomys
  • Allen's woodrat (H. alleni)
Nelsonia
(Diminutive woodrats)
  • Goldman's diminutive woodrat (N. goldmani)
  • Diminutive woodrat (N. neotomodon)
Ochrotomyini
Ochrotomys
  • Golden mouse (O. nuttalli)
Reithrodontomyini
Peromyscus
(Deer mice)
  • californicus group: California mouse (P. californicus)
  • eremicus group: Cactus mouse (P. eremicus)
  • Burt's deer mouse (P. caniceps)
  • Dickey's deer mouse (P. dickeyi)
  • Eva's desert mouse (P. eva)
  • Northern Baja deer mouse (P. fraterculus)
  • Angel Island mouse (P. guardia)
  • San Lorenzo mouse (P. interparietalis)
  • Mesquite mouse (P. merriami)
  • False canyon mouse (P. pseudocrinitus)
  • hooperi group: Hooper's mouse (P. hooperi)
  • crinitus group: Canyon mouse (P. crinitus)
  • maniculatus group: Deer mouse (P. maniculatus)
  • Northwestern deer mouse (P. keeni)
  • Black-eared mouse (P. melanotis)
  • Oldfield mouse (P. polionotus)
  • Santa Cruz mouse (P. sejugis)
  • Slevin's mouse (P. slevini)
  • leucopus group: White-footed mouse (P. leucopus)
  • Cotton mouse (P. gossypinus)
  • aztecus group: Aztec mouse (P. aztecus)
  • Gleaning mouse (P. spicilegus)
  • Winkelmann's mouse (P. winkelmanni)
  • boylii group: Brush mouse (P. boylii)
  • Texas mouse (P. attwateri)
  • Nimble-footed mouse (P. levipes)
  • Tres Marias Island mouse (P. madrensis)
  • White-ankled mouse (P. pectoralis)
  • Chihuahuan mouse (P. polius)
  • Schmidly's deer mouse (P. schmidlyi)
  • Nayarit mouse (P. simulus)
  • San Esteban Island mouse (P. stephani)
  • truei group: Pinyon mouse (P. truei)
  • Perote mouse (P. bullatus)
  • Zacatecan deer mouse (P. difficilis)
  • Osgood's mouse (P. gratus)
  • Northern rock mouse (P. nasutus)
  • melanophrys group: Plateau mouse (P. melanophrys)
  • Puebla deer mouse (P. mekisturus)
  • Marsh mouse (P. perfulvus)
  • furvus group: Blackish deer mouse (P. furvus)
  • Maya mouse (P. mayensis)
  • El Carrizo deer mouse (P. ochraventer)
  • megalops group: Brown deer mouse (P. megalops)
  • Zempoaltepec (P. melanocarpus)
  • Black-tailed mouse (P. melanurus)
  • mexicanus group: Mexican deer mouse (P. mexicanus)
  • Big deer mouse (P. grandis)
  • Guatemalan deer mouse (P. guatemalensis)
  • Naked-eared deer mouse (P. gymnotis)
  • Stirton's deer mouse (P. stirtoni)
  • Yucatan deer mouse (P. yucatanicus)
  • Chiapan deer mouse (P. zarhynchus)
Reithrodontomys
(New World
harvest mice)
  • Guerrero harvest mouse (R. bakeri)
  • Short-nosed harvest mouse (R. brevirostris)
  • Sonoran harvest mouse (R. burti)
  • Volcano harvest mouse (R. chrysopsis)
  • Chiriqui harvest mouse (R. creper)
  • Darien harvest mouse (R. darienensis)
  • Fulvous harvest mouse (R. fulvescens)
  • Slender harvest mouse (R. gracilis)
  • Hairy harvest mouse (R. hirsutus)
  • Eastern harvest mouse (R. humulis)
  • Western harvest mouse (R. megalotis)
  • Mexican harvest mouse (R. mexicanus)
  • Small-toothed harvest mouse (R. microdon)
  • Plains harvest mouse (R. montanus)
  • Small harvest mouse (R. musseri)
  • Nicaraguan harvest mouse (R. paradoxus)
  • Salt marsh harvest mouse (R. raviventris)
  • Rodriguez's harvest mouse (R. rodriguezi)
  • Cozumel harvest mouse (R. spectabilis)
  • Sumichrast's harvest mouse (R. sumichrasti)
  • Narrow-nosed harvest mouse (R. tenuirostris)
  • Zacatecas harvest mouse (R. zacatecae)
Onychomys
(Grasshopper mice)
  • Mearns's grasshopper mouse (O. arenicola)
  • Northern grasshopper mouse (O. leucogaster)
  • Southern grasshopper mouse (O. torridus)
Neotomodon
  • Mexican volcano mouse (N. alstoni)
Podomys
  • Florida mouse (P. floridanus)
Isthmomys
(Isthmus rats)
  • Yellow isthmus rat (I. flavidus)
  • Mount Pirri isthmus rat (I. pirrensis)
Megadontomys
(Giant deer mice)
  • Oaxaca giant deer mouse (M. cryophilus)
  • Nelson's giant deer mouse (M. nelsoni)
  • Thomas's giant deer mouse (M. thomasi)
Habromys
(Deer mice)
  • Chinanteco deer mouse (H. chinanteco)
  • Delicate deer mouse (H. delicatulus)
  • Ixtlán deer mouse (H. ixtlani)
  • Zempoaltepec deer mouse (H. lepturus)
  • Crested-tailed deer mouse (H. lophurus)
  • Schmidly's deer mouse (H. schmidlyi)
  • Jico deer mouse (H. simulatus)
Osgoodomys
  • Michoacan deer mouse (O. banderanus)
Taxon identifiers
Peromyscus leucopus