Fact-checked by Grok 2 weeks ago

Peromyscus

Peromyscus is a of small in the family , subfamily , commonly known as deer mice or white-footed mice, consisting of approximately 80 recognized species that are among the most abundant and ecologically diverse mammals in the . These mice are characterized by their bicolored fur—typically grayish-brown on the back and white on the underparts—large eyes and ears, and a often as long as the head and body, with adults weighing 15–30 grams and measuring 130–200 mm in total length. Native to North and , Peromyscus species diverged evolutionarily from other around 25 million years ago and exhibit remarkable adaptability across a wide range of environments. The genus occupies nearly every type of terrestrial habitat in North America, from the Canadian Arctic tundra and taiga through forests, grasslands, deserts, and montane regions to the tropical lowlands of Panama, with one or more species present in almost all ecological zones. Distribution extends from Labrador and Alaska southward to southern Mexico and Central America, where they thrive in diverse settings including urban edges, agricultural fields, and undisturbed wildlands, often reaching population densities of 1–22 individuals per hectare depending on food availability and season. Ecologically, Peromyscus mice are primarily nocturnal and omnivorous, feeding on seeds, nuts, fruits, insects, and occasionally small vertebrates, while caching food in burrows; they play key roles in seed dispersal, soil aeration, and as prey for predators like owls, hawks, foxes, and snakes. Reproduction is prolific, with females producing 3–4 litters per year of 1–9 pups each, and lifespans reaching up to 32 months in the wild, contributing to their resilience and high abundance. Peromyscus species are notable for their use as model organisms in biomedical and evolutionary research, particularly P. maniculatus and P. leucopus, which facilitate studies on genetics, physiology, aging, and disease transmission due to their natural genetic variation and adaptability. They serve as reservoirs for zoonotic pathogens, including hantavirus (causing hantavirus pulmonary syndrome) and Lyme disease bacteria, posing public health risks in endemic areas. Taxonomically, the genus includes seven subgenera, with ongoing debates over species boundaries driven by molecular and morphological analyses, reflecting their rapid evolutionary radiation. Conservation concerns arise for certain subspecies in fragmented habitats, though most species remain widespread and not currently threatened.

Taxonomy and phylogeny

Classification

The genus Peromyscus was established in 1841 by Christian Leopold Gloger. Peromyscus is classified within the family , subfamily , and tribe Peromyscini. The is Peromyscus arboreus Gloger, 1841, which is now regarded as a junior synonym of Peromyscus leucopus (Rafinesque, 1818). The of Peromyscus derives from terms pēros (maimed, or interpreted as boot-like) and mys (), commonly referring to the bicolored feet typical of many in the . Phylogenetic revisions recognize approximately 83 valid within Peromyscus as of 2024, with ongoing updates incorporating additional genetic data to refine boundaries, particularly in species complexes like the P. maniculatus group.

Evolutionary history

The genus Peromyscus originated in the , with molecular evidence indicating an early divergence of related lineages around 8 million years ago within the cricetid radiation. The earliest known fossils of Peromyscus appear in the Blancan stage of the , approximately 4.75 to 1.6 million years ago, as documented in faunal assemblages from sites like the Beck Ranch Local Fauna in , where dental and mandibular remains confirm the presence of the alongside other early cricetids. Diversification of Peromyscus accelerated during the Pliocene-Pleistocene transition, driven by climatic shifts and habitat changes in , leading to the emergence of multiple adapted to varied environments. This period saw the expansion of the genus across continental , with phylogenetic analyses revealing deep divergences in subgenera like Haplomylomys dating to 4.2–5.9 million years ago. Post-Ice Age during the Pleistocene further promoted , resulting in high through isolation in refugia and subsequent recolonization, as inferred from mitochondrial and nuclear DNA patterns showing formations tied to glacial-interglacial cycles. Key insights into these phylogenetic relationships come from mitochondrial DNA studies, such as those by Bradley and Baker (2001), which used cytochrome-b sequences to delineate species complexes like P. maniculatus and highlighted genetic distances supporting rapid lineage splitting. More recent genomic analyses, including whole-genome sequencing in 2022, have refined these findings by identifying chromosomal inversions and structural variants that underpin diversification, confirming within and updating divergence estimates for major clades. Evidence of rapid is particularly evident in the oldfield mouse (P. polionotus), where chromosomal polymorphisms, including pericentric inversions, have facilitated adaptive divergence in coastal and inland populations over the last few thousand years.

Physical characteristics

Morphology

Members of the genus Peromyscus exhibit a distinctive bicolored pelage, with the dorsum typically grayish to reddish-brown or yellowish and the venter, feet, and underside of the tail starkly white, providing in varied habitats. This soft, dense is adapted for regulation and protection, with the contrasting coloration enhancing against predators. The body is slender and agile, featuring a rounded form with relatively shorter forelimbs compared to strong, elongated hind limbs that facilitate jumping and climbing through arboreal and terrestrial environments. Large, prominent eyes, black and beady in appearance, are key adaptations for nocturnal , allowing these mice to navigate and forage effectively in low-light conditions. Complementing this, long vibrissae () serve as tactile sensors for detecting obstacles and prey in dim environments. Ears are large and rounded with minimal fur coverage, aiding in during crepuscular and nighttime activity. The is long and hairy, often comprising 80-100% of head-body , and is bicolored with a darker surface; it functions primarily for balance during agile movements. includes a formula of 1/1, 0/0, 0/0, 3/3, with low-crowned, cuspidate molars well-suited for grinding seeds and other vegetal matter central to their omnivorous diet.

Size and variation

Species of the Peromyscus display considerable variation in body size, with lengths generally ranging from 110 to 285 mm and weights from 10 to 50 g, though extremes occur across the approximately 58 . For instance, P. californicus represents one of the largest members, reaching up to 285 mm in total , while P. polionotus is among the smallest at around 110–150 mm. These differences reflect adaptations to diverse ecological niches within the . Sexual dimorphism in size is typically minimal, with sexes often alike in overall body proportions. However, in some species like P. maniculatus, males exhibit slightly longer tails compared to females, potentially linked to behavioral differences in locomotion or balance. In contrast, other species show negligible dimorphism or even slight female-biased size differences attributable to reproductive energy demands. Intraspecific variation is prominent, often manifesting as geographic clines that conform to , where individuals in colder climates tend to be larger for improved . For example, populations of P. maniculatus decrease in body mass and length from northern to southern latitudes, supporting this pattern. Such clines highlight the genus's in response to environmental gradients. Size-related adaptations include variations in tail length ratios and fur density, which enhance thermoregulation across populations. Longer tails relative to body size facilitate heat dissipation in warmer environments, while denser fur in colder-adapted individuals provides greater insulation to minimize heat loss. These traits underscore the evolutionary flexibility of Peromyscus in maintaining thermal balance.

Distribution and habitat

Geographic range

The genus Peromyscus is native to North and , encompassing a broad latitudinal range from the southern edge of the Canadian Arctic southward to the Panama-Colombia border. This distribution spans diverse biogeographic regions, including forests in the north and tropical lowlands in the , reflecting the genus's adaptability to varying climatic zones within the . Although the genus exhibits some faunal affinities to Holarctic assemblages in its northern extents due to shared ecological niches, Peromyscus species are strictly endemic to the , with no native presence in the . The core geographic range of Peromyscus is centered in the continental , where multiple species occur across nearly all states except the southeastern coastal plains, but the genus achieves its highest species diversity in . serves as the primary center of diversification for Peromyscus, hosting a high number of species, many of which are endemic to its varied physiographic provinces such as the ranges and . In , the genus extends through countries like , , , , and , with species richness decreasing southward but still supporting several taxa in montane and forested areas. Introduced populations outside the native range are rare and typically result from laboratory escapes. Altitudinally, Peromyscus species occupy elevations from in coastal and lowland habitats to over 4,000 m in high-elevation montane environments, such as the and Mexican sierras. This vertical distribution underscores the genus's ecological versatility, allowing coexistence across elevational gradients within regional ranges. The modern distribution pattern is largely shaped by historical biogeographic processes, including post-glacial recolonization of northern latitudes following Pleistocene glacial retreats, which facilitated range expansions from southern refugia.

Habitat types

Peromyscus species occupy a wide array of terrestrial habitats across , ranging from coniferous and forests to grasslands, deserts, shrublands, and rocky areas. For instance, the (P. leucopus) thrives in forests with dense , while the deer mouse (P. maniculatus) is commonly found in coniferous forests, shrublands, and grasslands. In arid regions, species like the (P. eremicus) inhabit scrublands, and oldfield mice (P. polionotus) utilize grassy dunes and fallow fields. This ecological versatility allows the genus to span elevations from below to over 4,300 meters in alpine zones. Within these ecosystems, Peromyscus prefer microhabitats offering cover and access to , such as ground-level burrows and nests constructed in logs or . Individuals often excavate shallow burrows or repurpose those of other beneath tree roots, rocks, or debris piles, providing protection from predators and environmental extremes. Nests, typically made from grasses, leaves, and fur, are situated in hollow logs, under , or within dense clusters, with nearby caches supporting their granivorous . These selections emphasize structurally complex areas with ample and undergrowth for concealment. Certain Peromyscus species exhibit adaptations suited to arid environments, particularly in the , where efficient water conservation is essential for survival. The (P. eremicus), for example, minimizes water loss through physiological mechanisms like reduced metabolic rates and selective feeding on low-water-content foods during dry periods, enabling persistence in hot, low-precipitation shrublands. These traits, including nocturnal activity and concentrated urine, facilitate occupancy of otherwise harsh desert habitats. Peromyscus are prevalent in human-modified landscapes, including agricultural fields and suburban edges, where fragmented habitats increase proximity to human settlements and elevate disease transmission risks. In croplands and urban-adjacent forests, species like P. maniculatus exploit disturbed areas with seed-rich soils, contributing to higher incidences of zoonotic pathogens such as . This adaptability to altered environments underscores their role in peri-urban ecosystems. Montane Peromyscus species, such as those in the P. mexicanus group, demonstrate seasonal altitudinal shifts, migrating along elevation gradients in response to climatic variations in mountain ranges of . These movements allow access to varying vegetation zones, from lower shrublands to higher coniferous forests, aiding survival during seasonal changes in temperature and resource availability. As of , approximately 58 are recognized in the .

Behavior and life history

Activity patterns

Species of the genus Peromyscus are primarily nocturnal, with activity concentrated during the night and peaks typically occurring at and dawn. This pattern persists year-round, though activity may decrease during periods of cold or inclement weather. In laboratory environments, individuals often display a distinct bimodal activity rhythm, with elevated movement shortly after lights-off and again toward the end of the dark phase. Locomotion in Peromyscus involves agile quadrupedal movement suited to diverse habitats, including excellent abilities on vegetation and structures. For escape from predators, they are proficient jumpers. Territorial behaviors are prominent, particularly among males, who defend home ranges typically spanning 0.02 to 0.3 hectares through scent-marking with and glandular secretions, though sizes vary by and conditions. Social structure is predominantly solitary outside of breeding periods, with individuals maintaining non-overlapping ranges except for limited overlap between sexes. However, exceptions occur in such as P. californicus, which forms monogamous pair bonds and exhibits biparental care. Navigation and social interactions rely heavily on olfaction for detecting scents and marking territories, complemented by audition for vocal communication and predator detection.

Diet and reproduction

Peromyscus species exhibit an omnivorous diet, with seeds comprising approximately 70% of their intake in certain habitats, supplemented by insects, fruits, and other plant matter. Arthropods and invertebrates form a significant portion, often around 21%, while herbage and fruits contribute lesser amounts. This composition varies by season and location; for instance, insects increase during summer foraging, comprising up to 55% of the diet. Foraging behavior in Peromyscus is characterized by scatter-hoarding, where individuals cache seeds opportunistically in shallow burrows or under litter near shrubs, often creating numerous small caches of 1-2 seeds each. Of seeds encountered, about 71% are cached rather than immediately consumed, with caches placed in mineral soil or light litter for quick access. Recovery rates are partial, as many caches are pilfered by conspecifics or other rodents. Nocturnal activity facilitates this caching, minimizing predation risk during foraging. Reproduction in Peromyscus is polyestrous, with females producing 3-5 litters per year depending on resource availability and latitude. Gestation lasts 22-30 days, and litter sizes range from 3-9 young, averaging 4-5 in many species. Sexual maturity is reached at 6-8 weeks, allowing rapid population turnover. In the wild, lifespan typically ranges from 1-2 years, though most individuals do not survive beyond one year due to predation and environmental factors; in captivity, individuals can live up to 8 years. Parental care varies across species but includes biparental investment in some, such as P. californicus, where males assist in nest guarding and pup retrieval, enhancing survival. Females for 3-4 weeks post-birth, during which pups remain altricial and dependent in the nest. This care strategy supports high reproductive output while adapting to fluctuating environmental conditions.

Ecological role

Population dynamics

Peromyscus populations exhibit high densities in optimal habitats, reaching up to 163 individuals per in areas with abundant cover and resources, such as woodlands with dense vegetation. This genus is the most abundant in , with species like Peromyscus maniculatus occupying diverse ecosystems and contributing significantly to small across the . Such high abundances are facilitated by their adaptability to varied environments, though densities typically range from 1 to 100 individuals per depending on local conditions. Population fluctuations in Peromyscus often follow cyclic patterns of boom and bust, occurring every 3–5 years and closely tied to mast years when seed abundance, particularly from oaks (Quercus spp.), surges. During mast events, increased availability boosts and , leading to rapid population growth that peaks in summer; however, crashes follow even when seeds remain plentiful, resulting in sharp declines to low numbers by the next spring. These cycles have been documented over decades in long-term studies, such as those at the Holt Research Forest, where crops consistently trigger rebounds from low phases. Several limiting factors regulate these dynamics, including predation pressure, periods of food scarcity following mast depletion, and disease outbreaks such as hantavirus epizootics that intensify during high-density phases. Predation and resource limitation can suppress growth post-peak, while parasitic infections, like intestinal nematodes, exacerbate crashes by increasing mortality in dense s. Hantavirus outbreaks, linked to elevated numbers, facilitate persistence and increase zoonotic transmission risk, as seen in associations between population surges and human cases. Recent as of 2025 links ongoing warming and maturation to increased Peromyscus abundance and body size in some regions. Demographically, Peromyscus display r-selected traits characterized by high , with females producing multiple per year and litter sizes averaging 4–6 , enabling rapid recovery. Juvenile dispersal plays a key role in and recolonization, with young individuals often moving up to 1 km from sites to establish new territories, particularly males avoiding . This high reproductive output and mobility support their resilience amid fluctuations. Monitoring efforts rely on trapping indices from mark-recapture studies, which reveal correlations between population trends and climate variability, including El Niño events that enhance and growth, thereby boosting survival and abundance. from 2023 has further linked these patterns to broader shifts, such as altered rainfall regimes influencing small communities in semiarid regions.

Interactions with other species

Peromyscus species serve as common prey for a variety of predators, including , hawks, , foxes, weasels, , and domestic cats, which exert significant pressure on their populations across diverse habitats. In response to these threats, individuals often display anti-predator behaviors such as freezing in place to avoid detection or rapid tail-waving to signal alarm and coordinate escape among group members. Interspecific competition with other , such as voles, is mitigated through niche partitioning, where Peromyscus typically exploit arboreal or structurally complex microhabitats while voles favor open grassy areas, allowing coexistence despite overlapping resource needs like seeds and . Spatial further reduces direct conflict, with Peromyscus maniculatus preferring sites with woody and Peromyscus eremicus selecting shrub-dominated cover in granivorous assemblages. Peromyscus engage in mutualistic interactions with plants primarily through seed dispersal, as their scatter-hoarding behavior caches uneaten seeds in locations that enhance and establishment, benefiting species like those in disturbed or arid ecosystems. These mice host a range of parasites, including ectoparasites like fleas (e.g., Monopsyllus thambus and Phalacropsylla oregonensis) and ticks (e.g., and spp.), which use them as s and vectors within communities. Endoparasites such as nematodes (e.g., Syphacia peromysci and Capillaria hepatica) and protozoans (e.g., peromysci) are also prevalent, often acquired through or contact, influencing health and parasite transmission dynamics. As in many food webs, Peromyscus link lower trophic levels by preying on arthropods, thereby regulating and populations and indirectly shaping in grasslands and forests. Their abundance can drive cyclic fluctuations in interacting species, underscoring their central ecological role.

Role as disease reservoirs

Hantavirus

Peromyscus maniculatus, commonly known as the deer mouse, serves as the primary reservoir for (SNV), the etiologic agent responsible for (HPS) in humans. This establishes persistent infections in its rodent host without causing apparent disease, allowing infected deer mice to shed the lifelong through , feces, and saliva. Other Peromyscus species, such as P. leucopus and P. boylii, have been implicated as secondary or alternative reservoirs in certain regions, though P. maniculatus remains the dominant vector across . Transmission to humans occurs primarily via of aerosolized viral particles from contaminated excreta or nesting materials, often during activities like cleaning -infested structures such as sheds, cabins, or trailers. In wild populations, SNV prevalence in P. maniculatus varies by region and environmental conditions but can reach up to 30% in endemic areas, as observed during the 1993 outbreak where serological surveys detected antibodies in approximately 14-30% of captured deer mice. Spillover events are facilitated by increased -human contact in peridomestic settings, where asymptomatic carrier introduce the into human environments without direct bites or other vectors. Epidemiologically, HPS cases are concentrated in the . As of December 2022, 864 cases had been confirmed nationwide since surveillance began in 1993, with additional cases reported annually thereafter (e.g., 7 cases in as of November 2025); cases continue primarily in states like , , and . The 1993 outbreak, which claimed 32 lives among 53 cases, highlighted the virus's potential for rapid emergence following ecological disruptions like flooding that boosted deer mouse populations. Ongoing through serological testing of Peromyscus populations helps track prevalence and predict outbreak risks in high-density rodent habitats. Prevention relies on rodent control measures, including sealing entry points in homes and outbuildings with rodent-proof materials, , and proper cleanup protocols to minimize risks. There is no licensed or specific antiviral for HPS, emphasizing the importance of public and to reduce exposure in endemic areas.

Lyme disease and other tick-borne diseases

The (Peromyscus leucopus) serves as a primary reservoir for Borrelia burgdorferi, the spirochete bacterium causing in . This rodent maintains persistent infections with minimal clinical impact, facilitating the enzootic cycle of the pathogen. Studies have documented seroprevalence rates of B. burgdorferi in P. leucopus ranging from 17% to 53% in endemic areas, with one analysis in woodland and interface zones reporting up to 32% positivity among captured mice. In the transmission cycle, larval (blacklegged ticks) acquire B. burgdorferi while feeding on infected P. leucopus hosts during the summer. These infected larvae molt into nymphs, which then quest for new hosts the following spring and transmit the pathogen to humans or other vertebrates upon attachment. This two-host pattern amplifies pathogen dissemination, as P. leucopus supports high larval tick burdens without significant grooming removal of early-stage parasites. Beyond , P. leucopus acts as a reservoir for other tick-borne pathogens vectored by I. scapularis, including (causative agent of , formerly ) and (agent of ). Experimental infections confirm that P. leucopus sustains A. phagocytophilum transmission to ticks, with infected mice exhibiting bacteremia levels sufficient for larval acquisition. Similarly, P. leucopus harbors B. microti at rates that enable transplacental and vector-based spread, contributing to human cases. Co-infections with multiple pathogens are prevalent in P. leucopus populations, increasing the risk of polymicrobial transmission to humans via questing nymphs. Epidemiologically, P. leucopus drives incidence primarily in the , where dense mouse populations correlate with elevated tick infection rates and human cases. exacerbates this by expanding suitable habitats northward; models indicate that risk could increase by up to 20% in northern regions by mid-century due to warmer temperatures favoring tick survival and reservoir host range shifts. By tolerating repeated I. scapularis infestations through limited initial grooming responses, P. leucopus amplifies local tick densities, sustaining high prevalence in endemic foci.

Additional pathogens

Peromyscus species, particularly western populations such as the deer mouse (Peromyscus maniculatus), serve as reservoirs for Yersinia pestis, the bacterium causing plague, with fleas collected from these rodents testing positive for the pathogen in regions like the western United States. Experimental studies have demonstrated moderate susceptibility of wild Peromyscus to subcutaneous Y. pestis infection, highlighting their potential role in maintaining enzootic cycles of the disease. Similarly, tularemia caused by Francisella tularensis subsp. holarctica has been diagnosed in deer mice during population irruptions in North America, including cases in west-central Saskatchewan where the bacterium was isolated from deceased individuals, indicating these rodents as incidental hosts capable of amplifying outbreaks. Beyond hantavirus, Peromyscus species are susceptible to other viruses with zoonotic potential, notably SARS-CoV-2. Studies from 2020 showed that white-footed mice (P. leucopus) and deer mice support efficient replication and transmission of the virus, positioning them as potential wildlife reservoirs in . For instance, intranasal challenge of deer mice resulted in robust and onward transmission to contact animals, underscoring their capacity to sustain the pathogen post-spillover from humans. Rabies virus infections are rare in Peromyscus, with virtually no verified cases reported in wild across , reflecting their low compared to carnivores. In contrast, leptospirosis, caused by spp., poses a zoonotic through contaminated ; white-footed deer mice exhibit acute to , serving as viable models for the disease and potential environmental amplifiers via urinary shedding. Emerging research post-2023 has identified spillover into Peromyscus, with detections of highly pathogenic A(H5N1) clade 2.3.4.4b in deer mice in the United States, suggesting these as incidental hosts amid expanding infections. Additionally, urban Peromyscus populations harbor antibiotic-resistant bacteria, including diverse resistomes in their linked to pressures like contamination and proximity to human activity. One Health approaches emphasize integrating surveillance for Peromyscus to monitor these pathogens, combining field trapping, metagenomic sequencing, and ecological modeling to predict zoonotic risks and inform interventions. Such strategies highlight the need for cross-sectoral to mitigate spillover from these ubiquitous hosts.

Use in scientific research

Laboratory models

Peromyscus species offer several advantages as laboratory models compared to the standard (Mus musculus), including a longer maximum lifespan of 5–7 years versus 2–3 years, which facilitates longitudinal studies of aging and chronic conditions. They also retain a high degree of wild-trait variability, such as natural genetic polymorphism and behaviors like in certain species, allowing researchers to investigate ecologically relevant phenotypes not easily replicated in highly domesticated M. musculus strains. Although similar in overall size to laboratory mice, Peromyscus exhibit anatomical differences, including larger dimensions in some populations, which can aid in surgical procedures requiring precise tissue access. Breeding Peromyscus in captivity is prolific, with sub-specific forms producing viable and fertile offspring readily in laboratory settings, though success often depends on providing enriched environments to reduce stereotypic behaviors and promote welfare. Colonies are maintained at the Peromyscus Genetic Stock Center at the , established in 1985 to supply genetically defined stocks for research and education. Genetic tools for Peromyscus have advanced significantly, with inbred strains developed for P. maniculatus since the mid-20th century to enable controlled genetic studies. Post-2020 developments include CRISPR-Cas9 applications, such as viral-mediated editing systems for targeted in species like P. californicus and P. maniculatus. While Peromyscus husbandry follows Institutional Animal Care and Use Committee (IACUC) guidelines similar to those for M. musculus, protocols are less standardized due to their relative novelty as models, requiring adaptations for species-specific behaviors and environmental needs. Historical use of Peromyscus in laboratory settings dates to the early , when researchers like R. Dice and associates conducted pioneering and studies using captive colonies to explore and .

Genetic and biomedical applications

Peromyscus species serve as valuable models in research, particularly for studying processes through hybrid zones. For instance, the oldfield mouse (P. polionotus) exhibits hybrid zones with related species where and can be examined, revealing mechanisms of postzygotic barriers such as reduced hybrid . These zones highlight how chromosomal rearrangements contribute to , with studies showing differential patterns across genomic regions. Additionally, chromosomal polymorphisms are prominent in the genus, with most species maintaining a diploid number of 2n=48 but varying fundamental numbers (FN) from 56 to 96 due to Robertsonian fusions and pericentric inversions, influencing evolutionary divergence. In biomedical applications, Peromyscus models illuminate aging mechanisms, including dynamics, where comparative studies across , including long-lived Peromyscus leucopus and P. maniculatus, demonstrate of activity with body mass and lifespan, suggesting adaptive maintenance strategies. research leverages Peromyscus due to natural variations in period length; for example, P. leucopus expresses core clock genes like Per1 and Per2 in , with photoperiod influencing their oscillation and linking to metabolic health independent of temperature. Reproductive isolation studies further utilize the genus, as seen in P. leucopus and P. gossypinus, where sexual imprinting drives strong conspecific preferences, reducing hybridization despite interfertility. Disease modeling with Peromyscus has advanced understanding of hantavirus , as P. maniculatus persistently with Sin Nombre virus without overt symptoms, mimicking dynamics and allowing dissection of viral persistence mechanisms. For , P. leucopus serves as a model, with post-2023 studies revealing differential immune responses compared to lab mice, including lower Borrelia burgdorferi colonization efficiency and modulated splenic transcriptomes that highlight tolerance. As of 2025, trials, including oral anti-OspA , have tested immune priming in Peromyscus, showing enhanced humoral memory and maternal transfer against tick-borne pathogens like Borrelia burgdorferi, informing zoonotic control strategies. Evolutionary ecology investigations employ Peromyscus for phylogeographic analyses using mtDNA, uncovering refugia and postglacial expansions in P. maniculatus that shaped across . to urban environments is evident in P. leucopus, where genomic signatures of positive selection in populations indicate rapid evolution in immune and metabolic loci, enabling persistence in fragmented habitats. Key findings include the evolution of in P. californicus, where 2010s studies link oxytocin pathways to pair bonding and ; for example, reproductive experience alters central expression, enhancing affiliative behaviors and stress resilience in males. Intranasal oxytocin administration further promotes coordinated social approach in pairs, underscoring its role in maintaining monogamous bonds.

Species diversity

Number and recognition of species

The genus Peromyscus currently includes 83 recognized , according to the American Society of Mammalogists' Mammal Diversity Database (version 2.3, 2025). This count reflects ongoing taxonomic updates and contrasts with other databases like (2024), which recognizes 58 , highlighting persistent debates in ; earlier estimates documented 56 in 2005. Species delimitation in Peromyscus employs an integrative taxonomy, combining morphological, genetic, and ecological evidence. Morphological criteria focus on cranial measurements, dental patterns, and pelage characteristics, while genetic analyses typically require 2-5% divergence in mitochondrial DNA sequences, such as the cytochrome b gene, to indicate species-level separation. Ecological factors, including habitat specialization and geographic isolation, provide additional support for recognizing distinct lineages, particularly in diverse regions like Mexico. The features several complexes that complicate due to hybridization and subtle differentiation. For example, the P. maniculatus group contains multiple closely related taxa, with P. maniculatus alone encompassing approximately 17 across its wide North American range following taxonomic revisions that elevated former subspecies (e.g., P. gambelii, P. labecula, P. sonoriensis) to full status. Recent taxonomic revisions have increased species diversity through splits based on and ; a notable case is the elevation of P. nicaraguae and P. salvadorensis from within P. mexicanus in 2015–2016, driven by genetic analyses of the cytochrome b gene. Ongoing debates surround Mexican taxa, where high cryptic diversity in groups like the P. mexicanus complex prompts further revisions using multilocus nuclear data. Conservation assessments highlight vulnerability in certain Peromyscus species, with 2 listed as vulnerable, 6 as endangered, and 9 as on the (version 2025), including P. stephani (, restricted to San Esteban Island).

Notable species and subspecies

The deer mouse (Peromyscus maniculatus) is one of the most widespread species in the genus, occurring across from to central and inhabiting diverse environments including boreal forests, grasslands, and deserts. It serves as a primary for hantaviruses such as Sin Nombre , contributing to outbreaks in human populations. The species encompasses a complex of subspecies adapted to local conditions, including P. m. sonoriensis, which inhabits arid desert regions like the Mojave and exhibits physiological adaptations to hot, dry environments. The (Peromyscus leucopus) is prevalent in the eastern and , favoring forests, woodlands, and edge habitats from southern to . It acts as a key reservoir for , harboring the bacterium and facilitating its transmission via ticks. A notable , P. l. noveboracensis, is adapted to and suburban settings in the northeastern U.S., thriving in fragmented landscapes alongside human development. The mouse (Peromyscus californicus) stands out as the largest species in the , with adults weighing 32–54 grams, and is characterized by its monogamous , where pairs form lasting bonds and share . It is restricted to coastal , forests, and woodlands along California's coastal ranges and the eastern Sierra Nevada. The oldfield mouse (Peromyscus polionotus) inhabits the , particularly open grasslands, sandhills, and agricultural fields from to . It has served as a model for studying and adaptive , notably through variations in coat color that match sandy substrates, driven by against predation. The beach-dwelling subspecies P. p. trissyllepsis (Perdido Key beach mouse) is federally endangered, threatened by habitat loss from coastal and storms in its narrow range along the Gulf Coast. Among other notable species, the cotton mouse (Peromyscus gossypinus) specializes in and swamp habitats, preferring bottomland forests and hydric hammocks in the southeastern U.S., where it forages on seeds, fruits, and . Regional endemics include the Aztec mouse (Peromyscus aztecus), confined to southern in volcanic highlands and grasslands of states like , , and .

References

  1. [1]
    Peromyscus mice as a model for studying natural variation - PMC
    Jun 17, 2015 · The deer mouse (genus Peromyscus) is the most abundant mammal in North America, and it occupies almost every type of terrestrial habitat.
  2. [2]
    [PDF] Deer Mice (Peromyscusspp.) Biology, Damage and Management
    ABSTRACT: The deer mouse is the most widely distributed and abundant small mammal in North America. They use a wide array of habitats, are very adaptable, ...Missing: taxonomy | Show results with:taxonomy
  3. [3]
    [PDF] TAXONOMY AND PHYLOGENETICS OF THE PEROMYSCUS ...
    Oct 17, 2019 · One or more species of Peromyscus occur in nearly all habitats of North America from the Canadian taiga through central Mexico.
  4. [4]
    Peromyscus - an overview | ScienceDirect Topics
    Peromyscus is defined as a genus of rodents commonly known as deer mice, which includes species such as the melanotic strain of the Peromyscus maniculatus.
  5. [5]
    ITIS - Report: Peromyscus - Integrated Taxonomic Information System
    Species, Peromyscus attwateri J. A. Allen, 1895 – Texas mouse, Texas Deermouse, Attwater's Mouse ; Species, Peromyscus aztecus (Saussure, 1860) – Aztec Deermouse ...
  6. [6]
    Peromyscus maniculatus • Eastern Deermouse
    Tribe, : Peromyscini. Genus, : Peromyscus. Species status. Living. Found in ... Taxonomy and phylogenetics of the Peromyscus maniculatus species group. From ...
  7. [7]
    White-footed mouse (Peromyscus leucopus) longevity, ageing, and ...
    Species: Peromyscus leucopus; Common name: White-footed mouse; Synonyms: Hesperomys affinis, Peromyscus arboreus, Hesperomys campestris, Peromyscus canus, ...
  8. [8]
    PEROMYSCUS Definition & Meaning - Merriam-Webster
    The meaning of PEROMYSCUS is a genus of rodents ... Word History. Etymology. New Latin, from Greek pēros maimed + myskos small mouse, diminutive of mys mouse ...Missing: boot bicolored feet
  9. [9]
    [PDF] Special Publications - Museum of Texas Tech University
    Oct 10, 2019 · so-. Page 25. BRADLEY ET AL.—MULTIPLE SPECIES IN PEROMYSCUS MANICULATUS. 21 noriensis, by 3.80%, 3.79%, 5.90%, 4.22%, and 4.28%, respectively.
  10. [10]
    A Taxonomic Odyssey: An annotated checklist of Peromyscus ...
    Nov 22, 2024 · Deer mice, Peromyscus, thrive in diverse environments and altitudes across North and Central America. The number of extant species continues ...
  11. [11]
    What Is Peromyscus? Evidence from nuclear and mitochondrial ...
    Our analyses indicated an early divergence of Isthmomys from Peromyscus (approximately 8 million years ago), whereas most other peromyscine taxa emerged within ...
  12. [12]
    Early Blancan Mammals of the Beck Ranch Local Fauna of Texas
    Of the 58 taxa identified, members of the genera Perognathus, Peromyscus, Nasua and Spilogale(?) are described as new species; Lasionycteris and Nasua are ...
  13. [13]
    evolutionary history of the subgenus Haplomylomys (Cricetidae
    Oct 7, 2017 · Haplomylomys, a subgenus of Peromyscus, has been studied intensively since the early 20th century, when Osgood (1909) addressed the group's ...Missing: etymology peros mys<|separator|>
  14. [14]
    Role of Pleistocene climatic oscillations on genetic differentiation ...
    Oct 21, 2021 · Peromyscus hylocetes and P. aztecus diverged during the Pliocene–Pleistocene at the central-south region of the TVB. We hypothesized that after ...
  15. [15]
    Chromosomal inversion polymorphisms shape the genomic ... - Nature
    Oct 17, 2022 · These results show that inversion polymorphisms have a significant impact on recombination, genome structure and genetic diversity in deer mice.
  16. [16]
    CHROMOSOMAL EVOLUTION AND THE MODE OF SPECIATION ...
    C-banded karyotype of a male Peromyscus polionotus . Chromosomes in parentheses are from other specimens of P. polionotus and illustrate the variation in pairs ...
  17. [17]
    [PDF] MAMMALIAN SPECIES No. 242, pp. 1-4, 4 figs. - Peromyscus alstoni.
    Dec 13, 1985 · GENERAL CHARACTERS. Peromyscus alstoni is medi- um-sized compared with other members of the genus. It has large, nearly naked ears, and soft ...
  18. [18]
    Deer mouse (Peromyscus californicus)
    Head and body length of Peromyscus species range from 70-170 mm and tail lengths are 40-205 mm. There are 2 subgenera and 55 species.Missing: size | Show results with:size
  19. [19]
    [PDF] California Mouse (Peromyscus californicus) - - Clark Science Center
    Jan 6, 1978 · Peromyscus californicus is the largest spe- cies of the genus in the United States. Total length is 220 to. 285 mm; tail is longer than head and ...
  20. [20]
    Peromyscus polionotus (oldfield mouse) - Animal Diversity Web
    Total length ranges from 110 to 150 millimeters with the average tail length ranging from 40 to 60 millimeters. Weight varies between 10 and 15 grams (Wilson ...
  21. [21]
    Peromyscus maniculatus (deer mouse) - Animal Diversity Web
    Peromyscus maniculatus is a North American species. It is distributed from the northern tree line in Alaska and Canada southward to central Mexico.Scientific Classification · Physical Description · Reproduction
  22. [22]
    Morphological variation in deer mice in relation to sex and habitat
    Peromyscus maniculatus ... Sexual dimorphism appeared to be age dependent rather than size dependent when adults and juveniles of similar body size were analysed.
  23. [23]
    [PDF] Ecomorphology of Peromyscus in Iowa - UNI ScholarWorks
    Pelage. Adults, near russet in. In adults, dorsum dark. Adults usually have winter, heavily mixed underparts white. Most grayish above,.
  24. [24]
    Body size trends in response to climate and urbanization in ... - Nature
    Jun 1, 2020 · Here we utilize a densely sampled, multi-source dataset to examine how climate and urbanization affect body size of Peromyscus maniculatus (PEMA) ...<|control11|><|separator|>
  25. [25]
    [PDF] Climate Change and Shrinkage of Small Mammals
    There was a study done with Peromyscus maniculatus (Deer Mouse) which found that overall the species conformed to Bergmann's Rule and decreased in body mass and ...
  26. [26]
    Effects of Rodent Thermoregulation on Animal Models in the ...
    As stated previously, the extremities of rodents, including the tail, assist with thermoregulation through the dissipation of excess body heat.Missing: length | Show results with:length
  27. [27]
    Heat loss from deer mice (Peromyscus): evaluation of seasonal ...
    Nov 1, 1986 · This paper investigates the influence of seasonal adaptations to thermoregulatory heat loss for deer mice (Peromyscus) during summer and ...
  28. [28]
    The Natural History of Model Organisms: Peromyscus mice as a ...
    Jun 17, 2015 · The name Peromyscus (Gloger, 1841) was first employed, albeit narrowly, in the middle of the 19th century. Quadrupeds of North America (Audubon ...
  29. [29]
    Late Pleistocene Altitudinal Segregation and Demography Define ...
    May 25, 2023 · Peromyscines are distributed mainly in North America (Alaska to Panama), and Mexico is considered its main diversity center [31].
  30. [30]
    Notes on Peromyscus (Muridae) of Mexico and Central America
    Oct 31, 2023 · Information on taxonomy, geographic distribution, and habitat is summarized for P. lepturus, P. lophurus, and P. simulatus. Peromyscus ixtlani, ...
  31. [31]
    Development partly determines the aerobic performance of adult ...
    Jan 1, 2008 · ... (Peromyscus maniculatus Le Conte) as a model for study for several reasons. Deer mice inhabit a wide altitudinal range, from below sea level ...
  32. [32]
    WILDLIFE SPECIES: Peromyscus maniculatus - USDA Forest Service
    FEDERAL LEGAL STATUS: No special status ; GENERAL DISTRIBUTION: North American deermice occur throughout most of North America and are abundant in most areas.
  33. [33]
    Desert Mice Offer Insight into Potential Climate Change Adaptations
    May 23, 2024 · The researchers discovered that to survive arid desert conditions, the cactus mice reduced water loss by decreasing food intake and lowering ...Missing: Sonoran | Show results with:Sonoran<|separator|>
  34. [34]
    When the tap runs dry: The physiological effects of acute experimental dehydration in Peromyscus eremicus
    **Summary of Adaptations of Peromyscus eremicus to Arid Habitats (Sonoran Desert) for Water Conservation:**
  35. [35]
    [PDF] thermoregulatory performance and plasticity in desert cricetid rodents
    Many cricetid rodents, Neotoma (woodrats) and Peromyscus (mice), are very successful inhabitants of the extremely hot and arid Mojave, Colorado and Sonoran ...
  36. [36]
    Deer Mouse - UC IPM
    There are seven species of mice belonging to the genus Peromyscus in California. The deer mouse is the most widespread and common of these species. The other ...Missing: taxonomy ecology
  37. [37]
    Support for rodent ecology and conservation to advance zoonotic ...
    May 11, 2021 · The conversion of ecosystems to agriculture and suburban-urban landscapes provides more opportunities for contact between humans and vectors of ...<|separator|>
  38. [38]
    Spatially heterogeneous impact of climate change on small ...
    Jan 22, 2015 · Here we repeated early twentieth century surveys of small mammals along elevational gradients in northern, central and southern regions of montane California.
  39. [39]
    Feeding pattern in Peromyscus maniculatus: The response to ...
    The prairie deermouse (Peromyscus maniculatus bairdi) is strongly nocturnal on a 12:12 LD-cycle with a bimodal, dusk-dawn feeding pattern.
  40. [40]
    Time Patterns of Peromyscus Activity and Their Correlations ... - jstor
    Eating, drinking and activity patterns of Peromyscus maniculatus sonoriensis. J. Mamm., 37:74-79. GENTRY, J. B., AND E. P. ODUM. 1957. The effect of weather ...
  41. [41]
    Species differences in urine scent-marking and counter-marking in ...
    Aug 5, 2025 · Species comparisons indicate that scent-marking may differ as a function of mating system and co-housing with the opposite sex ("pairing").
  42. [42]
    [PDF] The Evolution of Social and Reproductive Monogamy in ...
    Most relevant to this chapter, pop- ulations and species of Peromyscus exhibit a variety of social behaviours and mating systems (Wolff, 1989), with social ...Missing: locomotion | Show results with:locomotion
  43. [43]
    Integration of olfactory and auditory cues eliciting parental behavior
    May 22, 2023 · Olfaction and audition are two of the primary senses through which rodents participate in social interactions, and they span relatively more ...Missing: reliance | Show results with:reliance
  44. [44]
    energy relationships of the mammals of a desert shrub (larrea ... - jstor
    of Peromyscus spp. was ... and a variety of herbs in Wyoming, and from grassland with Yucca in Colorado, a diet: 70% seeds, 9% herbage, and 21% arthropods.
  45. [45]
    [PDF] Scatter-hoarding behavior of deer mice (Peromyscus maniculatus)
    First, some scatter-hoarded seeds are probably recovered later in summer by foraging deer ... The influence of environmental conditions on cache recovery and ...
  46. [46]
    Incomplete recovery of seeds from scatterhoards by granivorous ...
    Jan 13, 2022 · In our study, we documented >50% of pilfered caches had seeds remaining, with about 30% of those caches with at least one seed still buried in ...
  47. [47]
    Deer Mouse - SUNY ESF
    The two species of Peromyscus inhabiting the Adirondacks are similar in appearance, and are not always distinguishable from external characters.Missing: tribe | Show results with:tribe
  48. [48]
    [PDF] Life history account for Canyon Mouse
    Gestation is 24-25 days. Litter size averages 3 young (range 1-6) (Egoscue 1964).
  49. [49]
    Effects of reproductive status on behavioral and endocrine ...
    We tested this hypothesis in a biparental rodent, the California mouse (Peromyscus californicus). California mice are socially and genetically monogamous, and ...
  50. [50]
    [PDF] Piñon Deermouse - Peromyscus truei - b State Species Abstract a
    Litter size can range from 2–6 with litters of 3 or 4 being most common, and gestation lasts 25–27 days 3, 4, 16. Females nurse young for up to 30 days, and ...Missing: reproduction | Show results with:reproduction
  51. [51]
    https://fieldguide.wildlife.utah.gov/?Species=Peromyscus%20maniculatus
  52. [52]
    The interaction of parasites and resources cause crashes in a wild ...
    Nov 19, 2007 · However, Peromyscus populations rapidly crash in high mast years while food is still in high abundance, and there has been no explanation for ...
  53. [53]
    (PDF) Peromyscus leucopus Abundance and Acorn Mast
    Aug 6, 2025 · Abundance always increased after a low population phase coupled with a large acorn (Quercus) crop, but in 3 summers population declines followed ...
  54. [54]
    Hantaviruses: A Global Disease Problem - CDC
    Outbreaks of hantaviral disease have been associated with changes in rodent population densities, which may vary greatly across time, both seasonally and from ...<|separator|>
  55. [55]
    The ecological dynamics of hantavirus diseases - PubMed Central
    Feb 21, 2019 · Environmental factors are major triggers that affect reservoir ecology and virus ecology and thus are likely to affect hantavirus transmission ...
  56. [56]
    Peromyscus as a model system for understanding the regulation of ...
    In r-selected species such as these polygynous species of Peromyscus, organisms possess physiological traits that maximize an individual's reproductive output ...
  57. [57]
    [PDF] Dispersal in a Monogamous Rodent, Peromyscus californicus
    Dispersal distance is divided into 40-m intervals, which corresponds to the mean home-range diameter of adults.
  58. [58]
    Climatic influences on demography of the California mouse ...
    Aug 1, 2018 · To test for the effect of El Niño on demographic rates of California mice, we used the Oceanic Niño Index (ONI), the standard used by the ...
  59. [59]
    Decline in small mammal species richness in coastal‐central ...
    The richness and composition of a small mammal community inhabiting semiarid California oak woodland may be changing in response to climate change.
  60. [60]
    [PDF] WILDLIFE NOTES - Commonwealth of Pennsylvania
    Beavers live up to 15 years in captivity. The estimated lifespan in the wild is 10 to 12 years. Population. By the beginning of the twentieth century ...
  61. [61]
    [PDF] Social Behavior and Foraging Ecology of the Eastern Chipmunk ...
    The tail was then vibrated rapidly from side to side, often in short bursts coinciding with forward movements. This behavior (tail flick- ing) did not occur ...Missing: waving | Show results with:waving
  62. [62]
    Temporal Partitioning between Forest-Dwelling Small Rodents in a ...
    Temporal partitioning is reported as one of the main strategies adopted by coexisting mammal species to limit interspecific competition and behavioural ...
  63. [63]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC8833473/
  64. [64]
    Noise pollution alters ecological services: enhanced pollination and ...
    Mar 21, 2012 · We also documented seed removal by Peromyscus mice and A. californica, considered to be primarily seed predators and important seed dispersers, ...
  65. [65]
    [PDF] Caching rodents disproportionately disperse seed beneath invasive ...
    Dec 1, 2016 · Dispersal of native seed can be disrupted by invasive plants bearing attractive fruits, as these can satiate frugivores that then ignore native.
  66. [66]
    https://digitalcommons.unl.edu/manter/20
  67. [67]
    [PDF] Small mammal responses to bison reintroduction and prescribed fire ...
    Peromyscus and Microtus species play an important role in the upper trophic level dynamics of tallgrass prairie ecosystems through influencing the vegetation ...
  68. [68]
    [PDF] Patterns of Coexistence in Synaptomys Cooperi and Microtus ...
    Although these species do compete, this competition is relaxed when Microtus populations decline. When given access to preferred habitats the food habits of ...
  69. [69]
    Novel Focus of Sin Nombre Virus in Peromyscus eremicus Mice ...
    May 4, 2018 · The principal reservoir of SNV is the deer mouse, Peromyscus maniculatus (2), a habitat generalist. Evidence of virus infection can be detected ...
  70. [70]
    Genetic Analysis of the Diversity and Origin of Hantaviruses in ...
    Each hantavirus appears to be primarily associated with a specific rodent species, causing a persistent, asymptomatic, life-long infection in that species. They ...
  71. [71]
    Experimental Infection of Peromyscus Species Rodents with Sin ...
    We demonstrate that 6 distinct Peromyscus rodent species are permissive to experimental infection with Sin Nombre orthohantavirus (SNV).
  72. [72]
    Hantavirus Pulmonary Syndrome --- United States - CDC
    The deer mouse (Peromyscus maniculatus) (Figure 1) is the host for Sin ... Patterns of association with host and habitat: antibody reactive with Sin Nombre ...<|separator|>
  73. [73]
    Hantavirus Risk Maps | NASA Earthdata
    Jul 22, 2020 · On June 14, 1993, the CDC identified the deer mouse, found throughout North America, as the primary carrier. Other rodents have also been found ...
  74. [74]
    About Hantavirus - CDC
    May 13, 2024 · Eliminate or minimize contact with rodents in your home, workplace, or campsite to reduce your risk of exposure to hantaviruses. Seal holes and ...Clinician Brief · Hantavirus Prevention · View All HantavirusMissing: measures | Show results with:measures
  75. [75]
    Reported Cases of Hantavirus Disease - CDC
    Jun 26, 2024 · As of the end of 2022, 864 cases of hantavirus disease were reported in the United States since surveillance began in 1993.
  76. [76]
    Long-Term Studies of Hantavirus Reservoir Populations in ... - CDC
    Sin Nombre virus (SNV), whose host is the deer mouse (Peromyscus maniculatus) ... reservoir populations associated with increased virus transmission.
  77. [77]
    Seroepidemiologic Studies of Hantavirus Infection Among Wild ...
    Of 1,921 Peromyscus maniculatus (deer mice), 226 (11.8%) were antibody positive, including one collected in 1975. The highest antibody prevalence (71.4% of 35) ...
  78. [78]
    Hantavirus Prevention - CDC
    May 13, 2024 · People should avoid contact with rodent urine, droppings, saliva, and nesting materials. ... Rodent control is the primary strategy for preventing ...Reported Cases of Hantavirus... · How to Clean Up After Rodents · Small MammalsMissing: proofing | Show results with:proofing
  79. [79]
    Poleward Expansion of the White-Footed Mouse (Peromyscus ...
    Finally, the probability of occurrence of the white-footed mouse is related to the degree of habitat fragmentation and availability of food resources.Missing: radiation Ages
  80. [80]
    Experimental infections of the reservoir species Peromyscus ...
    Dec 4, 2012 · The rodent Peromyscus leucopus is a major natural reservoir for the Lyme disease agent Borrelia burgdorferi and a host for its vector Ixodes ...
  81. [81]
    Ixodes scapularis density and Borrelia burgdorferi prevalence along ...
    Jun 7, 2024 · Among P. leucopus mice, B. burgdorferi prevalence was between 17 and 32% in interface zones and 19% and 53% in woodland zones. Overall, 57% of ...
  82. [82]
    An enzootic transmission cycle of Lyme borreliosis spirochetes in ...
    In North America, two tick species are known to transmit B. burgdorferi s.s. to humans, Ixodes pacificus in the far west and Ixodes scapularis in the east. In ...
  83. [83]
    Ixodes scapularis Life cycle
    Both larvae and nymphs have the potential to become infected with Lyme disease bacteria (B. burgdorferi) and other tick-borne pathogens when they feed on ...
  84. [84]
    Ticks, Ixodes scapularis, Feed Repeatedly on White-Footed Mice ...
    Dec 17, 2017 · Inflammatory responses in white-footed mice (Peromyscus leucopus) following successive feeding challenges with nymphal ticks, Ixodes scapularis.
  85. [85]
    Cricetidae): An overlooked reservoir of tick‐borne pathogens in the ...
    Nov 14, 2021 · Mice belonging to the genus Peromyscus are one of the most important reservoirs of tick-borne pathogens in the United States.
  86. [86]
    Experimental evaluation of Peromyscus leucopus as a reservoir host ...
    Jan 28, 2017 · Although blacklegged ticks (Ixodes scapularis) have been identified as capable vectors, wild reservoirs have not yet been established for EMLA.
  87. [87]
    Transplacental transmission of tick-borne Babesia microti in its ...
    May 4, 2018 · Human babesiosis is an emerging tick-borne disease that shares the same vector, the blacklegged tick (Ixodes scapularis), and dominant reservoir ...
  88. [88]
    Broad diversity of host responses of the white-footed mouse ...
    Peromyscus leucopus, the white-footed mouse, is one of the more abundant mammals of North America and is a major reservoir host for at least five tickborne ...Missing: arboreus | Show results with:arboreus
  89. [89]
    Why Lyme disease is common in the northern US, but rare in the south
    Jan 28, 2021 · In the case of Lyme disease, a primary reservoir host in the northeastern US is the white-footed mouse, Peromyscus leucopus [11], and increased ...
  90. [90]
    Climate Change Indicators: Lyme Disease | US EPA
    Studies provide evidence that climate change has contributed to the expanded range of ticks, increasing the potential risk of Lyme disease, such as in areas of ...
  91. [91]
    Differential burdens of blacklegged ticks (Ixodes scapularis) on ...
    Adult Peromyscus spp. had an overall mean of 4.03 ticks per capture, while adult C. gapperi had a mean of 0.47 ticks per capture. There was a significant ...
  92. [92]
    Prevalence of <i>Yersinia pestis</i> in rodents and fleas associated ...
    Only one of 1,421 fleas, an Oropsylla hirsuta collected in 2002 from a deer mouse, Peromyscus maniculatus, tested positive for Y. pestis. Blood samples ...
  93. [93]
    Moderate Susceptibility to Subcutaneous Plague (Yersinia pestis ...
    Jul 1, 2021 · The variable response of wild mice to Yersinia pestis infection, the causative agent of plague, has generated much speculation concerning ...
  94. [94]
    tularemia in deer mice (peromyscus maniculatus) during a ...
    Tularemia, caused by the bacterium. Francisella tularensis, is a zoonotic disease that occurs over much of the northern hemisphere. It has a broad host range ...
  95. [95]
    SARS-CoV-2 infection, neuropathogenesis and transmission among ...
    To assess this potential, we challenged deer mice (Peromyscus maniculatus) with SARS-CoV-2 and found robust virus replication in the upper respiratory tract, ...
  96. [96]
    SARS-CoV-2 infection, neuropathogenesis and transmission among ...
    To assess this potential, we challenged deer mice (Peromyscus maniculatus) with SARS-CoV-2 and found robust virus replication in the upper respiratory tract, ...
  97. [97]
    Do Field Mice Transmit Rabies? Clearing Up the Confusion - Jones ...
    Epidemiological Data: U.S. public health records show virtually zero verified rabies cases originating from wild mice or rats. Documented Rodent Rabies Cases.
  98. [98]
    Peromyscus spp. Deer Mice as Rodent Model of Acute Leptospirosis
    Jun 12, 2025 · We found that Peromyscus leucopus white-footed deer mice are susceptible to acute leptospirosis, and thus might be an alternative rodent model.<|separator|>
  99. [99]
    [PDF] Avian influenza overview June–September 2025 | ECDC
    Sep 24, 2025 · Deer mouse (Peromyscus ... Events or conditions that increase mammalian or human exposure to avian influenza viruses may lead to spillover.
  100. [100]
    Unveiling the Gut Microbiota and Resistome of Wild Cotton Mice ...
    To fill this knowledge gap, we present a comprehensive analysis of gut bacteria associated with wild cotton mice (Peromyscus gossypinus) trapped from several ...
  101. [101]
    The Role of Peridomestic Rodents as Reservoirs for Zoonotic ...
    When considering foodborne zoonoses, multiple pathogens have been identified within Peromyscus hosts (Table 1). ... Leptospirosis: A zoonotic disease of global ...
  102. [102]
    The one health perspective to improve environmental surveillance of ...
    Oct 30, 2022 · We describe how One Health inspired environmental surveillance campaigns have emerged as the preferred tools to monitor human-adjacent environments.
  103. [103]
    Peromyscus - Acemap - DDE Scholar
    In reference to the coloring, the word Peromyscus comes from Greek words meaning 'booted mouse'. They are also accomplished jumpers and runners by comparison ...
  104. [104]
    Deer Mice As Laboratory Animals
    Deer mice and their allies (genus Peromyscus) are a wide- spread and diverse group of rodents in North America. Cap- tive bred stocks of normal and variant ...
  105. [105]
    Characterizing phenotypic data of Peromyscus leucopus compared ...
    Jun 14, 2024 · While P. leucopus appear physically similar to Mus musculus, they demonstrate significant anatomical differences in their bone size and length, ...
  106. [106]
    Peromyscus Genetic Stock Center - College of Pharmacy
    Jun 9, 2025 · The deer mouse (Peromyscus maniculatus) and congeneric species are the most common native North American mammal. They range from Alaska to ...
  107. [107]
    The evolution of nesting behaviour in Peromyscus mice
    Ethical Note. All experimental procedures were approved by the Harvard University Institutional Animal Care and Use Committee (IACUC protocol no. protocol 27 ...
  108. [108]
    Measurements of hybrid fertility and a test of mate preference for two ...
    Jan 16, 2019 · Research article ... Selection for male choice based primarily on mate compatibility in the oldfield mouse, Peromyscus polionotus rhoadsi.<|separator|>
  109. [109]
    THE GENETICS OF SPECIATION IN THE RODENT GENUS ...
    Earl G. Zimmerman, C. William Kilpatrick, B. J. Hart; THE GENETICS OF SPECIATION IN THE RODENT GENUS PEROMYSCUS, Evolution, Volume 32, Issue 3, 1 September.
  110. [110]
    Chromosomes of Peromyscus (Rodentia, Cricetidae)
    All species in the genus Peromyscus possess a diploid number of 48, but the number of total chromosome arms varies from 56 (e.g., P. crinitus) to 96 (e.g. ...
  111. [111]
    Rodents for comparative aging studies: from mice to beavers
    Jun 25, 2008 · Finally, we discuss our recent study, which used a comparative approach to reveal that telomerase activity coevolved with body mass in rodents.
  112. [112]
    Photoperiod influences visceral adiposity and the ... - PubMed Central
    These findings suggest that extended photoperiod through artificial light can promote visceral fat accumulation alone, independent of temperature.
  113. [113]
    Sexual imprinting and speciation between two Peromyscus species
    Our study demonstrates that sexual imprinting contributes to reproductive isolation that reduces hybridization between otherwise interfertile species.
  114. [114]
    Sin Nombre Virus Pathogenesis in Peromyscus maniculatus - NIH
    These findings suggest that rodent reservoirs for SNV may not be asymptomatic carriers and that lung morphology may be an indication of viral infection.
  115. [115]
    Comparative reservoir competence of Peromyscus leucopus, C57BL ...
    Jun 20, 2024 · Borrelia burgdorferi has minimal impact on the Lyme disease reservoir host Peromyscus leucopus. Vector Borne Zoonotic Dis 11:117–124. View.
  116. [116]
    Do white-footed mice, the main reservoir of the Lyme disease ... - NIH
    Nov 13, 2024 · The reservoir competence of the white-footed mouse, Peromyscus leucopus, whose role is to amplify and sustain the tick-borne pathogen of Lyme ...
  117. [117]
    Phylogeography within the Peromyscus maniculatus species group
    Here, we study the range dynamics and demography of a cosmopolitan species: the deer mouse, Peromyscus maniculatus.
  118. [118]
    Signatures of positive selection and local adaptation to urbanization ...
    Suggestive of urban adaptation, a specific mitochondrial genotype rose to fixation in white-footed mice (Peromyscus leucopus) populations in Chicago along with ...
  119. [119]
    Effects of Reproductive Experience on Central Expression of ...
    In the monogamous, biparental California mouse (Peromyscus californicus), paternal care has been linked to changes in the central and/or peripheral availability ...
  120. [120]
    Intranasal oxytocin drives coordinated social approach - Nature
    Sep 9, 2021 · Coordinated responses to challenge are essential to survival for bonded monogamous animals and may depend on behavioral compatibility.
  121. [121]
    ASM Mammal Diversity Database
    A comprehensive nomenclatural dataset for 50,000+ synonymous species-rank names, curated with type locality and specimen information. Integration between the ...ASM Mammal Diversity... · Search Database · Mammal Data Resources
  122. [122]
    An annotated checklist of Peromyscus (Cricetidae, Rodentia) in ...
    Nov 22, 2024 · Hooper and Musser (1964) initially proposed 59 species within the genus Peromyscus. Subsequently, Hooper (1968) reduced the count to 57 species ...
  123. [123]
    Mitochondrial DNA Differentiation during the Speciation Process in ...
    The study examines mtDNA divergence in Peromyscus polionotus and P. leucopus, finding 2% divergence in polionotus and 4% in leucopus, and aims to estimate  ...Missing: delimitation | Show results with:delimitation
  124. [124]
    IUCN Red List of Threatened Species
    To date, more than 172,600 species have been assessed for The IUCN Red List. This is an incredible achievement. However, our work is nowhere near complete. We ...About · 3.1 · Searching The IUCN Red List · Citing The IUCN Red List
  125. [125]
    [PDF] A Checklist of Parasites of <i>Peromyscus maniculatus</i> in North ...
    Aug 2, 2022 · This document represents a summary of parasites, in the broadest sense of the term, reported from Peromyscus maniculatus from throughout its ...
  126. [126]
    The Stability of Subspecific Characters Under Changed Conditions ...
    (I) Mice belonging to the subspecies Peromyscus maniculatus sonoriensis, from the Mojave Desert, were reared for more than eight years at La Jolla, ...
  127. [127]
    Genomes, expression profiles, and diversity of mitochondria of the ...
    Nov 26, 2019 · The White-footed Deermouse Peromyscus leucopus occupies a broad range of environments across much of central and eastern United States and ...
  128. [128]
    [PDF] Field Discrimination of Prairie Deer Mice and White-Footed Mice ...
    Prairie deer mice (Peromyscus maniculatus bairdii) and white-footed mice (Peromyscus leucopus noveboracensis) are common and widely distributed rodents in the ...
  129. [129]
    Differential gene expression in relation to mating system in ... - NIH
    Peromyscus californicus, the largest of the species examined (32–54 g), is also found in chaparral and scrub forest habitats from the San Francisco area to ...
  130. [130]
    Interactions between Parents and Parents and Pups in the ... - NIH
    Sep 19, 2013 · Since California mice are monogamous, one male was paired with a single female, and the pair remained together for the duration of the study.
  131. [131]
    Datasets -> California mouse - BrainMaps.org
    The California mouse (Peromyscus californicus) is a monogamous species of rodent found along the coastal mountain ranges and eastern Sierra Nevada of California ...
  132. [132]
    Oldfield Mouse (Peromyscus polionotus) - iNaturalist
    The oldfield mouse or beach mouse (Peromyscus polionotus) is a nocturnal species of rodent in the family Cricetidae. It is found in the southeastern United ...Missing: trisignatus threatened
  133. [133]
    Adaptive Variation in Beach Mice Produced by Two Interacting ... - NIH
    Aug 14, 2007 · Here we identify genetic changes contributing to an adaptive difference in color pattern between two subspecies of oldfield mice (Peromyscus polionotus).Missing: trisignatus threatened
  134. [134]
    Perdido Key beach mouse (Peromyscus polionotus trissyllepsis)
    The Perdido Key beach mouse is an endangered, small, nocturnal herbivore with a grayish fawn to wood brown body, and a white to pale grayish brown tail.<|control11|><|separator|>
  135. [135]
    [PDF] Cotton Mouse (Peromyscus gossypinus)
    Jun 15, 1977 · The preferred habitat of the cotton mouse is bottomland hardwood forests, mesic and hydric hammocks, and swamps (Rhoads, 1896; Howell, 1921; ...Missing: specialist | Show results with:specialist<|control11|><|separator|>
  136. [136]
    Peromyscus aztecus (Aztec mouse) - Animal Diversity Web
    As far as locomotion, walk and run on all four feet. They have contralateral limbs in synchrony, as well as quadrupedal ricochet. This means the hind and ...