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Damaraland mole-rat

The Damaraland mole-rat (Fukomys damarensis) is a medium-sized, subterranean rodent endemic to semi-arid regions of southern and central Africa, including Botswana, Namibia, South Africa, Zambia, and Zimbabwe, where it inhabits woodlands, savannahs, and secondary forests.^[1]^[2] Measuring 14–21 cm in body length with a short tail of 1–3 cm, it has a cylindrical body covered in thick, velvety fur ranging from pale gray to black, often with white patches on the head, and features large incisors for burrowing, small eyes, no external ear pinnae, and sensitive vibrissae for navigation in dark tunnels.^[1]^[3] This eusocial species lives in colonies of 2–48 individuals in extensive underground burrow systems up to 250 cm deep, exhibiting cooperative breeding with a single reproductive female and one to two breeding males, while non-breeders forage, dig, and care for young.^[2]^[3] Damaraland mole-rats are primarily herbivorous, feeding on geophytes such as roots, bulbs, tubers, and aloe leaves, supplemented occasionally by invertebrates like earthworms and insect larvae, and they store food in burrow chambers for efficient consumption.^[1]^[3] Their fossorial lifestyle has led to unique physiological adaptations, including hypoxia tolerance through enhanced oxygen delivery via specialized globin proteins, a low basal metabolic rate of approximately 0.66 mL O₂/g/h, and efficient nutrient absorption supported by a diverse gut microbiome.^[2] Colonies are monogamous, with reproduction typically occurring once annually in the wild—though up to twice in captivity—featuring a gestation period of 78–112 days and litters of 1–6 altricial young, which are weaned after approximately 4 weeks.^[3]^[2]^[4] Non-breeding females experience reproductive suppression via pheromones, and maturity is reached around 73 weeks, though dispersal is often male-biased.^[3]^[5] Behaviorally, these rodents are active around the clock, highly sensitive to vibrations and sounds for communication through squeaks, grunts, and growls, and they rarely surface except to gather nesting materials or during floods when they construct protective mounds.^[1]^[3] With a lifespan exceeding 15–21 years in captivity, Damaraland mole-rats serve as valuable models in biomedical research for studying aging, cancer resistance, and hypoxia responses, bridging traits seen in naked mole-rats and humans; recent studies (as of 2025) on its immune system and cell cultures further highlight its value.^[2]^[6]^[7] Classified as Least Concern by the IUCN due to stable populations across protected areas, they face no major threats but continue to attract scientific interest for their eusociality and environmental resilience.^[8]^[9]

Taxonomy and etymology

Taxonomy

The Damaraland mole-rat is scientifically classified under the binomial name Fukomys damarensis (Ogilby, 1838), with historical synonyms including Cryptomys damarensis.^[10] Its hierarchical classification places it within the domain Eukarya, kingdom Animalia, phylum Chordata, class Mammalia, order Rodentia, suborder Hystricomorpha, infraorder Hystricognathi, family Bathyergidae, genus Fukomys, and species F. damarensis.^[10] The karyotype of F. damarensis exhibits variation, with a diploid chromosome number (2n) of 74 or 78 and a fundamental number (FN) of 92; this consists of 16 metacentric autosomes and 56–60 acrocentric autosomes, a metacentric X chromosome, and an acrocentric Y chromosome.^[11] Historically, the species was classified in the genus Cryptomys until molecular phylogenetic analyses in the early 2000s revealed distinct clades within the African mole-rats, leading to its reclassification into the newly erected genus Fukomys based on both genetic and morphological evidence. Within the Bathyergidae family, F. damarensis belongs to the social Fukomys clade, which comprises multiple eusocial or cooperatively breeding species adapted to subterranean lifestyles, and it is phylogenetically distinct from the eusocial naked mole-rat (Heterocephalus glaber) in the separate genus Heterocephalus.

Etymology

The common name "Damaraland mole-rat" derives from the Damaraland region in northwestern Namibia, where the species was first collected and described, combined with "mole-rat" to reflect its fossorial, burrowing lifestyle similar to moles.^[2] The binomial scientific name is Fukomys damarensis. The genus Fukomys was erected in 2006 to encompass several social African mole-rats previously classified under Cryptomys; its name combines "fuko," derived from mfuko, a vernacular term for mole-rat in Zambian Bantu languages such as Bemba and Kaonde, with the Ancient Greek mys meaning "mouse," a common suffix for rodent genera.^[12] The specific epithet damarensis refers to Damaraland (or the Damara people indigenous to the area), the type locality of the species.^[2] Originally described in 1838 by William Ogilby as Bathyergus damarensis based on specimens obtained during an expedition to the Damara country on the southwest coast of Africa, the name has undergone generic revisions, including a period under Cryptomys damarensis.^[8]^[11]

Physical characteristics

Morphology

The Damaraland mole-rat (Fukomys damarensis) exhibits a robust, cylindrical body form with a low-slung carriage, typically measuring 14–20 cm in head-body length and 2–3 cm in tail length, while adults weigh 100–280 g.^[11]^[2] Males are slightly larger than females on average, though overall sexual dimorphism remains minimal.^[11] The limbs are short and stout, terminating in large, broad feet that facilitate burrowing, while the head is conical with a blunt, horseshoe-shaped muzzle.^[11] Prominent procumbent incisors project forward from the mouth, enabling efficient soil excavation.^[2] The pelage consists of short, thick, velvety fur that covers the body uniformly, ranging in coloration from pale fawn to dark brown or black, even within the same colony.^[11] A distinctive white patch often adorns the occipital region of the head, varying in shape and size, with occasional white stripes or patches along the dorsal and ventral midlines.^[11] Breeding females, or queens, display subtle morphological changes, including skeletal elongation that increases body length, supporting higher fecundity.^[13] Compared to its eusocial relative, the naked mole-rat (Heterocephalus glaber), the Damaraland mole-rat possesses a stockier build with short, stout limbs and a full coat of visible fur, in contrast to the elongated, nearly hairless form of the naked species.^[11]^[14]

Sensory and structural adaptations

The Damaraland mole-rat exhibits profound sensory modifications suited to its subterranean habitat, where vision is minimal and other senses dominate for navigation, foraging, and social interaction. Its eyes are tiny and poorly developed, often described as blue-tinted and concealed beneath thick, translucent skin that covers the eyelids, rendering visual acuity extremely limited.^[2] Despite this regression, the eyes retain sensitivity to light-dark cycles, enabling detection of surface threats or environmental changes when individuals occasionally emerge from burrows.^[15] The absence of external ear pinnae further streamlines the body for tunneling, while the internal ear structure is adapted for low-frequency sound and vibration detection through soil, facilitating communication and predator avoidance via seismic cues.^[16]^[17] Olfaction and tactile senses are highly elaborated to compensate for visual limitations. The olfactory system features an expanded repertoire of functional olfactory receptor genes, particularly in the OR7 family, supporting diverse odor detection essential for locating geophytes and recognizing colony members in darkness.^[18] Relative to brain size, the olfactory bulbs are enlarged compared to aboveground rodents, enhancing chemosensory processing for social cues and foraging.^[19] Tactile navigation relies on densely innervated vibrissae (whiskers) concentrated around the mouth, tail, and scattered across the body, along with sensitive body hairs that detect tunnel textures and air currents during movement.^[2] Structurally, the skeleton is reinforced for chisel-tooth digging, with a robust skull and massively developed jaw adductor muscles that generate high bite forces to excavate hard soils.^[20] Limbs are reduced in length but the forelimbs are powerfully muscled with enlarged claws and broad feet for efficient soil displacement.^[2] Specialized procumbent incisors, projecting forward outside the mouth, are adapted for both excavating burrows and gnawing through tough plant roots, protected by fur-lined buccal flaps that prevent soil ingress during feeding.^[2]

Distribution and habitat

Geographic range

The Damaraland mole-rat (Fukomys damarensis) is endemic to southern Africa, with its core distribution centered in the Damaraland region of central and northern Namibia. The species occupies a broad range extending to southern Angola, most of Botswana (excluding the extreme east), western Zambia, western Zimbabwe, and northern South Africa, particularly the Northern Cape and North West provinces.^[21]^[22]^[9]^[8] The extent of occurrence spans approximately 1,122,000 km² across semi-arid zones of the region, where populations are naturally fragmented by variations in soil type and rainfall patterns that influence habitat suitability.^[21]^[9] First described in 1838, the geographic range has remained largely stable over time, with no evidence of major historical contractions; however, localized extirpations are possible in areas converted to agriculture.^[21]^[11] The International Union for Conservation of Nature (IUCN) classifies the Damaraland mole-rat as Least Concern, based on a 2016 assessment, with the population trend considered stable.^[21]^[9]

Habitat preferences

The Damaraland mole-rat (Fukomys damarensis) prefers warm, semi-arid environments characterized by savannah scrublands, sandy grasslands, thorn-scrub woodlands, and secondary forests. These habitats are typically associated with loose, friable soils that facilitate burrowing, such as red Kalahari sands (psamments) and other coarse arenosols. The species avoids rocky terrains and waterlogged areas, favoring regions where soil consistency allows for extensive underground networks.^[11]^[1] Soil requirements are critical, with the mole-rats inhabiting deep, sandy substrates that can reach up to 2 meters or more in loose conditions, enabling deeper burrow systems for thermal regulation and foraging. Proximity to geophytes is essential, as their diet relies on underground storage organs like tubers of Acanthosicyos naudinianus (from the Cucurbitaceae family), bulbs of Dipcadi, Ledebouria, and Ornithogalum (Hyacinthaceae), and roots from Portulaceae species such as Talinum. These plants are more abundant in areas of moderate vegetation density, providing a reliable food source in otherwise arid landscapes.^[11]^[1] Climatic conditions in preferred habitats include high temperatures exceeding 28°C and low, unpredictable annual rainfall ranging from 200 to 400 mm, with most burrowing activity occurring during the brief wet season when soils are moist and workable. These semi-arid zones offer a stable microhabitat with sufficient plant density to support colony foraging without excessive surface exposure. The species selects sites with minimal flooding risk, constructing nests in elevated burrow chambers during seasonal inundations.^[11]^[1]

Ecology and behavior

Diet and foraging

The Damaraland mole-rat (Fukomys damarensis) has a primarily herbivorous diet consisting mainly of subterranean geophytes, including tubers, corms, bulbs, and roots such as the gemsbok cucumber (Acanthosicyos naudinianus) from the Cucurbitaceae family and bulbs from genera like Ornithogalum (Hyacinthaceae) and Dipcadi. These food items, which contain 77–80% moisture and exhibit 85–95% digestibility, provide all necessary nutrients without reliance on surface vegetation, occasionally supplemented by invertebrates such as earthworms, insect larvae, and termites.^[11]^[23]^[24]^[1]^[3] Foraging occurs through non-destructive excavation of shallow tunnels, typically 5–25 cm belowground, where individuals detect geophytes using olfactory cues from plant volatiles and sensitivity to soil vibrations. Upon locating a food patch, large tubers are left intact in situ and accessed via small entry holes to preserve the resource, while smaller bulbs and corms are harvested and transported to dedicated storage chambers for communal consumption.^[11]^[25]^[24] Non-breeders typically contribute more to these foraging efforts than breeders. Water requirements are met entirely through metabolic water derived from oxidized food substrates and preformed water in geophytes, eliminating the need for free-standing water sources; this is facilitated by low evaporative water loss and the production of highly concentrated urine with osmolalities exceeding 5000 mOsm/L under dehydration stress.^[2]^[11]^[26] Nutritional adaptations enable efficient processing of the high-fiber diet via hindgut fermentation in the cecum, where symbiotic microbes produce short-chain fatty acids (e.g., predominantly acetate) for energy extraction, yielding 266.80 ± 9.25 µmol/caecum per hour. Mineral homeostasis, including calcium and phosphate regulation, occurs independently of vitamin D₃ synthesis due to direct dietary absorption from geophytes, with excesses stored in skeletal and dental tissues; the species' basal metabolic rate is approximately 0.66 cm³ O₂/g·h, representing 67% of the allometrically predicted value for its body mass.^[23]^[11]^[27]^[2] Foraging activity intensifies during rainy seasons, when softened soil facilitates tunnel excavation and access to newly available geophyte patches that emerge post-rainfall.^[25]^[28] Damaraland mole-rats exhibit eusociality, living in cooperative colonies typically ranging from 2 to 40 individuals, with an average size of approximately 9 to 12 members.^[29]^[30] These groups consist of a single monogamous breeding pair—referred to as the king and queen—and non-breeding helpers, which are usually the pair's offspring that remain in the colony to assist with maintenance and survival.^[30]^[31] Colonies maintain a strict linear dominance hierarchy, with the breeding male ranked highest, followed by the breeding female, non-breeding males, and non-breeding females at the bottom. This hierarchy is enforced primarily through aggressive interactions, such as shoving, biting, and vocalizations including squeaks, grunts, and growls, which help establish and preserve social order.^[3]^[32] Non-breeding helpers contribute to colony tasks without specialized castes, performing essential roles in digging tunnels, foraging for geophytes and tubers, and providing care for pups, such as transporting food to the nest and offering fecal pellets for gut inoculation.^[30]^[2] Reproductive suppression of subordinates is socially induced, primarily through dominance behaviors by the breeding pair, preventing non-breeders from reproducing and ensuring high skew in favor of the king and queen.^[33]^[34] Dispersal in Damaraland mole-rats is male-biased and typically occurs during rainy seasons when soil softens, facilitating movement; however, success rates are low, with only about 10% of attempts resulting in the founding of new colonies or integration into existing ones.^[4]^[29] A 2023 study demonstrated that cooperative breeding is not obligate in this species, as breeding pairs can successfully reproduce and raise offspring without helpers, challenging the view of strict eusocial dependence.^[35] New colonies form primarily through fission events, often triggered by increased rainfall, or via dispersal, with mechanisms for inbreeding avoidance promoting outbreeding when dispersers encounter unrelated individuals.^[29]^[36]

Burrowing and daily activity

The Damaraland mole-rat constructs extensive underground burrow systems that serve as primary habitats, with mean total lengths of approximately 130 meters covering an area of about 1,403 square meters in studied colonies.^[37] These networks feature tunnels with a mean diameter of 6.5 centimeters and depths averaging 40 centimeters to the roof, including secondary foraging tunnels at 15–35 centimeters deep that branch extensively, comprising up to 80% of the system length.^[37] Deeper sections include 1–2 central burrows reaching up to 2 m in depth, connecting to specialized chambers such as nests for resting and rearing offspring, as well as areas for food storage and waste disposal; larger colonies exhibit more complex architectures with increased total length, branching, and covered area.^[37] Burrow construction is primarily undertaken by non-reproductive helpers using their incisors to loosen soil and forelimbs to excavate and transport it, with ejected material forming surface mounds, particularly following heavy rains that soften the substrate.^[38] In dispersing groups, such systems can extend to around 100 meters in length over a month of activity, producing over 120 mounds as soil is displaced.^[38] Colony size influences the scale, as larger groups enable more rapid and extensive digging through coordinated efforts.^[37] Daily activity follows flexible circadian rhythms entrained by both light and ambient temperature cues, with individuals often concentrating locomotion during cooler periods to facilitate digging and reduce heat stress.^[39] In free-ranging populations, patterns vary individually and seasonally, showing diurnal, nocturnal, or bimodal tendencies, but with greater body temperature fluctuations and lower minima in winter compared to summer, indicating reduced activity during drier, hotter conditions.^[40] Activity is predominantly nocturnal at moderate temperatures (20–30°C), though non-reproductives display more daytime movement, and rhythms adjust to small environmental shifts.^[41] Burrow defense and maintenance involve sealing entrances to protect against predators and intruders, primarily led by reproductive individuals who aggressively repel same-sex competitors while subordinates contribute minimally.^[42] Systems are kept sealed from the surface overall, with shallow plugs potentially aiding ventilation, and repairs focus on preserving integrity against collapse or invasion.^[43] Group coordination in burrowing and activity is synchronized, with no strict task specialization by body mass or caste; instead, helpers engage in collective digging and resting phases influenced by light detection and temperature, ensuring efficient system expansion and maintenance.^[43]

Reproduction

Breeding system

The Damaraland mole-rat (Fukomys damarensis) exhibits a eusocial breeding system characterized by extreme reproductive skew, where reproduction is monopolized by a single breeding female, termed the queen, and typically one breeding male within each colony of 10–25 individuals. Subordinate helpers, which include both males and females, remain reproductively inactive and sterile until opportunities for dispersal or colony fission arise, allowing them to establish new colonies or join existing ones as breeders. This hierarchy ensures that only unrelated pairs initiate reproduction, aligning with the species' obligate outbreeding strategy.^[44]^[45] Queen selection occurs through dominance establishment, often when an unrelated female pairs with a male, leading to physiological changes such as enhanced ovarian development in the dominant individual, including active follicular growth and the presence of corpora lutea, contrasting with the underdeveloped ovaries of subordinates that show luteinized but unruptured follicles. Suppression of subordinate reproduction involves a combination of social cues and self-restraint mechanisms, with the queen exerting behavioral control through aggression to maintain her status, while pheromonal signals may contribute to inhibiting ovarian activity in non-breeders, though direct physiological suppression eases under relaxed ecological constraints like rainfall-induced dispersal opportunities. Subordinates do not rapidly activate reproduction upon isolation from the queen, underscoring the role of inbreeding avoidance in sustaining skew.^[45]^[33]^[46] Mating dynamics feature monogamous pair-bonding between the queen and breeding male, supported by long-term consort relationships and neurobiological correlates like oxytocin receptor expression in reward centers, resembling bonds in other monogamous species. Courtship is female-initiated, involving substrate drumming with hind feet and chirping vocalizations to attract the male, followed by mutual chasing in tunnels, tail-raising, and lordosis postures before copulation. This system promotes genetic diversity through male-biased dispersal, where males travel farther (mean 215 m) than females to join colonies, preventing close-kin mating; genetic analyses reveal low inbreeding coefficients, with population differentiation (F_ST ≈ 0.167) indicating effective outbreeding and minimal inbreeding depression in wild populations.^[47]^[2]^[29] Recent research highlights that cooperative breeding in Damaraland mole-rats is non-obligate, as isolated unrelated pairs can successfully breed and rear offspring without helpers, suggesting that while eusociality enhances colony fitness, it is not essential for individual reproduction under laboratory conditions simulating relaxed ecological pressures.^[35]

Reproductive cycle

The reproductive cycle of the Damaraland mole-rat (Fukomys damarensis) is characterized by year-round breeding activity, though it peaks during the rainy season when ecological conditions favor dispersal and reduce reproductive suppression among subordinates.^[48] Courtship is initiated by the breeding female, who vocalizes and drums her hind feet upon encountering the breeding male; the pair then engages in circular chasing in a head-to-tail formation, with the female mounting the male's head before adopting a lordosis posture, allowing the male to sniff her genitalia and mount for copulation. Mating occurs frequently over approximately 10 days, often involving multiple copulations with neck-biting by the male. Gestation lasts 78–92 days, during which the female's body mass can increase by up to 21%.^[11] Females can produce up to three litters per year, with interbirth intervals aligning closely with the gestation period.^[2] Litter sizes range from 1 to 6 pups, with an average of 3; sizes tend to increase with maternal parity, reaching means of about 4.3 pups by the fourth litter in captivity.^[11]^[2] Pups are born altricial, hairless, and with eyes closed, weighing 8–10 g; they develop pelage within 4–6 days, open their eyes around 18 days, begin consuming solid food at 6–8 days, and are fully weaned after approximately 28 days of nursing by the queen.^[2]^[11] Parental care is provided primarily by the breeding female through nursing, but non-breeding helpers play a crucial cooperative role, including retrieving wandering pups to the nest, providing fecal pellets to establish the pups' gut microbiome, transporting food to the nursery, and assisting in thermoregulation by huddling with the litter to maintain warmth in the burrow environment.^[2] Pups reach sexual maturity at around 14 months, though subordinates typically remain suppressed until dispersal or colony founding.^[11] Breeding females exhibit extended longevity, living up to 20–21 years in captivity, which supports their high lifetime reproductive output compared to non-breeders.^[2]

Physiology and genetics

Physiological adaptations

The Damaraland mole-rat (Fukomys damarensis) exhibits remarkable tolerance to hypoxia, enabling survival in burrow environments with low oxygen levels due to poor ventilation and group huddling in nest chambers.^[50] This adaptation is facilitated by high oxygen affinity hemoglobin, a shared trait among African mole-rats that enhances oxygen binding and delivery under low-oxygen conditions, along with ventilatory adjustments; it also features a reduced basal metabolic rate approximately 30–60% lower than predicted for rodents of similar body mass, thereby conserving oxygen demand.^[51]^[52] Thermoregulation in the Damaraland mole-rat shows poikilothermic tendencies, with body temperatures typically ranging from 32–35°C, lower than many surface-dwelling rodents, allowing energy savings in fluctuating subterranean conditions.^[40] Individuals often huddle in groups to maintain thermal stability, particularly during cooler periods when body temperature variability increases, as evidenced by higher heterothermy indices in winter.^[53]^[54] These mole-rats demonstrate exceptional longevity, with lifespans reaching up to 20 years in captivity—far exceeding the 3–4 years typical for comparably sized rodents—attributed in part to resistance against oxidative stress through efficient DNA repair mechanisms and low rates of cellular damage accumulation.^[55]^[52] This longevity is linked to minimal cancer incidence, potentially supported by a mutation in the HAS2 gene that may enable production of high-molecular-mass hyaluronan to inhibit aberrant cell proliferation.^[56] Water and mineral conservation are critical adaptations, achieved through production of highly concentrated urine to minimize water loss in arid habitats and vitamin D-independent calcium absorption from geophyte-based diets, enabling high fractional uptake (over 85%) without reliance on sunlight exposure for activation.^[57]^[58] Unlike the naked mole-rat, which achieves similar hypoxia tolerance through more extreme ventilatory suppression and complete hairlessness for heat dissipation, the Damaraland mole-rat employs distinct metabolic strategies, including less pronounced respiratory adjustments, while retaining sparse fur.^[52]^[59]

Genetic structure

The Damaraland mole-rat (Fukomys damarensis) has a diploid chromosome number of 2n = 78 and a fundamental number (FN) of 92. This karyotype reflects minor differences in chromosomal structure across populations but does not include polymorphisms associated with the species' eusociality, as social organization appears independent of gross cytogenetic differences.^[60] Despite forming small colonies typically comprising 10–25 individuals, Damaraland mole-rats show low levels of inbreeding in the wild, with breeding pairs often unrelated (mean relatedness r ≈ 0.02) and overall colony relatedness averaging around 0.22; however, captive populations exhibit inbreeding depression affecting traits like body mass.^[61]^[62] High heterozygosity is maintained through outbreeding facilitated by male-biased dispersal, where males more frequently leave colonies to join or found new ones, promoting gene flow.^[29] Microsatellite marker analyses confirm that colonies are not fully inbred, as multiple paternities and immigrant sires contribute to genetic diversity within groups. Reproductive skew in Damaraland mole-rats, where a single breeding female and one to three males monopolize reproduction, involves genetic mechanisms that suppress fertility in non-breeders, including downregulation of genes in pathways akin to oxytocin signaling, which regulate social behavior and reproductive inhibition.^[45] Microsatellite studies further reveal that this skew persists without extreme inbreeding, as helper subordinates retain potential fertility suppressed by social and genetic factors rather than fixed genetic defects. Population genetics of Damaraland mole-rats display a spatial structure characterized by isolation by distance, where genetic differentiation increases with geographic separation between colonies.^[5] A 2021 study using microsatellite loci across 96 individuals from 21 colonies demonstrated moderate gene flow driven by dispersers, particularly males, which counteracts local isolation and supports colony fission-fusion dynamics over distances up to several kilometers.^[29] As of 2025, genomic sequencing efforts, including a high-quality assembly from 2014 and subsequent fibroblast-based analyses in 2024, have identified species-specific adaptations in cancer resistance genes, such as enhanced DNA repair pathways and hyaluronan regulation, sharing similarities with naked mole-rats but distinct in hypoxia tolerance and proteostasis mechanisms.^[56]^[7]

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Jul 30, 2014 · In Damaraland mole-rats Fukomys damarensis, natal philopatry typically results in colonies consisting of a breeding female and up to two ...Missing: fur coloration
[34]
Damaraland mole-rats do not rely on helpers for reproduction or ...
May 29, 2023 · Our results suggest that Damaraland mole-rats do not need groups to survive and that cooperative breeding in the species is not obligate.Missing: reclassification | Show results with:reclassification
[35]
[PDF] Out-breeding behaviour and xenophobia in the Damaraland mole ...
Out-breeding behaviour and xenophobia were investigated in laboratory colonies of the Damaraland mole-rat. Cryptomys damarensis.
[36]
Burrow Architecture of the Damaraland Mole-Rat (Fukomys ...
Aug 6, 2025 · A higher temperature stress in habitats of F. damarensis may be indicated by deeper nests, but it should be noted that not all of its ...<|control11|><|separator|>
[37]
An example of burrow system architecture of dispersing Damaraland ...
The study provides an example of dispersal in Damaraland mole-rats and gives new insights into the method of burrow system construction of this species. It ...
[38]
Full article: The role of ambient temperature and light as cues in the ...
Mar 5, 2024 · In order to determine whether the circadian rhythm of LA of the Damaraland mole-rat could entrain Ta cycles without light, all animals were ...
[39]
Body Temperature Patterns and Rhythmicity in Free-Ranging ...
Oct 18, 2011 · We investigated patterns of T b patterns in a homeothermic, free-ranging small mammal, the Damaraland mole-rat (Fukomys damarensis) during both the summer and ...Missing: basal | Show results with:basal
[40]
The effect of ambient temperature on locomotor activity patterns in reproductive and non‐reproductive female Damaraland mole‐rats
### Summary of Locomotor Activity Patterns in Damaraland Mole-Rats
[41]
Colony defense in Damaraland mole-rats, Cryptomys damarensis
In contrast, they strongly suggest that Damaraland mole-rats defend burrows primarily to defend their breeding status against potential competitors. If defense ...Missing: coordination | Show results with:coordination
[42]
[PDF] architecture of Damaraland mole rat burrow system
The first animals caught in the traps might be those actively involved in defence and repair of the tunnel system. We found in two out of 24 colonies a ...
[43]
[PDF] group dynamics and social control of reproduction in African mole-rats
In African mole-rats, reproduction is unequally partitioned, with dominant individuals monopolizing breeding, causing a 'reproductive skew' and varying ...
[44]
Socially Induced Infertility in Naked and Damaraland Mole-Rats
The naked and Damaraland mole-rats are group-living, subterranean mammals in which reproduction is distributed unequally among members of a social group.Missing: karyotype chromosomes<|control11|><|separator|>
[45]
Physiological suppression eases in Damaraland mole-rat societies ...
Physiological suppression in subordinate mole-rats eases during the annual rains when dispersal constraints relax, increasing reproductive readiness.Missing: pheromones | Show results with:pheromones
[46]
[PDF] Damaraland and naked mole-rats: convergence of social evolution 19
Sep 28, 2015 · As a consequence, overlapping litters of nonbreeding indi- viduals remain with their parents and adopt various helper roles, including ...
[47]
Physiological suppression eases in Damaraland mole-rat societies ...
Here we present new evidence from wild Damaraland mole-rats, Fukomys damarensis, revealing that physiological suppression among subordinate females eases ...Missing: queen aggression pheromones
[48]
Extreme Physiology Extreme Tolerance to Hypoxia, Hypercapnia ...
Data is from naked mole-rats and three comparison species, including another African mole-rat species, the Damaraland mole-rat (DMR). This figure is from ...
[49]
Naked mole-rat and Damaraland mole-rat exhibit lower respiration ...
BMR of the two mole-rat species were estimated to be about 30 % - 60 % lower than that predicted by body mass [12,29-31,56,64]. The comparison between these ...
[50]
Body Temperature Patterns and Rhythmicity in Free-Ranging ... - NIH
Oct 18, 2011 · The Damaraland mole-rat is a eusocial species that occurs in colonies of up to 40 individuals [26], [27]. They inhabit closed burrow systems ...
[51]
Together or alone? Huddling energetic savings in three social mole ...
Thermoregulation is one of the most energetically demanding physiological processes in endothermic animals and this is most apparent in small-bodied species at ...<|separator|>
[52]
Establishment of primary and immortalized fibroblasts reveals ...
Dec 2, 2024 · The Damaraland mole-rat (DMR, Fukomys Damarensis, Fig. 1a) is a eusocial, long-lived, medium-sized mole-rat species that inhabits a complex maze ...<|control11|><|separator|>
[53]
Not just a cousin of the naked mole-rat - PubMed Central
In this regard, other African mole-rat species, such as the Damaraland mole-rat (DMR; Fukomys damarensis; Fig. 1), who share many similar characteristics ...
[54]
Adaptations to a Subterranean Environment and Longevity ...
Sep 11, 2014 · The DMR was known as Cryptomys damarensis prior to a recent subclassification into a new genus, Fukomys (Kock et al., 2006). The animals ...
[55]
Dietary Calcium Content, Calcium Balance and Mode of Uptake in a ...
When mole-rats were fed a diet low in Ca, apparent fractional absorption of Ca was high (85.88%). This increased still further when the diet was changed to a ...
[56]
Vitamin D metabolism in the Damara mole-rat is altered by exposure ...
Damara mole-rats' vitamin D metabolism is altered by sunlight, increasing 1,25(OH)2D, but mineral metabolism remains unaffected. They have low vitamin D status.Missing: Damaraland | Show results with:Damaraland
[57]
Not just a cousin of the naked mole-rat - ScienceDirect.com
Damaraland mole-rat (DMR) shares multiple characteristics in common with NMR, but shows higher degree of similarity with human in some aspects of their ...
[58]
[PDF] THE EVOLUTION OF NUCLEAR MICROSATELLITE DNA ...
share the same karyotype (2N ... damarensis with a 2N = 74-78 and NF = 92-96 (Nevo ... wild colonies of naked mole-rats (Heterocephalus glaber) by DNA.
[59]
Eusociality in African mole-rats: new insights from patterns of genetic ...
Using microsatellite markers, we show that most breeding pairs in wild colonies of the Damaraland mole–rat are indeed unrelated (R = 0.02 ± 0.04) and that mean ...Missing: chromosomal | Show results with:chromosomal
[60]
Establishment of primary and immortalized fibroblasts reveals ...
Dec 2, 2024 · Resistance of Damaraland mole-rat (DMR) fibroblasts to various cytotoxic agents. Cell viability of DMR, naked mole-rat (NMR), and mouse skin ...