Dhole
The dhole (Cuon alpinus), also known as the Asiatic wild dog, is a species of canid native to the forests of South, East, and Southeast Asia, distinguished by its highly social pack structure and cooperative hunting strategies that enable it to pursue medium- to large-sized ungulates such as deer and wild boar.[1] Unlike other canids like wolves, dholes possess fewer but larger teeth adapted for shearing flesh, and they communicate via distinctive whistling calls during hunts in dense vegetation.[2] Typically diurnal, dholes form packs of 5 to 12 individuals, though larger groups up to 40 have been observed, with complex social dynamics including alloparenting and communal pup-rearing.[3] Their historical range once extended from the Indian subcontinent to parts of Russia and Indonesia, but fragmentation has confined extant populations primarily to protected areas amid competition with larger predators like tigers and leopards.[4] Classified as Endangered on the IUCN Red List since 2015, the global dhole population is estimated at fewer than 2,500 mature individuals, with ongoing declines driven by habitat loss, prey depletion, human persecution, and disease transmission from domestic dogs.[5] Conservation efforts focus on habitat connectivity and anti-poaching measures in strongholds like India's protected forests, where dholes exhibit adaptability to varied ecosystems from tropical lowlands to montane regions, though their reliance on abundant ungulate prey underscores vulnerability to ecological imbalances. Despite their elusive nature limiting data, recent studies highlight the species' ecological role as an apex regulator of herbivore populations, emphasizing the need for landscape-scale protections to avert further extirpations.[6]Taxonomy and Evolution
Etymology and Naming
The common name "dhole" has an uncertain etymology, though it is reported to originate from an ancient Asiatic term connoting recklessness or daring, as noted by zoologist St. George Mivart in 1890.[7] [8] The earliest documented English usage appears in an 1808 account by British soldier Thomas Williamson, who described encounters with the species in India.[9] Alternative English names include Asiatic wild dog, reflecting its similarity to the African wild dog (Lycaon pictus), and whistling dog or red dog, the latter alluding to its vocalizations and reddish coat.[10] [11] The scientific binomial Cuon alpinus was first proposed as Canis alpinus by naturalist Peter Simon Pallas in 1811, based on specimens from Asian mountainous regions.[12] In 1833, Brian Houghton Hodgson initially classified it as Canis primaevus, positing it as an ancestral form of the domestic dog, but later recognized its distinctiveness and erected the genus Cuon in 1838 to accommodate it.[9] [13] The genus name Cuon derives from the Ancient Greek κύων (kuōn), meaning "dog," while the specific epithet alpinus is Latin for "alpine" or "mountain-dwelling," referencing the species' preferred habitats in hilly and forested uplands.[14] [15]Phylogenetic Relationships and Reticulate Evolution
The dhole (Cuon alpinus) belongs to the tribe Canini within the family Canidae, forming a monophyletic genus distinct from Canis and Lycaon. Phylogenetic analyses of mitochondrial genomes position the dhole as sister to the Canis clade (encompassing wolves, coyotes, dogs, and jackals), with a divergence estimated at 5.22–7.06 million years ago based on ancient and modern sequences.[16] Nuclear genomic data corroborate this placement, showing the dhole clustering outside Canis but within the core Canini radiation, basal to Canis relative to the African wild dog (Lycaon pictus).[16] The complete mitochondrial genome of the dhole, at 16,672 base pairs—the shortest among canids—further supports this topology when analyzed with 14 concatenated protein-coding genes via maximum parsimony methods.[17] Ancient DNA from European dhole fossils reveals greater mitochondrial diversity in Pleistocene populations (e.g., 185 pairwise differences) compared to modern Asian dholes (17 differences), indicating a historical range contraction and loss of basal lineages.[16] Some morphologically identified fossils have been reclassified as gray wolves (Canis lupus) upon genetic scrutiny, highlighting challenges in distinguishing extinct dholes from sympatric canids without molecular evidence.[16] Overall, the dhole's phylogenetic position underscores its evolutionary independence from Canis, despite morphological convergences like pack-hunting adaptations. Reticulate evolution in the dhole lineage is evidenced by ancient interspecific gene flow, particularly with the African wild dog (Lycaon pictus), as detected in genomic comparisons revealing shared alleles inconsistent with strict bifurcating phylogeny.[18] This gene flow likely occurred during Pleistocene range overlaps in Eurasia and Africa, facilitating adaptive introgression but predating modern divergences.[18] No substantial recent hybridization with Canis species is documented, though low contemporary genetic diversity (e.g., phylogeographic structuring across Asian subpopulations) suggests bottlenecks that may mask older reticulate signals.[19] Such non-tree-like processes challenge purely cladistic models for Canini, emphasizing hybrid origins in shaping dhole adaptations like hypercarnivory.[20]Subspecies and Genetic Diversity
Traditionally, taxonomists have described 7 to 12 subspecies of Cuon alpinus based on morphological traits including body size, pelage coloration, and cranial features, often categorized into northern forms (e.g., C. a. alpinus, C. a. hesperius, C. a. laniger) with larger builds and lighter coats, and southern forms (e.g., C. a. adjustus, C. a. lepturus, C. a. sumatrensis, C. a. javanicus) exhibiting smaller size and darker fur.[7] These distinctions, initially proposed in the late 19th century, reflect potential clinal variations across the species' range rather than sharp genetic breaks, and their taxonomic validity has been questioned due to overlap in traits and limited sample sizes in early descriptions.[21] Genetic studies have found minimal differentiation supporting discrete subspecies, with mitochondrial DNA analyses revealing shared haplotypes across nominal groups, such as between C. a. dukhunensis and C. a. adjustus, indicating ongoing gene flow historically.[22] The IUCN assesses Cuon alpinus as monotypic, without formal recognition of subspecies, emphasizing range-wide threats over subspecific divisions.[23] Population genetic diversity in dholes is generally low, attributed to Pleistocene bottlenecks and recent fragmentation, though it varies regionally: highest in southern Indian mainland populations (e.g., haplotype diversity up to 0.89 in some samples) and lowest in isolated Southeast Asian isolates like Java (near-zero diversity in Baluran National Park samples).[24] Microsatellite-based assessments across Indian tiger reserves identify five differentiated subpopulations with moderate heterozygosity (mean 0.62–0.68), but signal recent declines (e.g., effective population size reductions of 50–70% over the past century), heightening inbreeding risks (F_IS up to 0.15).[25] Sumatran and Javan populations show close relatedness, potentially warranting separate management despite low overall variation.[26]Fossil Record
The fossil record of Cuon alpinus extends from the Middle Pleistocene to the Holocene, with the oldest confirmed remains documented from the Trinchera-Galería locality at the Sierra de Atapuerca site complex in Spain, dating to the Middle Pleistocene.[27] Additional early Middle Pleistocene fossils have been identified in Java, indicating the species' presence in Southeast Asia during this period.[28] These findings suggest C. alpinus originated in Eurasia and dispersed widely across the continent. Fossils from the Middle Pleistocene in Europe include records from Poland, dated between 650 and 450 ka, where C. alpinus inhabited open landscapes alongside other large canids such as Lycaon lycaonoides.[29] In the Iberian Peninsula, Pleistocene populations exhibited dental and postcranial dimensions larger than those of extant dholes, with morphometric analyses revealing diachronic trends in size reduction over time.[21] Late Pleistocene European fossils are known from multiple sites, including Jáchymka Cave in the Czech Republic (ca. 35–45 ka), Bacho Kiro Cave in Bulgaria (ca. 39–45 ka), and Peștera Seacă din Ogașul Stoienilor in Romania (ca. 25 ka).[16] Ancient DNA extracted from these and similar remains has verified C. alpinus in select cases but reclassified others as gray wolves (Canis lupus), underscoring the challenges posed by morphological overlap and size variation in fossil identification.[16] Genetic analyses further indicate greater mitochondrial divergence in ancient European dholes compared to modern Asian populations, implying significant historical gene flow and subsequent loss of diversity.[16] The species' Pleistocene distribution encompassed much of Eurasia, including Central Asia, but fossil evidence becomes scarce after the Last Glacial Maximum, correlating with regional extinctions in Europe and northern Asia.[16] Isolated records from North America, such as in Alaska and Mexico, remain tentative and require further verification due to limited material and potential misattributions.[30] Overall, the fragmented fossil record reflects C. alpinus' adaptability to diverse Pleistocene environments but highlights identification difficulties that may underestimate its past abundance.[16]Physical Characteristics
Morphology and Adaptations
The dhole (Cuon alpinus) measures 90 cm in combined head and body length, with a tail length of 40-45 cm and a shoulder height of 50 cm.[1] Adults weigh 12-20 kg, showing minimal sexual dimorphism in size.[31] The body is slender and agile, with a thick muzzle distinguishing it from other canids.[1] The pelt is predominantly rusty red above with paler underparts, exhibiting regional variations from light brownish-gray to deep red; it darkens to sooty brown at birth, maturing by three months, and includes a bushy, typically dark tail.[1] Summer fur is shorter and coarser, while winter pelage provides insulation in cooler ranges.[12] The skull is wide and massive, with a convex profile, well-developed sagittal crest, and enlarged masseter muscles enabling powerful bites for prey dismemberment.[9] Dentition totals 38 teeth, featuring one fewer lower molar per side than typical canids (dental formula: I³/³, C¹/¹, P⁴/⁴, M²/²), reduced upper molars (one-third to one-half wolf size, single-cusped), and carnassials specialized for shearing meat indicative of hypercarnivory.[1][9][32] These features, including post-carnassial molar reduction, facilitate rapid flesh consumption during group feeding on ungulates.[32][31]Sensory and Vocal Capabilities
Dhomes possess dichromatic vision, with sensitivity to short (blue to near-UV) and medium (green) wavelengths, enabling detection of movement and contrast particularly in forested environments during diurnal hunts.[33] They rely primarily on sight to locate prey, supplemented by sound cues for pack coordination in dense habitats.[33] [34] Olfaction is highly developed, as in other canids, with dholes using scent to track prey over distances and in undergrowth where visibility is limited.[33] In dense Asian forests, they depend heavily on smell during pursuits, integrating it with visual detection for effective pack hunting.[34] Auditory capabilities include sensitivity extending to higher frequencies, aiding in social coordination among pack members.[35] Acute hearing facilitates detection of prey sounds and maintains contact during chases, where whistles and other calls propagate through vegetation.[33] Dhomes exhibit a diverse vocal repertoire comprising 11 distinct call types, classified into low-tonal (e.g., yaps, whistles, barks, howls, squeals, screams, whines), high-tonal (squeaks, yap-squeaks), and pulsed (staccato, grambles) categories based on frequency, structure, and rhythm.[36] Whistles, often frequency-modulated sweeps, serve for long-distance pack contact during hunts, while yaps occur in everyday activities and aggression, and barks signal inter-individual conflicts.[36] [37] High situational specificity characterizes most calls, with nine types linked primarily to one context, such as screams in aggression or sexual interactions; unlike wolves, dholes lack prolonged howls for territory marking.[36] Some calls feature biphonation, combining low- and high-frequency components to enhance individual recognition in noisy environments.[38]Distribution and Habitat
Historical Range
The dhole (Cuon alpinus) historically occupied a broad expanse across Asia, extending from temperate and boreal forests in the Russian Far East and Siberia southward through diverse habitats in China, the Indian subcontinent, and into Southeast Asia. In the 18th and 19th centuries, the species' northern limit reached the Altai Mountains and regions like Primorye (Ussuri dhole populations), with sightings documented as far north as reported by Pallas.[39] [12] Across China, dholes were distributed in most provinces, including northern areas up to the Yangtze River and Himalayan foothills, prior to 20th-century declines driven by habitat loss and persecution.[40] [41] The range included Mongolia, the Korean Peninsula, and extended westward into the forests and grasslands of India and Burma (Myanmar), where 19th-century accounts describe packs in forested tracts.[1] In Southeast Asia, historical presence spanned Indochina (including Laos, Vietnam, and Cambodia), the Malay Peninsula, and islands such as Java, Sumatra, and Indonesia, reflecting adaptation to tropical and subtropical ecosystems.[11] This pre-20th-century distribution represented a continuous gradient from alpine to lowland habitats, supporting metapopulations that have since fragmented. Overall, the dhole's historical range covered approximately five million square kilometers, but populations vanished from more than 80% of this area by the late 20th century due to human activities including bounties, deforestation, and competition with domestic livestock.[23] Fossil evidence indicates even wider Pleistocene distributions into Europe and possibly North America, but Holocene records confirm the Asian focus as the baseline for recent historical extent.[16]Current Distribution
The dhole (Cuon alpinus) currently inhabits fragmented populations across South and Southeast Asia, occurring in approximately 11 countries including India, Nepal, Bhutan, Bangladesh, Myanmar, Thailand, Laos, Cambodia, Vietnam, Malaysia, and Indonesia, with possible remnants in China.[41][42] India holds the largest remaining populations, primarily in protected areas such as tiger reserves in central India (e.g., Kanha, Bandhavgarh), the Western Ghats, Eastern Ghats, and parts of the northeast.[41][43] In Southeast Asia, distributions are more discontinuous, with records from forested regions in Thailand, Laos, and Indonesia's islands of Sumatra and Java, though local extirpations have occurred in many areas.[41][44] Global population estimates range from 4,500 to 10,500 individuals, of which 949 to 2,215 are mature, reflecting severe fragmentation into small, isolated packs typically numbering 5–12 animals.[41] These subpopulations exhibit high fluctuation and are confined to less than 20% of their historical range, with densities lowest in peripheral regions like China and highest in core Indian habitats.[26] Recent camera trap surveys and genetic studies confirm ongoing presence in key sites, such as Bhutan's Jigme Singye Wangchuck National Park and Cambodia's Cardamom Mountains, but underscore the vulnerability due to isolation.[41][25]Habitat Preferences and Requirements
Dhōles (Cuon alpinus) primarily occupy forested ecosystems across South and Southeast Asia, favoring habitats that provide dense vegetative cover for stalking prey while allowing open spaces for cooperative pursuits. These include tropical moist deciduous forests, dry deciduous forests, and montane forests with mixed evergreen and broadleaf components.[45] Studies in the Himalayas indicate selective use of most available habitat types, with avoidance of barren lands and conifer-dominated stands such as those of Juniperus and Abies species, where prey density is typically low.[45] Elevational range extends from near sea level to over 4,000 meters, though populations are concentrated in mid-elevation forests with altitudinal gradients supporting diverse ungulate prey.[46] Key habitat requirements encompass high densities of medium- to large-sized ungulates, such as deer and wild boar, which form the core of the dhole's diet and necessitate territories with sufficient biomass to sustain pack hunting.[11] Proximity to perennial water sources is essential for drinking and thermoregulation, particularly in drier seasonal forests.[11] Denning sites, often natural rock crevices, burrows excavated by other species, or thickets, must be available within territories to support reproduction, with packs showing fidelity to areas offering secure, elevated refuges.[11] Habitat suitability is further influenced by structural complexity, including understory cover for concealment and grassy clearings for chases, as dhōles exhibit flexibility in microhabitat use but depend on overall landscape connectivity to mitigate fragmentation effects.[45] In regions like the Indian subcontinent and Southeast Asian highlands, dhōles persist in mosaic landscapes blending forests with meadows, but anthropogenic degradation reduces viability by diminishing prey and increasing human-wildlife conflict exposure.[46] Conservation assessments highlight that only a fraction of potential habitats currently support viable populations, underscoring the need for protected areas preserving these multifaceted requirements.Behavior and Ecology
Social and Territorial Dynamics
Dhōles (Cuon alpinus) exhibit highly social behavior, living in packs typically comprising 5 to 12 adults, though sizes range from 2 to 25 individuals and occasionally up to 40.[47] Packs are structured around a dominant breeding pair that leads group activities, but the hierarchy is less rigid than in gray wolves (Canis lupus), permitting multiple females to breed in some clans and emphasizing cooperative roles over strict dominance.[11] This social organization facilitates collective hunting and pup-rearing, with non-breeding members contributing to communal care and defense.[10] Communication within packs relies on a diverse vocal repertoire, including whines, yaps, squeaks, screams, growls, and chatter calls, which serve to maintain contact during hunts, signal alarms, and reinforce social bonds.[48] These vocalizations enable coordination over distances, particularly in dense forests, and differ from the howls of other canids, reflecting adaptations to dhōle pack dynamics. Scent marking and body postures also play roles in intra-pack interactions and hierarchy maintenance.[48] Territorially, dhōles defend large home ranges averaging up to 100 km² (about 34 square miles), which overlap minimally with neighboring packs to secure prey resources.[49] They mark territories using urine, feces, and gland secretions, and respond aggressively to intrusions, employing group chases and vocal threats. Observations indicate a "dear enemy" phenomenon, wherein dhōles display greater aggression toward unfamiliar intruders than established neighbors, reducing energy expenditure on routine boundary patrols while prioritizing threats from strangers.[50] This strategy aligns with their reliance on pack cooperation for territorial integrity and resource access.[50]Hunting Strategies and Diet
Dholes (Cuon alpinus) are highly cooperative pack hunters that primarily target medium- to large-sized ungulates through relentless pursuit tactics, overwhelming prey with superior numbers and stamina rather than stealth or ambush. Packs, typically comprising 5–12 adults but occasionally up to 30 individuals, coordinate attacks by encircling and chasing quarry over distances of several kilometers until exhaustion, with individuals taking turns to harass and bite at vulnerable areas like the hindquarters.[51][52] This endurance-based strategy exploits the dholes' cursorial adaptations, enabling them to subdue animals 10 times their individual body weight, such as sambar deer or wild boar, though success rates vary with pack size and prey density—larger packs preferentially select bigger prey species.[51][53] Vocalizations play a critical role in maintaining pack cohesion during hunts; distinctive whistles and high-pitched calls allow coordination across dense vegetation, reassembling scattered members and signaling pursuit phases without visual contact.[11][36] The dholes' diet is carnivorous and opportunistic but heavily skewed toward ungulate biomass, comprising 80–90% in most studied populations across Asian forests and grasslands. Key prey includes barking deer (Muntiacus spp.), sambar (Rusa unicolor), muntjac, chital (Axis axis), and wild boar (Sus scrofa), with selection favoring species in the 30–100 kg range for optimal energy return, though larger gaur (Bos gaurus) are taken by bigger packs.[53][51][54] Smaller mammals like rodents or hares constitute less than 10% of intake, while occasional scavenging or predation on other carnivores (e.g., viverrids) supplements during ungulate scarcity; livestock depredation occurs but remains secondary to wild prey in protected areas.[53][45] Scat analyses reveal frequent ingestion of vegetation (e.g., bamboo grass in 76% of samples), likely for digestion aid rather than nutrition, underscoring their hypercarnivorous niche amid competition with solitary felids like tigers.[6] Dietary composition shifts seasonally with prey availability, but dholes exhibit positive selectivity for abundant, fast-reproducing ungulates, minimizing overlap with apex predators' preferences for prime-age adults.[51][54]Reproduction and Life Cycle
Dhöles breed seasonally, with mating typically occurring from November to March, varying by latitude and local climate conditions such as the dry season in India.[1][49] In a pack, reproduction is generally monopolized by a dominant monogamous pair, with other members providing cooperative support rather than breeding competitively.[55][49] Gestation lasts 60 to 63 days, after which the female gives birth to a litter of typically 4 to 8 pups in a den excavated in earthen burrows, rock crevices, or streambed areas.[1][49] Litter sizes can reach up to 12 pups, facilitated by the female's up to 16 mammary glands, though smaller litters of 3 to 4 are common in some observations.[55] Pups are born altricial, blind, and covered in sooty brown fur, developing their adult rusty-red coat by three months of age.[1] Parental care is communal, with the nursing mother reliant on pack members who regurgitate predigested meat to her and the pups starting around three weeks, supplementing nursing that continues for at least 58 days until weaning.[1][49] Pups remain in or near the den for 70 to 80 days, beginning to explore outside at about 10 weeks; by six months, they accompany adults on hunts and receive priority access to kills, while gaining proficiency in prey dispatch by eight months.[49][55] Juveniles reach full physical size by one year but attain sexual maturity around three years, at which point females often disperse to join other packs.[55][49] Adults maintain pack associations post-independence, contributing to hunting and rearing subsequent litters in a cooperative system that enhances pup survival amid high predation risks.[1] In the wild, dhöles have an average lifespan of about 10 years, though individuals in captivity can live up to 16 years.[55][49]Interspecific Interactions
Dhols engage in exploitative competition with sympatric apex predators, particularly tigers (Panthera tigris) and leopards (Panthera pardus), due to substantial dietary overlap on medium- to large-sized ungulates such as sambar deer (Rusa unicolor; preferred by both dholes and tigers), chital (Axis axis), and wild boar (Sus scrofa). This competition is evident across multiple sites in Asia, where dholes' prey spectrum aligns closely with that of leopards and partially with tigers, contributing to resource partitioning challenges in multi-predator guilds. Larger dhole packs enable access to bigger prey items, potentially intensifying overlap during hunts for shared species weighing 130–190 kg.[51] Coexistence is facilitated by spatial and behavioral mechanisms, including dholes' avoidance of sambar-rich habitats frequented by tigers, which reduces direct interference despite low tiger densities (e.g., 0.36 individuals per 100 km² in some Thai forests). Temporal overlaps are moderate with leopards (overlap coefficient Δ = 0.70) and high (>80%) with tigers in diurnal activity patterns, showing limited partitioning; dholes remain crepuscular or diurnal, aligning closely with prey like muntjac (Δ = 0.90) and wild boar (Δ = 0.83) to maximize hunting efficiency over competitor avoidance. In regions like northern Laos, dholes exhibit low temporal overlap with smaller felids such as clouded leopards (Δ = 0.51), suggesting finer-scale partitioning among subordinate carnivores.[52][56][57] Dhols face intraguild predation risks, with tigers exerting dominance and leopards occasionally preying on them—evidenced by dhole hairs in leopard scats—making solitary individuals or smaller groups more vulnerable than packs. Pack cohesion allows dholes to mob larger felids, deterring attacks and enabling defensive responses against kleptoparasitism, though overall dhole densities remain suppressed by dominant competitors in high-predator landscapes. Opportunistic predation on smaller carnivores occurs rarely, accounting for approximately 6% of biomass in some diets, primarily through scavenging or targeting vulnerable individuals.[52]Health and Pathogens
Dholes (Cuon alpinus) exhibit vulnerability to multiple pathogens, particularly viral and parasitic agents circulating among sympatric canids, with domestic dogs serving as key reservoirs that facilitate spillover in human-modified landscapes. This susceptibility is exacerbated by the species' social structure, which enables rapid intra-pack transmission, and habitat fragmentation, which increases contact with feral dog populations. Empirical evidence from serological surveys and outbreak records indicates that infectious diseases contribute substantially to mortality, especially in small, isolated populations.[58][59] Canine distemper virus (CDV) represents a primary viral threat, causing acute respiratory, neurological, and gastrointestinal symptoms with high lethality in unvaccinated populations. Outbreaks have been documented in both wild and captive dholes; for instance, a 2011–2012 epizootic in Cambodia, attributed to transmission from domestic dogs, decimated local packs, though populations showed partial recovery by 2015. In zoos, CDV incursions have resulted in near-total pack mortality, underscoring the pathogen's potency absent immunity. Seroprevalence studies near protected areas reveal CDV exposure rates up to 40% in adjacent free-ranging dogs, signaling ongoing spillover risk. Rabies virus similarly affects dholes, with a notable outbreak in the 1940s linked to regional epizootics. Other viruses include canine adenovirus type 1 (CAV-1), responsible for infectious canine hepatitis; a reported outbreak in captive dholes demonstrated hemorrhagic liver pathology and rapid fatalities. Canine parvovirus has also been implicated in pack declines, though quantitative data remain limited.[60][61][62] Parasitic infections further compromise dhole health, often via ectoparasite vectors or prey-derived cycles. Sarcoptic mange, caused by Sarcoptes scabiei, induces severe dermatological lesions and debilitation, frequently spilling over from domestic dogs. Tick-borne protozoa such as Babesia gibsoni and Hepatozoon canis were molecularly confirmed in dholes for the first time in 2022, with infections potentially leading to hemolytic anemia and myositis. Endoparasites include nematodes like Toxocara canis, detected in feces and contributing to enteric pathology. Protozoan Sarcocystis spp. cysts, acquired from infected prey such as chital (Axis axis), are prevalent in dhole tissues but appear non-pathogenic, with dholes functioning as definitive hosts in a prey-predator-parasite dynamic; overdispersion within packs suggests uneven burden distribution. Trypanosomiasis has been noted anecdotally, though confirmatory data are sparse. Arthropod vectors transmit additional bacterial agents, amplifying overall disease burden in endemic tick habitats.[58][63][64]| Pathogen | Type | Key Effects | Documented Transmission/Source |
|---|---|---|---|
| Canine distemper virus (CDV) | Viral | Respiratory/neurological failure, high mortality | Domestic dogs; 2011–2012 Cambodia outbreak[60] |
| Rabies virus | Viral | Neurological paralysis, fatal | Regional epizootics; 1940s outbreak[65] |
| Canine adenovirus type 1 (CAV-1) | Viral | Hepatic hemorrhage | Captive outbreaks[66] |
| Babesia gibsoni / Hepatozoon canis | Protozoal | Anemia, tissue damage | Ticks; first detected 2022[63] |
| Sarcoptes scabiei | Ectoparasitic | Skin lesions, emaciation | Domestic/feral canids[58] |
| Sarcocystis spp. | Protozoal | Asymptomatic cysts | Prey consumption; non-pathogenic in dholes[64] |