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Caviidae
Caviidae
Caviidae
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"Cavy" redirects here. For the animal commonly referred to as "cavy", see guinea pig. For possible confusion, see Kavi.

Caviidae
Temporal range: Middle Miocene–Holocene
Capybara
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Rodentia
Parvorder: Caviomorpha
Family: Caviidae
Fischer von Waldheim, 1818
Subfamilies

 Caviinae
 Dolichotinae
 Hydrochoerinae

Caviidae, the cavy family, is composed of rodents native to South America and includes the domestic guinea pig, wild cavies, and the largest living rodent, the capybara. They are found across South America in open areas from moist savanna to thorn forests or scrub desert. This family of rodents has fewer members than most other rodent families, with 19 species in seven genera in three subfamilies.

Characteristics

[edit]
Guinea pig skull on top of a capybara skull

With the exception of the maras, which have a more rabbit-like appearance, caviids have short, heavy bodies and large heads. Most have no visible tails. They range in size from the smaller cavies at 22 cm in body length, and 300 grams in weight, up to the capybara, the largest of all rodents at 106 to 134 cm in length, and body weights of 35 to 66 kilograms. Even larger forms existed in the Pliocene, such as Phugatherium, which was about the size of a tapir.[1]

They are herbivores, eating tough grasses or softer leaves, depending on species. The dental formula is similar to that of various other rodents: 1.0.1.31.0.1.3. Females give birth to two or three furred and active young after a gestation period of 50 to 90 days in most species, or 150 days in the capybara. In most species, they are sexually mature within a few months of birth, although in capybaras, maturity is not reached until around 18 months.[2]

Social organisation varies widely among the group. Many cavies are promiscuous, forming no long-lasting social groups, although, in some species, males maintain harems of two or more females. In contrast, maras are monogamous, and form temporary colonial crèches to care for the young of multiple mothers. Capybaras live in groups of around 10 individuals, and sometimes many more, each with a single dominant male, and a number of females, subordinate males, and juveniles.[2]

Classification

[edit]
Further information: List of caviids

The family Caviidae is a sister group to the family Dasyproctidae, both of which are members of the superfamily Cavioidea.[3] Fossils caviids first appeared during the middle of the Miocene epoch in South America.[4]

Family Caviidae

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Caviidae

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from Grokipedia
Caviidae is a family of caviomorph endemic to , encompassing approximately 21 species across seven genera, notable for including the world's largest rodent, the (Hydrochoerus hydrochaeris), and the domesticated (Cavia porcellus). Members of this family are hystricognath characterized by a distinctive jaw structure, short or absent tails, and limbs adapted for terrestrial or semiaquatic lifestyles, with all species featuring four digits on the forefeet and three on the hindfeet. The family Caviidae is divided into three extant subfamilies: (true cavies, including genera Cavia, Galea, Microcavia, and Kerodon, with about 17 species), Dolichotinae (maras, genus Dolichotis with two species), and Hydrochoerinae (capybaras, genera Hydrochoerus and Hydrochoeropsis with three species). These are primarily herbivorous, feeding on grasses, aquatic plants, and other vegetation, and exhibit diverse habitats ranging from grasslands and forests to wetlands across most of the continent, from and southward to . Evolutionarily, Caviidae originated in the , with major radiations during the and Pleistocene leading to their current diversity, as evidenced by records showing adaptations to open environments and niches. Behaviorally, caviids are diurnal or crepuscular social animals, often living in groups for protection against predators, with communication via vocalizations, scent marking, and postural displays; is precocial, with litters born fully furred and mobile shortly after birth. Economically, the has been domesticated for over 5,000 years in the for food and as a , while capybaras are hunted for meat and leather, and some species face threats from habitat loss and hunting that affect their , though most are listed as Least Concern by the IUCN.

Physical characteristics

Morphology

Members of the Caviidae family possess a robust, cylindrical body form with a barrel-shaped torso, short limbs, and posture, enabling efficient terrestrial movement. The head is proportionally large, featuring a broad muzzle, short rounded ears, and small eyes positioned laterally. Tails are vestigial or entirely absent in most species, a characteristic trait distinguishing them from many other . This overall structure supports their herbivorous lifestyle, with compact builds ranging from compact and stocky in cavies to more elongated in maras. The of caviids is adapted for grinding fibrous vegetation, featuring (high-crowned) cheek teeth that grow continuously throughout life to compensate for wear. The dental formula is consistently 1/1 incisors, 0/0 canines, 1/1 premolars, 3/3 molars (total 20 teeth), with incisors that are relatively short and enamel covering only the anterior surface. These teeth exhibit a simple occlusal pattern of transverse laminae, facilitating effective mastication of material. Fur in Caviidae is typically dense and coarse, often wiry in texture, providing and protection against environmental abrasions; coloration varies from browns and grays dorsally to paler underparts. Notable exceptions include the maras ( spp.), which have thinner, sparser pelage more akin to hares. Body size shows significant variation across the family: smaller genera like Microcavia (mountain cavies) measure 18–25 cm in head-body length and weigh 0.2–0.5 kg, while the ( hydrochaeris) is the largest, attaining up to 1.3 m in length and 65 kg in mass. Limb morphology emphasizes terrestrial , with short, sturdy fore- and hindlimbs bearing four digits on the forefeet and three on the hindfeet, each tipped with short, sharp claws rather than hooves. The soles are naked and glandular, aiding in traction and scent marking during locomotion. These features support a in open habitats, though without extreme specialization for speed or .

Sensory adaptations

Members of the Caviidae family, such as guinea pigs (Cavia porcellus) and capybaras (Hydrochoerus hydrochaeris), exhibit specialized olfactory systems adapted for detecting scents in social and foraging contexts. The (VNO), a chemosensory structure in the , plays a critical role in processing pheromones and social s, enabling responses to conspecific cues for mating and territory marking. Guinea pigs, in particular, demonstrate high sensitivity to urinary nonvolatiles via the VNO, which facilitates individual recognition and reproductive behavior. Additionally, in guinea pigs, the nasal cavities are relatively large, with the posterior occupying about 10.6% of the total volume, supporting efficient odor filtration and detection in diverse environments. The in caviids is well-suited for open habitats, featuring large, mobile pinnae that enhance . In guinea pigs, the pinnae develop rapidly postnatally, contributing to directional transfer functions that allow discrimination of sound sources within hemifields and across the midline from birth. Sensitive structures enable detection of high-frequency sounds, with hearing thresholds similar to humans, making them responsive to predator cues and conspecific vocalizations. Capybaras show aquatic adaptations in hearing, with small ears positioned high on the head to remain alert while submerged, and the ability to press their ears flat against their heads during dives to protect against water ingress. Visual capabilities in Caviidae are limited, particularly in low-light conditions, reflecting their primarily diurnal lifestyle. Guinea pigs possess dichromatic color vision with cone photopigments sensitive to 429 nm and 529 nm wavelengths, and a neutral point at 480 nm, but their rods peak at 494 nm, providing modest scotopic sensitivity. Laterally placed eyes grant a wide field of view, up to approximately 340 degrees, aiding predator detection in open areas, though this creates a small blind spot directly in front of the nose. Reliance on olfaction and audition compensates for these visual constraints during crepuscular or nocturnal activity. Tactile senses are mediated by vibrissae () and specialized foot pads, supporting navigation in burrows or uneven terrain. In guinea pigs, mystacial vibrissae are arranged in rows with deep musculature from the M. nasolabialis profundus, enabling limited asymmetric movements for tactile exploration and eye protection, though unlike nocturnal , they do not exhibit rhythmic whisking. These vibrissae transmit mechanical stimuli to the brain via innervation, facilitating social interactions and obstacle avoidance. Foot pads provide additional proprioceptive feedback during locomotion on varied substrates.

Habitat and distribution

Geographic range

The family Caviidae is native to , with a broad distribution extending from and in the north to in southern and in the south. Members of this family occupy diverse open habitats across this range but are notably absent from most of western and large portions of the lowlands. The overall current extent spans approximately 15 million km² across 12 countries, including , , , , , , , , , , , and , though distribution varies by subfamily and species with gaps in densely forested Amazonian areas for certain taxa. Specific ranges differ among key genera. The (Hydrochoerus hydrochaeris), the largest caviid, is widespread in northern and central , occurring from through , , , , , , and northeastern , primarily east of the in savanna and wetland-adjacent areas. In contrast, maras ( spp.), such as the (D. patagonum), are restricted to arid and semi-arid steppes in southern and adjacent parts of , ranging from approximately 28°S to 50°S in . Wild guinea pigs ( spp.), including species like the (C. tschudii), are concentrated in the Andean regions, from and southward to northern and , often at high elevations in grassy habitats. Domestic guinea pigs (C. porcellus), derived from Andean wild ancestors, have been introduced to regions far beyond their native range, including , , , and parts of and , following their transport by Spanish explorers in the late . These introduced populations are now established as pets and in some feral groups worldwide, though they do not form wild populations comparable to native caviids. Historically, the modern distribution of Caviidae reflects post-Pleistocene expansions from origins tied to Andean diversification, where uplift and climatic shifts facilitated dispersal into lowland grasslands across southern after the .

Habitat preferences

Members of the Caviidae family predominantly inhabit open terrestrial environments such as grasslands, savannas, and shrublands, which provide ample foraging opportunities while allowing visibility for predator detection. For instance, species in the genus , like the wild guinea pig (Cavia aperea), favor linear habitats including field margins and roadsides adjacent to grassy areas dominated by gramineae plants. In contrast, the subfamily , represented by capybaras ( hydrochaeris), exhibits semi-aquatic preferences, utilizing marshes, swamps, and riverine wetlands for resting and , often selecting sites with proportional availability of these water bodies across seasons. Similarly, maras (Dolichotis patagonum) occupy arid grasslands and brushlands with sparse shrub cover in the Monte and Patagonian deserts, prioritizing open spaces for movement. The family demonstrates a broad altitudinal range, from to elevations exceeding 4,500 m in the , enabling adaptation to diverse topographic conditions. Montane species, such as the (Cavia tschudii), thrive in highland wetlands and grasslands between 2,000 and 3,800 m, where rocky substrates and coarse vegetation support their burrowing habits. Southern mountain cavies (Microcavia australis) extend into high-altitude populations above 2,000 m in regions like the Puna, favoring valleys with protective rock outcrops. Shelter requirements vary but commonly involve in loose or natural crevices for protection and . Many caviids, including Microcavia and species, excavate extensive burrow systems under cover to evade predators. Capybaras, however, rely on flooded areas and dense riparian shrublands for refuge, constructing resting beds in herbaceous during dry periods. plays a critical role in selection, with open areas preferred for and vigilance against threats, while adjacent dense cover—such as tall grasses or shrubs—facilitates rapid escape. Caviidae species tolerate a spectrum of climates from tropical to temperate zones, with specialized adaptations to environmental stressors. Capybaras endure seasonal flooding in tropical wetlands, using access for cooling and predator avoidance. In arid and semi-arid settings, rock cavies ( rupestris) in the biome exploit dry, rocky terrains with low scrubby vegetation near stony hillsides, demonstrating resilience to through crevice dwelling. Maras adapt to the harsh, low-productivity conditions of Patagonian steppes, where sparse vegetation and open exposure support their diurnal lifestyle despite temperature fluctuations.

Behavior and ecology

Social organization

Social organization in Caviidae varies widely across species, ranging from solitary individuals to large multimale-multifemale groups, influenced by habitat and resource distribution. In capybaras (Hydrochoerus hydrochaeris), groups typically consist of 6–16 individuals, including one dominant male, several females, and subordinates, though herds can expand to over 100 during dry seasons when converging at water sources. Wild guinea pigs (Cavia aperea) form smaller units of 1 male and 1–2 females, reflecting a more dispersed spatial arrangement in natural populations. In contrast, maras (Dolichotis patagonum) exhibit monogamous pair bonds as the core social unit, with pairs sometimes aggregating in communal warrens housing up to 29 pairs for shared burrow use. Hierarchies within groups are often linear and based on age, , and residency, with dominant individuals, particularly males, defending territories against intruders. capybaras establish a stable linear dominance order, where higher-ranking individuals access preferred resources and initiate interactions. In wild guinea pigs, females form similar linear hierarchies, while males maintain territorial boundaries through aggressive displays. Maras show less pronounced hierarchies beyond pair bonds, though dominant pairs may control prime burrow access within warrens. Communication in Caviidae relies on vocalizations, scent marking, and postural displays to maintain group cohesion and signal threats. Vocal repertoires include whines for contact, purrs for contentment, and high-pitched alarm calls to alert others of predators, as observed in wild cavies. Scent marking via anal glands and urine deposits territory boundaries and individual identity, particularly by males in guinea pigs and capybaras. Postural displays, such as upright stances or tail flicks, accompany aggressive encounters to assert dominance without physical contact. Cooperative behaviors enhance group survival, including and collective vigilance. In guinea pigs, non-parental females engage in allogrooming and pup guarding, supporting communal care within groups. Capybara groups demonstrate shared vigilance, where larger sizes reduce individual scanning time, allowing subordinates to contribute to anti-predator monitoring. Sex ratios in stable groups are often female-biased, promoting female kin bonds, while dispersal patterns help regulate . Juvenile males typically emigrate from natal groups around , joining peripheral males or forming new units, as seen in capybaras and pigs. In maras, pair stability limits dispersal, but unpaired individuals may roam to find mates or integrate into warrens.

Diet and feeding

Members of the Caviidae family are primarily herbivorous, with diets consisting mainly of grasses, herbs, and aquatic plants. These rely on in the caecum to break down from fibrous plant material, enabling efficient extraction of nutrients from low-quality forage. This digestive process involves microbial activity in the enlarged caecum and colon, where volatile fatty acids are produced to provide energy. Foraging strategies among caviids typically involve in groups, often during dawn and dusk to minimize predation risk, with individuals selectively on available during dry seasons when preferred grasses are scarce. Group may facilitate social learning of food sources, enhancing efficiency in patchy environments. Nutritional adaptations include coprophagy, where soft caecal pellets are re-ingested to recycle proteins and obtain essential synthesized by gut microbes, alongside a high tolerance for fiber that supports their hindgut-based . Dietary variations occur across species; for instance, capybaras (Hydrochoerus hydrochaeris) consume up to 3 kg of grasses and aquatic plants daily, reflecting their large body size and semi-aquatic lifestyle. In contrast, rock cavies ( spp.) incorporate more seeds, roots, and tender shoots into their diet, adapting to rocky, arid habitats with limited grass availability. Water intake differs markedly, with desert-dwelling species like the Patagonian mara ( patagonum) obtaining most hydration from moisture-rich plants and requiring minimal free water, while semi-aquatic forms such as capybaras depend on regular access to water bodies for drinking and foraging.

Reproduction and life cycle

Members of the Caviidae family exhibit diverse mating systems, ranging from in capybaras ( hydrochaeris), where dominant males form harems with multiple females to monopolize breeding, to in guinea pigs ( spp.), where females mate with multiple males during estrus. Breeding is often seasonal, particularly in species tied to rainfall patterns that influence resource availability, though some like domestic guinea pigs breed year-round. Gestation periods vary significantly across the family; for instance, guinea pigs have a short of 59–72 days, producing litters of 2–4 precocial young that are born fully furred, eyed, and capable of following the mother immediately. In contrast, capybaras have a prolonged of 150–155 days, resulting in litters of up to 8 pups, with an average of 5, also precocial but requiring initial group protection. Parental care is generally minimal due to the precocial nature of , but communal and occur in social species like capybaras, where non-mothers in the group assist in rearing pups to enhance survival. In guinea pigs, mothers provide limited for the first few weeks, with young quickly becoming independent foragers. Life stages feature rapid growth, with reached in 1–2 months for guinea pigs under social influences and up to 18 months for capybaras; wild lifespans average 4–8 years, though capybaras can reach 15 years in captivity. Mortality is high among juveniles due to predation by foxes, , and aquatic predators, compounded by in competitive multimale groups of species like guinea pigs.

Classification

Subfamilies

The family Caviidae is divided into three recognized subfamilies: , Dolichotinae, and , a classification supported by both morphological traits and molecular phylogenetic analyses. The subfamily includes the cavies in the genera Cavia, Galea, and Microcavia, encompassing 17 species characterized by short or absent tails, robust bodies, and highly social group-living habits adapted to diverse open habitats. Dolichotinae comprises the maras, with 2 species in the genus (including D. patagonum and D. salinicola; the latter formerly placed in the synonymized genus Pediolagus), featuring long legs, elongated limbs, and morphology for rapid movement across arid plains. Hydrochoerinae includes the semi-aquatic capybaras (, with partial webbing) and the terrestrial rock cavies (, adapted to climbing on rocky terrains), totaling 4 ; while sharing dentition and close genetic affinities, this group is occasionally considered close to Caviinae but recognized as distinct. The subfamily Dasyproctinae, including agoutis (Dasyprocta) and pacas (now often in Cuniculidae), with around 24 species noted for diurnal activity and seed-caching behaviors, was historically included within Caviidae but excluded in modern taxonomy based on molecular data affirming Caviidae's monophyly without it. Taxonomic revisions since the 2010s, driven by cytochrome b sequencing and multi-locus phylogenies, have reinforced the monophyly of Caviidae and its subfamilies within the superfamily Cavioidea, resolving prior uncertainties about basal relationships among caviomorph rodents; recent elevations in Cavia (e.g., C. anolaimae and C. guianae in 2013) reflect ongoing genetic clarifications as of 2025.

Genera and species

The family Caviidae comprises approximately 23 extant distributed across six genera, all native to with the exception of the domesticated , which has been introduced worldwide. Taxonomic revisions based on molecular data have resolved several historical synonymies, such as distinguishing Cavia patzelti as a separate from C. tschudii, though the exact count varies slightly (21–24) depending on whether certain are elevated to full status. No new have been described since the early , but ongoing genetic studies continue to clarify relationships within genera like . The genus Cavia includes nine recognized species of guinea pigs, characterized by their short tails and rounded bodies; these are primarily found in grasslands and forests from Colombia to southern Brazil, with C. porcellus being the only domesticated species originating from Andean wild stocks. Key species include C. aperea (wild guinea pig, widespread in eastern South America), C. fulgida (shiny guinea pig, endemic to central Brazil), C. intermedia (Santa Catarina's guinea pig, restricted to a small island off Brazil and listed as vulnerable due to habitat loss), C. magna (greater guinea pig, in coastal Brazil), C. porcellus (domestic guinea pig, globally distributed but wild ancestors in Peru), C. tschudii (montane guinea pig, in the Andes), and others like C. patzelti (Ecuadorian cavy, recently split via DNA evidence). Hydrochoerus, the capybaras, contains two species and represents the largest alive, weighing up to 65 kg; they are semi-aquatic and endemic to wetlands across northern and central . H. hydrochaeris (greater capybara) is abundant and listed as least concern, while H. isthmius () is smaller and confined to and northwestern , with stable populations. The genus Dolichotis encompasses two species of maras, hare-like cavies adapted to arid steppes , ; both are diurnal and monogamous, with D. patagonum () being near threatened due to and degradation, and D. salinicola (salt desert cavy) vulnerable from limited range. Microcavia features three species of mountain cavies, small burrowers endemic to the and adjacent highlands from to ; M. australis (southern mountain cavy) is common, while M. shiptoni and M. niata face localized threats from .
GenusNumber of SpeciesNotable Characteristics and Notes
Cavia9Guinea pigs; diverse habitats; C. porcellus domesticated and introduced globally; several endemics like C. intermedia (vulnerable).
Hydrochoerus2Capybaras; largest species H. hydrochaeris (up to 1.3 m long); semi-aquatic, least concern overall.
Dolichotis2Maras; Patagonian endemics; D. salinicola vulnerable due to arid loss.
Microcavia3Mountain cavies; Andean endemics; smallest wild cavy genus, with no major conservation concerns.
Galea5Yellow-toothed cavies; G. musteloides is the smallest cavy (150–250 g); widespread but some debated via .
Kerodon2Rock cavies; Brazilian caatinga endemics; K. rupestris near threatened from rock exploitation.
The genus Galea has five species of yellow-toothed cavies, named for their prominent incisors, inhabiting dry forests and grasslands from to ; G. musteloides (common yellow-toothed cavy) is the smallest member of the family at 150–300 g and widely distributed, while others like G. spixii are more localized with potential for future taxonomic splits based on DNA. Kerodon consists of two species of rock cavies, specialized for rocky terrains in northeastern ; both are endemic and exhibit agile climbing behaviors, with K. acrobata listed as vulnerable due to restricted range and K. rupestris near threatened from quarrying activities.

Evolution and fossil record

Phylogenetic history

The family Caviidae belongs to the superfamily Cavioidea within the suborder Hystricognathi, representing one of the major clades of South American caviomorph that diversified following the isolation of the continent after of . Molecular clock estimates indicate that the Hystricognathi split from other rodent lineages around 60 million years ago in the , with the subsequent divergence of from Old World hystricognaths occurring approximately 43 million years ago during the middle Eocene. Within , the origins of Caviidae trace back to the , with divergence from other caviomorph lineages estimated at 30-40 million years ago, coinciding with the of in isolated South American ecosystems. Key evolutionary adaptations in Caviidae, such as the development of hypsodont dentition suited for abrasive herbivory, emerged post-Gondwanan isolation, enabling these to exploit fibrous vegetation in the absence of competing mammalian herbivores. This shift toward specialized and is supported by morphological analyses of dental , linking it to the family's ecological across diverse habitats. Molecular phylogenetic studies, incorporating (mtDNA) sequences like and 12S/16S rRNA, alongside nuclear genes such as the and , robustly support the monophyly of Caviidae within Hystricognathi. These datasets reveal well-defined clades corresponding to the family's subfamilies, with high bootstrap support confirming internal branching patterns. Interspecific relationships position Caviidae as part of Cavioidea, with more recent mitogenomic data placing it sister to Dasyproctidae and Cuniculidae within Cavioidea. Within the family, the capybara lineage () appears basal, diverging early from the ancestors of and Dolichotinae around 10-15 million years ago. The major radiation of Caviidae occurred during the , approximately 20-10 million years ago, driven by the expansion of open grasslands and savannas in , which favored the diversification of herbivorous forms adapted to these environments. Bayesian relaxed clock methods calibrated with constraints estimate this period as pivotal for the emergence of extant genera, aligning with paleoenvironmental shifts toward more arid, vegetated landscapes.

Fossil species

The fossil record of Caviidae dates back to the middle , with the oldest known species being Prodolichotis pridiana from the Formation (La Victoria and Villavieja formations) in the Honda Group of , approximately 13.5–11.8 million years ago (Ma). This early representative indicates the initial diversification of the family within the Cavioidea superfamily during this period. Subsequent discoveries include Palaeocavia species from the late of , marking the emergence of the subfamily . The epoch represents a peak in Caviidae diversity, with at least 16 extinct genera documented across , reflecting adaptive radiations in various environments. Notable among these are giant hydrochoerine forms like Cardiatherium, which attained body lengths comparable to modern capybaras (up to about 1.3–1.5 m) and adapted to semi-aquatic lifestyles. Key fossil sites yielding these remains include the Formation in for early forms and Miocene localities in , for additional caviid taxa. During the Pliocene and Pleistocene, Caviidae transitioned toward modern morphologies, with small-bodied caviines like early Cavia species appearing alongside persistent large hydrochoerines. Many megafaunal representatives, including oversized capybaras, underwent extinction around 10,000 years ago as part of the broader late Pleistocene megafaunal turnover in South America, likely driven by climatic shifts and human arrival. Throughout their evolutionary history, Caviidae exhibited trends toward increased body size in some lineages and greater hypsodonty (high-crowned teeth) in others, adaptations correlated with Miocene aridification and the spread of open grasslands across the continent.

Human interactions

Domestication

The guinea pig (Cavia porcellus), the most prominent domesticated member of the Caviidae family, was first domesticated by indigenous Andean peoples around 5,000 to 7,000 years ago in regions spanning modern-day , , and . Archaeological evidence, including burned bones from sites like Huacaloma in , indicates early use for food through roasting and boiling, as well as in rituals and offerings, reflecting their cultural significance in pre-Inca societies. This domestication likely began with the capture of wild Cavia tschudii or related species from highland areas, marking one of the earliest instances of rodent husbandry in the . Artificial selection during domestication favored traits enhancing utility and manageability, including greater docility, reduced , and sociophilic behavior compared to wild cavies, as well as increased litter sizes averaging 3–4 pups compared to averages of around 2–3 in wild relatives. Genetic changes also produced varied colors and textures, diverging from the uniform grayish-brown of wild populations, with modern breeds like the smooth-coated American and rosetted Abyssinian exemplifying these adaptations. These modifications diminished wild survival traits, such as heightened fear responses and exploratory activity, while promoting traits suited to . Following their introduction to Europe by Spanish explorers in the 16th century, guinea pigs rapidly gained popularity as exotic pets across social classes, evidenced by skeletal remains from sites like and Mons in dating to the late 1500s. By the , selective breeding for ornamental purposes had proliferated diverse varieties. Simultaneously, their utility expanded to laboratory research; notably, in 1907, Norwegian scientists Axel Holst and Theodor Frølich used guinea pigs to induce , leading to the identification of deficiency due to their inability to synthesize the nutrient, akin to humans. This established them as a key model in nutritional, infectious disease, and reproductive studies. Efforts to domesticate other Caviidae species have been limited, with capybaras (Hydrochoerus hydrochaeris) undergoing semi-intensive farming in Venezuela since the mid-20th century primarily for meat production. These initiatives involve confined rearing systems adapted from pig husbandry, yielding regulated harvests of 7,000–8,000 animals annually (as of the mid-2000s), though full genetic domestication remains minimal due to ongoing reliance on wild stocks and behavioral challenges.

Conservation status

The majority of wild Caviidae species are classified as Least Concern by the , reflecting their widespread distributions and stable populations in suitable habitats across South America. For instance, the (Hydrochoerus hydrochaeris), the largest in the , is abundant and adaptable, with no immediate risk of . However, endemic and insular face higher threats; the (Cavia intermedia) is Critically Endangered due to its extremely restricted range on a single 10-hectare island off Brazil's coast, where stochastic events could lead to . Primary threats to wild Caviidae include habitat loss from and , which has reduced available wetlands and grasslands essential for many . Hunting for and hides remains a significant pressure, particularly for larger like capybaras, which are targeted in rural areas despite legal restrictions. Competition from , such as introduced rats on islands, exacerbates risks for endemics like C. intermedia. Conservation efforts focus on habitat protection and regulated use, with several species benefiting from inclusion in national parks and reserves. In Brazil, the Serra do Tabuleiro State Park safeguards the sole population of C. intermedia, while Argentina's Ischigualasto Provincial Park supports mara populations through anti-poaching patrols. Although not listed under CITES, capybaras are managed through sustainable harvesting programs in countries like Venezuela and Colombia, where annual quotas prevent overexploitation and promote population stability. Population estimates indicate capybaras number in the millions across their range, with densities up to 0.5 individuals per hectare in optimal wetlands, whereas smaller endemics like C. intermedia persist at approximately 42 individuals (as of 2005), with recent estimates suggesting 24-60. Emerging climate impacts pose additional challenges, with models projecting range contractions and shifts southward for Caviidae in warming regions of southern , potentially overlapping with intensified and reducing suitable habitats by mid-century.

References

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