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Insectivora

Insectivora is an obsolete taxonomic order that historically encompassed a polyphyletic group of small, insectivorous placental mammals, including hedgehogs, , moles, and solenodons, among others previously lumped together as a based on shared insect-eating habits rather than close evolutionary relationships. Advances in and morphological analyses have reclassified most of its members into the monophyletic order , which excludes unrelated groups like tenrecs and golden moles now placed in . represents one of the most species-rich mammalian orders, with over 500 living species (as of 2024) distributed across four families: (hedgehogs and gymnures, ~24 species), Solenodontidae (solenodons, 2 living species), Soricidae (, ~430 species), and (moles, ~45 species), plus the extinct Nesophontidae. Recent taxonomic revisions continue to increase the recognized species diversity. Members of are characterized by their small to medium size, typically ranging from a few grams to about 1.5 kg, with compact bodies, elongated pointed snouts, small or reduced eyes and ears, short tails, and sharp, interlocking teeth adapted for capturing and consuming such as , worms, and crustaceans, though some also prey on small vertebrates. They exhibit a simple digestive system lacking a caecum, reflecting a eutherian , and many species display specialized adaptations for their lifestyles, including forelimbs and velvety fur in burrowing moles, defensive spines in hedgehogs, and venomous delivered via grooved teeth in solenodons. These mammals are primarily nocturnal or crepuscular, with high metabolic rates necessitating frequent feeding—, for instance, may eat up to three times their body weight daily—and keen sensory systems relying on vibrissae (), olfaction, and echolocation in some moles. Eulipotyphlans inhabit a wide range of environments worldwide, from tropical forests and grasslands to temperate woodlands and high-altitude regions up to 3,660 m, but are absent from , , and most of except for introduced or relictual populations. Molecular estimates suggest the order originated in the around 80–86 million years ago, with major diversification following the Cretaceous-Paleogene and the fossil record beginning in the . Its play key ecological roles as predators of soil , contributing to and serving as prey for larger carnivores. Conservation concerns affect several , particularly island endemics like the critically endangered solenodons, threatened by habitat loss and invasive predators.

Overview and History

Definition and Scope

The taxonomic order Insectivora was established in 1821 by Thomas Edward Bowdich, building on Georges Cuvier's earlier recognition of a group of insect-eating mammals in the early . Bowdich grouped small placental mammals primarily adapted for consuming , such as , moles, and hedgehogs, based on shared dietary habits and primitive morphological features. This classification reflected the era's emphasis on functional anatomy, with later contributions from 19th-century scientists like , who highlighted the order's retention of ancestral eutherian traits in works such as his 1880 analysis of mammalian evolution. The original scope of Insectivora encompassed approximately 450 species across seven families, functioning as a that accommodated a diverse array of primitive-looking placentals not easily assigned to more specialized orders like or Rodentia. These mammals were typically small, with pointed snouts, sharp teeth suited for piercing exoskeletons, and or scansorial lifestyles, though the grouping overlooked deeper phylogenetic relationships. Phylogenetic analyses revealed Insectivora's , showing it was not a monophyletic but a paraphyletic grade of early-diverging placentals, where similarities arose from rather than shared ancestry. Seminal molecular studies in the late , including sequence data from multiple genes, confirmed this artificiality, partitioning the group into distinct lineages. The order became defunct in the 1990s as taxonomic revisions dismantled it, though the informal term "" persists to denote any reliant on for sustenance. Former Insectivora members were reassigned to modern orders like (encompassing , moles, and hedgehogs) and (including tenrecs and golden moles).

Historical Classification

The order Insectivora was established by Thomas Edward Bowdich in 1821 as a taxonomic grouping for small mammals adapted to an insectivorous diet, initially encompassing forms such as hedgehogs and based on shared dietary and morphological traits. This early classification drew from Georges Cuvier's broader recognition of insect-eating placentals but formalized them as a distinct order within his natural system of mammalian arrangement. In 1880, refined and expanded the concept of Insectivora to include a wider array of shrew-like and mole-like forms, emphasizing their retention of primitive eutherian features such as generalized and skeletal structure, which positioned them near the base of placental evolution. Huxley's arrangement, outlined in his application of evolutionary principles to vertebrate classification, excluded more specialized groups like tree shrews and elephant shrews while highlighting Insectivora's role as a foundational lineage from which other orders might have diverged. Twentieth-century developments further solidified Insectivora's status, with incorporating it in his 1945 comprehensive classification of mammals as an order within the cohort Unguiculata, alongside Chiroptera and other groups; this framework sparked ongoing debates about whether Insectivora exemplified the primitive placental condition, serving as a "scrapbasket" for basal eutherians. By the , morphological analyses by Leigh Van Valen, particularly his 1967 study of fossils, began questioning the of Insectivora through detailed comparisons of cranial and dental features that suggested multiple evolutionary origins for its included families. The emergence of cladistic methodologies in the and accelerated scrutiny of Insectivora's coherence, as parsimony-based phylogenies revealed inconsistencies in traditional groupings based on shared primitive traits rather than synapomorphies. By 1997, Malcolm C. McKenna's influential retained Insectivora at the level to accommodate its diverse lineages but explicitly acknowledged its paraphyletic nature, foreshadowing further revisions.

Taxonomy

Traditional Families

The traditional classification of Insectivora encompassed seven families of small, primarily insectivorous mammals, united by shared primitive morphological features such as a dentition specialized for crushing and shearing , including dilambdodont or zalambdodont cheek teeth that facilitate efficient prey processing. This grouping, established in early 20th-century , emphasized their ecological role as opportunistic predators of invertebrates, with most exhibiting an insect-based comprising over 70% of their intake, though some incorporate , small vertebrates, and matter. The total diversity under this traditional order was historically estimated at approximately 450 , with current recognized diversity exceeding 650 across these families, reflecting a broad radiation across terrestrial habitats worldwide, excluding and . Soricidae (shrews): Comprising approximately 488 , this family represents the most diverse group within traditional Insectivora, characterized by their tiny size (often under 10 cm in body length), high metabolic rates, and in some cases, venomous salivary secretions delivered through grooved teeth to subdue larger prey. are typically terrestrial or semi-aquatic, with elongated snouts for probing soil and dense fur for insulation in temperate and tropical environments. Talpidae (moles): With about 45 , moles are distinguished by their adaptations, including powerful forelimbs with broad, spade-like claws for excavating extensive burrow systems, reduced eyes covered by skin, and velvety fur that allows movement in any direction underground. These traits enable a subterranean lifestyle focused on hunting earthworms and in moist soils of the . Erinaceidae (hedgehogs and gymnures): This family includes approximately 24 species, notable for their defensive spines—modified hairs covering the dorsum in hedgehogs, though absent in the more primitive gymnures—and a compact body with short limbs suited to nocturnal foraging in leaf litter or undergrowth. The spines, numbering thousands per individual, provide protection against predators across Eurasian and African habitats. Solenodontidae (solenodons): Limited to 2 species endemic to the islands of and , solenodons are large (up to 1 kg) for insectivores, featuring long, flexible snouts for sniffing out prey, venomous bites via specialized lower incisors, and a shrew-like body with coarse fur and a scaly tail. Their nocturnal, burrowing habits reflect isolation on ancient landmasses. Tenrecidae (tenrecs): Encompassing around 31 species, primarily in , tenrecs exhibit remarkable morphological variation, from spiny, hedgehog-like forms to or types, with key traits including detachable barbed quills for defense in some genera and a cloaca-like in reproductive unique among placentals. They occupy diverse niches, from arboreal to semi-, underscoring in island ecosystems. Chrysochloridae (golden moles): This family consists of about 21 species confined to , characterized by iridescent, golden-hued , hypertrophied forelimbs with massive claws for burrowing, and sealed ear canals with no external pinnae, adaptations that support a fully subterranean existence in sandy or loamy soils. Macroscelididae (elephant shrews or sengis): Including 19 species across , this family is marked by an elongated, proboscis-like snout for detecting , enlarged hindlimbs enabling bipedal saltation, and large eyes for diurnal activity, though it was sometimes considered peripheral to core Insectivora due to its more habits. In modern taxonomy, these families have been reassigned to distinct orders like Eulipotyphla and Afrosoricida based on molecular evidence, as detailed in subsequent revisions.

Modern Revisions

The traditional order Insectivora was first demonstrated to be polyphyletic through molecular analyses in the 1990s, with early DNA sequence data from mitochondrial and nuclear genes revealing that several included families did not share a common ancestry exclusive to the group. A seminal study by Springer et al. (1997) analyzed sequences from three mitochondrial genes and two nuclear genes, showing that golden moles (Chrysochloridae) clustered with other endemic African mammals rather than with core insectivores like shrews and moles. This finding initiated the dismantling of Insectivora, as subsequent work by Stanhope et al. (1998) expanded the analysis to all six insectivore families using protein-coding genes, confirming the exclusion of tenrecs (Tenrecidae), golden moles, and elephant shrews (Macroscelidea) into a new clade, Afrotheria, later refined as Afroinsectiphilia within it. The removal of Macroscelidea marked a key step in these revisions, as molecular evidence placed elephant shrews firmly within Afroinsectiphilia alongside tenrecs and golden moles, supported by shared retroposon insertions and mitochondrial genome phylogenies that contradicted their prior morphological assignment to Insectivora. The remaining "core" insectivores—shrews (Soricidae), moles (Talpidae), hedgehogs (Erinaceidae), and solenodons (Solenodontidae)—were reclassified into the order , part of the superorder, based on robust support from concatenated nuclear and mitochondrial datasets. The order also includes the extinct Nesophontidae. Douady et al. (2002) provided pivotal evidence for this using 11 nuclear genes, demonstrating that Soricidae, , and form a well-supported to the exclusion of other placentals, with Solenodontidae as a basal . Phylogenetic analyses combining mtDNA and nuclear genes have consistently affirmed the monophyly of Soricidae + + within , with bootstrap support exceeding 90% in multi-locus studies. Approximate divergence dates for place its crown radiation at 70–80 million years ago, estimated via Bayesian relaxed clocks calibrated with 87 constraints across 131 nuclear genes from 116 placental species. Tenrecidae and Chrysochloridae were transferred to the order within , while Solenodontidae remained in due to shared syntenic associations and sequence divergences aligning them with Laurasian lineages. As of 2025, these revisions are widely accepted in major databases, with the successor groups (593 species) and (55 species) encompassing approximately 648 species collectively, reflecting ongoing taxonomic refinements from genomic data.

Successor Groups

Eulipotyphla

Eulipotyphla is a monophyletic order of placental mammals within the superorder Laurasiatheria, comprising small to medium-sized insectivorous species primarily adapted to terrestrial and fossorial lifestyles. This clade was established through molecular phylogenetic analyses that resolved the relationships among former "insectivore" groups, excluding Afrotherian lineages, and historically formed the core of the polyphyletic Insectivora order. The order encompasses four families: Soricidae (shrews), Talpidae (moles), Erinaceidae (hedgehogs and moonrats), and Solenodontidae (solenodons), with 593 recognized living species worldwide (as of March 2025), accounting for approximately 9% of placental mammal diversity. Eulipotyphlans exhibit notable diversity in form and ecology, divided into two suborders: Solenodonota, which includes the solenodons, and Erinaceota, encompassing the hedgehogs and moonrats, shrews, and moles. Shrews (Soricidae) are the most speciose family, with over 380 species characterized by elongated, flexible snouts used for probing soil and vegetation for invertebrates. Moles (Talpidae) are fossorial specialists, exemplified by the European mole (Talpa europaea), which constructs extensive underground tunnel systems for foraging and nesting. Hedgehogs (Erinaceidae) feature defensive spines and nocturnal habits, while solenodons (Solenodontidae), such as the Haitian solenodon (Solenodon paradoxus), represent rare, semi-fossorial Caribbean endemics with primitive traits like separated toes. Shared morphological and physiological features among eulipotyphlans include long, narrow, and often highly flexible snouts equipped with sensitive vibrissae for detecting prey, as well as generally reduced eyes adapted to low-light environments. Many species, particularly , possess exceptionally high metabolic rates—up to several times the expected basal rate for similar-sized mammals—to support their energy-intensive foraging, necessitating frequent meals equivalent to their body weight daily. A distinctive in certain shrews, such as the ( brevicauda), involves production in enlarged submandibular salivary glands, which facilitates prey immobilization through neurotoxic peptides delivered via grooved teeth. These traits underscore the order's evolutionary specialization for insectivory and microhabitat exploitation across Laurasian continents.

Afrosoricida

Afrosoricida represents one of the successor clades to the traditional order Insectivora, comprising small, primarily insectivorous mammals endemic to and its surrounding islands, distinct from the Eurasian-focused . This order includes two families: Tenrecidae, encompassing tenrecs and otter shrews with approximately 33 species across 10 genera, and Chrysochloridae, the golden moles with about 21 species in 9 genera, for a total of roughly 54 species. Molecular phylogenetic analyses in the late 1990s and early 2000s reclassified these groups within the superorder, highlighting their ancient African origins rather than close ties to lipotyphlan insectivores. A defining feature of is its position within , a superordinal clade that includes , sea cows, , aardvarks, and elephant shrews, united by molecular evidence such as shared retroposon insertions and protein sequence similarities despite superficial resemblances to other insectivores. Golden moles, in particular, demonstrate remarkable with true moles () and marsupial moles () in their adaptations, including hypertrophied forelimbs modified for powerful scratch-digging through soil. Unlike talpid moles, which rely on humeral rotation powered primarily by intrinsic forelimb muscles, golden moles employ a distinct involving enlarged extrinsic muscles like the deltoideus and pectoralis for lateral soil displacement. The Tenrecidae family exhibits substantial diversity, with subfamilies such as Tenrecinae (common tenrecs, primarily terrestrial and spiny forms endemic to ) and Potamogalinae (otter shrews, confined to mainland rivers). For instance, the lowland streaked tenrec (Hemicentetes semispinosus) features specialized barbed quills on its dorsal surface and head, which detach upon contact to deter predators, complemented by a stridulating organ for acoustic communication among family groups. In contrast, the giant otter shrew (Potamogale velox), the largest tenrecid at up to 1 kg, displays semi-aquatic adaptations including a streamlined , dense waterproof , and a powerful laterally compressed tail for propulsion, enabling agile swimming and diving in central waterways to hunt and crustaceans. Afrosoricida originated through divergence between Tenrecidae and Chrysochloridae around 63–67 million years ago, near the Cretaceous-Paleogene boundary, as estimated from analyses of mitochondrial and nuclear genes. Tenrecs show high in , where over 30 species across eight genera have radiated since a single colonization event approximately 29 million years ago, occupying diverse niches from to arboreal habitats amid the island's . This underscores Afrosoricida's role in illustrating how and vicariance shaped African mammal evolution, separate from Laurasian lineages.

Biology and Ecology

Physical Adaptations

Insectivora, as traditionally classified, exhibit specialized adapted for piercing and crushing the exoskeletons of and other small . Their teeth typically feature sharp cusps and dilambdodont upper molars, characterized by a W-shaped occlusal pattern that enhances shearing and grinding efficiency. This structure is evident in and moles, where the dilambdodont configuration facilitates the breakdown of chitinous prey. In contrast, tenrecs and golden moles display zalambdodont molars with a V-shaped pattern, which similarly optimizes crushing while minimizing wear from abrasive insect parts. Sensory adaptations in these groups reflect their often nocturnal or lifestyles, prioritizing non-visual cues for navigation and foraging. Fossorial species like moles have markedly reduced eyes, with optic nerves containing fewer fibers than expected for their , limiting visual reliance in dark subterranean environments. Enhanced olfaction is widespread, supported by disproportionately large olfactory bulbs relative to overall brain mass, which process odorants critical for detecting prey and conspecifics. Some , such as the (Sorex araneus), employ echolocation using high-frequency ultrasonic calls, with frequencies reaching up to 200 kHz, to probe surroundings and locate in cluttered habitats. Body forms across Insectivora are generally compact and suited to agile movement through dense vegetation or . Most weigh less than 100 g, enabling rapid maneuvers and energy-efficient burrowing or climbing. Elongated snouts and flexible necks predominate, providing in probing crevices for hidden prey while maintaining . Defensive traits vary, including the modified spines of hedgehogs that deter predators through mechanical irritation, and the venom-delivering salivary glands in solenodons, which inject hypotensive toxins via specialized grooves in their lower incisors to immobilize threats or prey. Shrews exemplify extreme physiological demands tied to these adaptations, possessing the highest field metabolic rates among mammals at approximately 14 ml O₂/g/hr, which sustains near-continuous but contributes to short lifespans of 1–2 years.

Diet and Behavior

Insectivores primarily consume such as , , and larvae, which form the bulk of their diet to meet high metabolic demands. , for instance, actively hunt small arthropods and worms on the or in leaf litter, often ambushing prey with rapid strikes enabled by their specialized . Moles focus on soil-dwelling like , slugs, and ant larvae, consuming up to 60-70% of their body weight daily to sustain constant activity. Hedgehogs exhibit some omnivory, incorporating eggs, small vertebrates like frogs, and occasionally fruits alongside and . In the group, tenrecs are largely insectivorous but opportunistic omnivores that include small vertebrates, bird eggs, and fruits in their diet, while golden moles target , , crickets, and , occasionally supplementing with small or snakes when invertebrate availability is low. Otter shrews specialize in aquatic and semi-aquatic prey, including , , and caught near edges. Foraging behaviors in insectivores are predominantly solitary and nocturnal, allowing them to exploit low-light conditions for detecting prey via heightened senses of smell, touch, and . Shrews typically glean from surfaces or under , patrolling territories with quick, erratic movements to capture elusive prey. s engage in extensive burrowing, constructing shallow feeding tunnels and deeper permanent burrows; a single can excavate up to 150 feet (approximately 46 meters) of new tunnels per day in search of food. Golden moles similarly burrow or "sand-swim" through loose substrates, covering distances up to 6 kilometers nightly while sensing s to locate . shrews employ semi-aquatic hunting strategies, diving briefly into calm pools to pursue prey by touch and along riverbanks and beds, with each dive lasting only seconds. These behaviors minimize and predation risk, though some like certain tenrecs forage arboreally or on the ground using echolocation-like clicks for . Social and reproductive behaviors among insectivores emphasize low , with most species maintaining solitary lifestyles outside of brief periods or overwintering groups for . Territoriality is common, often enforced through scent marking via specialized glands, as seen in tenrecs that self-anoint with saliva-mixed scents. Reproduction is explosive to counter high mortality rates; female typically produce 1-3 litters per year, each with 4-10 young, breeding primarily in their first year of life. Similar patterns occur in other groups, such as moles with 2-4 litters of 2-5 young annually, and tenrecs that may enter between breeding seasons to conserve energy. Pair-living or small multi-male/multi-female groups form temporarily during breeding in some species, but overall, social structures remain minimal, impacting interpretations of mammalian social evolution. Insectivores play key ecological roles as pest controllers by exerting significant predation pressure on invertebrate populations, thereby regulating ecosystem dynamics in forests and soils. Moles, through their burrowing, aerate soil, enhance water percolation, and incorporate organic matter, benefiting plant growth while targeting soil pests like grubs and larvae. Shrews and similar species reduce insect abundances, with occasional population booms leading to temporary but strong negative impacts on local arthropod communities, contributing to biological control in temperate habitats. This predation helps maintain balance in food webs, preventing outbreaks of agricultural or forest pests.

Evolution and Distribution

Fossil Record

The fossil record of Insectivora, a historically recognized but now paraphyletic grouping encompassing the modern orders and , traces back to the immediate aftermath of the Cretaceous-Paleogene (K-Pg) mass extinction approximately 66 million years ago (mya). Early eulipotyphlan fossils, representing the core of traditional northern insectivores, appear abruptly in the of the , dating to between 66 and 61.7 mya, with primitive forms exhibiting shrew-like dental adaptations for insectivory. In contrast, the afrosoricidan lineage, including tenrecs and golden moles, has a sparse early fossil record, with significant gaps in the early of and no unequivocal representatives until the Eocene or later. Molecular clock estimates place the divergence of eulipotyphlan lineages within the superorder around 77–85 mya and afrosoricidan lineages within around 66 mya (with the Afrotheria-Laurasiatheria split ~100 mya), predating the K-Pg boundary but aligning with a post-extinction radiation into vacant ecological niches. Proto-insectivorous eutherians, such as Zalambdalestes lechei from deposits in (approximately 80 ), provide evidence of pre-K-Pg origins, featuring elongated snouts and carnassial-like teeth suited for capturing small prey, though not directly ancestral to crown-group . Key fossils include Adapisoriculus species from the early of (e.g., Hainin, , ~64 ), which display primitive insectivore traits like multicusped molars and are debated as either stem eulipotyphlans or unrelated archaic mammals. By the Eocene, more derived forms emerged, such as early soricids and erinaceids, reflecting diversification amid and forest expansion. Oligocene records highlight extinct lineages like the Geolabidinae, a subfamily of mole-like eulipotyphlans from North American deposits (extending into the , ~33–23 ), characterized by adaptations including robust humeri for digging, though convergent with modern talpids. The Nesophontidae, endemic to the , represent a late radiation of shrew-like eulipotyphlans with fossils from the onward; these insular forms persisted until their extinction shortly after colonization around 1500 , likely due to introduced predators and alteration. fossils, such as early soricines, further document ongoing evolution, with forms like primitive ancestors supporting molecular estimates of a crown age around 75 . This post-K-Pg radiation involved rapid speciation, with eulipotyphlans exploiting insect-rich understories, leading to convergent fossoriality in multiple independent lineages (e.g., talpids and geolabidines). Over 100 extinct genera are documented across these groups, underscoring a once-diverse assemblage diminished by later extinctions and ecological shifts.

Geographic Range

The successor groups to the traditional Insectivora, namely and , exhibit distinct global distributions shaped by historical biogeographic events. species are nearly cosmopolitan, occurring across , , North and South America, and parts of , but are absent from , , and extreme polar regions. Their ranges expanded significantly during the Pleistocene through migrations facilitated by climatic fluctuations and formations, allowing colonization of new habitats in the Holarctic and Neotropics. In contrast, is strictly endemic to and , with golden moles confined to southern and and tenrecs primarily in alongside scattered populations in western . These groups occupy diverse habitats, including , grasslands, and wetlands, with adaptations supporting (underground burrowing in moles and golden moles), arboreal (climbing in some and gymnures), and semi-aquatic (otter ) lifestyles. They span altitudinal ranges from to over 4,000 m, as seen in high-elevation like Sorex sinalis in the and , which inhabit montane up to 4,500 m. Highest species diversity occurs in tropical regions, particularly , where over 100 species (primarily Crocidura) thrive in varied and montane ecosystems. Conservation challenges affect approximately 20% of species across these groups, based on IUCN assessments, with primary threats including habitat loss from and , pesticide use reducing prey, and . For instance, the Cuban solenodon (Solenodon cubanus) is classified as Endangered due to habitat degradation and predation by introduced black rats (Rattus rattus), which compete for resources and prey on juveniles on islands. , such as De Winton's golden mole (Chrysospalax trevelyani), are often Vulnerable, facing severe impacts from mining activities that destroy subterranean habitats in .