Hubbry Logo
EmballonuridaeEmballonuridaeMain
Open search
Emballonuridae
Community hub
Emballonuridae
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Emballonuridae
Emballonuridae
Emballonuridae
View on Wikipedia
from Wikipedia

Emballonuridae
Proboscis bats
Scientific classification Edit this classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Chiroptera
Superfamily: Emballonuroidea
Family: Emballonuridae
Gervais in de Castelnau, 1855
Type genus
Emballonura
Temminck, 1838
Genera

See Text

Emballonuridae is a family of microbats, many of which are referred to as sac-winged or sheath-tailed bats. They are widely distributed in tropical and subtropical regions around the world. The earliest fossil records are from the Eocene.[1][2]

Description

[edit]

The emballonurids include some of the smallest of all bats, and range from 3.5 to 10 cm in body length. They are generally brown or grey, although the species of genus Diclidurus are white. The faces are said to be handsome, the heads being comparable to those of domestic dogs, and their wings are long and narrow. As with other microchiropteran families, they use ultrasonic echolocation to sense the surrounding environment and their prey; the signals of some species are unusual in being audible to humans.[3]

Possession of the postorbital processes, the reduced, noncontacting premaxillaries, and rather simple shoulder and elbow joints, which is similar to pteropodids, makes them rather a primitive group. However, they are more advanced in the reduction of the second digit phalanges and the flexion of the third digit proximal phalanges over the metacarpal dorsal side.[2]

The wing surface extends between the legs, a membrane known as a uropatagium, and the structure of these is a characteristic in many of the genera. They have tails which are partially enclosed, a short part of which projects through the uropatagium to form a sheath. The usual arrangement of the uropatagium is as to be fixed to the tail, but the sheathtail feature is joined by an elastic component which allows greater flexibility; they are able to use the hind legs for locomotion and to adjust the membrane's surface while in flight.[4] As a common name indicates, many species also possess sac-shaped glands in their wings (propatagium), which are open to the air and may release pheromones to attract mates. Other species have throat glands which produce strong-smelling secretions.[5] They have the dental formula

Dentition
1-2.1.2.3
2-3.1.2.3

These bats generally prefer to roost in better-illuminated areas than other species of bats. Their dwellings can often be found in hollow trees and entryways to caves or other structures. Some species, such as the genus Taphozous, live in large colonies, but others are solitary. Species living away from the tropics may enter periods of torpor or extended hibernation during colder months.[5]

Emballonurids feed mainly on insects and occasionally on fruit. Most of these bats catch their meals while flying.

The common name for some groups, 'sheath-tailed bats', is sometimes noted as sheathtails.[3]

Distribution

[edit]

Found in the Neotropics, Afrotropics, southern Asia, Australia and South Pacific islands.[2]

Classification

[edit]
Further information: List of emballonurids

Family Emballonuridae

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Emballonuridae

View on Grokipedia
from Grokipedia
Emballonuridae is a family of bats in the order Chiroptera, consisting of approximately 52 species divided between the (30 species in 5 genera) and the (22 species in 8 genera), all of which are small to medium-sized and strictly insectivorous. Commonly known as sac-winged bats or sheath-tailed bats, they are distinguished by morphological adaptations such as a tail that protrudes from a sheath formed by the interfemoral and, in many species, glandular sacs along the margins used for producing scents during and territorial marking. These bats inhabit tropical and subtropical regions across , , southern , , the Pacific Islands, and the from southern to central , where they contribute to ecosystem services like insect . Members of Emballonuridae exhibit a range of sizes, with forearm lengths typically between 30 and 60 mm and body masses from 4 to 30 grams, featuring large ears, small eyes, and fur colors ranging from gray to brown. The family is divided into two subfamilies: Emballonurinae (sac-winged bats found in both the Old and New Worlds) and Taphozoinae (sheath-tailed bats restricted to the Old World), though phylogenetic studies indicate complex evolutionary relationships, including paraphyly in certain genera like Emballonura. Dentally, the formula is typically 1/3, 1/1, 2/2, 3/3 = 32 teeth in New World species, with some Old World genera exhibiting 2/3, 1/1, 2/2, 3/3 = 34 teeth, along with an elongated calcar and generally lacking prominent nose leaves (though some species have elongated snouts), adaptations suited to their aerial insectivory. Ecologically, emballonurids roost in colonies on vertical surfaces such as trunks, walls, cliffs, or human structures, often in well-lit sites near water bodies like rivers or mangroves to facilitate . Their diet primarily comprises flying such as flies, beetles, moths, and mosquitoes, captured in flight using echolocation, with some showing preferences for riparian habitats at elevations from to about 900 meters. Behaviorally, they are nocturnal and gregarious, employing pheromones from wing sacs for social communication, particularly in males during breeding seasons that vary by region but generally align with wet periods to support survival. While most remain data-deficient, several face threats from habitat loss and are listed as vulnerable or endangered by the IUCN, highlighting their sensitivity to in tropical ecosystems.

Description

Morphology

Emballonuridae bats exhibit long, narrow wings characterized by a high and pointed wingtips, adaptations that facilitate fast and agile flight suited to open-air and efficient capture. The second digit of the wing lacks phalanges, while the third has two, contributing to the streamlined structure that minimizes drag during sustained flight. A distinctive feature is the uropatagium, a that fully encloses the , creating the "sheath-tailed" appearance characteristic of the family; the tip projects freely through a longitudinal slit at the posterior edge of this sheath, allowing flexibility without compromising membrane integrity. Many , known as sac-winged bats, possess sac-like glandular structures located in the propatagium between the wing membranes near the forward edge, which store and release pheromones essential for chemical communication. These sacs enable males to produce volatile scents during displays, such as hovering flights where fluids are sprayed toward females, aiding in mate attraction and social signaling; the odors, comprising terpenoids, aromatic compounds, and fatty acids, vary by individual and colony to convey genetic or status information. In genera like Saccopteryx, additional throat glands, or gular sacs, are present exclusively in males and serve for release during territorial and behaviors. Histologically, these glands consist of sebaceous cells and sudoriferous cells embedded in collagen-rich , with pigmented cuboidal epithelial-lined ducts extending caudally up to 7 mm for secretion dispersal. The secretions likely include complex chemical profiles similar to wing sac pheromones, supporting olfactory mate assessment, though exact compositions remain under study. The dental formula of Emballonuridae typically varies as 1–2/2–3.1.2.3, totaling 30–34 teeth, with W-shaped cusps on molars adapted for crushing exoskeletons. Primitive traits include reduced, unfused premaxillae and the presence of postorbital processes, reflecting early chiropteran morphology. Echolocation in Emballonuridae relies on laryngeal production of ultrasonic pulses, generated by specialized vocal folds and arytenoid cartilages in the , enabling precise navigation and prey detection. Echolocation call frequencies range from 20 to 100 kHz, often incorporating constant-frequency components around 40–50 kHz for Doppler shift compensation during flight. Some also produce audible elements in their social calls for communication. Roosting adaptations include a preference for exposed, illuminated sites such as entrances or building exteriors, linked to crepuscular or diurnal activity in certain species, which reduces predation risk while allowing visual orientation. Foot morphology features strong claws and pads on the toes, facilitating secure clinging to vertical surfaces in head-down postures with limbs splayed.

Size and Coloration

Emballonuridae species exhibit a wide range of body sizes, with head-body lengths typically spanning 3.5 to 10 cm and lengths from approximately 35 to 95 mm. Smaller genera, such as Emballonura, measure 3 to 4 cm in head-body length and have s around 37 to 47 mm, while larger forms like Taphozous reach up to 10 cm in head-body length with s up to 95 mm. Weights vary from 3.5 to 60 g across the family, reflecting this size diversity, with Emballonura species averaging 3.6 to 5.3 g and heavier Taphozous or Saccolaimus forms reaching 28 to 60 g. in size occurs in several genera, often with females larger than males; for instance, in Saccopteryx bilineata, females exceed males by about 15% in body mass and length. Fur coloration in Emballonuridae is predominantly brown to gray, with many species showing a dorsal-ventral where the back is darker and the underparts paler. Notable exceptions include the whitish pelage of Diclidurus ghost bats and the yellowish ventral fur in Saccolaimus flaviventris. Wing membranes are generally thin and translucent, aiding in visual during roosting. Sexual dichromatism is rare in the family, though some species display differences in pigmentation during breeding seasons, where males develop more pronounced dark or reddish hues around glandular areas for signaling. Juveniles typically exhibit paler fur than adults, with grayer tones and sparser pelage that darkens and lengthens over the first few months as fur develops fully.

Taxonomy

Etymology and History

The name Emballonura, the of the family Emballonuridae, derives from the Greek emballōn (present participle of emballein, meaning "to ") combined with Latinized oura ("tail"), alluding to the tail membrane that encloses or "throws in" the tail tip. The family name Emballonuridae was formally established by French naturalist Louis Paul Gervais in 1855, as part of a broader in de Castelnau's Expédition dans les parties de l'Amérique du Sud. The genus Emballonura was first described by Dutch zoologist Coenraad Jacob Temminck in 1838, based on specimens from , marking an early recognition of sheath-tailed bat diversity in tropical regions. Earlier, in 1818, introduced the genus Taphozous (from Greek taphos, meaning "tomb" or "grave," referring to their roosting habits), which became a cornerstone of emballonurid through 19th-century explorations of tropical colonies that yielded numerous new species descriptions. Initially, emballonurids were often conflated with the family due to superficial similarities in wing structure and dentition, leading to taxonomic instability until Gervais elevated them to family status; this confusion persisted into the late , as noted in George Edward Dobsons's 1875 catalog, which misplaced several genera. American mammalogist Gerrit Smith Miller Jr. clarified much of this history in , synonymizing erroneous genera like Taphonycteris with Taphozous and solidifying the family's distinct morphological traits, such as the unique tail sheath. The 20th century brought revisions incorporating bioacoustic data, particularly echolocation call analyses from the onward, which highlighted emballonurids' diverse strategies and supported divisions like Emballonurinae and Taphozousinae. British mammalogist John Edwards Hill contributed significantly through detailed morphological studies, including notes on Southeast Asian emballonurids in the and that refined genus boundaries. The fossil record of Emballonuridae traces back to the early Eocene, with Eppsinycteris anglica from the Blackheath Beds of , (approximately 55 million years ago), representing a primitive form that shares derived dental and skeletal features with extant members, suggesting early divergence of modern families. Diversification accelerated in the , as evidenced by new genera like Oligopteryx from deposits, indicating to tropical ecosystems. Post-2000 molecular phylogenies, using mitochondrial and nuclear DNA sequences, have further refined relationships; for instance, analyses of the tribe Emballonurini confirmed Emballonura's and trans-oceanic dispersal patterns across the .

Classification

Emballonuridae is placed within the suborder and superfamily Emballonuroidea, forming a basal lineage among yangochiropteran families and exhibiting sister relationships to groups such as Molossidae within the broader radiation. The family comprises two primary subfamilies: Emballonurinae, which includes and sac-winged bats characterized by glandular scent sacs in the wing membranes used for production, and Taphozoinae, consisting of sheath-tailed bats lacking these wing sacs but featuring a distinctive sheath enclosing the tail tip for roosting support. Emballonuridae encompasses 14 genera and approximately 54 , with Emballonurinae containing 12 genera and around 36 , while Taphozoinae includes 2 genera and about 18 . Key genera in Emballonurinae include Emballonura (8 , primarily ), Paremballonura (2 , Southeast Asian), Saccopteryx (5 , Neotropical), Diclidurus (4 , South American), Peropteryx (4 , Neotropical), Balantiopteryx (2 , Central American), Centronycteris (2 , South American), Cyttarops (1 , Neotropical), Cormura (1 , South American), Mosia (1 , African), Rhynchonycteris (1 , Neotropical), and Coleura (2 , [Old World](/page/Old World)); in Taphozoinae, notable genera are Taphozous (ca. 16 , [Old World](/page/Old World)) and Saccolaimus (2 , Asia-Australia). Species diversity stands at 51-55, with recent discoveries in the contributing to this tally, such as the description of Emballonura tiavato from Madagascar's dry forests in 2007, highlighting ongoing taxonomic refinements in the family. Molecular phylogenetic studies from the , utilizing and nuclear loci, reveal a deep divergence between and Neotropical lineages, with Emballonurinae showing a distinct Neotropical radiation separate from the Old World Emballonurini tribe, supporting monophyly of the subfamilies and key branches such as the basal position of Diclidurus within New World taxa. The type species for the , via the Emballonura, is Emballonura monticola.

Distribution and Habitat

Geographic Range

Emballonuridae, commonly known as sac-winged or sheath-tailed bats, exhibit a distribution primarily confined to tropical and subtropical regions of the Old and New Worlds, with no presence in temperate zones, , or north of . This , comprising approximately 52-55 species across 13 genera as of 2024, is absent from polar and high-latitude areas, reflecting their adaptation to warm climates. Their ranges are disjunct, separated by vast oceanic and continental barriers, with core populations in , southern , , , and . In the Neotropics, emballonurids range from southern through to northern , encompassing countries such as , , , , , and Trinidad. Genera like Saccopteryx and Peropteryx are endemic to this region, with S. bilineata distributed from Jalisco and in southward to , the , and eastern , while P. macrotis extends from southern throughout into much of , including northeastern and northern . These bats occupy lowland forests and coastal areas up to about 1,000-1,500 meters elevation, though some populations have experienced recent range contractions due to and in regions like the . The Afrotropical range spans from and eastward to and , southward to , the , , and northeastern , including islands like and the . Dominant genera include Coleura and Taphozous, with C. afra widespread across this area from and to and , and T. mauritianus occurring from to eastern . Endemism is notable on islands, such as C. seychellensis restricted to the , though habitat loss has led to contractions, particularly in fragmented savannas and forests of eastern . In the Indomalayan and Australasian realms, emballonurids extend from and through southern , , and to and Pacific islands, including , , , , and the Northern Marianas. Genera like Taphozous and Emballonura prevail here, with T. melanopogon ranging from to the and E. semicaudata found across , , and . Island endemics, such as the Mariana sheath-tailed bat (E. semicaudata rotensis), highlight biogeographic patterns, but many populations have contracted sharply due to on islands like and Saipan. Most species are sedentary, though some Taphozous and Saccolaimus species, like S. flaviventris in , undertake short seasonal movements between northern and southern regions during winter.

Habitat Preferences

Emballonuridae, commonly known as sac-winged or sheath-tailed bats, primarily inhabit tropical and subtropical environments, including humid rainforests, seasonal forests, mangroves, and savannas. Some , such as those in the Taphozous, demonstrate adaptability to modified landscapes, including urban areas where they in human-made structures like and bridges. These bats generally favor warm, humid climates with temperatures ranging from 20–30°C, reflecting their distribution across equatorial and near-equatorial regions. In cooler or drier seasons, individuals may enter short periods of to conserve energy, though full is rare due to their tropical affinities. Roosting preferences in Emballonuridae are distinctive, often involving exposed and illuminated sites such as hollow trees, caves, rock crevices, and human structures like attics and bridges, unlike the darker roosts favored by many other families. This preference for open, well-lit areas facilitates and reduces predation risk in their environments. Microhabitat requirements include vertical surfaces for clinging, with some like those in the genus Diclidurus utilizing foliage or exposed branches under palm fronds for diurnal roosting, allowing activity during daylight hours. Foraging areas are typically near roosts in continuous forest patches, emphasizing the need for proximity to insect-rich open spaces. Habitat fragmentation poses significant challenges for Emballonuridae, as many species prefer continuous habitats for roosting and connectivity; populations, such as the Pacific sheath-tailed bat (Emballonura semicaudata), are particularly vulnerable to isolation and degradation from like feral goats. Their altitudinal distribution spans from to approximately 1800 m, as observed in montane forests of where species like Emballonura monticola occur up to 1800 m, and in the where species such as Balantiopteryx plicata reach up to 1500 m. In Himalayan foothills, genera like Taphozous are recorded up to around 1500 m. This elevational range underscores their adaptability to varied topographic conditions within tropical zones, though higher altitudes may limit distribution due to cooler temperatures.

Ecology and Behavior

Diet and Foraging

Emballonuridae bats are predominantly insectivorous, specializing in the aerial capture of flying insects such as , beetles (Coleoptera), flies (Diptera), and occasionally spiders (Araneidae). Their diet reflects an opportunistic yet selective approach, with forest-dwelling individuals consuming a broader range of 1–9 insect orders, while those in semi-urban areas focus on 3–8 orders, emphasizing Lepidoptera and Coleoptera. This feeding strategy positions them as key aerial insectivores in tropical and subtropical ecosystems, where they contribute to controlling pest populations through high nightly consumption rates. Foraging occurs primarily through aerial hawking, involving high-speed, straight-line flights over open areas like water surfaces, forest edges, or canopy gaps, which suit their long, narrow wings optimized for efficient cruising rather than maneuverability. They rely on echolocation for prey detection, emitting multiharmonic constant-frequency search pulses, with frequencies varying by genus; for example, in Taphozous species primarily in the second harmonic at 11–13 kHz, while species use higher frequencies around 40–50 kHz. These transition to frequency-modulated sweeps during approach and terminal buzz phases for precise targeting. For example, in Taphozous mauritianus, detection ranges extend to about 3 m, though this varies across species from 1.5 to 25 m depending on foraging habitat, allowing interception of evasive mid-flight. Some genera, such as Taphozous, occasionally supplement their insect diet with small fruits, though this remains secondary to insectivory. Seasonal fluctuations in insect abundance influence foraging intensity, with heightened activity and intake during wet seasons when prey is plentiful, and reduced foraging or energy conservation via torpor during dry periods of scarcity. Taphozous species, for instance, employ daily torpor to lower metabolic rates, mitigating the challenges of fluctuating food supplies in tropical environments. Digestively, emballonurids exhibit a high metabolic rate suited to rapid processing of chitinous insects, supported by dilambdodont cheek teeth featuring a W-shaped cusp pattern that efficiently crushes exoskeletons. As apex insect predators, they play a vital trophic role in maintaining balance in tropical food webs but are vulnerable to bioaccumulation of persistent pesticides like organochlorines, which concentrate in their tissues through contaminated prey.

Reproduction

Emballonuridae exhibit predominantly polygynous systems, where males defend harems of one to eight females through defense or territorial behaviors. In genera such as Saccopteryx, males utilize wing sacs containing pheromones produced from glandular secretions mixed with and to perform displays, including hovering and wing-fluttering to fan scents toward receptive females. Similarly, in Taphozous species like T. melanopogon, males maintain polygynous harems by guarding territories, often with multiple females during the breeding season. Breeding in Emballonuridae is typically seasonal in subtropical regions but can occur year-round in tropical environments, with peaks often aligned to rainy seasons when abundance supports and pup rearing. Many are monestrous, producing one litter per year, though polyoestry has been observed in some palaeotropical forms. Gestation periods in Emballonuridae range from 3 to 5.5 months, varying by species and latitude; for example, Taphozous georgianus has a gestation of about 4 months, while Saccopteryx bilineata averages 169 days. Litter sizes are usually one offspring, with twins being rare exceptions in species like Taphozous mauritianus. The placenta in Emballonuridae features a distinctive , a blood-filled aiding exchange, alongside vascular tubules that facilitate maternal-fetal blood flow in an endotheliochorial configuration. Parturition results in altricial young that are blind, hairless, and dependent on maternal care, with birth weights around 2–3.5 g in species like Saccopteryx bilineata. lasts 6–8 weeks, during which pups are nursed and gradually weaned as they develop fur and flight capabilities. is reached at 6–12 months, with males maturing slightly earlier than females in Saccopteryx bilineata. Parental care is primarily maternal, with females carrying pups attached to their teats during initial foraging flights until the young can fly independently at around 2 months. In polygynous Taphozous species, males provide indirect care by guarding harems and territories, protecting females and offspring from intruders. Emballonuridae have lifespans of 5–9 years in the wild, with records up to 8.8 years for Taphozous hilli and 7.1 years for Saccopteryx bilineata. Fecundity is low due to single annual births and monestrous cycles, resulting in limited lifetime reproductive output of typically 5–10 offspring per female.

Social Structure

Emballonuridae bats display a wide range of , from solitary individuals to complex colonial structures with defined hierarchies. Colony sizes vary significantly across genera; for instance, species in the genus Taphozous often form small groups of fewer than 20 individuals, with roughly equal numbers of males and females, though some populations of Taphozous melanopogon aggregate in large numbers up to 15,000 in roosts like temples. In contrast, Emballonura species, such as Emballonura semicaudata, typically occur in smaller groups, with documented colonies ranging from a few dozen to several hundred individuals in Pacific island habitats. This variability reflects adaptations to resource availability and roost types, with larger groups more common in stable or hollow environments. Social systems within Emballonuridae include harem-based in several Neotropical genera, such as Saccopteryx bilineata, where dominant males defend territories containing multiple females, while non-territorial males queue for access or remain peripheral. Fission-fusion dynamics are observed in some species, like Rhynchonycteris naso and Saccopteryx bilineata, where group composition changes daily as individuals split and rejoin based on needs and social affiliations, facilitating flexible associations without rigid territories. In genera like Diclidurus, is minimal, with individuals solitary outside the breeding period (January to June), forming temporary small groups of 4-7 (one male and several females) only early in the breeding season (January–February), which influences limited year-round interactions. These systems promote mate guarding and resource access, with patrilineal kin groups in Saccopteryx enhancing male competition. Communication in Emballonuridae extends beyond echolocation to multimodal signals that maintain social bonds and hierarchies. Acoustic signals include low-frequency social calls (below 50 kHz, often in the 20-45 kHz range for territorial and purposes) used by males in Saccopteryx to advertise dominance and attract females. Visual displays, such as wing-spreading and aerial maneuvers, complement these in harem defense, while olfactory cues via pheromones produced in wing sacs allow scent-marking of territories and individual recognition, with males in Saccopteryx mixing glandular secretions to signal genetic quality. Roost hierarchies often follow linear dominance patterns in mixed-sex groups, particularly in Saccopteryx, where aggressive interactions peak during breeding, establishing male status and female positioning for . Interspecific interactions among Emballonuridae are generally tolerant, with many sharing roosts in caves or foliage without significant , as seen in Peruvian lowland communities where up to 34 species, including multiple Emballonuridae, co-occupy sites. This tolerance may reduce predation risk through collective vigilance, though occasional instances of larger Emballonuridae preying on smaller heterospecifics occur in mixed roosts. Diurnal activity patterns in some genera, such as Diclidurus albus, which exhibits extended crepuscular foraging due to pale coloration aiding early emergence, shape social dynamics by limiting group formations to brief mating periods rather than persistent colonies.

Conservation

Status and Threats

The conservation status of Emballonuridae species varies widely, with the majority classified as Least Concern on the IUCN Red List due to their broad distributions in tropical regions. However, approximately 10-15% are considered threatened, including Vulnerable, Endangered, and Critically Endangered categories, primarily driven by localized pressures on island populations. For instance, the Pacific sheath-tailed bat (Emballonura semicaudata) is listed as Endangered globally, reflecting severe declines across its Pacific range. The Seychelles sheath-tailed bat (Coleura seychellensis), an island endemic, is Critically Endangered, with fewer than 100 individuals remaining due to extreme habitat fragmentation. Similarly, the subspecies Emballonura semicaudata rotensis in the Mariana Islands faces critically high extinction risk and is federally listed as Endangered in the United States. Primary threats to Emballonuridae include from and , which fragments foraging areas and reduces prey availability in tropical forests. Roost disturbance from human activities such as , , and infrastructure development often leads to colony abandonment, particularly in cave- and tree-dependent species. Climate change exacerbates these issues by altering rainfall patterns and increasing the frequency of extreme storms, which disrupt populations and roosts in vulnerable island habitats. Island endemics within the family are particularly vulnerable to , with high risks stemming from small sizes and isolation. In the , Emballonura semicaudata rotensis populations have declined by over 90% since the early 1900s, now restricted to a single known site on with fewer than 500 individuals. Species on , such as certain Taphozous populations, face analogous threats from habitat loss and invasives, contributing to broader insular declines across the family. Additional risks include bioaccumulation through contaminated insect prey, leading to sublethal effects like impaired and in species such as sheath-tailed bats. harvesting in roost caves disturbs maternity colonies and can cause direct mortality, especially in Old World populations. In , collisions with wind turbines pose an emerging threat to open-air foragers like the yellow-bellied sheath-tailed bat (Saccolaimus flaviventris), with documented fatalities at coastal wind farms. Overall population trends for Emballonuridae are stable in continental tropical areas, where common species maintain large numbers, but sharply declining on islands due to cumulative threats, resulting in fragmented distributions. Legal protections are patchy but include national endangered species listings for key taxa and habitat safeguards in protected areas; for example, Brazilian conservation units cover significant ranges for Neotropical emballonurids, while Australian national parks provide roost security for several species. Some taxa, such as Taphozous mixtus, have been proposed for Appendix II to regulate international trade, though most lack such global coverage.

Conservation Efforts

Conservation efforts for the Emballonuridae family emphasize the protection of critical roosting and foraging s through designated protected areas, particularly in biodiverse regions like the . In the Neotropics, Indigenous Territories serve as key reserves that safeguard emballonurid populations by maintaining forest cover and limiting , contributing significantly to overall diversity conservation in the region. Similarly, in , coastal protected areas such as those along Kenya's shoreline focus on preserving coral caves essential for species like the endangered Hildegarde's tomb (Taphozous hildegardeae), where -specific monitoring tracks population trends and habitat use. Research programs play a vital role in advancing knowledge and management of Emballonuridae, with the IUCN SSC Bat Specialist Group leading initiatives since the 2010s that include acoustic surveys to detect and monitor species across their ranges. Genetic studies have assessed variability within Emballonuridae taxa, informing population viability and supporting targeted interventions. Radio-tracking techniques have been employed to map roost sites, particularly for tree-roosting Australian species like Saccolaimus saccolaimus, aiding in the identification of high-priority conservation zones. Reintroduction and habitat restoration efforts target vulnerable island populations, such as the Pacific sheath-tailed bat (Emballonura semicaudata), where priority actions include habitat enhancement and exploratory programs to bolster declining numbers in regions like and the . In Australia, restoration initiatives incorporate tree-planting to provide suitable roosting hollows for emballonurids, enhancing urban and fragmented landscapes for species dependent on large trees. Policy measures address direct threats to roosts, including guidelines for sustainable harvesting in that minimize disturbance to cave-dwelling emballonurids by enforcing temporal segregation and protective buffers around colonies. African species, such as the naked-rumped tomb bat (Taphozous nudiventris), benefit from integration into broader bat conservation frameworks like the Eurobats agreement, which promotes transboundary protection for migratory populations. Community involvement is integral to these efforts, with education campaigns in fostering respect for bats among guano miners and local residents to reduce persecution and promote coexistence. In Kenya, collaborative projects with coastal communities develop ecotourism guidelines for cave roosts, ensuring visitor impacts are minimized while generating support for habitat protection. Future priorities include climate modeling to predict range shifts for Emballonuridae amid habitat alterations, alongside strengthened international collaborations through organizations like Bat Conservation International, which prioritizes species such as Emballonura semicaudata in global action plans.

References

  1. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10159116/
  2. https://mars.unh.edu/wild/emballonuridae.asp
  3. https://www.depts.ttu.edu/nsrl/publications/downloads/OP155.pdf
  4. https://animaldiversity.ummz.umich.edu/accounts/Rhynchonycteris_naso/
  5. https://animaldiversity.org/accounts/Emballonuridae/
  6. https://royalsocietypublishing.org/doi/10.1098/rstb.1981.0034
  7. https://www.britannica.com/animal/sheath-tailed-bat
  8. https://pmc.ncbi.nlm.nih.gov/articles/PMC6754726/
  9. https://academic.oup.com/jmammal/article/89/6/1401/909738
  10. https://www.researchgate.net/publication/226419112
  11. https://doi.org/10.1007/s00435-008-0072-6
  12. https://academic.oup.com/zoolinnean/article/202/3/zlad180/7578357
  13. https://zslpublications.onlinelibrary.wiley.com/doi/abs/10.1111/j.1469-7998.2006.00250.x
  14. https://academic.oup.com/jmammal/article-abstract/78/3/954/905406
  15. https://downloads.regulations.gov/FWS-R4-ES-2019-0106-0548/attachment_13.pdf
  16. http://www.faunaparaguay.com/emballonuridae.html
  17. https://www.dcceew.gov.au/sites/default/files/env/pages/a117ced5-9a94-4586-afdb-1f333618e1e3/files/38-ind.pdf
  18. https://bioone.org/journals/american-museum-novitates/volume-2006/issue-3538/0003-0082%282006%293538%255B1%253AANSOEC%255D2.0.CO%253B2/A-New-Species-of-Emballonura-Chiroptera--Emballonuridae-from-the/10.1206/0003-0082%282006%293538%5B1:ANSOEC%5D2.0.CO%3B2.full
  19. https://animalia.bio/yellow-bellied-sheath-tailed-bat?category=1
  20. https://www.encyclopedia.com/environment/encyclopedias-almanacs-transcripts-and-maps/sac-winged-bats-sheath-tailed-bats-and-ghost-bats-emballonuridae
  21. https://striresearch.si.edu/sensory-and-cognitive-ecology-lab/wp-content/uploads/sites/115/2022/06/2021_munoz-romo_et_al_mammal_review_-_following_the_odor_trail.pdf
  22. https://journals.co.za/doi/pdf/10.10520/AJA0012723X_1384
  23. https://www.merriam-webster.com/dictionary/Emballonuridae
  24. https://www.gbif.org/species/5218741
  25. https://www.researchgate.net/publication/242192383_Synopsis_of_South_American_bats_of_the_family_Emballonuridae
  26. https://flmnhbulletin.com/index.php/flmnh/article/view/flmnh-vol60-no3
  27. https://academic.oup.com/jmammal/article/93/6/1440/910878
  28. https://itis.gov/servlet/SingleRpt/SingleRpt?search_topic=TSN&search_value=180041
  29. https://pmc.ncbi.nlm.nih.gov/articles/PMC10159116/
  30. https://www.inaturalist.org/taxa/41334-Emballonuridae
  31. https://www.researchgate.net/publication/228684590_A_New_Species_of_Emballonura_Chiroptera_Emballonuridae_from_the_Dry_Regions_of_Madagascar
  32. https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0285271
  33. https://onlinelibrary.wiley.com/doi/abs/10.1111/j.1095-8312.2007.00942.x
  34. https://animaldiversity.org/accounts/Saccopteryx_bilineata/
  35. https://www.science.smith.edu/departments/biology/VHAYSSEN/msi/pdf/643_Peropteryx_macrotis.pdf
  36. https://www.science.smith.edu/departments/Biology/VHAYSSEN/msi/pdf/i0076-3519-582-01-0001.pdf
  37. https://tb.plazi.org/GgServer/html/E773F77E18E18E9D34472F0E86CF5F90
  38. https://speciesstatus.sanbi.org/assessment/last-assessment/2239/
  39. https://www.sciencedirect.com/science/article/abs/pii/S1055790312001248
  40. https://www.mammaldiversity.org/taxon/1004808/
  41. https://australian.museum/learn/animals/bats/yellow-bellied-sheathtail-bat/
  42. https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0240434
  43. https://academic.oup.com/icb/article/51/3/337/640694
  44. https://www.scielo.br/j/bn/a/tRwdTp9mrSdjkhS5WgKJ5qp/?lang=en
  45. https://animaldiversity.org/accounts/Diclidurus_albus/
  46. https://bioone.org/journals/american-museum-novitates/volume-2016/issue-3870/3870.1/Roosting-Ecology-of-Amazonian-Bats--Evidence-for-Guild-Structure/10.1206/3870.1.full
  47. https://bioone.org/journals/acta-chiropterologica/volume-6/issue-2/001.006.0208/Habitat-use-of-the-Pacific-Sheath-Tailed-Bat-Emballonura-semicaudata/10.3161/001.006.0208.full
  48. https://animaldiversity.org/accounts/Emballonura_monticola/
  49. https://www.science.smith.edu/departments/biology/VHAYSSEN/msi/pdf/i0076-3519-301-01-0001.pdf
  50. https://www.researchgate.net/publication/343712097_A_Recent_Survey_of_Bats_with_Descriptions_of_Echolocation_Calls_and_New_Records_from_the_Western_Himalayan_Region_of_Uttarakhand_India
  51. https://www.researchgate.net/publication/242187703_Diet_of_the_Black-bearded_Tomb_Bat_Taphozous_melanopogon_Temminck_1841_Chiroptera_Emballonuridae_in_India
  52. https://cdnsciencepub.com/doi/10.1139/z80-244
  53. https://animaldiversity.org/accounts/Taphozous_melanopogon/
  54. https://pmc.ncbi.nlm.nih.gov/articles/PMC3699716/
  55. https://pmc.ncbi.nlm.nih.gov/articles/PMC6308895/
  56. https://www.researchgate.net/publication/331022170_Biomonitoring_of_persistent_organic_pollutants_in_Egypt_using_Taphozous_perforatus_Chiroptera_Emballonuridae
  57. https://animaldiversity.org/accounts/Taphozous_melanopogon_phillipinensis/
  58. https://www.publish.csiro.au/ZO/ZO9730375
  59. https://www.researchgate.net/publication/18364043_Reproduction_in_the_common_sheath-tailed_bat_Taphozous_georgianus_Thomas_Microchiroptera_Emballonuridae_in_Western_Australia
  60. https://academic.oup.com/jmammal/article/89/1/50/1023380
  61. https://anatomypubs.onlinelibrary.wiley.com/doi/10.1002/aja.1001030103
  62. https://link.springer.com/article/10.1007/BF03186398
  63. https://genomics.senescence.info/species/entry.php?species=Saccopteryx_bilineata
  64. https://pmc.ncbi.nlm.nih.gov/articles/PMC2291157/
  65. https://www.science.smith.edu/departments/biology/VHAYSSEN/msi/pdf/i0076-3519-597-01-0001.pdf
  66. https://genomics.senescence.info/species/entry.php?species=Taphozous_hilli
  67. https://thainationalparks.com/species/black-bearded-tomb-bat
  68. https://www.researchgate.net/publication/320108511_Sociality_of_Bats
  69. https://sta.uwi.edu/fst/lifesciences/sites/default/files/lifesciences/documents/ogatt/Diclidurus_albus%20-%20Northern%20Ghost%20Bat.pdf
  70. https://www.science.smith.edu/departments/biology/VHAYSSEN/msi/pdf/i0076-3519-316-01-0001.pdf
  71. https://link.springer.com/article/10.1007/BF00299399
  72. https://www.jstor.org/stable/1381626
  73. https://www.researchgate.net/publication/312061983_Roosting_Ecology_of_Amazonian_Bats_Evidence_for_Guild_Structure_in_Hyperdiverse_Mammalian_Communities
  74. https://ecos.fws.gov/ecp/species/1919
  75. https://www.federalregister.gov/documents/2015/10/13/2015-25298/endangered-and-threatened-wildlife-and-plants-proposed-endangered-status-for-five-species-from
  76. https://ecos.fws.gov/docs/recovery_plan/American%2520Samoa%2520Species_Report%2520Emballonura%2520semicaudata%2520semicaudata_2020.pdf
  77. https://ecos.fws.gov/docs/recovery_plan/Emballonura%2520semicaudata%2520rotensis%2520Species%2520Report.pdf
  78. https://pubs.usgs.gov/publication/70118612
  79. https://micronesica.org/sites/default/files/271-2_article_08ed.pdf
  80. https://efsa.onlinelibrary.wiley.com/doi/abs/10.2903/j.efsa.2019.5758
  81. https://www.batcon.org/our-work/endangered-species-interventions/
  82. https://www.ari.vic.gov.au/__data/assets/pdf_file/0023/746060/ARI-Technical-Report-389-Systematic-review-of-onshore-wind-farm-collisions.pdf
  83. https://www.researchgate.net/publication/233491099_Habitat_use_of_the_Pacific_sheath-tailed_bat_Emballonura_semicaudata_on_Aguiguan_Mariana_Islands
  84. https://pmc.ncbi.nlm.nih.gov/articles/PMC11455905/
  85. https://cites.org/eng/cop/01/prop/index.php
  86. https://www.sciencedirect.com/science/article/pii/S2530064420300778
  87. https://www.batcon.org/our-work/endangered-species-interventions/saving-hildegardes-tomb-bat-in-kenya/
  88. https://www.iucnbsg.org/
  89. https://www.geneticsmr.org/articles/assessing-genetic-variability-in-bat-species-of-emballonuridae-phyllostomidae-vespertilionidae-and-molossidae-families-c.pdf
  90. https://www.publish.csiro.au/zo/ZO20044
  91. https://www.researchgate.net/publication/356624439_Status_of_Emballonura_semicaudata_Pacific_Sheath-Tailed_Bat_and_Priority_Conservation_Actions
  92. https://www.sciencedirect.com/science/article/pii/S0006320725001831
  93. https://wildlifeleaders.org/sites/default/files/documents/Bat%2520Group%2520SE%2520Asia%2520Bat%2520Guano%2520Harvesting%2520Guidelines.pdf
  94. https://www.eurobats.org/species/taphozous-nudiventris
Add your contribution
Related Hubs
User Avatar
No comments yet.