Bat
Bats are winged mammals; the only mammals capable of true and sustained flight. Bats are more agile in flight than most birds, flying with their long spread-out digits covered with a thin membrane or patagium. The smallest bat, and one of the smallest extant mammals, is Kitti's hog-nosed bat, which is in length, across the forearm and in mass. The largest bats are the flying foxes, with the giant golden-crowned flying fox reaching a weight of and having a wingspan of.
The second largest order of mammals after rodents, bats account for about 20% of all classified mammal species worldwide, with at least 1,500 known species. These were traditionally divided into two suborders: the largely fruit-eating megabats and the echolocating microbats. But more recent evidence has supported dividing the order into Yinpterochiroptera and Yangochiroptera, with megabats as members of the former along with several species of microbats. Many bats are insectivores, and most of the rest are frugivores or nectarivores. A few species feed on animals other than insects; for example, the vampire bats are haematophagous. Most bats are nocturnal, and many roost in caves or other refuges; it is uncertain whether bats have these behaviours to escape predators. Bats are distributed globally in almost all regions. They are important in their ecosystems for pollinating flowers and dispersing seeds as well as controlling insect populations.
Bats provide humans with some direct benefits, at the cost of some disadvantages. Bat dung has been mined as guano from caves and used as fertiliser. Bats consume insect pests, reducing the need for pesticides and other insect management measures. Bats are sometimes numerous enough and close enough to human settlements to serve as tourist attractions, and they are used as food in Africa, Asia, the Pacific and the Caribbean. Due to their physiology, bats are one type of animal that acts as a natural reservoir of many pathogens, such as rabies, and since they are highly mobile, social, and long-lived, they can readily spread disease among themselves. If humans interact with bats, these traits become potentially dangerous to humans.
Depending on the culture, bats may be symbolically associated with positive traits, such as protection from certain diseases or risks, rebirth, or long life, but in the West, bats are popularly associated with darkness, malevolence, witchcraft, vampires, and death.
Etymology
A dialectal English name for bats is "flittermouse", which matches their name in other Germanic languages, related to the fluttering of wings. Middle English had bakke, most likely cognate with Old Swedish natbakka, which may have undergone a shift from -k- to -t- influenced by Latin blatta,. The word bat was probably first used in the early 1570s. The order name Chiroptera derives from the Ancient Greek χείρ, meaning "hand", and πτερόν, meaning "wing".Phylogeny and taxonomy
Evolution
The delicate skeletons of bats do not fossilise well; it is estimated that only 12% of bat genera that lived have been found in the fossil record. The oldest known bat fossils include Archaeonycteris praecursor and Altaynycteris aurora, both known only from isolated teeth. The oldest complete bat skeletons are Icaronycteris gunnelli and Onychonycteris finneyi, known from two skeletons discovered in Wyoming. The extinct bats Palaeochiropteryx tupaiodon and Hassianycteris kumari, both of which lived 48 million years ago, are the first fossil mammals whose colouration has been discovered: both were reddish-brown.Bats were formerly grouped in the superorder Archonta, along with the treeshrews, colugos, and primates. Modern genetic evidence now places bats in the superorder Laurasiatheria, with its sister taxon as Ferungulata, which includes carnivorans, pangolins, odd-toed ungulates, and even-toed ungulates. One study places Chiroptera as a sister taxon to odd-toed ungulates.
The flying primate hypothesis proposed that when adaptations to flight are removed, megabats are allied to primates and colugos by anatomical features not shared with microbats, and thus flight evolved twice in mammals. Genetic studies have strongly supported the common ancestry of all bats and the single origin of mammal flight.
Co-evolutionary evidence
An independent molecular analysis trying to establish the dates when bat ectoparasites evolved came to the conclusion that bedbugs similar to those known today had already diversified and become established over 100 million years ago, suggesting that they initially all evolved on non-bat hosts and "bats were colonized several times independently, unless the evolutionary origin of bats has been grossly underestimated". No analysis has provided estimates for the age of the flea lineages associated with bats. The oldest known members of a different lineage of bat ectoparasites, however, are from roughly 20 million years ago, well after the origin of bats. The bat-ectoparasitic earwig family Arixeniidae has no fossil record but is not believed to originate more than 23 million years ago.Inner systematics
A 2011 study supported separating megabats and microbats. However, other and more recent evidence indicates that megabats belong within the microbats. Two new suborders have been proposed; Yinpterochiroptera includes the Pteropodidae, or megabat family, as well as the families Rhinolophidae, Hipposideridae, Craseonycteridae, Megadermatidae, and Rhinopomatidae. Yangochiroptera includes the other families of bats, a conclusion supported by a 2005 DNA study. A 2013 phylogenomic study supported the two new proposed suborders.The 2003 discovery of an early fossil bat from the 52-million-year-old Green River Formation, Onychonycteris finneyi, indicates that flight evolved before echolocative abilities. Unlike modern bats, Onychonycteris had claws on all five of its fingers. It also had longer hind legs and shorter forearms, possible adaptations for climbing. This palm-sized bat had short, broad wings, suggesting that it could not fly as fast or as far as later bat species. Instead of flapping its wings continuously while flying, Onychonycteris probably switched between flaps and glides in the air. Hence flight in bats likely developed from gliding and in arboreal locomotors, rather than terrestrial runners. This model of flight development, commonly known as the "trees-down" theory, holds that bats first flew by taking advantage of height and gravity to drop down on to prey, rather than running fast enough for a ground-level take-off.
The molecular phylogeny was controversial, as it pointed to microbats not having a unique common ancestry, which implied that some seemingly unlikely transformations occurred. The first is that laryngeal echolocation evolved twice in bats, once in Yangochiroptera and once in the rhinolophoids. The second is that laryngeal echolocation had a single origin in Chiroptera, was lost in the family Pteropodidae, and later evolved as a system of tongue-clicking in the genus Rousettus. Analyses of the sequence of the vocalisation gene FoxP2 were inconclusive on whether laryngeal echolocation was lost in the pteropodids or gained in the echolocating lineages. Echolocation probably first derived in bats from communicative calls. The Eocene bats Icaronycteris and Palaeochiropteryx had cranial adaptations suggesting an ability to produce ultrasound. This may have been used at first mainly to forage on the ground for insects and map out their surroundings in their gliding phase or for communicative purposes. After the adaptation of flight was established, it may have been refined to target flying prey. A 2008 analysis of the hearing gene Prestin seems to favour the idea that echolocation developed independently at least twice, rather than being lost secondarily in the pteropodids, but ontogenic analysis of the cochlea supports that laryngeal echolocation evolved only once.
Classification
Bats are placental mammals. After rodents, they are the largest order, making up about 20% of known mammal species. In 1758, Carl Linnaeus classified the seven bat species he knew of in the genus Vespertilio in the order Primates. Around twenty years later, the German naturalist Johann Friedrich Blumenbach gave them their own order, Chiroptera. Since then, the number of described species has risen to over 1,500, traditionally classified as two suborders: Megachiroptera and Microchiroptera. Not all megabats are larger than microbats. Several characteristics distinguish the two groups. Microbats use echolocation for navigation and finding prey, but megabats, apart from those in the genus Rousettus, do not. Accordingly, megabats have well-developed eyesight. Megabats have a claw on the second finger of the forelimb, external ears close to form a ring, and lack a tail. They only feed on plant material like fruit and nectar.File:Haeckel Chiroptera.jpg|thumb|upright|"Chiroptera" from Ernst Haeckel's Kunstformen der Natur, 1904
Below is a table chart following the bat classification of families recognised by various authors of the ninth volume of Handbook of the Mammals of the World published in 2019: