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33 million year old Myotis (Chiroptera, Vespertilionidae) and the rapid global radiation of modern bats

  • Gregg F. Gunnell ,

    Contributed equally to this work with: Gregg F. Gunnell, Richard Smith, Thierry Smith

    gregg.gunnell@duke.edu

    Affiliation Division of Fossil Primates, Duke University Lemur Center, Durham, North Carolina, United States of America

  • Richard Smith ,

    Contributed equally to this work with: Gregg F. Gunnell, Richard Smith, Thierry Smith

    Affiliation Directorate Earth & History of Life, Royal Belgian Institute of Natural Sciences, Brussels, Belgium

  • Thierry Smith

    Contributed equally to this work with: Gregg F. Gunnell, Richard Smith, Thierry Smith

    Affiliation Directorate Earth & History of Life, Royal Belgian Institute of Natural Sciences, Brussels, Belgium

Abstract

The bat genus Myotis is represented by 120+ living species and 40+ extinct species and is found on every continent except Antarctica. The time of divergence of Myotis has been contentious as has the time and place of origin of its encompassing group the Vespertilionidae, the most diverse (450+ species) and widely distributed extant bat family. Fossil Myotis species are common, especially in Europe, beginning in the Miocene but earlier records are poor. Recent study of new specimens from the Belgian early Oligocene locality of Boutersem reveals the presence of a relatively large vespertilionid. Morphological comparison and phylogenetic analysis confirms that the new, large form can be confidently assigned to the genus Myotis, making this record the earliest known for that taxon and extending the temporal range of this extant genus to over 33 million years. This suggests that previously published molecular divergence dates for crown myotines (Myotis) are too young by at least 7 million years. Additionally, examination of first fossil appearance data of 1,011 extant placental mammal genera indicates that only 13 first occurred in the middle to late Paleogene (48 to 33 million years ago) and of these, six represent bats, including Myotis. Paleogene members of both major suborders of Chiroptera (Yangochiroptera and Yinpterochiroptera) include extant genera indicating early establishment of successful and long-term adaptive strategies as bats underwent an explosive radiation near the beginning of the Early Eocene Climatic Optimum in the Old World. A second bat adaptive radiation in the New World began coincident with the Mid-Miocene Climatic Optimum.

Introduction

Bats make up over one fifth of all living mammal species [1]. They occupy nearly every corner of the Earth and exploit a wide variety of habitats and climatic zones. Remarkably, the basic topology of the bat tree of life was established very early in their evolutionary history as they underwent a nearly instantaneous adaptive radiation during the Eocene, exploiting a previously under-utilized yet virtually limitless food resource, that of night flying insects.

Here we demonstrate the late Paleogene occurrence of the well-known living bat genus Myotis and document the first occurrences of extant bat and other mammalian taxa in the fossil record. We show that the presence of extant genera of major bat clades was established very early suggesting that the adaptive roles filled by these taxa were also in place very early in their diversification, roles that have been maintained to the present day. The vespertilionid bat genus Myotis is virtually ubiquitous with over 120 known extant species distributed around the Earth and found in nearly every geographic province except the poles and some oceanic islands [1]. In general, Myotis is viewed as a relatively unspecialized taxon that retains a primitive dentition [2] and, like most vespertilionids, Myotis lacks exaggerated morphological specializations (greatly enlarged cochlea) associated with advanced echolocating abilities [3].

Traditionally three or four subgenera of Myotis have been recognized based on ecologically associated morphological features that appeared to differentiate between M. (Myotis), M. (Selysius), M. (Leuconoe), and occasionally M. (Cistugo) and M. (Pizonyx) as well [46]. However, molecular phylogenetic analyses have repeatedly failed to support these morphological groupings [712] instead finding upwards of ten separate Myotis clades including a New World clade consisting of three subclades and an Old World clade consisting of a distinct Ethiopian clade and, at least, eight Eurasian clades [12]. Ecological groupings similar to those used to initially cluster Myotis species into subgenera appear in parallel within these clades [13]. Of these, only the New World and Ethiopian clades appear to be geographically circumscribed with the other clades often including taxa that, together, are broadly distributed across Eurasia.

There is an extensive fossil record of Myotis known predominantly from the late Oligocene through Holocene in Europe [1421] with lesser occurrences known from the Plio-Pleistocene of Africa, the late Miocene through Pleistocene in North America, and the Pleistocene and Holocene of China, Japan and Madagascar [2235]. In the following work a new species of Myotis is described from the earliest Oligocene. Following this an examination of early fossil occurrences of bat species assigned to extant genera is presented in the context of a developing scenario of separate bat adaptive radiations centered in Old and New Worlds.

The new Myotis species described here comes from the Boutersem locality in central Belgium which, along with associated localities at Hoogbutsel and Hoeleden (Fig 1), has been known since the early 1950’s and has produced a fairly extensive vertebrate faunal assemblage [3642]. The Boutersem Sand Member belongs to the Borgloon Formation and is stratigraphically positioned just above the marine St. Huibrechts-Hern Formation located at the base of the Rupelian (earliest Oligocene), dated at 33.9 Ma [4344]. Boutersem and its associated localities are included in European reference level MP 21 and are each approximately 33.5 million years old.

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Fig 1. Map showing the geographic positions of the Belgian localities of Hoogbutsel, Hoeleden, and Boutersem-TGV that yielded the early myotine Myotis belgicus sp. nov. and the plecotine Quinetia misonnei.

https://doi.org/10.1371/journal.pone.0172621.g001

Material and methods

Material collected

One of us (RS) screen washed 6+ tons of matrix from the Boutersem Sand Member of the Borgloon Formation (Fig 1). No permits were required for the described study. Collection of specimens complied with all relevant local regulations and no endangered or protected species were disturbed or harmed in any way. Screen residues were then sorted under a binocular microscope and teeth and bones were extracted, mounted on pins where appropriate, identified and assigned catalog numbers. In all over 2000 vertebrate specimens were found including the 50 bat specimens described herein. The types and figured specimens described here are stored at the Royal Belgian Institute of Natural Sciences, Brussels, Belgium (RBINS = IRSNB).

Nomenclatural acts

The electronic edition of this article conforms to the requirements of the amended International Code of Zoological Nomenclature, and hence the new names contained herein are available under that Code from the electronic edition of this article. This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the ICZN. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix "http://zoobank.org/". The LSID for this publication is urn:lsid:zoobank.org:pub:A1E97058-ED37-46BB-95A5-55A7DFDD67A1. The electronic edition of this work was published in a journal with an ISSN, and has been archived and is available from the following digital repositories: PubMed Central, LOCKSS.

Standard anatomical comparisons were made with extant myotines and other vespertilionids in the collections of the RBINS and with appropriate fossil specimens of similar ages and from other circum-Tethys localities based on primary taxonomic literature (see S1 Table for a list of comparative specimens examined). Tooth terminology follows [2]. Measurements were taken either from scaled SEM images or by use of a binocular dissecting microscope fitted with a measuring reticule. Tooth measurements of fossils are presented in Tables 1 and 2.

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Table 1. Measurements (in mm) of lower teeth of Quinetia misonnei and Myotis belgicus (L = length, W = width, H = height).

https://doi.org/10.1371/journal.pone.0172621.t001

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Table 2. Measurements (in mm) of upper teeth of Quinetia misonnei and Myotis belgicus (* = estimate, abbreviations as in Table 1).

https://doi.org/10.1371/journal.pone.0172621.t002

Results

Systematic paleontology

Class Mammalia Linnaeus, 1785

Order Chiroptera Blumenbach, 1779

Family Vespertilionidae Gray, 1821

Subfamily Myotinae Tate, 1942

Genus Myotis Kaup, 1829

Myotis belgicus sp. nov. urn:lsid:zoobank.org:act:65A2D5F3-7655-4F02-8007-F6B4C0DA18EB

Holotype.

IRSNB M 2172, right dentary with m1-3 and alveoli for i1-3, c, and p2-4 (Figs 2U–2W, 3A and 3B).

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Fig 2. Dentition of early Oligocene myotine Myotis belgicus n. sp. from Boutersem, Belgium.

(a-b) left M3, IRSNB M 2180 in labial and occlusal views; (c-d) right M1, IRSNB M 2179 in labial and occlusal views; (e-f) left P4, IRSNB M 2178 in labial and occlusal views; (g-h) left C1, IRSNB M 2177 in labial and lingual views; (i-k) right c1, IRSNB M 2176 in lingual, labial and occlusal views; (l-n) right p2, IRSNB M 2175 in lingual, labial and occlusal views; (o-q) left p3, IRSNB M 2174 in lingual, labial and occlusal views; (r-t) right p4, IRSNB M 2173 in lingual, labial and occlusal views; (u-w) right dentary m1-3, IRSNB M 2172 (Holotype) in lingual, labial, and occlusal views. Extant myotine Myotis myotis (x-y) right maxillary with I1-M3 and right dentary with i1-m3, IRSNB 98-067-0003 in occlusal views.

https://doi.org/10.1371/journal.pone.0172621.g002

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Fig 3. Comparison of the early Oligocene vespertilionids from Boutersem, Belgium with the extant myotine Myotis myotis.

Early Oligocene myotine Myotis belgicus n. sp., IRSNB M 2172, Holotype, (a-b) right dentary with m1-3 and alveoli for i1-3, c, and p2-4 in labial and occlusal views. Early Oligocene vespertilionine Quinetia misonnei, IRSNB M 1189, holotype (c-d) right dentary p4-m3 (p4 now lost) and IRSNB M 2184 (e-h) right humerus. Extant myotine Myotis myotis, IRSNB 98-067-0003, (i-j) right dentary, (k) right maxillary, and (l-o) right humerus. Dentaries in labial and occlusal views, maxilla in occlusal view and humeri in ventral and dorsal views.

https://doi.org/10.1371/journal.pone.0172621.g003

Locality and horizon.

Boutersem, Boutersem Sand Member, MP-21, Borgloon Formation, early Oligocene, Rupelian. Myotis belgicus is also present at Hoogbutsel, approximately 6 km northeast of Boutersem in the same formation and member.

Referred specimens.

From Boutersem: IRSNB M 2173 (Right p4, Fig 2R–2T); IRSNB M 2174 (Left p3, Fig 2O–2Q); IRSNB M 2175 (Right p2, Fig 2L–2N); IRSNB M 2176 (Right c, Fig 2I–2Kn); IRSNB M 2177 (left C1, Fig 2G and 2H); IRSNB M 2178 (Left P4, Fig 2E and 2F); IRSNB M 2179 (Right M1, Fig 2C and 2D); IRSNB M 2180 (Left M3, Fig 2A and 2B); BOU 131 RS (Right M1); BOU 142 RS (Left m2); BOU 150 RS (Left m2); BOU 220 RS (Right p4); BOU 244 RS (Right p4); BOU 279 RS (Right m2); BOU 325 RS (Right m3); BOU 332 RS (Right p4); BOU 333 RS (Left M3 broken); BOU 334 RS (Right m1); BOU 359 RS (Right M3 broken); BOU 363 RS (Left dentary with m2-3); BOU 364 RS (Right dentary m3); BOU 405 RS (Left C); BOU 568 RS (Right M2); BOU 580 RS (Left M2); BOU 592 RS (Right C); BOU 593 RS (Left c); BOU 612 RS (Right p4); BOU 616 RS (Right M2); BOU 630 RS (Left m2).

From Hoogbutsel: IRSNB HG 1250 (Left p4); IRSNB HG 1899 (Right p2); IRSNB HG 2058 (Left C); IRSNB HG 2299 (Right p3); IRSNB HG 2365 (Left p3); IRSNB HG 2447 (Left p4); IRSNB HG 2527 (Left p4); IRSNB HG 3825 (Left c); IRSNB HG 4426 (Left p4); IRSNB HG 4591 (Left p4). See Tables 1 and 2 for tooth measurements.

Diagnosis.

A moderately large Myotis species with the following combination of morphological characters: lower canine relatively low and robust with heavy lingual cingulid; p4 with distinct lingual cingulid that turns upward anteriorly to form a projecting cuspule; lower molars with relatively broad trigonid fossae and very robust hypoconulids; upper canine projecting, only slightly posteriorly curved with a continuous cingulum and distinct lingual ridge; P4 with steeply sloping postparacrista and moderate parastyle; upper molars with very weak paraloph, a short sloping postprotocrista, an anteroposteriorly broad protofossa, and two narrow but distinct ectoflexi.

Etymology.

Belgicus, for Belgium where the Boutersem locality is found.

Description.

In general, Myotis belgicus has about the same tooth proportions as extant Myotis velifer, one of the larger living species. In tooth morphology, M. belgicus is quite similar to extant Myotis myotis but averages 25% smaller in molar dimension than this living species (based on tooth measurements taken in the University of Michigan Museum of Zoology [UMMZ] collections).

The upper canine (Fig 2G and 2H) of M. belgicus is robust with a strong circular root that is longer in extent than the crown. The crown is circular at its base and is surrounded by a modest basal cingulid. The crown tapers to a point and has a distinctive lingual ridge that runs from base to tip and curves slightly posteriorly.

P4 (Fig 2E and 2F) has a prominent paracone and a steeply sloping paracristid that extends to a small, rounded metastylar region. There is a weak labial cingulum that expanded to form a short shelf as it wraps around the anterior aspect of the tooth where it is continuous with a flat, rounded and modestly developed lingual shelf that is not distended posteriorly.

M1 (Fig 2C and 2D) is very similar to that of M. myotis only differing in having a somewhat weaker postmetacrista, a postprotocrista that does not extend all the way to postcingulum and having a metastylar region that extends relatively farther labially. There are two distinct ectoflexi present as in M. myotis, a broader and deeper one anterior to the mesostyle and a narrower and shallower one posterior to the mesostyle.

M3 (Fig 2A and 2B) in M. belgicus differs somewhat from that of M. myotis, more resembling species such as M. daubentonii, in being relatively longer and in retaining a small metacone, a relatively long premetacrista, a distinct mesostyle, and in having a more extensive protofossa.

The lower canine (Fig 2I–2K) of M. belgicus has a tall crown with a convex anterior surface and a flattened posterior surface. It has a complete cingulid that angles towards the tip on the labial side and broadens both posteriorly and lingually, all typical Myotis characteristics. The posterior cingulid is notched as in some species of extant Myotis (e.g. M. daubentonii).

The second and third lower premolars (Fig 2L–2Q) are single-rooted teeth with a single, centered, tapering cusp dominating the crown. As in all Myotis species, p3 is slightly smaller than p2. Both teeth are encircled by continuous and moderately heavy cingulids.

The lower fourth premolar (Fig 2R–2T) is double-rooted and has a protoconid that is as tall as that of the molars and nearly as tall as the tip of the canine. It has a faint yet obvious preprotocristid that extends to the cingulid lingually to join a protruded cingular surface that extends towards the tip anteriorly. The labial and lingual cingulids extend posteriorly to join in a broad posterior cingular shelf with the lingual cingulid being slightly broader than the labial one. There is postprotocristid that extends down the posterolingual surface of the protoconid to join a cingulid that is distended slightly at the posterolingual border of the tooth.

The lower molars (Fig 2U–2W and Fig 3A and 3B) are typical of Myotis species in being myotodont with trigonids slightly taller than talonids and all major cusps present and acutely pointed. The m1 trigonid fovea is broader and more open than that of m2-3, m1 and m2 are of nearly equal size while m3 is somewhat smaller. All three molars have distinct hypoconulids (slightly smaller on m3) and strong labial cingulids that wrap around the anterior base of the teeth almost to the lingual border and extend around the posterior base of the crowns to terminate at the hypoconulid. There are no lingual cingulids developed. The cristid obliqua joins the postvallid just labial of center (m1) or nearly centrally (m2-3) and all three teeth have relatively deep talonid basins and well developed entocristids that wall off the lingual side of the talonids.

Comparative analysis.

In addition to the phylogenetic analysis (see below), the Boutersem specimens can be assigned to Myotis rather than to any other vespertilionid based on the combination of the following features: 3.1.3.3 dental formula, the presence of a single-rooted p3 that is somewhat smaller than p2, myotodont lower molars that have relatively deep talonid basins, well developed entocristids and lacking lingual cingulids, a relatively high crowned lower canine with well-developed mesial and distolingual shelves, a projecting upper canine with a distinct lingual ridge, a circular cross-section and complete but not especially robust cingulum, M1 and M2 lacking both paraconules and metalophs, protofossa of M1 and M2 open posteriorly, and M3 being relatively short.

The Boutersem Myotis specimens represent the earliest known record of this extant genus. Only some isolated potential myotine teeth from Le Batut (MP 19) in France are older but these teeth differ from Myotis in having upper molars with a paraloph and a protofossa closed posteriorly, both features more typical of enigmatic “Leuconoe”. Myotodont species such as “L”. salodorensis from Oensingen (MP 25) in Switzerland and “L”. lavocati from Le Garouillas (MP 25–28) in France, both share features of upper teeth that distinguish them from Myotis, particularly in the presence of a distinct paraconule lacking in Myotis [21]. Younger still are three Myotis species from Herrlingen 8–9 (MP 29) in Germany [45]. Compared to the Boutersem Myotis, M. minor is much smaller with a relatively smaller, shorter and more delicate p4, M. intermedius is somewhat smaller in molar dimensions but with a substantially smaller and shorter p4, while M. major has larger m1-2, similar sized m3, smaller p4, more robust M1 and a more constricted P4 lingual shelf.

Based on its presence in Boutersem, the origin of Myotis must be at least as old as the early Oligocene. Slightly older Khonsunycteris aegyptiacus [46] from the Fayum in Egypt (34 mya) differs from Myotis belgicus (and all other Myotis species) in having p2 larger relative to p3, p2 relatively long with a distended labial surface and with a distinct preprotocristid, in having a double-rooted p3, and in having lower molars with more crestiform paraconids. Nonetheless, Khonsunycteris may well represent the earliest known myotine [2].

In a recent paper examining molecular relationships among approximately ¾ of the global diversity of Myotis species (~90 out of ~120 recognized species), Ruedi et al. [12] present evidence that crown-group Myotis diverged from a common ancestry with other vespertilionids (specifically a Kerivoula-Murina clade) at approximately 26 million years ago. Further, crown myotines are demonstrated to have diverged from enigmatic “Myotislatirostris by approximately 21 mya. These authors suggest that because “M.” latirostris, M. siligorensis alticraniatus (subsumed into M. siligorensis by Simmons [1]) and an unnamed Myotis species from China all possess nyctalodont or sub-nyctalodont molars that myotodonty is not a diagnostic character of the genus Myotis despite the fact that virtually all of the other 117+ extant Myotis species and all of the 40+ fossil species of Myotis possess this dental characteristic to the exclusion of most other vespertilionids.

Ruedi et al. [12] also cite Submyotodon [21] as an example of a myotine taxon that has both sub-nyctalodont and sub-myotodont molars together in the same jaw. As it turns out, these sorts of occurrences are not entirely uncommon–Gunnell et al. [47] noted the presence of myotodont and submyotodont molars together in the myzopodid genus Phasmatonycteris and similar occurrences are known in some molossids [4849] and in some archaic bats [50] where the disposition of the hypoconulid is often variable. The archaic bat Stehlinia, well represented from late Eocene and Oligocene Quercy deposits in France, typically is nyctalodont but some specimens of S. quercyi and S. gracilis mutans have sub-myotodont molars [51]. These examples suggest that many combinations of postcristid and hypoconulid are possible within bat species and that within a large and widespread radiation such as that of Myotis, some species should be expected to have developed molars that differ somewhat from the ancestral myotodont condition. However, clearly these are exceptions to an otherwise apomorphic condition shared by virtually all myotines, suggesting that the few outliers are not especially phylogenetically relevant.

Additionally, it is also important to keep in mind that it is not only the possession of myotodont molars that defines the genus Myotis morphologically–species of the genus also possess in combination with myotodonty the features cited above (tall lower canine with distinct distolingual cingulids, 3.1.3.3 dental formula, p3 smaller than p2 (a derived condition compared to archaic bats[50]), single-rooted p3 (derived compared to Khonsunycteris which has a double-rooted p3 [46]), tall, dagger-like upper canines with distinct lingual ridges (all derived compared to archaic bats [50]), P4 simple with rounded labial shelf, and upper molars lacking paraconules and metalophs (both derived compared to archaic bats [50]) and a distally open protofossa.

Ruedi et al. [12] cite the existence of Cistugo as another taxon sharing these same dental features with Myotis therefore making the assignment of Khonsunycteris and now Myotis belgicus to Myotinae less probable given the molecularly derived basal position of Cistugo relative to other vespertilionids [11]. However, a close inspection of the dentition of Myotis belgicus reveals many features in which it differs from Cistugo and more closely resembles Myotis including having: a lower canine with heavier lingual cingulid and lacking the distinctive lingual ridge that extends nearly to tip of canine in Cistugo; p4 with lingual cingulum turned towards tip of protoconid and forming a small cingular cuspule as in Myotis and unlike Cistugo where the cingulid is straight and flat; p4 anteroposteriorly more extensive and relatively shorter as in Myotis; upper molars with relatively deeper ectoflexi and a metastylar shelf that extends buccally beyond the meso- and parastyles; upper molars lacking a distinct paraloph as in Myotis (Cistugo has a distinct paraloph, a condition that more resembles Quinetia (see below) and “Leuconoe”); upper canines with less distinct cingulum and possessing a distinct lingual ridge that is absent in Cistugo; P4 relatively shorter with a rounded lingual shelf that is not extended distally; p2 relatively larger relative to p3 and less reduced relative to p4 as in Myotis and unlike in Cistugo where p2 and p3 are more similar in size, both small; both p2-3 with relatively higher protoconids like in Myotis not like Cistugo where these cusps are lower and equal in height.

Ruedi et al. [12] note that the divergence date for Myotis they predicted based on their analysis (at most 26 mya), while older than previous molecular estimates [810], is still nearly 7 million years younger than those suggested by paleontological evidence. Ruedi et al. [12] use only two paleontological calibrations to provide temporal constraints in their analysis—the hypothesized split of Myotis daubentonii and Myotis bechsteinii dated at between 5 and 11.6 Ma and a Myotis clade divergence in the late Oligocene or early Miocene (estimated by Ruedi et al. to be between 20 and 31 Ma). We suspect that by using firmer minimum dates for the first appearance of true Myotis (at 33.5 Ma) to provide temporal constraints, the differences in morphological and molecular divergence times for the genus would likely shrink to insignificance. Amador et al. [52] estimated a divergence time between the myotine and vespertilionine clades of 35.94 Ma, which would fit well with a first appearance of Myotis at 33.5 Ma.

Subfamily Vespertilioninae Gray, 1821

Tribe Plecotini Gray, 1866

Quinetia misonnei (Quinet, 1965)

Holotype.

IRSNB M 1189, right dentary p4-m3 (p4 now lost) (Figs 3C, 3D and 4H–4J).

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Fig 4. Dentition of early Oligocene vespertilionine Quinetia misonnei from Boutersem, Belgium.

IRSNB M 2183 (a-b) left M2, IRSNB M 2182 (c-d) right M1, IRSNB M 2181 (e-g) p4, and IRSNB M 1189 (holotype) (h-j) right dentary m1-3. Upper molars in labial and occlusal views, dentary and p4 in labial, occlusal and lingual views.

https://doi.org/10.1371/journal.pone.0172621.g004

Paratype.

IRSNB M 1190, Left dentary m1-2

Locality and horizon.

Hoogbutsel, Boutersem Sand Member, MP-21, Borgloon Formation, early Oligocene, Rupelian. Q. misonnei is also present at Boutersem, approximately 6 km southwest of Hoogbutsel in the same formation and member.

Referred specimens.

From Hoogbutsel: IRSNB M1191 –Reg. 4200 (Edentulous dentary); IRSNB M1192 –Reg. 4201 (Left dentary with m1-2); IRSNB HG 541 (Left m1 or m2); IRSNB HG 1466 (Left C); IRSNB HG 3171 (Right c). From Boutersem: IRSNB M 2181 (Right p4, Fig 4E–4G); IRSNB M 2182 (Right M1, Fig 4C and 4D); IRSNB M 2183 (Left M2, Fig 4A and 4B); IRSNB M 2184 (Right complete humerus, Fig 3E–3H); BOU 263 RS (Right M1); BOU 280 RS (Right m1); BOU 326 RS (Right m2); BOU 327 RS (Left m2); BOU 359 RS (R M3 broken); BOU 387 RS (Right m3); BOU 404 RS (Right dentary with m1-2); BOU 406 RS (Right m2); BOU 432 RS (Right m2); BOU 519 RS (Right dentary with m2-3); BOU 538 RS (Right m3 broken); BOU 559 RS (Left m1); BOU 591 RS (Right dentary with m2-3, m2 broken, includes all anterior alveoli and ascending ramus); BOU 632 RS (Right m1); BOU 697 RS (Left M2); BOU 702 RS (Left M2); BOU 817 RS (Right p4). See Tables 1 and 2 for tooth measurements.

Description.

Quinetia misonnei is represented by upper molars, a lower p4 and lower molars, a complete humerus and complete dentaries that include alveoli of all lower teeth.

The alveoli preserved in the dentary (Fig 3C and 3D) confirm the presence of the primitive bat lower dental formula of 3.1.3.3. Judging by the alveoli the canine was robust and p2 and p3 were single-rooted and nearly identical in size. The horizontal ramus is slender with a mental foramen presence below and just anterior to p2. The ascending ramus is relatively tall and straight (not leaning anteriorly), taller than is typical for extant plecotins like Plecotus and Barbastella. It has a rounded coronoid process and an articular condyle situated well above the tooth row. The angular process is broken posteriorly but appears as though it would have been extensive as in living plecotins. The mandibular fossa is relatively large and less restricted than in Barbastella.

The upper molars of Quinetia (Fig 4A–4D) resemble those of Plecotus more than Barbastella in being noticeably wider than long, with M1 being somewhat less so than M2. Both molars have two ectoflexi with those on M2 being more sharply defined and deeper. Both molars also have distinct paralophs and present, though less distinct, metalophs. As in Plecotus, M2 has an extended metastylar region that reaches labially beyond the para- and mesostyles. M2 has distinct hook-like para- and metastyles while only the parastyle of M1 is weakly curved. Both upper molars have moderate lingual cingula and neither shows any development of a hypocone or hypocone shelf.

The p4 of Quinetia (now lost from the holotype but figured previously [18, 53] is double-rooted and relatively small and short (Fig 4E–4G) as in Plecotus. It has a prominent protoconid and a distinct, low paraconid connected to the protoconid by a well-developed paracristid. An equally well-developed postprotocristid extends from the tip of the protoconid to the posterolingual corner of the tooth where it ends at the cingulid. There is a cingulid that nearly encircles, ending at the paraconid on both the anterolabial and anterolingual sides. The cingulid is widest posteriorly.

The lower molars of Quinetia are nyctalodont and have noticeably higher trigonids compared to talonids (Fig 4H–4J) like those found in most plecotins. Like Barbastella m3 is only somewhat reduced compared to m1-2. Unlike Barbastella and Plecotus, Quinetia has more closed molar trigonids with narrower trigonid fovea. The talonid of m3 in Quinetia is as wide as the trigonid, not narrower as in Plecotus and Barbastella. All three molars in Quinetia have relatively weak labial cingulids and lack any sign of lingual cingulids except a small ridge at the base of trigonid notch.

The complete humerus from Boutersem (Fig 3E–3H) is assigned to Quinetia based on size. The molars of Quinetia are very close in size to living Myotis nigricans which has an average humerus length (based on three specimens from the University of Michigan Museum of Zoology [UMMZ] collections) of 20.46 mm as compared to 20.0 mm for the Boutersem bat. Based on molar size, M. belgicus should have a humerus close in size to that of extant Myotis velifer which has an average humerus length (based on eight UMMZ specimens) of 26.06 mm. Based on these comparisons the humerus from Boutersem is more likely to be that of Quinetia rather than M. belgicus.

The humerus is very similar to those of extant vespertilionids (Fig 3L–3O). The trochiter (greater tuberosity) is robust and extends proximally well beyond the humeral head. The head is rounded and only slightly wider than tall. The lesser tuberosity extends to the level of the head and is rounded and robust as well. The deltopectoral crest is broad proximally, tapers distally and extends about 1/5 of the way down the shaft.

The distal end of the humerus has a trochlea only slightly more proximodistally extensive than the capitulum and continuous with it (not separated by a capitular groove). The capitulum and trochlea are aligned with the center of the shaft as is typical of vespertilionids, not offset from the shaft as in many other bats. The lateral capitular tail is narrower than the capitulum (proximodistally) and flairs laterally. The epitrochlea is not offset medially and does not extend distally beyond the surface of the trochlea. As in most vespertilionids, the distal end of the humerus is relatively narrow mediolaterally.

Comparative analysis.

Quinetia misonnei was first described as a species of Myotis by Quinet [53]. Horáček [18] noted that M. misonnei had nyctalodont molars with shallow talonid basins and no entocristid development, in contrast to Myotis. He proposed the genus Quinetia to replace Myotis for this species. He also noted that these molar characteristics along with the presence of a slender and pointed p4 are quite similar to the plecotin Barbastella. Horáček [18] also indicated that Q. misonnei molars had well-developed lingual cingulids, a rare feature in most vespertilionids except plecotins. However, Horáček never had the opportunity to examine the type and referred specimens of Quinetia first-hand. We now know, based on close inspection of the type and the additional specimens from Boutersem, that Quinetia molars do not have lingual cingulids and, as noted by Horáček [18], Quinetia retains a p3 that, judging by the alveolus, was probably similar in size to or only slightly smaller than p2, both in contrast to Barbastella.

However, extant Plecotus does retain a small p3, a moderately sized p2, and has relatively short and tall p4 with a prominent anterolingual cingular cuspule, features which are also true of Quinetia. Quinetia differs from Plecotus in having M1-2 with para- and metalophs, a higher coronoid process of the dentary, and m1-2 with anteroposteriorly shorter (more closed) trigonids. In addition our phylogenetic analysis (see below) finds that Quinetia misonnei is consistently linked as the sister taxon of extant Plecotus austriacus supporting Horáček’s [18] notion that Quinetia was a probable plecotine vespertilionid.

In general, Quinetia appears closer to plecotins than to other vespertilionids. It clearly is more primitive in some features than extant plecotins including having distinct para- and metalophs on upper molars and a distinct paraconid on p4 but this may not be surprising given its probable position at the base of that clade. Importantly, the presence of plecotin vespertilionines at Boutersem and Hoogbutsel at 33.5 mya, implies that vespertilionines and myotines had diverged by that time (and that vespertilionines had diversified within the subfamily), adding support to the notion that the larger bats from these Belgian localities are myotines and almost certainly represent true Myotis as suggested here.

Phylogenetic analysis

In order to further test the phylogenetic affinities of the bats from Boutersem, we conducted a phylogenetic analysis of a dental character matrix. The morphological data set upon which our analysis was based included 280 dental characters and 27 taxa. The matrix was built using Morphobank Version 3.0a [54] and is available for download as a TNT or NEXUS file (S1 and S2 Files). Besides Myotis belgicus and Quinetia misonnei, five other fossil taxa were scored including the archaic bat Onychonycteris finneyi (Onychonycteridae), the myzopodids Phasmatonycteris butleri and P. phiomensis, the mystacinid Mystacina miocenalis, and the basal myotine vespertilionid Khonsunycteris aegypticus. Extant taxa represent a variety of Old World Yangochiroptera including Noctilionoidea (Mystacinidae and Myzopodidae [55] although the latter family may belong in the Emballonuroidea instead [52]) and Vespertilionoidea (Miniopteridae, Cistugidae, and Vespertilionidae; see S2 Table for a list of included taxa and their current taxonomic placements). Character states were scored using original specimens, or Micro-Ct images of teeth or in some case by examining high quality casts housed at the Duke Lemur Center, Division of Fossil Primates.

All trees were rooted utilizing Onychonycteris finneyi as the most basal outgroup. The matrix was analyzed in TNT version 1.5 [56]. The search strategy followed that of Spaulding and Flynn [57] utilizing the ‘New Technology search’ option, selecting the sectorial search, ratchet and tree fusing search methods, all with default parameters. Under these settings, replications were run until the minimum length tree was found in 1000 separate replicates. The generated trees were then analyzed under typical search options (using TBR) to fully explore the discovered tree islands. Bremer support indices were determined using TNT and were calculated for 10 supplementary steps. Bootstrap values were calculated using TNT (1000 bootstrap replicates. Results were examined with Winclada 1.00.08 using Strict Consensus and Majority Rule trees.

The phylogenetic analysis yielded 241 equally parsimonious trees, with a tree length of 705 steps, and CI of 0.38 and RI of 0.52. The strict consensus tree is 1110 steps long with a CI = 0.24 and RI = 0.07. In the strict consensus, 24 nodes are collapsed. The majority rule consensus (Fig 5) is 708 steps long. Its CI and RI equal 0.38 and 0.51, respectively. The only value of Bremer support that TNT found is situated at the very base of the tree, between Onychonycteris finneyi (i.e., the most basal outgroup) and the other taxa (the value is greater than 10); this node has a Bootstrap value of 100. Two internal nodes also have Bootstrap values of 69 (for the Austronomus-Chaerephon clade) and 60 (for the Myotis belgicus-Myotis myotis clade)

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Fig 5. 50% majority rule consensus tree of 708 steps, CI = 0.38, RI = 0.51.

https://doi.org/10.1371/journal.pone.0172621.g005

In general the majority rule tree based on dental evidence conforms to results found based on other molecular and morphological analyses [52, 55] with some caveats (Fig 5). The separation of Cistugo and Miniopterus from Vespertilionidae into distinct families [11, 58] is supported by our analysis and we recover monophyletic Mystacinidae, Natalidae and Myzopodidae. Also Khonsunycteris appears as a basal vespertilionoid as has been previously suggested [2].

However, within other vespertilionoids relationships become more problematic, likely due to rampant dental homoplasy. Myotis is found to be paraphyletic with M. daubentonii more closely related to vespertilionines rather than other species of Myotis. The recognized tribes of vespertilionines are not well supported and the two molossids (Chaerephon and Austronomus) are nested within Pipistrellini along with Barbastella (a plecotin) and Scotoecus (a nycticein). These results are perhaps not surprising given the overall very similar morphology of most vespertilionoid dentitions.

The importance of this analysis for the purposes of this paper lies in the consistent linkage of Myotis belgicus to Myotis myotis to the exclusion of all other taxa. This is compelling support for including the new Boutersem species in the genus Myotis. The analysis also serves to confirm the likelihood that Quinetia is closely related to living plecotine vespertilionids and should be included in that subfamily as Horáček [18] had previously suggested.

Summary.

The evidence presented above favors an appearance of the modern genus Myotis at about 33.5 mya in Europe. As noted, this date is at odds with divergence dates obtained using molecular phylogenetic reconstructions [812]. However, the discrepancies between morphological and molecular divergence times have begun to converge as molecular dates have gotten older [812]. The morphological and molecular dates for the divergence of Myotis are now about 7–10 million years apart but it appears that, as more evidence is accumulated, this difference is slowly decreasing.

Ruedi et al. [12] favor a geographic origin of Myotis in eastern Asia, either from their Eastern Palearctic or Oriental bioregions (see their Fig 3). Interestingly, these regions contain what would have been the northern shoreline of eastern Tethys during the Oligocene so perhaps, even the biogeographic region of origin supported by fossils and molecules is not so far apart either.

The fossil evidence favors an origination of basal myotines in North Africa in the later Eocene [2] followed shortly thereafter by the appearance of Myotis in the early Oligocene of Europe at Boutersem and Hoogbutsel. Additionally, the occurrence of Quinetia, a basal plecotin vespertilionine, at Boutersem provides corroborating evidence that the vespertilionid subfamilies Vespertilioninae and Myotinae had already diverged by 33.5 mya making the early occurrence of Myotis not especially surprising. Corroborating support of this hypothesis may be found in the presence of a bat from Prémontré in France [59] dated to 50 mya and potentially representing the earliest member of Vespertilionidae. Fossil evidence is now converging on a minimum divergence time of the family Vespertilionidae at ~ 50 mya and the divergence of Myotinae and Vespertilioninae by ~35–40 mya.

Nonetheless, it is true that Myotis species are very primitive bats (at least viewed in the light of what is now understood about chiropteran evolutionary trajectories [5051]) and finding shared apomorphies between the fossil species from Belgium and recent species is very difficult (a common problem in paleontology). Despite this, based on the known evidence, it is not possible to exclude the Boutersem taxon from Myotis nor is it possible to identify any other extant vespertilionid that these specimens more closely resemble.

Bat adaptive radiation

The presence of Myotis at 33.5 Ma in Belgium not only opens up questions about the phyletic and geographic origins of Myotinae but, in conjunction with other early occurrences of species representing extant bat genera (see below), also suggests that the early radiation of modern bats was fundamentally different from other mammalian orders.

The earliest Eocene (55.8 Ma) was a time of dramatic change in global mammalian communities as archaic Paleocene assemblages were replaced by a much more cosmopolitan and more modern communities consisting of early ancestors of many modern orders [6061]. It has been well established based on molecular evidence [55, 6263] that archaic bats must have partaken in this great rearrangement of communities [64] in conjunction with the Paleocene-Eocene Thermal Maximum (PETM) but to date no fossil bats have been found from deposits documenting the PETM. Therefore, it appears that the radiation of modern bats post-dates the PETM [55] and was more coincident with the onset and duration of the Early Eocene Climatic Optimum (52–50 Ma [59]).

As fossil evidence from the Eocene has slowly been accumulating it has begun to tell a similar tale to that of molecular evidence. Archaic bats begin to appear in the early Eocene fossil records of both the Old and New Worlds [50] but as yet there are no fossil bats present in earliest Eocene faunal assemblages [50]). Modern crown-group bat families begin to appear in the later part of the early Eocene (Fig 6A) [51, 6566].

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Fig 6. Bat global first appearance.

(a) First appearance in the global fossil record of extant bat vs. other placental mammal families and genera from the Early Eocene through the Early Miocene. Compilation includes 15 families (75% of all extant families) and 14 genera of bats and 56 families (64% of all extant families) and 20 genera of other placentals (modified from McKenna and Bell [67], see S3 File). (b) Estimated molecular divergence times (black line) versus global fossil first appearances (red line) of extant bat families (molecular dates based on Teeling et al. [55] with modifications from Amador et al. [52], fossil first appearance data modified from S3 File). Families in the green box are exclusively New World in distribution today, families in the blue box are exclusively Old World, and the three families in the purple box are cosmopolitan but have Old World origins.

https://doi.org/10.1371/journal.pone.0172621.g006

By the middle Eocene a fundamental difference between bats and other placentals begins to become apparent. Modern bat genera begin to appear throughout the middle and late Eocene into the early Oligocene. Virtually no other mammalian group shows such early occurrences of species representing modern genera (except for a single enigmatic record of the genus Tarsius from the middle Eocene of China) with the earliest appearances of other living placental genera not occurring until the late Oligocene (Fig 6A).

A closer examination of which extant bat genera begin to appear early in the record reveals the presence of Hipposideros in the middle Eocene [51, 66, 6869], Rhinolophus and Tadarida in the late Eocene [6768, 70], Myotis in the early Oligocene (this paper) and Megaderma and Mormopterus in the late Oligocene [45, 7172]. The presence in the Old World of two of the four major clades of echolocating bats (Rhinolophoidea and Vespertilionoidea) demonstrates that modern family level diversity has already begun to be established in the Paleogene with rhinolophoid families Hipposideridae, Megadermatidae and Rhinolophidae and vespertilionoid families Vespertilionidae and Molossidae being represented by species belonging to extant genera by that time.

While it is not possible to be absolutely certain that fossil Hipposideros species were filling the same adaptive roles as modern Hipposideros species, given the extremely similar morphology shared by each (as far as is known) it seems that it is logical to assume that they were. Today Hipposideros and Rhinolophus possess a sophisticated echolocation system (high duty cycle, constant frequency) that allows them to exploit cluttered and complex habitats often very near to the ground [7374]. A similar style of habitat exploitation can be hypothesized for early fossil representatives of these taxa. Evidence from a fossil hipposiderid, Tanzanycteris, from the middle Eocene of Africa indicates, based on the presence of greatly enlarged cochlea, that this bat was already utilizing a similar echolocation system to modern hipposiderids [75].

If a similar rationale can be applied to other early appearing species of crown-group bat genera then the following can be noted (based on summaries from Nowak [73]): fossil Tadarida and Mormopterus species were probably rapid, relatively high flyers that hunted in open areas and may have lived in large colonies (especially Tadarida); fossil Megaderma species likely exploited habitats near the ground and may have preyed on small vertebrates as well as insects and roosted in small groups; fossil Myotis may have occupied a wide variety of habitats as living species do, were probably fairly fast and moderately high flyers that exploited areas over ponds and water courses in search of flying insects. Myotis typically roosts in caves today but may also roost in trees and rock hollows and depending on the season, may roost in rather large groups.

Fig 6B compares predicted molecular divergence times of bat families with fossil first appearances (FADs) and highlights an important geographical component of the bat adaptive radiation. Virtually all of the families where molecular divergences and morphological first appearances are nearly congruent are found in the Old World or among cosmopolitan groups that were first established in the Old World. Those families that have widely differing times of divergence and first appearances are almost exclusively New World taxa, taxa with extremely under-represented fossil records (Pteropodidae, Miniopteridae) or taxa of low extant diversity (Mystacinidae, Craseonycteridae, Nycteridae, Myzopodidae).

The probable reasons for the lack of congruence between molecular divergence times and morphological first appearances for New World bat clades are two-fold–the lack of a decent post-Mesozoic fossil record prior to the Late Miocene in South and Central America and the potential later arrival of ancestral noctilionoids into the New World [47]. If ancestral noctilionoids did not reach the New World until the latest Eocene or early Oligocene this could help to explain a second explosive adaptive radiation of bats (best typified by Phyllostomidae) in the New World in the Miocene [76].

It is becoming increasingly clearer that the geographic origins of crown-group Chiroptera are centered in the circum-Tethys region [50, 66] (Fig 7). The earliest known records of confirmed bats come from Europe, India, North Africa and Australia from localities all dating to around 53–54 mya [50, 65, 7778] but all of these represent archaic bat groups that have no clear phylogenetic connections with modern taxa. Modern families followed almost immediately by some modern genera of bats began to appear in the Old World in the late early to middle Eocene of Europe and North Africa [66]. The appearance of extant generic level taxa representing differentiated clades within Rhinolophoidea and Vespertilionoidea so early in the Paleogene is evidence of rapid diversification and suggests that the adaptive roles played by species within these genera were established very early and seemingly continue to the present day.

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Fig 7. Proposed trajectory of bat evolutionary history.

Light-filled tapered rectangle represents the archaic bat radiation beginning near the Paleocene-Eocene boundary and ending at the beginning of the Oligocene, coincident with drop in global temperatures. Dark-filled tapered rectangles represent modern bat adaptive radiations, one in the Old World coincident with the Early Eocene Climatic Optimum and a second one in the New World coincident with the Mid-Miocene Climatic Optimum. Paleotemperature curve in blue with black stars indicating PETM (Paleocene-Eocene Thermal Maximum), EECO (Early Eocene Climatic Optimum), the Grande Coupure, LOW (Late Oligocene Warming Event), and the MMCO (Mid-Miocene Climatic Optimum. Red lines indicate range of selected modern genera of bats, red oval on Old World map indicates probable area where both archaic and modern bats first arose, and red arrows on circum-southern oceanic area indicates the probable origin and route taken by ancestral noctilionoids to reach the New World [47].

https://doi.org/10.1371/journal.pone.0172621.g007

Conclusions

Bat evolutionary history as now understood (Fig 7) can be best visualized as consisting of the following phases: 1) an Old World early archaic phase centered around the ancient Tethys Sea wherein early bats develop many defining characteristics (flight, echolocation, roosting behavior) either from an ancestry in the New World (North American Onychonycteris and Icaronycteris [3,50]) or from in situ origination near Tethys region [50]; 2) an Eocene rapid adaptive radiation of crown-group bat taxa in the Old World coincident with the onset of the Early Eocene Climatic Optimum wherein bats undergo rapid diversification into night flying, insect predating forms while developing modifications of flight and echolocating abilities in order to fully exploit an aerial hawking life-style [59, 7980]–it is during this radiation that within-community niches apparently were established and were begun to be occupied by species of extant genera in the Old World; and 3) a second rapid diversification of noctilionoids, coincident with the Mid-Miocene Climatic Optimum, after their ancestors arrived in the New World in the latest Eocene or early Oligocene [8182]. This New World radiation produced a remarkable taxonomic diversity as well as broad morphological disparity across an array of dietary specializations (fruit eaters, nectar feeders, insect specialists of many kinds, blood consuming vampires, and animal and invertebrate consuming specialists) among noctilionoids bats, especially Phyllostomidae [1, 76, 8384]. In both the Old World and the New World after the initial establishment of extant bat families in the Eocene and Miocene respectively, these communities rapidly diversified and apparently remained relatively stable throughout the course of the rest of the Cenozoic.

Supporting information

S1 File. Taxon-character matrix utilized in phylogenetic analysis in TNT format.

https://doi.org/10.1371/journal.pone.0172621.s001

(TNT)

S2 File. Taxon-character matrix utilized in phylogenetic analysis in NEXUS format.

https://doi.org/10.1371/journal.pone.0172621.s002

(NEX)

S3 File. First appearance data of placental mammals in the fossil record.

https://doi.org/10.1371/journal.pone.0172621.s003

(XLSX)

S1 Table. List of comparative specimens used during this study.

https://doi.org/10.1371/journal.pone.0172621.s004

(DOCX)

S2 Table. Classification of species employed in phylogenetic analysis.

https://doi.org/10.1371/journal.pone.0172621.s005

(DOCX)

Acknowledgments

We thank Annelise Folie, Wim Wouters, and Wim Van Neer (Royal Belgian Institute of Natural Sciences, Brussels), for giving access to comparative material, providing casts, and pictures or discussions about fossil bats. We thank Philip Myers and Priscilla Tucker (University of Michigan Museum of Zoology, Ann Arbor), Nancy B. Simmons and Eileen Westwig (American Museum of Natural History, New York) and Gerhard Storch, Irina Ruf and Katrin Krohmann (Senckenberg Forschungsinstitut, Frankfurt am Main) for access to extant bat specimens. SEM pictures were made at RBINS by Julien Cillis and Eric De Bast. Floréal Solé was instrumental in performing the phylogenetic analyses. We also thank two anonymous reviewers who improved the content of this paper. This research was funded by project BR/121/A3/PALEURAFRICA of the Federal Science Policy Office of Belgium. This is Duke Lemur Center Publication 1341.

Author Contributions

  1. Conceptualization: GFG TS RS.
  2. Data curation: GFG TS RS.
  3. Formal analysis: GFG TS.
  4. Funding acquisition: TS GFG.
  5. Investigation: GFG TS RS.
  6. Methodology: GFG TS RS.
  7. Project administration: GFG TS RS.
  8. Resources: RS.
  9. Supervision: GFG TS RS.
  10. Validation: GFG TS RS.
  11. Visualization: GFG TS RS.
  12. Writing – original draft: GFG TS RS.
  13. Writing – review & editing: GFG TS RS.

References

  1. 1. Simmons NB. Order Chiroptera. In: Wilson DE, Reeder DM, editors. Mammal species of the world, a taxonomic and geographic reference, 3rd Edition. Baltimore: The Johns Hopkins University Press; 2005. Pp. 312–529.
  2. 2. Gunnell GF, Eiting EP, Simons EL. African Vespertilionoidea (Chiroptera) and the antiquity of Myotinae. In: Gunnell GF, Simmons NB, editors. Evolutionary History of Bats–Fossils, Molecules and Morphology. Cambridge: Cambridge University Press; 2012. pp. 252–266.
  3. 3. Simmons NB, Seymour KL, Habersetzer J, Gunnell GF. Primitive early Eocene bat from Wyoming and the evolution of flight and echolocation. Nature. 2008; 451: 818–822. pmid:18270539
  4. 4. Tate GHH. A review of the genus Myotis (Chiroptera) of Eurasia, with special reference to species occurring in the East Indies. (Results of the Archbold Expeditions, No. 39). Bull Am Mus Nat Hist. 1941; 78: 537–565.
  5. 5. Findley JS. Phenetic relationships among bats of the genus Myotis. Syst Zool. 1972; 21: 31–52.
  6. 6. Koopman KF. Order Chiroptera. In: Wilson DE, Reeder DM, editors. Mammal species of the world, a taxonomic and geographic reference, 2nd Edition. Washington, DC: Smithsonian Institution Press; 1993. Pp. 137–241.
  7. 7. Ruedi M, Mayer F. Molecular systematics of bats of the genus Myotis (Vespertilionidae) suggests deterministic ecomorphological convergences. Mol Phylogenet Evol. 2001; 21: 436–448. pmid:11741385
  8. 8. Stadelmann B, Herrera G, Arroyo-Cabrales J, Ruedi M. Molecular systematics of the piscivorous bat Myotis (Pizonyx) vivesi. J Mammal. 2004; 85: 133–139.
  9. 9. Stadelmann B, Jacobs D, Schoeman C, Ruedi M. Phylogeny of African Myotis bats (Chiroptera, Vespertilionidae) inferred from cytochrome b sequences. Acta Chiropterol. 2004; 6: 177–192.
  10. 10. Stadelmann B, Kunz TH, Lin LK, Ruedi M. Molecular phylogeny of New World Myotis (Chiroptera, Vespertilionidae) inferred from mitochondrial and nuclear DNA genes. Mol Phylogenet Evol. 2007; 43: 32–48. pmid:17049280
  11. 11. Lack JB, Roehrs ZP, Stanley CE Jr, Ruedi M, Van den Bussche RA. Molecular phylogenetics of Myotis indicate familial-level divergence for the genus Cistugo (Chiroptera). J Mammal. 2007; 91: 976–992.
  12. 12. Ruedi M, Stadelmann B, Gager Y, Douzery EJP, Francis CM, Lin L-K, et al. Molecular phylogenetic reconstructions identify East Asia as the cradle for the evolution of the cosmopolitan genus Myotis (Mammalia, Chiroptera). Mol Phylogenet Evol. 2013; 69: 437–449. pmid:23988307
  13. 13. Ghazali M, Moratelli R, Dzeverin I. Ecomorph evolution in Myotis (Vespertilionidae, Chiroptera). J Mammal Evol. 2016;
  14. 14. Kowalski K. Insectivores, bats and rodents from the early Pleistocene bone breccia of Podlesice near Kroczyce (Poland). Acta Palaeontol Pol. 1956; 1: 331–393.
  15. 15. Kowalski K. Fauna of bats from the Pliocene of Węże in Poland. Acta Zool Cracov. 1962; 7: 39–51.
  16. 16. Storch G. Order Chiroptera. In: Rossner GE, Heissig K, editors. The Miocene Land Mammals of Europe. München: Friedich Pfeil; 1999. Pp. 81–90.
  17. 17. Horáček I. Přehled kvartérnich netopýrů (Chiroptera) Československa (Review of Quaternary bats in Czechoslovakia, In Czech). Lynx (Praha). 1976; 18: 35–59.
  18. 18. Horáček I. On the early history of vespertilionid bats in Europe: the Lower Miocene record from the Bohemian Massif. Lynx (Praha). 2001; 32: 123–154.
  19. 19. Ziegler R. Die Chiroptera (Mammalia) aus dem Untermiozän von Wintershof-West bei Eichstätt (Bayern). Mitt. Bayer. Staatssaml Paläontol hist Geol. 1993; 33: 119–154.
  20. 20. Ziegler R. Die Chiroptera (Mammalia) aus dem Untermiozän von Stubersheim 3 (Baden-Württemberg). Münchner Geowiss Abh. 1994; 26: 97–116.
  21. 21. Ziegler R. Bats (Chiroptera, Mammalia) from Middle Miocene karstic fissure fillings of Petersbuch near Eichstätt, Southern Franconian Alb (Bavaria). Geobios. 2003; 36: 447–490.
  22. 22. Guilday JE, Hamilton HW, McCrady AD. The Pleistocene vertebrate fauna of Robinson Cave, Overton County, Tennessee. Palaeovertebrata. 1969; 2: 25–75.
  23. 23. Martin RA. Synopsis of late Pliocene and Pleistocene bats of North America and the Antilles. Am Mid Nat. 1972; 87: 326–335.
  24. 24. Butler PM. Insectivora and Chiroptera. In: Maglio VJ, Cooke HBS, editors. Evolution of African Mammals. Cambridge: Harvard University Press; 1978. Pp 56–68.
  25. 25. Morgan GS. Fossil bats (Mammalia: Chiroptera) from the late Pleistocene and Holocene Vero Fauna, Indian River County, Florida. Brimleyana. 1985; 11: 97–117.
  26. 26. Morgan GS. Neotropical Chiroptera from the Pliocene and Pleistocene of Florida. Bull Am Mus Nat Hist. 1991; 206: 176–213.
  27. 27. Morgan GS. Late Rancholabrean mammals from southernmost Florida, and the Neotropical influence in Florida Pleistocene faunas. Smithson Contrib Paleobiol. 2002; 93: 15–38.
  28. 28. Czaplewski NJ. Middle Blancan vertebrate assemblage from the Verde Formation, Arizona. Contrib Geol Univ Wyo. 1987; 25: 133–155.
  29. 29. Czaplewski NJ. Miocene bats from the lower Valentine Formation of northeastern Nebraska. J Mammal. 1991; 72: 715–722.
  30. 30. Czaplewski NJ. Late Tertiary bats (Mammalia, Chiroptera) from the southwestern United States. Southwest Nat. 1993; 38: 111–118.
  31. 31. Yoon MH, Kuramoto T, Uchida TA. Studies of Middle Pleistocene bats including Pleistomyotis gen. et sp. nov. and two new extinct Myotis species from the Akiyoshi-dai Plateau. Bull Akiyoshi-dai Mus Nat Hist. 1984; 19: 15–26.
  32. 32. Qiu Z, Storch G. The early Pliocene micromammalian fauna of Bilike, Inner Mongolia, China (Mammalia: Lipotyphla, Chiroptera, Rodentia, Lagomorpha). Senck lethaia. 2000; 80: 173–229.
  33. 33. Samonds KE. Late Pleistocene bat fossils from Anjohibe Cave, northwestern Madagascar. Acta Chiropterol. 2007; 9: 39–65.
  34. 34. Gunnell GF. Chiroptera. In: Werdelin L, Sanders WJ, editors. Cenozoic Mammals of Africa. Berkeley: University of California Press; 2010. Pp. 581–597.
  35. 35. Gunnell GF, Eiting TP, Geraads D. New late Pliocene bats (Chiroptera) from Ahl al Oughlam, Morocco. N Jb Geol Palaont. 2011; 260: 55–71.
  36. 36. Glibert M, de Heinzelin de Braucourt J. Le gîte des vertébrés tongriens de Hoogbutsel. Bull Inst R Sc N B-S. 1952; 28: 1–22.
  37. 37. Smith R. Les vertébrés terrestres de l'Oligocène inférieur de Belgique (Formation de Borgloon, MP 21): inventaire et interprétation des données actuelles. In: Lopez-Martinez N, Pelaez-Campomanez P, Hernandez Fernandez M, editors. En torno a Fósiles de Mamíferos: Datación, Evolución y Paleoambiente, Coloquios de Paleontologia, Volumen Extraordinario en homenaje al Dr. Remmert Daams. 2003; 1: 647–657.
  38. 38. Smith R. Insectivores (Mammalia) from the earliest Oligocene (MP 21) Belgium. Neth J Geosci. 2004; 83: 187–192.
  39. 39. Smith R. Le genre Euronyctia (Nyctitheriidae, Mammalia) en Europe Occidentale. Strata. 2006; 13: 229–241.
  40. 40. Smith R. Présence du genre Eotalpa (Mammalia, Talpidae) dans l’Oligocene inférieur de Belgique (Formation de Borgloon, MP 21). Bull Inst R Sc N B-S. 2007; 77: 159–165.
  41. 41. Smith R, Smith T. The carnivoran-like insectivore Butselia biveri Quinet & Misonne, 1965 (Mammalia, Plesiosoricidae) from the lowermost Oligocene of Europe. Span J Palaeontol. 2012; 27: 105–116.
  42. 42. Smith R, van den Hoek Ostende LW. A new heterosoricid shrew from the lowermost Oligocene of Europe. Acta Palaeontol Pol. 2006; 51: 381–384.
  43. 43. Vandenberghe N, Hilgen FJ, Speijer RP. The Paleogene Period. In: Gradstein FM, Ogg JG, Schmitz M, Ogg G, editors. The Geologic Time Scale, 1st Edition. Amsterdam: Elsevier BV; 2012. Pp. 855–921.
  44. 44. BiochronM’97. Synthèses et tableaux de corrélations / Syntheses and correlation tables. In: Aguilar J-P, Legendre S, Michaux J, editors. Actes du Congrès BiochroM’97. Mém Trav l’Inst Montpellier, Ecole Prat Hautes Etudes, Sc Vie Ter. 1997; 21: 769–805.
  45. 45. Ziegler R. The bats (Chiroptera, Mammalia) from the Late Oligocene fissure fillings Herrlingen 8 and Herrlingen 9 near Ulm (Baden-Wurttemberg). Senck lethaia. 2000; 80: 647–683.
  46. 46. Gunnell GF, Simons EL, Seiffert ER. New bats (Mammalia: Chiroptera) from the late Eocene and early Oligocene, Fayum Depression, Egypt. J Vertebr Paleontol. 2008; 28: 1–11.
  47. 47. Gunnell GF, Simmons NB, Seiffert ER. New Myzopodidae (Chiroptera) from the Late Paleogene of Egypt: Emended family diagnosis and biogeographic origins of Noctilionoidea. PLoS One e86712. 2014; pmid:24504061
  48. 48. Legendre S, Rich THV, Rich PV, Knox GJ, Punyaprasiddhi P, Trumpy DM, et al. Miocene fossil vertebrates from the Nong Hen-I (A) exploration well of Thai Shell Exploration and Production Company Limited, Phitsanulok Basin, Thailand. J Vertebr Paleontol. 1988; 8: 278–289.
  49. 49. Czaplewski N. Bats (Mammalia: Chiroptera) from Gran Barranca (early Miocene, Colhuehuapian), Chubut Province, Argentina. In: Madden RH, Carlini AA, Vucetich MG, Kay RF, editors. The Paleontology of Gran Barranca: Evolution and Environmental Change through the Middle Cenozoic of Patagonia. Cambridge: Cambridge University Press; 2010. Pp. 240–252.
  50. 50. Smith T, Habersetzer J, Simmons NB, Gunnell GF. Systematics and paleobiogeography of early bats. In: Gunnell GF, Simmons NB, editors. Evolutionary History of Bats–Fossils, Molecules and Morphology. Cambridge: Cambridge University Press; 2012. Pp. 23–66.
  51. 51. Maitre E. Western European middle Eocene to early Oligocene Chiroptera: systematics, phylogeny and palaeoecology based on new material from the Quercy (France). Swiss J Palaeontol. 2014; 133: 141–242.
  52. 52. Amador LI, Moyers Arévalo RL, Almeida FC, Catalano SA, Giannini NP. Bat systematics in the light of unconstrained analyses of a comprehensive molecular supermatrix. J Mammal Evol. 2016;
  53. 53. Quinet GE. Myotis misonnei n. sp., Chiroptère de l’Oligocène de Hoogbutsel. Bull Inst Roy Sci Natur Belgique. 1965; 41: 1–11.
  54. 54. O'Leary MA, Kaufman SG. MorphoBank 3.0: Web application for morphological phylogenetics and taxonomy. 2012; Available from: http://www.morphobank.org.
  55. 55. Teeling EC, Springer MS, Madsen O, Bates P, O’Brien SJ, Murphy WJ. A molecular phylogeny for bats illuminates biogeography and the fossil record. Science. 2005; 307: 580–585. pmid:15681385
  56. 56. Goloboff PA, Catalano S. TNT version 1.5, including a full implementation of phylogenetic morphometrics. Cladistics. 2016; 32: 221–238.
  57. 57. Spaulding M, Flynn JJ. Phylogeny of the Carnivoramorpha: the impact of postcranial characters. J Syst Palaeontol. 2012; 10: 653–677.
  58. 58. Hoofer R, Van Den Bussche RA. Molecular phylogenetics of the chiropteran family Vespertilionidae. Acta Chiropterol. 2003; 5 (supplement): 1–63.
  59. 59. Hand SJ, Sigé B, Archer M, Black KH. An evening bat (Chiroptera: Vespertilionidae) from the late early Eocene of France, with comments on the antiquity of modern bats. Palaeovertebrata. 2016;
  60. 60. Gingerich PD. Environment and evolution through the Paleocene-Eocene thermal maximum. Trends Ecol Evol. 2006; 21: 246–253. pmid:16697910
  61. 61. Gingerich PD, Clyde WC. Overview of mammalian biostratigraphy in the Paleocene-Eocene Fort Union and Willwood Formations of the Bighorn and Clarks Fork Basins. In: Gingerich PD, editor. Palaeocene-Eocene Stratigraphy and Biotic Change in the Bighorn and Clarks Fork Basin, Wyoming, Univ Mich Pap Paleontol. 2001; 33: 1–14.
  62. 62. Eick GN, Jacobs DS, Matthee CA. A nuclear DNA phylogenetic perspective on the evolution of echolocation and historical biogeography of extant bats (Chiroptera). Mol Biol Evol. 2005; 22: 1869–1886. pmid:15930153
  63. 63. Miller-Butterworth CM, Murphy WJ, O’Brien SJ, Jacobs DS, Springer MS, Teeling EC. A family matter: conclusive resolution of the taxonomic position of the long-fingered bats, Miniopterus. Mol Biol Evol. 2007; 24: 1553–1561. pmid:17449895
  64. 64. Simmons NB. An Eocene big bang for bats. Science. 2005; 307: 527–528. pmid:15681371
  65. 65. Ravel A, Marivaux L, Tabuce R, Adaci M, Mahboubi M, Mebrouk F, et al. The oldest African bat from the early Eocene of El Kohol (Algeria). Naturwissenschaften. 2011; 98: 397–405. pmid:21442243
  66. 66. Ravel A, Adaci M, Bensalah M, Charruault A-L, Essid EM, Ammar HK, et al. Origine et radiation initiale des chauves-souris modernes: nouvelles découvertes dans l’Éocène d’Afrique du Nord. Geodiversitas. 2016; 38: 355–434.
  67. 67. McKenna MC, Bell SK. Classification of Mammals Above the Species Level. New York: Columbia University Press; 1997.
  68. 68. Revilliod P. Contribution a l’étude des Chiroptères des terrains Tertiaires. Troisième partie et fin. Mem Soc Paleontolog Suisse. 1922; 45: 133–195.
  69. 69. Sigé B. Le gisement du Bretou (Phosphorites du Quercy, Tarn-et-Garonne, France) et sa faune de vertébrés de l’Eocène supérieur. IV. Insectivores et Chiroptères. Palaeontogr Abt A. 1988; 205: 69–102.
  70. 70. Bonis L. de, Crochet J-Y, Rage J-C, Sigé B, Sudre J, Vianey-Liaud M. Nouvelles faunes de Vertébrés oligocènes des phosphorites du Quercy. Bull Mus Hist Nat Paris. 1973; 174: 105–113.
  71. 71. Legendre S. Identification de deux sous-genres fossiles et compréhension phylogénique du genre Mormopterus (Molossidae, Chiroptera). C R Acad Sci Paris. 1984; 298: 715–720.
  72. 72. Sevilla P. Rhinolophoidea (Chiroptera, Mammalia) from the upper Oligocene of Carrascosa del Campo (Central Spain). Geobios. 1990; 23: 173–188.
  73. 73. Nowak RM. Walker’s Bats of the World. Baltimore: The Johns Hopkins University Press; 1994.
  74. 74. Jones G, Teeling EC. The evolution of echolocation in bats. Trends Ecol Evol. 2006; 21: 149–156. pmid:16701491
  75. 75. Gunnell GF, Jacobs BF, Herendeen PS, Head JJ, Kowalski E, Msuya CP, et al. Oldest placental mammal from sub-Saharan Africa: Eocene microbat from Tanzania–Evidence for early evolution of sophisticated echolocation. Palaeontol Electron 2002; 5: 10 p.
  76. 76. Rojas D, Warsi OM, Dávalos LM. Bats (Chiroptera: Noctilionoidea) challenge a recent origin of extant Neotropical diversity. Syst Biol. 2016; 65: 432–448. pmid:26865275
  77. 77. Hand SJ, Novacek M, Godthelp H, Archer M. First Eocene bat from Australia. J Vertebr Paleontol. 1994; 14: 375–381.
  78. 78. Smith T, Rana RS, Missiaen P, Rose KD, Sahni A, Singh H, et al. High bat (Chiroptera) diversity in the Early Eocene of India. Naturwissenschaften. 2007; 94: 1003–1009. pmid:17671774
  79. 79. Habersetzer J, Storch G. Klassifikation und funktionelle Flügelmorphologie paläogener Fledermäuse (Mammalia, Chiroptera). Cour Forsch Senck. 1987; 91: 117–150.
  80. 80. Simmons NB, Geisler JH. 1998. Phylogenetic relationships of Icaronycteris, Archaeonycteris, Hassianycteris, and Palaeochiropteryx to extant bat lineages, with comments on the evolution of echolocation and foraging strategies in Microchiroptera. Bull Am Mus Nat Hist. 1998; 235: 1–182.
  81. 81. Czaplewski NJ, Morgan GS. New basal noctilionoid bats (Mammalia: Chiroptera) from the Oligocene of subtropical North America. In: Gunnell GF, Simmons NB, editors. Evolutionary History of Bats: Fossils, Molecules and Morphology. Cambridge: Cambridge University Press; 2012. Pp. 162–209.
  82. 82. Morgan GS, Czaplewski NJ. Evolutionary history of the Neotropical Chiroptera: the fossil record. In: Gunnell GF, Simmons NB, editors. Evolutionary History of Bats: Fossils, Molecules and Morphology. Cambridge: Cambridge University Press; 2012. Pp. 105–161.
  83. 83. Dumont ER, Dávalos LM, Goldberg A, Santana SE, Rex K, Voigt CC. Morphological innovation, diversification and invasion of a new adaptive zone. Proc R Soc B. 2012; 279: 1797–1805. pmid:22113035
  84. 84. Cirranello A, Simmons NB, Solari S, Baker RJ. Morphological diagnoses of higher-level phyllostomid taxa (Chiroptera: Phyllostomidae). Acta Chiropterol. 2016; 18: 39–71.