Abstract
A fossil palpigrade is described and figured from mid-Cretaceous (Cenomanian) amber from northern Myanmar. Electrokoenenia yaksha Engel and Huang, gen. n. et sp. n., is the first Mesozoic fossil of its order and the only one known as an inclusion in amber, the only other fossil being a series of individuals encased in Pliocene onyx marble and 94–97 million years younger than E. yaksha. The genus is distinguished from other members of the order but is remarkably consistent in observable morphological details when compared to extant relatives, likely reflecting a consistent microhabitat and biological preferences over the last 100 million years.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Among arachnid orders, the one with the least available information regarding their fossil history is the Palpigradi, sometimes known as the microwhip scorpions. This group of truly minute chelicerates, ranging in size from approximately 1–3 mm, has been investigated rather little since their first discovery and description by Grassi and Calandruccio in 1885 (Grassi and Calandruccio 1885; Grassi 1886). Today, nearly 90 species have been documented, and very little information is available regarding refined specifics of their biology, although the fascinating account of the troglobitic Eukoenenia spelaea (Peyerimhoff 1902) feeding on heterotrophic cyanobacteria (Smrž et al. 2013) is in contrast to the prevalence of predatory behavior among most non-acarine arachnids (Beccaloni 2009: prominent detritivorous and herbivorous lineages are present among mites (e.g., Walter and Proctor 1999). A considerable amount of basic natural history information is needed for palpigrades, to ascertain the generality of cyanobacterial feeding and other details of their biology.
Understandable for a group with individuals of such diminutive proportions, fossils have not been forthcoming in abundance. Indeed, it takes special modes of preservation in order to preserve with sufficient fidelity the fine details of such a small-bodied arthropod. Remarkably, a rather coarsely preserved compression from the Jurassic Solnhofen Lagerstätte was for a long while considered to be a primitive member of the order. The genus Sternarthron Haase 1890a was originally described as a large, primitive arachnid putatively among the Palpigadi (Haase 1890a, b), a placement rather quickly called into question by Handlirsch (1906) but still adopted by various researchers (e.g., Petrunkevitch 1949, 1955; Crowson et al. 1967; Savory 1971, 1974; Rowland and Sissom 1980). Among more current authors, the palpigrade affinities of Sternarthron have similarly been questioned (e.g., Carpenter 1992; Harvey 2003), and in fact, Sternarthron zitteli Haase represents the nymphal stage of Chresmoda obscura Germar 1839 (Orthopterida: Chresmododea) (see Delclòs et al. 2008, who also more extensively review the history and literature on Sternarthron). The only other fossil attributed to the order, and the only one correctly placed therein, has been Paleokoenenia mordax Rowland and Sissom 1980, represented by a series of individuals preserved in Pliocene lithified travertine from the Onyx marble formation (Rowland and Sissom 1980).
During recent investigations into the diversity of arthropods preserved as inclusions in Burmese amber, a single individual of a minute palpigrade was discovered situated within an internal fracture plane of a much larger piece with inclusions. This individual is the sole fossil of the order from the Mesozoic and predates all previous fossil palpigrades by more than 94–97 million years. This significant find prompted a brief description of the fossil despite the inability to observe several anatomical details, and as the first pre-Neogene representative of its order.
Material and methods
The single individual was located in a larger piece of amber and lying within a small, internal fracture which reflected much light making it difficult to see the specimen which was easy to overlook. The palpigrade was isolated from the remainder of the block and prepared into a thin, square chip of amber of a couple of millimeter thickness and of approximately 5.3-mm length and width, and was stabilized in a surrounding disc of epoxy. After preparation the amber piece was then suitable for examination under the compound microscope with both transmitted and reflected light, and utilizing an Olympus SZX-12 stereomicroscope and BX-41 compound microscope. We also employed confocal laser scanning microscopy (CLSM) using a Zeiss LSM 710 with 10× objectives and using a laser at 488 nm. In spite of the preparation, the fine fractures in the amber surrounding the inclusion as well as the placement of additional organic matter and small layers of trapped air near the integument in some places (Figs. 1 and 3c) rendered finer details of some features such as chaetotaxy difficult to see, and thereby limited comparisons with extant relatives. For some structures, a direct view was not possible, and so precise measurements were not obtainable, but relative proportions to other sclerites were attempted. Despite these setbacks, the significance of a 100-million-year-old palpigrade warranted documentation and description (Grimaldi and Engel 2007). The format and terminology for the description generally follow that of Rowland and Sissom (1980) and van der Hammen (1982). Following van der Hammen (1982), we have numbered body segments through the entire length of the body (rather than with separate numbering schemes within each tagma as used by Rowland and Sissom (1980)). Analogous to that partially employed by Engel and Grimaldi (2014), we have used a subscript annotation to indicate particular serial appendages (c, p, and 1–4 indicating chelicera, pedipalp, and walking legs 1–4, respectively), with Roman numerals distinguishing subdivisions within podites (e.g., “tarsomere3 II” denotes the second tarsomere of the third walking leg). Condé (1996), Harvey (2003), and Prendini (2011) have summarized the current classification of the order. The age, biotic diversity, and composition of Burmese amber have been reviewed by Grimaldi et al. (2002) and Shi et al. (2012). The nomenclatural acts established herein are registered under ZooBank LSID urn:lsid:zoobank.org:pub:3F5095F6-FFB7-4488-9F8D-5528F8CFB8A2.
Results
All authors contributed to the development of the project and text discussion; in addition, MSE discovered the fossil in the amber piece, and worked on the comparative analysis, descriptions, photography, and illustrations; DYH did initial amber sorting and preparation, and contributed to the descriptions, photography, and CLSM; LCVB and MA worked on imaging and illustrations; CYC contributed to initial amber sorting and preparation and CLSM; DA worked on extensive final preparation of the amber to make close observation possible.
Systematic paleontology
Order Palpigradi Thorell 1888
Family Eukoeneniidae Petrunkevitch 1955
Genus Electrokoenenia Engel and Huang, gen. n.
Type species Electrokoenenia yaksha Engel and Huang, sp. n.
Diagnosis
Propeltidium with anterodorsal cone, with anterolateral margins of propeltidium tapering gently away from cone to the widest point of carapace at about tangent of coxae1, then margins slightly constricted and tapering to posterior end; frontal organ rounded and U-shaped, with distinct concavity between rounded lateral “arms;” prosomal sterna exceedingly difficult to observe but apparently with only five sterna, apparent fused sterna II + III articulating with the coxae of anterior two pairs of walking legs broadest. Opisthosoma (segments VII–XVII) without ventral sacs and sterna without protuberances; segments XV–XVII (pygidial segments) tapering rapidly in width such that segment XVII is distinctly narrower than width of segment XV; segment XV distinctly wider than segment XVII, about 1.7× as wide as segment XVII, segment XV slightly narrower than segment XIV, segment XIV about 1.5× as wide as segment XV; setation of pygidial segments (XV–XVII) not discernible (possibly absent); flagellum only slightly shorter than opisthosoma, with 11 roughly moniliform articles, each flagellar article longer than wide (ranging from about 1.7–2.1 times as long as wide), not compact, those medially slightly more slender than those basally or apically, each flagellar article with apical whorl of several long, simple setae, individual setae longer than length of an individual article.
Etymology
The generic name is a combination of the prefix electro- (electrum, meaning, “amber,” and a reference to the discovery of the first amber-preserved palpigrade) and Koenenia Grassi and Calandruccio, first generic name in the order albeit preoccupied and thereby succeeded by Eukoenenia Börner. The gender of the name is feminine. The generic name is registered under LSID urn:lsid:zoobank.org:act:FF0A399D-52AB-4D00-A805-718F923B014E.
Electrokoenenia yaksha Engel and Huang, sp. n.
Holotype
Possible ♀ (Fig. 1; reconstruction in Fig. 2), NIGP 163253, Albian-Cenomanian boundary, Hukawng Valley, northern Myanmar; deposited in the Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China.
Diagnosis
As for the genus (vide supra).
Description
Generic features with the addition of the following: Total length (as preserved, from anteriormost point of prosoma to apex of flagellum) 1.47 mm; integument largely yellowish throughout (except where partly cleared postmortem), with imbricate to microgranulose sculpture; prosomal maximum width (at about apical one-third length) 0.13 mm; prosomal median length 0.35 mm; anterior of propeltidium tapering gently to anterior midpoint, with distinct anterodorsal cone; mesopeltidia not discernible; metapeltidium largely damaged over top of coxae4. Frontal organ present albeit scarcely visible, near apex of cone of propeltidium (Fig. 2), rounded U-shaped, about as long as wide (Fig. 2b), median concavity of “U” as wide apically as width of lateral “arm” of “U,” depth of concavity about one-half length of total organ length, width of organ about as wide as width of podite X of leg1; lateral organs not visible.
Appendages on left side damaged and largely missing except chelicera, pedipalp, and leg1 present. Chelate chelicera with proximal poditec long and slender, longer than chela (precise measurement not possible as there is no direct lateral view with the structure angled away from all accessible viewpoints); fixed chela poditec (i.e., secondary poditec inclusive of immoveable digit) length 0.13 mm, fixed chela body length excluding immoveable digit 0.08 mm, width 0.05 mm; apotele as long as immoveable digit (Figs. 3a, b, and 4b); immoveable digit with 12–13 long, slender teeth along nearly entire length, apotele with ten long slender teeth along entire length (Fig. 3b); surface setation of cheliceral podites not discernible.
Coxae of all appendages (except chelicera), medially separated by more than their width; coxap of pedipalp and leg1 each about 2.5 times as long as basal width, each tapering in width from base to apex (somewhat conical in appearance); coxa2 about 1.5 times as long as basal width, tapering slightly along length (with squat appearance); coxa3 and coxa4 about 2 times as long as basal width, faintly tapering along length (rather semi-cylindrical in appearance).
Pedipalp femurp much longer than wide; patellap cylindrical, slightly longer and narrower than tibiap, with at least one stiff seta at midlength and three near apex; tibiap slightly broader than patellap, with apical half appearing slightly swollen and basal half tapered, with at least a few scattered short setae in apical half; basitarsomerep I with tapered base, otherwise parallel-sided in apical three-quarters, distinctly narrower than tibiap, with at least four elongate, stiff setae visible (two near midlength, two near apex), slightly longer than basitarsomerep II; basitarsomeresp II and III subequal in length, cylindrical, as wide as basitarsomerep I, and with similar setation as on basitarsomerep I; tarsomerep I as wide as basitarsusp, about as long as basitarsomerep III, with at least one long setae near midlength and two near apex; tarsomerep II (apicalmost) more swollen than tarsomerep I, approximately 3.5 times longer than wide, longer than tarsomerep I (tarsomerep I about two-thirds length tarsomerep II), apically tapering to pretarsal claws (with fine, short seta just basad and between claws) (Fig. 4c), with at least three elongate lateral setae (one near base, one near midlength, one near apex), and two dorsal elongate setae, first slightly apicad level of midlength lateral seta, second at about level of apical lateral seta.
Leg1 distinctly longer than pedipalp, about as thick as pedipalpal podites. Trochanter4 about half as long as coxa4; femur4 long, longer than patella4, patella4 and more distal podites distinctly more slender than femur4; patella4 only slightly shorter than tibia4; basitarsus4 about three-quarters length of tibia4; tarsus4 divided into two tarsomeres, proximal tarsomere4 (tarsomere4 I) about two-thirds length of basitarsus4, subequal in length to apical tarsomere4 (tarsomere4 II); leg chaetotaxy difficult to discern, at least a few long setae at base of each podite from patella through apical tarsomere.
Opisthosoma elongate, largely parallel-sided and compressed (dorsoventrally) as preserved, length 0.63 mm, setae (where discernible) at apex of segments, short and simple; segments X, XI, and XII approximately equal in length and width, each about 0.16-mm wide, 0.08-mm long; segment IX similar to X but slightly narrower anteriorly and apparently slightly longer medially; segment VIII slightly narrower than IX and distinctly shorter, at most approximately three-quarters length of segment IX; segment XIII slightly shorter and narrower than segment XII; segments XIII and XIV distinctly tapering in width and length toward pygidial segments. Flagellum long, length 0.50 mm, individual flagellar articles each longer than wide, individual widths about 0.014 mm.
Etymology
The specific epithet is taken from South Asian mythology where the “yaksha” were nature spirits who held stewardship over the wonders hidden in the earth (such as the wonders of Burmese amber, recovered from their resting place in the earth). The name is treated as a noun in apposition. The species is registered under LSID urn:lsid:zoobank.org:act:4876BF69-92BC-424E-8B3B-BD4A1DEB12D1.
Discussion
The genus is superficially similar to the extant genus Leptokoenenia Condé 1965, known from five species in Saudi Arabia, the Republic of the Congo, northern Brazil, and Italy (Souza and Ferreira 2013), and both have rather rounded lateral “arms” to the frontal organ of the propeltidium, although other aspects of the form disagree (e.g., more of a broad concavity between these elements in the fossil). It differs most notably from Leptokoenenia by the more dramatic narrowing of the pygidial segments, and the more slender and long flagellar articles with fewer long setae (typically compact and wider than long and with dense setae in females of Leptokoenenia). The large number of elongate “teeth” on the chelicercal digits is distinctive for the genus. Typically, there are between seven and ten such serrations, and they are more tooth-like in form. In the fossil, these are more numerous on the immovable digit (at least 13 visible), while the apotele (moveable digit) bears ten. Moreover, these are elongated into stiff, spinelike structures that form a fine comb along the inner surfaces of each claw. Unfortunately, many of the finer details commonly compared among living palpigrades are simply not visible in the minute fossil (e.g., most chaetotaxy), either owing to its inclusion in the amber (and inability to make preparations closer to the integument or suitable for compound microscopic examination) or due to the nature of preservation (slightly desiccated, bordered by microscopic fractures, and positioned among other organic debris).
Not surprisingly, the morphology of these chelicerates has changed little over the last 100 million years, and although the fossil is considered generically distinct, the differences between the genera of eukoeneniids are rather subtle, with little anatomical disparity across the order. Most arachnid orders extend well into the Paleozoic and can in some groups exhibit similar degrees of conserved morphology over vast expanses of geological time (Dunlop 2010). Indeed, even many behaviors among arachnids are quite ancient, with well-documented occurrences in the Mesozoic (e.g., Engel and Grimaldi 2014). While certain chelicerates are hallmark examples of bradytely (e.g., Norton et al. 1988; Rudkin et al. 2008; Dunlop 2010; Sidorchuk et al. 2015), much of this conservatism remains unquantified. Such bradytely likely reflects a conserved and stable ecological niche for otherwise generalized organisms (versus a specialized niche which would undoubtedly be associated with concomitant specializations in the organisms occupying them and certainly would be so as those niches change over time, or even disappear!), much as was perceived by Simpson (1953). Indeed, such would seem to be the case for many groups that also appear to exhibit some degree of bradytely whereby each occurs in microhabitats (e.g., subcortical environments) that would be expected to be consistent over long periods of geological time (e.g., Hamilton 1978; Engel and Grimaldi 2002; Cognato and Grimaldi 2008; Chatzimanolis et al. 2013). Living within tropical soils and caves could be argued to fit into such a generalization and this may account for much of the perceived conserved morphology across the order and despite their clear antiquity based on phylogenetic position (Dunlop 2010; Garwood and Dunlop 2014), and now further witnessed by the current fossil, and that what disparity as does exist within the order reflects comparatively minor deviations and specializations. Fortunately, phylogenetic hypotheses are being developed at long last for the palpigrades (Giribet et al. 2014), and these should provide an ultimate framework from which to address some of the evolutionary questions, including bradytely, surrounding these tiny arachnids.
It is hoped that by bringing the discovery of this microscopic fossil to the attention of other researchers, further material might be discovered. Indeed, these tiny, soft-bodied arthropods may be overlooked easily, particularly if placed near other inclusions or debris, or if situated among fissures. The present specimen was at first not noticed owing to its placement among a series of reflective fractures, none of which extended far from the inclusion, in the center of a larger piece. In the unprepared amber piece, the palpigrade appeared only as a slightly darker, thick area at the center of a minute whorl of reflections, with none of the fissures coming near to other inclusions or the edges of the piece, and it was only after more careful examination that the palpigrade could be discerned. This prompted detailed preparation to isolate it from other inclusions that then made it largely observable as well as rendered its study possible. Such preparation will undoubtedly be necessary for any future specimens that are discovered. It is remarkable to consider the circumstances that lead to the entrapment of the current individual. As noted, palpigrades live interstitially in moist habitats such as tropical or subtropical soils or may be littoral, occurring along shores. Species are also found in cave environments and can be troglobitic. While the Burmese amber forest was certainly a moist tropical climate, there was nothing about the piece in which the palpigrade was discovered that suggested it represented a humus fauna, instead including several aerial insects such as small flies and wasps. This does not preclude extended contact near the forest floor or near the edge of water, but does make it more difficult to understand the taphonomic circumstances that lead to its capture and preservation. Regardless, preservation in amber is perhaps the only medium through which such minute animals could be adequately characterized, their fine features and fragile forms too readily destroyed or rendered unidentifiable in sediments. The present individual leaves the potential for further specimens to be discovered, and in amber deposits throughout the Cretaceous and Tertiary, particularly humid environments such as those of India, the Dominican Republic, Lebanon, and eastern North America, and especially those whose inclusions are more representative of a litter fauna, such as the amber of Archingeay in France.
References
Beccaloni J (2009) Arachnids. CSIRO Publishing, Collingwood
Carpenter FM (1992) Superclass Hexapoda. In: Moore RC, Kaesler RL (eds) Treatise on Invertebrate Paleontology, R, Arthropoda 4 [Volumes 3–4]. University of Kansas Press, Lawrence, pp. i–xxii + 1–655
Chatzimanolis S, Newton AF, Soriano C, Engel MS (2013) Remarkable stasis in a phloeocharine rove beetle from the Late Cretaceous of New Jersey (Coleoptera, Staphylinidae). J Paleontol 87(2):177–182
Cognato AI, Grimaldi DA (2008) 100 million years of morphological conservatism in a bark beetle (Coleoptera: Curculionidae; Scolytinae). Syst Entomol 34(1):1–8
Condé B (1965) Présence de Palpigrades dans le milieu interstitiel littoral. Comptes Rendus Hebdomadaires des Séances de l’Académie des Sci Paris 261(12):1898–1900
Condé B (1996) Les Palpigrades, 1885–1995: Acquisitions et lacunes. Revue Suisse de Zoologie, hors série, 87–106
Crowson RA, Rolfe WDI, Smart J, Waterston C, Willey EC, Wooton RJ (1967) Arthropoda: Chelicerata, Pycnogonida, Paleoisopus, Myriapoda and Insecta. In: Harland WB, Holland CH, House MR, Hughes NF, Reynolds AB, Rudwick MJS, Satterthwaite GE, Tarlo LBH, Willey EC (eds) The fossil record. Geological Society of London, London, pp 499–534
Delclòs X, Nel A, Azar D, Bechly G, Dunlop JA, Engel MS, Heads SW (2008) The enigmatic Mesozoic insect taxon Chresmodidae (Polyneoptera): new palaeobiological and phylogenetic data, with the description of a new species from the Lower Cretaceous of Brazil. Neues Jahrbuch für Geologie und Paläontologie Abhandlungen 247(3):353–381
Dunlop JA (2010) Geological history and phylogeny of Chelicerata. Arthropod Structure Dev 39(2–3):124–142
Engel MS, Grimaldi DA (2002) The first Mesozoic Zoraptera (Insecta). Am Mus Novit 3362:1–20
Engel MS, Grimaldi DA (2014) Whipspiders (Arachnida: Amblypygi) in amber from the Early Eocene and mid-Cretaceous, including maternal care. Novitates Paleoentomologicae 9:1–17
Garwood RJ, Dunlop JA (2014) Three-dimensional reconstruction and the phylogeny of extinct chelicerate orders. Peer J 2:e641. doi:10.7717/peerj.641
Germar EF (1839) Die versteinertern Insekten Solenhofens. Nova Acta Leopoldina Carolina Akademia Halle 19(1):187–222
Giribet G, McIntyre E, Christian E, Espinasa L, Ferreira RL, Francke ÓF, Harvey MS, Isaia M, Kovác Ĺ, McCutchen L, Souza MFVR, Zagmajster M (2014) The first phylogenetic analysis of Palpigradi (Arachnida)—the most enigmatic arthropod order. Invertebr Syst 28(4):350–360
Grassi GB (1886) I progenitori dei Miriapodi e degli Insetti memoria V. Intorno ad un nuovo aracnide artrogastro (Koenenia mirabilis) rappresentante di un nuovo ordine (Microthelyphonida). Bollettino della Società Entomologica Italiana Firenze 18:153–172
Grassi GB, Calandruccio S (1885) Intorno ad un nuovo aracnide artrogastro (Koenenia mirabilis), che crediamo rappresentante d’un nuovo ordine (Microteliphonida). Naturalista Siciliano 4(127–133):162–168
Grimaldi D, Engel MS (2007) Why descriptive science still matters. Bioscience 57(8):646–647
Grimaldi DA, Engel MS, Nascimbene PC (2002) Fossiliferous Cretaceous amber from Myanmar (Burma): its rediscovery, biotic diversity, and paleontological significance. Am Mus Novit 3361:1–72
Haase E (1890a) Bemerkungen zur Paläontologie der Insecten. Neues Jahrbuch für Mineralogie Geologie und Palaeontologie 1890(2):1–33
Haase E (1890b) Beiträge zur Kenntnis der fossilen Arachniden. Z Dtsch Geol Ges 42:629–657
Hamilton WD (1978) Evolution and diversity under bark. In: Mound LA, Waloff N (eds) Diversity of insect faunas. Blackwell Scientific, Oxford, pp 154–175
Handlirsch A (1906) Die fossilen Insekten und die Phylogenie der rezenten Formen: Ein Handbuch für Paläontologen und Zoologen. Engelmann, Leipzig
Harvey MS (2003) Catalogue of the smaller arachnid orders of the world: Amblypygi, Uropygi, Schizomida, Palpigradi, Ricinulei and Solifugae. CSIRO Publishing, Collingwood
Norton RA, Bonamo PM, Grierson JD, Shear WA (1988) Oribatid mite fossils from a terrestrial Devonian deposit near Gilboa, New York. J Paleontol 62(2):259–269
Petrunkevitch AI (1949) A study of Palaeozoic Arachnida. Trans Connect Acad Arts Sci 37:69–315
Petrunkevitch AI (1955) Arachnida. In: Moore RC (ed) Treatise on invertebrate paleontology, Part P, Arthropoda 2. University of Kansas Press, Lawrence, pp 42–162
Peyerimhoff P (1902) Découverter en France du genre Kaenenia [sic] (Arachn. Palpigradi). Bulletin de la Société Entomologique de France 1902:280–283
Prendini L (2011) Order Palpigradi Thorell, 1888. Zootaxa 3148:121
Rowland JM, Sissom WD (1980) Report on a fossil palpigrade from the Tertiary of Arizona, and a review of the morphology and systematics of the order (Arachnida: Palpigradida). J Arachnol 8(1):69–86
Rudkin DM, Young GA, Nowlan GS (2008) The oldest horseshoe crab: a new xiphosurid from Late Ordovician Konservat-Lagerstätten deposits, Manitoba, Canada. Palaeontology 51(1):1–9
Savory TH (1971) Evolution in the Arachnida. Merrow Monographs, Watford
Savory T (1974) On the arachnid order Palpigradi. J Arachnol 2(1):43–45
Shi G, Grimaldi DA, Harlow GE, Wang J, Wang J, Yang M, Lei W, Li Q, Li X (2012) Age constraint on Burmese amber based on U-Pb dating of zircons. Cretac Res 37:155–163
Sidorchuk EA, Schmidt AR, Ragazzi E, Roghi G, Lindquist EE (2015) Plant-feeding mite diversity in Triassic amber (Acari: Tetrapodili). J Syst Palaeontol 13(2):129–151
Simpson GG (1953) The major features of evolution. Columbia University Press, New York
Smrž J, Kováč L, Mikeš J, Lukešová A (2013) Microwhip scorpions (Palpigradi) feed on heterotrophic cyanobacteria in Slovak caves—a curiosity among Arachnida. PLoS One 8(10):e75989. doi:10.1371/journal.pone.0075989
Souza MFVR, Ferreira RL (2013) Two new species of the enigmatic Leptokoenenia (Eukoeneniidae: Palpigradi) from Brazil: first record of the genus outside intertidal environments. PLoS One 8(11):e77840. doi:10.1371/journal.pone.0077840
Thorell T (1888) Pedipalpi e Scorpioni dell’ Archipelago malese conservati nel Museo Civico di Storia Naturale di Genova. Annali del Museo Civico di Storia Naturale di Genova, Serie 2 [vol 6] 26: 327–428
van der Hammen L (1982) Comparative studies in Chelicerata II. Epimerata (Palpigradi and Actinotrichida). Zoologische Verhandelingen 196:1–70
Walter D, Proctor H (1999) Mites: ecology, evolution and behaviour. CABI Publishing, Wallingford
Acknowledgments
H.D.-Y. was supported through the National Basic Research Program of China (2012CB821903) and the National Natural Science Foundation of China (41222013), while that of D.A. was through the collaborative project, “Biodiversity: Origin, Structure, Evolution and Geology” granted by the Lebanese University. L.C.V.B. was partially supported by the U.S. National Science Foundation grant (DEB-1144162, to M.S.E.), and M.A. through a doctoral fellowship from the Fondo para la Innovación, Ciencia y Tecnología, Peru. We are immensely grateful to three anonymous reviewers for their helpful comments on an earlier version of the manuscript. This is a contribution of the Division of Entomology, University of Kansas Natural History Museum.
Author information
Authors and Affiliations
Corresponding authors
Additional information
Communicated by: Sven Thatje
Rights and permissions
About this article
Cite this article
Engel, M.S., Breitkreuz, L.C.V., Cai, C. et al. The first Mesozoic microwhip scorpion (Palpigradi): a new genus and species in mid-Cretaceous amber from Myanmar. Sci Nat 103, 19 (2016). https://doi.org/10.1007/s00114-016-1345-4
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00114-016-1345-4