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Hard ticks in Burmese amber with Australasian affinities

Published online by Cambridge University Press:  07 November 2022

Lidia Chitimia-Dobler
Affiliation:
Bundeswehr Institute of Microbiology, Neuherbergstrasse 11, 80937 Munich, Germany
Jason A. Dunlop
Affiliation:
Museum für Naturkunde, Leibniz Institute for Evolution and Biodiversity Science, Invalidenstrasse 43, D-10115 Berlin, Germany
Timo Pfeffer
Affiliation:
Keyence Deutschland GmbH, Siemensstrasse 1, D-63263 Neu-Isenburg, Germany
Felix Würzinger
Affiliation:
Keyence Deutschland GmbH, Siemensstrasse 1, D-63263 Neu-Isenburg, Germany
Stephan Handschuh
Affiliation:
VetCore Facility for Research/Imaging Unit, University of Veterinary Medicine Vienna, Veterinärplatz 1, A-1210 Vienna, Austria
Ben J. Mans*
Affiliation:
Epidemiology, Parasites and Vectors, Agricultural Research Council-Onderstepoort Veterinary Research, Onderstepoort, South Africa Department of Life and Consumer Sciences, University of South Africa, Pretoria, South Africa
*
Author for correspondence: Ben J. Mans, E-mail: [email protected]

Abstract

Three examples of metastriate hard ticks (Ixodida: Ixodidae) with apparent affinities to modern Australasian genera are described from the mid-Cretaceous (ca. 100 Ma) Burmese amber of Myanmar. Two nymphs of Bothriocroton muelleri sp. nov. represent the oldest (and only) fossil record of this genus, living members of which are restricted to Australia and predominantly feed on monitor lizards, snakes and echidnas. A female of Archaeocroton kaufmani sp. nov. shares its basis capitulum shape with the tuatara tick Archaeocroton sphenodonti (Dumbleton, 1943), the only extant member of this genus and an endemic species for New Zealand. The presence of 2 Australasian genera in Burmese amber is consistent with a previous record of an Ixodes Latreille, 1795 tick from this deposit which resembles Australian members of this genus. They further support an emerging hypothesis that fauna of the amber forest, which may have been on an island at the time of deposition, was at least partly Gondwanan in origin. A revised evolutionary tree for Ixodida is presented compiling data from several new Burmese amber ticks described in the last few years.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

Ticks (Arachnida: Parasitiformes: Ixodida) are haematophagous ectoparasites found on several vertebrate hosts. For an overview of their biology and economic significance as disease vectors, see Sonenshine and Roe (Reference Sonenshine and Roe2013). About 900 living species are known (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña, Horak, Shao and Barker2010), divided across 3 families and 20 extant genera. Molecular data (Mans et al., Reference Mans, de Klerk, Pienaar, Castro and Latif2012, Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019) suggest that the group may have originated during the Permian, but fossils are only known from the mid-Cretaceous or younger. For recent summaries, see, e.g. de la Fuente (Reference de la Fuente2003), Dunlop et al. (Reference Dunlop, Apanaskevich, Lehmann, Hoffmann, Fusseis, Ehlke, Zachow and Xiao2016), Chitimia-Dobler et al. (Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017, Reference Chitimia-Dobler, Pfeffer and Dunlop2018, Reference Chitimia-Dobler, Mans, Handschuh and Dunlop2022) and Peñalver et al. (Reference Peñalver, Arillo, Delclòs, Peris, Grimaldi, Anderson, Nascimbene and Pérez-de la Fuente2017). An extinct family and genus (Deinocrotonidae: Deinocroton Peñalver et al., Reference Peñalver, Arillo, Delclòs, Peris, Grimaldi, Anderson, Nascimbene and Pérez-de la Fuente2017), possibly related to the extant Nuttalliellidae, was described from the Cretaceous (ca. 100 Ma) Burmese amber outcropping in Myanmar. A second extinct family, Khimairidae, has since been recognized (Chitimia-Dobler et al., Reference Chitimia-Dobler, Mans, Handschuh and Dunlop2022), and the same amber deposit yields the oldest hard ticks (Ixodidae). These Burmese amber fossils currently comprise examples of the extant genera Ixodes Latreille, 1795 (Chitimia-Dobler et al., Reference Chitimia-Dobler, Mans, Handschuh and Dunlop2022), Amblyomma CL Koch, 1844 (Chitimia-Dobler et al., Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017) and Haemaphysalis (Allocereae) CL Koch, 1844 (Chitimia-Dobler et al., Reference Chitimia-Dobler, Pfeffer and Dunlop2018), as well as 2 extinct genera, Cornupalpatum Poinar and Brown, Reference Poinar and Brown2003, and Compluriscutula Poinar and Buckley, Reference Poinar and Buckley2008, whose affinities probably lie close to Amblyomma.

Burmese amber thus yields an increasingly diverse and interesting tick fauna, both in terms of extinct taxa and the oldest records of several living groups. Here, 3 new ticks from amber are described which are of particular biogeographical significance with respect to an ongoing debate (e.g. Poinar, Reference Poinar2018) about whether Burmese amber hosts a fauna with Laurasian or Gondwanan affinities. Two well-preserved nymphs represent the first, and so far only, fossils referable to the extant Australian genus Bothriocroton Keirans, King and Sharrad, Reference Keirans, King and Sharrad1994, a group which is today found on monitor lizards, snakes and the short-beaked echidna among the monotremes. The third amber fossil is a female referred to Archaeocroton Barker and Burger, Reference Barker and Burger2018 which resembles the extant tuatara tick (cf. Godfrey et al., Reference Godfrey, Bull and Nelson2008) from New Zealand. The new material draws 2 more modern tick genera back into the mid-Cretaceous and is consistent with the hypotheses that the so-called metastriate ticks (i.e. all hard ticks excluding Ixodes) radiated during the Early Cretaceous (Mans et al., Reference Mans, de Klerk, Pienaar, Castro and Latif2012), or the Jurassic (Mans et al., Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019). In this context, the provisional evolutionary tree presented in Chitimia-Dobler et al. (Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017, Fig. 3) is revised and updated to include both the new fossils from the present study and other published records in the recent literature.

Materials and methods

The 2 nymphs assigned to Bothriocroton come from the collection of Mr Patrick Müller and bear the original inventory numbers BUB1544 and BUB1573. The female assigned to Archaeocroton originates from the collections of the first author and has been deposited in the Museum für Naturkunde, Berlin (accession number MB.A. 4452). Burmese amber mostly comes from deposits in the Hukawng valley of northern Myanmar and has been dated to the mid-Cretaceous (earliest Cenomanian), or about 98.79 ± 0.62 Ma (Shi et al., Reference Shi, Grimaldi, Harlow, Wang, Yang, Lei, Li and Li2012). A subsequent study by Smith and Ross (Reference Smith and Ross2018) based on bivalve borings in the resin suggests that there has been only minimal reworking of the inclusions, and a Cenomanian age of about 100 Ma for the fossils may be appropriate. Further details about the history of discovery and the geological setting can be found in Grimaldi et al. (Reference Grimaldi, Engel and Nascimbene2002) and Ross et al. (Reference Ross, Mellish, York, Crighton and Penney2010); see also Selden and Ren (Reference Selden and Ren2017) for a recent review focused on the arachnids. An updated list of Burmese amber inclusions can be found in Ross (Reference Ross2021).

For photography, a Keyence VHX-6000 digital microscope (Keyence Itasca, IL, USA) with a tiltable stand and a combination of incident and transmitted light for focus stacking was used (with 100× to 1000× magnification). Image stacks were combined using software Helicon Focus 6.7.1 and polarized light was used to obtain more details. For computed tomography (μ-CT), the Archaeocroton sample was mounted on a specimen holder and scanned using a Zeiss Xradia MicroXCT-400 (Carl Zeiss X-Ray Microscopy, Pleasanton, CA, USA) at 40 kVp tube voltage. The tomography was acquired using the 4X detector assembly. The reconstructed image volume was processed and visualized by volume rendering using 3D software package Amira 6.4. Drawings were prepared with a camera lucida attachment on a Leica M205C stereomicroscope (Leica Microsystems, Wetzlar, Germany), again using a combination of incident and transmitted light where appropriate.

The Archaeocroton fossil is a female, which shows significant damage to 1 side of its body. All legs on the left side are broken as well as a little part of the idiosoma. The fact that part of the legs (tarsi) are broken and have an unusual position and all broken segments are very dry are signs of possible tick damage by the host during grooming and not during the polishing process of the amber piece.

Results

Systematic palaeontology for the Bothriocroton

Class Arachnida Lamarck, Reference Lamarck1801

Order Parasitiformes Reuter, Reference Reuter1909

Suborder Ixodida Leach, Reference Leach1815

Family Ixodidae Murray, Reference Murray1877

Bothriocroton Keirans, King and Sharrad, Reference Keirans, King and Sharrad1994

Bothriocroton muelleri Chitimia-Dobler, Mans and Dunlop sp. nov.

Etymology: In honour of Mr Patrick Müller (Kashöfen), who has made some extraordinary fossil ticks in Burmese amber available for study.

Material: Holotype BUB1544 and paratype BUB1573 (coll. P. Müller). Burmese amber, Myanmar, Late Cretaceous (Cenomanian).

Diagnosis: Body oval, scutum subtriangular with few large punctuations, the second article of palps at least twice as long as the third article, 11 festoons, eyes absent, spiracle plates comma-shaped extruding noticeably from lateral body margins, coxae I–IV with external spurs, tarsus I strongly humped and tarsus IV humped.

Description of the holotype: BUB1544 is an unengorged nymph (Fig. 1); dorsal surface partially obscured because of scratches in the matrix.

Fig. 1. Holotype of Bothriocroton muelleri sp. nov., P. Müller collection no. BUB1544, from Late Cretaceous (ca. 100 Ma) Burmese amber from Myanmar. (A) Dorsal overview. (B) Ventral overview. (C) Coxal spurs (arrowed). (D) Posterior idiosoma showing Y-shaped anal groove, extruded spiracle plates (arrowed) and 11 festoons (numbered). (E) Capitulum, including palps with long second article and hypostome with 2/2 dentition. (F) Leg I tarsus with prominent distal hump (arrowed) plus 6 additional lobes. (G) Leg IV tarsus with small hump (arrowed). Scale bars equal 1 mm (A, B), 250 μm (C), 500 μm (D) and 200 μm (E–G).

Idiosoma: Ornamentation indistinct; body oval; length from apices of scapulae to posterior body margin 2013 μm, breadth 1525 μm; scutum width 1056 μm (measured in middle of scutum), and 747 μm (from scapula to edge); subtriangular with hints of a few central large punctuations; scapulae short and rounded (Fig. 2A), cervical grooves long, shallow and linear anteriorly and slightly diverging posteriorly, not reaching end of scutum; eyes equivocal, probably absent; 11 festoons ranging from 145 to 197 μm in basal width (Fig. 1D); spiracle plates extruding noticeably from lateral body margins, 183 μm long, 136 μm wide (Figs 1D and 2B); anus visible, median, to the level of spiracle; anal groove Y-shape, close to anus with lateral arms reaching the upper limit of the anus and slightly converging (Fig. 2B), tail of the ‘Y’ does not reach middle festoon.

Fig. 2. Camera lucida drawings of the specimen shown in Fig. 1. (A) Dorsal view. (B) Ventral view. (C) Details of leg I tarsus including humped distal region plus 6 additional lobes (numbered). (D) Details of capitulum; palpal articles numbered, note the elongate second article. (E) Details of leg IV tarsus with small hump. Legs numbered from I to IV. Scale bars equal 500 μm (A, B) and 100 μm (C–E).

Capitulum: Length from apices to posterior margin of basis 725.2 μm; basis capituli rectangular, 239.9 μm long and 334.8 μm broad, posterior margin straight, lateral margins straight, cornua absent, ventrally posterior margin straight, palpi elongated (Figs 1E and 2D), with length of 4 articles as follows: article 1, 79 μm; article 2, 254.1 μm – with external proximal side concave, while distal end of article 2 is noticeably wider, 1.86 times longer than third article – article 3, 136.5 μm; article 4, 31.9 μm; hypostome shorter than the palpi, length 182 μm, width at base 97.7 μm; hypostomal dentition 2/2 (Figs 1E and 2D), with 5 or 6 well-developed, rounded denticles in each file; porose areas absent.

Legs: Coxae I–IV with small external spur (Figs 1C and 2B); tarsus I with stout, strongly humped region distally (Figs 1F and 2C); 6 less prominent lobes present dorsally, decreasing in size in the direction of trochanter, no spurs, length 522 μm; tarsus IV also ends in hump (Figs 1G and 2E); claws paired, slender, simple, slightly curved; with distinct pulvillus on all legs; Haller's organ small, located before the strongly humped region.

Chaetotaxy: Dorsally any setae (see below) were not visible, as the amber matrix bears many scratches hindering further examination.

Description of the paratype: BUB1573 is another unengorged nymph (Fig. 3); slightly smaller than the holotype.

Fig. 3. Paratype of B. muelleri sp. nov., P. Müller collection no. BUB1573, from Late Cretaceous (ca. 100 Ma) Burmese amber from Myanmar. (A) Dorsal overview. (B) Ventral overview. (C) Scutum showing large punctuations, cervical grooves (arrowed), but no evidence of eyes; note also several white, peg-like setae on the idiosoma. (D) Posterior idiosoma showing Y-shaped anal groove. (E) Capitulum. Scale bars equal 1 mm (A, B), 200 μm (C–E).

Idiosoma: Body oval with integument leathery; length from apices of scapulae to the posterior body margin 1333 μm, breadth 1207 μm; scutum width 896 μm (measured in middle of scutum), and 558 μm (from scapula to edge); subtriangular with few central large punctuations (Fig. 3C); scapulae short and rounded, cervical grooves long, shallow and linear anteriorly and slightly diverging posteriorly, not reaching end of scutum (Figs 3C and 4A); eyes absent; 11 festoons (first indistinct); spiracle plates on lateral body margins (Fig. 4B), 134 μm long, 88.8 μm broad; anus visible, median, up to level of spiracle; anal groove Y-shaped (Figs 3D and 4B), close to the anus with lateral arms reaching upper limit of anus and slightly converging, tail of the ‘Y’ does not reach middle festoon.

Fig. 4. Camera lucida drawings of the paratype specimen shown in Fig. 3. (A) Dorsal view. (B) Ventral view. Legs numbered from I to IV. Scale bar equals 500 μm.

Capitulum: Length from apices to posterior margin of basis 482.5 μm; basis capituli rectangular, 143.8 μm long and 282.6 μm broad, posterior margin straight, lateral margins straight, cornua absent, ventrally posterior margin straight, palpi elongated, with length of 4 articles as follows: article 1, 43.5 μm; article 2, 175.6 μm – again with external proximal side concave and distal end of article 2 noticeably wider, 2.64 times longer than third article – article 3, 66.3 μm, without external spur; article 4, 32.5 μm; hypostome shorter than the palpi (Figs 3E and 4B), length 182 μm, width at base 97.7 μm; hypostomal dentition apparently 2/2 but not as clearly preserved as in holotype, at least 4 well-developed, rounded denticles in each file; porose areas absent.

Legs: Coxae with small external spur (not clearly visible on all legs); tarsus IV ends with slight hump (Fig. 4B); claws paired, slender, simple, slightly curved; with distinct pulvillus on all legs.

Chaetotaxy: Small hairs can again be observed on the legs (Fig. 4). Idiosoma covered dorsally by numerous, short, white, peg-like setae (Figs 3C and 4A) (68–83 μm long and 19.8 μm broad), but very few hairs observed on scutum; a few hairs visible ventrally.

Remarks: The 2 fossils described here as Bothriocroton muelleri sp. nov. are presumed conspecific, despite a slight difference in size, and represent a new hard tick genus for Burmese amber. They appear to lack eyes (Figs 1 and 2), and while blindness matches the condition in, e.g. Compluriscutula vetulum Poinar and Buckley, Reference Poinar and Buckley2008 the pedipalps of C. vetulum differ from those in the new fossils. Specifically, in C. vetulum the 4th article of the pedipalp is long and ends with elongate terminal setae (cf. Fig. 2D here with its short article 4). Also the idiosoma in C. vetulum bears 13 festoons along its posterior margin (Poinar and Buckley, Reference Poinar and Buckley2008, Fig. 3), while the new specimens have only 11 (Figs 1 and 2), all more or less the same size. The new taxon is thus the 4th Burmese amber tick species with 11 festoons; the others being Cornupalpatum burmanicum Poinar and Buckley, Reference Poinar and Buckley2008, Amblyomma birmitum Chitimia-Dobler et al., Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017 and Haemaphysalis (Alloceraea) cretacea Chitimia-Dobler et al., Reference Chitimia-Dobler, Pfeffer and Dunlop2018. Of these, C. burmanicum differs from the new fossil in having a unique extra claw on the penultimate (third) pedipalp article (Poinar and Brown, Reference Poinar and Brown2003, Figs 3 and 4), which is not seen in the new fossils (Fig. 2D). The absence of eyes in the new fossils is the strongest character for excluding A. birmitum. The other amber species in an extant genus, H. cretacea, has an elongate body, also with 11 festoons, and is eyeless, but unlike the new fossils it has the brevirostrate condition and has a dental formula with 8–10 denticles in a file.

Comparisons with extant ticks

The Amblyomma sensu Horak et al. (Reference Horak, Camicas and Kierans2002) remains a controversial genus that includes ticks with quite different morphologies and lifestyles. Twenty eyeless Amblyomma species have been noted in the literature (Horak et al., Reference Horak, Camicas and Kierans2002), of which 19 are now valid (Madder et al., Reference Madder, Horak and Stoltz2010; Schachat et al., Reference Schachat, Robbins and Goddard2018), all of which potentially merit comparison with the new (blind) nymphs. The validity of these eyeless Amblyomma species as a group is still subject to debate and a wider reevaluation/reclassification of the entire Amblyomma genus may be necessary (Kaufman, Reference Kaufman1972; Klompen et al., Reference Klompen, Oliver, Keirans and Homsher1997, Reference Klompen, Dobson and Barker2002). In detail, several Amblyomma species were originally placed in another genus, Aponomma Neumann, Reference Neumann1899, although the revision of Kaufman (Reference Kaufman1972) revealed this to be a heterogeneous group of eyeless ticks with a predilection for reptiles. Kaufman (Reference Kaufman1972) divided Aponomma into 3 species groups: (1) ‘typical’ Aponomma, including 15 species of reptile-associated ticks from the Afrotropical and Oriental zoogeographic regions, (2) ‘indigenous Australian’ species (now Bothriocroton; see below) and (3) 2 ‘primitive’ Aponomma species.

Robertsicus and Archaeocroton

The ‘primitive’ Aponomma species sensu Kaufman (Reference Kaufman1972) has recently been elevated by Barker and Burger (Reference Barker and Burger2018) to new, monotypic genera, namely Robertsicus Barker and Burger, Reference Barker and Burger2018 and Archaeocroton Barker and Burger, Reference Barker and Burger2018. Robertsicus was erected for Robertsicus elaphensis (Price, Reference Price1958), formerly Amblyomma elaphense Price, Reference Price1958 that parasitizes the Trans-Pecos rat-snake in the Chihuahuan Desert of Mexico and south-eastern USA. Similar to the new fossils (Fig. 1E) this genus/species has a 2/2 hypostomal dentition, but differs in a scutum which is broader than long, but is cordiform, smooth and without cervical grooves (cf. Figs 2B and 4A of the new fossils), the setae and punctuations are minute and it has a very small, bluntly rounded spur on coxae I–IV (e.g. Keirans et al., Reference Keirans, William and Degenhardt1985). In the new fossils the spurs are larger (Figs 1C and 2B). Archaeocroton was erected for Archaeocroton sphenodonti (Dumbleton, Reference Dumbleton1943). The 2 amber nymphs can also be excluded from Archaeocroton (see below) as the scutum here is sub-cordiform and the coxae have an external spur and a single subterminal spur on the trochanter (Kaufman, Reference Kaufman1972). The new fossils lack spurs on the trochanter (Figs 2B and 4B).

Eyeless Amblyomma

Identifying ‘Amblyomma-like’ nymphs is extremely difficult in most cases, even more so with fossils. So far, there are no workable keys, and there are no established diagnostic characters for nymphs of either Amblyomma or Bothriocroton. However, a comparison with known eyeless Amblyomma nymphs (as the new fossil is eyeless) and with described Bothriocroton nymphs are given in the sections below.

Several characters exclude the eyeless Amblyomma species which corresponded to the ‘typical’ Aponomma species sensu Kaufman (Reference Kaufman1972). Nymphs of this species group are characterized by an anal groove being present and embracing the anus posteriorly; eyes absent; festoons present and numbering 11; basis capituli variable in form but often subrectangular or subtriangular; palpi elongate and constricted proximally, with article 2 being especially long and with reptiles as hosts (Horak et al., Reference Horak, Camicas and Kierans2002; Klompen et al., Reference Klompen, Dobson and Barker2002; Barker and Murrell, Reference Barker and Murrell2004; Beati et al., Reference Beati, Keirans and Durden2008).

Excluding the 2 ‘primitive’ ticks (see above) which are now in their own genera, the eyeless Aponomma sensu Kaufman (Reference Kaufman1972) is distributed as follows. There are 7 Afrotropical species: Amblyomma arcanum Karsch, 1879, Amblyomma exornatum Koch, 1844, Amblyomma flavomaculatum Lucas, 1846, Amblyomma inopinatum Santos Dias, 1989, Amblyomma latum Koch, 1844, Amblyomma orlovi Kolonin, 1992 and Amblyomma transversale Lucas, 1845. Amblyomma transversale has recently been reinstated as the separate genus Africaniella Travassos Dias, 1974 (Hornok et al., Reference Hornok, Kontschán, Takács, Chaber, Halajian, Abichu, Kamani, Szekeres and Plantard2020). There is also 1 Afrotropical/Oriental species (Amblyomma gervaisi Lucas, 1847), 3 Oriental species (Amblyomma crassipes Neumann, 1901, Amblyomma fuscolineatum Lucas, 1847 and Amblyomma pattoni Neumann, Reference Neumann1910), 3 Oriental/Australasian species (Amblyomma fimbriatum Koch, 1844, Amblyomma trimaculatum Lucas, 1878 and Amblyomma varanense Supino, 1897) and 3 purely Australasian species (Amblyomma komodoense Oudemans, 1928, Amblyomma kraneveldi Anastos, 1956 and Amblyomma soembawense Anastos, 1956). Any of these could potentially be related to the new amber fossils – which could be taken as evidence for their inclusion in the ‘eyeless’ Amblyomma assemblage – but as detailed below these modern species are either known only from adults or differ from the new material.

Eyeless Amblyomma in the Afrotropics

Amblyomma arcanum and A. inopinatum were accepted as valid species by Guglielmone and Nava (Reference Guglielmone and Nava2014) and only adults are known (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña and Horak2014), which makes it difficult to compare directly to the new amber species at the nymphal stage. For A. orlovi it is not clear whether this is a valid species and is known only from the female (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña and Horak2014). Amblyomma exornatum is known from various stages and differs from the new fossils in having a hypostome dentition of 3/3 (2/2 in the fossils: Figs 1E and 2D), teeth continuing posteriorly as crenulations and a small corona distally, and tarsus I with a small distal dorsal hump (Theiler, Reference Theiler1945a); as opposed to the large hump seen in the fossils (Figs 1F and 2C). Based on personal observations of A. flavomaculatum nymphs held in the Museum für Naturkunde Berlin, observations include: a hypostome dentition of 3/3 with teeth in 6–7 lines, a rosette visible distally, the cervical grooves are short, deep and arched, the setae and interstitial punctuations are small and regularly distributed and the nymphal tarsus is similar to that of the female with less prominent protrusions (see also Saratsiotis, Reference Saratsiotis1972).

Amblyomma latum is a senior synonym of several species and is characterized by a spot of red pigmentation in the eye region, cuticle which is thin and transparent with no hairs present. Again, comparative material (labelled as a synonym: Amblyomma leave Neumann, Reference Neumann1899) in the Museum für Naturkunde collection was examined. The hypostome has a 2/2 dentition (like the fossils) but with a corona, coxa I has an external spur sharper and longer than the internal one (only 1 spur in the fossils: Figs 1C and 2B), coxae II–IV have 1 median spur; tarsus I long; tarsi II–IV taper fairly gradually from a slight median swelling in some instances this swelling is large enough to produce the effect of a hump (Theiler, Reference Theiler1945b), but not to the same extent as in the fossils (Figs 1F and 2C). Finally, A. transversale has abdominal skin showing fine transverse striations, but hairs appear to be absent. The coxae have a single spur, tarsus I show well-pronounced false articulation, the distal portion with a large hump and 1 or 2 ventral spurs (Theiler, Reference Theiler1945b).

Eyeless Amblyomma from other regions

Taxa occurring outside (wholly or in part) of the Afrotropical region are potentially closer in terms of biogeography to possible Australasian-derived fossils. Amblyomma gervaisi ranges across the Afrotropical to the Oriental region. The species is glabrous, with a scutum longer than wide, subtriangular and non-ornamented (punctate in the fossils: Fig. 4A). Its cervical grooves are quite long and the tarsus is without a spur (Neumann, Reference Neumann1899). The purely Oriental species, A. crassipes has a subcordiform scutum and, similar to the fossils, has large punctuations over the entire surface. Unlike the fossils (Figs 1E and 2D), the hypostome has a 3/3 dentition at its base and a corona. Coxa I has 2 spurs and coxae II–IV 1 spur. Tarsus I shows a distinct swelling (Theiler, Reference Theiler1945a), but not the strong hump as in the fossils (Figs 1F and 2C). Amblyomma crassipes is similar to A. fuscolineatum (see below), but is provisionally considered valid because scant material is available for examination and the types have not been compared (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña, Horak, Shao and Barker2010).

Amblyomma fuscolineatum Lucas, 1847 is variously recorded in the literature (see Guglielmone and Nava, Reference Guglielmone and Nava2014). The description of the nymph in Schulze (Reference Schulze1936) is confusing, but the hypostome has a 3/3 dentition and the cervical groove is divergent and reaches the end of the scutum. Amblyomma pattoni is a senior synonym of Aponomma pseudolaeve Schulze, Reference Schulze1935; cf. Kaufman (Reference Kaufman1972) and Camicas et al. (Reference Camicas, Hervy, Adam and Morel1998). The description in Schulze (Reference Schulze1935) is very brief; noting that the nymph looks like the female except that the hypostome is different. Thus the hypostome dentition is 2/2 and punctuations are generally absent with just a few punctuations on the scapula (Schulze, Reference Schulze1935).

Other species occur from the Oriental through to the Australasian region. Amblyomma fimbriatum is a senior synonym of several taxa (see Guglielmone and Nava, Reference Guglielmone and Nava2014). It has the scutum postero-lateral margins straight or slightly convex, several, large, scattered punctuations and a few small ones, cervical grooves ending in short, ill-defined depressions, a hypostome dentition of 3/3 (2/2 in the fossils), coxae each with a single short spur (similar to the fossils) and tarsi humped but without spurs (Roberts, Reference Roberts1953). Amblyomma trimaculatum has a scutum with the postero-lateral margins slightly convex, punctuations relatively large and distributed mainly laterally, the hypostome dentition is again 3/3 and the tarsi are humped, but without spurs (Roberts, Reference Roberts1953). Finally, from the Australasian region, A. komodoense and A. kraneveldi only adults are known (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña and Horak2014) precluding direct comparison to the new fossil nymphs. Amblyomma soembawense Anastos, 1956 is only known from adults and the larva: the nymph is unknown (Guglielmone and Nava, Reference Guglielmone and Nava2014).

Assignment to Bothriocroton

In the absence of a strong match between the 2 amber nymphs and any of the ‘eyeless’ Amblyomma species (see above), the next taxon to consider is Bothriocroton. This subgenus was raised by Keirans et al. (Reference Keirans, King and Sharrad1994) for Aponomma glebopalma Keirans, King and Sharrad, Reference Keirans, King and Sharrad1994 and subsequently expanded (Klompen et al., Reference Klompen, Dobson and Barker2002) to include the rest of Kaufman's (Reference Kaufman1972) ‘indigenous Australian’ Aponomma ticks, with Bothriocroton also placed in its own subfamily: Bothriocrotoninae. The ‘indigenous Australian’ Aponomma species were recognized by Kaufman (Reference Kaufman1972) on the following character combinations: a single subterminal spur on the trochanter (absent in all other Aponomma and in Bothriocroton glebopalma, and also absent in the new fossils) and lateral grooves on the scutum of the male partial or complete – absent in ‘typical Aponomma’, R. elaphensis, and B. glebopalma – but present in A. sphenodonti. Thus absence of eyes, elongate palps, a subpentagonal basis capituli shape, coxae with 2 spurs in all instars and trochanters with a single subterminal ventral spur – albeit absent in B. glebopalma (see e.g. Klompen et al., Reference Klompen, Dobson and Barker2002) – are morphological features that can be considered characteristic for the living Bothriocroton species. Spiracle plates extruding from the lateral border of the idiosoma anterior to the first festoon in Bothriocroton oudemansi (Neumann, 1910) were first described by Neumann (Reference Neumann1910) and are present in the new fossil. The large wax glands laterally near setae s6, Md3 of Clifford et al. (Reference Clifford, Anastos and Elbl1961), and anterior to the first festoons (Klompen et al., Reference Klompen, Black, Keirans and Oliver1996) in the larvae are also promising diagnostic characters, but cannot be tested in the present fossil material.

The new Burmese amber nymphs are tentatively assigned to Bothriocroton based on a combination of: (1) the absence of eyes, (2) the second article of the palps being longer than the third (Figs 1E and 2D), (3) a dental formula of 2/2 in a file (Figs 1E and 2D), (4) coxae I–IV with obvious external spurs (Figs 1C and 2B), (5) the absence of a trochanter spur, (6) tarsus I with a stout, strong hump and 6 small dorsal protrusions (Figs 1F and 2C) and tarsus IV also ending with a hump (Figs 1G and 2E) and (7) spiracle plates extruding from the lateral border of the anterior to the first festoon (Fig. 1B and D). The 7th character could place the new fossil tick close to some Asian Amblyomma, species (see above) which, at least in the adult stage, have 3 lobes close to the hump: for example, Amblyomma supinoi in Voltzit and Keirans (Reference Voltzit and Keirans2002). It is also similar to some Ornithodoros species – albeit in a different family, Argasidae – which also present prominent dorsal lobes, including bipartite lobes, which are used in species diagnoses (see e.g. Bakkes et al., Reference Bakkes, De Klerk, Latif and Mans2018).

Bothriocroton is, numerically, a small tick genus today with only 7 extant species and no division into subgenera (Barker et al., Reference Barker, Walker and Campelo2014; Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña and Horak2014). In addition to the type species (B. glebopalma), 4 of its species were traditionally referred to Aponomma: Bothriocroton auruginans (Schulze, Reference Schulze1936), Bothriocroton concolor (Neumann, Reference Neumann1899), Bothriocroton hydrosauri (Neumann, Reference Neumann1899) and Bothriocroton tachyglossi (Roberts, Reference Roberts1953). Note that B. tachyglossi was considered a synonym of B. hydrosauri, but there is convincing evidence for its validity (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña, Horak, Shao and Barker2010). The 2 remaining species are B. oudemansi (Neumann, Reference Neumann1910) – at one time considered a synonym of B. concolor, although there is sound evidence for its validity (Guglielmone et al., Reference Guglielmone, Robbins, Apanaskevich, Petney, Estrada-Peña, Horak, Shao and Barker2010) – and Bothriocroton undatum (Fabricius, 1775) (=Aponomma decorosum Koch, 1867).

Morphology shows Bothriocroton closely related to Amblyomma and the general leg and palpal chaetotaxy resembles that of Amblyomma sensu lato. Bothriocroton species are generally rather large ticks with long mouthparts: the longirostra condition. Iridescent ornamentation on the scutum is absent, but the living species B. glebopalma and B. undatum have white ornamentation, which could not be observed in the new fossils. Bothriocroton ticks can also be recognized by the adult hypostomal dentition, which is either in a 2/2 or 3/3 arrangement; with the internal row much smaller than other rows. The scutum is also broader than long. In females and nymphs, conspicuous posterolateral indentations formed by the confluence of larger punctuations are present.

Comparisons to living Bothriocroton species

The new amber fossils appear to be morphologically closest to the extant species B. undatum, especially with respect to the dental formula, the coxal spurs and stout, strong hump which is very evident on tarsus I and dorsal lobes which are not so prominent (Figs 1F and 2C), plus a small hump on tarsus IV (Figs 1G and 2E). The fossils also share with B. oudemansi the same dental formula and coxal spurs (see e.g. Beati et al., Reference Beati, Keirans and Durden2008); however, tarsal humps are lacking in this modern species. The scutum in the new fossils is subtriangular, broader than long, with its postero-lateral margins slightly convex. It is larger than the scutum in both B. undatum and B. oudemansi. The cervical grooves form long, deep depressions (Figs 2A and 4A), which broaden and become shallow and divergent, but do not reach the posterior scutal margin. It may also be noted that B. glebopalma has a deeply pitted and pilose scutum in both the adult and immature stages, unlike the other eyeless Amblyomma species previously placed in Aponomma (Keirans et al., Reference Keirans, King and Sharrad1994).

Systematic palaeontology for the Archaecroton

Emended diagnosis: Metastriate ticks with body sub-circular; 11 festoons; basis capitulum lateral angles produced into sub-conical processes; hypostome dentition 2/2 without corona; spiracle plates sub-circular; tarsi I–IV with pseudo-articulation at 1/3 of its length.

Family Ixodidae Murray, Reference Murray1877

Genus Archaeocroton Barker and Burger, Reference Barker and Burger2018

Archaeocroton kaufmani Chitimia-Dobler, Mans and Dunlop sp. nov.

Etymology: After T. S. Kaufman who first recognized the distinctness of the modern species now placed in Archaeocroton.

Material: Holotype from Burmese amber, Myanmar. Late Cretaceous (Cenomanian) in the Museum für Naturkunde, Berlin (accession number MB.A. 4452).

Diagnosis: Fossil Archaeocroton in which cornuae are extremely broad; spiracle plates comma shape; hypostome dentition 2/2 without corona; 11 festoons; tarsi I–IV with pseudo-articulation to the 1/3 of its length (Supplementary Fig. 1); tarsus IV ends with a dorso-apical hook.

Description: Female.

Idiosoma: Body subcircular, slightly elongate, widest posteriorly, integument leathery; length from middle of scutum to posterior body margin 1390 μm. Maximum width (measured in middle, behind third legs) 1984 μm; scutum 1156 μm wide (measured in middle), or 837 μm long (from middle to edge); sub-cordiform, with few spare punctuations (Figs 5 and 6); scapulae short and rounded. Cervical grooves not visible (Figs 5 and 6). Posterior margin of idiosoma with 11 visible festoons (width 176–229 μm) (Figs 5 and 6), no grooves separate festoons from the rest of idiosoma. Anus visible, median; anal groove semi-circular, contouring behind anus (Figs 5 and 6). Genital aperture not clearly visible, apparently located approximately between coxae II and III. Stigmas best seen in CT scans (Fig. 7), comma-shaped with round macula; left stigma 392 μm long and 265 μm wide, right stigma 403 μm long and 275 μm wide.

Fig. 5. Holotype and only known specimen of the hard tick Archaeocroton kaufmani sp. nov. (Ixodida: Ixodidae) in the Museum für Naturkunde, Berlin (accession number MB.A. 4452).

Fig. 6. Interpretative camera lucida drawings of the specimen shown in Fig. 5. Legs numbered from I to IV and festoons numbered from 1 to 11.

Fig. 7. CT images of the holotype (penetrating the artefacts) and emphasizing again the presence of 11 festoons (left both above and down). Additionally highlighting the outline of the stigma (left down), chelicera structure (right above) and the 2 + 2 dentition of the hypostome (right down). The volume renderings especially emphasize air-filled cavities in the amber fossil.

Capitulum: Length from apices to posterior margin of basis 569 μm. Basis capitulum triangular dorsally with lateral angles produced into sub-conical processes, length 452 μm, maximum width 188 μm, more than twice as broad as long; posterior margin straight, cornuae extremely broad and very blunt. Ventrally sub-triangular, lateral projection distinct and appears acute in ventral view; auriculas indistinct; porose areas only slightly visible, but sub-circular, located centrally on basis capituli. Palpi elongate; 4 articles with lengths: article 1, 82 μm; article 2, 280 μm (with external proximal side concave); article 3, 133 μm; article 4 could not be measured. Hypostome somewhat shorter than adjacent palpi (Figs 5 and 6); hypostomal dentition 2/2. The external left file has 10 well-developed denticles, the external right file has only 9; internal files have 7 smaller denticles; apical corona absent. Chelicerae well-developed, equal in length to hypostome, with minute dorsal denticles on internal side of the unmovable fingers and with sawdust appearance due to the 6 kinds of teeth (Fig. 7).

Legs: Coxae I–IV without internal spurs; external spur on coxae I–IV is small. Tarsus I taper distally and has a pseudo-articulation at 1/3 of its length; tarsi IV 520 μm (length of tarsus 190 μm, length of tarsus 330 μm) with pseudo-articulation at 1/3 of its length and ending with a dorso-apical hook; tarsi II and III with pseudo-articulation at 1/3 of its length.

Chaetotaxy: Short hairs observed on all leg articles. Palps bear long seta on internal (mesal) side of second article, and 3 long internal setae on third article, plus 1–2 setae on external side of the second and third articles (Figs 5 and 6).

Anomaly: Basis capitulum reveals an abnormality on the left side (Figs 5 and 6). Deformation occurs before sub-conical process and goes a little below the basis capitulum. Ventrally lateral projection not completely developed, appearing more round than angular. Anomaly also reaches basis of hypostome, where right external file has only 9 denticles (not 10 as per left part) and is thicker than normal.

Remarks: The tuatara tick was originally described as Aponomma sphenodonti Dumbleton, Reference Dumbleton1943 and was regarded as a ‘primitive Aponomma species’ sensu Kaufman (Reference Kaufman1972), who hinted that it may warrant a separate genus. Aponomma Neumann, Reference Neumann1899 was subsequently synonymized with Amblyomma by Klompen et al. (Reference Klompen, Dobson and Barker2002) (see also above), while Barker and Burger (Reference Barker and Burger2018) confirmed Kaufman's earlier intuition and recognized the tuatara tick as the sole representative of a new genus, Archaeocroton, so named for retaining several apparently plesiomorphic features. The body of the new female amber specimen is sub-circular, slightly wider than long, widest posteriorly and has a leathery integument. In this sense it is similar to the previously described Burmese amber fossil A. birmitum as well as some living members of Amblyomma (Voltzit and Keirans, Reference Voltzit and Keirans2003), to B. oudemansi (Beati et al., Reference Beati, Keirans and Durden2008), R. elaphensis and to A. sphenodonti (see e.g. Barker and Burger, Reference Barker and Burger2018). The new fossil lacks eyes, and in this sense it is similar to the Burmese amber species C. burmanicum (Poinar and Brown, Reference Poinar and Brown2003), C. vetulum (Poinar and Buckley, Reference Poinar and Buckley2008) and H. cretacea (Chitimia-Dobler et al., Reference Chitimia-Dobler, Pfeffer and Dunlop2018).

The number of festoons around the posterior margin of the idiosoma can be a useful diagnostic character in metastriate ticks, both at the genus and species levels. Hyalomma have 5, Haemaphysalis have 9 or 11 and Amblyomma have 11 (Neumann, Reference Neumann1911; Nuttall et al., Reference Nuttall, Warburton, Cooper and Robinson1911; Lindquist et al., Reference Lindquist, Galloway, Artsob, Lindsay, Drebot, Wood and Robbins2016). The central festoon is usually positioned directly behind the anus (Clifford and Anastos, Reference Clifford and Anastos1960). The new fossil has 11 well-defined festoons (Figs 5–7) and no groove separates the festoons from the rest of the idiosoma. The number of festoons and the shape of the stigmata are thus morphological features similar to the Burmese amber fossil A. birmitum. The new fossil has the genital aperture located between coxae II and III. This would be similar to fossil A. birmitum (Chitimia-Dobler et al., Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017) and to some modern Amblyomma species coming from former Gondwanan regions, and also to B. oudemansi (Kaufman, Reference Kaufman1972; Beati et al., Reference Beati, Keirans and Durden2008) and to A. sphenodonti (Barker and Burger, Reference Barker and Burger2018). By contrast, other species have the genital aperture located between coxae II (Voltzit and Keirans, Reference Voltzit and Keirans2003; Voltzit, Reference Voltzit2007), except for 3 Neotropical Amblyomma species which have the genital aperture between coxae III: namely Amblyomma cruciferum Neumann, 1901, Amblyomma darwini Hirst and Hirst, 1910 and Amblyomma humerale Koch, 1844 (Voltzit, Reference Voltzit2007).

The key character here is the shape of the basis capitulum, which is very distinctive in the new fossil. It is triangular dorsally with lateral angles produced into sub-conical processes and extremely broad with very blunt cornuae, while ventrally it is sub-triangular; the lateral projections are distinct and appear acute with indistinct auriculas. A basis capitulum of this form is very rare among the extant ixodid females. This triangular shape dorsally and sub-triangular with lateral projections ventrally is specific for females of A. sphenodonti, and for nymphs and larvae of Hyalomma, but not for the adults (Apanaskevich and Horak, Reference Apanaskevich and Horak2008). Some extant Amblyomma species can have a (sub)triangular basis capitulum, as do the extinct Burmese amber genera Cornupalpatum and Compluriscutula (Poinar and Brown, Reference Poinar and Brown2003; Poinar and Buckley, Reference Poinar and Buckley2008), however, in all these cases the basis capitulum is not as broad as in the current fossil.

The denticles on the hypostome are usually arranged in parallel longitudinal rows, or files, and the dentition formula indicates the number of files on each side of the midline of the hypostome. For example, 2/2 indicates the presence of 2 files on each side. The lateral-most row is designated as file 1. The relative size of the denticles differs characteristically between different species of ticks, such that the number of teeth in each file is a useful diagnostic character. The lateral file generally has denticles at least as large as any present elsewhere on the hypostome (Lindquist et al., Reference Lindquist, Galloway, Artsob, Lindsay, Drebot, Wood and Robbins2016). In the new fossil, the hypostome tooth columns have a 2/2 arrangement, distributed along the whole length of the hypostome (Figs 5 and 6), with 10 well-developed teeth in the external file and 7 smaller teeth in the second, without corona. All modern Asian, African and Neotropical Amblyomma adults have a 3/3 or 4/4 tooth arrangement, or even 5/5 in females of Amblyomma clypeolatum Neumann, Reference Neumann1899 (Voltzit and Keirans, Reference Voltzit and Keirans2002, Reference Voltzit and Keirans2003; Voltzit, Reference Voltzit2007). In a few modern species the internal files are also less developed than the external ones: A. sphenodonti (Barker and Burger, Reference Barker and Burger2018), B. tachyglossi (Roberts, Reference Roberts1953) and A. transversale (Theiler, Reference Theiler1945b). In A. sphenodonti the hypostome tooth columns have a 2/2 arrangement, with 5 or 6 teeth in a file and corona (Dumbleton, Reference Dumbleton1943; Kaufman, Reference Kaufman1972). The chelicerae structure is unique for ixodid ticks, none of the extant tick species is known to have a sawdust appearance on the internal side of the unmovable fingers (Fig. 8).

Fig. 8. Comparative sketches of the distinctively triangular basis capitulum in dorsal view in the extant tuatara tick, Archaeocroton sphenodonti Dumbleton, Reference Dumbleton1943 (left), and the new amber species A. kaufmani sp. nov. (right), with the special chelicera structure. Not to scale.

In the amber fossil the stigma is comma-shaped, with round macula and about 392–403 μm long. In A. sphenodonti the stigma is sub-circular and 230 μm long, slightly angulate at a posterior dorsal angle (Dumbleton, Reference Dumbleton1943). Tarsus IV (527 μm) of the new fossil has a pseudo-articulation at 1/3 of its length and ends in a dorso-apical hook. Tarsi II and III have also a pseudo-articulation at 1/3 of its length, but no dorso-apical hook. Pseudo-articulation of tarsi I and IV is also characteristic for A. sphenodonti. The dorso-apical hook in the new fossil is not present on other ixodid species and represents a useful diagnostic character; see above. Usually, Amblyomma adults have 1 or 2 ventro-apical hook(s) (Kaufman, Reference Kaufman1972; Voltzit and Keirans, Reference Voltzit and Keirans2003) as do some Dermacentor species (Filippova, Reference Filippova1997). Taken together, the observed morphological characteristics suggest that the new fossil is closely related to the tuatara tick A. sphenodonti and can also be placed in Archaeocroton.

Anomaly in the basis capitulum

The anomaly observed in the basis capitulum with a discrepancy in the number of teeth between the left and right files is the first example recorded for a tick in amber. It can be classified as an exoskeleton anomaly. A number of biological or non-biological factors may cause morphological abnormalities in ticks: (1) somatic or germinal mutations, (2) injury, (3) exposure to chemical agents, (4) environmental stress, (5) host resistance to tick infestation or (6) blood-feeding on unusual hosts (Feldman-Muhsam, Reference Feldman-Muhsam1948; Campana-Rouget, Reference Campana-Rouget1959a, Reference Campana-Rouget1959b; Latif et al., Reference Latif, Dhadialla and Newson1988; Guglielmone et al., Reference Guglielmone, Castella, Mangold, Estrada-Peña and Viñabal1999; Dergousoff and Chilton, Reference Dergousoff and Chilton2007; Nowak-Chmura, Reference Nowak-Chmura2012). Zharkov et al. (Reference Zharkov, Dubinina, Alekseev and Jensen2000) considered that the exoskeleton abnormalities in Ixodes tick are greatly dependent on anthropogenic pressure, and it may be the most reliable way of biomonitoring the environment pollution level.

Scutum pattern and dental formula

No Amblyomma species have been described thus far with white spots related to colour patterns on the festoons, even more on all festoons and the side of the scutum. Among hard ticks, many species of Metastriata have intricate ornamentation on the scutum and/or festoons that is often used as a taxonomic character. However, the biological function(s) of this ornamentation remains unclear (Schachat et al., Reference Schachat, Robbins and Goddard2018). The scutum pattern of the fossil is similar to A. sphenodonti (Barker and Burger, Reference Barker and Burger2018). In fact, the white pattern on the scutum and festoons is related to the parts of extant females where the purple zones are not observed. In addition, the new fossil shares with A. sphenodonti the shape of the basis capitulum and the shape and position of the porose areas (cf. Barker and Burger, Reference Barker and Burger2018). Amblyomma birmitum, the first fossil female, has also a 2/2 dentition but the teeth are of the same size (Chitimia-Dobler et al., Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017). Some extant species have the hypostome dentition of the fossil female, e.g. R. elaphensis has a 2/2 hypostomal dentition (although the hypostome figured has a single supernumerary tooth between files 1 and 2 on the left side of the hypostome as viewed from above) and the hypostome ends with a denticle corona (Keirans et al., Reference Keirans, William and Degenhardt1985), while B. oudemansi also has the same dental formula (Beati et al., Reference Beati, Keirans and Durden2008).

Discussion

All living Bothriocroton ticks are restricted to the Australian faunal region while the single living Archaeocroton species is only found in New Zealand. The new Burmese amber fossils are thus not only the oldest putative records of these 2 genera, but also the only records outside their current biogeographical areas. An obvious question is whether the modern representatives are relicts of previously much wider distributions. Alternatively, are these Australasian genera Gondwanan in origin, with lineages that migrated into the area that became the Burmese amber forest prior to the mid-Cretaceous? Burmese amber was deposited on the so-called West Burma terrane which is presumed to have rifted from northern Australia at some point in Earth history. It forms part of the Incertus Arc which in some models is thought to have formed in the Late Jurassic (about 155 Ma) and was potentially linked to northern Australia and India via the Woyla Arc (see e.g. Hall, Reference Hall2012). This connection may have provided a short window of land bridges for colonization of the Burma terrane by Gondwanan faunal elements, before the bridges were lost at the beginning of the Cretaceous (ca. 140 Ma). By the time of amber deposition (ca. 100 Ma) the Burmese amber forest was probably on an island (e.g. Westerweel et al., Reference Westerweel, Roprech, Licht, Dupont-Nivet, Win, Poblete, Ruffet, Swe, Thi and Aung2019), which eventually collided with southeast Asia.

This scenario would be consistent with Bothriocroton and Archaeocroton originating in Gondwana, with some lineages migrating onto the West Burma terrane and surviving until at least the mid-Cretaceous. Similarly, it explains the presence of an Australasian-like Ixodes in Burmese amber reported by Chitimia-Dobler et al. (Reference Chitimia-Dobler, Mans, Handschuh and Dunlop2022). Mans et al.'s (Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019) estimate of (maximally) 186 Ma for the radiation of metastriate ticks and 164 Ma for the divergence of the main metastriate lineages is well before the date at which the land bridges may have been lost (140 Ma). In other words, metastriates in Gondwanan territories may have diversified into the current genera just prior to the time when they could have still made their way onto the West Burma terrain. If this was not the case, and if the Burmese amber fauna were to be shown to be predominantly Laurasian in origin, the disjunct distribution for Bothriocroton and Archaeocroton in Burmese amber and in Australia and New Zealand, respectively needs explanation. Either a very broad former distribution across Asia and Australasia needs to be explained, or a more recent, probably post-Cretaceous, migration of these ticks from Asia to Australasia, plus the extinction of the genera in Asia needs to be inferred.

An interesting parallel case of Burmese amber hosting an endemic New Zealand taxon is the beetle genus Cyclaxyra Broun, 1893 (Cyclaxyridae) (Wu et al., Reference Wu, Li and Ding2018). Further examples of Burmese amber beetles which are morphologically very similar to living relatives restricted to an austral distribution (e.g. Australia, New Zealand, southern South America) were discussed by Cai et al. (Reference Cai, Lawrence, Yamamoto, Leschen, Newton, Ślipiński, Yin, Huang and Engel2019 and references therein). They suggested that the modern populations may be relicts of a previously much wider distribution.

Hosts of the living relatives

Examining the hosts of modern Bothriocroton and Archaeocroton species may also be informative for reconstructing the evolutionary history of these genera. Bothriocroton hydrosauri and B. tachyglossi have been mostly collected from the short-beaked echidna, or spiny anteater, Tachyglossus aculeatus (Shaw, 1792) (Monotrema: Tachyglossidae). In detail, Andrews et al. (Reference Andrews, Beveridge, Bull, Chilton, Dixon and Petney2006) reported the 2 species from Wowan, Queensland, Boompa, Monto, Gladstone, Woolooga, Biloela, Rockhampton, Emu Park, Belmont, Yeppoon, St Lawrence, Mackay, Marian; from cattle in Dululu, Mackay, Degilbo and from an unknown host in Woolooga, Queensland. Putative specimens of ‘A. hydrosauri’ from a snake from the Darling Downs proved, on re-examination, to be B. undatum. In summary, no specimens of B. hydrosauri or B. tachyglossi were seen from reptiles in Queensland or from echidnas in southern Queensland (Andrews et al., Reference Andrews, Beveridge, Bull, Chilton, Dixon and Petney2006). Bothriocroton glebopalma has been described from the black-palmed rock monitor lizard Varanus glebopalma Mitchell, 1955 and the Kimberly rock monitor Varanus glauerti Mertens, 1957 in Western Australia and the Northern Territory. Some specimens were collected from formalin-preserved hosts, revealing that all stages of B. glebopalma parasitize monitor lizards (Keirans et al., Reference Keirans, King and Sharrad1994). Bothriocroton glebopalma was found in an area where A. fimbriatum, a parasite of monitor lizards and various species of snakes, was the only known member of the genus found in both regions mentioned above (Keirans et al., Reference Keirans, King and Sharrad1994). However, the same study also described Amblyomma glauerti Keirans, King and Sharrad, Reference Keirans, King and Sharrad1994 that occur in the same regions and parasitize the same hosts.

The living species which best matches the new fossils, B. undatum, has also been recorded from echidnas, snakes and monitor lizards (e.g. Roberts, Reference Roberts1964). In a wider context, Chitimia-Dobler et al. (Reference Chitimia-Dobler, Pfeffer and Dunlop2018) reviewed parameters in the fossil record for host–parasite co-evolution in ticks. It is conceivable that B. muelleri fed on dinosaurs or reptiles in the Burmese amber forests similar to related Bothriocroton lineages in Australasia. The Cretaceous–Palaeogene extinction event may have caused extant Bothriocroton species to undergo host switches to monotremes or to remain with reptiles.

A fossil assignable to Archaeocroton is of particular interest in that the only living species is hosted by the tuatara. The host lives in borrows associated with the fairy prion bird, Pachyptila turtur (Kuhl, 1820). Although this bird has been found infested with Ixodes auritulus Neumann, 1904, it has never been found carrying A. sphenodonti, which suggests that the tuatara tick is quite host-specific (Dumbleton, Reference Dumbleton1943). The tuatara is, of course, the only living representative of the Rhynchocephalia. This clade is the sister group of Squamata (i.e. lizards and snakes), many of which host species of Amblyomma. As such, a tick with several plesiomorphic characters is associated with a reptile popularly considered to be a ‘living fossil’ (Cree, Reference Cree2014). In fact, the living fossil moniker has been challenged, or at least requires careful definition, as the tuatara belongs to a previously much more diverse lineage (Rauhut et al., Reference Rauhut, Heyng, López-Arbarello and Hecker2012; Herrera-Flores et al., Reference Herrera-Flores, Stubbs and Benton2017) with rhyncocephalians originating in the Triassic and diversifying in the Jurassic. The new amber fossil may have also used a rhyncocephalian host. Although diversity dropped after the Jurassic, several rhyncocephalian lineages were still present during the mid-Cretaceous (Herrera-Flores et al., Reference Herrera-Flores, Stubbs and Benton2017, Fig. 1), even if the known fossil genera of similar age to the Burmese amber forest are all American rather than Asian. Determination of the host(s) of the fossil A. kaufmani sp. nov. would be an intriguing prospect, but for the moment remains equivocal.

Tick evolutionary tree

As noted above, Bothriocroton and Archaeocroton belong to the Metastriata; a clade encompassing all hard ticks excluding Ixodes. In detail, Metastriata includes 14 extant and 2 extinct genera. Recent molecular studies have clarified relationships between metastriate genera to some extent (Mans et al., Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019, Reference Mans, Kelava, Pienaar, Featherston, de Castro, Quetglas, Reeves, Durden, Miller, Laverty, Shao, Takano, Kawabata, Moustafa, Nakao, Matsuno, Greay, Evasco, Barker and Barker2021; Kelava et al., Reference Kelava, Mans, Shao, Moustafa, Matsuno, Takano, Kawabata, Sato, Fujita, Ze, Plantard, Hornok, Gao, Barker, Barker and Nakao2021). As such, deep divergences exist at the base of the metastriate tree that result in various separate lineages (Fig. 9). This includes a separate lineage composed of Archaeocroton, Bothriocroton, Haemaphysalis sensu stricto and Haemaphysalis (Allocereae) and a lineage composed of Africaniella and Robertsicus. The extinct Compluriscutula may represent another distinct lineage closely related to either of these prior lineages. Another lineage includes Amblyomma and the Rhipicephalinae (Anomalohimalaya, Cosmiomma, Dermacentor, Hyalomma, Margaropus, Rhipicephalus and Rhipicentor). This latter lineage probably also includes the extinct Cornupalpatum. Possible reasons for the current inability to define the basal relationships of the metastriate genera more clearly may be the rapid diversification of lineages as well as possible extinction of various metastriate genera (represented by Compluriscutula and Cornupalpatum, but probably others as well). Previous hard ticks from Burmese amber documented Amblyomminae (Chitimia-Dobler et al., Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017) and Haemaphysalinae (Chitimia-Dobler et al., Reference Chitimia-Dobler, Pfeffer and Dunlop2018) and now a third subfamily: Bothriocrotoninae. In the phylogeny presented above this represents one of the first lineages to branch off from the metastriate stem.

Fig. 9. Evolutionary tree, revised and modified from Chitimia-Dobler et al. (Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017, Fig. 3). Included here is Peñalver et al.'s (Reference Peñalver, Arillo, Delclòs, Peris, Grimaldi, Anderson, Nascimbene and Pérez-de la Fuente2017) extinct, mid-Cretaceous Burmese amber genus Deinocroton, which is thought to be close to Nuttalliella, the extinct genus Khimaira and the extant genera Ixodes and Haemaphysalis (Chitimia-Dobler et al., Reference Chitimia-Dobler, Pfeffer and Dunlop2018, Reference Chitimia-Dobler, Mans, Handschuh and Dunlop2022), together with the new Cretaceous records of Archaecroton and Bothriocroton (this study). The phylogeny and estimated times of divergence are according to Barker and Murrell (Reference Barker and Murrell2004), Mans et al. (Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019), Mans et al. (Reference Mans, Kelava, Pienaar, Featherston, de Castro, Quetglas, Reeves, Durden, Miller, Laverty, Shao, Takano, Kawabata, Moustafa, Nakao, Matsuno, Greay, Evasco, Barker and Barker2021) and Kelava et al. (Reference Kelava, Mans, Shao, Moustafa, Matsuno, Takano, Kawabata, Sato, Fujita, Ze, Plantard, Hornok, Gao, Barker, Barker and Nakao2021).

Metastriata is estimated to have split off from Prostriata (=Ixodes) in the Early Triassic (ca. 234 ± 18 Ma) with a further putative divergence into the modern genera in the Early Cretaceous at ca. 180 ± 15 Ma (Mans et al., Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019). In other words, the Burmese amber fossils assigned to the Amblyomminae, Haemaphysalinae and now also Bothriocrotoninae and Archaeocrotininae came from a time after the suggested radiation into living genera (Fig. 9). Bothriocroton and Amblyomma, representing the 2 most basal subfamilies (as well as Archaeocroton) tend to be found on reptiles (see also above), while Haemaphysalis tends to be associated with mammals. The subfamily Rhipicephalinae – which are exclusively found on placental mammals – may well be much earlier to the suggested radiation and is currently only known convincingly from a handful of subfossil records.

In this context, a putative Baltic amber example of the rhipicephaline genus Hyalomma in de la Fuente (Reference de la Fuente2003) was treated as a misidentified caeculid mite by E. Sidorchuk in Chitimia-Dobler et al. (Reference Chitimia-Dobler, De Araujo, Ruthensteiner, Pfeffer and Dunlop2017). Its interpretation as a tick was defended by Estrada-Peña and de la Fuente (Reference Estrada-Peña and de la Fuente2018), who suggested that the distinctive inward-facing ‘rakes’ on the legs could be artefacts of setae covered with debris. This interpretation remains unconvincing. The fossil in question was originally interpreted as male, and is now considered a female, and a clear expression of characters belonging to Hyalomma, or to ticks in general, is absent. For this reason, the amber Hyalomma record is excluded from Fig. 9 and suggests that it remains an unreliable calibration point for molecular clock studies as was used previously (Sands et al., Reference Sands, Apanaskevich, Matthee, Horak, Harrison, Karim, Mohammad, Mumcuoglu, Rajakaruna, Santos-Silva and Matthee2017; Mans et al., Reference Mans, Featherston, Kvas, Pillay, de Klerk, Pienaar, de Castro, Schwan, Lopez, Teel, Pérez de León, Sonenshine, Egekwu, Bakkes, Heyne, Kanduma, Nyangiwe, Bouattour and Latif2019).

In conclusion, the Burmese amber fossils have to date yielded a remarkable assemblage of tick fossils of both extant and extinct families and genera. This includes the extinct families and genera Deinocrotonidae, Khimairidae, Compluriscutula and Cornupalpatum, respectively. It also includes the extant genera, notably the prostriate Ixodes and the metastriate Amblyomma, Archaecroton, Bothriocroton and Haemaphysalis, giving them minimum dates of origin of at least 100 Ma that serve as valuable calibration points for molecular dating. There is a ray of hope that future findings will highlight more genera that will deepen our understanding of tick evolution.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182022001585.

Data

All data generated or analysed during this study are included in this published article (and its supplementary files).

Acknowledgements

We thank Patrick Müller for making this material available for study and Andy Ross for comments on the biogeography of Burmese amber arthropods. We also thank Santiago Nava and Richard Robbins for providing literature.

Author's contributions

L. C.-D. shot the photographs, described the species; B. J. M. contributed to the description and interpreted the tick evolution; S. H. carried out the micro-CT scanning providing images and videos for the description; J. A. D. made the drawing for all specimens. L. C.-D., B. J. M. and J. A. D. wrote the manuscript. All authors read and proofed the final version of the manuscript.

Financial support

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conflict of interest

We acknowledge the current sociopolitical conflict in northern Myanmar that resumed in 2017. We have limited our research to material predating this conflict. We hope that research on specimens collected before the conflict, while acknowledging the situation in Kachin state will raise awareness of this current conflict and its associated human cost.

References

Andrews, RH, Beveridge, I, Bull, CM, Chilton, NB, Dixon, B and Petney, T (2006) Systematic status of Aponomma tachyglossi Roberts (Acari: Ixodidae) from echidnas, Tachyglossus aculeatus, from Queensland, Australia. Systematic and Applied Acarology 11, 2339.CrossRefGoogle Scholar
Apanaskevich, DA and Horak, IG (2008) The genus Hyalomma Koch, 1844: V. Re-evaluation of the taxonomic rank of taxa comprising the H. (Euhyalomma) marginatum Koch complex of species (Acari: Ixodidae) with re-description of all parasitic stages and notes on biology. International Journal of Acarology 34, 1342.CrossRefGoogle Scholar
Bakkes, DK, De Klerk, D, Latif, AA and Mans, BJ (2018) Integrative taxonomy of Afrotropical Ornithodoros (Ornithodoros) (Acari: Ixodida: Argasidae). Ticks and Tick-borne Diseases 9, 10061037.CrossRefGoogle ScholarPubMed
Barker, SC and Burger, TD (2018) Two new genera of hard ticks, Robertsicus n. gen. and Archaeocroton n. gen., and the solution to the mystery of Hoogstraal's and Kaufman's ‘primitive’ tick from the Carpathian Mountains. Zootaxa 4500, 543552.CrossRefGoogle Scholar
Barker, SC and Murrell, A (2004) Systematics and evolution of ticks with a list of valid genus and species names. Parasitology 129, S15S36.CrossRefGoogle ScholarPubMed
Barker, SC, Walker, AR and Campelo, D (2014) A list of the 70 species of Australian ticks; diagnostic guides to and species accounts of Ixodes holocyclus (paralysis tick), Ixodes cornuatus (southern paralysis tick) and Rhipicephalus australis (Australian cattle tick); and consideration of the place of Australia in the evolution of ticks with comments on four controversial ideas. International Journal of Parasitology 44, 941953.CrossRefGoogle ScholarPubMed
Beati, L, Keirans, JE and Durden, LA (2008) Bothriocroton oudemansi (Neumann, 1910) n. comb. (Acari: Ixodida: Ixodidae), an ectoparasite of western long-beaked echidna in Papua New Guinea: redescription of the male and first description of the female and nymph. Systematic Parasitology 69, 185200.CrossRefGoogle ScholarPubMed
Cai, C, Lawrence, JF, Yamamoto, S, Leschen, RAB, Newton, AF, Ślipiński, A, Yin, Z, Huang, D and Engel, MS (2019) Basal polyphagan beetles in mid-Cretaceous amber from Myanmar: biogeographic implications and long-term morphological stasis. Proceedings of the Royal Society B: Biological Sciences 286, 20182175.CrossRefGoogle ScholarPubMed
Camicas, J-L, Hervy, JP, Adam, F and Morel, P-C (1998) The Ticks of the World. Nomenclature, Described Stages, Hosts, Distribution (Acarida: Ixodida). Paris: Orstom.Google Scholar
Campana-Rouget, Y (1959 a) La tératologie des tiques. Annales de Parasitologie Humaine et Comparee 34, 209260 (in French).CrossRefGoogle Scholar
Campana-Rouget, Y (1959 b) La tératologie des tiques (fin). Annales de Parasitologie Humaine et Comparee 34, 354431 (in French).CrossRefGoogle Scholar
Chitimia-Dobler, L, De Araujo, BC, Ruthensteiner, B, Pfeffer, T and Dunlop, JA (2017) Amblyomma birmitum a new species of hard tick in Burmese amber. Parasitology 144, 14111448.CrossRefGoogle ScholarPubMed
Chitimia-Dobler, L, Pfeffer, T and Dunlop, JA (2018) Haemaphysalis cretacea a nymph of a new species of hard tick in Burmese amber. Parasitology 145, 14401451.CrossRefGoogle ScholarPubMed
Chitimia-Dobler, L, Mans, BJ, Handschuh, S and Dunlop, JA (2022) A remarkable assemblage of ticks from mid-Cretaceous Burmese amber. Parasitology 149, 820830.CrossRefGoogle ScholarPubMed
Clifford, CM and Anastos, G (1960) The use of chaetotaxy in the identification of larval ticks (Acarina: Ixodidae). Journal of Parasitology 46, 567578.CrossRefGoogle Scholar
Clifford, CM, Anastos, G and Elbl, A (1961) The larval ixodid ticks of the Eastern United States (Acarina: Ixodidae). Miscellaneous Publications of the Entomological Society of America 2, 213237.Google Scholar
Cree, A (2014) Tuatara: Biology and Conservation of a Venerable Survivor. Canterbury: Canterbury University Press, 584pp.Google Scholar
de la Fuente, J (2003) The fossil record and the origin of ticks (Acari: Parasitiformes: Ixodida). Experimental and Applied Acarology 29, 331344.CrossRefGoogle ScholarPubMed
Dergousoff, SJ and Chilton, NB (2007) Abnormal morphology of an adult Rocky Mountain wood tick, Dermacentor andersoni (Acari: Ixodidae). Journal of Parasitology 93, 708709.CrossRefGoogle ScholarPubMed
Dumbleton, LJ (1943) A new tick from the tuatara (Sphenodon punctatus). New Zealand Journal of Science and Technology 24, 185B190B.Google Scholar
Dunlop, JA, Apanaskevich, DA, Lehmann, J, Hoffmann, R, Fusseis, F, Ehlke, M, Zachow, S and Xiao, X (2016) Microtomography of the Baltic amber tick Ixodes succineus reveals affinities with the modern Asian disease vector Ixodes ovatus. BMC Evolutionary Biology 16, 203.CrossRefGoogle ScholarPubMed
Estrada-Peña, A and de la Fuente, J (2018) The fossil record and the origin of ticks revisited. Experimental and Applied Acarology 75, 255261.CrossRefGoogle ScholarPubMed
Feldman-Muhsam, B (1948) On some abnormalities in Hyalomma savignyi. Parasitology 40, 9395.CrossRefGoogle Scholar
Filippova, NA (1997) Ixodid ticks of the subfamily Amblyomminae. In Fauna of Russia and neighbouring countries. 4 Nauka, St. Petersburg: Nauka Publishing House.Google Scholar
Godfrey, SS, Bull, CM and Nelson, NJ (2008) Seasonal and spatial dynamics of ectoparasite infestation of a threatened reptile, the tuatara (Sphenodon punctatus). Medical and Veterinary Entomology 22, 374385.CrossRefGoogle ScholarPubMed
Grimaldi, DA, Engel, MS and Nascimbene, PC (2002) Fossiliferous Cretaceous amber from Myanmar (Burma): its rediscovery, biotic diversity, and paleontological significance. American Museum Novitates 3361, 171.2.0.CO;2>CrossRefGoogle Scholar
Guglielmone, AA and Nava, S (2014) Names for Ixodidae (Acari: Ixodoidea): valid, synonyms, incertae sedis, nomina dubia, nomina nuda, lapsus, incorrect and suppressed names – with notes on confusions and misidentifications. Zootaxa 3767, 1256.CrossRefGoogle ScholarPubMed
Guglielmone, AA, Castella, J, Mangold, AJ, Estrada-Peña, A and Viñabal, EA (1999) Phenotypic anomalies in a collection of Neotropical ticks (Ixodidae). Acarologia 40, 127132.Google Scholar
Guglielmone, AA, Robbins, RG, Apanaskevich, DA, Petney, TN, Estrada-Peña, A, Horak, IG, Shao, R and Barker, SC (2010) The Argasidae, Ixodidae and Nuttalliellidae (Acari: Ixodida) of the world: a list of valid species names. Zootaxa 2528, 128.CrossRefGoogle Scholar
Guglielmone, AA, Robbins, RG, Apanaskevich, DA, Petney, TN, Estrada-Peña, A and Horak, IG (2014) The Hard Ticks of the World (Acari: Ixodida: Ixodidae). Berlin: Springer.CrossRefGoogle Scholar
Hall, R (2012) Late Jurassic–Cenozoic reconstructions of the Indonesian region and the Indian Ocean. Tectonophysics 570–571, 141.CrossRefGoogle Scholar
Herrera-Flores, JA, Stubbs, TL and Benton, MJ (2017) Macroevolutionary patterns in Rhynchocephalia: is the tuatara (Sphenodon punctatus) a living fossil? Paleontology 60, 319328.CrossRefGoogle Scholar
Horak, IG, Camicas, J-L and Kierans, JE (2002) The Argasidae, Ixodidae and Nuttalliellidae (Acari: Ixodida): a world list of valid tick names. Experimental and Applied Acarology 28, 2754.CrossRefGoogle ScholarPubMed
Hornok, S, Kontschán, J, Takács, N, Chaber, A, Halajian, A, Abichu, G, Kamani, J, Szekeres, S and Plantard, O (2020) Molecular phylogeny of Amblyomma exornatum and Amblyomma transversale, with reinstatement of the genus Africaniella (Acari: Ixodidae) for the latter. Ticks and Tick-borne Diseases 11, 101494.CrossRefGoogle ScholarPubMed
Kaufman, TS (1972) A Revision of the Genus Aponomma Neumann, 1899 (Acarina: Ixodidae). PhD thesis. University of Maryland, College Park, United States of America.Google Scholar
Keirans, JE, William, G and Degenhardt, WG (1985) Aponomma elaphense Price, 1959 (Acari: Ixodidae): diagnosis of the adults and nymph with first description of the larva. Proceedings of the Biological Society of Washington 98, 711717.Google Scholar
Keirans, JE, King, DR and Sharrad, RD (1994) Aponomma (Bothriocroton) glebopalma, n. subgen., n. sp., and Amblyomma glauerti n. sp. (Acari: Ixodida: Ixodidae), parasites of monitor lizards (Varanidae) in Australia. Journal of Medical Entomology 31, 132147.CrossRefGoogle Scholar
Kelava, S, Mans, BJ, Shao, R, Moustafa, MAM, Matsuno, K, Takano, A, Kawabata, H, Sato, K, Fujita, H, Ze, C, Plantard, O, Hornok, S, Gao, S, Barker, D, Barker, SC and Nakao, R (2021) Phylogenies from mitochondrial genomes of 120 species of ticks: insights into the evolution of the families of ticks and of the genus Amblyomma. Ticks and Tick-borne Diseases 12, 101577.CrossRefGoogle ScholarPubMed
Klompen, JSH, Black, WC IV, Keirans, JE and Oliver, JH Jr. (1996) Evolution of ticks. Annual Review of Entomology 41, 141161.CrossRefGoogle ScholarPubMed
Klompen, JSH, Oliver, JH Jr., Keirans, JE and Homsher, PJ (1997) A re-evaluation of relationships in the Metastriata (Acari: Parasitiformes: Ixodida). Systematic Parasitology 38, 124.CrossRefGoogle Scholar
Klompen, JSH, Dobson, SJ and Barker, SC (2002) A new subfamily, Bothriocrotoninae n. subfam., for the genus Bothriocroton Keirans, King & Sharrad, 1994 status amend (Ixodida: Ixodidae), and the synonymy of Aponomma Neumann, 1899 with Amblyomma Koch, 1844. Systematic Parasitology 53, 101107.CrossRefGoogle ScholarPubMed
Lamarck, JB (1801) Systême des animaux sans vertèbres, ou Tableau général desclasses, des ordres et des genres de ces animaux. Chez L'auteur, au Muséum d'Hist. Naturelle, An IX, Paris, pp. 1472.Google Scholar
Latif, AA, Dhadialla, TS and Newson, RM (1988) Abnormal development of Amblyomma variegatum (Acarina: Ixodidae). Journal of Medical Entomology 25, 142143.CrossRefGoogle ScholarPubMed
Leach, WE (1815) A tabular view of the external characters of four classes of animals, which Linné arranged under Insecta; with the distribution of the genera composing three of these classes into orders, &c. and descriptions of several new genera and species. Transactions of the Linnean Society of London 11, 306400.CrossRefGoogle Scholar
Lindquist, EE, Galloway, TD, Artsob, H, Lindsay, LR, Drebot, M, Wood, H and Robbins, RG (2016) A handbook to the ticks of Canada (Ixodida: Ixodidae, Argasidae). Biological Survey of Canada 7, 1317.Google Scholar
Madder, M, Horak, I and Stoltz, H (2010) Ticks. Tick Identification. Pretoria: University of Pretoria, Faculty of Veterinary Science, 58pp.Google Scholar
Mans, BJ, de Klerk, D, Pienaar, R, Castro, MH and Latif, AA (2012) The mitochondrial genomes of Nuttalliella namaqua (Ixodoidea: Nuttalliellidae) and Argas africolumbae (Ixodoidea: Argasidae): estimation of divergence dates for the major tick lineages and reconstruction of ancestral blood-feeding characteristics. PLoS One 7, e4946.CrossRefGoogle Scholar
Mans, BJ, Featherston, J, Kvas, M, Pillay, KA, de Klerk, DG, Pienaar, R, de Castro, MH, Schwan, TG, Lopez, JE, Teel, P, Pérez de León, AA, Sonenshine, DE, Egekwu, NI, Bakkes, DK, Heyne, H, Kanduma, EG, Nyangiwe, N, Bouattour, A and Latif, AA (2019) Argasid and ixodid systematics: implications for soft tick evolution and systematics, with a new argasid species list. Ticks and Tick-borne Diseases 10, 219240.CrossRefGoogle ScholarPubMed
Mans, BJ, Kelava, S, Pienaar, R, Featherston, J, de Castro, MH, Quetglas, J, Reeves, WK, Durden, LA, Miller, MM, Laverty, TM, Shao, R, Takano, A, Kawabata, H, Moustafa, MAM, Nakao, R, Matsuno, K, Greay, TL, Evasco, KL, Barker, D and Barker, SC (2021) Nuclear (18S–28S rRNA) and mitochondrial genome markers of Carios (Carios) vespertilionis (Argasidae) support Carios Latreille, 1796 as a lineage embedded in the Ornithodorinae: re-classification of the Carios sensu Klompen and Oliver (1993) clade into its respective subgenera. Ticks and Tick-borne Diseases 12, 101688.CrossRefGoogle ScholarPubMed
Murray, A (1877) Economic Entomology. London: Chapman & Hall, pp. 190207.CrossRefGoogle Scholar
Neumann, LG (1899) Révision de la famille des ixodidés (3e mémoire). Mémoires de la Société Zoologique de France 12, 107294.Google Scholar
Neumann, LG (1910) Description de deux nouvelles espèces d'Ixodinae. Tijdschrift voor Entomologie 53, 1117.Google Scholar
Neumann, LG (1911) Ixodidae. Das Tierreich 26, 1169.Google Scholar
Nowak-Chmura, M (2012) Teratological changes in tick morphology in ticks feeding on exotic reptiles. Journal of Natural History 46, 911921.CrossRefGoogle Scholar
Nuttall, GHF, Warburton, C, Cooper, WF and Robinson, LE (1911) Ticks. A Monograph of the Ixodoidea, Part 2. Cambridge: Cambridge University Press.Google Scholar
Peñalver, E, Arillo, A, Delclòs, X, Peris, D, Grimaldi, DA, Anderson, SR, Nascimbene, PC and Pérez-de la Fuente, R (2017) Ticks parasitized feathered dinosaurs as revealed by Cretaceous amber assemblages. Nature Communications 8, 1024.CrossRefGoogle ScholarPubMed
Poinar, GO Jr. (2018) Burmese amber: evidence of Gondwanan origin and Cretaceous dispersion. Historical Biology 31, 13041309.Google Scholar
Poinar, GO Jr. and Brown, AE (2003) A new genus of hard ticks in Cretaceous Burmese amber (Acari: Ixodida: Ixodidae). Systematic Parasitology 54, 199205.CrossRefGoogle ScholarPubMed
Poinar, GO Jr. and Buckley, R (2008) Compluriscutula vetulum (Acari: Ixodida: Ixodidae), a new genus and species of hard tick from Lower Cretaceous Burmese amber. Proceedings of the Entomological Society of Washington 110, 445450.CrossRefGoogle Scholar
Price, MA (1958) A new species of tick from the Trans-Pecos region of Texas. Journal of Parasitology 4, 649651.CrossRefGoogle Scholar
Rauhut, OWM, Heyng, AM, López-Arbarello, A and Hecker, A (2012) A new rhynchocephalian from the Late Jurassic of Germany with a dentition that is unique amongst tetrapods. PLoS One 7, e46839.CrossRefGoogle ScholarPubMed
Reuter, ER (1909) Morphologie und Ontogenie der Acariden mit besonderer Berücksichtigung von Pediculopsis graminum (E. Reut.). Acta Societatis Scientiarum Fennicae 36, 1288.Google Scholar
Roberts, FHS (1953) The Australian Species of Aponomma and Amblyomma (Ixodoidea). Yeerongpilly, Queensland: Division of Animal Health and Production, C.S.I.R.O., Veterinary Parasitology Laboratory, 159pp.CrossRefGoogle Scholar
Roberts, FHS (1964) Further observations on the Australian species of Aponomma and Amblyomma with descriptions of the nymphs of Amblyomma morelliae (L. Koch) and Amb. loculosum Neumann (Acarina: Ixodidae). Australian Journal of Zoology 12, 288313.CrossRefGoogle Scholar
Ross, AJ (2021) Burmese (Myanmar) amber taxa, on-line supplement v.2021.1. 27pp. Available at http://www.nms.ac.uk/explore/stories/natural-world/burmese-amber/.Google Scholar
Ross, AJ, Mellish, C, York, P and Crighton, B (2010) Burmese amber. In Penney, D (ed.), Biodiversity of Fossils in Amber from the Major World Deposits. Manchester: Siri Scientific Press, pp. 208235.Google Scholar
Sands, AF, Apanaskevich, DA, Matthee, S, Horak, IG, Harrison, A, Karim, S, Mohammad, MK, Mumcuoglu, KY, Rajakaruna, RS, Santos-Silva, MM and Matthee, CA (2017) Effects of tectonics and large scale climatic changes on the evolutionary history of Hyalomma ticks. Molecular Phylogenetics and Evolution 114, 153165.CrossRefGoogle ScholarPubMed
Saratsiotis, A (1972) Contribution a l’étude morphologique et biologique du genre Aponomma Neumann, 1899 (Acariens, Ixodidea). Acarologia 13, 476494.Google Scholar
Schachat, SR, Robbins, RG and Goddard, J (2018) Color patterning in hard ticks (Acari: Ixodidae). Journal of Medical Entomology 55, 113.CrossRefGoogle ScholarPubMed
Schulze, P (1935) Zur Kenntnis der Zeckengattung Aponomma Neum. Zoologischer Anzeiger 112, 327331.Google Scholar
Schulze, P (1936) Neue und wenig bekannte Amblyommen und Aponommen aus Afrika, Südamerika, Indien, Borneo und Australien (Ixodidae). Parasitenkunde 8, 619637.CrossRefGoogle Scholar
Selden, PA and Ren, D (2017) A review of Burmese amber arachnids. Journal of Arachnology 45, 324343.CrossRefGoogle Scholar
Shi, G-H, Grimaldi, DA, Harlow, GE, Wang, J, Yang, M-C, Lei, W-Y, Li, Q and Li, X-H (2012) Age constraints on Burmese amber based on U–Pb dating of zircons. Cretaceous Research 37, 155163.CrossRefGoogle Scholar
Smith, RDA and Ross, AJ (2018) Amberground pholadid bivalve borings and inclusions in Burmese amber: implications for proximity of resin-producing forests to brackish waters, and the age of the amber. Earth and Environmental Science Transactions of the Royal Society of Edinburgh 107, 239247.CrossRefGoogle Scholar
Sonenshine, D and Roe, RM (eds) (2013) Biology of Ticks, 2nd Edn. Bands 1–2. Oxford: Oxford University Press.Google Scholar
Theiler, G (1945 a) Ticks in the South African Zoological Survey Collection. Part III. The ornate Aponommas. Onderstepoort Journal of Veterinary Science and Animal Industry 20, 165178.Google Scholar
Theiler, G (1945 b) Ticks in the South African Zoological Survey Collection. Part IV. The inornate Aponommas. Onderstepoort Journal of Veterinary Science and Animal Industry 20, 179190.Google Scholar
Voltzit, OV (2007) A review of Neotropical Amblyomma species (Acari: Ixodidae). Acarina 15, 3134.Google Scholar
Voltzit, OV and Keirans, JE (2002) A review of Asian Amblyomma species (Acari, Ixodida, Ixodidae). Acarina 10, 95136.Google Scholar
Voltzit, OV and Keirans, JE (2003) A review of African Amblyomma species (Acari, Ixodida, Ixodidae). Acarina 11, 135214.Google Scholar
Westerweel, J, Roprech, P, Licht, A, Dupont-Nivet, G, Win, Z, Poblete, F, Ruffet, G, Swe, HH, Thi, MK and Aung, DW (2019) Burma Terrane part of the Trans-Tethyan arc during collision with India according to palaeomagnetic data. Nature Geoscience 12, 863868.CrossRefGoogle ScholarPubMed
Wu, H, Li, L and Ding, M (2018) The first cyclaxyrid beetle from Upper Cretaceous Burmese amber (Coleoptera: Cucujoidea: Cyclaxyridae). Cretaceous Research 91, 6670.CrossRefGoogle Scholar
Zharkov, SD, Dubinina, HV, Alekseev, AN and Jensen, PM (2000) Anthropogenic pressure and changes in Ixodes tick populations in the Baltic region of Russia and Denmark. Acarina 8, 137141.Google Scholar
Figure 0

Fig. 1. Holotype of Bothriocroton muelleri sp. nov., P. Müller collection no. BUB1544, from Late Cretaceous (ca. 100 Ma) Burmese amber from Myanmar. (A) Dorsal overview. (B) Ventral overview. (C) Coxal spurs (arrowed). (D) Posterior idiosoma showing Y-shaped anal groove, extruded spiracle plates (arrowed) and 11 festoons (numbered). (E) Capitulum, including palps with long second article and hypostome with 2/2 dentition. (F) Leg I tarsus with prominent distal hump (arrowed) plus 6 additional lobes. (G) Leg IV tarsus with small hump (arrowed). Scale bars equal 1 mm (A, B), 250 μm (C), 500 μm (D) and 200 μm (E–G).

Figure 1

Fig. 2. Camera lucida drawings of the specimen shown in Fig. 1. (A) Dorsal view. (B) Ventral view. (C) Details of leg I tarsus including humped distal region plus 6 additional lobes (numbered). (D) Details of capitulum; palpal articles numbered, note the elongate second article. (E) Details of leg IV tarsus with small hump. Legs numbered from I to IV. Scale bars equal 500 μm (A, B) and 100 μm (C–E).

Figure 2

Fig. 3. Paratype of B. muelleri sp. nov., P. Müller collection no. BUB1573, from Late Cretaceous (ca. 100 Ma) Burmese amber from Myanmar. (A) Dorsal overview. (B) Ventral overview. (C) Scutum showing large punctuations, cervical grooves (arrowed), but no evidence of eyes; note also several white, peg-like setae on the idiosoma. (D) Posterior idiosoma showing Y-shaped anal groove. (E) Capitulum. Scale bars equal 1 mm (A, B), 200 μm (C–E).

Figure 3

Fig. 4. Camera lucida drawings of the paratype specimen shown in Fig. 3. (A) Dorsal view. (B) Ventral view. Legs numbered from I to IV. Scale bar equals 500 μm.

Figure 4

Fig. 5. Holotype and only known specimen of the hard tick Archaeocroton kaufmani sp. nov. (Ixodida: Ixodidae) in the Museum für Naturkunde, Berlin (accession number MB.A. 4452).

Figure 5

Fig. 6. Interpretative camera lucida drawings of the specimen shown in Fig. 5. Legs numbered from I to IV and festoons numbered from 1 to 11.

Figure 6

Fig. 7. CT images of the holotype (penetrating the artefacts) and emphasizing again the presence of 11 festoons (left both above and down). Additionally highlighting the outline of the stigma (left down), chelicera structure (right above) and the 2 + 2 dentition of the hypostome (right down). The volume renderings especially emphasize air-filled cavities in the amber fossil.

Figure 7

Fig. 8. Comparative sketches of the distinctively triangular basis capitulum in dorsal view in the extant tuatara tick, Archaeocroton sphenodonti Dumbleton, 1943 (left), and the new amber species A. kaufmani sp. nov. (right), with the special chelicera structure. Not to scale.

Figure 8

Fig. 9. Evolutionary tree, revised and modified from Chitimia-Dobler et al. (2017, Fig. 3). Included here is Peñalver et al.'s (2017) extinct, mid-Cretaceous Burmese amber genus Deinocroton, which is thought to be close to Nuttalliella, the extinct genus Khimaira and the extant genera Ixodes and Haemaphysalis (Chitimia-Dobler et al., 2018, 2022), together with the new Cretaceous records of Archaecroton and Bothriocroton (this study). The phylogeny and estimated times of divergence are according to Barker and Murrell (2004), Mans et al. (2019), Mans et al. (2021) and Kelava et al. (2021).

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