Abstract
Trombiculid mites were collected from the edible dormouse (Glis glis) within the Carpathian–Balkan distribution gradient of host species. Representatives of five genera (Leptotrombidium, Neotrombicula, Brunehaldia, Hirsutiella, Schoutedenichia) and 10 species of chiggers were discovered in the material, based on morphological and/or molecular data. Brunehaldia, new to the fauna of Greece, was recorded for the first time from the edible dormouse. Neotrombicula talmiensis was new to the fauna of Greece and Neotrombicula vulgaris was new to the fauna of North Macedonia. Successful amplification and sequencing of COI was carried out in relation to three genera and six species. The intraspecific variation of taxa hitherto distinguished based on morphological criteria was juxtaposed with molecular data, using the distance method and the phylogenetic approach. The molecular methods indicated wider than hitherto recognized, intraspecific morphological variation for Leptotrombidium europaeum and N. talmiensis. On the other hand, an inference limited to morphology proved to be insufficient for species delineation, which was confirmed by the relatively low identity (%) of examined COI sequences as well as the size of inter-/intraspecific K2P distance threshold. Our study provides support for integrative taxonomy that combines different sources of evidence and contributes to recognition of the scope of intraspecific variation. The high degree of hidden diversity revealed with the application of molecular tools, votes for a careful approach to the identification of chiggers. The confirmed cases of co-invasion, including the representatives of various genera (Leptotrombidium and Neotrombicula, Brunehaldia and Neotrombicula, Neotrombicula and Schoutedenichia, Hirsutiella and Schoutedenichia) additionally support the need to include all larvae found on a given host specimen in the identification process.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Trombiculidae (sensu Kudryashova 1998; Shatrov and Kudryashova 2008) comprise Trombiculinae, Leeuwenhoekiinae, Gahrliepiinae and Apoloniinae. According to the most recent inventory (Nielsen et al. 2021), 188 genera and 3013 species have been hitherto described for the family (excl. ca. 20 species described in 2021/2022), and around 200 species have been recorded from the western Palearctic (Kudryashova 1998; Stekolnikov and Daniel 2012). The unstable taxonomy of Trombiculidae is shown by the about 5500 synonymies, redescriptions, and new combinations of species names recorded between 1921 and 2021, and summarized by Nielsen et al. (2021).
For over 260 years the specific affiliation of chiggers has been ascertained based on morphology. However, a scarce knowledge of intraspecific variation, as well as species diagnosing based on limited material, without critically addressing all published characteristics of a species, constitute common problems in chigger taxonomy. An additional difficulty concerns the keys for species identification that often refer to the character states of specimens collected from selected areas within the geographic limits of the species, and not to the specimens originating from the entire distribution range. In view of the above but also in view of the great scarcity of other evidence that would support the correct identification of chiggers, any association of a name with a set of morphological—both qualitative and quantitative—characters, is burdened with a risk of misidentification. An additional obstacle lies in the frequently applied ‘serial’ identifications that consider hundreds of specimens assigned to the same species, without paying enough attention to the relatively common phenomenon of co-invasion. The latter may constitute a real pitfall, especially in the case of similar species.
The molecular techniques (with special reference to DNA sequencing) that have been increasingly applied in chigger taxonomy in recent years (e.g., Shao et al. 2006; Moniuszko et al. 2015; Antonovskaia 2018; Jacinavicius et al. 2018) contribute to the verification of species statuses. Their role in answering the question of what is behind a name cannot be overestimated, although for obvious reasons it seems to be a long-term task. In hitherto research, the most often used markers for taxonomic identification of chiggers and inference at various levels of relatedness were the nucleotide sequences of the mitochondrial gene coding for cytochrome oxidase subunit I (COI) (Young et al. 2012; Moniuszko et al. 2017, 2018; Zajkowska and Mąkol 2022), the small ribosomal subunit 18S rRNA (18S) gene (Pepato et al. 2010; Mendoza-Roldan et al. 2017; Bassini-Silva et al. 2018), and—to a lesser extent—the large ribosomal subunit 28S rRNA (Pepato et al. 2010; Klimov et al. 2018). Still limited feedback, compared to some other terrestrial Parasitengona families, is due to the low success rate recorded in the analyzes, as evidenced by the small number of topic-related publications and the small number of sequences assigned to species (> 330 COI sequences; 14 18S rRNA sequences; four 28S rRNA sequences (GenBank, accessed 26 January 2023).
Larvae of Trombiculidae are considered as habitat-specific rather than host-specific ectoparasites (Goff 1979); however, small mammals, such as rodents, bats, and insectivores, are among the most frequent hosts for chiggers (Shatrov and Kudryashova 2008). Here we address the question of species diversity of Trombiculidae infesting the edible dormouse, Glis glis (L.) (Rodentia: Gliridae). The species is considered arboreal (Cornis et al. 2017); however, some literature data (e.g., Vikyrchak and Ploshchansky 2020) point to its tendency to occupy subterranean habitats.
To date, 14 chigger species, identified based on morphology, have been recorded from this host. The inventory of records, provided by Kirillov et al. (2022), comprising 12 species—Ascoschoengastia latyshevi (Schluger), Hirsutiella zachvatkini (Schluger), Leptotrombidium europaeum (Daniel et Brelih), Leptotrombidium silvaticum Hushcha et Schluger, Miyatrombicula muris (Oudemans), Neotrombicula austriaca Kepka, Neotrombicula inopinata (Oudemans), Neotrombicula japonica (Tanaka, Kaiwa, Teramura et Kagaya), Neotrombicula nagayoi (Sasa, Hayashi, Sato, Miura et Asahina), Neotrombicula vernalis (Willmann), Neotrombicula vulgaris (Schluger), and Schoutedenichia sp.—should be completed with two more species, recorded by Kepka (1964) and Mulyarskaya (1965): Neotrombicula autumnalis Shaw and Neotrombicula talmiensis (Schluger). Of those, N. autumnalis has been known as widely distributed within the geographic range of G. glis; however, its status should be verified as likely to represent several taxa. The occurrence of N. vernalis on G. glis reported by Kirillov et al. (2022, referring to Kepka 1964) should be confirmed due to the inconsistency of data provided in the original publication.
The aim of the present study was to trace the species composition of ectoparasitic chiggers associated with G. glis, within the Carpathian–Balkan distribution gradient of the host species. The sampling was focused on subterranean habitats of potential occurrence of the host species. We have also attempted to verify the identity of trombiculid species with the application of molecular techniques to check the congruence between various input data used for species identification.
Material and methods
Sampling
Trombiculid larvae were sampled from edible dormouse in 2020–2022, at underground shelters: bunkers (concrete military tunnels) and caves, in Poland (permissions: WPN.6205.31.2020.MM, WPN.6205.15.2022.MM), Albania, North Macedonia, and Greece (Fig. 1). Rodents were collected using Sherman traps (23 × 8 × 9 cm) in Poland, or caught directly by hand in the other countries. The entire body surface of each potential host specimen was screened for larvae. Parasitized individuals were temporarily transferred to a cotton bag, to avoid cross-contamination with ectoparasitic larvae. Chiggers were removed from the hosts using smooth forceps and transferred directly to 96% EtOH. Afterwards, all rodents were released unharmed in their natural habitat.
DNA extraction, amplification, and sequencing
The genomic DNA was extracted from the entire (non-punctured) larval specimens; the exoskeletons that remained after extraction were mounted on microscope slides for purpose of morphological examination. Polymerase chain reaction, and selection of programs used for sequence analyses follows Zajkowska and Mąkol (2022) and Mironov et al. (2012). The COI gene was PCR amplified by primers LCO1490/HCO2198 (Folmer et al. 1994), bcdF01/bcdR04 or bcdF04/bcdR04 (Dabert et al. 2010), and the nuclear 28S rDNA, including the D2 region, was amplified with primers 28SF0001/28SR0990 (Mironov et al. 2012). In selecting the subset of samples intended for 28S rDNA sequencing, the quality of agarose gel electrophoresis of PCR products was assessed and samples that suggested the separate species affiliation after COI analyses were forwarded for sequencing targeting at 28S rDNA gene. DNA sequencing of PCR products on both strands was performed by Genomed (Poland).
Contigs were assembled in Geneious v.9.1.8 (https://www.geneious.com). Sequence similarity search against sequences stored in GenBank was done using BLASTn search implemented in Geneious. The single haplotype sequences obtained in this study were deposited in the GenBank under the following accession numbers: OQ924402–OQ924413 (COI) and OQ925889–OQ925891 (28S).
Alignment
The multiple sequence alignment consisting of COI and 28S sequences was produced in Geneious using the MAFFT algorithm (gap opening penalty: 1.53). The published sequences of Trombiculidae and of outgroup taxa (Bdellidae spp.) (Table S1), retrieved from GenBank, served for comparison.
Species delimitation
For species delimitation based on COI sequences, a phylogenetic method – generalized mixed Yule coalescent (GMYC; Fujisawa and Barraclough 2013) – was applied, as well as two distance matrix methods – automatic barcode gap discovery (ABGD; Puillandre et al. 2011) and ‘assemble species by automatic partitioning’ (ASAP; Puillandre et al. 2021). The GMYC adopts a likelihood approach to analyze the timing of branching events, seeking for significant switches between a Yule (interspecific) and a coalescent (intraspecific) branching structure (Vences et al. 2021). The maximum likelihood ultra-metric tree was inferred in BEAST v.2.6.7 (Bouckaert et al. 2019). The GMYC analysis was done in R software (R Core Team 2016) using the packages ape, paran, rncl and splits.
The web-based program interfaces were used for ABGD (https://bioinfo.mnhn.fr/abi/public/abgd/), which calculates the pairwise distance based on the barcode gap, and for ASAP (https://bioinfo.mnhn.fr/abi/public/asap), which uses the hierarchical clustering algorithm based on pairwise genetic distances. Genetic distance between sequences (alignments created from COI sequences obtained during this study and those retrieved from GenBank but also the subsets of COI and 28S sequences obtained during the present study) was estimated with Kimura-2 parameter (K2P) substitution model (Kimura 1980) in MegaX (Kumar et al. 2018).
To determine the species affiliation of chiggers, the results of delimitation were compared with the results of morphological analysis.
Morphological analysis
The larvae (the entire specimens as well as exoskeletons that remained after DNA extraction) were mounted on microscope slides in Faure’s fluid (Walter and Krantz 2009). The morphological examination of larvae, including measurements, was carried out under a Nikon Eclipse E600 compound microscope, equipped with differential interference contrast (DIC) and DS-Fi1 camera system, using the NIS-Elements BR software.
In morphological identification of specimens to genus and species level we referred to identification keys as well as to original descriptions and redescriptions (Vercammen-Grandjean and Langston 1976; Kolebinova 1992; Kudryashova 1998; Fernandes and Kulkarni 2003; Stekolnikov and Daniel 2012; Stekolnikov 2013, 2018). The morphological terminology and abbreviations appearing in the text follow Stekolnikov (2013). Additionally, the LV denotes larva/e. The slide-mounted material is stored at the Department of Invertebrate Systematics and Ecology, Wrocław University of Environmental and Life Sciences.
The following sequence of issues was adopted for species accounts: current name, synonymy, material examined (followed by the total number of larvae/larval exoskeletons subjected to morphological analyses and the number of sequences, if obtained; numbers in square parentheses refer to the localities in Fig. 1), diagnosis (incl. verified diagnosis), distribution and hosts, remarks (optional).
Phylogenetic analysis
Models of nucleotide substitution (GTR + G + I) were evaluated for COI alignment (own sequences and sequences retrieved from GenBank) using MegaX based on Bayesian information criterion (BIC) and Akaike’s information criterion (AIC). The maximum likelihood (ML) phylogenetic tree was created with MegaX (Kumar et al. 2018); support values for ML branches were generated with the bootstrap method, with 1000 replicates. The phylogenetic tree visualization was made using iTOL (https://itol.embl.de).
Results
In total, 94 chiggers were collected from 15 specimens of G. glis, at eight localities in Poland, Albania, North Macedonia, and Greece (Fig. 1). Larvae were found exclusively within hosts’ ears (Fig. 2). Fifty-two larvae were selected for further, molecular and/or morphological analyses.
Sequence performance
Of 46 specimens intended for molecular studies, we received 25 COI sequences, which accounted for an overall barcoding success of 54%. We also obtained seven sequences of 28S rDNA. Twelve COI sequences and three 28S sequences were represented by unique haplotypes. Due to the low number of 28S sequences obtained, these sequences could be used for comparative purposes to a limited extent.
The value of genetic divergence between 12 COI single haplotype sequences (Table S2), that produced 573 bp sequence alignment, suggested the presence of three genera in the part of the material examined with the application of molecular tools. The genera were supported by BLASTn comparison, allowing for assignment of the sequences to Leptotrombidium, Neotrombicula and Schoutedenichia. The genetic distance was 35.5–37.5% between Leptotrombidium and Neotrombicula, 40.5–43.6% between Leptotrombidium and Schoutedenichia, and 28.4–32.1% between Neotrombicula and Schoutedenichia.
Molecular species delimitation
The species delimitation was carried out on two subsets of sequences assigned to two genera, Neotrombicula and Leptotrombidium, based on sequence similarity search.
Leptotrombidium alignment (434 bp) composed of 47 single haplotype sequences, including five obtained during the present study and 42 retrieved from GenBank (Table S1), pointed to the occurrence 19 operational taxonomic units (OTU) in ASAP (asap-score = 3.5) and GMYC, and of 19 OTU and 21 (or 22) OTU in ABGD, at initial partition and at recovery partition, respectively. The sequences (n = 5) obtained from chiggers collected from G. glis formed two separate OTUs, with 7.9% distance threshold value, irrespective of the method of delimitation applied. In ASAP and ABGD the barcode gap within Leptotrombidium revealed a 5–10% p-distance between putative species (Fig. 3).
Neotrombicula alignment (439 bp) composed of 10 unique haplotype sequences, including six obtained during the present study and four retrieved from GenBank (Table S1), indicated the occurrence of seven putative species (already at initial partition). Of those, three putative species were represented by larvae collected from G. glis. The results of delimitation were consistent for all three methods, ABGD, ASAP (with asap-score = 1.5), and GMYC. In the case of ABGD and ASAP the same distance threshold value, 8.1%, was calculated. In ASAP and ABGD the barcode gap within Neotrombicula revealed 2–15% and 17–18% p-distance, respectively, between groups representing putative species (Fig. 3).
Species account and taxonomy
At preliminary, morphology-based inference at the level of genus we used four alcohol-preserved specimens and 32 exoskeletons recovered after DNA extraction. In the case of nine slides, their quality did not allow the in-depth morphological analysis, thus four alcohol-preserved specimens and 23 exoskeletons that remained after DNA extraction served for morphology-based, species-level inference.
We confirmed the presence of three genera preliminarily distinguished based on molecular analyses. For the two other genera, in the lack of legible sequences, the morphology served as the only source of identification. Finally, the members of the following genera were recognized in the examined material: Leptotrombidium, Neotrombicula, Schoutedenichia, Hirsutiella and Brunehaldia.
Leptotrombidium
Leptotrombidium europaeum (Daniel et Brelih)
Material examined. 12 LV (one entire specimen and seven exoskeletons mounted on slides; 11 COI sequences): [1] Poland, Chuda Cave, 19 June 2020, leg. TP, 3 LV (two exoskeletons; three COI sequences/one haplotype [OQ924407]); [2] Poland, Wiercica Cave, 20 May 2020, leg. TP, 2 LV (one entire specimen and one exoskeleton; one COI sequence/one haplotype [OQ924402]) and 16 June 2020, leg. TP, 5 LV (two exoskeletons; five COI sequences/two haplotypes [OQ924403 and OQ924406]); [3] Poland, Wilcza Góra Cave, 15 June 2022, leg. PZ, 2 LV (two exoskeletons; two COI sequences). For metric and meristic data see Table 1.
Diagnosis (after Vercammen-Grandjean and Langston 1976; Stekolnikov and Daniel 2012; Stekolnikov 2013). SIF = 7B-B-3-2111.0000; fPp = N/N/BNN; fCx = 1.1.1; fSt = 2.2; fSc: PL > AM > AL; Ip = 7761017; fD = 2H-(8–15)-(8–12)-(711)-(5–11)-(…), basic formula 2H-10-8-8-6-4-2-2; DS = 35–51; VS = 29–51; NDV = 69–102.
Distribution and hosts
Hitherto records originate from Albania, Austria, Azerbaijan, Belarus, Bulgaria, Czechia, Estonia, France, Latvia, Lithuania, North Macedonia, Moldova, Montenegro, Poland, Romania, Russia, Serbia (Kosovo), Slovakia, Slovenia, Spain, Turkey and Ukraine; species of a wide range of insectivorous and rodent hosts (Moniuszko and Mąkol 2014, and references therein).
Remarks
A variable number of setae attributed to subsequent rows on the opisthosoma dorsum—i.e., fD = 2H-8-8-6-(…); 2H-9-8-6-(…); 2H-10-8-8-(…)—was observed in specimens that revealed significant similarity or identity (97.4–100%) of sequences, including the states 2H-9-8-6-(…) and 2H-10-8-8-(…) observed in case of two specimens that produced identical sequences (0% K2P distance). In case of the first two rows (C and D), the number of setae was consistent with the data provided in the diagnosis; in case of the third row (E), three out of eight specimens had six setae. Moreover, in five specimens lower values of Ip (690, 723, 737, 759, 762) were observed, compared to data provided in the diagnosis of L. europaeum. Yet another larva, with Ip = 805 falling within the variability range known for the species (Ip = 776–1017), shared 98.7 and 97.3% identity with larvae, for which the respective values of Ip, 690 and 737, went beyond those hitherto recorded for L. europaeum. Some specimens were also characterized by shorter setae AM, AL, PL. The shape of the scutum and of dorsal and ventral setae on idiosoma was consistent with one provided in the original description. Due to the scale of differences, and at a high level of identity of COI sequences of examined specimens, the observed deviations from the range of metric traits known for L. europaeum, are regarded here as manifesting the intraspecific variation. The following data should be incorporated in the modified diagnosis: (…) Ip = 6901017; fD = 2H-(8–15)-(8–12)-(611)-(5–11)-(…).
Based on discriminant analysis, Stekolnikov (2004) described two species—Leptotrombidium alanicum Stekolnikov and Leptotrombidium paradux syn. montanum Vercammen-Grandjean and Langston—morphologically similar to L. europaeum, noting that high geographical variation was the reason for poor species differentiation at quite distinct differences in sympatrically occurring specimens. Some specimens from the sample analyzed here fell within the range of L. alanicum. The status of L. alanicum and L. paradux, so close to L. europaeum (e.g.), also requires verification in terms of possible synonymy.
The set of morphological character states of only one of the specimens preliminarily assigned here to L. europaeum was fully compliant with L. europaeum according to the keys of Kudryashova (1998) and Stekolnikov (2013). However, in the key provided by Stekolnikov (2013) the data contained in the modified diagnosis (Stekolnikov and Daniel 2012) were not included. The identical or highly similar COI sequences obtained from specimens examined in the present study vote for their common specific affiliation.
Eleven COI sequences represented four haplotypes. Genetic distance between four haplotypes of L. europaeum (alignment 573 bp) varied between 0.9 and 2.9% (Table S2). All four sequences were classified within one OTU.
The measure of the genetic distance points to the common species identity of the examined specimens and also confirms the relatively wide variation of morphological traits in L. europaeum.
Leptotrombidium sp. A
Material examined. 2 LV (one entire specimen and one exoskeleton mounted on slides; one COI sequence [OQ924404], one 28S sequence [OQ925889]): [4] Albania, Perlat, 10 Oct. 2020, leg. TP. For metric and meristic data see Table 1.
Remarks. Both specimens revealed the similarity to L. europaeum. The values of PW and DS only slightly departed from those known for L. europaeum (Table 1). Both larvae of Leptotrombidium sp. A were collected from the same host specimen. Based on the key by Stekolnikov (2013) one specimen [OQ924404] fits L. europaeum, and the other one [specimen 8203/1] fits L. europaeum/L. alanicum. The specimens differ from each other in the number of setae in the first two rows on opisthosoma dorsum: 2H-14-9-(…) and 2H-10-10-(…), but the observed character states still fit the diagnosis of L. europaeum provided by Stekolnikov and Daniel (2012).
Genetic distance between the COI sequence obtained from OQ924404 and four sequences of L. europaeum (alignment 573 bp) was 10.1–11.5% (Table S2). Species delimitation assigned OQ924407 to separate OTU.
The ultimate decision concerning the affiliation of specimens requires further study of more extensive material, aiming at in-depth recognition of intraspecific genetic variation in Trombiculidae and translating into the scope of variation of morphological traits.
Neotrombicula
Neotrombicula talmiensis (Schluger)
Material examined. 12 LV (nine exoskeletons mounted on slides; nine COI sequences/three haplotypes [OQ924410; OQ924411; OQ924413]; five 28S sequences/one haplotype [OQ925891]): [8] Greece, Pylos, 9 Oct. 2021, leg. TP. For metric and meristic data see Table 2.
Diagnosis (after Stekolnikov et al. 2019): SIF = 7BS-B-3-3111.1000; fPp = B/B/N(B)BB; fsp = 7.7.7; fCx = 1.1.1; fSt = 2.2; fSc: PL > AM ≥ AL; fD = 2H-8-6-6-4-6-2, 2H-6-6-6-4-4-2; DS = 30–36; VS = 27–36; NDV = 59–70; Ip = 835–929; eyes 2 + 2; f1 anterior to S1; f2 posterior to S2.
Distribution and hosts. Hitherto records originate from Albania, Armenia, Azerbaijan, Bulgaria, China, Czechia, Georgia, Hungary, Iran, Italy, Kazakhstan, Kyrgyzstan, Moldova, Poland, Romania, Russia, Slovakia, South Korea, Turkmenistan, Ukraine; hosts: mammals—rodents, soricomorphs, eulipotyphlas (formerly within insectivores), lagomorphs, bats, carnivores—and birds (Moniuszko and Mąkol 2014; Shamsi et al. 2020, and references therein).
Remarks
Species new to the fauna of Greece. Larvae originate from three specimens of G. glis collected at one locality. All specimens share the palpal chaetotaxy formula fPp = B/B/BBB. The range of metric and meristic traits, except for slightly departing values (recorded in each case for one specimen), falls within or overlaps with the published data on N. talmiensis (Kolebinova 1992; Stekolnikov et al. 2014). The lower number of setae on the dorsal and ventral side of opisthosoma (NDV = 50, n = 1), higher maximum number of dorsal setae (DS = 38) and lower minimum number of ventral setae (VS = 20, n = 1), as well as shorter legs (Ip = 716, n = 1), at a high level of identity of COI sequences examined, should be incorporated in the modified diagnosis of the species.
The genetic distance between three single haplotype sequences of N. talmiensis (alignment 573 bp) was 0.2–0.5%, whereas it was 14.3–15% between N. talmiensis and Neotrombicula sp. A (Table S2) and 23.5–23.8% between N. talmiensis and Neotrombicula sp. B. Species delimitation grouped three single haplotype COI sequences within one OTU.
The null distance was recorded between five 28S sequences (alignment 734 bp).
Neotrombicula vulgaris (Schluger)
Material examined. 1 LV (entire specimen mounted on slide): [6] North Macedonia, Kavadarci, 20 Oct. 2020, leg. TP. For metric and meristic data see Table 2.
Diagnosis (after Stekolnikov and Daniel 2012): SIF = 7BS-N-3–3111.1000; fPp = B/B/NNB; fCx = 1.1.1; fSt = 2.2; fSc: PL > AM > AL; Ip = 725–916; fD = 4H-(7–10)-(10–15)-(7–16)-(6–11)-…; DS = 43–63; VS = 24–37; NDV = 72–95.
Distribution and hosts
Azerbaijan, Bulgaria, Czechia, [?] China, Georgia, Hungary, Iran, Moldova, Poland, Russia, Slovakia, Spain, Turkey, Turkmenistan, Ukraine; hosts: rodents and eulipotyphlas, occasionally bats and humans (Schluger 1955; Gadzhiev and Dubovchenko 1976; Moniuszko and Mąkol 2014; Shamsi et al. 2020, and references therein; Stekolnikov and Mumcuoglu 2022).
Remarks
Species new to the fauna of North Macedonia. Identification based exclusively on morphology, with the application of the key provided by Kudryashova (1998). In the only specimen examined, the nine setae were observed in row D on the opisthosoma dorsum, thus the following data should be incorporated in the modified diagnosis of the species: fD = 4H-(7–10)-(9–15)-(….).
Neotrombicula sp. A
Material examined. 2 LV (two exoskeletons mounted on slides; two COI sequences [OQ924409; OQ924412]): [7] Greece, Thasos, 29 Sept. 2021, leg. TP. For metric and meristic data see Table 2.
Remarks. The specimens can be identified as N. talmiensis based on the key provided by Kudryashova (1998). They share the following character states with N. talmiensis: SD < 60; PL > AM = AL; fD = 2H-6–6-(…). The differences between Neotrombicula sp. A and N. talmiensis pertain to the position of posterolateral setae (PL) in relation to sensilla (S) bases: PL/SB (in Neotrombicula sp. A) vs. SB-PL (in N. talmiensis), and to the presence of four setae in row E (n = 1) (vs. six setae in N. talmiensis). Moreover, some metric character states of one specimen of Neotrombicula sp. A, slightly depart from the scope known for N. talmiensis, whereas in the case of the second specimen, all character states fall within the range recognized for N. talmiensis (see also Table 2).
Two single haplotype COI sequences obtained from two specimens assigned to Neotrombicula sp. A represented one OTU and the genetic distance between them (alignment 573 bp) was 0.7%, whereas it was 14.3–15% between Neotrombicula sp. A and N. talmiensis (Table S2). The results confirm a separate identity of Neotrombicula sp. A; however, the ultimate decision on species affiliation (assignment to already known species or providing with a new name, i.e., the description of a new species) should be made after examination of more extensive material.
Neotrombicula sp. B
Material examined. 1 LV (exoskeleton lost; one COI [OQ924408] and one 28S [OQ925890] sequence): [4] Albania, Perlat, 10 Oct. 2020, leg. TP.
Remarks. In the lack of exoskeleton, the identity of Neotrombicula sp. B could be assessed based exclusively on molecular data. Species delimitation allowed to assign [OQ924408] to yet separate OTU. The genetic distance between the COI sequence of the only specimen of Neotrombicula sp. B and N. talmiensis (alignment 573 bp) was 23.5–23.8%, and 23.7–23.9% between Neotrombicula sp. B and Neotrombicula sp. A (Table S2).
A comparison between 28S single haplotype sequences of [OQ925890] and N. talmiensis [OQ925891] (alignment 734 bp) revealed the distance of 2.2%, which also votes for separate species identity of Neotrombicula sp. A.
Brunehaldia
Diagnosis (after Stekolnikov and Daniel 2012). SIF = 7BS-B-3–211(0)1(0)0.0000. fCx = 1.1.(1–5). Eyes absent. Scutum trapezoidal, with rounded or concave posterior margin; sensillary bases situated posterior to the level of PL; AL and PL approximate to each other. Sensilla clavate, fusiform or pyriform, covered with setules. Two or more pairs of humeral setae. Scutal and idiosomal setae covered with long thin barbs.
Distribution and hosts. Afghanistan, Azerbaijan, Bulgaria, Egypt, France (Corsica), Israel, Iran, Kazakhstan, Kosovo, Kyrgyzstan, Morocco, North Macedonia, Pakistan, Spain, Ukraine, Uzbekistan, Russia, Turkey, Turkmenistan; parasites of rodents and of eulipotyphlas, rarely found on birds (Shamsi et al. 2020, and references therein; Stekolnikov and Daniel 2012).
Brunehaldia sp.
Material examined. 1 LV (exoskeleton mounted on slide): [8] Greece, Pylos, 9 Oct. 2021, leg. TP. For metric and meristic data see Table 3.
Remarks. New country record (Greece) and new host record. The only specimen examined displays the SIF formula 7BS-B-3-2111.0000. Comparison of the material with the data for eight hitherto described members of Brunehaldia points to the closest similarity of our specimen to Brunehaldia bulgarica (Vercammen-Grandjean et Kolebinova). The following character states fall within the range of diagnostic traits of B. bulgarica: fPp = B/B/BBB; fCx = 1.1.3; fSt = 2.2; NDV = 106; DS = 58; VS = 48. However, we could observe also the smaller scutum in the specimen examined, as well as some other departing character states: SB = 15, Ip = 511, fD = 4H-10–12-10-(…), PL > AL ≥ AM vs. SB = 21–23, Ip = 669–712, fD = 4H-8-(10–12)-(10–13)-(9–11)-6–2 and PL > AL > AM for B. bulgarica.
Due to the number and significance of differences, and in view of the lack of molecular data that would allow further comparison, we have refrained from a final decision on the affiliation of the specimen, until more material is available.
Hirsutiella
Hirsutiella zachvatkini (Schluger)
Material examined. 2 LV (one entire specimen and one exoskeleton, mounted on slides): [5] Albania, Langarica Canyon, 15 Oct. 2020, leg. TP; [6] North Macedonia, Kavadarci, 20 Oct. 2020, leg. TP. For metric and meristic data see Table 3.
Diagnosis (after Stekolnikov 2001). SIF = 7BS-B-3–2111.1000; fPp = B/B/BBB; fSt = 2.2; fSc: PL > AL > AM or AM > AL; Ip = 997–1120; DS = 86; VS = 73; NDV = 159.
Distribution and hosts. Albania, Austria, Azerbaijan, Belarus, Bulgaria, Czechia, France, Georgia, Germany, Hungary, Kazakhstan, Kyrgyzstan, Latvia, North Macedonia, Moldova, Poland, Romania, Russia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Ukraine, former Yugoslavia; hosts: rodents and eulipotyphlas (Moniuszko and Mąkol 2014, and references therein).
Remarks
Identification was based exclusively on morphology. In general, the values of morphometric traits fell within the range of H. zachvatkini or were slightly lower than data provided for the species by Stekolnikov (2001) and Moniuszko et al. (2015). In relation to most characters, they were also slightly lower than data provided by Imaz et al. (2006). The value that more markedly departed from species diagnosis pertained to index pedibus (Ip = 864) recorded for the specimen from Albania.
Stekolnikov (2001), in the diagnosis of N. zachvatkini referred to exact metric and meristic character states, except for Ip. The diagnosis, however, was not modified despite the relatively wide range of morphometric data recorded for specimens assigned to the species (Table 3), reported by various authors. The latter may be due to the uncertain status of H. zachvatkini, being likely to represent a species complex, thus should be verified based on more extensive material from the geographic range of ‘H. zachvatkini’, supported by molecular evidence.
Schoutedenichia
Diagnosis (after Stekolnikov 2018). SIF = 4B(4BS, 5B)-N(B)-3-2(1)1(0)1(0)0.0000. Eyes 2 + 2 or 1 + 1. Scutum trapezoidal, with straight or concave posterior margin; sensillary bases situated far apart (distance between sensilla larger than distance between sensillum and lateral scutal margin). Sensilla clavate to globose, covered with setules.
Distribution and hosts
Palearctic, Nearctic, as well as Afrotropical and Australian regions; hosts: rodents, eulipotyphlas, squamates (Stekolnikov and Daniel 2012; Moniuszko and Mąkol 2014; Stekolnikov 2018).
Remarks
The genus comprises six subgenera, and 104 nominal species (Stekolnikov 2019; Nielsen et al. 2021; Stekolnikov and Matthee 2022). We refrained from ascertaining the systematic affiliation of the material obtained during the present study to the particular subgenus due to the unstable criteria of recognition of subgenera distinguished within Schoutedenichia.
Schoutedenichia sp. A
Material examined. 1 LV (exoskeleton mounted on slide): [6] North Macedonia, Kavadarci 20 Oct. 2020, leg. TP. For metric and meristic data see Table 4.
Remarks. The specimen revealed similarity to Schoutedenichia (Platytrichia) krampitzi (Willmann) (e.g., SIF = 4B-B-3-1110.0000; fCx = 1.1.1.; for comparison of metric and meristic data of S. krampitzi and Schoutedenichia sp. A, see Table 4) and differed from the latter species in the presence of three barbed setae on palpal tibia [vs. two nude setae and one barbed seta in S. (P.) krampitzi]. The observed difference may contribute to the intraspecific variation of S. (P.) krampitzi; however, the further inference should be based on a larger series of specimens.
Schoutedenichia sp. B
Material examined. 1 LV (exoskeleton mounted on slide; COI sequence [OQ924405]): [5] Albania, Langarica Canyon, 15 Oct. 2020, leg. TP. For metric and meristic data see Table 4.
Remarks. The SIF formula in the examined specimen (5B-B-3-2110.0000) pointed to its affiliation with Schoutedenichia (Pentachia); however, the palpal setal formula in relation to palp femur, palp genu and palp tibia (B/N/BBN) differed from the one observed in the only species, Schoutedenichia (Pentachia) xeri Taufflieb, known for the subgenus (B/B/BBB). Other differences, whose importance should be confirmed in future, pertained to the shape of sensilla bases on scutum [dorsal and ventral cuticular frames present in our specimen; only dorsal frame around the sensilla base—in S. (P.) xeri], the serration of chelicera [smooth cheliceral blade in our specimen; cheliceral blades serrated dorsally in S. (P.) xeri] and number of setae in the row C on opisthosoma dorsum [2H-10-(…) in our specimen, 2H-6-(…) in S. (P.) xeri]. A comparison of metric and meristic data of S. (P.) xeri and Schoutedenichia sp. B is provided in Table 4. Due to the observed differences, S. (P). xeri and the specimen examined in the present study may represent two distinct species. The latter should be confirmed, however, through inference based on more extensive material.
The genetic distance between the COI sequence of Schoutedenichia sp. B, and Schoutedenichia (S.) centralkwangtunga (Mo, Chen, Ho et Li) (KY971498), being the only sequence of Schoutedenichia available in the GenBank, equals 20.4%.
Multiple invasions
We observed four cases of synchronous and syntopic parasitism of chiggers on the edible dormouse, and all of them pertained to the representatives of different genera that entered the pair-wise interaction. Larvae of Leptotrombidium sp. A and of Neotrombicula sp. B were parasitising the same host specimen, a juvenile male of G. glis in Albania. The presence of Schoutedenichia sp. B and H. zachvatkini on the same host (adult female) was stated also in Albania. The other cases of multiple parasitism pertained to N. talmiensis and Brunehaldia sp. (on adult female) in Greece, and to N. vulgaris and Schoutedenichia sp. A (on juvenile female) in North Macedonia.
Phylogenetic relationships
The support for species delineated based on molecular and morphological criteria was tested on 417 bp dataset consisting of 114 COI sequences (12 obtained during present study, and 100 assigned to chiggers and two of outgroup taxa, retrieved from the GenBank).
Results confirmed the clear separation of genera. Sequences of Trombiculidae collected from G. glis were clearly delineated and scattered between distinct clades containing Leptotrombidium, Neotrombicula and Schoutedenichia (Fig. 4). The corresponding branches were either well- or a strongly supported.
Discussion
The representatives of five genera and 10 species of Trombiculidae were recognized in the material collected from G. glis. The successful amplification and sequencing of COI was carried out for three genera and six species. For the remaining taxa the molecular analyses failed which confirms the low success rate of obtaining COI sequences for chiggers (e.g., Antonovskaia 2018; Bassini-Silva et al. 2018; Kumlert et al. 2018).
The study shows a discrepancy between the results of molecular and morphological identification. The scale of this discrepancy cannot be estimated at present due to the scarcity of sequences that allow the comparison. The scope of intraspecific variation of morphological traits largely varies across Trombiculidae and seems to be related to the frequency of records of morphologically distinguished species. Only sometimes the latter can be translated into greater geographic distribution of the species. In the case of L. europaeum, we could establish the wider, than hitherto observed, variation in the number of setae assigned to the row E on the opisthosoma dorsum, the lower values of Ip, and several other metric data that contribute to wider variation known for the species (Table 1), as reported by various authors. Only the indistinct differences recorded between L. europaeum and Leptotrombidium sp. A (value of PW and DS), could contribute to widening the intraspecific variation as well, whereas all other character states recognized for two specimens of Leptotrombidium sp. A fell within the variability range of L. europaeum reported in the present study. The measure of genetic distance between these two species (10.1–11.5%) voted for their separate identity. In the lack of clear morphological differences between them, we would attribute the phenomenon to hidden biodiversity of chiggers, even more difficult to detect due to the likely presence of relatively wide host spectra of ectoparasitic larvae, and the already confirmed (Moniuszko et al. 2015) phenomenon of phenotypic plasticity expressed in host-associated differences in morphometric traits of parasitic larvae.
As in L. europaeum, the wider than hitherto observed range of metric and meristic traits, at high level of identity of COI sequences, was recognized in two (out of eight) specimens assigned to N. talmiensis. The separate identity of N. talmiensis, Neotrombicula sp. A and Neotrombicula sp. B was confirmed by the measure of genetic distance (see also Table S2). The morphological differences between N. talmiensis and Neotrombicula sp. A (in the lack of voucher of Neotrombicula sp. B) were small, and pertained to slight departure of data of only one specimen from the range specified for N. talmiensis. Nevertheless, the concept of N. talmiensis as a group of closely related species (Stekolnikov 2001, 2002; Shatrov and Antonovskaia 2021) cannot be re-appraised without application of molecular tools.
The re-assessment of the usefulness of characters in species description should involve both qualitative and quantitative traits. Among the former ones, the shape of galeala and the structure of setae on palps—with special reference to palp genu, tibia and tarsus—should be prioritized. As we do not know the actual variation of morphological traits at the intraspecific level, the application of morphological keys in species identification is of limited value and should be done with extreme care.
The obtained results indicate the likely occurrence of cryptic species within Trombiculidae, and they indicate that the set of morphological traits used to distinguish species must be verified due to the high variability observed at the intraspecific level. Such verification is necessary because of the growing interest in the group, resulting also from the medical-veterinary importance of these mites and entailing the risk of an increasing number of misidentifications.
The recognition of species boundaries within Trombiculidae, based almost exclusively on morphological criteria, is in a state of flux. The species affiliation of all specimens for which we failed to obtain COI sequences, would remain provisional until more extensive material can be examined and verified with the application of morphological as well as molecular methods (including multiple markers). Thus, we fully support the opinion of Kumlert et al. (2018) who claim that intraspecific variation of morphometric characteristics supported by molecular genotyping needs to be more comprehensively investigated for the members of the Trombiculidae.
The molecular species delimitation could also be helpful in inferring on species diversity. The method—to our best knowledge applied for the first time in relation to trombiculid mites, although tested already for other Parasitengona groups (e.g., Stålstedt et al. 2016; Blattner et al. 2019; Tyukosova et al. 2022)—allowed us to hypothesize on actual species borders and to juxtapose it with the results of morphological identification.
The distance methods were confirmed by means of phylogenetic analyses. Resolving discrepancies related to the position of species (with sequences retrieved from the GenBank) in the phylogenetic tree (e.g., N. inopinata) is beyond the scope of the present study and should be clarified in a separate project.
Multiple invasions, quite commonly observed in Trombiculidae (e.g., Moniuszko et al. 2018; Jacinavicius et al. 2021; Stekolnikov et al. 2022), have also been discovered in the present study. The likely occurrence of simultaneous parasitism of representatives of various genera and species on the same host, entails the necessity to examine all specimens which are present in the material. The inference on species composition cannot be made without in-depth morphological examination, the best supported by molecular analyses.
References
Antonovskaia AA (2018) Using DNA markers in studies of chigger mites (Acariformes, Trombiculidae). Entomol Rev 98:1351–1368. https://doi.org/10.1134/S0013873818090130
Bassini-Silva R, Jacinavicius FC, Muñoz-Leal S, Maturano R, Welbourn WC, Ochoa R, Bauchan GR, Barros-Battesti DM (2018) A new species of the genus Eutrombicula Ewing, 1938 (Trombidiformes: Trombiculidae) and new records for the species Eutrombicula batatas (Linnaeus, 1758) in Brazil. Acarologia 58:976–986. https://doi.org/10.24349/acarologia/20184304
Blattner L, Gerecke R, von Fumetti S (2019) Hidden biodiversity revealed by integrated morphology and genetic species delimitation of spring dwelling water mite species (Acari, Parasitengona: Hydrachnidia). Parasit Vector 12:492. https://doi.org/10.1186/s13071-019-3750-y
Bouckaert R, Vaughan TG, Barido-Sottani J, Duchêne S, Fourment M, Gavryushkina A et al (2019) BEAST 25: An advanced software platform for Bayesian evolutionary analysis. PLoS Comput Biol 15:e1006650. https://doi.org/10.1371/journal.pcbi.1006650
Cornils JS, Hoelzl F, Rotter B, Bieber C, Ruf T (2017) Edible dormice (Glis glis) avoid areas with a high density of their preferred food plant - the European beech. Front Zool 14:23. https://doi.org/10.1186/s12983-017-0206-0
Dabert M, Witaliński W, Kaźmierski A, Kaźmierski A, Olszanowski Z, Dabert J (2010) Molecular phylogeny of acariform mites (Acari, Arachnida): strong conflict between phylogenetic signal and long-branch attraction artifacts. Mol Phylogenet Evol 56:222–241. https://doi.org/10.1016/j.ympev.2009.12.020
Dabert M, Proctor H, Dabert J (2016) Higher-level molecular phylogeny of the water mites (Acariformes: Prostigmata: Parasitengonina: Hydrachnidiae). Mol Phylogenet Evol 101:75–90. https://doi.org/10.1016/j.ympev.2016.05.004
Daniel M, Brelih S (1959) The chigger larvae of the family Trombiculidae (Acari) - parasites upon small mammals in Slovenia. Acta Soc Zool Bohemoslov 23:358–375
Fernandes SJS, Kulkarni SM (2003) Studies on the trombiculid mite fauna of India. Records of the zoological survey of India. Occas Pap 212:1–539
Folmer O, Black M, Hoeh W, Lutz R, Vrijenhoek R (1994) DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Mol Marine Biol Biotechnol 3:294–299
Fujisawa T, Barraclough TG (2013) Delimiting species using single-locus data and the generalized mixed Yule coalescent (GMYC) approach: a revised method and evaluation on simulated datasets. Syst Biol 62:707–724. https://doi.org/10.1093/sysbio/syt033
Gadzhiev AT, Dubovchenko TA (1976) Ectoparasites of the horseshoe bat, Rhinolophus mehelyi in the Azerbaijan – SSR. Zool Zhurnal 2:24–28
Goff ML (1979) Host exploitation by chiggers (Acari: Trombiculidae) infesting Papua New Guinea land mammals. Pac Insects 20:321–353
Imaz A, Galicia D, Moraza ML, Stekolnikov AA (2006) Contribution to the knowledge of chigger mites (Acari: Trombiculidae) parasitizing Apodemus sylvaticus (L.) (Rodentia, Muridae) on the Iberian Peninsula. Acarologia 46:53–64
Jacinavicius FC, Bassini-Silva R, Mendoza-Roldan JA, Muñoz-Leal S, Hingst-Zaher E, Ochoa R, Bauchan GR, Barros-Battesti DM (2018) A contribution to the knowledge of Quadraseta brasiliensis Goff and Gettinger, 1989 (Trombidiformes: Trombiculidae), with description of the deutonymph instar. Acarologia 58:442–456. https://doi.org/10.24349/acarologia/20184252
Jacinavicius FC, Arbex RL, Barros-Battesti DM, Bassini-Silva R (2021) Evidence of co-parasitism between different species of chiggers (Trombidiformes: Trombiculidae) parasitizing cricetid rodents in Morro Grande Forest Reserve, São Paulo State Brazil. Entomol Commun 3:ec03043. https://doi.org/10.37486/2675-1305.ec03043
Kepka O (1964) Die Trombiculinae (Acari, Trombiculidae) in Österreich. Z Parasitenkd 23:548–642
Kimura M (1980) A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. J Mol Evol 16:111–120
Kirillov AA, Kirillova NY, Ruchin AB (2022) Parasites, bacteria and viruses of the edible dormouse Glis glis (Rodentia: Gliridae) in the Western Palaearctic. Diversity 14:562. https://doi.org/10.3390/d14070562
Klimov PB, OConnor BM, Chetverikov PE, Bolton SJ, Pepato AR, Mortazavi AL, Tolstikov AV, Bauchan GR, Ochoa R (2018) Comprehensive phylogeny of acariform mites (Acariformes) provides insights on the origin of the four-legged mites (Eriophyoidea), a long branch. Mol Phylogenet Evol 119:105–117. https://doi.org/10.1016/j.ympev.2017.10.017
Kolebinova MG (1992) Acariformes, Trombidioidea, Trombiculidae, Leeuwenhoekiidae. Aedib Acad Sci Bulg, Sofia 21:1–171
Kudryashova NI (1998) Chigger mites (Acariformes, Trombiculidae) of East Palaearctics. KMK Scientific Press, Moscow
Kumar S, Stecher G, Li M, Knyaz C, Tamura K (2018) MEGA X: molecular evolutionary genetics analysis across computing platforms. Mol Biol Evol 35:1547–1549. https://doi.org/10.1093/molbev/msy096
Kumlert R, Chaisiri K, Anantatat T, Stekolnikov AA, Morand S, Prasartvit A, Makepeace BL, Sungvornyothi S, Paris DH (2018) Autofluorescence microscopy for paired-matched morphological and molecular identification of individual chigger mites (Acari: Trombiculidae), the vectors of scrub typhus. PloS ONE 13:e0193163. https://doi.org/10.1371/journal.pone.0193163
Mendoza-Roldan JA, Barros-Battesti DM, Bassini-Silva R, Jacinavicius FC, Nieri-Bastos FA, Franco FL, Marcili A (2017) A new species of pit mite (Trombidiformes: Harpirhynchidae) from the South American rattlesnake (Viperidae): morphological and molecular analysis. Entomol Ornithol Herpetol 6:201. https://doi.org/10.4172/2161-0983.1000201
Mironov SV, Dabert J, Dabert M (2012) A new feather mite species of the genus Proctophyllodes Roin, 1877 (Astigmata: Proctophyllodidae) from the long-tailed tit Aegithalos caudatus (Passeriformes: Aegithalidae) – morphological description with DNA barcode data. Zootaxa 3253:54–61. https://doi.org/10.11646/zootaxa.3253.1.2
Moniuszko H, Mąkol J (2014) Chigger mites (Actinotrichida: Parasitengona, Trombiculidae) of Poland. An updated distribution and hosts. Ann Parasitol 60:103–117
Moniuszko H, Zaleśny G, Mąkol J (2015) Host-associated differences in morphometric traits of parasitic larvae Hirsutiella zachvatkini (Actinotrichida: Trombiculidae). Exp Appl Acarol 67:123–133. https://doi.org/10.1007/s10493-015-9925-0
Moniuszko H, Shatrov AB, Mąkol J (2017) Description of active postlarval forms of Neotrombicula vulgaris (Schluger, 1955) (Prostigmata: Trombiculidae), with notes on biology and ecology of the species. Annal Zool 67:243–251. https://doi.org/10.3161/00034541ANZ2017.67.2.005
Moniuszko H, Felska M, Mąkol J (2018) Evidence for co-invasion events: different chigger species (Actinotrichida, Trombidioidea: Trombiculidae) share a host. Exp Appl Acarol 76:29–39. https://doi.org/10.1007/s10493-018-0293-4
Mulyarskaya LV (1965) Materials on studying chiggers in northwestern Azerbaidzhan. Proc Zool Inst Acad Sci 24:162–182
Nielsen DH, Robbins RG, Rueda LM (2021) Annotated world checklist of the Trombiculidae and Leeuwenhoekiidae (1758–2021) (Acari: Trombiculoidea), with notes on nomenclature, taxonomy and distribution. Zootaxa 4967:1–243. https://doi.org/10.11646/zootaxa.4967.1.1
Pepato AR, da Rocha CEF, Dunlop JA (2010) Phylogenetic position of the Acariform mites: sensitivity to homology assessment under total evidence. BMC Evol Biol 10:235. https://doi.org/10.1186/1471-2148-10-235
Puillandre N, Lambert A, Brouillet S, Achaz G (2011) ABGD, automatic barcode gap discovery for primary species delimitation. Mol Ecol 21:1864–1877. https://doi.org/10.1111/j.1365-294X.2011.05239.x
Puillandre N, Brouillet S, Achaz G (2021) ASAP: assemble species by automatic partitioning. Mol Ecol Resour 21:609–620. https://doi.org/10.1111/1755-0998.13281
Santibáñez‐Sáenz P (2015) Trobicúlidos y trombiculiasis en La Rioja. Dissertation, Universidad de La Rioja. https://dialnet.unirioja.es/servlet/tesis?codigo=46014 (Accessed 18 Sept 2022)
Sasa M, Hayashi S, Sato K, Miura A, Asahina S (1950) Studies on tsutsugamushi, part 5. Chiggers collected in the Mt, vol 67. Fuji area Tokyo Iji Shinshi. Zasshi Tokyo Ika Daigaku, p. 4
Schluger EG (1955) Superfamily Trombeae Turk. I. Family Trombiculidae Ewing. Subfamily Trombiculinae ewing. In: Bregatova NG, Bulanova-Zakhvatkina EM, Volgin VI, Dubinin VB, Zakhvatkin AA, Zemskaya AA, Lanse AB, Pavlovskii EN, Serdyukova GV, Schluger EG (eds) Acarina of the rodent fauna of the U.S.S.R., vol 59. Zool lnst Nauk SSSR, Leningrad, pp 118–217
Schluger EG, Vysotzkaya SO (1970) On the fauna of chigger-mites (Acariformes, Trombiculidae) from the Transcarpathian region. Parazitologiya 4:153–164
Shamsi M, Stekolnikov AA, Saboori A, Hakimitabar M, Golpayegani AZ (2020) Contribution to the fauna of chigger mites (Acariformes: Trombiculidae) of Iran. Zootaxa 4834:301–355. https://doi.org/10.11646/zootaxa.4834.3.1
Shao R, Mitani H, Barker SC, Takahashi M, Fukunaga M (2005) Novel mitochondrial gene content and gene arrangement indicate illegitimate inter-mtDNA recombination in the chigger mite, Leptotrombidium pallidum. J Mol Evol 60:764–773. https://doi.org/10.1007/s00239-004-0226-1
Shao R, Barker SC, Mitani H, Takahashi M, Fukunaga M (2006) Molecular mechanisms for the variation of mitochondrial gene content and gene arrangement among chigger mites of the genus Leptotrombidium (Acari: Acariformes). J Mol Evol 63:251–261. https://doi.org/10.1007/s00239-005-0196-y
Shatrov AB, Kudryashova NI (2008) Taxonomic ranking of major trombiculid subtaxa with remarks on the evolution of host-parasite relationships (Acariformes: Parasitengona: Trombiculidae). Annal Zool 58:279–287. https://doi.org/10.3161/000345408X326591
Shatrov AB, Antonovskaia AA (2021) Stylostome of the trombiculid mite larvae Neotrombicula talmiensis (Schluger, 1955) (Acariformes, Trombiculidae) feeding on two host species in the Russian Far East. Acarologia 61:412–431. https://doi.org/10.24349/acarologia/20214442
Shaw G (1790) The autumnal acarus or harvest bug. Nat Misc 2:42
Stålstedt J, Wohltmann A, Bergsten J, Mąkol J (2016) Towards resolving the double classification in Erythraeus (Actinotrichida: Erythraeidae): matching larvae with adults using 28S sequence data and experimental rearing. Organism Divers Evol 16:761–790. https://doi.org/10.1007/s13127-016-0283-5
Stekolnikov AA (1999) A revision of the chigger mites species groupv ulgaris (Trombiculidae: Neotrombicula). Parazitologiya 33:387–403
Stekolnikov AA (2001) Systematics of chigger mites of the genus Hirsutiella Schluger et Vysotzkaja, 1970 (Acari, Trombiculidae). Entomol Obozr 80:219–242
Stekolnikov AA (2002) Variability in chigger mites of talmiensis species group, genus Neotrombicula Hirst 1925 (Acari, Trombiculidae) in areas of sympatria on the Western Caucasus. Entomol Obozr 81:761–777
Stekolnikov AA (2004) Variability in Leptotrombidium europaeum and two new related chigger mite species (Acari: Trombiculidae) from Caucasus. Parazitologiya 38:388–405
Stekolnikov AA (2013) Leptotrombidium (Acari: Trombiculidae) of the world. Zootaxa 3728:1–173. https://doi.org/10.11646/Zootaxa.3728.1.1
Stekolnikov AA (2018) Taxonomy and distribution of African chiggers (Acariformes, Trombiculidae). Eur J Taxon 395:1–233. https://doi.org/10.5852/ejt.2018.395
Stekolnikov AA, Daniel M (2012) Chigger mites (Acari: Trombiculidae) of Turkey. Zootaxa 3216:1–104. https://doi.org/10.11646/zootaxa.3216.1.1
Stekolnikov AA, Matthee S (2022) Two new species and new records of chigger mites (Acariformes: Trombiculidae) from South Africa. Int J Acarol 48:594–604. https://doi.org/10.1080/01647954.2022.2152094
Stekolnikov AA, Mumcuoglu KY (2022) Chigger mites (Acariformes: Trombiculidae) of Israel. Int J Acarol 48:266–274. https://doi.org/10.1080/01647954.2022.2058608
Stekolnikov AA, Ballardini M, Mignon W, Scapin P, Ulbano M, Marsan A, Balduzzi A (2014) First finding of the chigger mite Neotrombicula talmiensis (Acari: Trombiculidae) in Italy. Int J Acarol 40:419–420. https://doi.org/10.1080/01647954.2014.942361
Stekolnikov AA, Saboori A, Shamsi M, Hakimitabar M (2019) Chigger mites (Acariformes: Trombiculidae) of Iran. Zootaxa 4549:1–66. https://doi.org/10.11646/zootaxa.4549.1.1
Stekolnikov AA, Shamsi M, Saboori A, Golpayegani AZ, Hakimitabar M (2022) Distribution of chigger mites (Acari: Trombiculidae) over hosts, parasitopes, collection localities, and seasons in northern Iran. Exp Appl Acarol 86:21–47. https://doi.org/10.1007/s10493-021-00680-w
Tao J-M, Ashram S-EI, Alouffi A, Zhang Y, Weng Y-B, Lin R-Q (2022) Population genetic structure of Neoschongastia gallinarum in South China based on mitochondrial DNA markers. Parasitol Res 121:2793–2802. https://doi.org/10.1007/s00436-022-07605-5
Taufflieb R (1966) Quatre nouveaux Schoutedenichia de la Republique Centrafricaine. Acarologia 8:287–295
Tyukosova V, Gerecke R, Stur E, Ekrem T (2022) Disentangling the identity of Lebertia porosa Thor, 1900 using integrative taxonomy (Acari: Hydrachnidia). Eur J Taxon 836:131–169. https://doi.org/10.5852/ejt.2022.836.1921
Vences M, Miralles A, Brouillet S, Ducasse J, Fedosov A, Kharchev V, Kostadinov I, Kumari S, Patmanidis S, Scherz MD, Puillandre N, Renner SS (2021) iTaxoTools 0.1: Kickstarting a specimen-based software toolkit for taxonomists. Megataxa 006:077–092. https://doi.org/10.11646/megataxa.6.2.1
Vercammen-Grandjean PH, Kolebinova MG (1966) Revision of the subgenus Brunehaldia Vercammen-Grandjean, 1956. Description of two new species (Trombiculidae: Acarina). Acarologia 8:431–437
Vercammen-Grandjean PH, Langston LR (1976) The chigger mites of the World. Leptotrombidium complex. George Williams Hooper Foundation, vol III. University of California, San Francisco, pp 1–1061
Vikyrchak O, Ploshchansky P (2020) Finds of the fat dormouse (Glis glis) in cave-type shelters in the Middle Dniestr Region. Theriol Ukr 19:96–102. https://doi.org/10.15407/TU1910
Walter DE, Krantz GW (2009) Collecting, rearing, and preparing specimens. In: Krantz GW, Walter DE (eds) A manual of acarology, 3rd edn. Texas Tech University Press, Lubbock, pp 83–96
Willmann C (1955) Eine ausbeute parasitischer Acari von Kleinsäugern auf Sizilien. Z Parasitenkd 17:175–184
Womersley H (1944) Notes on and additions to the Trombiculinae and Leeuwenhoekiinae (Acarina) of Australia and New Guinea. Trans R Soc S Aust 68:82–112
Womersley H (1952) The scrub-typhus and scrub-itch mites (Trombiculidae, Acarina) of the Asiatic-Pacific region. Part I. (text). Rec S Aust Mus 10:1–435
Wulandhari SA, Paladsing Y, Saesim W, Charoennitiwat V, Sonthayanon P, Kumlert R, Morand S, Sumruayphol S, Chaisiri K (2021) High prevalence and low diversity of chigger infestation in small mammals found in Bangkok Metropolitan parks. Med Vet Entomol 35:534–546. https://doi.org/10.1111/mve.12531
Young MR, Behan-Pelletier VM, Hebert PD (2012) Revealing the hyperdiverse mite fauna of Subarctic Canada through DNA barcoding. PLoS ONE 7:e48755. https://doi.org/10.1371/journal.pone.0048755
Zajkowska P, Mąkol J (2022) Parasitism, seasonality, and diversity of trombiculid mites (Trombidiformes: Parasitengona, Trombiculidae) infesting bats (Chiroptera) in Poland. Exp Appl Acarol 86:1–20. https://doi.org/10.1007/s10493-021-00683-7
Zhou Q, Wang Z-X, Tao J-M, Qin J-P, Lu J-P, Lin R-Q, Wang L-M, Weng Y-B, Tan Z-J (2020) Characterization of Neoschoengastia gallinarum from subtropical China by rDNA and identification of two genotypes based on mitochondrial co1. Parasitol Res 119:3339–3345. https://doi.org/10.1007/s00436-020-06856-4
Acknowledgements
We thank Anna Marchewka for her assistance in the field work.
Author information
Authors and Affiliations
Contributions
PZ: study design, sampling, data curation, investigation, formal analysis, writing the original draft, editing. TP: conceptualization, sampling, data curation. JM: conceptualization, study design, data curation, investigation, writing the original draft, review, and editing. All authors have read and approved the final version of the manuscript.
Corresponding author
Ethics declarations
Conflict of interest
No potential conflict of interest was reported by the authors.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Zajkowska, P., Postawa, T. & Mąkol, J. Let me know your name: a study of chigger mites (Acariformes: Trombiculidae) associated with the edible dormouse (Glis glis) in the Carpathian–Balkan distribution gradient. Exp Appl Acarol 91, 1–27 (2023). https://doi.org/10.1007/s10493-023-00824-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10493-023-00824-0