Mites inhabiting nests of wood warbler, Phylloscopus sibilatrix (Aves: Passeriformes), in the Wielkopolska National Park in western Poland.

The wood warbler, Phylloscopus sibilatrix (Aves: Passeriformes), is a well-known model organism for studying bird migration, breeding habitat selection and nest predation. The nest acarofauna of this bird species has not been extensively studied so far. To provide a comprehensive report on mite species inhabiting wood warbler nests and to assess infestation parameters (prevalence, intensity, and abundance) for mite species and orders, we collected 45 nests of this bird species in the Wielkopolska National Park in western Poland. Analyses revealed a huge diversity (198 species) of mites inhabiting wood warbler nests. We found individuals belonging to the Mesostigmata, Trombidiformes and Sarcoptiformes. The Trombidiformes, represented in our study only by the Prostigmata, achieved statistically significantly lower intensity and abundance, compared to representatives of other orders. However, the number of recorded prostigmatid species was high (65). The most common were: Stigmaeus sphagneti (22 nests), Stigmaeus longipilis (16), Eupodes voxencollinus (15), Cunaxa setirostris (14), Stigmaeus pilatus (11), and Linopodes sp. 2 (10). The prevalence of Mesostigmata and Sarcoptiformes was equal, reaching 91.1%. Most of Gamasina (Mesostigmata) species found in this study were more characteristic of the soil environment and forest litter than bird nests, but there was also a typical bird parasite, viz. Ornithonyssus sylviarum. None of the observed species of Uropodina (Mesostigmata) or Oribatida (Sarcoptiformes) was typical for bird nests. Among the Uropodina, the highest parameters of nest infestation were achieved by Oodinychus ovalis, whereas among the Oribatida, they were achieved by Metabelba pulverosa. We discuss the importance of wood warbler nests for mite dispersal, survival and reproduction.

Inclusion of juvenile stages improves diversity assessment and adds to our understanding of mite ecology - A case study from mires in Norway.

Arachnid orders, Mesostigmata, Trombidiformes, and Sarcoptiformes, commonly known as 'mites', are abundant in mires, both as adults and as juveniles. However, due to the challenges of identification, the juvenile forms are often excluded from analyses. This is the first study in mires that included all three mite orders identified to the species level, including juvenile instars. We aimed to compare how diversity and the response to ecological variables differed if only the adults (ad) vs. the total number of specimens (ad+juv) are considered. Samples of 20 Sphagnum species (five subgenera) were collected and mites were extracted using Berlese funnels. Overall, nearly 60,000 mites were analyzed; of these Mesostigmata made up 1.87% of the total, Trombidiformes -0.27%, and Sarcoptiformes -97.86%. The study revealed 154 species (33 Mesostigmata, 24 Trombidiformes, and 97 Sarcoptiformes), the highest diversity of mites ever reported from mires. The inclusion of juveniles increased observed species richness by 6%, with 10 species (one Mesostigmata, six Trombidiformes, and three Sarcoptiformes) represented only by juvenile forms. Seventeen species are new to Norway (four Mesostigmata, one Sarcoptiformes, and 12 Trombidiformes, including five undescribed species of Stigmaeidae and Cunaxidae). Four of these were represented in the samples only by juveniles. Including the juveniles explained a greater amount of the variability of Trombidiformes (explanatory variables account for 23.60% for ad, and 73.74% for ad+juv) and Mesostigmata (29.23% - ad, 52.91% - ad+juv), but had less of an impact for Sarcoptiformes (38.48% - ad, 39.26% - ad+juv). Locality, Sphagnum subgenus and species, wetness, and trophic state significantly affected the mite communities and should be taken into consideration when studying mires. Since juvenile stages contribute significantly to mite diversity in mires, they should also be included in mite studies in other habitats.

Long-term stasis in acariform mites provides evidence for morphologically stable evolution: Molecular vs. morphological differentiation in Linopodes (Acariformes; Prostigmata).

Molecular species delimitation, usually by COI DNA barcoding, shows that cryptic speciation is a common phenomenon observed in most animal phyla. Cryptic species have frequently been observed among all major taxa of mites. The mites of the eupodoid genus Linopodes are cosmopolitan in distribution and are most often found in soil-related habitats. Currently, the genus consists of 22 morphologically similar species, which, in practice, are indistinguishable on the basis of their morphological features. The diagnostic issue of the Linopodes species may be caused by the poor delineation of the species, which need taxonomic revision, or the low morphological variability among cryptic species. In this paper, we present the results of molecular species delimitation carried out using sampled Linopodes populations and the level of morphological inter/intraspecific variation within defined groups. We compared COI, 18S and 28S sequence data together with morphological characters. The molecular delimitation revealed seven well-defined species of Linopodes based on DNA sequences. A well-supported phylogenetic tree revealed the same seven species, while morphological analysis showed negligible phenotypic differentiation among the species revealed. We demonstrate that mites can undergo changes in their DNA accompanied by morphological stasis lasting at least 80 MY.

Molecular phylogeny of Eupodidae reveals that the family Cocceupodidae (Actinotrichida; Eupodoidea) and its genus Filieupodes are valid taxa.

The family Eupodidae is one of eight families belonging to the superfamily Eupodoidea. Although the Eupodidae are very common mites, they are still poorly investigated and the systematic parameters of the family are vague with unclear intrafamilial relationships between its genera. According to the hypothesis of Jesionowska (Genus 21(4):637-658, 2010), the eupodid genera Cocceupodes, Linopodes and her new genus Filieupodes should be transferred from the Eupodidae to a separate family named Cocceupodidae. The opposite hypothesis of Khaustov (ZooKeys 422:11-22, 2014) considers the family Cocceupodidae an artificial taxon and the genus Filieupodes a junior synonym of Cocceupodes and assignes the family Eupodidae its primary definition. Here, we present the first molecular reconstruction of phylogenetic relationships within the Eupodidae. We test the taxonomic status of the Eupodidae and refer to the previous hypotheses based on morphological data. According to the reconstructed phylogram based on nuclear (18S + 28S rDNA) and mitochondrial (COI) sequences as well as morphological characters tracing this analysis, we have concluded that: (1) the genera Linopodes, Filieupodes and Cocceupodes are a separate monophyletic lineage of familial rank and the sister group of Eupodidae s.s., and (2) the genus Filieupodes should be considered a separate genus being a sister group of the Linopodes-Cocceupodes clade.

Tydeus shabestariensis sp. nov. and description of the male of Neopronematus sepasgosariani (Acari: Tydeoidea), with a key to the Iranian species of Tydeus.

A new species of the family Tydeidae from Iran, Tydeus shabestariensis sp. nov., is described from adult males and females collected from soil in apple orchards. A key to species of Tydeus of Iran, based on females, is provided. The male of Neopronematus sepasgosariani (Tydeoidea: Iolinidae) is also described and illustrated for the first time.

New species and records of Neopronematus (Acari: Iolinidae) from Iran with a key to world species.

In this paper, Neopronematus kamalii Darbemamieh and Hajiqanbar sp. nov. (Acari: Prostigmata: Iolinidae), collected from apricot leaves in Kermanshah province, Iran, is described and illustrated. Also, the following species were collected and identified from Kermanshah province, Iran: Neopronematus rapidus (Kuznetzov, 1972), Neopronematus solani Laniecka and Kazmierski, 2013; Neopronematus sepasgosariani Sadeghi, Laniecka and Kazmierski, 2012; Neopronematus lundqvisti Sadeghi, Laniecka and Kazmierski, 2012; and Neopronematus neglectus (Kuznetzov, 1972). Some information about the genus, morphologically close species, remarks and a key to Neopronematus species of the world are given as well.

On the arboreal acarofauna of Hungary: some new and rare species of prostigmatic mites (Acari: Prostigmata: Tydeidae, Iolinidae and Stigmaeidae).

Eleven arboreal prostigmatic mites from the families Tydeidae, Iolinidae and Stigmaeidae (Prostigmata) are recorded from Hungary. Among them, 8 species are new for science: Tydeus narolicatus Kazmierski and Ripka sp. nov., T. martae Kazmierski sp. nov., T clavimaculatus Kazmierski sp. nov., Lorryia hungarica Laniecka and Ripka sp. nov., L. sanctikingai Ripka and Laniecka sp. nov., L. bathorii Ripka and Kazmierski sp. nov., Neopronematus solani Laniecka and Kazmierski sp. nov., and Mediolata ronaldi Laniecka sp. nov. Neopronematus lundqvisti Sadeghi et al., 2012 is a new species for fauna of Hungary.

Molecular phylogeny of acariform mites (Acari, Arachnida): strong conflict between phylogenetic signal and long-branch attraction artifacts.

Acariformes (one of the two main lineages of Acari) represent an exceptionally diverse group of Arachnida. We performed first comprehensive phylogenetic analysis of Acariformes using sequence data from the nuclear small subunit rRNA gene (18S rDNA) and the mitochondrial cytochrome c oxidase subunit I (COI, amino acids). Our analyses confirm the monophyly of Acariformes and recognize two orders within Acariformes: Sarcoptiformes, consisting of Endeostigmata and Oribatida+Astigmata, and Trombidiformes. The data revealed the origin of Astigmata within Oribatida with the desmonomatan superfamily Crotonioidea as the source of astigmatan radiation and the sexual family Hermanniidae as the sister group, which generally supports previous morphological hypotheses. These results were found despite the strong conflict between long-branch attraction (LBA) artifacts and phylogenetic signal. It is likely that the conflict resulted from differences in the substitution rates among acariform lineages, especially comparing slowly evolving Oribatida with rapidly evolving Astigmata. The use of likelihood methods considered more resistant to LBA only slightly decreased the chance of falling into the LBA trap; the probability of recovering the origin of Astigmata within Desmonomata differs only by about 10% from that of having the long branched Astigmata and Trombidiformes either connected directly or shifted to deep parts of the tree due to outgroup attraction. Molecular dating using the rate-smoothing method PATHd8 shows that Acariformes originated c. 435 MYA and were probably among the earliest arthropods invading terrestrial habitats in late Silurian or the Lower Devonian, when the first vascular plants are thought to have arisen. Our analyses did not support the monophyly of Acari because we recovered clades Acariformes-Solifugae and Parasitiformes-Pseudoscorpionida. However, a formal revision of arachnid classification that would reflect these results must await future analyses.