Autofluorescence microscopy for paired-matched morphological and molecular identification of individual chigger mites (Acari: Trombiculidae), the vectors of scrub typhus.
Rawadee Kumlert, Kittipong Chaisiri, Tippawan Anantatat, Alexandr A. Stekolnikov, Serge Morand, Anchana Prasartvit, Benjamin L. Makepeace, Sungsit Sungvornyothin, Daniel H. Paris.
PLoS ONE, 13 (3): e0193163 (2018).
S U M M A R Y
Conventional gold standard characterization of chigger mites involves chemical preparation procedures (i.e. specimen clearing) for visualization of morphological features,
which however contributes to destruction of the arthropod host DNA and any endosymbiont or pathogen DNA harbored within the specimen.
In this study, a novel work flow based on autofluorescence microscopy was developed to enable identification of trombiculid mites to the species level on the basis of
morphological traits without any special preparation, while preserving the mite DNA for subsequent genotyping. A panel of 16 specifically selected fluorescence microscopy
images of mite features from available identification keys served for complete chigger morphological identification to the species level, and was paired with corresponding
genotype data. We evaluated and validated this method for paired chigger morphological and genotypic ID using the mitochondrial cytochrome c oxidase subunit I gene (coi) in
113 chigger specimens representing 12 species and 7 genera (Leptotrombidium, Ascoschoengastia, Gahrliepia, Walchia, Blankaartia, Schoengastia and Schoutedenichia) from the
Lao People’s Democratic Republic (Lao PDR) to the species level (complete characterization), and 153 chiggers from 5 genera (Leptotrombidium, Ascoschoengastia, Helenicula,
Schoengastiella and Walchia) from Thailand, Cambodia and Lao PDR to the genus level.
A phylogenetic tree constructed from 77 coi gene sequences (approximately 640 bp length, n = 52 new coi sequences and n = 25 downloaded from GenBank), demonstrated clear grouping
of assigned morphotypes at the genus levels, although evidence of both genetic polymorphism and morphological plasticity was found.
With this new methodology, we provided the largest collection of characterized coi gene sequences for trombiculid mites to date, and almost doubled the number of available
characterized coi gene sequences with a single study. The ability to provide paired phenotypic-genotypic data is of central importance for future characterization of mites and
dissecting the molecular epidemiology of mites transmitting diseases like scrub typhus.