Taxonomic Position of Entomoparasitic Nematodes Isolated from Fleas in Gorno-Altai High-Mountain Natural Plague Focus

Objective of the study was to investigate entomoparasitic nematodes from rodent fleas, collected in Gorno-Altai high-mountain natural plague focus in 2016–2017, with identification of their taxonomic status. Materials and methods. Given are the results of morphological and genetic analysis of entomoparasitic nematodes – parasites of fleas Amphipsylla primaris primaris living on flat-headed high-mountain voles Alticola strelzovi, fleas Rhadinopsylla li transbaicalica of Daurian pika Ochotona dauurica, fleas Rhadinopsylla dahurica, collected at the burrows of the rodents. Results and conclusions. Identified have been nucleotide sequences of ITS2 spacer region of ribosomal operon in entomoparasitic nematodes of three flea species: Amphipsylla primaris primaris, Rhadinopsylla li transbaicalica, and Rhadinopsylla dahurica. Based on comparative phylogenetic analysis and identified high percentage of homology of the stated nucleotide sequences (92–99 %), appurtenance to Rubzovinema spp. species and close relation to earlier proposed by us multi-host species Rubzovinema polyxenica from C. tesquorum, A. rossica, and C. secundus fleas from Volga-Ural steppe plague focus has been established. For the first time ever separate branch of evolution of entomoparasitic nematodes – flea parasites, represented by Rubzovinema ssp., has been identified. Determined has been wide spread of Rubzovinema ssp. nematodes in biocenoses of steppe zone of Russia across Precaspian territory and Altai Mountains.

Phylogenetic Analysis of Entomoparasitic Nematodes, Potential Control Agents of Flea Populations in Natural Foci of Plague

Entomoparasitic nematodes are natural control agents for many insect pests, including fleas that transmitYersinia pestis, a causative agent of plague, in the natural foci of this extremely dangerous zoonosis. We examined the flea samples from the Volga-Ural natural focus of plague for their infestation with nematodes. Among the six flea species feeding on different rodent hosts (Citellus pygmaeus,Microtus socialis, andAllactaga major), the rate of infestation varied from 0 to 21%. The propagation rate of parasitic nematodes in the haemocoel of infected fleas was very high; in some cases, we observed up to 1,000 juveniles per flea specimen. Our study of morphology, life cycle, and rDNA sequences of these parasites revealed that they belong to three distinct species differing in the host specificity. On SSU and LSU rRNA phylogenies, these species representing three genera (Rubzovinema,Psyllotylenchus, andSpilotylenchus), constitute a monophyletic group close to Allantonema and Parasitylenchus, the type genera of the families Allantonematidae and Parasitylenchidae (Nematoda: Tylenchida). We discuss the SSU-ITS1-5.8S-LSU rDNA phylogeny of the Tylenchida with a special emphasis on the suborder Hexatylina.

Phylogenetic analysis of Tylenchida Thorne, 1949 as inferred from D2 and D3 expansion fragments of the 28S rRNA gene sequences

The evolutionary relationships of 82 species of tylenchid and aphelenchid nematodes were evaluated by use of sequence data of the D2 and D3 expansion fragments of the 28S ribosomal RNA genes. Nine automatic and one culled sequence alignments were analysed using maximum parsimony and Bayesian inference approaches. The molecular data sets showed that the order Tylenchida comprises lineages that largely correspond to two suborders, Hoplolaimina and Criconematina, and other taxonomic divisions as proposed by Siddiqi (2000). Several significant results also derived from our study include: i) the basal position of groups that include entomoparasitic nematodes within tylenchid trees; ii) paraphyly of the superfamily Dolichodoroidea sensu Siddiqi (2000); iii) evidence for a Pratylenchus, Hirschmanniella and Meloidogyne clade; and iv) lack of support for widely held traditional placement of Radopholus within Pratylenchidae and placement of this genus within Hoplolaimidae or Heteroderidae. Congruence and incongruence of molecular phylogeny and traditional classifications and morphological-based hypotheses of phylogeny of tylenchids are discussed.

Genome sizes of the entomopathogenic nematodes Steinernema carpocapsae and Heterorhabditis bacteriophora (Nematoda: Rhabditida)

There is currently no information on the genome size and complexity in the entomoparasitic nematodes Steinernema and Heterorhabditis. DNA reassociation kinetics were used to determine the genome size and complexity in 2 species: Steinernema carpocapsae and Heterorhabditis bacteriophora. C0t curves derived from renaturation kinetics of denatured DNA indicate that the genomes of these entomoparasitic rhabditids are different both in size and complexity. Genome sizes were estimated at 2·3 × 108 bp for S. carpocapsae and 3·9 × 107 bp for H. bacteriophora and repetitive DNA contents were found to represent 39% and 51% of these respective genomes.