While RNA interference (RNAi) has been deployed to facilitate gene function studies in diverse helminths, parasitic nematodes appear variably susceptible. To test if this is due to inter-species differences in RNAi effector complements, we performed a primary sequence similarity survey for orthologs of 77 Caenorhabditis elegans RNAi pathway proteins in 13 nematode species for which genomic or transcriptomic datasets were available, with all outputs subjected to domain-structure verification. Our dataset spanned transcriptomes of Ancylostoma caninum and Oesophagostomum dentatum, and genomes of Trichinella spiralis, Ascaris suum, Brugia malayi, Haemonchus contortus, Meloidogyne hapla, Meloidogyne incognita and Pristionchus pacificus, as well as the Caenorhabditis species C. brenneri, C. briggsae, C. japonica and C. remanei, and revealed that: (i) Most of the C. elegans proteins responsible for uptake and spread of exogenously applied double stranded (ds)RNA are absent from parasitic species, including RNAi-competent plant-nematodes; (ii) The Argonautes (AGOs) responsible for gene expression regulation in C. elegans are broadly conserved, unlike those recruited during the induction of RNAi by exogenous dsRNA; (iii) Secondary Argonautes (SAGOs) are poorly conserved, and the nuclear AGO NRDE-3 was not identified in any parasite; (iv) All five Caenorhabditis spp. possess an expanded RNAi effector repertoire relative to the parasitic nematodes, consistent with the propensity for gene loss in nematode parasites; (v) In spite of the quantitative differences in RNAi effector complements across nematode species, all displayed qualitatively similar coverage of functional protein groups. In summary, we could not identify RNAi effector deficiencies that associate with reduced susceptibility in parasitic nematodes. Indeed, similarities in the RNAi effector complements of RNAi refractory and competent nematode parasites support the broad applicability of this research genetic tool in nematodes.
1 Treatments against pathogens or pests are often very specific and, as a fundamental first step, require the ability to identify taxa correctly and unambiguously. We used PCR amplification techniques to successfully establish a molecular identification key for economically important thrips species. 2 A PCR amplified 433 bp long fragment of the mitochondrial COI coding gene was analysed by automated direct sequencing and RFLP. Sequencing of 264 individual thrips representing 10 named species detected 17 haplotypes. Variation within species was low, whereas among species variation was high resulting in an average sequence divergence of 18.6% and an average pairwise species differentiation (calculated as F ST -value) of 0.9896. 3 Two restriction enzymes (AluI, Sau3AI) produced patterns that allowed unambiguous identification of all thrips species. 4 Statistical support for the quality of the key was given by (i) a highly significant permutation approach, assigning individual haplotypes to the correct species groups and (ii) a hierarchical NJ cluster analysis in which all conspecific individual sequences clustered together with maximal (100%) bootstrap support. 5 This study has shown that the use of genetic markers represents a valuable alternative for situations, such as epidemiological research, in which correct identification with classical morphological methods is either very difficult and time consuming or virtually impossible.
The potato cyst nematode Globodera pallida is a serious pest of potato crops. Nematode FMRFamide-like peptides (FLPs) are one of the most diverse neuropeptide families known, and modulate sensory and motor functions. As neuromuscular function is a well-established target for parasite control, parasitic nematode FLP signaling has significant potential in novel control strategies. In the absence of transgenic parasitic nematodes and the reported ineffectiveness of neuronal gene RNAi in Caenorhabditis elegans, nothing is known about flp function in nematode parasites. In attempts to evaluate flp function in G. pallida, we have discovered that, unlike in C. elegans, these genes are readily susceptible to RNAi. Silencing any of the five characterized G. pallida flp genes (Gp-flp-1, -6, -12, -14, or -18) incurred distinct aberrant behavioral phenotypes consistent with key roles in motor function. Further delineation of these effects revealed that double-stranded RNA exposure time (> or = 18 h) and concentration (> or = 0.1 microg/ml) were critical to the observed effects, which were reversible. G. pallida flp genes are essential to coordinated locomotory activities, do not display redundancy, and are susceptible to RNAi, paving the way for the investigation of RNAi-mediated flp gene silencing as a novel plant parasite control strategy.
Quercus petraea and Quercus robur are two closely related oak species that frequently hybridize. We sequenced 70 clones containing the 5.8S and ITS2 regions of ribosomal DNA (rDNA) from these two species and did not detect a species-specific difference. Surprisingly, three divergent (up to 12.6%) rDNA families were identified in both species, indicating that they predate the speciation event. Despite a large between-rDNA-families divergence, rDNA sequences were very similar within families, suggesting ongoing concerted evolution. Expression analysis, relative-rate tests, and mutation spectrum analyses indicated that only a single rDNA family is functional. We propose that past hybridization events, combined with nucleolar dominance, were the evolutionary processes underlying the contemporary rDNA variability in Q. petraea and Q. robur.
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