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Helminth Microbiomes - A Hidden Treasure Trove?
There is increasing attention on the complex interactions occurring between gastrointestinal parasitic helminths and the microbial flora (microbiota) inhabiting the host gut. However, little is known about the occurrence, structure, and function of microbial populations residing within parasite organs and tissues. In this article, we argue that an in-depth understanding of the interplay between parasites and their microbiomes may significantly enhance current knowledge of parasite biology and physiology, and may lead to the discovery of entirely novel, anthelmintic-independent interventions against parasites and parasitic diseases
Hammondia isolated from dogs and foxes are genetically distinct
Hammondia heydorni is regarded as a protozoan parasite that uses canids, e.g. dogs and foxes, as definitive hosts, but clinical signs of infection are rare. This study therefore took advantage of the opportunity to study an oocyst population from the faeces of a dog suffering from intermittent bouts of diarrhoea. Oocysts from the naturally infected dog were shown to be H. heydorni by using the polymerase chain reaction combined with DNA sequencing as a diagnostic tool.† A comparison of the first internal transcribed spacer (ITS1) sequence of ribosomal DNA obtained with those from other dog and fox oocysts, previously regarded as H. heydorni, showed these oocysts contained identical ITS1 sequences. However, the oocyst DNA from the fox and dog differed by the presence/absence of a 9 bp insertion/deletion within intron 1 of the alpha tubulin gene, and this difference was conserved across a number of different oocyst populations from the 2 species of host. A PCR assay was established that takes advantage of this insertion/deletion and is able to differentiate between the 2 oocyst populations. This study therefore provides evidence that H. heydorni oocysts from dogs and foxes represent 2 distinct genetic lineages that can be differentiated using a PCR, which targets the alpha tubulin locus. © 2005 Cambridge University Press
Molecular detection of Cyclospora in water, soil, vegetables and humans in southern Italy signals a need for improved monitoring by health authorities
To date, in Europe, there is scant information on the occurrence of Cyclospora in water from treatment plants and
in humans, and no data are available on soil or fresh plant products. Here, we undertook the first molecular survey
of Cyclospora in multiple biological matrices collected from the Apulia region of southern Italy. Samples of irrigation
water from four municipal treatment plants, eight different types of vegetables or fruit (cucumber,
lettuce, fennel, celery, tomato, melon, endive and chicory) and soil from the same farms on which these plants
were grown, as well as faecal samples from humans living in the same region were tested by qPCR-coupled
single-strand conformation polymorphism (SSCP) analysis and DNA sequencing. Cyclospora was detected in
15.5% of all 213 samples tested. Specifically, this protist was detected in (i) treated water (21.3% of 94 samples),
well water (6.2% of 16), but not drinking water (0% of 3); (ii) soil (11.8% of 51 samples) and vegetables (12.2% of
49),with the highest prevalence (18.7%) on fennel; and (iii) human stools (27.5% of 40 samples). In environmental
and food samples, Cyclosporawas detectedmainly in autumn and was significantly more prevalent in the faeces
from humans of 40–50 years of age. This is the first comprehensive molecular survey of Cyclospora in
environmental, food and human faecal samples in Europe. These data suggest that irrigation water, soil and vegetables
might be contaminated by Cyclospora cayetanensis, which might represent a source of infection to
humans in the study area and calls for monitoring by health authorities
DNA Footprints: Using Parasites to Detect Elusive Animals, Proof of Principle in Hedgehogs
The Western European Hedgehog (Erinaceous europaeus) is a nocturnal animal that is in decline in much of Europe, but the monitoring of this species is subjective, prone to error, and an inadequate basis for estimating population trends. Here, we report the use of Crenosoma striatum, a parasitic nematode specific to hedgehogs as definitive hosts, to detect hedgehog presence in the natural environment. This is achieved through collecting and sampling the parasites within their intermediate hosts, gastropoda, a group much simpler to locate and sample in both urban and rural habitats. C. striatum and Crenosoma vulpis were collected post-mortem from the lungs of hedgehogs and foxes, respectively. Slugs were collected in two sessions, during spring and autumn, from Skomer Island (n = 21), which is known to be free of hedgehogs (and foxes); and Pennard, Swansea (n = 42), known to have a healthy hedgehog population. The second internal transcribed spacer of parasite ribosomal DNA was used to develop a highly specific, novel, PCR based multiplex assay. Crenosoma striatum was found only at the site known to be inhabited by hedgehogs, at an average prevalence in gastropods of 10% in spring and autumn. The molecular test was highly specific: One mollusc was positive for both C. striatum and C. vulpis, and differentiation between the two nematode species was clear. This study demonstrates proof of principle for using detection of specific parasite DNA in easily sampled intermediate hosts to confirm the presence of an elusive nocturnal definitive host species. The approach has great potential as an adaptable, objective tool to supplement and support existing ecological survey methods
The mitochondrial genome of Parascaris univalens - implications for a “forgotten” parasite
© Jabbar et al.; licensee BioMed Central Ltd. 2014
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated. The file attached is the Published/publisher’s pdf version of the article
Clear Genetic Distinctiveness between Human- and Pig-Derived Trichuris Based on Analyses of Mitochondrial Datasets
The whipworm, Trichuris trichiura, causes trichuriasis in ∼600 million people worldwide, mainly in developing countries. Whipworms also infect other animal hosts, including pigs (T. suis), dogs (T. vulpis) and non-human primates, and cause disease in these hosts, which is similar to trichuriasis of humans. Although Trichuris species are considered to be host specific, there has been considerable controversy, over the years, as to whether T. trichiura and T. suis are the same or distinct species. Here, we characterised the entire mitochondrial genomes of human-derived Trichuris and pig-derived Trichuris, compared them and then tested the hypothesis that the parasites from these two host species are genetically distinct in a phylogenetic analysis of the sequence data. Taken together, the findings support the proposal that T. trichiura and T. suis are separate species, consistent with previous data for nuclear ribosomal DNA. Using molecular analytical tools, employing genetic markers defined herein, future work should conduct large-scale studies to establish whether T. trichiura is found in pigs and T. suis in humans in endemic regions
Assessment of the genetic relationship between Dictyocaulus species from Bos taurus and Cervus elaphus using complete mitochondrial genomic datasets
Background: Dictyocaulus species are strongylid nematodes of major veterinary significance in ruminants, such as
cattle and cervids, and cause serious bronchitis or pneumonia (dictyocaulosis or “husk”). There has been ongoing
controversy surrounding the validity of some Dictyocaulus species and their host specificity. Here, we sequenced
and characterized the mitochondrial (mt) genomes of Dictyocaulus viviparus (from Bos taurus) with Dictyocaulus sp.
cf. eckerti from red deer (Cervus elaphus), used mt datasets to assess the genetic relationship between these and
related parasites, and predicted markers for future population genetic or molecular epidemiological studies.
Methods: The mt genomes were amplified from single adult males of D. viviparus and Dictyocaulus sp. cf. eckerti
(from red deer) by long-PCR, sequenced using 454-technology and annotated using bioinformatic tools. Amino
acid sequences inferred from individual genes of each of the two mt genomes were compared, concatenated and
subjected to phylogenetic analysis using Bayesian inference (BI), also employing data for other strongylids for
comparative purposes.
Results: The circular mt genomes were 13,310 bp (D. viviparus) and 13,296 bp (Dictyocaulus sp. cf. eckerti) in size,
and each contained 12 protein-encoding, 22 transfer RNA and 2 ribosomal RNA genes, consistent with other
strongylid nematodes sequenced to date. Sliding window analysis identified genes with high or low levels of
nucleotide diversity between the mt genomes. At the predicted mt proteomic level, there was an overall sequence
difference of 34.5% between D. viviparus and Dictyocaulus sp. cf. eckerti, and amino acid sequence variation within
each species was usually much lower than differences between species. Phylogenetic analysis of the concatenated
amino acid sequence data for all 12 mt proteins showed that both D. viviparus and Dictyocaulus sp. cf. eckerti were
closely related, and grouped to the exclusion of selected members of the superfamilies Metastrongyloidea,
Trichostrongyloidea, Ancylostomatoidea and Strongyloidea.
Conclusions: Consistent with previous findings for nuclear ribosomal DNA sequence data, the present analyses
indicate that Dictyocaulus sp. cf. eckerti (red deer) and D. viviparus are separate species. Barcodes in the two mt
genomes and proteomes should serve as markers for future studies of the population genetics and/or
epidemiology of these and related species of Dictyocaulus.This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. The attached file is the published pdf
Comparative genome analysis indicates high evolutionary potential of pathogenicity genes in Colletotrichum tanaceti
Colletotrichum tanaceti is an emerging foliar fungal pathogen of commercially grown pyrethrum (Tanacetum cinerariifolium). Despite being reported consistently from field surveys in Australia, the molecular basis of pathogenicity of C. tanaceti on pyrethrum is unknown. Herein, the genome of C. tanaceti (isolate BRIP57314) was assembled de novo and annotated using transcriptomic evidence. The inferred putative pathogenicity gene suite of C. tanaceti comprised a large array of genes encoding secreted effectors, proteases, CAZymes and secondary metabolites. Comparative analysis of its putative pathogenicity gene profiles with those of closely related species suggested that C. tanaceti likely has additional hosts to pyrethrum. The genome of C. tanaceti had a high repeat content and repetitive elements were located significantly closer to genes inferred to influence pathogenicity than other genes. These repeats are likely to have accelerated mutational and transposition rates in the genome, resulting in a rapid evolution of certain CAZyme families in this species. The C. tanaceti genome showed strong signals of Repeat Induced Point (RIP) mutation which likely caused its bipartite nature consisting of distinct gene-sparse, repeat and A-T rich regions. Pathogenicity genes within these RIP affected regions were likely to have a higher evolutionary rate than the rest of the genome. This “two-speed” genome phenomenon in certain Colletotrichum spp. was hypothesized to have caused the clustering of species based on the pathogenicity genes, to deviate from taxonomic relationships. The large repertoire of pathogenicity factors that potentially evolve rapidly due to the plasticity of the genome, indicated that C. tanaceti has a high evolutionary potential. Therefore, C. tanaceti poses a high-risk to the pyrethrum industry. Knowledge of the evolution and diversity of the putative pathogenicity genes will facilitate future research in disease management of C. tanaceti and other Colletotrichum spp
Analyses of mitochondrial amino acid sequence datasets support the proposal that specimens of Hypodontus macropi from three species of macropodid hosts represent distinct species
Background: Hypodontus macropi is a common intestinal nematode of a range of kangaroos and wallabies
(macropodid marsupials). Based on previous multilocus enzyme electrophoresis (MEE) and nuclear ribosomal DNA
sequence data sets, H. macropi has been proposed to be complex of species. To test this proposal using
independent molecular data, we sequenced the whole mitochondrial (mt) genomes of individuals of H. macropi
from three different species of hosts (Macropus robustus robustus, Thylogale billardierii and Macropus [Wallabia]
bicolor) as well as that of Macropicola ocydromi (a related nematode), and undertook a comparative analysis of the
amino acid sequence datasets derived from these genomes.
Results: The mt genomes sequenced by next-generation (454) technology from H. macropi from the three host
species varied from 13,634 bp to 13,699 bp in size. Pairwise comparisons of the amino acid sequences predicted
from these three mt genomes revealed differences of 5.8% to 18%. Phylogenetic analysis of the amino acid
sequence data sets using Bayesian Inference (BI) showed that H. macropi from the three different host species
formed distinct, well-supported clades. In addition, sliding window analysis of the mt genomes defined variable
regions for future population genetic studies of H. macropi in different macropodid hosts and geographical regions
around Australia.
Conclusions: The present analyses of inferred mt protein sequence datasets clearly supported the hypothesis that
H. macropi from M. robustus robustus, M. bicolor and T. billardierii represent distinct species.© 2013 Jabbar et al.; licensee BioMed Central Ltd. This is an open access article distributed under the terms of the Creative
Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and
reproduction in any medium, provided the original work is properly cited
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