Project description:Microsporidia are intracellular eukaryotes that infect many animals and cause opportunistic infections in AIDS patients. The disease is transmitted via environmentally resistant spores. Two spore wall constituents from the microsporidian Encephalitozoon intestinalis were characterized. Spore wall protein 1 (SWP1), a 50-kDa glycoprotein recognized by monoclonal antibody (MAb) 11B2, was detected in developing sporonts and at low levels on the surfaces of mature spores. In contrast, SWP2, a 150-kDa glycoprotein recognized by MAb 7G7, was detected on fully formed sporonts and was more abundant on mature spores than SWP1. Nevertheless, the SWPs appeared to be complexed on the surfaces of mature spores. SWP1 and SWP2 are similar at the DNA and protein levels and have 10 conserved cysteines in the N-terminal domain, suggesting similar secondary structures. The C-terminal domain of SWP2 has a unique region containing 50 repeating 12- or 15-amino-acid units that lacks homology to known protein motifs. Antibodies from mice infected with E. intestinalis recognized SWP1 and SWP2. The characterization of two immunogenic SWPs from E. intestinalis will allow the study of exospore structure and function and may lead to the development of useful tools in the diagnosis and treatment of microsporidiosis.

Project description:Microsporidia from the Encephalitozoonidae are obligate intracellular parasites with highly conserved and compacted nuclear genomes: they have few introns, short intergenic regions, and almost identical gene complements and chromosome arrangements. Comparative genomics of Encephalitozoon and microsporidia in general have focused largely on the genomic diversity between different species, and we know very little about the levels of genetic diversity within species. Polymorphism studies with Encephalitozoon are so far restricted to a small number of genes, and a few genetically distinct strains have been identified; most notably, three genotypes (ECI, ECII, and ECIII) of the model species E. cuniculi have been identified based on variable repeats in the rRNA internal transcribed spacer (ITS). To determine if E. cuniculi genotypes are genetically distinct lineages across the entire genome and at the same time to examine the question of intraspecies genetic diversity in microsporidia in general, we sequenced de novo genomes from each of the three genotypes and analyzed patterns of single nucleotide polymorphisms (SNPs) and insertions/deletions across the genomes. Although the strains have almost identical gene contents, they harbor large numbers of SNPs, including numerous nonsynonymous changes, indicating massive intraspecies variation within the Encephalitozoonidae. Based on this diversity, we conclude that the recognized genotypes are genetically distinct and propose new molecular markers for microsporidian genotyping.

Project description:The mitochondrial genome of the smallest known free-living insect Scydosella musawasensis (Polilov, 2015) is published in this paper. The mitochondrial DNA (mtDNA) is 14 719 base pairs (bp) in length and contained 13 protein-coding genes, 2 rRNA genes and 21 tRNA genes. The overall base composition of the genome in descending order was 40.59% - A, 13.85% - C, 36.82% - T and 8.73% - G, with a significant AT bias of 77.41%.

Project description:Polyomaviruses are known to infect mammals and birds. Deep sequencing and metagenomic analysis identified the first polyomavirus from a cartilaginous fish, the giant guitarfish (Rhynchobatus djiddensis). Giant guitarfish polyomavirus 1 (GfPyV1) has typical polyomavirus genome organization, but is the smallest polyomavirus genome (3.96 kb) described to date.

Project description:An obligate parasite associated with gastrointestinal disease in humans

Project description:Seven isolates of Encephalitozoon hellem from human immunodeficiency virus-positive patients were genotyped through a series of markers: the internal transcribed spacer (ITS) of ribosomal DNA, the polar tube protein (PTP) gene, and two intergenic spacers (IGS-TH and IGS-HZ) whose polymorphism is newly reported. The genome markers were all analyzed at three levels: PCR amplification followed by polyacrylamide gel electrophoresis, single-strand conformation analysis (SSCA), and DNA sequencing. The polymorphisms detected involve insertions/deletions and point mutations. SSCA can distinguish any pair of sequences, even those differing by a single base pair. The different isolates studied fit into the previously described ITS genotype 1A, except one which seems to be a 2A derivative variant (2D). When PTP and the new markers IGS-TH and IGS-HZ were analyzed, most of the isolates displayed different genotypes, demonstrating that E. hellem has a strong intraspecies variability. A set of markers such as those used here may be very useful in genotyping of clinical samples and in the assessment of epidemiological relationships among E. hellem strains.

Project description:BackgroundMicrosporidia are obligate intracellular opportunistic fungi that cause significant pathology in immunocompromised hosts. However, 11 percent of immunocompetent individuals in the general population are microsporidia-seropositive, indicating that severe immune suppression may not be a prerequisite for infection. Encephalitozoon intestinalis is transmitted in contaminated water and initially infects gastro-intestinal enterocytes, leading to diarrheal disease. This organism can also disseminate to many other organs. A recent report suggests that microsporidia can establish persistent infections, which anti-fungal treatment does not eradicate. Like other intracellular pathogens, microsporidia infection stresses the host cell and infected individuals have elevated hydrogen peroxide and free radical levels.FindingsAs oxidative stress can lead to DNA damage, we hypothesized that E. intestinalis-infection would increase host cell nuclear mutation rate. Embryo fibroblasts from Big BlueTM transgenic mice were E. intestinalis-infected and host nuclear mutation frequency was determined by selection of temperature-sensitive c-II gene mutant λ phage. The host mutation frequency in E. intestinalis-infected cultures was 2.5-fold higher than that observed in either mock-infected cells or cells infected with UV-inactivated E. intestinalis spores.ConclusionsThese data provide the first evidence that microsporidia infection can directly increase host cellular mutation frequency. Additionally, some event in the microsporidia developmental cycle between host cell attachment and parasitophorous vacuole formation is required for the observed effect. As there is considerable evidence linking infection with other intracellular pathogens and cancer, future studies to dissect the mechanism by which E. intestinalis infection increases host mutation frequency are warranted.

Project description:Microsporidia are intracellular parasites that are highly-derived relatives of fungi. They have compacted genomes and, despite a high rate of sequence evolution, distantly related species can share high levels of gene order conservation. To date, only two species have been analysed in detail, and data from one of these largely consists of short genomic fragments. It is therefore difficult to determine how conservation has been maintained through microsporidian evolution, and impossible to identify whether certain regions are more prone to genomic stasis.Here, we analyse three large fragments of the Enterocytozoon bieneusi genome (in total 429 kbp), a species of medical significance. A total of 296 ORFs were identified, annotated and their context compared with Encephalitozoon cuniculi and Antonospora locustae. Overall, a high degree of conservation was found between all three species, and interestingly the level of conservation was similar in all three pairwise comparisons, despite the fact that A. locustae is more distantly related to E. cuniculi and E. bieneusi than either are to each other.Any two genes that are found together in any pair of genomes are more likely to be conserved in the third genome as well, suggesting that a core of genes tends to be conserved across the entire group. The mechanisms of rearrangments identified among microsporidian genomes were consistent with a very slow evolution of their architecture, as opposed to the very rapid sequence evolution reported for these parasites.

Project description:The complete resequencing and assembly as a single molecule of the R. intestinalis strain L1-82 genome

Project description:Microsporidia are obligate intracellular protozoa that have been shown to be pathogenic to most living creatures. The development of in vitro cell culture propagation methods has provided researchers with large numbers of spores and facilitated the study of these organisms. Here, we describe heterogeneity within cell culture-propagated Encephalitozoon intestinalis suspensions. Flow cytometer histograms depicting the log side scatter and forward-angle light scatter of spores from nine suspensions produced over 12 months consistently showed two populations differing in size. The suspensions were composed primarily of the smaller-spore subpopulation (76.4% +/- 5.1%). The presence of two subpopulations was confirmed by microscopic examination and image analysis (P < 0.001). Small subpopulation spores were noninfectious in rabbit kidney (RK13) cell culture infectivity assays, while the large spores were infectious when inocula included > or = 25 spores. The small spores stained brilliantly with fluorescein isothiocyanate-conjugated monoclonal antibody against Encephalitozoon genus spore wall antigen, while the large spores stained poorly. There was no difference in staining intensities using commercial (MicroSporFA) and experimental polyclonal antibodies. Vital-dye (DAPI [4',6'-diamidino-2-phenylindole], propidium iodide, or SYTOX Green) staining showed the spores of the small subpopulation to be permeable to all vital dyes tested, while spores of the large subpopulation were not permeable in the absence of ethanol pretreatment. PCR using primers directed to the 16S rRNA or beta-tubulin genes and subsequent sequence analysis confirmed both subpopulations as E. intestinalis. Our data suggest that existing cell culture propagation methods produce two types of spores differing in infectivity, and the presence of these noninfective spores in purified spore suspensions should be considered when designing disinfection and drug treatment studies.