79 research outputs found
Putative cis-Regulatory Elements Associated with Heat Shock Genes Activated During Excystation of Cryptosporidium parvum
Abstract Background
Cryptosporidiosis is a ubiquitous infectious disease, caused by the protozoan parasitesCryptosporidium hominis and C. parvum, leading to acute, persistent and chronic diarrhea worldwide. Although the complications of this disease can be serious, even fatal, in immunocompromised patients of any age, they have also been found to lead to long term effects, including growth inhibition and impaired cognitive development, in infected immunocompetent children. The Cryptosporidium life cycle alternates between a dormant stage, the oocyst, and a highly replicative phase that includes both asexual vegetative stages as well as sexual stages, implying fine genetic regulatory mechanisms. The parasite is extremely difficult to study because it cannot be cultured in vitro and animal models are equally challenging. The recent publication of the genome sequence of C. hominis and C. parvum has, however, significantly advanced our understanding of the biology and pathogenesis of this parasite. Methodology/Principal Findings
Herein, our goal was to identify cis-regulatory elements associated with heat shock response in Cryptosporidium using a combination of in silico and real time RT-PCR strategies. Analysis with Gibbs-Sampling algorithms of upstream non-translated regions of twelve genes annotated as heat shock proteins in the Cryptosporidium genome identified a highly conserved over-represented sequence motif in eleven of them. RT-PCR analyses, described herein and also by others, show that these eleven genes bearing the putative element are induced concurrent with excystation of parasite oocysts via heat shock. Conclusions/Significance
Our analyses suggest that occurrences of a motif identified in the upstream regions of theCryptosporidium heat shock genes represent parts of the transcriptional apparatus and function as stress response elements that activate expression of these genes during excystation, and possibly at other stages in the life cycle of the parasite. Since heat shock and excystation represent a critical step in the development of the infectious sporozoite form ofCryptosporidium, these results provide important insight into the pathogenicity of the parasite
Rare mutations and potentially damaging missense variants in genes encoding fibrillar collagens and proteins involved in their production are candidates for risk for preterm premature rupture of membranes
Preterm premature rupture of membranes (PPROM) is the leading identifiable cause of preterm birth with ~ 40% of preterm births being associated with PPROM and occurs in 1% - 2% of all pregnancies. We hypothesized that multiple rare variants in fetal genes involved in extracellular matrix synthesis would associate with PPROM, based on the assumption that impaired elaboration of matrix proteins would reduce fetal membrane tensile strength, predisposing to unscheduled rupture. We performed whole exome sequencing (WES) on neonatal DNA derived from pregnancies complicated by PPROM (49 cases) and healthy term deliveries (20 controls) to identify candidate mutations/variants. Genotyping for selected variants from the WES study was carried out on an additional 188 PPROM cases and 175 controls. All mothers were self-reported African Americans, and a panel of ancestry informative markers was used to control for genetic ancestry in all genetic association tests. In support of the primary hypothesis, a statistically significant genetic burden (all samples combined, SKAT-O p-value = 0.0225) of damaging/potentially damaging rare variants was identified in the genes of interest—fibrillar collagen genes, which contribute to fetal membrane strength and integrity. These findings suggest that the fetal contribution to PPROM is polygenic, and driven by an increased burden of rare variants that may also contribute to the disparities in rates of preterm birth among African Americans
In Silico Derivation of HLA-Specific Alloreactivity Potential from Whole Exome Sequencing of Stem Cell Transplant Donors and Recipients: Understanding the Quantitative Immuno-biology of Allogeneic Transplantation
Donor T cell mediated graft vs. host effects may result from the aggregate
alloreactivity to minor histocompatibility antigens (mHA) presented by the HLA
in each donor-recipient pair (DRP) undergoing stem cell transplantation (SCT).
Whole exome sequencing has demonstrated extensive nucleotide sequence variation
in HLA-matched DRP. Non-synonymous single nucleotide polymorphisms (nsSNPs) in
the GVH direction (polymorphisms present in recipient and absent in donor) were
identified in 4 HLA-matched related and 5 unrelated DRP. The nucleotide
sequence flanking each SNP was obtained utilizing the ANNOVAR software package.
All possible nonameric-peptides encoded by the non-synonymous SNP were then
interrogated in-silico for their likelihood to be presented by the HLA class I
molecules in individual DRP, using the Immune-Epitope Database (IEDB) SMM
algorithm. The IEDB-SMM algorithm predicted a median 18,396 peptides/DRP which
bound HLA with an IC50 of <500nM, and 2254 peptides/DRP with an IC50 of <50nM.
Unrelated donors generally had higher numbers of peptides presented by the HLA.
A similarly large library of presented peptides was identified when the data
was interrogated using the Net MHCPan algorithm. These peptides were uniformly
distributed in the various organ systems. The bioinformatic algorithm presented
here demonstrates that there may be a high level of minor histocompatibility
antigen variation in HLA-matched individuals, constituting an HLA-specific
alloreactivity potential. These data provide a possible explanation for how
relatively minor adjustments in GVHD prophylaxis yield relatively similar
outcomes in HLA matched and mismatched SCT recipients.Comment: Abstract: 235, Words: 6422, Figures: 7, Tables: 3, Supplementary
figures: 2, Supplementary tables:
Species-level classification of the vaginal microbiome
Background
The application of next-generation sequencing to the study of the vaginal microbiome is revealing the spectrum of microbial communities that inhabit the human vagina. High-resolution identification of bacterial taxa, minimally to the species level, is necessary to fully understand the association of the vaginal microbiome with bacterial vaginosis, sexually transmitted infections, pregnancy complications, menopause, and other physiological and infectious conditions. However, most current taxonomic assignment strategies based on metagenomic 16S rDNA sequence analysis provide at best a genus-level resolution. While surveys of 16S rRNA gene sequences are common in microbiome studies, few well-curated, body-site-specific reference databases of 16S rRNA gene sequences are available, and no such resource is available for vaginal microbiome studies. Results
We constructed the Vaginal 16S rDNA Reference Database, a comprehensive and non-redundant database of 16S rDNA reference sequences for bacterial taxa likely to be associated with vaginal health, and we developed STIRRUPS, a new method that employs the USEARCH algorithm with a curated reference database for rapid species-level classification of 16S rDNA partial sequences. The method was applied to two datasets of V1-V3 16S rDNA reads: one generated from a mock community containing DNA from six bacterial strains associated with vaginal health, and a second generated from over 1,000 mid-vaginal samples collected as part of the Vaginal Human Microbiome Project at Virginia Commonwealth University. In both datasets, STIRRUPS, used in conjunction with the Vaginal 16S rDNA Reference Database, classified more than 95% of processed reads to a species-level taxon using a 97% global identity threshold for assignment. Conclusions
This database and method provide accurate species-level classifications of metagenomic 16S rDNA sequence reads that will be useful for analysis and comparison of microbiome profiles from vaginal samples. STIRRUPS can be used to classify 16S rDNA sequence reads from other ecological niches if an appropriate reference database of 16S rDNA sequences is available
Stem Cell Transplantation As A Dynamical System: Are Clinical Outcomes Deterministic?
Outcomes in stem cell transplantation (SCT) are modeled using probability
theory. However the clinical course following SCT appears to demonstrate many
characteristics of dynamical systems, especially when outcomes are considered
in the context of immune reconstitution. Dynamical systems tend to evolve over
time according to mathematically determined rules. Characteristically, the
future states of the system are predicated on the states preceding them, and
there is sensitivity to initial conditions. In SCT, the interaction between
donor T cells and the recipient may be considered as such a system in which,
graft source, conditioning and early immunosuppression profoundly influence
immune reconstitution over time. This eventually determines clinical outcomes,
either the emergence of tolerance or the development of graft versus host
disease. In this paper parallels between SCT and dynamical systems are explored
and a conceptual framework for developing mathematical models to understand
disparate transplant outcomes is proposed.Comment: 23 pages, 4 figures. Updated version with additional data, 2 new
figures and editorial revisions. New authors adde
In Silico Derivation of HLA-Specific Alloreactivity Potential from Whole Exome Sequencing of Stem Cell Transplant Donor-Recipient Pairs
Whole Exome Sequencing to Estimate Alloreactivity Potential Between Donors and Recipients in Stem Cell Transplantation
Whole exome sequencing was performed on HLA-matched stem cell donors and
transplant recipients to measure sequence variation contributing to minor
histocompatibility antigen differences between the two. A large number of
nonsynonymous single nucleotide polymorphisms were identified in each of the
nine unique donor-recipient pairs tested. This variation was greater in
magnitude in unrelated donors as compared with matched related donors.
Knowledge of the magnitude of exome variation between stem cell transplant
recipients and donors may allow more accurate titration of immunosuppressive
therapy following stem cell transplantation.Comment: 12 pages- main article, 29 pages total, 5 figures, 1 supplementary
figur
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