11 research outputs found

    Chromatography paper strip sampling of enteric adenoviruses type 40 and 41 positive stool specimens

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    BACKGROUND: The enteric subgroup F adenoviruses type 40 (Ad40) and 41 (Ad41) are the second most important cause of acute infantile gastroenteritis after rotaviruses. Repeated community outbreaks have been associated with antigenic changes among the Ad40 and Ad41 strains due to host immune pressure. Therefore large field epidemiological surveys and studies on the genetic variations in different isolates of Ad40 and Ad41 are important for disease control programs, the design of efficient diagnostic kits and vaccines against subgroup F adenoviruses. A novel method using sodium dodecyl sulphate SDS/EDTA-pretreated chromatography paper strips was evaluated for the collection, storage and shipping of Ad40/41 contaminated stool samples. RESULTS: This study shows that adenoviral DNA can be successfully detected in the filter strips by PCR after four months storage at -20°C, 4°C, room temperature (20–25°C) and 37°C. Furthermore no adenoviral infectivity was observed upon contact with the SDS/EDTA-pretreated strips. CONCLUSIONS: Collecting, storing and transporting adenovirus type 40 and 41 positive stool samples on SDS/EDTA-pretreated chromatography filter strips is a convenient, biosafe and cost effective method for studying new genome variants and monitoring spread of enteric adenovirus strains during outbreaks

    Subgroup Prevalence and Genotype Circulation Patterns of Human Respiratory Syncytial Virus in Belgium during Ten Successive Epidemic Seasons▿

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    Human respiratory syncytial virus (HRSV) is the leading viral cause of severe respiratory illness for infants and young children worldwide. Two major antigenic groups (A and B) of HRSV exist, and viruses from both subgroups can cocirculate during epidemics; however, their frequencies might differ between seasons. The subgroup prevalence and genotype distribution patterns of HRSV strains were investigated in a community in Belgium during 10 successive epidemic seasons (1996 to 2006). A regular 3-year cyclic pattern of subgroup dominance was observed, consisting of two predominant HRSV-A seasons, followed by a single HRSV-B-dominant year. HRSV infections with both subgroups were more prevalent among children younger than 6 months and had a peak incidence in December. The most frequently detected genotypes were GA5 and GB13, the latter including strains with the 60-nucleotide duplication in the G gene. Furthermore, GA5 remained the dominant HRSV genotype in two consecutive epidemic seasons twice during the study period. Additional variability was detected among the GB13 isolates, due to the usage of a novel termination codon in the G gene. Dual infections with both HRSV subgroups were detected for 9 patients, and subsequent infections with the heterologous HRSV subgroup were documented for 15 patients. Among five patients with homologous reinfections, only one was caused by HRSV-B. Our results support the hypothesis that the overall prevalence of HRSV-A over HRSV-B could be due to a more-transient subgroup A-specific immune protection

    Molecular Evolution and Circulation Patterns of Human Respiratory Syncytial Virus Subgroup A: Positively Selected Sites in the Attachment G Glycoprotein

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    Human respiratory syncytial virus (HRSV) is the most common etiological agent of acute lower respiratory tract disease in infants and can cause repeated infections throughout life. In this study, we have analyzed nucleotide sequences encompassing 629 bp at the carboxy terminus of the G glycoprotein gene for HRSV subgroup A strains isolated over 47 years, including 112 Belgian strains isolated over 19 consecutive years (1984 to 2002). By using a maximum likelihood method, we have tested the presence of diversifying selection and identified 13 positively selected sites with a posterior probability above 0.5. The sites under positive selection correspond to sites of O glycosylation or to amino acids that were previously described as monoclonal antibody-induced in vitro escape mutants. Our findings suggest that the evolution of subgroup A HRSV G glycoprotein is driven by immune pressure operating in certain codon positions located mainly in the second hypervariable region of the ectodomain. Phylogenetic analysis revealed the prolonged cocirculation of two subgroup A lineages among the Belgian population and the possible extinction of three other lineages. The evolutionary rate of HRSV subgroup A isolates was estimated to be 1.83 × 10(−3) nucleotide substitutions/site/year, projecting the most recent common ancestor back to the early 1940s

    Genetic Variability and Molecular Evolution of the Human Respiratory Syncytial Virus Subgroup B Attachment G Protein

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    Human respiratory syncytial virus (HRSV) is the most important cause of acute respiratory disease in infants. Two major subgroups (A and B) have been identified based on antigenic differences in the attachment G protein. Antigenic variation between and within the subgroups may contribute to reinfections with these viruses by evading the host immune responses. To investigate the circulation patterns and mechanisms by which HRSV-B viruses evolve, we analyzed the G protein genetic variability of subgroup B sequences isolated over a 45-year period, including 196 Belgian strains obtained over 22 epidemic seasons (1982 to 2004). Our study revealed that the HRSV-B evolutionary rate (1.95 × 10(−3) nucleotide substitutions/site/year) is similar to that previously estimated for HRSV-A (1.83 × 10(−3) nucleotide substitutions/site/year). However, natural HRSV-B isolates appear to accommodate more drastic changes in their attachment G proteins. The most recent common ancestor of the currently circulating subgroup B strains was estimated to date back to around the year 1949. The divergence between the two major subgroups was calculated to have occurred approximately 350 years ago. Furthermore, we have identified 12 positively selected sites in the G protein ectodomain, suggesting that immune-driven selective pressure operates in certain codon positions. HRSV-A and -B strains have similar phylodynamic patterns: both subgroups are characterized by global spatiotemporal strain dynamics, where the high infectiousness of HRSV permits the rapid geographic spread of novel strain variants
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