Molecular epidemiology of hepatitis C(HCV) among blood donors french between 2008 and 2011 and characterization of complete genome hepatitis C virus(HCV) among genotype 2 strains

La distribution des génotypes du virus de l’hépatite C (VHC). chez les donneurs de sang Français entre 2008 et 2011 a été analysée afin d’actualiser nos connaissances. Le génotypage des souches a permis d’identifier la diversité des génotypes circulants. Les sous-types 1a, 1b et 3a sont majoritairement retrouvés (80% des souches). L’analyse phylogénétique a démontré une grande variabilité chez les types 2 et 4 représentés par de nombreux sous-types. Les résultats montrent que les comportements à risque tendent à influencer et redessiner la distribution de ces génotypes dans la population générale. Certains sous-types se répandent dans des groupes à risque où ils finissent par adopter un profil épidémique. Enfin, la sélection des donneurs et la mise en place de tests diagnostiques ont permis de rendre la contamination transfusionnelle négligeable. Les données épidémiques obtenues ont été enrichies de nouvelles connaissances sur l'évolution et la classification du VHC. 15 séquences codantes complètes de plusieurs souches appartenant au type 2 ont été caractérisées. L’analyse phylogénétique révèle 2 clusters distincts. Le cluster 1 comprend la plupart des souches tandis que le cluster 2 comprend le sous-type 2l. Les génomes obtenus ont un ORF de 9042 à 9108 bases (3014 à 3036 acides aminés). Les distances moyennes entre sous- types sont égales à 20% dans le cluster 1 et 26% entre les deux clusters. La bifurcation entre clusters a eu lieu tôt lors de l'évolution du virus. L'insertion de 60 bases dans la région NS5A caractéristique du type 2 est absente chez les 2l. Donc, l'apparition et la fixation de celle-ci sont tardives dans l'évolution du virus.The distribution of genotypes of hepatitis C virus (HCV) infection among blood donors French between 2008 and 2011 was analyzed in order to update our knowledge. Genotyping strains identified the diversity of circulating genotypes. Subtypes 1a, 1b and 3a are found predominantly (80 % of strains). Phylogenetic analysis showed a great variability in types 2 and 4 represented by many subtypes. The results show that risk behaviors tend to influence and reshape the distribution of these genotypes in the general population. Some subtypes are spreading risk groups where they eventually adopt an epidemic profile. Finally, donor selection and implementation of diagnostic tests reduced drastically blood contamination. Epidemic data were enriched of new knowledge about the evolution and classification of HCV. 15 complete coding sequences of several strains of type 2 have been characterized. Phylogenetic analysis reveals two distinct clusters. Cluster 1 includes most strains while cluster 2 includes subtype 2l. Genomes obtained have an ORF of 9042 to 9108 bases (3014-3036 amino acids). The average distances between subtypes are equal to 20% in cluster 1 and 26 % between the two clusters. The bifurcation between clusters occurred early during the evolution of the virus. The insertion of 60 bases in the NS5A region characteristic of Type 2 is absent in 2l. So the appearance and fixing it is late in the evolution of the virus

Evidence for two phylogenetic clusters within hepatitis C virus (HCV) genotype 2 inferred from analysis of complete coding sequences of 15 HCV strains.

International audienceThe aim of this study was to gain further insight into the evolution and classification of hepatitis C virus (HCV) by assessing the subtype distribution of 273 genotype 2 strains isolated from French blood donors from 1990 to 2010 and by determining complete coding sequences in subtype 2 strains. These classified into 7 of the established subtypes and into 15 additional lineages not yet assigned to a known subtype. Phylogenetic tree construction showed two well-supported clusters. Cluster 1 included most subtype 2 strains while cluster 2 included subtype 2l and one unassigned subtype 2. Full genome sequencing was performed on 15 genotype 2 strains belonging to both clusters, that is, one subtype 2b, two subtype 2c, three subtype 2i, two subtype 2j, one subtype 2k, two subtype 2l, and four unassigned strains. Genomes included a 9042- to 9108-nucleic acid open reading frame coding for a polyprotein comprising 3014-3036 amino acids. Mean nucleotide distances between subtypes belonging to the first cluster was 20.2 ± 1.4% while the mean distance between the two clusters was 25.9 ± 0.3%. Analysis indicated that the bifurcation between subtype 2l and other subtype 2 strains occurred early in the evolutionary process. Subtype 2l retained a genomic feature characteristic of non-genotype 2, that is, absence of the 60-nucleotide insertion in the NS5A region. This finding suggests that appearance and fixation of this insertion occurred late in the evolutionary history of HCV type 2 and that its absence is an ancestral feature of HCV

Analysis of hepatitis C virus strains circulating in republic of the Congo

The aim of this study was to assess the seroprevalence, viremia, genotype distribution, and demographic history of hepatitis C virus (HCV) in the Republic of the Congo. Testing was carried out on sera samples collected in 2005 from 807 Bantus belonging to the Kongo, Teke, and Ngala subgroups and 80 Pygmies. Positive HCV serology was found in 50 (5.6%) individuals including31 (60%) who were viremic. Seroprevalence increased with age with a cutoff at 50 years:2.8% 50. Twenty-one strains belonged to four described subtypes, that is, 4c in eight cases, 4h in two, 4k in three, and 4r in eight. Ten strains could not be assigned to any known subtype and may represent six new variants, that is, subtype 4 in five cases and subtype 2 in one. Evolutionary analysis of subtype 4c and 4r sequences indicated a period of enhanced transmission in the mid-twentieth century probably due to iatrogenic causes. This study underlines the high genetic diversity of strains in the Republic of the Congo with nine subtypes 4 and one subtype 2

Lentiviral-mediated gene delivery in human monocyte-derived dendritic cells: optimized design and procedures for highly efficient transduction compatible with clinical constraints.

Gene delivery to dendritic cells (DCs) could represent a powerful method of inducing potent, long-lasting immunity. Although recent studies underline the intense interest in lentiviral vector-mediated monocyte-derived DC transduction, efficient gene transfer methods currently require high multiplicities of infection and are not compatible with clinical constraints. We have designed a strategy to optimize the efficiency and clinical relevance of this approach. Initially, using a third generation lentiviral vector expressing green fluorescent protein, we found that modifying the vector design, the DC precursor cell type, and the DC differentiation stage for transduction results in sustained transgene expression in 75-85% of immature DCs (transduction at a multiplicity of infection of 8). This high efficiency was reproducible among different donors irrespective of whether DCs were expanded from fresh or cryopreserved CD14(+) precursors. We then developed procedures that bypass the need for highly concentrated lentiviral preparations and the addition of polybrene to achieve efficient transduction. DCs transduced under these conditions retain their immature phenotype and immunostimulatory potential in both autologous and allogeneic settings. Furthermore, genetically modified DCs maintain their ability to respond to maturation signals and secrete bioactive IL-12, indicating that they are fully functional. Finally, the level of transgene expression is preserved in the therapeutically relevant mature DCs, demonstrating that there is neither promoter-silencing nor loss of transduced cells during maturation. The novel approach described should advance lentiviral-mediated monocyte-derived DC transduction towards a clinical reality.Journal ArticleResearch Support, Non-U.S. Gov'tSCOPUS: ar.jinfo:eu-repo/semantics/publishe

HLA-G Haplotypes Are Differentially Associated with Asthmatic Features

Human leukocyte antigen (HLA)-G, a HLA class Ib molecule, interacts with receptors on lymphocytes such as T cells, B cells, and natural killer cells to influence immune responses. Unlike classical HLA molecules, HLA-G expression is not found on all somatic cells, but restricted to tissue sites, including human bronchial epithelium cells (HBEC). Individual variation in HLA-G expression is linked to its genetic polymorphism and has been associated with many pathological situations such as asthma, which is characterized by epithelium abnormalities and inflammatory cell activation. Studies reported both higher and equivalent soluble HLA-G (sHLA-G) expression in different cohorts of asthmatic patients. In particular, we recently described impaired local expression of HLA-G and abnormal profiles for alternatively spliced isoforms in HBEC from asthmatic patients. sHLA-G dosage is challenging because of its many levels of polymorphism (dimerization, association with β2-microglobulin, and alternative splicing), thus many clinical studies focused on HLA-G single-nucleotide polymorphisms as predictive biomarkers, but few analyzed HLA-G haplotypes. Here, we aimed to characterize HLA-G haplotypes and describe their association with asthmatic clinical features and sHLA-G peripheral expression and to describe variations in transcription factor (TF) binding sites and alternative splicing sites. HLA-G haplotypes were differentially distributed in 330 healthy and 580 asthmatic individuals. Furthermore, HLA-G haplotypes were associated with asthmatic clinical features showed. However, we did not confirm an association between sHLA-G and genetic, biological, or clinical parameters. HLA-G haplotypes were phylogenetically split into distinct groups, with each group displaying particular variations in TF binding or RNA splicing sites that could reflect differential HLA-G qualitative or quantitative expression, with tissue-dependent specificities. Our results, based on a multicenter cohort, thus support the pertinence of HLA-G haplotypes as predictive genetic markers for asthma

Human pegivirus isolates characterized by deep sequencing from hepatitis C virus‐RNA and human immunodeficiency virus‐RNA–positive blood donations, France

International audienceHuman pegivirus (HPgV, formerly GBV-C) is a member of the genus Pegivirus, family Flaviviridae. Despite its identification more than 20 years ago, both natural history and distribution of this viral group in human hosts remain under exploration. Analysis of HPgV genomes characterized up to now points out the scarcity of French pegivirus sequences in databases. In order to bring new data regarding HPgV genomic diversity, we investigated 16 French isolates obtained from HCV- and HIV-RNA positive blood donations following deep sequencing and coupled molecular protocols. Initial phylogenetic analysis of 5'UTR / E2 partial sequences permitted to assign HPgV isolates to genotypes 2 (n=15) and 1 (n=1), with up to 16% genetic diversity observed for both regions considered. Seven nearly-full length representative genomes were characterized subsequently, with complete polyprotein coding sequences exhibiting up to 13% genetic diversity; closest nucleotide divergence with available HPgV sequences was in the range 7-11%. A 36nt deletion located on the NS4B coding region (N-terminal part, 12aa) of the genotype 1 HPgV genome characterized was identified, along with single nucleotide deletions in two genotype 2 5'UTR sequences

Molecular characterization of genotype 2 and 4 hepatitis C virus isolates in French blood donors

The subtype distribution of 142 genotype 2 and 97 genotype 4 hepatitis C virus (HCV) isolates from the sera of 1,319 volunteer blood donors in France was determined by gene sequencing and by phylogenetic analysis of the NS5B region and E1 envelope. Findings underlined a wide range of subtypes in both genotypes, that is, 20 in HCV-2 and 11 in HCV-4. Eighteen of these 31 subtypes had not been defined previously. Some subtypes, that is, 2a, 2b, 2c, 2i, 2k, 4a, and 4d, showed numerous strains while subtypes in donors from West Africa or Central Africa showed an endemic profile with only a few strains. A Bayesian coalescence approach was used to estimate the demographic history of each HCV subtype. The estimated mean dates of the most recent common ancestors (MRCA) were 1,889 (confidence interval (CI), 1,842-1,930) for HCV-2a, 1,886 (CI, 1,843-1,921) for HCV-2b, 1,791 (CI, 1,699-1,848) for HCV-2c, 1,846 (CI, 1,803-1,878) for HCV-2i, 1,911 (CI, 1,879-1,937) for HCV-4a, and 1,957 (CI, 1,943-1,967) for HCV-4d. The period of spread for subtype 2b, 2c, and 2i was between 1900 and 1960 whereas rapid exponential spread for subtype 2a, 4a, and 4d occurred in the 1960s. The inferred histories of population growth indicated that transmission rates differed according to HCV subtype. These results may help to predict the future burden of HCV in France

Divergent Gemycircularvirus in HIV-Positive Blood, France

International audienceWe retrospectively analyzed the impact of HLA-DPB1 mismatches in a large cohort of 1342 French patients who underwent 10/10 HLA-matched unrelated HSCT. A significant impact of HLA-DPB1 allelic mismatches (2 vs 0) was observed in severe acute GVHD (aGVHDIII-IV) (risk ratio (RR)=1.73, confidence interval (CI) 95% 1.09-2.73, P=0.019) without impact on OS, TRM, relapse and chronic GVHD (cGVHD). According to the T-cell epitope 3 (TCE3)/TCE4 HLA-DPB1 disparity algorithm, 37.6% and 58.4% pairs had nonpermissive HLA-DPB1, respectively. TCE3 and TCE4 disparities had no statistical impact on OS, TRM, relapse, aGVHD and cGVHD. When TCE3/TCE4 disparities were analyzed in the graft-vs-host or host-vs-graft (HVG) direction, only a significant impact of TCE4 nonpermissive disparities in the HVG direction was observed on relapse (RR=1.34, CI 95% 1.00-1.80, P=0.048). In conclusion, this French retrospective study shows an adverse prognosis of HLA-DPB1 mismatches (2 vs 0) on severe aGVHD and of nonpermissive TCE4 HVG disparities on relapse after HLA-matched 10/10 unrelated HSCT

HLA-H: Transcriptional Activity and HLA-E Mobilization

International audienceLittle attention is paid to pseudogenes from the highly polymorphic HLA genetic region. The pseudogene HLA-H is defined as a non-functional gene because it is deleted at different frequencies in humans and because it encodes a potentially non-functional truncated protein. However, different studies have shown HLA-H transcriptional activity. We formerly identified 13 novel HLA-H alleles, including the H*02:07 allele, which reaches 19.6% in East Asian populations and encodes a full-length HLA protein. The aims of this study were to explore the expression and possible function of the HLA-H molecule. HLA-H may act as a transmembrane molecule and/or indirectly via its signal peptide by mobilizing HLA-E to the cell surface. We analyzed HLA-H RNA expression in Peripheral Blood Mononuclear Cells (PBMC), Human Bronchial Epithelial Cells (HBEC), and available RNA sequencing data from lymphoblastoid cell lines, and we looked to see whether HLA-E was mobilized at the cell surface by the HLA-H signal peptide. Our data confirmed that HLA-H is transcribed at similar levels to HLA-G. We characterized a hemizygous effect in HLA-H expression, and expression differed according to HLA-H alleles; most interestingly, the HLA-H*02:07 allele had the highest level of mRNA expression. We showed that HLA-H signal peptide incubation mobilized HLA-E molecules at the cell surface of T-Lymphocytes, monocytes, B-Lymphocytes, and primary epithelial cells. Our results suggest that HLA-H may be functional but raises many biological issues that need to be addressed

Low Prevalence of HLA-G Antibodies in Lung Transplant Patients Detected using MAIPA-Adapted Protocol

Lung transplantation is often complicated by acute and/or chronic rejection leading to graft-function loss. In addition to the HLA donor-specific antibodies (HLA-DSA), a few autoantibodies are correlated with the occurrence of these complications. Recently, antibodies directed against non-classical HLA molecules, HLA-G, -E, and -F have been detected in autoimmune diseases, like systemic lupus erythematosus. Non-classical HLA molecules are crucial in the immunological acceptance of the lung graft, and some of their isoforms, like HLA-G*01:04 and -G*01:06, are associated with a negative clinical outcome. The aim of this study is to determine the frequency of detection of HLA-G antibodies in lung transplant recipients (LTRs) and their impact on the occurrence of clinical complications. After incubating the cell lines SPI-801, with and without three different HLA-G isoform expression, with sera from 90 healthy blood donors and 35 LTRs (before and after transplantation), HLA-G reactivity was revealed using reagents from commercial monoclonal antibody immobilization of platelet antigen assay (MAIPA ApDIA®). Only one serum from one blood donor had specific reactivity against the HLA-G transduced lines. Non-specific reactivity in many sera from LTRs was observed with transduced- and wild-type cell lines, which may suggest recognition of an autoantigen expressed by the SPI-801 cell line. In conclusion, this study allowed the development of a specific detection tool for non-denatured HLA-G antibodies. These antibodies seem uncommon, both in healthy subjects and in complicated LTRs. This study should be extended to patients suffering from autoimmune diseases as well as kidney and heart transplant recipients