RNA Control of HIV-1 Particle Size Polydispersity

HIV-1, an enveloped RNA virus, produces viral particles that are known to be much more heterogeneous in size than is typical of non-enveloped viruses. We present here a novel strategy to study HIV-1 Viral Like Particles (VLP) assembly by measuring the size distribution of these purified VLPs and subsequent viral cores thanks to Atomic Force Microscopy imaging and statistical analysis. This strategy allowed us to identify whether the presence of viral RNA acts as a modulator for VLPs and cores size heterogeneity in a large population of particles. These results are analyzed in the light of a recently proposed statistical physics model for the self-assembly process. In particular, our results reveal that the modulation of size distribution by the presence of viral RNA is qualitatively reproduced, suggesting therefore an entropic origin for the modulation of RNA uptake by the nascent VLP

RNA Viral Community in Human Feces: Prevalence of Plant Pathogenic Viruses

The human gut is known to be a reservoir of a wide variety of microbes, including viruses. Many RNA viruses are known to be associated with gastroenteritis; however, the enteric RNA viral community present in healthy humans has not been described. Here, we present a comparative metagenomic analysis of the RNA viruses found in three fecal samples from two healthy human individuals. For this study, uncultured viruses were concentrated by tangential flow filtration, and viral RNA was extracted and cloned into shotgun viral cDNA libraries for sequencing analysis. The vast majority of the 36,769 viral sequences obtained were similar to plant pathogenic RNA viruses. The most abundant fecal virus in this study was pepper mild mottle virus (PMMV), which was found in high concentrations—up to 10(9) virions per gram of dry weight fecal matter. PMMV was also detected in 12 (66.7%) of 18 fecal samples collected from healthy individuals on two continents, indicating that this plant virus is prevalent in the human population. A number of pepper-based foods tested positive for PMMV, suggesting dietary origins for this virus. Intriguingly, the fecal PMMV was infectious to host plants, suggesting that humans might act as a vehicle for the dissemination of certain plant viruses

Poliovirus mutant that contains a cold-sensitive defect in viral RNA synthesis

By manipulating an infectious cDNA clone of poliovirus, we have introduced a single-codon insertion into the 3A region of the viral genome which has been proposed to encode a functional precursor of the virion-linked protein VPg. The resulting mutant was cold sensitive in monkey kidney cells. Viral RNA synthesis was poor at 32.5 degrees C, although no other function of the virus was obviously affected. The synthesis of both positive and negative strands was severely depressed. Temperature shift experiments suggest that a normal level of production of the affected function was required only during the early (exponential) phase of RNA synthesis. Analysis of viral polyprotein processing at the nonpermissive temperature revealed that some of the normal cleavages were not made, most likely as a consequence of the defect in RNA synthesis or as a result of the concomitant reduction in the level of virally encoded proteases

HLA and HIV Infection Progression: Application of the Minimum Description Length Principle to Statistical Genetics

The minimum description length (MDL) principle states that the best model to account for some data minimizes the sum of the lengths, in bits, of the descriptions of the model and the residual error. The description length is thus a criterion for model selection. Description-length analysis of HLA alleles from the Chicago MACS cohort enables classification of alleles associated with plasma HIV RNA, an indicator of infection progression. Progression variation is most strongly associated with HLA-B. Individuals without B58s supertype alleles average viral RNA levels 3.6-fold greater than individuals with them.Comment: 17 pages, 1 figur

Influence of viral genes on the cell-to-cell spread of RNA silencing

The turnip crinkle virus-based vector TCV–GFPDCP had been devised previously to study cell-to-cell and long-distance spread of virus-induced RNA silencing. TCV–GFPDCP, which had been constructed by replacing the coat protein (CP) gene with a green fluorescent protein (GFP) coding sequence, was able to induce RNA silencing in single epidermal cells, from which RNA silencing spread from cell-to-cell. Using this unique local silencing assay together with mutagenesis analysis, two TCV genes, p8 and p9, which were involved in the intercellular spread of virus-induced RNA silencing, were identified. TCV–GFPDCP and its p8- or p9-mutated derivatives, TCVmp8–GFPDCP and TCVmp9–GFPDCP, replicated efficiently but were restricted to single Nicotiana benthamiana epidermal cells. TCV–GFPDCP, TCVmp8–GFPDCP, or TCVmp9–GFPDCP was able to initiate RNA silencing that targeted and degraded recombinant viral RNAs in inoculated leaves of the GFP-expressing N. benthamiana line 16c. However, cell-to-cell spread of silencing to form silencing foci was triggered only by TCV–GFPDCP. Non-replicating TCVmp88–GFPDCP and TCVmp28mp88–GFPDCP with dysfunctional replicase genes, and single-stranded gfp RNA did not induce RNA silencing. Transient expression of the TCV p9 protein could effectively complement TCVmp9–GFPDCP to facilitate intercellular spread of silencing. These data suggest that the plant cellular trafficking machinery could hijack functional viral proteins to permit cell-to-cell movement of RNA silencing

Banana plants use post-transcriptional gene silencing to control banana streak virus infection

Banana streak virus (BSV), the causative agent of banana streak disease, is a plant pararetrovirus belonging to the family Caulimoviridae, genus Badnavirus. The genome of BSV is a circular double-stranded DNA of 7.4 kbp made of three ORFs and like other pararetroviruses replicates via reverse transcription of viral pregenomic RNA (Lockhart, 1990). While the first two ORFs encode two small proteins of unknown function, the third ORF (~210 kD) encodes a polyprotein that can be cleaved to yield the viral coat protein and proteins with homology to aspartic protease, reverse transcriptase and RNaseH. Little information is available about antiviral defense response of the host plant on BSV or other members of Caulimoviridae. RNA silencing, also known as RNA interference (RNAi), is an ancient gene regulation and cell defense mechanism, which exists in most eukaryotes (Xie and Qi, 2008). Plants have adapted the RNA silencing machinery into an antiviral defense system. Interestingly, Arabidopsis plants infected with Cauliflower mosaic virus (CaMV), a type member of the genus Caulimovirus in the family Caulimoviridae, accumulate siRNAs of 21, 22 and 24 nt size classes, where the 24 nt species are the most predominant ones (Blevins et al., 2006; Moissiard and Voinnet, 2006). Further analysis showed that, the leader region (600 nt) of CaMV pregenomic RNA produces massive amounts of siRNAs with several hot and cold spots of siRNA generation (Blevins et al., 2011) to function as a decoy for the RNA silencing defense system of the plant. To determine whether the viral decoy strategy was universally used among viruses belonging to the family Caulimoviridae, we have performed a deep sequencing of total siRNAs of 6 Cavendish banana plants infected independently with one of the 6 BSV species we own in the laboratory. We obtained for the first time, experimental evidence of virus-derived small RNA (vsRNA) from those 6 BSV species by blasting sequencing data against the 6 BSV species genomes. vsRNA are enriched in 21-nt class thus BSV are likely silenced at the post-transcriptional level. Besides, our data unequivocally show that the decoy strategy used by the CaMV is not employed by the BSV since most of the hot spots of siRNA production are located in ORF1 and 2. Information generated about siRNAs derived from BSV genome could help us to design silencing-based transgenic and non-transgenic (RNA vaccination) approaches to obtain BSV resistance in banana crop. (Texte intégral