15 APOBEC3 GENES ARE UNIQUE TO MAMMALS, BUT COPY NUMBERS VARY SIGNIFICANTLYAPOBEC3 (A3) proteins are of considerable interest because most are potent DNA cytidine deaminases that have the capacity to restrict the replication and/or edit the sequences of a wide variety of parasitic elements, including many retroviruses and retrotransposons (reviewed in references 5, 8-10, and 14). Likely substrates include (i) lentiviruses, such as human immunodeficiency virus type 1, human immunodeficiency virus type 2, simian immunodeficiency virus, maedi-visna virus, feline immunodeficiency virus, and equine infectious anemia virus; (ii) alpha-, beta-, gamma-, and deltaretroviruses, such as Rous sarcoma virus, MasonPfizer monkey virus or mouse mammary tumor virus, murine leukemia virus or feline leukemia virus, and human T-cell leukemia virus or bovine leukemia virus, respectively; (iii) spumaviruses, such as primate foamy virus and feline foamy virus; (iv) hepadnaviruses, such as hepatitis B virus; (v) endogenous retroviruses and long terminal repeat retrotransposons, such as human endogenous retrovirus K, murine intracisternal A particle, murine MusD, and porcine endogenous retrovirus; (vi) non-long terminal repeat retroposons, such as L1 and Alu; and (vii) DNA viruses, such as adenoassociated virus and human papillomavirus. Over the past few years, there has also been an increasing appreciation for the multiple, distinct mechanisms that parasitic elements use to coexist with the A3 proteins of their hosts. Together, these observations indicate that the evolution of the A3 proteins has been driven by a requirement to minimize the spread of exogenous and endogenous genetic threats. The likelihood that the A3 proteins might exist solely for this purpose has been supported recently by studies indicating that A3-deficient mice have no obvious phenotypes apart from a notable increase in susceptibility to retrovirus infection (16,19,21,23).A3 genes are specific to mammals and are organized in a tandem array between two vertebrate-conserved flanking genes, CBX6 and CBX7 (Fig. 1A) (e.g., see reference 13). Based on a limited number of genomic sequences, it is already clear that the A3 copy number can vary greatly from mammal to mammal. For instance, mice have one A3 gene (10, 16), pigs have two (13), cattle and sheep have three (13), cats have four (17), horses have six (2), and humans and chimpanzees have seven (4, 10, 11). Other mammals are likely to have copy numbers within this range, but the cat and horse loci, in particular, highlight the difficulty in making such predictions (2, 17).
We report the first and only case of a porcine epidemic diarrhea (PED) outbreak occurring in December 2014 in northern France, and we show using the full-length genome sequence of the French PED virus (PEDV) isolate that it was a PEDV indel strain close to German PEDV strains recently isolated.
Since 2015, annual West Nile virus (WNV) outbreaks of varying intensities have been reported in France. Recent intensification of enzootic WNV circulation was observed in the South of France with most horse cases detected in 2015 (n = 49), 2018 (n = 13), and 2019 (n = 13). A WNV lineage 1 strain was isolated from a horse suffering from West Nile neuro-invasive disease (WNND) during the 2015 episode in the Camargue area. A breaking point in WNV epidemiology was achieved in 2018, when WNV lineage 2 emerged in Southeastern areas. This virus most probably originated from WNV spread from Northern Italy and caused WNND in humans and the death of diurnal raptors. WNV lineage 2 emergence was associated with the most important human WNV epidemics identified so far in France (n = 26, including seven WNND cases and two infections in blood and organ donors). Two other major findings were the detection of WNV in areas with no or limited history of WNV circulation (Alpes-Maritimes in 2018, Corsica in 2018–2019, and Var in 2019) and distinct spatial distribution of human and horse WNV cases. These new data reinforce the necessity to enhance French WNV surveillance to better anticipate future WNV epidemics and epizootics and to improve the safety of blood and organ donations.
The selection of motile human spermatozoa, from fertile and infertile semen samples was compared by using Percoll density gradient centrifugation or the swim-up procedure. Selected spermatozoa were evaluated according to their motility, % normal forms, nuclear maturity (aniline blue staining, acridine orange staining, ethidium bromide uptake and SDS nuclear decondensation). These methods showed differences between fertile and infertile men. The swim-up procedure, based on motility, resulted in greater proportions of motile spermatozoa and eliminated mainly tail abnormalities. Percoll gradient separation, based on density, selected oval-headed spermatozoa with good motility. Nuclear maturity level was improved by both methods but Percoll gradient separation generally resulted in spermatozoa with better nuclear maturity than those selected by the swim-up procedure.
The emergence and worldwide spread of SARS-CoV-2 raises new concerns and challenges regarding possible environmental contamination by this virus through spillover of human sewage, where it has been detected. The coastal environment, under increasing anthropogenic pressure, is subjected to contamination by a large number of human viruses from sewage, most of them being non-enveloped viruses like norovirus. When reaching coastal waters, they can be bio-accumulated by filter-feeding shellfish species such as oysters. Methods to detect this viral contamination were set up for the detection of non-enveloped enteric viruses, and may need optimization to accommodate enveloped viruses like coronaviruses (CoV). Here, we aimed at assessing methods for the detection of CoV, including SARS-CoV-2, in the coastal environment and testing the possibility that SARS-CoV-2 can contaminate oysters, to monitor the contamination of French shores by SARS-CoV-2 using both seawater and shellfish. Using the porcine epidemic diarrhea virus (PEDV), a CoV, as surrogate for SARS-CoV-2, and Tulane virus, as surrogate for non-enveloped viruses such as norovirus, we assessed and selected methods to detect CoV in seawater and shellfish. Seawater-based methods showed variable and low yields for PEDV. In shellfish, the current norm for norovirus detection was applicable to CoV detection. Both PEDV and heat-inactivated SARS-CoV-2 could contaminate oysters in laboratory settings, with a lower efficiency than a calicivirus used as control. Finally, we applied our methods to seawater and shellfish samples collected from April to August 2020 in France, where we could detect the presence of human norovirus, a marker of human fecal contamination, but not SARS-CoV-2. Together, our results validate methods for the detection of CoV in the coastal environment, including the use of shellfish as sentinels of the microbial quality of their environment, and suggest that SARS-CoV-2 did not contaminate the French shores during the summer season.
In Europe, modified live vaccines (MLV) are commonly used to control porcine reproductive and respiratory syndrome virus (PRRSV) infection. However, they have been associated with safety issues such as reversion to virulence induced by mutation and/or recombination. On a French pig farm, we identified a field recombinant strain derived from two PRRSV-1 MLV (MLV1). As a result, we aimed to evaluate its clinical, virological, and transmission parameters in comparison with both parental strains. Three groups with six pigs in each were inoculated with either one of the two MLV1s or with the recombinant strain; six contact pigs were then added into each inoculated group. The animals were monitored daily for 35 days post-inoculation (dpi) for clinical symptoms; blood samples and nasal swabs were collected twice a week. PRRS viral load in inoculated pigs of recombinant group was higher in serum, nasal swabs, and tonsils in comparison with both vaccine groups. The first viremic contact pig was detected as soon as 2 dpi in the recombinant group compared to 10 and 17 dpi for vaccine groups. Estimation of transmission parameters revealed fastest transmission and longest duration of infectiousness for recombinant group. Our in vivo study showed that the field recombinant strain derived from two MLV1s demonstrated high viremia, shedding and transmission capacities.
Porcine endogenous retroviruses (PERV) are a major concern when porcine tissues and organs are used for xenotransplantation. PERV has been shown to infect human cells in vitro, highlighting a potential zoonotic risk. No pathology is associated with PERV in its natural host, but the pathogenic potential might differ in the case of cross-species transmission and can only be inferred from knowledge of related gammaretroviruses. We therefore investigated the integration features of the PERV DNA in the human genome in vitro in order to further characterize the risk associated with PERV transmission. In this study, we characterized 189 PERV integration site sequences from human HEK-293 cells. Data showed that PERV integration was strongly enhanced at transcriptional start sites and CpG islands and that the frequencies of integration events increased with the expression levels of the genes, except for the genes with the highest levels of expression, which were disfavored for integration. Finally, we extracted genomic sequences directly flanking the integration sites and found an original 8-base statistical palindromic consensus sequence [TG(int)GTACCAGC]. All these results show similarities between PERV and murine leukemia virus integration site selection, suggesting that gammaretroviruses have a common pattern of integration and that the mechanisms of target site selection within a retrovirus genus might be similar.
Rabbit haemorrhagic disease is a viral disease that emerged in the 1980s and causes high mortality and morbidity in the European rabbit (Oryctolagus cuniculus). In 2010, a new genotype of the rabbit haemorrhagic disease virus emerged and replaced the former circulating Lagovirus europaeus/GI.1 strains. Several recombination events have been reported for the new genotype Lagovirus europaeus/ GI.2, with pathogenic (variants GI.1a and GI.1b) and benign (genotype GI.4) strains that served as donors for the non-structural part while GI.2 composed the structural part; another recombination event has also been described at the p16/p23 junction involving GI.4 strains. In this study, we analysed new complete coding sequences of four benign GI.3 strains and four GI.2 strains. Phylogenetic and recombination detection analyses revealed that the first GI.2 strains, considered as non-recombinant, resulted from a recombination event between GI.3 and GI.2, with GI.3 as the major donor for the nonstructural part and GI.2 for the structural part. Our results indicate that recombination contributed to the emergence, persistence and dissemination of GI.2 as a pathogenic form and that all described GI.2 strains so far are the product of recombination. This highlights the need to study full-genomic sequences of lagoviruses to understand their emergence and evolution. Since the 1980s, European rabbits worldwide, either domestic or wild, have been affected by rabbit haemorrhagic disease 1. This highly contagious and fatal disease is caused by the rabbit haemorrhagic disease virus (RHDV), a single-stranded positive-sense RNA virus that belongs to the family Caliciviridae, genus Lagovirus. Benign rabbit caliciviruses that confer more or less protection against pathogenic strains, as well as moderately pathogenic strains, including Michigan rabbit calicivirus (MRCV), have also been described 2-7. In 2010, a new pathogenic lagovirus was identified in France 8 , formerly designated as RHDV2 or RHDVb and now as Lagovirus europaeus/GI.2 according to a proposal for a unified nomenclature for lagoviruses 9. GI.2 caused unusual mortalities in rabbits vaccinated against GI.1 (former G1-G6) strains 8, 10. Further analysis revealed genetic differences that were reflected in its positioning in a phylogenetic tree based on capsid protein (VP60) sequences. GI.2 constituted a new phylogenetic group 8, 11 with more than 15% divergence from all know benign and pathogenic lagoviruses. Other unique characteristics include its ability to fatally infect rabbits younger than two months (previously resistant to the disease) 11, 12 and several hare species (Lepus spp.) 13-17. Differences in disease duration, mortality rates, and in the frequency of occurrence of subacute/chronic forms have also been
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