Serological, molecular and phylogenetic analysis of Rice Yellow Mottle Virus (RYMV) isolates collected in Southern-Benin

The rice yellow mottle is the best known viral disease of rice in Africa. It causes significant economic losses in farmer’s fields. The serological properties of Rice Yellow Mottle Virus (RYMV) isolates, collected in Southern Benin, were assessed by immunological tests with polyclonal and monoclonal antibodies (Pabs and MAbs). The isolates CP (Capsid protein) portions, obtained by RT-PCR, were sequenced and their amino-acids sequences were analyzed and used for phylogenetic analysis. Three different RYMV pathogenic groups, including three resistance breaking (RB) isolates (Be20, Be21 and Be27) which over came allele rymv1-5gene, were identified. Two serotypes Ser1/strain S1 and Ser2/ strain S2 were also distinguished. The molecular properties of the isolates CP gene and the phylogenetic characteristics indicated that the Southern Benin RYMV strain is heterogeneous. The strain S1-Benin linked to the West Central African lineage(S1-WCA) is related to strain from Togo and Niger, whereas, the strain S2 Benin is the stumps of the West African lineage (S1-WA) and is related to Mali, Burkina Faso and Ivory Coast RYMV strains. These results reported the virus pathogenicity level and showed the relationships between RYMV strains in all Dahomey gap countries and in West and Central Africa. Keywords: serotypes, RYMV strains, RB isolates and phylogenetic analysis

Flavivirus: From Structure to Therapeutics Development

Flaviviruses are still a hidden threat to global human safety, as we are reminded by recent reports of dengue virus infections in Singapore and African-lineage-like Zika virus infections in Brazil. Therapeutic drugs or vaccines for flavivirus infections are in urgent need but are not well developed. The Flaviviridae family comprises a large group of enveloped viruses with a single-strand RNA genome of positive polarity. The genome of flavivirus encodes ten proteins, and each of them plays a different and important role in viral infection. In this review, we briefly summarized the major information of flavivirus and further introduced some strategies for the design and development of vaccines and anti-flavivirus compound drugs based on the structure of the viral proteins. There is no doubt that in the past few years, studies of antiviral drugs have achieved solid progress based on better understanding of the flavivirus biology. However, currently, there are no fully effective antiviral drugs or vaccines for most flaviviruses. We hope that this review may provide useful information for future development of anti-flavivirus drugs and vaccines.

African-lineage Zika virus replication dynamics and maternal-fetal interface infection in pregnant rhesus macaques

Following the Zika virus (ZIKV) outbreak in the Americas, ZIKV was causally associated with microcephaly and a range of neurological and developmental symptoms, termed congenital Zika syndrome (CZS). The viruses responsible for this outbreak belonged to the Asian lineage of ZIKV. However, in-vitro and in-vivo studies assessing the pathogenesis of African-lineage ZIKV demonstrated that African-lineage isolates often replicated to high titer and caused more severe pathology than Asian-lineage isolates. To date, the pathogenesis of African-lineage ZIKV in a translational model, particularly during pregnancy, has not been rigorously characterized. Here we infected four pregnant rhesus macaques with a low-passage strain of African-lineage ZIKV and compared its pathogenesis to a cohort of four pregnant rhesus macaques infected with an Asian-lineage isolate and a cohort of mock-inoculated controls. Viral replication kinetics were not significantly different between the two experimental groups and both groups developed robust neutralizing antibody titers above levels considered to be protective. There was no evidence of significant fetal head growth restriction or gross fetal harm at delivery (1-1.5 weeks prior to full term) in either group. However, a significantly higher burden of ZIKV vRNA was found in maternal-fetal interface tissues in the macaques exposed to an African-lineage isolate. Our findings suggest that ZIKV of any genetic lineage poses a threat to pregnant individuals and their infants. IMPORTANCE ZIKV was first identified in 1947 in Africa, but most of our knowledge of ZIKV is based on studies of the distinct Asian genetic lineage, which caused the outbreak in the Americas in 2015-16. In its most recent update, the WHO stated that improved understanding of African-lineage pathogenesis during pregnancy must be a priority. Recent detection of African-lineage isolates in Brazil underscores the need to understand the impact of these viruses. Here we provide the first comprehensive assessment of African-lineage ZIKV infection during pregnancy in a translational non-human primate model. We show African-lineage isolates replicate with similar kinetics to Asian-lineage isolates and can infect the placenta. However, there was no evidence of more severe outcomes with African-lineage isolates. Our results highlight both the threat that African-lineage ZIKV poses to pregnant individuals and their infants and the need for future epidemiological and translational in-vivo studies with African-lineage ZIKV.

Kinetics of Asian and African Zika Virus Lineages over Single-cycle and Multi-cycle Growth in Culture: gene expression, cell killing, virus production, and mathematical modeling

Since 2014, an Asian lineage of Zika virus has caused outbreaks, and it has been associated with neurological disorders in adults and congenital defects in newborns. The resulting threat of the Zika virus to human health has prompted the development of new vaccines, which have yet to be approved for human use. Vaccines based on the attenuated or chemically inactivated virus will require large-scale production of the intact virus to meet potential global demands. Intact viruses are produced by infecting cultures of susceptible cells, a dynamic process that spans from hours to days and has yet to be optimized. Here, we infected Vero cells adhesively cultured in well-plates with two Zika virus strains: a recently isolated strain from the Asian lineage, and a cell-culture-adapted strain from the African lineage. At different time points post-infection, virus particles in the supernatant were quantified; further, microscopy images were used to quantify cell density and the proportion of cells expressing viral protein. These measurements were performed across multiple replicate samples of one-step infections every four hours over 60 hours and for multi-step infections every four to 24 hours over 144 hours, generating a rich dataset. For each set of data, mathematical models were developed to estimate parameters associated with cell infection and virus production. The African-lineage strain was found to produce a 14-fold higher yield than the Asian-lineage strain in one-step growth and a 7-fold higher titer in multi-step growth, suggesting a benefit of cell-culture adaptation for developing a vaccine strain. We found that image-based measurements were critical for discriminating among different models, and different parameters for the two strains could account for the experimentally observed differences. An exponential-distributed delay model performed best in accounting for multi-step infection of the Asian strain, and it highlighted the significant sensitivity of virus titer to the rate of viral degradation, with implications for optimization of vaccine production. More broadly, this work highlights how image-based measurements can contribute to discrimination of virus-culture models for the optimal production of inactivated and attenuated whole-virus vaccines.

Transcriptional signatures of Zika virus infection in astrocytes

Astrocytes are an early and important target of Zika virus (ZIKV) infection in the developing brain, but the impacts of infection on astrocyte function remain controversial. Given that nonhuman primate (NHP) models of ZIKV infection replicate aspects of neurologic disease seen in human infections, we cultured primary astrocytes from the brain tissue of infant rhesus macaques and then infected the cells with Asian or African lineage ZIKV to identify transcriptional patterns associated with infection in these cells. The African lineage virus appeared to have greater infectivity and promote stronger antiviral signaling, but infection by either strain ultimately produced typical virus response patterns. Both viruses induced hypoxic stress, but the Asian lineage strain additionally had an effect on metabolic and lipid biosynthesis pathways. Together, these findings describe an NHP astrocyte model that may be used to assess transcriptional signatures following ZIKV infection.

African-lineage Zika virus replication dynamics and maternal-fetal interface infection in pregnant rhesus macaques

ABSTRACTFollowing the Zika virus (ZIKV) outbreak in the Americas, ZIKV was causally associated with microcephaly and a range of neurological and developmental symptoms, termed congenital Zika syndrome (CZS). The isolates responsible for this outbreak belonged to the Asian lineage of ZIKV. However, in-vitro and in-vivo studies assessing the pathogenesis of African-lineage ZIKV demonstrated that African-lineage isolates often replicated to high titer and caused more severe pathology than Asian-lineage isolates. To date, the pathogenesis of African-lineage ZIKV in a translational model, particularly during pregnancy, has not been rigorously characterized. Here we infected four pregnant rhesus macaques with a low-passage strain of African-lineage ZIKV and compared its pathogenesis to a cohort of four pregnant rhesus macaques infected with an Asian-lineage isolate and a cohort of mock-infected controls. Viral replication kinetics were not significantly different between the two experimental groups and both groups developed robust neutralizing antibody titers above levels considered to be protective. There was no evidence of significant fetal head growth restriction or gross fetal harm at delivery in either group. However, a significantly higher burden of ZIKV vRNA was found in maternal-fetal interface tissues in the macaques exposed to an African-lineage isolate. Our findings suggest that ZIKV isolates of any genetic lineage pose a threat to women and their infants.IMPORTANCEZIKV was first identified over 70 years ago in Africa, but most of our knowledge of ZIKV is based on studies of the distinct Asian genetic lineage, which caused the outbreak in the Americas in 2015-16. In its most recent update, the WHO stated that improved understanding of African-lineage pathogenesis during pregnancy must be a priority. Recent detection of African-lineage isolates in Brazil underscores the need to understand the impact of these viruses. Here we provide the first comprehensive assessment of African-lineage ZIKV infection during pregnancy in a translational non-human primate model. We show African-lineage isolates replicate with similar kinetics to Asian-lineage isolates and are capable of infecting the placenta. However, there was no evidence of more severe outcomes with African-lineage isolates. Our results highlight both the threat that African-lineage ZIKV poses to women and their infants and the need for future epidemiological and translational in-vivo studies with African-lineage ZIKV.