Positive selection and recombination shaped the large genetic differentiation of Beet black scorch virus population

Phylogenomic Analyses of the Hemagglutinin-Neuraminidase (HN) Gene in Human Parainfluenza Virus Type 4 Isolates in Japan

To better understand the phylogenomics of the hemagglutinin-neuraminidase (HN) gene and HN protein in human parainfluenza virus type 4 (HPIV4), we performed phylogenomic analyses using various bioinformatics methods. The main bioinformatics analyses included a time-scaled phylogeny, genetic distance assessments, and three-dimensional (3D) structure mapping of the HN protein with conformational epitope and selective pressure analyses. The time-scaled phylogenetic tree indicated that the most recent common ancestor of the HN gene emerged approximately 100 years ago. Additionally, the tree revealed two distinct clusters corresponding to HPIV4a and HPIV4b. The divergence times for the most recent common ancestors of the HN gene in HPIV4a and HPIV4b strains were estimated to be around 1993 and 1986, respectively. The evolutionary rates of the gene varied significantly between clusters, ranging from approximately 1.2 × 10-3 to 8.7 × 10-4 substitutions per site per year. Genetic distances within each cluster were relatively short (less than 0.04). Phylodynamic analyses demonstrated an increase in the genome population size around the year 2000. Structural analyses revealed that the active sites of the HN protein were located at the protein's head. Furthermore, the most conformational epitopes were located in adjacent active sites of the protein. These results suggested that reinfection may be unlikely to occur in the case of most HPIV4. Together, the HN gene and protein of HPIV4 strains isolated in Japan have undergone unique evolutionary changes. In addition, antibodies targeting the conformational epitopes of the HPIV4 HN protein may contribute to protection against the virus.

Banana bunchy top virus genetic diversity in Pakistan and association of diversity with recombination in its genomes

Banana Bunchy top virus (BBTV) is a multipartite circular single strand DNA virus that belongs to genus Babuvirus and family Nanoviridae. It causes significant crop losses worldwide and also in Pakistan. BBTV is present in Pakistan since 1988 however, till now only few (about twenty only) sequence of genomic components have been reported from the country. To have insights into current genetic diversity in Pakistan fifty-seven genomic components including five complete genomes (comprises of DNA-R, -U3, -S, -M, -C and -N components) were sequenced in this study. The genetic diversity analysis of populations from Pakistan showed that DNA-R is highly conserved followed by DNA-N, whereas DNA-U3 is highly diverse with the most diverse Common Region Stem-loop (CR-SL) in BBTV genome, a functional region, which previously been reported to have undergone recombination in Pakistani population. A Maximum Likelihood (ML) phylogenetic analysis of entire genomes of isolates by using sequence of all the components concatenated together with the reported genomes around the world revealed deeper insights about the origin of the disease in Pakistan. A comparison of the genetic diversity of Pakistani and entire BBTV populations around the world indicates that there exists a correlation between genetic diversity and recombination. Population genetics analysis indicated that the degree of selection pressure differs depending on the area and genomic component. A detailed analysis of recombination across various components and functional regions suggested that recombination is closely associated with the functional parts of BBTV genome showing high genetic diversity. Both genetic diversity and recombination analyses suggest that the CR-SL is a recombination hotspot in all BBTV genomes and among the six components DNA-U3 is the only recombined component that has extensively undergone inter and intragenomic recombination. Diversity analysis of recombinant regions results on average one and half fold increase and, in some cases up to four-fold increase due to recombination. These results suggest that recombination is significantly contributing to the genetic diversity of BBTV populations around the world.