A multigene phylogentic analysis of Potato virus Y and its application in strain identification.

The objective of this study is to develop a rapid and accurate multigene phylogenetic analysis to identify Potato virus Y (PVY) strains. The phylogenetic relationships of strains within the PVY species were evaluated with isolate-strain association using five datasets of concatenated sequences from the P1, HC-pro, VPg and CP genes to determine the best dataset for PVY strain identification. Results from phylogenetic analyses and Bayesian tip-association significance (BaTS) tests indicated that the major PVY strains could be distinguished using the P1, VPg and CP concatenated sequences datasets but not the remaining concatenated sequence datasets. Phylogenetic trees reconstructed from the concatenated sequences of P1, VPg and CP genes revealed that the ML and NJ trees had broadly similar topologies and that both were better than the maximum clade credibility tree (MCC). Additionally, the full genome of HLJ26, one isolate randomly selected for the multigene phylogenetic analysis, was clustered with high confidence among members of the PVYNTN-NW (SYR-Ⅱ) strain, which includes isolates of SYR-Ⅱ-2-8, SYR-Ⅱ-Be1 and SYR-Ⅱ-DrH. This suggests that it was a PVYNTN-NW (SYR-Ⅱ) isolate. Recombination analysis of this isolate identified four putative recombination joints in the P1, HC-pro/P3, VPg and the 5'-terminus of CP. This pattern is similar to that observed in the genomic structure of PVYNTN-NW (SYR-I), supporting the classification of this isolate as the PVYNTN-NW strain (SYR-Ⅱ). Simultaneously, two expected fragments of approximately 1 000 and 400 bp in size were also amplified from the isolate by a multiplex RT-PCR, consistent with the expected band pattern of the PVYNTN-NW (SYR-Ⅱ) strain. This further supports the utility of the multigene phylogenetic method in identifying PVY strains. We propose that the major PVY strains could be distinguished accurately using multigene phylogenetic analysis based on the concatenated sequences from the P1, VPg and CP genes.

[Comparative analysis of population genetic structure of Potato virus Y from different hosts].

Nucleotide sequences of P3 and pipo genes of Potato virus Y (PVY) from potato and tobacco were compared to investigate the effect of hosts on the population genetic structure. Meanwhile, mutation, natural selection and gene flow were evaluated to determine evolutionary forces responsible for the population genetic dynamics. The fixation indices of population differentiation (FST) of PVY from tobacco and potato were 0.116 and 0.120, respectively with significant difference, suggesting a moderate genetic differentiation between the two populations. Genetic variation analysis showed that nucleotide identities in P3 and pipo genes among the viral isolates from tobacco were respectively in the range of 85.2%-100% and 76.5%-100% while that from potato were respectively in the range of 95.7%-100% and 93.0%-100%, indicating higher genetic variation in PVY from tobacco than that from potato. Moreover, purifying selection was detected on the majority of polymorphic sites within P3 gene, suggesting that most of mutations in the gene were harmful and consequently being eliminated by natural selection. Conversely, positive selection was detected on two polymorphic sites, suggesting that these two mutations were beneficial to PVY. Neither purifying nor positive selection was detected in pipo gene, indicating neutral evolution of the gene. The values of gene flow (Nm) between PVY populations from tobacco and potato in P3 and pipo genes were 1.91 and 1.83, respectively, suggesting strong gene flow also contributes significantly to the population genetic dynamics of PVY population. In summary, this study indicates there was a significant genetic variation in PVY hosted by tobacco and potato, and mutation, natural selection and gene flow all contribute to the genetic diversity and population dynamic of the virus.

[Sequence variation and protein structure of pipo gene in Potato virus Y].

The objectives of this study were to understand the sequence variation and the putative protein structure of pipo gene in the Potato virus Y (PVY) collected from Solanum tuberosum. The pipo gene in PVY was cloned using a pair of degenerate primers designed from its conserved region and its sequences were used to re-construct phylogenetic tree in Potyvirus genera by a Bayesian inference method. An expected fragment of 235 bp was amplified in all 20 samples by RT-PCR and the pipo genes in the 20 samples assayed shared more than 92% nucleotide sequence similarity with the published sequences of PVY strains. Among the 20 pipo gene sequences, 13 polymorphic sites were detected, including 4 parsimony informative sites and 9 singleton variable sites. These results indicate that PVY pipo gene is highly conserved but some sequence variations exist. Further analyses suggest that the pipo gene encodes a hydrophilic protein without signal peptide and transmembrane region. The protein has theoretical isoelectric points (pI) ranging from 11.26 to 11.62 and contains three highly conserved regions, especially between aa 10 and 59. The protein is likely located in the mitochondria and has a-helix secondary structure. Bayesian inference of phylogenetic trees reveals that PVY isolates are clustered in the same branch with high posterior probability, while Sunflower chlorotic mottle virus (SoCMoV) and Pepper severe mosaic virus (PepSMV) are closely related, consisting with the classification of Potyvirus genera using other approaches. Our analyses suggest that the pipo gene can be a new marker for phylogenetic analysis of the genera. The results reported in this paper provide useful insights in the genetic variation and the evolution of PVY and can stimulate further research on structure and function of the PIPO protein.

[Population genetics of plant pathogens].

Comparing to natural ecosystems, the evolution of plant pathogens in agricultural ecosystems is generally faster due to high-density monocultures, large-scale application of agrochemicals, and international trade in agricultural products. Knowledge of the population genetics and evolutionary biology of plant pathogens is necessary to understand disease epidemiology, effectively breed and use resistant cultivars, and control plant diseases. In this article, we outlined the aims of population genetic studies in plant pathogens, discuss contributions of five evolutionary forces (i.e., mutation, gene flow, recombination, random genetic drift, and natural selection) to origin, maintenance, and distribution of genetic variation in time and space, and gave an overview of current research status in this field.