Bioinformatics for microbial genotyping of equine encephalitis viruses, orthopoxviruses, and hantaviruses

Abstract

Microbial genotyping is essential for forensic discrimination of pathogen strains, tracing epidemics, and understanding evolutionary processes. Phylogenetic analyses were performed and genotyping assays designed for five viral species complexes or genera: Western, Eastern, and Venezuelan equine encephalitis viruses, hantavirus segments L, M, and S, and orthopoxviruses. For each group, sequence alignments and phylogenetic trees were built. PCR signatures composed of primer pairs or TaqMan™ triplets were designed and mapped to nodes of the trees for sub-type or strain specific PCR-based identification. In addition, single nucleotide polymorphisms (SNPs) were identified and mapped to trees, and SNP microarray probes were designed to enable highly multiplexed genotyping of an unsequenced sample by hybridization. SNP-based trees corresponded well with MSA trees. Near-perfect isolate resolution was possible for all viruses analyzed computationally using either SNPs or PCR signatures. More tree nodes were represented by SNP loci than by PCR signatures, as PCR signatures often represented subsets of strains not corresponding to a branch. However, while PCR genotyping is possible, the number of PCR signatures needed to characterize an unknown can be very large. SNP microarrays are a suitable alternative, as arrays enable highly multiplexed, high resolution genotyping of an unknown in a single hybridization assay.