Divergent Host-Microbe Interaction and Pathogenesis Proteins Detected in Recently Identified Species.

() Liberibacter taxa are economically important bacterial plant pathogens that are not culturable; however, genome-enabled insights can help us develop a deeper understanding of their host-microbe interactions and evolution. The draft genome of a recently identified taxa, Liberibacter capsica, was curated and annotated here with a total draft genome size of 1.1 MB with 1,036 proteins, which is comparable to other species with complete genomes. A total of 459 orthologous clusters were identified among L. capsica, L. asiaticus, L. psyllaurous L. americanus, L. africanus, and , and these genes within these clusters consisted of housekeeping and environmental response functions. We estimated the rates of molecular evolution for each of the 443 one-to-one ortholog clusters and found that all L. capsica orthologous pairs were under purifying selection when the synonymous substitutions per synonymous site (dS) were not saturated. These results suggest that these genes are largely maintaining their conserved functions. We also identified the most divergent single-copy orthologous proteins in L. capsica by analyzing the ortholog pairs that represented the highest nonsynonymous substitutions per nonsynonymous site (dN) values for each pairwise comparison. From these analyses, we found that 21 proteins which are known to be involved in pathogenesis and host-microbe interactions, including the Tad pilus complex, were consistently divergent between L. capsica and the majority of other species. These results further our understanding of the evolutionary genetics of . L. capsica and, more broadly, the evolution of . () Liberibacter taxa are economically important plant pathogens vectored by insects; however, these host-dependent bacterial taxa are extremely difficult to study because they are unculturable. Recently, we identified a new . Liberibacter lineage ( Liberibacter capsica) from a rare insect metagenomic sample. In this current study, we report that the draft genome of Liberibacter capsica is similar in genome size and protein content compared to the other Liberibacter taxa. We provide evidence that many of their shared genes, which encode housekeeping and environmental response functions, are evolving under purifying selection, suggesting that these genes are maintaining similar functions. Our study also identifies 21 proteins that are rapidly evolving amino acid changes in Liberibacter capsica compared to the majority of other taxa. Many of these proteins represent key genes involved in -host interactions and pathogenesis and are valuable candidate genes for future studies.