Furthermore, three additional T3SEs that are present in phylogroup 2 Pav are inferred to have been lost completely in Pav BP631 since it’s divergence from Pmp and Pan. This striking pattern suggests that phylogroup 1 Pav BP631 was under strong selective pressure to lose T3SEs deployed by the other Pav lineage. The only putatively functional selleck chemicals T3SEs that are
common among the three Pav strains are HopAA1 and HopAZ1. HopAA1 is encoded in the CEL and descended from the common ancestor of P. syringae. It has been shown to play a role in the suppression of innate immunity in Arabidopsis [35]. Pav BP631 also carries a paralogous copy (in-paralog) of hopAA1 in addition to the one in the CEL. This paralogous hopAA1 allele is also learn more present in the two strong Arabidopsis pathogens Pto DC3000 and Pma ES4326. One of the most interesting findings is that hopAZ1 was independently acquired in all three Pav strains, which points to HopAZ1 as a promising candidate for modulating hazelnut host specificity. Unfortunately, this T3SE has not been functionally characterized and has no conserved domains. HopAZ1 alleles are present in twelve of the 29 P. syringae strains with SAHA HDAC mw sequenced genomes and dispersed among four of five phylogroups. A genealogical analysis of the hopAZ1 family shows strong discordance
from the evolutionary history of the core genome, indicating frequent horizontal transmission of this T3SE family (Additional file 3: Figure S3). Conclusions Our comparative genomic analysis of three Pav
isolates has further confirmed convergent evolution of two independent lineages onto hazelnut, and that this convergence is not due to genetic exchange between lineages. Furthermore, the divergence in T3SE complements suggests that the molecular mechanisms of defense evasion are distinct in each lineage. There has been particularly extensive remodeling of its T3SE repertoire in the more recently emerged lineage possibly in response to recognition by host factors that have coevolved with the T3SEs deployed by the other lineage. However, both lineages have been diversifying as hazelnut pathogens since long before the initial hazelnut decline outbreak this website was first documented in 1976. This suggests that changes in agricultural practice such as the propagation of new cultivars in Greece in the 1960s and 70s and the expansion of hazelnut cultivation into marginal habitats in Italy may have provided suitable conditions for the epidemic emergence of previously cryptic pathogens. While this scenario is clearly conjecture, we now have a number of strong candidate loci to pursue. Functional characterization of these loci in the future may reveal the key steps that these two distinct lineages took in order to subvert the hazelnut immune system. Methods Sequencing and genome assembly followed the methods described in [36].