Morphological and phylogenetic analyses of Pythium species in South Africa.

The genus Pythium is important in agriculture, since it contains many plant pathogenic species, as well as species that can promote plant growth and some that have biocontrol potential. In South Africa, very little is known about the diversity of Pythium species within agricultural soil, irrigation and hydroponic systems. Therefore, the aim of the study was to characterise a selection of 85 Pythium isolates collected in South Africa from 1991 through to 2007. The isolates were characterised morphologically as well as through sequence and phylogenetic analyses of the internal transcribed spacer regions (ITS) and the 5.8S gene of the nuclear ribosomal DNA. Phylogenetic analyses showed that the isolates represented ten of the 11 published Pythium clades [Lévesque & De Cock, 2004. Molecular phylogeny and taxonomy of the genus Pythium. Mycological Research 108: 1363-1383]. Characterisation of isolates in clade D and J suggested that the phylogenetic concept of Pythium acanthicum and Pythium perplexum respectively, needs further investigation in order to enable reliable species identification within these clades. Our phylogenetic analyses of Pythium species in clade B also showed that species with globose sporangia group basal within this clade, and are not dispersed within the clade as previously reported. The 85 South African isolates represented 34 known species, of which 20 species have not been reported previously in South Africa. Additionally, three isolates (PPRI 8428, 8300 and 8418) were identified that may each represent putative new species, Pythium sp. WJB-1 to WJB-3.

Natural variation reveals key amino acids in a downy mildew effector that alters recognition specificity by an Arabidopsis resistance gene.

RPP13, a member of the cytoplasmic class of disease resistance genes, encodes one of the most variable Arabidopsis proteins so far identified. This variability is matched in ATR13, the protein from the oomycete downy mildew pathogen Hyaloperonospora parasitica recognized by RPP13, suggesting that these proteins are involved in tight reciprocal coevolution. ATR13 exhibits five domains: an N-terminal signal peptide, an RXLR motif, a heptad leucine/isoleucine repeat, an 11-amino-acid repeated sequence and a C-terminal domain. We show that the conserved RXLR-containing domain is dispensable for ATR13-mediated recognition, consistent with its role in transport into the plant cytoplasm. Sequencing ATR13 from 16 isolates of H. parasitica revealed high levels of amino acid diversity across the entire protein. The leucines/isoleucines of the heptad leucine repeat were conserved, and mutation of particular leucine or isoleucine residues altered recognition by RPP13. Natural variation has not exploited this route to detection avoidance, suggesting a key role of this domain in pathogenicity. The extensive variation in the 11-amino-acid repeat units did not affect RPP13 recognition. Domain swap analysis showed that recognition specificity lay in the C-terminal domain of ATR13. Variation analyses combined with functional assays allowed the identification of four amino acid positions that may play a role in recognition specificity. Site-directed mutagenesis confirmed that a threonine residue is absolutely required for RPP13 recognition and that recognition can be modulated by the presence of either an arginine or glutamic acid at other sites. Mutations in these three amino acids had no effect on the interaction of ATR13 with a resistance gene unlinked to RPP13, consistent with their critical role in determining RPP13-Nd recognition specificity.

Host-parasite coevolutionary conflict between Arabidopsis and downy mildew.

Plants are constantly exposed to attack by an array of diverse pathogens but lack a somatically adaptive immune system. In spite of this, natural plant populations do not often suffer destructive disease epidemics. Elucidating how allelic diversity within plant genes that function to detect pathogens (resistance genes) counteracts changing structures of pathogen genes required for host invasion (pathogenicity effectors) is critical to our understanding of the dynamics of natural plant populations. The RPP13 resistance gene is the most polymorphic gene analyzed to date in the model plant Arabidopsis thaliana. Here we report the cloning of the avirulence gene, ATR13, that triggers RPP13-mediated resistance, and we show that it too exhibits extreme levels of amino acid polymorphism. Evidence of diversifying selection visible in both components suggests that the host and pathogen may be locked in a coevolutionary conflict at these loci, where attempts to evade host resistance by the pathogen are matched by the development of new detection capabilities by the host.