The structure of an abequose - containing O-polysaccharide isolated from Pectobacterium aquaticum IFB5637.

Soft rot and blackleg diseases, caused by pectinolytic bacteria from the numerous species of Dickeya and Pectobacterium, pose a serious threat to the world potato production. Besides, infections triggered by these pectinolytic bacteria lead to huge economic losses in the cultivation of other crops, vegetables, and ornamentals. Strains belonging to the genus Pectobacterium tend to be isolated from various environments such as rotten or asymptomatic plants, weeds, soil or water. The main virulence factors of these phytopathogenic bacteria involve plant cell wall degrading enzymes (PCWDEs) i.e. pectinases, cellulases and proteases. Among accessory virulence factors, there is often lipopolysaccharide (LPS) listed. This constituent of the external part of bacterial cell wall contains lipid A, inner and outer core in addition to O-polysaccharide (OPS). LPS plays an important role in plant-microbe interactions, in particular during the first step of pathogen recognition. In this study we present the chemical structure of OPS of the first Pectobacterium aquaticum strain (IFB5637) isolated from water in Poland. The OPS consists of two common hexoses, such as mannose and glucose, as well as an abequose (3,6-dideoxy-d-xylo-hexose), the first 3,6-dideoxyhexose identified among the Pectobacteriaceae family: According to our best knowledge this is the first determined structure of the OPS of P. aquaticum.

Comparative genomics and pangenome-oriented studies reveal high homogeneity of the agronomically relevant enterobacterial plant pathogen Dickeya solani.

BACKGROUND: Dickeya solani is an important plant pathogenic bacterium causing severe losses in European potato production. This species draws a lot of attention due to its remarkable virulence, great devastating potential and easier spread in contrast to other Dickeya spp. In view of a high need for extensive studies on economically important soft rot Pectobacteriaceae, we performed a comparative genomics analysis on D. solani strains to search for genetic foundations that would explain the differences in the observed virulence levels within the D. solani population. RESULTS: High quality assemblies of 8 de novo sequenced D. solani genomes have been obtained. Whole-sequence comparison, ANIb, ANIm, Tetra and pangenome-oriented analyses performed on these genomes and the sequences of 14 additional strains revealed an exceptionally high level of homogeneity among the studied genetic material of D. solani strains. With the use of 22 genomes, the pangenome of D. solani, comprising 84.7% core, 7.2% accessory and 8.1% unique genes, has been almost completely determined, suggesting the presence of a nearly closed pangenome structure. Attribution of the genes included in the D. solani pangenome fractions to functional COG categories showed that higher percentages of accessory and unique pangenome parts in contrast to the core section are encountered in phage/mobile elements- and transcription- associated groups with the genome of RNS 05.1.2A strain having the most significant impact. Also, the first D. solani large-scale genome-wide phylogeny computed on concatenated core gene alignments is herein reported. CONCLUSIONS: The almost closed status of D. solani pangenome achieved in this work points to the fact that the unique gene pool of this species should no longer expand. Such a feature is characteristic of taxa whose representatives either occupy isolated ecological niches or lack efficient mechanisms for gene exchange and recombination, which seems rational concerning a strictly pathogenic species with clonal population structure. Finally, no obvious correlations between the geographical origin of D. solani strains and their phylogeny were found, which might reflect the specificity of the international seed potato market.