Abstract
BackgroundTwo-component systems (TCS) play critical roles in sensing and responding to environmental cues. Azospirillum is a plant growth-promoting rhizobacterium living in the rhizosphere of many important crops. Despite numerous studies about its plant beneficial properties, little is known about how the bacterium senses and responds to its rhizospheric environment. The availability of complete genome sequenced from four Azospirillum strains (A. brasilense Sp245 and CBG 497, A. lipoferum 4B and Azospirillum sp. B510) offers the opportunity to conduct a comprehensive comparative analysis of the TCS gene family.ResultsAzospirillum genomes harbour a very large number of genes encoding TCS, and are especially enriched in hybrid histidine kinases (HyHK) genes compared to other plant-associated bacteria of similar genome sizes. We gained further insight into HyHK structure and architecture, revealing an intriguing complexity of these systems. An unusual proportion of TCS genes were orphaned or in complex clusters, and a high proportion of predicted soluble HKs compared to other plant-associated bacteria are reported. Phylogenetic analyses of the transmitter and receiver domains of A. lipoferum 4B HyHK indicate that expansion of this family mainly arose through horizontal gene transfer but also through gene duplications all along the diversification of the Azospirillum genus. By performing a genome-wide comparison of TCS, we unraveled important ‘genus-defining’ and ‘plant-specifying’ TCS.ConclusionsThis study shed light on Azospirillum TCS which may confer important regulatory flexibility. Collectively, these findings highlight that Azospirillum genomes have broad potential for adaptation to fluctuating environments.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-015-1962-x) contains supplementary material, which is available to authorized users.
Highlights
Two-component systems (TCS) play critical roles in sensing and responding to environmental cues
B510, a strain isolated from disinfected rice stems in Japan [27], (ii) A. lipoferum 4B isolated from rice in France, (iii) A. brasilense Sp245 isolated from wheat in Brazil [14], and (iv) A. brasilense CBG497, isolated from maize grown on an alkaline soil in Mexico [15]
A. lipoferum 4B possesses a total of 244 putative TCS genes out of 6,233 ORFs, comprising 118 genes encoding histidine kinase (HK) (69 classic HKs and 49 hybrid HKs (HyHK)) and 121 RRs
Summary
Two-component systems (TCS) play critical roles in sensing and responding to environmental cues. Plants live in intimate association with complex communities of microorganisms that fulfill important functions relative to plant growth and health [1] These microorganisms can establish beneficial, neutral or detrimental associations of varying intimacy with their hosts. Two component systems (TCS) are one of the primary means used by bacteria to sense and adjust their behaviour They play important roles in a broad range of adaptive mechanisms such as virulence, chemotaxis, metabolism, motility, etc. The TCS signalling pathway relies on a phosphotransfer reaction between two proteins, a generally membrane-bound histidine kinase (HK), characterized by the presence of a HisKA (PF00512) and a HATPase domain (PF02518), and Borland et al BMC Genomics (2015) 16:833 a response regulator (RR) containing a REC domain (PF00072). More complex versions of TCS exist, called hybrid HKs (HyHK), with HK fused to REC, allowing multiple intramolecular phosphotransfer reactions or phosphorelays [4]
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