Project description:The α-proteobacterium Sinorhizobium fredii NGR234 has an exceptionally wide host range as it forms nitrogen-fixing nodules with more legumes than any other known microsymbiont. Within its 6.9 Mbp genome it encodes two N-acyl-homoserine-lactone synthase genes (i.e. traI and ngrI) involved in the biosynthesis of two distinct autoinducer I-type molecules. Here we report on the construction of a NGR234-ΔtraI and a NGR234-ΔngrI mutant and the genome wide RNA-seq-based transcriptome analysis in the parent strain and in the two constructed mutants. A high-resolution RNA-seq analysis of early stationary phase cultures in the background of NGR234-ΔtraI suggested that up to 316 genes (4.9% of all predicted genes) were differentially expressed in the mutant vs. the parent strain. Similarly, in the background of NGR234-ΔngrI 466 differentially regulated genes (7.3% of all predicted genes) were identified. A considerable overlap in the gene expression pattern was uncovered between both mutants resulting in a common set of 186 genes which were almost identically regulated. Co-regulated genes that were linked to the ngrI- and the traI-dependent autoinducer regulatory circuits included 53 flagella biosynthesis genes and genes linked to EPS succinoglycan biosynthesis. Among the genes and ORFs that were differentially regulated in NGR234-ΔtraI were those linked to replication of the pNGR234a symbiotic plasmid and cytochrome c-related genes. In the NGR234-ΔngrI mutant biotin and pyrroloquinoline quinone (PQQ) biosynthesis genes were differentially expressed as well as the entire cluster of 21 genes linked to assembly of the NGR234 type three secretion system II (T3SS-II). We also discovered that genes responsible for octopine catabolism in NGR234 are strongly repressed in the presence of high levels of N-acyl-homoserine-lactones (AHLs). Surprisingly, only few truly symbiosis-related genes were identified that appeared to be quorum sensing regulated. Together with nodulation assays, the RNAseq-based findings suggested that QS-dependent gene regulation appears to be of higher relevance during non-symbiotic growth rather than for life within root nodules.

Project description:The M-NM-1-proteobacterium Sinorhizobium fredii NGR234 has an exceptionally wide host range as it forms nitrogen-fixing nodules with more legumes than any other known microsymbiont. Within its 6.9 Mbp genome it encodes two N-acyl-homoserine-lactone synthase genes (i.e. traI and ngrI) involved in the biosynthesis of two distinct autoinducer I-type molecules. Here we report on the construction of a NGR234-M-NM-^TtraI and a NGR234-M-NM-^TngrI mutant and the genome wide RNA-seq-based transcriptome analysis in the parent strain and in the two constructed mutants. A high-resolution RNA-seq analysis of early stationary phase cultures in the background of NGR234-M-NM-^TtraI suggested that up to 316 genes (4.9% of all predicted genes) were differentially expressed in the mutant vs. the parent strain. Similarly, in the background of NGR234-M-NM-^TngrI 466 differentially regulated genes (7.3% of all predicted genes) were identified. A considerable overlap in the gene expression pattern was uncovered between both mutants resulting in a common set of 186 genes which were almost identically regulated. Co-regulated genes that were linked to the ngrI- and the traI-dependent autoinducer regulatory circuits included 53 flagella biosynthesis genes and genes linked to EPS succinoglycan biosynthesis. Among the genes and ORFs that were differentially regulated in NGR234-M-NM-^TtraI were those linked to replication of the pNGR234a symbiotic plasmid and cytochrome c-related genes. In the NGR234-M-NM-^TngrI mutant biotin and pyrroloquinoline quinone (PQQ) biosynthesis genes were differentially expressed as well as the entire cluster of 21 genes linked to assembly of the NGR234 type three secretion system II (T3SS-II). We also discovered that genes responsible for octopine catabolism in NGR234 are strongly repressed in the presence of high levels of N-acyl-homoserine-lactones (AHLs). Surprisingly, only few truly symbiosis-related genes were identified that appeared to be quorum sensing regulated. Together with nodulation assays, the RNAseq-based findings suggested that QS-dependent gene regulation appears to be of higher relevance during non-symbiotic growth rather than for life within root nodules. In total 12 samples were analyzed (six different treatments with two independent samples), treatment A: NGR234 wild type strain in stationary phase, treatment B: NGR234 traI-mutant strain in stationary phase, treatment C: NGR234 ngrI-mutant strain in stationary phase, treatment D: NGR234 wild type strain in exponential phase, treatment E: NGR234 wild type supplemented with 0.05 M-BM-5M AHLs in exponential phase, treatment F: NGR234 wild type supplemented with 50 M-BM-5M AHLs in exponential phase

Project description:During their lifecycle, from free-living soil bacteria to endosymbiotic nitrogen-fixing bacteroids of legumes, rhizobia must colonize, and cope with environments where nutrient concentrations and compositions vary greatly. Bacterial colonization of legume rhizospheres and of root surfaces is subject to a fierce competition for plant exudates. By contrast root nodules offer to rhizobia sheltered nutrient-rich environments within which the cells that successfully propagated via infection threads can rapidly multiply. To explore the effects on symbiosis of a slower rhizobia growth and metabolism, we deleted one or two copies of the three functional rRNA operons of the promiscuous Sinorhizobium fredii strain NGR234 and examined the impact of these mutations on free-living and symbiotic lifestyles. Strains with two functional rRNA operons (NGRΔrRNA1 and NGRΔrRNA3) grew almost as rapidly as NGR234, and NGRΔrRNA1 was as proficient as the parent strain on all of the five legume species tested. By contrast, the NGRΔrRNA1,3 double mutant, which carried a single rRNA operon and grew significantly slower than NGR234, had a reduced symbiotic proficiency on Cajanus cajan, Macroptilium atropurpureum, Tephrosia vogelii, and Vigna unguiculata. In addition, while NGRΔrRNA1 and NGR234 equally competed for nodulation of V. unguiculata, strain NGRΔrRNA1,3 was clearly outcompeted by wild-type. Surprisingly, on Leucaena leucocephala, NGRΔrRNA1,3 was the most proficient strain and competed equally NGR234 for nodule occupation. Together, these results indicate that for strains with otherwise identical repertoires of symbiotic genes, a faster growth on roots and/or inside plant tissues may contribute to secure access to nodules of some hosts. By contrast, other legumes such as L. leucocephala appear as less selective and capable of providing symbiotic environments susceptible to accommodate strains with a broader spectrum of competences.

Project description:Here we announce the complete genome sequence of the symbiotic and nitrogen-fixing bacterium Sinorhizobium fredii USDA257. The genome shares a high degree of sequence similarity with the closely related broad-host-range strains S. fredii NGR234 and HH103. Most strikingly, the USDA257 genome encodes a wealth of secretory systems.

Project description:Sinorhizobium fredii NGR234 Transcriptome or Gene expression

Project description:RNA-seq in the broad host range strain Sinorhizobium fredii NGR234 identifies a large set of genes linked to quorum sensing-dependent regulation in the background of a traI and ngrI deletion mutant

Project description:The absence of quorum sensing signals triggers the expression of the symbiotic genes in broad host range rhizobia

Project description:Rhizobium sp. NGR234

Project description:Symbiotic nitrogen-fixing bacterium with a broad host-range

Project description:Sinorhizobium fredii NGR234 Transcriptome or Gene expression