Project description:The general stress response (GSR) allows bacteria to monitor and defend against a broad set of unrelated, adverse environmental conditions. In Alphaproteobacteria, the key step in GSR activation is phosphorylation of the response regulator PhyR. In Sphingomonas melonis Fr1, seven PhyR-activating kinases (Paks), PakA to PakG, are thought to directly phosphorylate PhyR under different stress conditions, but the nature of the activating signals remains obscure. PakF, a major sensor of NaCl and heat shock, lacks a putative sensor domain but instead harbors a single receiver (REC) domain (PakFREC) N-terminal to its kinase catalytic core. Such kinases are called "hybrid response regulators" (HRRs). How HRRs are able to perceive signals in the absence of a true sensor domain has remained largely unexplored. In the present work, we show that stresses are actually sensed by another kinase, KipF (kinase of PakF), which phosphorylates PakFREC and thereby activates PakF. KipF is a predicted transmembrane kinase, harboring a periplasmic CHASE3 domain flanked by two transmembrane helices in addition to its cytoplasmic kinase catalytic core. We demonstrate that KipF senses different salts through its CHASE3 domain but is not a sensor of general osmotic stress. While salt sensing depends on the CHASE3 domain, heat shock sensing does not, suggesting that these stresses are perceived by different mechanisms. In summary, our results establish a two-tiered histidine kinase pathway involved in activation of the GSR in S. melonis Fr1 and provide the first experimental evidence for the so far uncharacterized CHASE3 domain as a salt sensor.Hybrid response regulators (HRRs) represent a particular class of histidine kinases harboring an N-terminal receiver (REC) domain instead of a true sensor domain. This suggests that the actual input for HRRs may be phosphorylation of the REC domain. In the present study, we addressed this question by using the HRR PakF. Our results suggest that PakF is activated through phosphorylation of its REC domain and that this is achieved by another kinase, KipF. KipF senses heat shock and salt stress, with the latter requiring the periplasmic CHASE3 domain. This work not only suggests that HRRs work in two-tiered histidine kinase pathways but also provides the first experimental evidence for a role of the so far uncharacterized CHASE3 domain in salt sensing.

Project description:Sphingomonas melonis FR1 Genome sequencing and assembly

Project description:Analysis of the genes transcriptionally regulated in the course of the general stress response in Sphingomonas melonis Fr1

Project description:To further elucidate the responsive patterns of S. melonis TY to hyperosmotic stress at transcriptional level, transcriptome sequencings were carried out on S. melonis TY cultured under three levels of salt stress (0%, 1%, 2%) for 10 or 30 minutes.

Project description:Transcriptome of the wild type (WT) of S. melonis TY and snc137 deleted cells carrying either a plasmid overexpressing SNC137 (Δsnc137 comp.), or an empty control vector (Δsnc137)

Project description:Drought and salinity are most ubiquitous environmental factors that causing hyperosmotic threats to Sphingomonas and impairs their efficiency of performing environmental functions. However, bacteria have developed various responses and regulation systems to coping with these abiotic challenges. Among which post-transcriptional regulation plays vital roles in regulating gene expression and cellular homeostasis, as hyperosmotic stress conditions could lead to induction of specific small RNA (sRNA) that participates in stress response regulation. Here, we report a candidate functional sRNAs landscape of S. melonis which could help for comprehensive analyses of sRNA regulation in Sphingomonas species. WGCNA analysis revealed a 263 nt sRNA SNC251 which transcribed from its own promoter and shew the most dramatic correlation coefficient with hyperosmotic factors was characterized. An in vivo translation-reporter system constructed in this study revealed positive regulation and feedback mechanisms between the SNC251 and nicotine degradation genes. Deletion of snc251 affected multiple cellular processes and nicotine degradation capacity of S. melonis TY, while overexpression of SNC251 facilitated the biofilm formation capability of TY under hyperosmotic stress. Two genes of TonB system were further verified could be activated by SNC251, which also means SNC251 is a trans-acting small RNA. Briefly, this research reported a summary of sRNAs which participate in hyperosmotic stress response in S. melonis TY and revealed a novel sRNA SNC251 which is necessary for hyperosmotic stress response.

Project description:The general stress response in Alphaproteobacteria was recently described to depend on the alternative sigma factor ?(EcfG), whose activity is regulated by its anti-sigma factor NepR. The response regulator PhyR, in turn, regulates NepR activity in a partner-switching mechanism according to which phosphorylation of PhyR triggers sequestration of NepR by the sigma factor-like effector domain of PhyR. Although genes encoding predicted histidine kinases can often be found associated with phyR, little is known about their role in modulation of PhyR phosphorylation status. We demonstrate here that the PhyR-NepR-?(EcfG) cascade is important for multiple stress resistance and competitiveness in the phyllosphere in a naturally abundant plant epiphyte, Sphingomonas sp. strain Fr1, and provide evidence that the partner switching mechanism is conserved. We furthermore identify a gene, designated phyP, encoding a predicted histidine kinase at the phyR locus as essential. Genetic epistasis experiments suggest that PhyP acts upstream of PhyR, keeping PhyR in an unphosphorylated, inactive state in nonstress conditions, strictly depending on the predicted phosphorylatable site of PhyP, His-341. In vitro experiments show that Escherichia coli inner membrane fractions containing PhyP disrupt the PhyR-P/NepR complex. Together with the fact that PhyP lacks an obvious ATPase domain, these results are in agreement with PhyP functioning as a phosphatase of PhyR, rather than a kinase.

Project description:Nicotine is a type of environmental pollutant present in the tobacco waste that is generated during tobacco manufacturing. Sphingomonas melonis TY can utilize nicotine as a sole source of carbon, nitrogen and energy via a variant of the pyridine and pyrrolidine pathway (the VPP pathway). In this study, we report the identification of two novel sets of genes, ndrA1A2A3, and ndrB1B2B3B4, which are crucial for nicotine degradation by strain TY. ndrA1A2A3 and ndrB1B2B3B4 exhibit similarity with both nicotine dehydrogenase ndh from Arthrobacter nicotinovorans and nicotine hydroxylase vppA from Ochrobactrum sp. SJY1. The transcriptional levels of ndrA1A2A3 and ndrB1B2B3B4 in strain TY were significantly upregulated in the presence of nicotine. Furthermore, ndrA1 or ndrB2 knockout resulted in a loss of the ability to degrade nicotine, whereas gene complementation restored the capacity of each mutant to utilize nicotine for growth. Biodegradation assays indicated that the mutant strains retained the ability to degrade the first intermediate in the pathway, 6-hydroxynicotine (6 HN). However, heterologous expression of ndrA1A2A3 and ndrB1B2B3B4 did not confer nicotine dehydrogenase activity to E. coli DH5?, Pseudomonas putida KT2440 or Sphingomonas aquatilis. These results provide information on the VPP pathway of nicotine degradation in S. melonis TY, and we conclude that these two sets of genes have essential functions in the conversion of nicotine to 6 HN in strain TY.

Project description:Sphingomonas melonis overview

Project description:Proteome of the wild type (WT) of S. melonis TY and snc137 deleted cells carrying either a plasmid overexpressing SNC137 (Δsnc137 comp.), or an empty control vector (Δsnc137)