Sinorhizobium meliloti CtrA Stability Is Regulated in a CbrA-Dependent Manner That Is Influenced by CpdR1

Schallies, Karla B.; Sadowski, Craig Shaw; Meng, Julia; Gibson, Katherine E.

doi:10.1128/jb.02593-14

Cited by 16 publications

(12 citation statements)

References 57 publications

(126 reference statements)

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“…As PopA is responsive to the second messenger cyclic di-GMP, levels of which oscillate during the cell cycle (Abel et al, 2013; Lori et al, 2015), our work suggests that CpdR and RcdA may represent an ancestral adaptor complex that has been co-opted by Caulobacter for coupling second messenger cues to cell cycle progression. In S. meliloti , it is clear that adaptors play a crucial role in the symbiosis transition, where misregulation of CpdR dramatically affects proper nodule formation and plant growth (Kobayashi et al, 2009; Pini et al, 2015; Schallies et al, 2015). In general, bacterial development (such as the morphological transition of Caulobacter or sporulation of Bacillus ) requires changes in proteome composition within a single generation.…”

Section: Discussionmentioning

confidence: 99%

An Adaptor Hierarchy Regulates Proteolysis during a Bacterial Cell Cycle

Joshi

Bergé

Radhakrishnan

et al. 2015

Cell

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150

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Summary Regulated protein degradation is essential. The timed destruction of crucial proteins by the ClpXP protease drives cell-cycle progression in the bacterium Caulobacter crescentus. Although ClpXP is active alone, additional factors are inexplicably required for cell-cycle dependent proteolysis. Here, we show that these factors constitute an adaptor hierarchy where different substrates are destroyed based on the degree of adaptor assembly. The hierarchy builds upon priming of ClpXP by the adaptor CpdR, which promotes degradation of one class of substrates and also recruits the adaptor RcdA to degrade a second class of substrates. Adding the PopA adaptor promotes destruction of a third class of substrates, while inhibiting degradation of the second class. We dissect RcdA to generate bespoke adaptors, identifying critical substrate elements needed for RcdA recognition and uncovering additional cell-cycle dependent ClpXP substrates. Our work reveals how hierarchical adaptors and primed proteases orchestrate regulated proteolysis during bacterial cell-cycle progression.

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Section: Discussionmentioning

confidence: 99%

An Adaptor Hierarchy Regulates Proteolysis during a Bacterial Cell Cycle

Joshi

Bergé

Radhakrishnan

et al. 2015

Cell

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150

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“…For example, in the plant symbiont Sinorhizobium meliloti , there are two orthologs of CpdR, but only one (CpdR1) exhibits physiological defects when either deleted or overactivated (73). CpdR1 appears to play a role in controlling CtrA stability, which is particularly important in the endoreduplication process during symbiosis (98; 110). Less is know about the role of RcdA in S. meliloti, but depletion of RcdA increases CtrA levels (98) supporting its role in controlling CtrA stability similar to that seen in Caulobacter .…”

Section: Cell Cycle Progressionmentioning

confidence: 99%

Regulated Proteolysis in Bacteria:Caulobacter

Joshi¹,

Chien

2016

Annu. Rev. Genet.

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Protein degradation is essential for all living things. Bacteria use energy-dependent proteases to control protein destruction in a highly specific manner. Recognition of substrates is determined by the inherent specificity of the proteases and through adaptor proteins that alter the spectrum of substrates. In the α-proteobacterium Caulobacter crescentus, regulated protein degradation is required for stress responses, developmental transitions, and cell cycle progression. In this review, we describe recent progress in our understanding of the regulated and stress responsive protein degradation pathways in Caulobacter. We discuss how organization of highly specific adaptors into functional hierarchies drives destruction of proteins during the bacterial cell cycle. Because all cells must balance the need for degradation of many true substrates with the toxic consequences of nonspecific protein destruction, principles found in one system will likely generalize to others.

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“…Due to the conservation of the CtrA regulatory system in αproteobacteria, some homologous genes encoding components of this system that function in cell cycle regulation, such as ctrA, ccrM, cpdR1, divJ, divK, gcrA, and pleC, have been identified in Sinorhizobium meliloti (the symbiont of Medicago species) (12)(13)(14). Additionally, a few specific genes, such as cbrA, are essential for cell cycle regulation through interplay with the CtrA system (15,16).…”

mentioning

confidence: 99%

“…Since S. meliloti and C. crescentus belong to -proteobacteria, based on the research results of C. crescentus, with the aid of DNA sequence homology analysis, many cell cycle regulatory genes such as ctrA, ccrM, cpdR1, divJ, divK, gcrA and pleC, have been identified in S. meliloti (12)(13)(14). In addition, the hybrid histidine kinase CbrA is linked to the CtrA regulatory system, which is an important regulator of cell division in S. meliloti (15,16). However, it is still unclear whether these regulatory proteins conduct environmental nutrition signals (e.g., ammonia nitrogen) and whether they play a regulatory role in the symbiotic process.…”

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confidence: 99%

Direct regulation of cell cycle regulatory gene expression by NtrX to promoteSinorhizobium meliloticell division

Xing

Huang

et al. 2020

Preprint

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In α-proteobacteria, the CtrA signaling pathway regulates cell cycle progression. A species whose cell duplication is associated with CtrA stability is affected by the response regulator NtrX. However, the function of NtrX acting on the cell cycle regulation in bacteria remains unclear. Here, we report that NtrX controls transcription of the CtrA system genes involved in cell cycle regulation in a legume symbiont, Sinorhizobium meliloti. Three groups of ntrX mutants showed the similar cell cycle defects, such as slow growth, abnormal shapes, and irregular genomic DNA accumulation. Expression of the CtrA signaling pathway genes including ctrA, gcrA, dnaA, divL and cpdR1, is differentially regulated by the phosphorylated NtrX protein. The regulation is achieved through direct protein-DNA interactions. The 53rd aspartate residue known as the conserved phosporylation site and located in the receiver domain of NtrX, is required for S. meliloti cell cycle regulation. Interestingly, expression of S. meliloti ntrX derivatives in Caulobacter and Agrobacterium strains showed distinct defects of cell duplication and growth, suggesting that NtrX plays different roles in cell cycle regulation in these bacteria. Our findings demonstrate that NtrX is an upstream transcriptional regulator of the CtrA signaling pathway in S. meliloti, which could be associated with nitrogen nutrient response.

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Sinorhizobium meliloti CtrA Stability Is Regulated in a CbrA-Dependent Manner That Is Influenced by CpdR1

Cited by 16 publications

References 57 publications

An Adaptor Hierarchy Regulates Proteolysis during a Bacterial Cell Cycle

An Adaptor Hierarchy Regulates Proteolysis during a Bacterial Cell Cycle

Regulated Proteolysis in Bacteria:Caulobacter

Direct regulation of cell cycle regulatory gene expression by NtrX to promoteSinorhizobium meliloticell division

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