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NusA and NusG are transcription factors that stimulate RNA polymerase pausing in Bacillus subtilis . While NusA was known to function as an intrinsic termination factor in B. subtilis , the role of NusG in this process was unknown. To examine the individual and combinatorial roles that NusA and NusG play in intrinsic termination, Term-seq was conducted in wild type, NusA depletion, Δ nusG , and NusA depletion Δ nusG strains. We determined that NusG functions as an intrinsic termination factor that works alone and cooperatively with NusA to facilitate termination at 88% of the 1400 identified intrinsic terminators. Our results indicate that NusG stimulates a sequence-specific pause that assists in the completion of suboptimal terminator hairpins with weak terminal A-U and G-U base pairs at the bottom of the stem. Loss of NusA and NusG leads to global misregulation of gene expression and loss of NusG results in flagella and swimming motility defects.

CsrA (carbon storage regulator A) is a widely distributed bacterial RNA binding protein that regulates translation initiation and mRNA stability of target transcripts. In γ-proteobacteria, CsrA activity is competitively antagonized by one or more small RNAs (sRNAs) containing multiple CsrA binding sites, but CsrA in bacteria outside the γ-proteobacteria is antagonized by a protein called FliW. Here we show that FliW of Bacillus subtilis does not bind to the same residues of CsrA required for RNA binding. Instead, CsrA mutants resistant to FliW antagonism (crw) altered residues of CsrA on an allosteric surface of previously unattributed function. Some crw mutants abolished CsrA–FliW binding, but others did not, suggesting that FliW and RNA interaction is not mutually exclusive. We conclude that FliW inhibits CsrA by a noncompetitive mechanism that differs dramatically from the well-established sRNA inhibitors. FliW is highly conserved with CsrA in bacteria, appears to be the ancestral form of CsrA regulation, and represents a widespread noncompetitive mechanism of CsrA control.

The commitment of differentiating cells to a specialized fate is fundamental to the correct assembly of tissues within a multicellular organism. Because commitment is often irreversible, entry into and progression through this phase of development must be tightly regulated. Under nitrogen-limiting conditions, the multicellular cyanobacterium Anabaena sp. strain PCC 7120 terminally commits ∼10% of its cells to become specialized nitrogen-fixing heterocysts. Although commitment is known to occur 9–14 h after the induction of differentiation, the factors that regulate the initiation and duration of this phase have yet to be elucidated. Here, we report the identification of four genes that share a functional domain and modulate heterocyst commitment: hetP (alr2818), asl1930, alr2902, and alr3234. Epistatic relationships between all four genes relating to commitment were revealed by deleting them individually and in combination; asl1930 and alr3234 acted most upstream to delay commitment, alr2902 acted next in the pathway to inhibit development, and hetP acted most downstream to drive commitment forward. Possible protein–protein interactions between HetP, its homologs, and the heterocyst master regulator, HetR, were assessed, and interaction partners were defined. Finally, patterns of gene expression for each homolog, as determined by promoter fusions to gfp and reverse transcription–quantitative PCR, were distinct from that of hetP in both spatiotemporal organization and regulation. We posit that a dynamic succession of protein–protein interactions modulates the timing and efficiency of the commitment phase of development and note that this work highlights the utility of a multicellular cyanobacterium as a model for the study of developmental processes.

Following the success of the inaugural games, the Microbial Olympics return with a new series of events and microbial competitors. The games may have moved to a new hosting venue, but the dedication to training, fitness, competition (and yes, education and humour) lives on.

NusA and NusG are transcription elongation factors that stimulate RNA polymerase pausing in Bacillus subtilis. While NusA was known to function as an intrinsic termination factor, the role of NusG in this process had not been explored. To examine the individual and combinatorial roles that NusA and NusG play in intrinsic termination, Term-seq was conducted in wild type, NusA depletion, ΔnusG, and NusA depletion ΔnusG strains. We determined that NusG functions as an intrinsic termination factor that works alone and cooperatively with NusA to facilitate termination at 88% of the 1,400 identified intrinsic terminators. The loss of both proteins leads to global misregulation of gene expression. Our results indicate that NusG stimulates a sequence-specific pause that assists in the completion of suboptimal terminator hairpins with weak terminal A-U and G-U base pairs at the bottom of the stem. Moreover, the loss of NusG results in flagella and swimming motility defects. Competing Interest Statement The authors have declared no competing interest. Footnotes * https://www.ncbi.nlm.nih.gov/geo/ * https://github.com/zfmandell/Term-seq

Bacteria and phages are locked in a co-evolutionary arms race where each entity evolves mechanisms to restrict the proliferation of the other. Phage-encoded defense inhibitors have proven powerful tools to interrogate how defense systems function. A relatively common defense system is BREX (Bacteriophage exclusion); however, how BREX functions to restrict phage infection remains poorly understood. A BREX system encoded by the SXT integrative and conjugative element, Ind5, was recently identified in , the causative agent of the diarrheal disease cholera. The lytic phage ICP1 that co-circulates with encodes the BREX inhibitor OrbA, but how OrbA inhibits BREX is unclear. Here, we determine that OrbA inhibits BREX using a unique mechanism from known BREX inhibitors by directly binding to the BREX component BrxC. BrxC has a functional ATPase domain that, when mutated, not only disrupts BrxC function but also alters how BrxC multimerizes. Furthermore, we find that OrbA binding disrupts BrxC-BrxC interactions. We determine that OrbA cannot bind BrxC encoded by the distantly related BREX system encoded by the SXT Ban9, and thus fails to inhibit this BREX system that also circulates in epidemic . Lastly, we find that homologs of the Ind5 BrxC are more diverse than the homologs of the Ban9 BrxC. These data provide new insight into the function of the BrxC ATPase and highlight how phage-encoded inhibitors can disrupt phage defense systems using different mechanisms. With renewed interest in phage therapy to combat antibiotic-resistant pathogens, understanding the mechanisms bacteria use to defend themselves against phages and the counter-strategies phages evolve to inhibit defenses is paramount. Bacteriophage exclusion (BREX) is a common defense system with few known inhibitors. Here, we probe how the vibriophage-encoded inhibitor OrbA inhibits the BREX system of , the causative agent of the diarrheal disease cholera. By interrogating OrbA function, we have begun to understand the importance and function of a BREX component. Our results demonstrate the importance of identifying inhibitors against defense systems, as they are powerful tools for dissecting defense activity and can inform strategies to increase the efficacy of some phage therapies.

Bacterial immune systems employ diverse mechanisms to restrict phage infection, yet the regulation of defense expression in response to different infection outcomes remains poorly understood. Here, we find that restricted phage infection potentiates immunity by inducing an increase in immune protein abundance, establishing a heightened state of immunity that is critical for overcoming phage-encoded counterdefenses. This dynamic regulation is dependent on a conserved WYL domain repressor, suggesting this is a widespread strategy in bacterial immunity. In contrast, productive phage infection triggers the horizontal transfer of the mobile element carrying the immune system, ensuring its persistence within the bacterial population. Finally, we demonstrate that harnessing this regulatory logic provides a powerful genetic tool for identifying phages that encode counterdefenses. Together, our work reveals that the fate of an infection dictates divergent outcomes for the expression and dissemination of bacterial immunity.

The RNA-binding protein CsrA is a post-transcriptional regulator that is encoded in genomes throughout the bacterial phylogeny. In the gamma-proteobacteria, the activity of CsrA is inhibited by small RNAs that competitively sequester CsrA binding. In contrast, the firmicute Bacillus subtilis encodes a protein inhibitor of CsrA called FliW, that non-competitively inhibits CsrA activity but the precise mechanism of antagonism is unclear. Here we take an unbiased genetic approach to identify residues of FliW important for CsrA inhibition that fall into two distinct spatial and functional classes. Most loss-of-function alleles mutated FliW residues that surround the critical regulatory CsrA residue N55 and abolished CsrA interaction. Two loss-of-function alleles however mutated FliW residues near the CsrA core dimerization domain and maintained interaction with CsrA. One of these two alleles reversed charge at what appeared to be a salt bridge with the CsrA core region, charge reversal of the CsrA partner residue phenocopied the FliW allele, and charge reversal of both residues simultaneously restored antagonism. We propose a model in which initial interaction between FliW and CsrA is necessary but not sufficient for antagonism which also requires salt bridge formation with, and deformation of, the CsrA core domain to allosterically abolish RNA binding activity. CsrA is a small dimeric protein that binds RNA and is one of the few known examples of transcript-specific translational regulators in bacteria. A protein called FliW binds to and antagonizes CsrA; despite having a high-resolution three-dimensional structure of the FliW-CsrA complex, the mechanism of non-competitive inhibition remains unresolved. Here we identify FliW residues required for antagonism and we find that the residues make a linear connection in the complex from initial binding interaction with CsrA to a critical salt bridge near the core of the CsrA dimer. We propose that the salt bridge represents an allosteric contact that distorts the CsrA core to prevent RNA binding.

During growth, bacteria increase in size and divide. Division is initiated by the formation of the Z-ring, an intense ring-like cytoskeletal structure formed by treadmilling protofilaments of the tubulin homolog FtsZ. FtsZ localization is thought to be controlled by the Min and Noc systems, and here, we explore why cell division fails at high temperature when the Min and Noc systems are simultaneously mutated. Microfluidic analysis of a minD noc double mutant indicated that FtsZ formed proto-Z-rings at periodic inter-chromosome locations but that the rings failed to mature and become functional. Extragenic suppressor analysis indicated that a variety of mutations restored high temperature growth to the minD noc double mutant, and while many were likely pleiotropic, others implicated the proteolysis of the transcription factor Spx. Further analysis indicated that a Spx-dependent pathway activated the expression of ZapA, a protein that primarily compensates for the absence of Noc. Additionally, an Spx-independent pathway increased the activity of the divisome to reduce the length of the cytokinetic period. Finally, we provide evidence of an as-yet-unidentified protein that is activated by Spx and governs the frequency of polar division and minicell formation. Bacteria must properly position the location of the cell division machinery in order to grow, divide, and ensure each daughter cell receives one copy of the chromosome. In B. subtilis, cell division site selection is thought to depend on two systems called Min and Noc, and while neither is individually essential, cells fail to grow at high temperature when both are mutated. Here, we show that cell division fails in the absence of Min and Noc, not due to a defect in FtsZ localization, but rather a failure in the maturation of the cell division machinery. To understand what happens when the division machinery fails to mature, suppressor mutations that bypass the need for Min, Noc, or both were selected. Some of the mutants activated the Spx stress response pathway while others appeared to directly enhance divisome activity.

The motile bacterium Bacillus subtilis depends on long helical structures known as the flagellar filament to propel themselves through different environments. A single B. subtilis can have up to 15 filaments, and each filament is made up of ~12,000 copies of a single protein known as flagellin. Flagellin is thought to be one of the most expensive proteins the cell has to synthesize due its sheer number. Thus, flagellin synthesis is highly regulated. Here we characterize how interactions between Flagellin and two other proteins (FliW and CsrA) govern flagellin synthesis. We show that these interactions restrict flagellin levels inside the cell and that loss of flagellin regulation leads to molecular crowding inside the cell. We further tease apart the mechanism for flagellin regulation using a combination of genetics and biochemistry. Together, these results further our understanding on how structural proteins synthesis is regulated. Moreover, this mechanism could be applied to other bacterial machines.