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1. Mfd Affects Global Transcription and the Physiology of Stressed Bacillus subtilis Cells

   https://doi.org/10.3389/fmicb.2021.625705  

   Martin, Holly Anne; Sundararajan, Anitha; Ermi, Tatiana S.; Heron, Robert; Gonzales, Jason; Lee, Kaiden; Anguiano-Mendez, Diana; Schilkey, Faye; Pedraza-Reyes, Mario; Robleto, Eduardo A. (January 2021, Frontiers in Microbiology)

   null (Ed.)

   For several decades, Mfd has been studied as the bacterial transcription-coupled repair factor. However, recent observations indicate that this factor influences cell functions beyond DNA repair. Our lab recently described a role for Mfd in disulfide stress that was independent of its function in nucleotide excision repair and base excision repair. Because reports showed that Mfd influenced transcription of single genes, we investigated the global differences in transcription in wild-type and mfd mutant growth-limited cells in the presence and absence of diamide. Surprisingly, we found 1,997 genes differentially expressed in Mfd – cells in the absence of diamide. Using gene knockouts, we investigated the effect of genetic interactions between Mfd and the genes in its regulon on the response to disulfide stress. Interestingly, we found that Mfd interactions were complex and identified additive, epistatic, and suppressor effects in the response to disulfide stress. Pathway enrichment analysis of our RNASeq assay indicated that major biological functions, including translation, endospore formation, pyrimidine metabolism, and motility, were affected by the loss of Mfd. Further, our RNASeq findings correlated with phenotypic changes in growth in minimal media, motility, and sensitivity to antibiotics that target the cell envelope, transcription, and DNA replication. Our results suggest that Mfd has profound effects on the modulation of the transcriptome and on bacterial physiology, particularly in cells experiencing nutritional and oxidative stress. 

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2. Regulation of late‐acting operons by three transcription factors and a CRISPR‐Cas component during Myxococcus xanthus development

   https://doi.org/10.1111/mmi.15252  

   Saha, Shreya; Kroos, Lee (March 2024, Molecular Microbiology)

   Abstract Upon starvation, rod‐shapedMyxococcus xanthusbacteria form mounds and then differentiate into round, stress‐resistant spores. Little is known about the regulation of late‐acting operons important for spore formation. C‐signaling has been proposed to activate FruA, which binds DNA cooperatively with MrpC to stimulate transcription of developmental genes. We report that this model can explain regulation of thefadIJoperon involved in spore metabolism, but not that of the spore coat biogenesis operonsexoA‐I,exoL‐P, andnfsA‐H. Rather, a mutation infruAincreased the transcript levels from these operons early in development, suggesting negative regulation by FruA, and a mutation inmrpCaffected transcript levels from each operon differently. FruA bound to all four promoter regions in vitro, but strikingly each promoter region was unique in terms of whether or not MrpC and/or the DNA‐binding domain of Nla6 bound, and in terms of cooperative binding. Furthermore, the DevI component of a CRISPR‐Cas system is a negative regulator of all four operons, based on transcript measurements. Our results demonstrate complex regulation of sporulation genes by three transcription factors and a CRISPR‐Cas component, which we propose produces spores suited to withstand starvation and environmental insults. 

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3. Fatty Acid Synthesis Knockdown Promotes Biofilm Wrinkling and Inhibits Sporulation in Bacillus subtilis

   https://doi.org/10.1128/mbio.01388-22  

   Arjes, Heidi A.; Gui, Haiwen; Porter, Rachel; Atolia, Esha; Peters, Jason M.; Gross, Carol; Kearns, Daniel B.; Huang, Kerwyn Casey (September 2022, mBio)

   Parsek, Matthew (Ed.)

   ABSTRACT Many bacterial species typically live in complex three-dimensional biofilms, yet much remains unknown about differences in essential processes between nonbiofilm and biofilm lifestyles. Here, we created a CRISPR interference (CRISPRi) library of knockdown strains covering all known essential genes in the biofilm-forming Bacillus subtilis strain NCIB 3610 and investigated growth, biofilm colony wrinkling, and sporulation phenotypes of the knockdown library. First, we showed that gene essentiality is largely conserved between liquid and surface growth and between two media. Second, we quantified biofilm colony wrinkling using a custom image analysis algorithm and found that fatty acid synthesis and DNA gyrase knockdown strains exhibited increased wrinkling independent of biofilm matrix gene expression. Third, we designed a high-throughput screen to quantify sporulation efficiency after essential gene knockdown; we found that partial knockdowns of essential genes remained competent for sporulation in a sporulation-inducing medium, but knockdown of essential genes involved in fatty acid synthesis exhibited reduced sporulation efficiency in LB, a medium with generally lower levels of sporulation. We conclude that a subset of essential genes are particularly important for biofilm structure and sporulation/germination and suggest a previously unappreciated and multifaceted role for fatty acid synthesis in bacterial lifestyles and developmental processes. IMPORTANCE For many bacteria, life typically involves growth in dense, three-dimensional communities called biofilms that contain cells with differentiated roles held together by extracellular matrix. To examine how essential gene function varies between vegetative growth and the developmental states of biofilm formation and sporulation, we created and screened a comprehensive library of strains using CRISPRi to knockdown expression of each essential gene in the biofilm-capable Bacillus subtilis strain 3610. High-throughput assays and computational algorithms identified a subset of essential genes involved in biofilm wrinkling and sporulation and indicated that fatty acid synthesis plays important and multifaceted roles in bacterial development. 

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4. RNAi Strategies Against Downy Mildews: Insights Into dsRNA Uptake and Silencing

   https://doi.org/10.1111/mpp.70140  

   Göl, Deniz; Okechukwu, Emeka; Ünal, Gizem; Webb, Anne; Wood, Tom; Hong, Yiguo; Sherif, Sherif_M; Wacker, Theresa; Studholme, David_J; McDowell, John_M; et al (August 2025, Molecular Plant Pathology)

   ABSTRACT Downy mildew (DM) diseases are caused by destructive obligate pathogens with limited control options, posing a significant threat to global agriculture. RNA interference (RNAi) has emerged as a promising, environmentally sustainable strategy for disease management. We evaluated the efficacy of dsRNA‐mediated RNAi in suppressing key biological functions in DM pathogens ofArabidopsis thaliana, pea and lettuce:Hyaloperonospora arabidopsidis(Hpa),Peronospora viciaef. sp.pisi(Pvp) andBremia lactucae(Bl), respectively. Conserved genes,cellulose synthase 3(CesA3) andbeta‐tubulin(BTUB), were targeted. Silencing these genes significantly impaired spore germination and infection across species and reduced gene expression correlated with suppressed sporulation, confirming silencing efficacy. We tested dsRNAs from chemical synthesis, in vitro transcription, andEscherichia coliexpression. Uptake and silencing efficiency varied with dsRNA length and concentration. InHpa, short dsRNAs (21–25 bp) produced a variable spore germination rate, with 25 bp dsRNA causing a 247.10% increase, whereas longer dsRNAs (≥ 30 bp) completely inhibited germination. Similarly, inPvp, dsRNAs of 21–25 bp resulted in a 73.05%–77.46% germination rate, while 30–75 bp dsRNAs abolished germination. Confocal microscopy using Cy‐5‐labelled short‐synthesised dsRNA (SS‐dsRNA) confirmed uptake by spores. Sequence specificity influenced efficacy, highlighting the need for precise target design. Multiplexed RNAi impacted silencing synergistically, further reducing germination and sporulation inHpa. Importantly, SS‐dsRNA‐mediated silencing was durable, with reduced gene expression sustained at 4, 7, 10 and 11 days post‐inoculation. Taken together, our findings demonstrate the potential of dsRNA‐mediated gene silencing as a precise, sustainable tool for managing DM pathogens in multiple crop species. 

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5. Biophysical modeling reveals the transcriptional regulatory mechanism of Spo0A, the master regulator in starving Bacillus subtilis

   https://doi.org/10.1128/msystems.00072-25  

   Zhang, Yujia; Palma, Cristina_S D; Chen, Zhuo; Zarazúa-Osorio, Brenda; Fujita, Masaya; Igoshin, Oleg A; Eichenberger, Patrick (May 2025, mSystems)

   Svensson, Sarah L (Ed.)

   ABSTRACT In starvingBacillus subtilisbacteria,the initiation of two survival programs—biofilm formation and sporulation—is controlled by the same phosphorylated master regulator, Spo0A~P. Its gene,spo0A,is transcribed from two promoters, Pvand Ps,that are, respectively, regulated by RNA polymerase (RNAP) holoenzymes bearing σ^Aand σ^H. Notably, transcription is directly autoregulated by Spo0A~P binding sites known as 0A1, 0A2, and 0A3 box, located in between the two promoters. It remains unclear whether, at the onset of starvation, these boxes activate or repressspo0Aexpression, and whether the Spo0A~P transcriptional feedback plays a role in the increase inspo0Aexpression. Based on the experimental data of the promoter activities under systematic perturbation of the promoter architecture, we developed a biophysical model of transcriptional regulation ofspo0Aby Spo0A~P binding to each of the 0A boxes. The model predicts that Spo0A~P binding to its boxes does not affect the RNAP recruitment to the promoters but instead affects the transcriptional initiation rate. Moreover, the effects of Spo0A~P binding to 0A boxes are mainly repressive and saturated early at the onset of starvation. Therefore, the increase inspo0Aexpression is mainly driven by the increase in RNAP holoenzyme levels. Additionally, we reveal that Spo0A~P affinity to 0A boxes is strongest at 0A3 and weakest at 0A2 and that there are attractive forces between the occupied 0A boxes. Our findings, in addition to clarifying how the sporulation master regulator is controlled, offer a framework to predict regulatory outcomes of complex gene-regulatory mechanisms. IMPORTANCECell differentiation is often critical for survival. In bacteria, differentiation decisions are controlled by transcriptional master regulators under transcriptional feedback control. Therefore, understanding how master regulators are transcriptionally regulated is required to understand differentiation. However, in many cases, the underlying regulation is complex, with multiple transcription factor binding sites and multiple promoters, making it challenging to dissect the exact mechanisms. Here, we address this problem for theBacillus subtilismaster regulator Spo0A. Using a biophysical model, we quantitatively characterize the effect of individual transcription factor binding sites on eachspo0Apromoter. Furthermore, the model allows us to identify the specific transcription step that is affected by transcription factor binding. Such a model is promising for the quantitative study of a wide range of master regulators involved in transcriptional feedback. 

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