Purpose: The global rise in multidrug-resistant (MDR) Klebsiella pneumoniae, a critical ESKAPE pathogen, has outpaced the development of effective antibiotics. Bacteriophage therapy offers a promising alternative, but therapeutic candidates must be carefully selected for broad activity, genetic safety, synergistic cocktail performance, and clinical stability. Methods: We isolated and characterized six novel lytic phages (vB_Kpn_AM.K1 to vB_Kpn_AM.K6) targeting K. pneumoniae by assessing morphology, host range, growth kinetics, physicochemical stability, and resistance frequency. Genomes were sequenced to confirm absence of lysogeny and virulence genes. Infection dynamics was visualized via fluorescence microscopy. Phage activity was tested across 60 different MDR K. pneumoniae clinical isolates, obtained from diverse sources such as blood, sputum, occult feces, urine etc. Results: All six isolated phages were identified as novel dsDNA phages belonging to Caudoviricetes, with genome sizes ranging from 111 to 169 Kbp, devoid of virulence and AMR genes and demonstrating strong bacteriolytic activity. Growth kinetics indicated burst sizes varying from 12-148 PFU/infected cell. The phages displayed stability between 4-50°C, pH 4 -10 and sustained complete activity after lyophilization. More significantly, the phages and their cocktail combinations could effectively kill 93% of MDR K. pneumoniae clinical isolates. Conclusion: These findings establish a panel of genetically safe, phenotypically diverse phages with broad and synergistic activity against MDR K. pneumoniae. The unique replication phenotypes and formulation stability highlight their potential for therapeutic development and deployment in clinical or resource-limited settings.

Bacterial cryptic prophages not only encode genes that reduce the viability of the host upon induction but also contribute to host survival during stressful conditions. Rac is a cryptic prophage of Escherichia coli, and it encodes a toxic protein KilR, which causes morphological defects to the host. However, the mechanistic basis of its action is not well understood. In this study, we provide evidence that KilR is a dual inhibitor that affects cell division and cytoskeletal organization. We show that KilR expression is highly toxic, as demonstrated previously, and its predicted C-terminal unstructured region plays a crucial role in its function via a length-dependent manner. Low levels of KilR expression lead to cell filamentation and disruption of Z-rings, while high levels result in rod-shaped defects and mislocalization of the MreB cytoskeletal protein. Using fluorescent fusions, we observed that KilR is diffusively localized in the cytoplasm. When MreBCD proteins are overexpressed, KilR co-localizes with them, forming membrane-associated filaments, indicating a physical association. However, overexpressed MreBCD proteins do not alleviate the KilR-associated growth defect, unlike FtsZ. Finally, we present evidence that chromosomal KilR contributes to the co-inhibition of FtsZ and MreB localization in response to oxidative stress. Our data indicate that KilR inhibits MreB-associated cytoskeletal system, in addition to its effect on FtsZ-associated cell division system. We propose that the dual inhibition activity of KilR contributes to its high level of toxicity and to its function in SOS-independent DNA damage tolerance during oxidative stress.IMPORTANCEKilR is a Rac cryptic prophage-encoded toxic protein, which contributes to host survival during oxidative stress conditions. It is known to inhibit cell division by targeting the tubulin homolog, FtsZ. In this study, we show that KilR affects FtsZ-mediated cell division and MreB-mediated cell elongation. The simultaneous inhibition of cell division and cell elongation is known to be crucial for bacterial survival during stress conditions like oxidative stress. Our study identifies KilR as a cell division and cell elongation inhibitor, offering insights into how bacterial-phage coevolution drives the emergence of cryptic prophage elements, with specific genes enhancing bacterial fitness.

Background: Bacteriophages are the most genetically diverse biological entities in nature. Our current understanding of phage biology primarily stems from studies on a limited number of model bacteriophages. Jumbo phages, characterized by their exceptionally large genomes, are less frequently isolated and studied. Some jumbo phages exhibit remarkable genetic diversity, unique infection mechanisms, and therapeutic potential. Methods: In this study, we describe the isolation of Sharanji, a novel Escherichia coli jumbo phage, isolated from chicken feces. The phage genome was sequenced and analyzed extensively through gene annotation and phylogenetic analysis. The jumbo phage was phenotypically characterized through electron microscopy, host range analysis, and survival at different pH and temperatures, and one-step growth curve assay. Finally, Sharanji mediated infection of E. coli is studied through fluorescence microscopy, to analyze its mechanism of infection compared to well-studied nucleus-forming jumbo phages. Results: Whole genome sequencing reveals that Sharanji has a genome size of 350,079 bp and is a phage encompassing 593 ORFs. Genomic analysis indicates that the phage belongs to the Asteriusvirus genus and is related to E. coli jumbo phages PBECO4 and 121Q. Phenotypic analysis of isolated phage Sharanji, indicates that the phage size is 245.3 nm, and it is a narrow-spectrum phage infecting E. coli K12 strains, but not other bacteria including avian pathogenic E. coli. Infection analysis using microscopy shows that Sharanji infection causes cell filamentation. Furthermore, intracellular phage nucleus-like structures were not observed in Sharanji-infected cells, in contrast to infection by ΦKZ-like jumbo phages. Conclusions: Our study reports the isolation and characterization of Sharanji, one of the large E. coli jumbo phages. Both genotypic and phenotypic analyses suggest that Sharanji serves as a unique model system for studying phage-bacteria interactions, particularly within the context of non-nucleus-forming jumbo phages. Further exploration of jumbo phages holds promise for uncovering new paradigms in the study of microbial viruses.

Jumbo phages are characterized by their remarkably large-sized genome and unique life cycles. Jumbo phages belonging to Chimalliviridae family protect the replicating phage DNA from host immune systems like CRISPR-Cas and restriction-modification system through a phage nucleus structure. Several recent studies have provided new insights into jumbo phage infection biology, but the pan-genome diversity of jumbo phages and their relationship with CRISPR-Cas targeting beyond Chimalliviridae are not well understood. In this study, we used pan-genome analysis to identify orthologous gene families shared among 331 jumbo phages with complete genomes. We show that jumbo phages lack a universally conserved set of core genes but identified seven “soft-core genes” conserved in over 50% of these phages. These genes primarily govern DNA-related activities, such as replication, repair, or nucleotide synthesis. Jumbo phages exhibit a wide array of accessory and unique genes, underscoring their genetic diversity. Phylogenetic analyses of the soft-core genes revealed frequent horizontal gene transfer events between jumbo phages, non-jumbo phages, and occasionally even giant eukaryotic viruses, indicating a polyphyletic evolutionary nature. We categorized jumbo phages into 11 major viral clusters (VCs) spanning 130 sub-clusters, with the majority being multi-genus jumbo phage clusters. Moreover, through the analysis of hallmark genes related to CRISPR-Cas targeting, we predict that many jumbo phages can evade host immune systems using both known and yet-to-be-identified mechanisms. In summary, our study enhances our understanding of jumbo phages, shedding light on their pan-genome diversity and remarkable genome protection capabilities. IMPORTANCE Jumbo phages are large bacterial viruses known for more than 50 years. However, only in recent years, a significant number of complete genome sequences of jumbo phages have become available. In this study, we employed comparative genomic approaches to investigate the genomic diversity and genome protection capabilities of the 331 jumbo phages. Our findings revealed that jumbo phages exhibit high genetic diversity, with only a few genes being relatively conserved across jumbo phages. Interestingly, our data suggest that jumbo phages employ yet-to-be-identified strategies to protect their DNA from the host immune system, such as CRISPR-Cas.

Antimicrobial resistance has emerged as a global threat to the treatment of infectious diseases. Antibacterial photodynamic therapy (aPDT) is a promising alternative approach and is highly suitable for the treatment of cutaneous bacterial infections through topical applications. aPDT relies on light-responsive compounds called photosensitizer (PS) dyes, which generate reactive oxygen species (ROS) when induced by light, thereby killing bacterial cells. Despite several previous studies in this area, the molecular details of targeting and cell death mediated by PS dyes are poorly understood. In this study, we further investigate the antibacterial properties of two water-soluble Sn(IV) tetrapyridylporphyrins that were quaternized with methyl and hexyl groups (1 and 2). In this follow-up study, we demonstrate that Sn(IV)-porphyrins can be photoexcited by blue light (a 427 nm LED) and exhibit various levels of bactericidal activity against both Gram-(+) and Gram-(−) strains of bacteria. Using localization studies through fluorescence microscopy, we show that 2 targets the bacterial membrane more effectively than 1 and exhibits comparatively higher aPDT activity. Using multiple fluorescence reporters, we demonstrate that photoactivation of 1 and 2 results in extensive collateral damage to the bacterial cells including DNA cleavage, membrane damage, and delocalization of central systems necessary for bacterial growth and division. In summary, this investigation provides deep insights into the mechanism of bacterial killing mediated by the Sn(IV)-porphyrins. Moreover, our approach offers a new method for evaluating the activity of PS, which may inspire the discovery of new PS with enhanced aPDT activity.

Successful development of phage-based therapeutics and their utility predominantly depend on the mode and route of phage administration. Topical and site-directed phage application evokes minimal immune clearance and allows more phage-host adsorption, thereby ensuring higher phage efficacy. However, a notable drawback of conventional topical phage applications is the absence of sustained release. Occlusive emollients guarantee the controlled release of active pharmaceutical ingredients (APIs), thereby facilitating administration, preventing moisture loss, and acting as a skin barrier. In this study, we developed phage and human platelet lysate (h-PL) incorporated cetomacrogol-based creams for combined phage therapy and wound healing. The base material for phage immobilization was formulated by emulsifying paraffin and sterile water with cetomacrogol (emulsifying agent). Specifically, we incorporated a Pseudomonas aeruginosa-infecting lytic phage vB_PaeM_M12PA in the formulation and characterized its genome in this study. Cetomacrogol, a nonionic PEG (polyethylene glycol) based ether, rendered phage stability and allowed initial burst release followed by continuous controlled release of phages from the embedding matrix in the initial 6-8 h. Rheological studies showed that the material has elastic properties with storage moduli (G′) values ranging from 109.51 ± 2.10 to 126.02 ± 3.13 kPa, indicating frequency-independent deformation. Platelet lysates in the cream acted as wound healing agents, and in vitro evaluation of cell migration and wound healing capacity of h-PL showed a significant enhancement by the sixth hour compared to untreated groups. The phage-incorporated cream showed sustained phage release in solid media and a significant reduction in bacterial growth in liquid cultures. In vivo wound healing studies in 6-week-old Wistar rats with full-thickness excision wounds and subsequent histopathological studies showed that the formulation enhanced wound healing and tissue restoration efficiency. In conclusion, the study unveils a promising approach for integrated phage therapy and wound healing strategies.

Actin is a major cytoskeletal system that mediates the intricate organization of macromolecules within cells. The bacterial cytoskeletal protein MreB is a prokaryotic actin-like protein governing the cell shape and intracellular organization in many rod-shaped bacteria, including pathogens. MreB stands as a target for antibiotic development, and compounds like A22 and its analogue, MP265, are identified as potent inhibitors of MreB. The bacterial actin MreB shares structural homology with eukaryotic actin despite lacking sequence similarity. It is currently not clear whether small molecules that inhibit MreB can act on eukaryotic actin due to their structural similarity. In this study, we investigate the molecular interactions between A22 and its analogue MP265 with MreB and eukaryotic actin through a molecular dynamics approach. Employing MD simulations and free energy calculations with an all-atom model, we unveil the robust interaction of A22 and MP265 with MreB, and substantial binding affinity is observed for A22 and MP265 with eukaryotic actin. Experimental assays reveal A22’s toxicity to eukaryotic cells, including yeast and human glioblastoma cells. Microscopy analysis demonstrates the profound effects of A22 on actin organization in human glioblastoma cells. This integrative computational and experimental study provides new insights into A22’s mode of action, highlighting its potential as a versatile tool for probing the dynamics of both prokaryotic and eukaryotic actins.

Bacteriophages, the natural predators of bacteria, are incredibly potent candidates to counteract antimicrobial resistance (AMR). However, the rapid development of phage-resistant mutants challenges the potential of phage therapy. Understanding the mechanisms of bacterial adaptations to phage predation is crucial for phage-based prognostic applications. Phage cocktails and combinatorial therapy, using optimized dosage patterns of antibiotics, can negate the development of phage-resistant mutations and prolong therapeutic efficacy. In this study, we describe the characterization of a novel bacteriophage and the physiology of phage-resistant mutant developed during infection. M12PA is a P. aeruginosa-infecting bacteriophage with Myoviridae morphology. We observed that prolonged exposure of P. aeruginosa to M12PA resulted in the selection of phage-resistant mutants. Among the resistant mutants, pyomelanin-producing mutants, named PA-M, were developed at a frequency of 1 in 16. Compared to the wild-type, we show that PA-M mutant is severely defective in virulence properties, with altered motility, biofilm formation, growth rate, and antibiotic resistance profile. The PA-M mutant exhibited reduced pathogenesis in an allantoic-infected chick embryo model system compared to the wild-type. Finally, we provide evidence that combinatory therapy, combining M12PA with antibiotics or other phages, significantly delayed the emergence of resistant mutants. In conclusion, our study highlights the potential of combinatory phage therapy to delay the development of phage-resistant mutants and enhance the efficacy of phage-based treatments against P. aeruginosa.

The cyanobacterial circadian oscillator, consisting of KaiA, KaiB, and KaiC proteins, drives global rhythms of gene expression and compaction of the chromosome and regulates the timing of cell division and natural transformation. While the KaiABC posttranslational oscillator can be reconstituted in vitro, the Kai-based oscillator is subject to several layers of regulation in vivo. Specifically, the oscillator proteins undergo changes in their subcellular localization patterns, where KaiA and KaiC are diffuse throughout the cell during the day and localized as a focus at or near the pole of the cell at night. Here, we report that the CI domain of KaiC, when in a hexameric state, is sufficient to target KaiC to the pole. Moreover, increased ATPase activity of KaiC correlates with enhanced polar localization. We identified proteins associated with KaiC in either a localized or diffuse state. We found that loss of Rbp2, found to be associated with localized KaiC, results in decreased incidence of KaiC localization and long-period circadian phenotypes. Rbp2 is an RNA-binding protein, and it appears that RNA-binding activity of Rbp2 is required to execute clock functions. These findings uncover previously unrecognized roles for Rbp2 in regulating the circadian clock and suggest that the proper localization of KaiC is required for a fully functional clock in vivo.

DNA integrity in bacteria is regulated by various factors that act on the DNA. trans-translation has previously been shown to be important for the survival of Escherichia coli cells exposed to certain DNA-damaging agents. However, the mechanisms underlying this sensitivity are poorly understood. In this study, we explored the involvement of the trans-translation system in the maintenance of genome integrity using various DNA-damaging agents and mutant backgrounds. Relative viability assays showed that SsrA-defective cells were sensitive to DNA-damaging agents, such as nalidixic acid (NA), ultraviolet radiation (UV), and methyl methanesulfonate (MMS). The viability of SsrA-defective cells was rescued by deleting sulA, although the expression of SulA was not more pronounced in SsrA-defective cells than in wild-type cells. Live cell imaging using a Gam-GFP fluorescent reporter showed increased double-strand breaks (DSBs) in SsrA-defective cells during DNA damage. We also showed that the ribosome rescue function of SsrA was sufficient for DNA damage tolerance. DNA damage sensitivity can be alleviated by partial uncoupling of transcription and translation by using sub-lethal concentrations of ribosome inhibiting antibiotic (tetracycline) or by mutating the gene coding for RNase H (rnhA). Taken together, our results highlight the importance of trans-translation system in maintaining genome integrity and bacterial survival during DNA damage.

Wherever bacteria are found, so are the viruses that infect them. These viruses, called bacteriophages are the most abundant biological entities on Earth. To initiate an infection, phages bind to specific bacterial surface proteins or cell wall components to inject their genetic material into the cell. To prevent infection by bacteriophages, bacteria have developed an arsenal of defense mechanisms. Restriction-Modification Systems contain two major components: a restriction endonuclease and a methyltransferase. CRISPR-Cas systems are comprised of a DNA-based array of clustered regularly interspaced short palindromic repeats and CRISPR-associated genes that enable antiphage function. Bacteriophage genomes are modified by a wide variety of chemical modifications. Nuclease activation is the other major target for known anti-CRISPR mechanisms.

Clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPRassociated (Cas) systems are prokaryotic adaptive immune systems that have been well characterized biochemically, but in vivo spatiotemporal regulation and cell biology remain largely unaddressed. Here, we used fluorescent fusion proteins introduced at the chromosomal CRISPR-Cas locus to study the localization of the type I-F CRISPR-Cas system in Pseudomonas aeruginosa. When lacking a target in the cell, the Cascade complex is broadly nucleoid bound, while Cas3 is diffuse in the cytoplasm. When targeted to an integrated prophage, however, the CRISPR RNA (crRNA)-guided type I-F Cascade complex and a majority of Cas3 molecules in the cell are recruited to a single focus. Nucleoid association of the Csy proteins that form the Cascade complex is crRNA dependent and specifically inhibited by the expression of anti-CRISPR AcrIF2, which blocks protospacer adjacent motif (PAM) binding. The Cas9 nuclease is also nucleoid localized, only when single guide RNA (sgRNA) bound, which is abolished by the PAM-binding inhibitor AcrIIA4. Our findings reveal PAM-dependent nucleoid surveillance and spatiotemporal regulation in type I CRISPR-Cas that separates the nuclease-helicase Cas3 from the crRNA-guided surveillance complex.

Bacterial infections have an enormous impact on public health, which are combated using antibiotics. The World Health Organization has predicted that drug-resistant disease caused by continuous use of antibiotics could cause nearly 10 million deaths each year by 2050 and catastrophic damage to the economy. With no successful discovery of novel set of antibiotics for nearly four decades, antimicrobial resistance has become a serious public health threat. As human race is already facing a dramatic challenge due to resistance in this antibiotic era, there is an urgent need for alternative therapies to combat this issue. That said, phage therapy - which uses bacterial viruses (phages) to combat bacterial infections and has been around for more than 100 years - is considered a promising alternative to antibiotic therapy, especially against multidrugresistant pathogens. Phage therapy has several advantages over antibiotic therapy: high specificity, i.e., targeting a specific pathogen but not the rest of the microbiome; ability to overcome bacterial biofilms; and ability to deliver novel antimicrobials like CRISPR-Cas nucleases. However, despite holding several advantages, conventional phage therapy technology is not widely successful. In this chapter, we highlight how bacteriophages are used to treat infections caused by pathogens, especially ESKAPE pathogens. We also summarize the currently available methods for bacteriophage genome engineering and discuss the advantages of using genetically engineered bacteriophages over conventional methods to combat bacterial infections.

The poles of Escherichia coli cells are emerging as hubs for major sensory systems, but the polar determinants that allocate their components to the pole are largely unknown. Here, we describe the discovery of a previously unannotated protein, TmaR, which localizes to the E. coli cell pole when phosphorylated on a tyrosine residue. TmaR is shown here to control the subcellular localization and activity of the general PTS protein Enzyme I (EI) by binding and polar sequestration of EI, thus regulating sugar uptake and metabolism. Depletion or overexpression of TmaR results in EI release from the pole or enhanced recruitment to the pole, which leads to increasing or decreasing the rate of sugar consumption, respectively. Notably, phosphorylation of TmaR is required to release EI and enable its activity. Like TmaR, the ability of EI to be recruited to the pole depends on phosphorylation of one of its tyrosines. In addition to hyperactivity in sugar consumption, the absence of TmaR also leads to detrimental effects on the ability of cells to survive in mild acidic conditions. Our results suggest that this survival defect, which is sugar- and EI-dependent, reflects the difficulty of cells lacking TmaR to enter stationary phase. Our study identifies TmaR as the first, to our knowledge, E. coli protein reported to localize in a tyrosine-dependent manner and to control the activity of other proteins by their polar sequestration and release.

All viruses require strategies to inhibit or evade the immune pathways of cells that they infect. The viruses that infect bacteria, bacteriophages (phages), must avoid immune pathways that target nucleic acids, such as CRISPR–Cas and restriction-modification systems, to replicate efficiently1. Here we show that jumbo phage ΦKZ segregates its DNA from immunity nucleases of its host, Pseudomonas aeruginosa, by constructing a proteinaceous nucleus-like compartment. ΦKZ is resistant to many immunity mechanisms that target DNA in vivo, including two subtypes of CRISPR–Cas3, Cas9, Cas12a and the restriction enzymes HsdRMS and EcoRI. Cas proteins and restriction enzymes are unable to access the phage DNA throughout the infection, but engineering the relocalization of EcoRI inside the compartment enables targeting of the phage and protection of host cells. Moreover, ΦKZ is sensitive to Cas13a—a CRISPR–Cas enzyme that targets RNA—probably owing to phage mRNA localizing to the cytoplasm. Collectively, we propose that Pseudomonas jumbo phages evade a broad spectrum of DNA-targeting nucleases through the assembly of a protein barrier around their genome.

CRISPR–Cas systems are adaptive immune systems that protect bacteria from bacteriophage (phage) infection1. To provide immunity, RNA-guided protein surveillance complexes recognize foreign nucleic acids, triggering their destruction by Cas nucleases2. While the essential requirements for immune activity are well understood, the physiological cues that regulate CRISPR–Cas expression are not. Here, a forward genetic screen identifies a two-component system (KinB–AlgB), previously characterized in the regulation of Pseudomonas aeruginosa alginate biosynthesis3,4, as a regulator of the expression and activity of the P. aeruginosa Type I-F CRISPR–Cas system. Downstream of KinB–AlgB, activators of alginate production AlgU (a σE orthologue) and AlgR repress CRISPR–Cas activity during planktonic and surface-associated growth5. AmrZ, another alginate regulator6, is triggered to repress CRISPR–Cas immunity upon surface association. Pseudomonas phages and plasmids have taken advantage of this regulatory scheme and carry hijacked homologs of AmrZ that repress CRISPR–Cas expression and activity. This suggests that while CRISPR–Cas regulation may be important to limit self-toxicity, endogenous repressive pathways represent a vulnerability for parasite manipulation.

Dynamic biological systems can be modelled to an equivalent modular structure using Boolean networks (BNs) due to their simple construction and relative ease of integration. The chemotaxis network of the bacterium Escherichia coli (E. coli) is one of the most investigated biological systems. In this study, the authors developed a multi-bit Boolean approach to model the drifting behaviour of the E. coli chemotaxis system. Their approach, which is slightly different than the conventional BNs, is designed to provide finer resolution to mimic high-level functional behaviour. Using this approach, they simulated the transient and steady-state responses of the chemoreceptor sensory module. Furthermore, they estimated the drift velocity under conditions of the exponential nutrient gradient. Their predictions on chemotactic drifting are in good agreement with the experimental measurements under similar input conditions. Taken together, by simulating chemotactic drifting, they propose that multi-bit Boolean methodology can be used for modelling complex biological networks. Application of the method towards designing bio-inspired systems such as nano-bots is discussed.

Transcription, the first step in the process of gene expression, is a process during which RNA is synthesized from the complementary DNA strand. RNA polymerase is the central machinery that catalyzes RNA synthesis in a DNA-dependent manner. To initiate transcription, RNA polymerase needs to recognize a region called promoter, which is located upstream of operons/genes. Transcription is tightly regulated through the stages of initiation, elongation and termination. Various factors, including DNA signals, regulatory proteins, noncoding RNAs and small ligands cooperates with RNA polymerase to control transcription. This article reviews our current understanding of transcription regulation in bacteria.

Although the list of proteins that localize to the bacterial cell poles is constantly growing, little is known about their temporal behavior. EI, a major protein of the phosphotransferase system (PTS) that regulates sugar uptake and metabolism in bacteria, was shown to form clusters at the Escherichia coli cell poles. We monitored the localization of EI clusters, as well as diffuse molecules, in space and time during the lifetime of E. coli cells. We show that EI distribution and cluster dynamics varies among cells in a population, and that the cluster speed inversely correlates with cluster size. In growing cells, EI is not assembled into clusters in almost 40% of the cells, and the clusters in most remaining cells dynamically relocate within the pole region or between the poles. In non-growing cells, the fraction of cells that contain EI clusters is significantly higher, and dispersal of these clusters is often observed shortly after exiting quiescence. Later, during growth, EI clusters stochastically re-form by assembly of pre-existing dispersed molecules at random time points. Using a fluorescent glucose analog, we found that EI function inversely correlates with clustering and with cluster size. Thus, activity is exerted by dispersed EI molecules, whereas the polar clusters serve as a reservoir of molecules ready to act when needed. Taken together our findings highlight the spatiotemporal distribution of EI as a novel layer of regulation that contributes to the population phenotypic heterogeneity with regard to sugar metabolism, seemingly conferring a survival benefit.

To maintain genome integrity, organisms employ DNA damage response, the underlying principles of which are conserved from bacteria to humans. The bacterial small RNA OxyS of Escherichia coli is induced upon oxidative stress and has been implicated in protecting cells from DNA damage; however, the mechanism by which OxyS confers genome stability remained unknown. Here, we revealed an OxyS-induced molecular checkpoint relay, leading to temporary cell cycle arrest to allow damage repair. By repressing the expression of the essential transcription termination factor nusG, OxyS enables read-through transcription into a cryptic prophage encoding kilR. The KilR protein interferes with the function of the major cell division protein FtsZ, thus imposing growth arrest. This transient growth inhibition facilitates DNA damage repair, enabling cellular recovery, thereby increasing viability following stress. The OxyS-mediated growth arrest represents a novel tier of defense, introducing a new regulatory concept into bacterial stress response.

The Sec system is responsible for protein insertion, translocation and secretion across membranes in all cells. The bacterial actin homolog MreB controls various processes, including cell wall synthesis, membrane organization and polarity establishment. Here we show that the two systems genetically interact and that components of the Sec system, especially the SecA motor protein, are essential for spatiotemporal organization of MreB in E. coli, as evidenced by the accumulation of MreB at irregular sites in Sec-impaired cells. MreB mislocalization in SecA-defective cells significantly affects MreB-coordinated processes, such as cell wall synthesis, and induce formation of membrane invaginations enriched in high fluidity domains. Additionally, MreB is not recruited to the FtsZ ring in secA mutant cells, contributing to division arrest and cell filamentation. Our results show that all these faults are due to improper targeting of MreB to the membrane in the absence of SecA. Thus, when we reroute RodZ, MreB membrane-anchor, by fusing it to a SecA-independent integral membrane protein and overproducing it, MreB localization is restored and the defect in cell division is corrected. Notably, the RodZ moiety is not properly inserted into the membrane, strongly suggesting that it only serves as a bait for placing MreB around the cell circumference. Finally, we show that MreB localization depends on SecA also in C. crescentus, suggesting that regulation of MreB by the Sec system is conserved in bacteria. Taken together, our data reveal that the secretion system plays an important role in determining the organization and functioning of the cytoskeletal system in bacteria.

While an increasing number of conserved small regulatory RNAs (sRNAs) are known to function in general bacterial physiology, the roles and modes of action of sRNAs from horizontally acquired genomic regions remain little understood. The IsrK sRNA of Gifsy-1 prophage of Salmonella belongs to the latter class. This regulatory RNA exists in two isoforms. The first forms, when a portion of transcripts originating from isrK promoter reads-through the IsrK transcription-terminator producing a translationally inactive mRNA target. Acting in trans, the second isoform, short IsrK RNA, binds the inactive transcript rendering it translationally active. By switching on translation of the first isoform, short IsrK indirectly activates the production of AntQ, an antiterminator protein located upstream of isrK. Expression of antQ globally interferes with transcription termination resulting in bacterial growth arrest and ultimately cell death. Escherichia coli and Salmonella cells expressing AntQ display condensed chromatin morphology and localization of UvrD to the nucleoid. The toxic phenotype of AntQ can be rescued by co-expression of the transcription termination factor, Rho, or RNase H, which protects genomic DNA from breaks by resolving R-loops. We propose that AntQ causes conflicts between transcription and replication machineries and thus promotes DNA damage. The isrK locus represents a unique example of an island-encoded sRNA that exerts a highly complex regulatory mechanism to tune the expression of a toxic protein.

Bacterial cells are intricately organized, despite the lack of membrane-bounded organelles. The extremely crowded cytoplasm promotes macromolecular self-assembly and formation of distinct subcellular structures, which perform specialized functions. For example, the cell poles act as hubs for signal transduction complexes, thus providing a platform for the coordination of optimal cellular responses to environmental cues. Distribution of macromolecules is mostly mediated via specialized transport machineries, including the MreB cytoskeleton. Recent evidence shows that RNAs also specifically localize within bacterial cells, raising the possibility that gene expression is spatially organized. Here we review the current understanding of where things are in bacterial cells and discuss emerging questions that need to be addressed in the future.

The bacterial cell poles are emerging as subdomains where many cellular activities take place, but the mechanisms for polar localization are just beginning to unravel. The general phosphotransferase system (PTS) proteins, enzyme I (EI) and HPr, which control preferential use of carbon sources in bacteria, were recently shown to localize near the Escherichia coli cell poles. Here, we show that EI localization does not depend on known polar constituents, such as anionic lipids or the chemotaxis receptors, and on the cell division machinery, nor can it be explained by nucleoid occlusion or localized translation. Detection of the general PTS proteins at the budding sites of endocytotic-like membrane invaginations in spherical cells and their colocalization with the negative curvature sensor protein DivIVA suggest that geometric cues underlie localization of the PTS system. Notably, the kinetics of glucose uptake by spherical and rod-shaped E. coli cells are comparable, implying that negatively curved "polelike" sites support not only the localization but also the proper functioning of the PTS system in cells with different shapes. Consistent with the curvature-mediated localization model, we observed the EI protein from Bacillus subtilis at strongly curved sites in both B. subtilis and E. coli. Taken together, we propose that changes in cell architecture correlate with dynamic survival strategies that localize central metabolic systems like the PTS to subcellular domains where they remain active, thus maintaining cell viability and metabolic alertness. © 2013 Govindarajan et al.

For many years, the bacterial cells were regarded as tiny vessels lacking internal organization. This view, which stemmed from the scarcity of membrane-bounded organelles, has changed considerably in recent years, mainly due to advancements in imaging capabilities. Consequently, despite the rareness of conventional organelles, bacteria are now known to have an intricate internal organization, which is vital for many cellular processes. The list of bacterial macromolecules reported to have distinct localization patterns is rapidly growing. Moreover, time-lapse imaging revealed the spatiotemporal dynamics of various bacterial macromolecules. Although the regulatory mechanisms that underlie macromolecules localization in bacterial cells are largely unknown, certain strategies elucidated thus far include the establishment of cell polarity, the employment of cytoskeletal proteins, and the use of the membrane properties, that is, curvature, electric potential, and composition, as localization signals. The most surprising mechanism discovered thus far is targeting of certain mRNAs to the subcellular domains where their protein products are required. This mechanism relies on localization features in the mRNA itself and does not depend on translation. Localization of other mRNAs near their genetic loci suggests that the bacterial chromosome is involved in organizing gene expression. Taken together, the deep-rooted separation between cells with nucleus and without is currently changing, highlighting bacteria as suitable models for studying universal mechanisms underlying cell architecture. © 2012 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.

The field of bacterial cell biology has been revolutionized in the last decade by improvements in imaging capabilities which have revealed that bacterial cells, previously thought to be non-compartmentalized, possess an intricate higher-order organization. Many bacterial proteins localize to specific subcellular domains and regulate the spatial deployment of other proteins, DNA and lipids. Recently, the surprising discovery was made that bacterial RNA molecules are also specifically localized. However, the mechanisms that underlie bacterial cell architecture are just starting to be unraveled. The limited number of distribution patterns observed thus far for bacterial proteins and RNAs, and the similarity between the patterns exhibited by these macromolecules, suggest that the processes that underlie their localization are inextricably linked. We discuss these spatial arrangements and the insights that they provide on processes, such as localized translation, protein complex formation, and crosstalk between bacterial machineries. © 2012 Elsevier Ltd.