A serine sensor for multicellularity in a bacterium

Subramaniam, Arvind R.; DeLoughery, Aaron; Bradshaw, Niels; Chen, Yun; O’Shea, Erin K.; Losick, Richard; Chai, Yunrong

doi:10.7554/elife.01501

Cited by 74 publications

(142 citation statements)

References 49 publications

Supporting

Mentioning

133

Contrasting

Order By: Relevance

“…3D, squares and triangles]) had much higher activities than the wild-type strain (YC952 [diamonds]). The reason why a mild decrease in the expression of sinR may lead to such a drastic increase in the expression of epsAepsO is due to hypersensitivity of SinR-mediated repression, a unique feature of SinR activity characterized in our previous studies (20,62).…”

Section: Fig 2 Colony and Pellicle Biofilms Formed By Mutants With Vamentioning

confidence: 99%

“…Based on observations in our previous studies (61,62), in which spontaneous mutants bearing point mutations in either the sinR or abrB gene were shown to form both robust biofilms and extensive cell chains, we decided to map the suppressor mutation by trying the targeted approach first and sequencing those biofilm-related regulatory genes in the suppressor mutant. Interestingly, our sequencing results indeed revealed a single nucleotide substitution in a region immediately upstream of sinR.…”

Section: Fig 2 Colony and Pellicle Biofilms Formed By Mutants With Vamentioning

confidence: 99%

See 1 more Smart Citation

The Bacterial Tyrosine Kinase Activator TkmA Contributes to Biofilm Formation Largely Independently of the Cognate Kinase PtkA in Bacillus subtilis

Gao

Greenwich

et al. 2015

J Bacteriol

Self Cite

View full text Add to dashboard Cite

In Bacillus subtilis, biosynthesis of exopolysaccharide (EPS), a key biofilm matrix component, is regulated at the posttranslational level by the bacterial tyrosine kinase (BY-kinase) EpsB. EpsB, in turn, relies on the cognate kinase activator EpsA for activation. A concerted role of a second BY-kinase-kinase activator pair, PtkA and TkmA, respectively in biofilm formation was also indicated in previous studies. However, the exact functions of PtkA and TkmA in biofilm formation remain unclear. In this work, we show that the kinase activator TkmA contributes to biofilm formation largely independently of the cognate kinase, PtkA. We further show that the biofilm defect caused by a ⌬tkmA mutation can be rescued by complementation by epsA, suggesting a functional overlap between TkmA and EpsA and providing a possible explanation for the role of TkmA in biofilm formation. We also show that the importance of TkmA in biofilm formation depends largely on medium conditions; the biofilm defect of ⌬tkmA is very severe in the biofilm medium LBGM (lysogenic broth M thiamine, 0.5% glycerol, 0.5% glutamic acid, 50 g/ml tryptophan, 50 g/ml threonine, and 50 g/ml phenylalanine). The molecular basis for the medium dependence is likely due to differential expression of tkmA and epsA in the two different media and complex regulation of these genes by both Spo0A and DegU. Our studies provide genetic evidence for possible cross talk between a BY-kinase activator (TkmA) and a noncognate kinase (EpsB) and an example of how environmental conditions may influence such cross talk in regulating biofilm formation in B. subtilis.[ IMPORTANCEIn bacteria, biosynthesis of secreted polysaccharides is often regulated by bacterial tyrosine kinases (BY-kinases). BY-kinases, in turn, rely on cognate kinase activators for activation. In this study, we investigated the role of a BY-kinase activator in biofilm formation in Bacillus subtilis. We present evidence that different BY-kinase activators may functionally overlap each other, as well as an example of how activities of the BY-kinase activators may be highly dependent on environmental conditions. Our study broadens the understanding of the complexity of regulation of the BY-kinases/kinase activators and the influence on bacterial cell physiology. Biofilms are multicellular communities of bacteria with highly complex structures and distinct morphological features (1-4). One of the most important characteristics of biofilms is the presence of a self-produced extracellular matrix, which allows individual cells within the biofilm to stick to each other (2, 3, 5). In Bacillus subtilis, the biofilm matrix consists of an exopolysaccharide (EPS); the amyloid fiber-like protein TasA; and a small hydrophobin, BslA (6-11). The regulatory circuit that controls the expression of the matrix-encoding genes has been well studied in B. subtilis (5,(12)(13)(14). EPS and TasA fibers are produced by the protein products of two matrix operons, epsA-epsO and tapA-sipW-tasA, respectively (8, 15). These two opero...

show abstract

Section: Fig 2 Colony and Pellicle Biofilms Formed By Mutants With Vamentioning

confidence: 99%

Section: Fig 2 Colony and Pellicle Biofilms Formed By Mutants With Vamentioning

confidence: 99%

The Bacterial Tyrosine Kinase Activator TkmA Contributes to Biofilm Formation Largely Independently of the Cognate Kinase PtkA in Bacillus subtilis

Gao

Greenwich

et al. 2015

J Bacteriol

Self Cite

View full text Add to dashboard Cite

show abstract

“…SinR is counteracted by a small antirepressor, SinI, whose expression is activated by a master regulator, Spo0A, under biofilm induction (13,14). More recently, we showed that metabolic signals also play important roles in triggering biofilm formation in B. subtilis (15)(16)(17). In one study, we discovered a novel serine-sensing mechanism that triggers biofilm formation by altering the translation efficiency of the biofilm repressor SinR in response to a decrease in cellular serine levels, which act as a proxy for the nutrient status in the bacterium (15).…”

mentioning

confidence: 98%

“…More recently, we showed that metabolic signals also play important roles in triggering biofilm formation in B. subtilis (15)(16)(17). In one study, we discovered a novel serine-sensing mechanism that triggers biofilm formation by altering the translation efficiency of the biofilm repressor SinR in response to a decrease in cellular serine levels, which act as a proxy for the nutrient status in the bacterium (15). In another study, acetic acid, a small volatile metabolite, was shown to stimulate biofilm formation in B. subtilis via air transmission (16).…”

mentioning

confidence: 99%

Genome-Wide Investigation of Biofilm Formation in Bacillus cereus

Yan

Gozzi

et al. 2017

Appl Environ Microbiol

Self Cite

View full text Add to dashboard Cite

Bacillus cereus is a soil-dwelling Gram-positive bacterium capable of forming structured multicellular communities, or biofilms. However, the regulatory pathways controlling biofilm formation are less well understood in B. cereus. In this work, we developed a method to study B. cereus biofilms formed at the air-liquid interface. We applied two genome-wide approaches, random transposon insertion mutagenesis to identify genes that are potentially important for biofilm formation, and transcriptome analyses by RNA sequencing (RNA-seq) to characterize genes that are differentially expressed in B. cereus when cells were grown in a biofilm-inducing medium. For the first approach, we identified 23 genes whose disruption by transposon insertion led to altered biofilm phenotypes. Based on the predicted function, they included genes involved in processes such as nucleotide biosynthesis, iron salvage, and antibiotic production, as well as genes encoding an ATP-dependent protease and transcription regulators. Transcriptome analyses identified about 500 genes that were differentially expressed in cells grown under biofilm-inducing conditions. One particular set of those genes may contribute to major metabolic shifts, leading to elevated production of small volatile molecules. Selected volatile molecules were shown to stimulate robust biofilm formation in B. cereus. Our studies represent a genome-wide investigation of B. cereus biofilm formation.IMPORTANCE In this work, we established a robust method for B. cereus biofilm studies and applied two genome-wide approaches, transposon insertion mutagenesis and transcriptome analyses by RNA-seq, to identify genes and pathways that are potentially important for biofilm formation in B. cereus. We discovered dozens of genes and two major metabolic shifts that seem to be important for biofilm formation in B. cereus. Our study represents a genome-wide investigation on B. cereus biofilm formation. KEYWORDS Bacillus cereus, biofilm formation, transcriptome, transposon mutagenesis Bacteria are capable of forming multicellular communities, known as biofilms (1, 2). Biofilms are clinically significant, because biofilms formed by pathogenic species are often associated with hospital-acquired infections, both acute and chronic (3). Biofilms are also significant in industry and the environment, causing billions of dollars of loss every year in ship, water, and dairy industries; however, in some cases, biofilms can be beneficial. In the field of agriculture, some of the rhizosphere-associated bacteria are used as biological control agents for plant protection. Those bacteria are able to protect plants from infections by various bacterial pathogens, fungi, and even worms through different mechanisms (4).Both Bacillus cereus and Bacillus subtilis belong to the rhizosphere-associated beneficial bacteria (4). Wild strains of B. subtilis are capable of forming robust pellicle

show abstract

“…Profiling has proven to be increasingly valuable in studies of the translation process, for example, in the discovery of novel open reading frames (ORFs), the determination of elongation rates, the identification of sites of ribosome pausing and in the study of protein folding (for review, see Morris 2009;Weiss and Atkins 2011;Michel and Baranov 2013;Ingolia 2014;Jackson and Standart 2015). It also has broad application in the analysis of global gene expression and has been exploited in studies of infectious diseases (Stern-Ginossar et al 2012, 2015Liu et al 2013;Arias et al 2014;Caro et al 2014;Jensen et al 2014;Muzzey et al 2014;Vasquez et al 2014;Yang et al 2015), cell growth, differentiation and development Huang et al 2013;Lee et al 2013;Stadler and Fire, 2013;Stumpf et al 2013;Subramaniam et al 2013;Baudin-Baillieu et al 2014;Brubaker et al 2014;Duncan and Mata 2014;Gonzalez et al 2014;Hendriks et al 2014;Katz et al 2014;Kronja et al 2014;Schrader et al 2014;Vaidyanathan et al 2014;de Klerk et al 2015), apoptosis (Wiita et al 2013), mitochondrial gene expression and disease (Rooijers et al 2013;Williams et al 2014), cell stress (Gerashenko et al 2012;Labunskyy et al 2014;Zid and O'Shea 2014;Sidrauski et al 2015), cell toxicity …”

Section: Introductionmentioning

confidence: 99%

The use of duplex-specific nuclease in ribosome profiling and a user-friendly software package for Ribo-seq data analysis

Chung

Hardcastle

Jones

et al. 2015

RNA

119

132

View full text Add to dashboard Cite

Ribosome profiling is a technique that permits genome-wide, quantitative analysis of translation and has found broad application in recent years. Here we describe a modified profiling protocol and software package designed to benefit more broadly the translation community in terms of simplicity and utility. The protocol, applicable to diverse organisms, including organelles, is based largely on previously published profiling methodologies, but uses duplex-specific nuclease (DSN) as a convenient, species-independent way to reduce rRNA contamination. We show that DSN-based depletion compares favorably with other commonly used rRNA depletion strategies and introduces little bias. The profiling protocol typically produces high levels of triplet periodicity, facilitating the detection of coding sequences, including upstream, downstream, and overlapping open reading frames (ORFs) and an alternative ribosome conformation evident during termination of protein synthesis. In addition, we provide a software package that presents a set of methods for parsing ribosomal profiling data from multiple samples, aligning reads to coding sequences, inferring alternative ORFs, and plotting average and transcript-specific aspects of the data. Methods are also provided for extracting the data in a form suitable for differential analysis of translation and translational efficiency.

show abstract

A serine sensor for multicellularity in a bacterium

Cited by 74 publications

References 49 publications

The Bacterial Tyrosine Kinase Activator TkmA Contributes to Biofilm Formation Largely Independently of the Cognate Kinase PtkA in Bacillus subtilis

The Bacterial Tyrosine Kinase Activator TkmA Contributes to Biofilm Formation Largely Independently of the Cognate Kinase PtkA in Bacillus subtilis

Genome-Wide Investigation of Biofilm Formation in Bacillus cereus

The use of duplex-specific nuclease in ribosome profiling and a user-friendly software package for Ribo-seq data analysis

Contact Info

Product

Resources

About