Your search keyword '"Mandic-Mulec, Ines"' showing total 12 results

1. Peptide signaling without feedback in signal production operates as a true quorum sensing communication system in Bacillus subtilis.

Author

Dogsa I, Spacapan M, Dragoš A, Danevčič T, Pandur Ž, and Mandic-Mulec I

Subjects

Oxygen, Bacillus subtilis metabolism, Bacterial Proteins metabolism, Models, Biological, Quorum Sensing

Abstract

Bacterial quorum sensing (QS) is based on signal molecules (SM), which increase in concentration with cell density. At critical SM concentration, a variety of adaptive genes sharply change their expression from basic level to maximum level. In general, this sharp transition, a hallmark of true QS, requires an SM dependent positive feedback loop, where SM enhances its own production. Some communication systems, like the peptide SM-based ComQXPA communication system of Bacillus subtilis, do not have this feedback loop and we do not understand how and if the sharp transition in gene expression is achieved. Based on experiments and mathematical modeling, we observed that the SM peptide ComX encodes the information about cell density, specific cell growth rate, and even oxygen concentration, which ensure power-law increase in SM production. This enables together with the cooperative response to SM (ComX) a sharp transition in gene expression level and this without the SM dependent feedback loop. Due to its ultra-sensitive nature, the ComQXPA can operate at SM concentrations that are 100-1000 times lower than typically found in other QS systems, thereby substantially reducing the total metabolic cost of otherwise expensive ComX peptide.

Published

2021

2. Social behaviours by Bacillus subtilis: quorum sensing, kin discrimination and beyond.

Author

Kalamara M, Spacapan M, Mandic-Mulec I, and Stanley-Wall NR

Subjects

Bacillus subtilis classification, Biofilms growth & development, Gene Expression Regulation, Bacterial, Signal Transduction, Bacillus subtilis genetics, Bacillus subtilis metabolism, Bacterial Proteins genetics, Quorum Sensing genetics

Abstract

Here, we review the multiple mechanisms that the Gram-positive bacterium Bacillus subtilis uses to allow it to communicate between cells and establish community structures. The modes of action that are used are highly varied and include routes that sense pheromone levels during quorum sensing and control gene regulation, the intimate coupling of cells via nanotubes to share cytoplasmic contents, and long-range electrical signalling to couple metabolic processes both within and between biofilms. We explore the ability of B. subtilis to detect 'kin' (and 'cheater cells') by looking at the mechanisms used to potentially ensure beneficial sharing (or limit exploitation) of extracellular 'public goods'. Finally, reflecting on the array of methods that a single bacterium has at its disposal to ensure maximal benefit for its progeny, we highlight that a large future challenge will be integrating how these systems interact in mixed-species communities., (© 2018 The Authors. Molecular Microbiology Published by John Wiley & Sons Ltd.)

Published

2018

3. ComQXPA quorum sensing systems may not be unique to Bacillus subtilis: a census in prokaryotic genomes.

Author

Dogsa I, Choudhary KS, Marsetic Z, Hudaiberdiev S, Vera R, Pongor S, and Mandic-Mulec I

Subjects

Acyl-Butyrolactones metabolism, Consensus Sequence, Genetic Variation, Genomics, Bacillus subtilis cytology, Bacillus subtilis genetics, Genetic Loci genetics, Genome, Bacterial genetics, Quorum Sensing genetics

Abstract

The comQXPA locus of Bacillus subtilis encodes a quorum sensing (QS) system typical of Gram positive bacteria. It encodes four proteins, the ComQ isoprenyl transferase, the ComX pre-peptide signal, the ComP histidine kinase, and the ComA response regulator. These are encoded by four adjacent genes all situated on the same chromosome strand. Here we present results of a comprehensive census of comQXPA-like gene arrangements in 2620 complete and 6970 draft prokaryotic genomes (sequenced by the end of 2013). After manually checking the data for false-positive and false-negative hits, we found 39 novel com-like predictions. The census data show that in addition to B. subtilis and close relatives, 20 comQXPA-like loci are predicted to occur outside the B. subtilis clade. These include some species of Clostridiales order, but none outside the phylum Firmicutes. Characteristic gene-overlap patterns were observed in comQXPA loci, which were different for the B. subtilis-like and non-B. subtilis-like clades. Pronounced sequence variability associated with the ComX peptide in B. subtilis clade is evident also in the non-B. subtilis clade suggesting grossly similar evolutionary constraints in the underlying quorum sensing systems.

Published

2014

4. Private link between signal and response in Bacillus subtilis quorum sensing.

Author

Oslizlo A, Stefanic P, Dogsa I, and Mandic-Mulec I

Subjects

Bacillus subtilis genetics, Bacterial Proteins metabolism, Chromatography, High Pressure Liquid, Microscopy, Fluorescence, Mutation, Bacillus subtilis physiology, Quorum Sensing, Signal Transduction

Abstract

Bacteria coordinate their behavior using quorum sensing (QS), whereby cells secrete diffusible signals that generate phenotypic responses associated with group living. The canonical model of QS is one of extracellular signaling, where signal molecules bind to cognate receptors and cause a coordinated response across many cells. Here we study the link between QS input (signaling) and QS output (response) in the ComQXPA QS system of Bacillus subtilis by characterizing the phenotype and fitness of comQ null mutants. These lack the enzyme to produce the ComX signal and do not activate the ComQXPA QS system in other cells. In addition to the activation effect of the signal, however, we find evidence of a second, repressive effect of signal production on the QS system. Unlike activation, which can affect other cells, repression acts privately: the de-repression of QS in comQ cells is intracellular and only affects mutant cells lacking ComQ. As a result, the QS signal mutants have an overly responsive QS system and overproduce the secondary metabolite surfactin in the presence of the signal. This surfactin overproduction is associated with a strong fitness cost, as resources are diverted away from primary metabolism. Therefore, by acting as a private QS repressor, ComQ may be protected against evolutionary competition from loss-of-function mutations. Additionally, we find that surfactin participates in a social selection mechanism that targets signal null mutants in coculture with signal producers. Our study shows that by pleiotropically combining intracellular and extracellular signaling, bacteria may generate evolutionarily stable QS systems., Competing Interests: The authors declare no conflict of interest.

Published

2014

5. The quorum sensing diversity within and between ecotypes of Bacillus subtilis.

Author

Stefanic P, Decorosi F, Viti C, Petito J, Cohan FM, and Mandic-Mulec I

Subjects

Bacillus subtilis classification, Bacillus subtilis genetics, Bacteria classification, Bacteria genetics, Base Sequence, Biodiversity, Biological Evolution, Molecular Sequence Data, Phylogeny, Soil Microbiology, Bacillus subtilis physiology, Ecotype, Genetic Variation, Quorum Sensing genetics

Abstract

Ecological sociobiology is an emerging field that aims to frame social evolution in terms of ecological adaptation. Here we explore the ecological context for evolution of quorum sensing diversity in bacteria, where social communication is limited to members of the same quorum sensing type (pherotype). We sampled isolates of Bacillus subtilis from soil on a microgeographical scale and identified three ecologically distinct phylogenetic groups (ecotypes) and three pherotypes. Each pherotype was strongly associated with a different ecotype, suggesting that it is usually not adaptive for one ecotype to 'listen' to the signalling of another. Each ecotype, however, contained one or more minority pherotypes shared with the other B. subtilis ecotypes and with more distantly related species taxa. The pherotype diversity within ecotypes is consistent with two models: first, a pherotype cycling model, whereby minority pherotypes enter a population through horizontal genetic transfer and increase in frequency through cheating the social interaction; and second, an occasional advantage model, such that when two ecotypes are each below their quorum densities, they may benefit from listening to one another. This is the first survey of pherotype diversity in relation to ecotypes and it will be interesting to further test the hypotheses raised and supported here, and to explore other bacterial systems for the role of ecological divergence in fostering pherotype diversity., (© 2012 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2012

6. Surfactin Facilitates Horizontal Gene Transfer in Bacillus subtilis.

Author

Danevčič, Tjaša, Dragoš, Anna, Spacapan, Mihael, Stefanic, Polonca, Dogsa, Iztok, and Mandic-Mulec, Ines

Subjects

HORIZONTAL gene transfer, SURFACTIN, BACILLUS subtilis, GENETIC transformation, LYSIS, BACTERIAL evolution

Abstract

Genetic competence for the uptake and integration of extracellular DNA is a key process in horizontal gene transfer (HGT), one of the most powerful forces driving the evolution of bacteria. In several species, development of genetic competence is coupled with cell lysis. Using Bacillus subtilis as a model bacterium, we studied the role of surfactin, a powerful biosurfactant and antimicrobial lipopeptide, in genetic transformation. We showed that surfactin itself promotes cell lysis and DNA release, thereby promoting HGT. These results, therefore, provide evidence for a fundamental mechanism involved in HGT and significantly increase our understanding of the spreading of antibiotic resistance genes and diversification of microbial communities in the environment. [ABSTRACT FROM AUTHOR]

Published

2021

7. ComX-Induced Exoproteases Degrade ComX in Bacillus subtilis PS-216.

Author

Spacapan, Mihael, Danevčič, Tjaša, and Mandic-Mulec, Ines

Subjects

PROTEOLYTIC enzymes, BACILLUS subtilis, EXTRACELLULAR enzymes

Abstract

Gram-positive bacteria use peptides as auto-inducing (AI) signals to regulate the production of extracellular enzymes (e.g., proteases). ComX is an AI peptide, mostly known for its role in the regulation of bacterial competence and surfactant production in Bacillus subtilis. These two traits are regulated accordingly to the bacterial population size, thus classifying ComX as a quorum sensing signal. ComX also indirectly regulates exoprotease production through the intermediate transcriptional regulator DegQ. We here use this peptide-based AI system (the ComQXPA system) as a model to address exoprotease regulation by ComX in biofilms. We also investigate the potential of ComX regulated proteases to degrade the ComX AI peptide. Results indicate that ComX indeed induces the expression of aprE, the gene for the major serine protease subtilisin, and stimulates overall exoprotease production in biofilms of B. subtilis PS-216 and several other B. subtilis soil isolates. We also provide evidence that these exoproteases can degrade ComX. The ComX biological activity decay is reduced in the spent media of floating biofilms with low proteolytic activity found in the comP and degQ mutants. ComX biological activity decay can be restored by the addition of subtilisin to such media. In contrast, inhibition of metalloproteases by EDTA reduces ComX biological activity decay. This suggests that both serine and metalloproteases, which are induced by ComX, are ultimately capable of degrading this signaling peptide. This work brings novel information on regulation of exoproteases in B. subtilis floating biofilms and reveals that these proteolytic enzymes degrade the AI signaling peptide ComX, which is also a major determinant of their expression in biofilms. [ABSTRACT FROM AUTHOR]

Published

2018

8. ComQXPA Quorum Sensing Systems May Not Be Unique to Bacillus subtilis: A Census in Prokaryotic Genomes.

Author

Dogsa, Iztok, Choudhary, Kumari Sonal, Marsetic, Ziva, Hudaiberdiev, Sanjarbek, Vera, Roberto, Pongor, Sándor, and Mandic-Mulec, Ines

Subjects

QUORUM sensing, BACILLUS subtilis, PROKARYOTIC genomes, GRAM-positive bacteria, TRANSFERASES, COMPUTATIONAL biology

Abstract

The comQXPA locus of Bacillus subtilis encodes a quorum sensing (QS) system typical of Gram positive bacteria. It encodes four proteins, the ComQ isoprenyl transferase, the ComX pre-peptide signal, the ComP histidine kinase, and the ComA response regulator. These are encoded by four adjacent genes all situated on the same chromosome strand. Here we present results of a comprehensive census of comQXPA-like gene arrangements in 2620 complete and 6970 draft prokaryotic genomes (sequenced by the end of 2013). After manually checking the data for false-positive and false-negative hits, we found 39 novel com-like predictions. The census data show that in addition to B. subtilis and close relatives, 20 comQXPA-like loci are predicted to occur outside the B. subtilis clade. These include some species of Clostridiales order, but none outside the phylum Firmicutes. Characteristic gene-overlap patterns were observed in comQXPA loci, which were different for the B. subtilis-like and non-B. subtilis-like clades. Pronounced sequence variability associated with the ComX peptide in B. subtilis clade is evident also in the non-B. subtilis clade suggesting grossly similar evolutionary constraints in the underlying quorum sensing systems. [ABSTRACT FROM AUTHOR]

Published

2014

9. Social Interactions and Biofilm Formation in Bacillus subtilis.

Author

Dogsa, Iztok, Oslizlo, Anna, Stefanic, Polonca, and Mandic-Mulec, Ines

Subjects

BACILLUS subtilis, SOCIAL interaction, BIOFILMS, QUORUM sensing, SURFACTIN, EXTRACELLULAR matrix

Abstract

Quorum sensing (QS) is a form of cooperative social behaviour which relies on extra-cellular signalling molecules that elicit the QS response across many cells and controls the development of many cooperative traits including biofilm formation. The main aim of this work is to review the published work on cooperative social behaviour of Bacillus subtilis and especially its QS system ComQXPA. This QS system involves four interacting components: the signal-processing enzyme ComQ, the ComX signal, the ComP receptor and the ComA transcriptional regulator. Phosphorylated ComA controls the transcription of many genes including those responsible for the production of surfactin and extracellular matrix, essential for biofilm formation. The ComQXPA QS shows a high degree of genetic polymorphism, which manifests itself in the separation of Bacillus subtilis strains into four different communication groups (pherotypes). The information exchange is possible between members of the same pherotype but not across pherotypes. We have recently suggested that this phenomenon is at least in part driven by the ecological divergence of strains, but may also be induced by frequency-dependent selection. The ComQXPA QS system controls the production of extracellular matrix (ECM) components: polysaccharides, proteins and nucleic acids. We will address the present understanding of the ECM structure-function relationships in B. subtilis biofilms and review published results on regulation, composition and distribution of ECM components. Despite many important recent discoveries on regulation of B. subtilis biofilm development, we know little about the molecular interactions in the ECM and the role they play in the QS and stability of the biofilm. Future research needs to address these questions better. [ABSTRACT FROM AUTHOR]

Published

2014

10. Social Interactions and Distribution of Bacillus subtilis Pherotypes at Microscale.

Author

Stefanic, Polonca and Mandic-Mulec, Ines

Subjects

*BACILLUS subtilis, *QUORUM sensing, *MICROBIAL genetics, *CELL communication, *GENETIC polymorphisms, *MICROBIOLOGY

Abstract

Bacillus subtilis strains communicate through the comQXPA quorum sensing (QS) system, which regulates genes expressed during early stationary phase. A high polymorphism of comQXP' loci was found in closely related strains isolated from desert soil samples separated by distances ranging from meters to kilometers. The observed polymorphism comprised four communication groups (pherotypes), such that strains belonging to the same pherotype exchanged information efficiently but strains from different pherotypes failed to communicate. To determine whether the same level of polymorphism in the comQXP' QS system could be detected at microscale, B. subtilis isolates were obtained from two separate 1-cm³ soil samples, which were progressively divided into smaller sections. Cross-activation studies using pherotype-responsive reporter strains indicated the same number of communication pherotypes at microscale as previously determined at macroscale. Sequencing of the housekeeping gene gyrA and the QS comQ gene confirmed different evolutionary rates of these genes. Furthermore, an asymmetric communication response was detected inside the two pherotype clusters, suggesting continuous evolution of the QS system and possible development of new languages. To our knowledge, this is the first microscale study demonstrating the presence of different QS languages among isolates of one species, and the implications of this microscale diversity for microbial interactions are discussed. [ABSTRACT FROM AUTHOR]

Published

2009

11. The ComX Quorum Sensing Peptide of Bacillus subtilis Affects Biofilm Formation Negatively and Sporulation Positively.

Author

Špacapan, Mihael, Danevčič, Tjaša, Štefanic, Polonca, Porter, Michael, Stanley-Wall, Nicola R., and Mandic-Mulec, Ines

Subjects

QUORUM sensing, BACILLUS subtilis, EXTRACELLULAR matrix proteins, BIOMASS, MONOSACCHARIDES, BIOFILMS

Abstract

Quorum sensing (QS) is often required for the formation of bacterial biofilms and is a popular target of biofilm control strategies. Previous studies implicate the ComQXPA quorum sensing system of Bacillus subtilis as a promoter of biofilm formation. Here, we report that ComX signaling peptide deficient mutants form thicker and more robust pellicle biofilms that contain chains of cells. We confirm that ComX positively affects the transcriptional activity of the PepsA promoter, which controls the synthesis of the major matrix polysaccharide. In contrast, ComX negatively controls the PtapA promoter, which drives the production of TasA, a fibrous matrix protein. Overall, the biomass of the mutant biofilm lacking ComX accumulates more monosaccharide and protein content than the wild type. We conclude that this QS phenotype might be due to extended investment into growth rather than spore development. Consistent with this, the ComX deficient mutant shows a delayed activation of the pre-spore specific promoter, PspoIIQ, and a delayed, more synchronous commitment to sporulation. We conclude that ComX mediated early commitment to sporulation of the wild type slows down biofilm formation and modulates the coexistence of multiple biological states during the early stages of biofilm development. [ABSTRACT FROM AUTHOR]

Published

2020

12. Corrigendum: ComX-Induced Exoproteases Degrade ComX in <italic>Bacillus subtilis</italic> PS-216.

Author

Spacapan, Mihael, Danevčič, Tjaša, and Mandic-Mulec, Ines

Subjects

BACILLUS subtilis, PROTEOLYTIC enzymes

Published

2018