Project description:Lactococcus lactis is a lactic acid bacterium of major importance for food fermentation and biotechnological applications. The ability to manipulate its genome quickly and easily through competence for DNA transformation would accelerate its general use as a platform for a variety of applications. Natural transformation in this species requires the activation of the master regulator ComX. However, the growth conditions that lead to spontaneous transformation, as well as the regulators that control ComX production, are unknown. Here, we identified the carbon source, nitrogen supply, and pH as key factors controlling competence development in this species. Notably, we showed that these conditions are sensed by three global regulators (i.e., CcpA, CodY, and CovR), which repress comX transcription directly. Furthermore, our systematic inactivation of known signaling systems suggests that classical pheromone-sensing regulators are not involved. Finally, we discovered that the ComX-degrading MecA-ClpCP machinery plays a predominant role based on the identification of a single amino-acid substitution in the adaptor protein MecA of a highly transformable strain. Contrasting with closely-related streptococci, the master competence regulator in L. lactis is regulated both proximally by general sensors and distantly by the Clp degradation machinery. This study not only highlights the diversity of regulatory networks for competence control in Gram-positive bacteria, but it also paves the way for the use of natural transformation as a tool to manipulate this biotechnologically important bacterium.

Project description:In marine Vibrio species, chitin-induced natural transformation enables bacteria to take up DNA from the external environment and integrate it into their genome via homologous recombination. Expression of the master competence regulator TfoX bypasses the need for chitin induction and drives expression of the genes required for competence in several Vibrio species. Here, we show that TfoX expression in two Vibrio campbellii strains, DS40M4 and NBRC 15631, enables high frequencies of natural transformation. Conversely, transformation was not achieved in the model quorum-sensing strain V. campbellii BB120 (previously classified as Vibrio harveyi). Surprisingly, we find that quorum sensing is not required for transformation in V. campbellii DS40M4. This result is in contrast to Vibrio cholerae that requires the quorum-sensing regulator HapR to activate the competence regulator QstR. However, similar to V. cholerae, QstR is necessary for transformation in DS40M4. To investigate the difference in transformation frequencies between BB120 and DS40M4, we used previously studied V. cholerae competence genes to inform a comparative genomics analysis coupled with transcriptomics. BB120 encodes homologs of all known competence genes, but most of these genes were not induced by ectopic expression of TfoX, which likely accounts for the non-functional natural transformation in this strain. Comparison of transformation frequencies among Vibrio species indicates a wide disparity among even closely related strains, with Vibrio vulnificus having the lowest functional transformation frequency. We show that ectopic expression of both TfoX and QstR is sufficient to produce a significant increase in transformation frequency in Vibrio vulnificus.

Project description:BACKGROUND: Streptococcus mutans, the etiological agent of human dental caries, displays complex regulation of natural genetic competence. Competence development in S. mutans is controlled by a peptide derived from ComS (comX inducing peptide, XIP); which along with the cytosolic regulator ComR controls the expression of the alternative sigma factor comX, the master regulator of competence development. ComR-XIP controls the expression of both PcomX and PcomS, with the latter creating a positive feedback loop. Recently, a gene embedded within the coding region of comX was discovered and designated xrpA (comX regulatory peptide A). XrpA was found to be an antagonist of ComX, but the mechanism was not established. In this study, we began to dissect how XrpA exerts control over competence development in S. mutans. METHODS: RNA-Seq was utilized to compare the transcriptomes of S. mutans wild-type strain UA159 (3 replicates), UA159 with addition of 2 uM sXIP (3 replicates) and with a mutant of xrpA (comX::T162C; 3 replicates). Strains were grown to OD600 nm = 0.5 in FMC medium before harvest. sXIP was added at OD600 nm = 0.2. Deep sequencing was performed at the University of Florida ICBR facilities (Gainesville, FL). Approximately 20 million short-reads were obtained for each sample. After removing adapter sequences from each short-read and trimming of the 3’-ends by quality scores (59), the resulting sequences were mapped onto the reference genome of strain UA159 (GenBank accession no. AE014133) using the short-read aligner. Mapped short-read alignments were then converted into readable formats using SAMTOOLS. RESULTS: Using an optimzed data analysis workflow, we mapped 14-19 million reads per sample to the genome of UA159. For viewing of the mapped reads aligned to the genome, .bam files were uploaded into the Integrative Genomics Viewer (IGV – version 2.3.55) (61). A .csv file containing raw read counts for each replicate (3) was then uploaded to Degust (http://degust.erc.monash.edu/) and edgeR analysis performed to determine Log2 fold change and a false discovery rate (FDR). Comparison of the transcriptome by RNA-Seq of the wild-type with the mutant lacking XrpA revealed 56 differentially expressed genes, with 34 upregulated in xrpA and 22 downregulated. Many of the upregulated genes were competence-related genes, including comX and genes that are a part of the ComX regulon of S. mutans . Since loss of xrpA caused upregulation of competence genes, we also analyzed the transcriptome of UA159 treated with 2 uM sXIP to induce competence, with UA159 treated with vehicle (DMSO) as a control. Cells treated with sXIP had 137 genes differentially expressed compared to the DMSO control. CONCLUSIONS: Collectively, these data reveal that the novel regulator XrpA exerts its influence over competence development by impacting ComRS functions, resulting in decreased expression of comX and late com gene expression that negatively impact transformability. These results highlight XrpA as a new negative regulator of competence signaling as well as broaden our understanding of the complex regulatory mechanisms that modulate competence and virulence in S. mutans.

Project description:Small distortions in transcriptional networks might lead to drastic phenotypical changes, especially in cellular developmental programs such as competence for natural transformation. Here, we report a pervasive circuitry rewiring for competence and predation interplay in commensal streptococci. Canonically, in model species of streptococci such as Streptococcus pneumoniae and Streptococcus mutans, the pheromone-based two-component system BlpRH is a central node that orchestrates the production of antimicrobial compounds (bacteriocins) and incorporates signal from the competence activation cascade. However, the human commensal Streptococcus salivarius does not contain a functional BlpRH pair and in this species, the competence signaling system ComRS directly couples bacteriocin production and competence commitment. This network shortcut might account for an optimal reaction against microbial competitors and could explain the high prevalence of S. salivarius in the human digestive tract. Moreover, the broad spectrum of bacteriocin activity against pathogenic bacteria showcases the commensal and genetically tractable S. salivarius species as a user-friendly model for natural transformation and bacterial predation.

Project description:Transcriptional profiling of the competence-stimulating peptide (CSP) response in Streptococcus mutans of FACS-separated subpopulations and mixed cells of a clonal culture. CSP-mediated competence development in S. mutans is a transient and biphasic process since only a subpopulation induces expression of ComX in the presence of CSP and activation of the DNA uptake machinery in this fraction shuts down ~3-4 hours post induction. Here we combine, for the first time in bacteria to our knowledge, flow cytometric sorting of cells and subpopulation-specific transcriptome analysis of both the competent and non-competent fractions of CSP-treated S. mutans cells. Sorting was guided by a ComX-GFP reporter and the transcriptome analysis demonstrated the successful combination of both methods because a strong enrichment of transcripts for comX and its downstream genes was achieved. Three two-component systems were expressed in the competent fraction, among them ComDE. Moreover, the recently identified regulator system ComR/S was expressed exclusively in the competent fraction. By contrast, expression of bacteriocin-related genes was at the same level in all cells. GFP reporter strains for ComE and mutacin V confirmed this expression pattern on the single cell level. Fluorescence microscopy revealed that some ComX-expressing cells committed autolysis in an early stage of competence initiation. In viable ComX-expressing cells, uptake of DNA could be shown on the single cell level. This study demonstrates that all cells in the population respond to CSP through activation of bacteriocin-related genes but that two subpopulations segregate, one becoming competent and another one that lyses, resulting in intrapopulation diversity of the clonal culture. Two conditions: induced and not induced with CSP. Three induced cell populations: competent subpopulation, incompetent subpopulation, all cells. Two biological replicates each population.

Project description:To perform natural transformation, one of the three main Horizontal Gene Transfer mechanisms, bacteria need to enter a physiological differentiated state called genetic competence. Interestingly, new bacteria displaying such aptitude are often discovered, and one of the latest is the human pathogen Staphylococcus aureus. Here, we developed a new protocol, based on planktonic cells cultures, leading to a large percentage of the population activating competence development and a significant improvement of S. aureus natural transformation efficiencies. Taking advantage of these new conditions, we performed transcriptomics analyses to characterize each central competence regulators regulon. SigH and ComK1 were both found essential for activating natural transformation genes but also important for activation or repression of peripheral functions. Even though ComK2 was not found important for the control of transformation genes, its regulon showed an important overlap with that of SigH and ComK1. Finally, we showed how microaerobic conditions, sensed by the SrrAB two-component system, was key to activate competence in S. aureus.

Project description:Pangenome arrays contain DNA oligomers targeting several sequenced reference genomes from the same species. In microbiology these can be employed to investigate the often high genetic variability within a species by comparative genome hybridization (CGH). The biological interpretation of pangenome CGH data depends on the ability to compare strains at a functional level, particularly by comparing the presence or absence of orthologous genes. Due to the high genetic variability, available genotype-calling algorithms can not be applied to pangenome CGH data. Therefore, we have developed the algorithm PanCGH that incorporates orthology information about genes to predict the presence or absence of orthologous genes in a query organism using CGH arrays that target the genomes of sequenced representatives of a group of microorganisms. PanCGH was tested and applied in the analysis of genetic diversity among 39 Lactococcus lactis strains from three different subspecies (lactis, cremoris, hordniae) and isolated from two different niches (dairy and plant). Clustering of these strains using the presence/absence data of gene orthologs revealed a clear separation between different subspecies and reflected the niche of the strains. Keywords: CGH, CGH analysis, orthology, Lactococcus lactis We analyzed 39 CGH arrays, where on each array different strain of L. lactis was hybridized.

Project description:Transcriptional profiling of the competence-stimulating peptide (CSP) response in Streptococcus mutans of FACS-separated subpopulations and mixed cells of a clonal culture. CSP-mediated competence development in S. mutans is a transient and biphasic process since only a subpopulation induces expression of ComX in the presence of CSP and activation of the DNA uptake machinery in this fraction shuts down ~3-4 hours post induction. Here we combine, for the first time in bacteria to our knowledge, flow cytometric sorting of cells and subpopulation-specific transcriptome analysis of both the competent and non-competent fractions of CSP-treated S. mutans cells. Sorting was guided by a ComX-GFP reporter and the transcriptome analysis demonstrated the successful combination of both methods because a strong enrichment of transcripts for comX and its downstream genes was achieved. Three two-component systems were expressed in the competent fraction, among them ComDE. Moreover, the recently identified regulator system ComR/S was expressed exclusively in the competent fraction. By contrast, expression of bacteriocin-related genes was at the same level in all cells. GFP reporter strains for ComE and mutacin V confirmed this expression pattern on the single cell level. Fluorescence microscopy revealed that some ComX-expressing cells committed autolysis in an early stage of competence initiation. In viable ComX-expressing cells, uptake of DNA could be shown on the single cell level. This study demonstrates that all cells in the population respond to CSP through activation of bacteriocin-related genes but that two subpopulations segregate, one becoming competent and another one that lyses, resulting in intrapopulation diversity of the clonal culture.

Project description:Transcriptional profiling of the M-NM-^T835np mutant vs the wild-type strain grown in BHI to OD600=0.5. An intimate linkage between the regulation of biofilm formation, stress tolerance and genetic competence exists in the dental caries pathogen Streptococcus mutans. We previously reported that the rcrRPQ genes, which encode ABC exporters (RcrPQ) and a MarR-family transcriptional regulator (RcrR) that represses the expression of the rcr operon, play a dominant role in regulation of development of genetic competence and connect competence with stress tolerance and (p)ppGpp production in S. mutans. Here we identify the region required for efficient RcrR binding to the rcr promoter region using purified recombinant RcrR (rRcrR) protein in electrophoretic mobility shift and fluorescence polarization assays. DNA fragments carrying mutations in the binding region resulted in decreased binding of rRcrR. Direct binding of RcrR to the comX gene promoter in vitro revealed that RcrR has the potential to directly regulate competence development. Likewise, direct interactions of rRcrR with the promoter region of relP, encoding a (p)ppGpp synthase, show the potential for RcrR-dependent modulation of (p)ppGpp pools. Introduction of mutations into the RcrR binding sites in the rcrR promoter region in vivo demonstrated that optimal RcrR binding is essential for proper expression of competence genes and optimal transformation efficiency. Transcription profiling by RNA-seq and mircroarrays of strains with mutations in rcrR showed that genes in the competence pathway were those most differentially expressed. Thus, here and in a accompanying paper, we establish mechanisms by which the products of the rcrRPQ operon integrate com gene expression, genetic transformation, ppGpp metabolism and stress tolerance in S. mutans Two-condition experiment, M-NM-^T835np mutant vs the wild-type strain. Biological replicates: 4 per strain, independently grown and harvested. One replicate per array

Project description:Transcriptomic analysis of Lactococcus lactis ssp. cremoris KW2 after ComX constitutive production