Polymyxin resistance in Enterobacter cloacae complex in Brazil: phenotypic and molecular characterization.

Enterobacter cloacae complex isolates have been reported as an important nosocomial multidrug resistance pathogen. In the present study, we investigated antimicrobial susceptibility and the colistin-resistance rates, their genetic determinants and clonality among clinical E. cloacae complex isolates from different Brazilian states. For this, an initial screening was carried out on 94 clinical isolates of E. clocacae complex received between 2016 and 2018 by LAPIH-FIOCRUZ, using EMB plates containing 4 µg/mL of colistin, followed MIC determination, resulting in the selection of 26 colistin-resistant isolates from the complex. The presence of carbapenemases encoding genes (blaKPC, blaNDM and blaOXA-48), plasmidial genes for resistance to polymyxins (mcr1-9) and mutations in chromosomal genes (pmrA, pmrB, phoP and phoQ) described as associated with resistance to polymyxin were screened by PCR and DNA sequencing. Finally, the hsp60 gene was sequenced to identify species of the E. cloacae complex and genetic diversity was evaluated by PFGE and MLST. The results have shown that among 94 E. cloacae complex isolates, 19 (20.2%) were colistin-resistant. The resistant strains exhibited MIC ranging from 4 to 128 µg / mL and E. hormaechei subsp. steigerwaltii was the prevalent species in the complex (31,6%), followed by E. cloacae subsp. cloacae (26,3%). The antimicrobials with the highest susceptibility rate were gentamicin (21%) and tigecycline (26%). Carbapenemases encoding genes (blaKPC n = 5, blaNDM n = 1) were detected in 6 isolates and mcr-9 in one. Among the modifications found in PmrA, PmrB, PhoP e PhoQ (two-component regulatory system), only the S175I substitution in PmrB found in E. cloacae subsp cloacae isolates were considered deleterious (according to the prediction of PROVEAN). By PFGE, 13 profiles were found among E. cloacae complex isolates, with EcD the most frequent. Furthermore, by MLST 10 ST's, and 1 new ST, were identified in E. cloacae. In conclusion, no prevalence of clones or association among carbapenemase production and polymyxin resistance was found between the E. cloacae. Thereby, the results suggest that the increased polymyxin-resistance is related to the selective pressure exerted by the indiscriminate use in hospitals. Lastly, this study highlights the urgent need to elucidate the mechanism involved in the resistance to polymyxin in the E. cloacae complex and the development of measures to control and prevent infections caused by these multiresistant bacteria.

Phylogenetic classification of natural product biosynthetic gene clusters based on regulatory mechanisms.

The natural products (NPs) biosynthetic gene clusters (BGCs) represent the adapting biochemical toolkit for microorganisms to thrive different microenvironments. Despite their high diversity, particularly at the genomic level, detecting them in a shake-flask is challenging and remains the primary obstacle limiting our access to valuable chemicals. Studying the molecular mechanisms that regulate BGC expression is crucial to design of artificial conditions that derive on their expression. Here, we propose a phylogenetic analysis of regulatory elements linked to biosynthesis gene clusters, to classify BGCs to regulatory mechanisms based on protein domain information. We utilized Hidden Markov Models from the Pfam database to retrieve regulatory elements, such as histidine kinases and transcription factors, from BGCs in the MIBiG database, focusing on actinobacterial strains from three distinct environments: oligotrophic basins, rainforests, and marine environments. Despite the environmental variations, our isolated microorganisms share similar regulatory mechanisms, suggesting the potential to activate new BGCs using activators known to affect previously characterized BGCs.

A bvrR/bvrS Non-Polar Brucella abortus Mutant Confirms the Role of the Two-Component System BvrR/BvrS in Virulence and Membrane Integrity.

Brucella abortus is a bacterial pathogen causing bovine brucellosis worldwide. This facultative extracellular-intracellular pathogen can be transmitted to humans, leading to a zoonotic disease. The disease remains a public health concern, particularly in regions where livestock farming is present. The two-component regulatory system BvrR/BvrS was described by isolating the attenuated transposition mutants bvrR::Tn5 and bvrS::Tn5, whose characterization led to the understanding of the role of the system in bacterial survival. However, a phenotypic comparison with deletion mutants has not been performed because their construction has been unsuccessful in brucellae and difficult in phylogenetically related Rhizobiales with BvrR/BvrS orthologs. Here, we used an unmarked gene excision strategy to generate a B. abortus mutant strain lacking both genes, called B. abortus ∆bvrRS. The deletion was verified through PCR, Southern blot, Western blot, Sanger sequencing, and whole-genome sequencing, confirming a clean mutation without further alterations at the genome level. B. abortus ∆bvrRS shared attenuated phenotypic traits with both transposition mutants, confirming the role of BvrR/BvrS in pathogenesis and membrane integrity. This B. abortus ∆bvrRS with a non-antimicrobial marker is an excellent tool for continuing studies on the role of BvrR/BvrS in the B. abortus lifestyle.

Phenotypes controlled by the Brucella abortus two component system BvrR/BvrS are differentially impacted by BvrR phosphorylation.

Brucella abortus is a zoonotic pathogen whose virulence depends on its ability to survive intracellularly at the endoplasmic reticulum derived compartment. The two-component system BvrR/BvrS (BvrRS) is essential for intracellular survival due to the transcriptional control of the type IV secretion system VirB and its transcriptional regulator VjbR. It is a master regulator of several traits including membrane homeostasis by controlling gene expression of membrane components, such as Omp25. BvrR phosphorylation is related to DNA binding at target regions, thereby repressing or activating gene transcription. To understand the role of BvrR phosphorylation we generated dominant positive and negative versions of this response regulator, mimicking phosphorylated and non-phosphorylated BvrR states and, in addition to the wild-type version, these variants were introduced in a BvrR negative background. We then characterized BvrRS-controlled phenotypes and assessed the expression of proteins regulated by the system. We found two regulatory patterns exerted by BvrR. The first pattern was represented by resistance to polymyxin and expression of Omp25 (membrane conformation) which were restored to normal levels by the dominant positive and the wild-type version, but not the dominant negative BvrR. The second pattern was represented by intracellular survival and expression of VjbR and VirB (virulence) which were, again, complemented by the wild-type and the dominant positive variants of BvrR but were also significantly restored by complementation with the dominant negative BvrR. These results indicate a differential transcriptional response of the genes controlled to the phosphorylation status of BvrR and suggest that unphosphorylated BvrR binds and impacts the expression of a subset of genes. We confirmed this hypothesis by showing that the dominant negative BvrR did not interact with the omp25 promoter whereas it could interact with vjbR promoter. Furthermore, a global transcriptional analysis revealed that a subset of genes responds to the presence of the dominant negative BvrR. Thus, BvrR possesses diverse strategies to exert transcriptional control on the genes it regulates and, consequently, impacting on the phenotypes controlled by this response regulator.

Corrigendum: Identification of novel thermosensors in gram-positive pathogens.

[This corrects the article DOI: 10.3389/fmolb.2020.592747.].

Intracellular Passage Triggers a Molecular Response in Brucella abortus That Increases Its Infectiousness.

Brucella abortus is a facultatively extracellular-intracellular pathogen that encounters a diversity of environments within the host cell. We report that bacteria extracted from infected cells at late stages (48 h postinfection) of the intracellular life cycle significantly increase their ability to multiply in new target cells. This increase depends on early interaction with the cell surface, since the bacteria become more adherent and penetrate more efficiently than in vitro-grown bacteria. At this late stage of infection, the bacterium locates within an autophagosome-like compartment, facing starvation and acidic conditions. At this point, the BvrR/BvrS two-component system becomes activated, and the expression of the transcriptional regulator VjbR and the type IV secretion system component VirB increases. Using bafilomycin to inhibit BvrR/BvrS activation and using specific inhibitors for VjbR and VirB, we showed that the BvrR/BvrS and VjbR systems correlate with increased interaction with new host cells, while the VirB system does not. Bacteria released from infected cells under natural conditions displayed the same phenotype as intracellular bacteria. We propose a model in which the B. abortus BvrR/BvrS system senses the transition from its replicative niche at the endoplasmic reticulum to the autophagosome-like exit compartment. This activation leads to the expression of VirB, which participates in the release of the bacterium from the cells, and an increase in VjbR expression that results in a more efficient interaction with new host cells.

Gene Expression Analysis of Microtubers of Potato Solanum tuberosum L. Induced in Cytokinin Containing Medium and Osmotic Stress.

Potato microtuber productions through in vitro techniques are ideal propagules for producing high quality seed potatoes. Microtuber development is influenced by several factors, i.e., high content sucrose and cytokinins are among them. To understand a molecular mechanism of microtuberization using osmotic stress and cytokinin signaling will help us to elucidate this process. We demonstrate in this work a rapid and efficient protocol for microtuber development and gene expression analysis. Medium with high content of sucrose and gelrite supplemented with 2iP as cytokinin under darkness condition produced the higher quantity and quality of microtubers. Gene expression analysis of genes involved in the two-component signaling system (StHK1), cytokinin signaling, (StHK3, StHP4, StRR1) homeodomains (WUSCHEL, POTH1, BEL5), auxin signaling, ARF5, carbon metabolism (TPI, TIM), protein synthesis, NAC5 and a morphogenetic regulator of tuberization (POTH15) was performed by qPCR real time. Differential gene expression was observed during microtuber development. Gene regulation of two component and cytokinin signaling is taking place during this developmental process, yielding more microtubers. Further analysis of each component is required to elucidate it.

Activation of regulator ArcA in the presence of hypochlorite in Salmonella enterica serovar Typhimurium.

Oxidative stress is the main mechanism behind efficient disinfectants, causing damage in bacterial macromolecules. Importantly, bacteria activate resistance mechanisms in response to damage generated by oxidative stress. Strategies allowing pathogens to survive oxidative stress are highly conserved among microorganisms. Many of these strategies entail genomic responses triggered by signals transduced through Two Component Systems (TCS). Recently, we demonstrated that the TCS ArcAB (specifically ArcA) participates in bacterial responses to hypochlorite, regulating the uptake of this toxic compound and being involved in resistance and survival inside neutrophils, where hypochlorous acid abounds. Here, we demonstrated that ArcA is required in the response to oxidative stress generated by hypochlorite, independent of its cognate sensor ArcB or the Asp54 of ArcA, the only phosphorylable residue in ArcA, which is required to function as a gene regulator. Our results suggest that ArcA could have additional functions to respond to oxidative stress, independent of its regulatory activity, which might require interaction with other unknown relevant proteins.

Identification of Novel Thermosensors in Gram-Positive Pathogens.

Temperature is a crucial variable that every living organism, from bacteria to humans, need to sense and respond to in order to adapt and survive. In particular, pathogenic bacteria exploit host-temperature sensing as a cue for triggering virulence gene expression. Here, we have identified and characterized two integral membrane thermosensor histidine kinases (HKs) from Gram-positive pathogens that exhibit high similarity to DesK, the extensively characterized cold sensor histidine kinase from Bacillus subtilis. Through in vivo experiments, we demonstrate that SA1313 from Staphylococcus aureus and BA5598 from Bacillus anthracis, which likely control the expression of putative ATP binding cassette (ABC) transporters, are regulated by environmental temperature. We show here that these HKs can phosphorylate the non-cognate response regulator DesR, partner of DesK, both in vitro and in vivo, inducing in B. subtilis the expression of the des gene upon a cold shock. In addition, we report the characterization of another DesK homolog from B. subtilis, YvfT, also closely associated to an ABC transporter. Although YvfT phosphorylates DesR in vitro, this sensor kinase can only induce des expression in B. subtilis when overexpressed together with its cognate response regulator YvfU. This finding evidences a physiological mechanism to avoid cross talk with DesK after a temperature downshift. Finally, we present data suggesting that the HKs studied in this work appear to monitor different ranges of membrane lipid properties variations to mount adaptive responses upon cooling. Overall, our findings point out that bacteria have evolved sophisticated mechanisms to assure specificity in the response to environmental stimuli. These findings pave the way to understand thermosensing mediated by membrane proteins that could have important roles upon host invasion by bacterial pathogens.

Molecular and genome characterization of colistin-resistant Escherichia coli isolates from wild sea lions (Zalophus californianus).

Using molecular and whole-genome sequencing tools, we investigated colistin-resistant Escherichia coli isolates from wild sea lions. Two unrelated E. coli colistin-resistant isolates, ST8259 and ST4218, were identified, both belonging to the B2 phylogroup and different serotypes. Polymorphisms in PmrA, PmrB, and PhoQ proteins were identified, and the role of PmrB and PhoQ in contributing to colistin resistance was determined by complementation assays. However, the mutations characterized in the present study are not involved in colistin resistance, which have been described in E. coli isolates from clinical settings. Therefore, the acquired mutations in pmrB and phoQ genes in resistance to colistin in bacteria related to marine environment animals are different. This work contributes to the surveillance and characterization of colistin resistance in Escherichia coli obtained from animals from aquatic environments.

PepO is a target of the two-component systems VicRK and CovR required for systemic virulence of Streptococcus mutans.

Streptococcus mutans, a cariogenic species, is often associated with cardiovascular infections. Systemic virulence of specific S. mutans serotypes has been associated with the expression of the collagen- and laminin-binding protein Cnm, which is transcriptionally regulated by VicRK and CovR. In this study, we characterized a VicRK- and CovR-regulated gene, pepO, coding for a conserved endopeptidase. Transcriptional and protein analyses revealed that pepO is highly expressed in S. mutans strains resistant to complement immunity (blood isolates) compared to oral isolates. Gel mobility assay, transcriptional, and Western blot analyses revealed that pepO is repressed by VicR and induced by CovR. Deletion of pepO in the Cnm+ strain OMZ175 (OMZpepO) or in the Cnm- UA159 (UApepO) led to an increased susceptibility to C3b deposition, and to low binding to complement proteins C1q and C4BP. Additionally, pepO mutants showed diminished ex vivo survival in human blood and impaired capacity to kill G. mellonella larvae. Inactivation of cnm in OMZ175 (OMZcnm) resulted in increased resistance to C3b deposition and unaltered blood survival, although both pepO and cnm mutants displayed attenuated virulence in G. mellonella. Unlike OMZcnm, OMZpepO could invade HCAEC endothelial cells. Supporting these phenotypes, recombinant proteins rPepO and rCnmA showed specific profiles of binding to C1q, C4BP, and to other plasma (plasminogen, fibronectin) and extracellular matrix proteins (type I collagen, laminin). Therefore this study identifies a novel VicRK/CovR-target required for immune evasion and host persistence, pepO, expanding the roles of VicRK and CovR in regulating S. mutans virulence.

Expressão e atividade de sistemas de dois componentes (TCS) de Salmonella enterica sorovar Typhimurium no contexto do metaboloma intestinal humano / Expression and activity of two-component systems of Salmonella enterica sorovar Typhimurium in the context of the human intestinal metabolome

A interação entre membros do microbioma intestinal humano, células hospedeiras e patógenos invasores pode ocorrer de diversas formas, sendo uma delas através de pequenas moléculas chamadas metabólitos. A percepção e resposta efetiva de um microrganismo às diferentes condições encontradas em seu ambiente, incluindo metabólitos produzidos por outros microrganismos, são fatores importantes para sua adaptação, sobrevivência e disseminação. Os sistemas de dois componentes (TCS) permitem a percepção e resposta a mudanças ambientais, regulando a expressão de genes específicos. Nosso grupo mostrou anteriormente que um extrato orgânico de fezes humanas (EF), bem como o ácido 3,4-dimetilbenzoico (3,4-DMB), encontrado no EF, inibe a capacidade de Salmonella enterica sorovar Typhimurium de invadir células hospedeiras. O presente trabalho propôs investigar o impacto do microbioma intestinal humano, bem como de pequenas moléculas produzidas por Clostridium citroniae (membro deste microbioma) na expressão e atividade dos genes de TCS de Salmonella. Os metabólitos de EF e de culturas puras de C. citroniae foram extraídos com acetato de etila e adicionados a meio de cultura. O pH do meio foi ajustado (~ 7,4) e a solução foi esterilizada por filtragem. Salmonella foi cultivada na presença ou ausência do EF e do extrato de C. citroniae, bem como do ácido 3,4-DMB, em condições aeróbias e anaeróbias, até alcançar o meio da fase logarítmica de crescimento. O RNA foi extraído para a realização de PCR em Tempo Real utilizando iniciadores direcionados a quase todos os TCS de Salmonella. Nossos resultados mostraram que vários genes de TCS envolvidos na virulência de Salmonella (SsrAB, EnvZ-OmpR, QseCB, PhoQP, TorSR, TtrRS) foram regulados diferencialmente por esses metabólitos, tanto em condições aeróbias quanto anaeróbias. EnvZ-OmpR, PhoPQ e SsrAB estão diretamente envolvidos na regulação das Ilhas de Patogenicidade 1 e 2 de Salmonella. QseCB é crucial para a detecção de quorum em Salmonella, de hormônios hospedeiros e para a regulação da motilidade (swimming). Vários outros TCS também foram regulados, incluindo TorSR e TtrRS, envolvidos na regulação da respiração anaeróbica de N-óxido de trimetilamina (TMAO) e tetrationato, respectivamente. Esses compostos são importantes para a sobrevivência de Salmonella no ambiente anaeróbico do intestino humano. Nossos resultados de avaliação de expressão gênica global de Salmonella cultivada na presença de ácido 3,4-DMB (aerobiose e anaerobiose) bem como na presença do EF em anaerobiose, mostraram que genes condificados em SPI-1 e SPI-2, SPI-4 e alguns genes do TCS foram reprimidos, enquanto genes marR, marB e marA foram ativadas nessas condições. Adicionalmente, comparamos nossos resultados de RNAseq, de Salmonella cultivada na presença do ácido 3,4-DMB em aerobiose, com resultados disponíveis da base de dados Salmonella Compendium. Ainda, a capacidade de Salmonella de adentrar e sobreviver dentro de células fagocíticas (macrófagos RAW 264.7) parece ser afetada pelas três condições testadas neste trabalho. Nossos resultados mostram que importantes vias de sinalização da virulência de Salmonella podem ser moduladas pelos metabólitos presentes no microbioma intestinal humano e abrem caminhos para novas pesquisas sobre a sinalização intercelular microbioma-patógeno no ambiente intestinal.

The interaction between members of the human gut microbiome, host cells and invading pathogens often occurs through small molecules, also called metabolites. The perception and effective response of a microorganism to the different conditions found in its environment, including metabolites produced by other microbes, is important for its adaptation, survival and dissemination. Two-component systems (TCS) allow the perception and response to environmental changes by regulating the expression of specific genes. Our group previously showed that organic extracts of human feces (EF) as well as the specific metabolite 3,4-dimethylbenzoic acid (3,4-DMB) found within the EF, inhibit the ability of Salmonella enterica sorovar Typhimurium to invade host cells. In the present work, we investigated the impact of the human gut microbiome as well as small molecules produced by Clostridium citroniae (a member of this microbiome) on the expression and activity of Salmonella TCS genes. Metabolites (from feces or C. citroniae cultures) were extracted using ethyl acetate and added to culture medium. The pH of the medium was adjusted (~7.4), and the solution was filter sterilized. Salmonella was grown in the presence or absence of the organic extracts as well as 3,4-DMB acid under aerobic and anaerobic conditions until it reached mid-log growth. RNA was then extracted for Real-time PCR using primers targeting almost all Salmonella TCS. Our results showed that several TCS involved in Salmonella virulence (SsrAB, EnvZ-OmpR, QseCB, PhoQP, TorSR, TtrRS) were differentially regulated by these metabolites both in aerobic and anaerobic conditions. EnvZ-OmpR, PhoPQ, and SsrAB are directly involved in the regulation of Salmonella Pathogenicity Islands 1 and 2. QseCB is crucial for Salmonella =quorum sensing, sensing of host hormones and regulation of swimming motility. Several other TCS were also regulated, including TorSR and TtrRS, which are involved in the anaerobic respiration of trimethylamine N-oxide (TMAO) and tetrathionate, respectively. These compounds are important for Salmonella survival in the anaerobic environment of the human gut. Our results of the evaluation of global Salmonella gene expression grown in the presence of 3,4-DMB acid (aerobiosis and anaerobiosis) as well as in the presence of EF in anaerobiosis, showed that genes encoded in SPI-1 and SPI-2, SPI-4 and some TCS genes have been repressed, while multiple drug resistance genes, as well marR, marB and marA genes have been activated under these conditions. Besides, we compared our results of RNAseq, Salmonella was grown in the presence of 3,4-DMB acid in aerobiosis, with results available from the Salmonella Compendium database. Also, Salmonella's ability to enter and survive within phagocytic cells (macrophages RAW 264.7) appears to be affected by the three conditions tested in this work. Our results show that important Salmonella virulence signalling pathways can be modulated by the metabolites present in the human intestinal microbiome and open the way for further research on the microbiome-pathogen intercellular signalling in the intestinal environment.

Quinazoline-Based Antivirulence Compounds Selectively Target Salmonella PhoP/PhoQ Signal Transduction System.

The rapid emergence of multidrug resistance among bacterial pathogens has become a significant challenge to human health in our century. Therefore, development of next-generation antibacterial compounds is an urgent need. Two-component signal transduction systems (TCS) are stimulus-response coupling devices that allow bacteria to sense and elaborate adaptive responses to changing environmental conditions, including the challenges that pathogenic bacteria face inside the host. The differential presence of TCS, present in bacteria but absent in the animal kingdom, makes them attractive targets in the search for new antibacterial compounds. In Salmonella enterica, the PhoP/PhoQ two-component system controls the expression of crucial phenotypes that define the ability of the pathogen to establish infection in the host. We now report the screening of 686 compounds from a GlaxoSmithKline published kinase inhibitor set in a high-throughput whole-cell assay that targets Salmonella enterica serovar Typhimurium PhoP/PhoQ. We identified a series of quinazoline compounds that showed selective and potent downregulation of PhoP/PhoQ-activated genes and define structural attributes required for their efficacy. We demonstrate that their bioactivity is due to repression of the PhoQ sensor autokinase activity mediated by interaction with its catalytic domain, acting as competitive inhibitors of ATP binding. While noncytotoxic, the hit molecules exhibit antivirulence effect by blockage of S Typhimurium intramacrophage replication. Together, these features make these quinazoline compounds stand out as exciting leads to develop a therapeutic intervention to fight salmonellosis.

The histidine kinase slnCl1 of Colletotrichum lindemuthianum as a pathogenicity factor against Phaseolus vulgaris L.

Colletotrichum lindemuthianum, the causal agent of anthracnose, is responsible for significant damage in the common bean (Phaseolus vulgaris L.). Unraveling the genetic mechanisms involved in the plant/pathogen interaction is a powerful approach for devising efficient methods to control this disease. In the present study, we employed the Restriction Enzyme-Mediated Integration (REMI) methodology to identify the gene slnCl1, encoding a histidine kinase protein, as involved in pathogenicity. The mutant strain, MutCl1, generated by REMI, showed an insertion in the slnCl1 gene, deficiency of the production and melanization of appressoria, as well as the absence of pathogenicity on bean leaves when compared with the wild-type strain. The slnCl1 gene encodes a histidine kinase class IV called SlnCl1 showing identity of 97% and 83% with histidine kinases from Colletotrichum orbiculare and Colletotrichum gloesporioides, respectively. RNA interference was used for silencing the histidine kinase gene and confirm slnCl1 as a pathogenicity factor. Furthermore, we identified four major genes involved in the RNA interference-mediated gene silencing in Colletotrichum spp. and demonstrated the functionality of this process in C. lindemuthianum. Silencing of the EGFP reporter gene and slnCl1 were demonstrated using qPCR. This work reports for the first time the isolation and characterization of a HK in C. lindemuthianum and the occurrence of gene silencing mediated by RNA interference in this organism, demonstrating its potential use in the functional characterization of pathogenicity genes.

Oxygen triggers signal transduction in the DevS (DosS) sensor of Mycobacterium tuberculosis by modulating the quaternary structure.

A major challenge to the control and eventual eradication of Mycobacterium tuberculosis infection is this pathogen's prolonged dormancy. The heme-based oxygen sensor protein DevS (DosS) plays a key role in this phenomenon, because it is a major activator of the transcription factor DevR. When DevS is active, its histidine protein kinase region is ON and it phosphorylates and activates DevR, which can induce the transcription of the dormancy regulon genes. Here, we have investigated the mechanism by which the ligation of molecular oxygen to a heme-binding domain in DevS switches OFF its histidine protein kinase region. To shed light on the oligomerization states of this protein and possible protein-surfaces of interaction, we used analytical gel filtration, together with dynamic light scattering, fluorescence spectroscopy and chemical crosslinking. We found that DevS exists as three major species: an octamer, a tetramer and a dimer. These three states were observed for the concentration range between 0.5 and 20 µm DevS, but not below 0.1 µm. Levels of DevS in M. tuberculosis are expected to range from 5 to 26 µm. When this histidine protein kinase was OFF, the DevS was mainly tetrameric and dimeric; by contrast, when the kinase was ON, the protein was predominantly octameric. The changes in quaternary structure were rapid upon binding to the physiological signal. This finding represents a novel strategy for switching the activity of a two-component heme-based sensor. An enhanced understanding of this process might potentially lead to the design of novel regulatory agents that target the multimer interfaces for treatment of latent tuberculosis.

Crystallization and initial X-ray diffraction analysis of the multi-domain Brucella blue light-activated histidine kinase LOV-HK in its illuminated state.

The pathogenic bacterium Brucella abortus codes for a multi-domain dimeric cytoplasmic histidine kinase called LOV-HK, which is a key blue light-activated virulence factor in this microorganism. The structural basis of the light activation mechanism of this protein remains unclear. In this work, full-length LOV-HK was cloned, expressed and purified. The protein was activated by light and crystallized under a controlled illumination environment. The merge of 14 individual native data sets collected on a single crystal resulted in a complete X-ray diffraction data set to a resolution of 3.70 Šwith over 2 million reflections. Crystals belong to space group P212121, with unit-cell parameters a = 95.96, b = 105.30, c = 164.49 Šwith a dimer in the asymmetric unit. Molecular replacement with Phaser using the individual domains as search models allowed for the reconstruction of almost the whole protein. Very recently, improved LOV-HK crystals led to a 3.25-Šresolution dataset. Refinement and model building is underway. This crystal model will represent one of the very few examples of a multi-domain histidine kinase with known structure.

Routes of phosphoryl group transfer during signal transmission and signal decay in the dimeric sensor histidine kinase ArcB.

The Arc (anoxic redox control) two-component system of Escherichia coli, comprising ArcA as the response regulator and ArcB as the sensor histidine kinase, modulates the expression of numerous genes in response to respiratory growth conditions. Under reducing growth conditions, ArcB autophosphorylates at the expense of ATP, and transphosphorylates ArcA via a His292 → Asp576 → His717 → Asp54 phosphorelay, whereas under oxidizing growth conditions, ArcB catalyzes the dephosphorylation of ArcA-P by a reverse Asp54 → His717 → Asp576 → Pi phosphorelay. However, the exact phosphoryl group transfer routes and the molecular mechanisms determining their directions are unclear. Here, we show that, during signal propagation, the His292 → Asp576 and Asp576 → His717 phosphoryl group transfers within ArcB dimers occur intra- and intermolecularly, respectively. Moreover, we report that, during signal decay, the phosphoryl group transfer from His717 to Asp576 takes place intramolecularly. In conclusion, we present a mechanism that dictates the direction of the phosphoryl group transfer within ArcB dimers and that enables the discrimination of the kinase and phosphatase activities of ArcB.

Brucella abortus Senses the Intracellular Environment through the BvrR/BvrS Two-Component System, Which Allows B. abortus To Adapt to Its Replicative Niche.

Brucella abortus is a facultative extracellular-intracellular pathogen belonging to a group of Alphaproteobacteria that establishes close interactions with animal cells. This bacterium enters host cells in a membrane-bound compartment, avoiding the lysosomal route and reaching the endoplasmic reticulum through the action of the type IV secretion system, VirB. In this work, we demonstrate that the BvrR/BvrS two-component system senses the intracellular environment to mount the transcriptional response required for intracellular life adaptation. By combining a method to purify intracellularly extracted bacteria with a strategy that allows direct determination of BvrR phosphorylation, we showed that upon entrance to host cells, the regulatory protein BvrR was activated (BvrR-P) by phosphorylation at aspartate 58. This activation takes place in response to intracellular cues found in early compartments, such as low pH and nutrient deprivation. Furthermore, BvrR activation was followed by an increase in the expression of VjbR and VirB. The in vitro activation of this BvrR-P/VjbR/VirB virulence circuit rescued B. abortus from the inhibition of intracellular replication induced by bafilomycin treatment of cells, demonstrating the relevance of this mechanism for intracellular bacterial survival and replication. All together, our results indicate that B. abortus senses the transition from the extracellular to the intracellular milieu through BvrR/BvrS, allowing the bacterium to transit safely to its replicative niche. These results serve as a working model for understanding the role of this family of two-component systems in the adaptation to intracellular life of Alphaproteobacteria.

Novel Two-Component System of Streptococcus sanguinis Affecting Functions Associated with Viability in Saliva and Biofilm Formation.

Streptococcus sanguinis is a pioneer species of teeth and a common opportunistic pathogen of infective endocarditis. In this study, we identified a two-component system, S. sanguinis SptRS (SptRS Ss ), affecting S. sanguinis survival in saliva and biofilm formation. Isogenic mutants of sptRSs (SKsptR) and sptSSs (SKsptS) showed reduced cell counts in ex vivo assays of viability in saliva compared to those of parent strain SK36 and complemented mutants. Reduced counts of the mutants in saliva were associated with reduced growth rates in nutrient-poor medium (RPMI) and increased susceptibility to the deposition of C3b and the membrane attach complex (MAC) of the complement system, a defense component of saliva and serum. Conversely, sptRSs and sptSSs mutants showed increased biofilm formation associated with higher levels of production of H2O2 and extracellular DNA. Reverse transcription-quantitative PCR (RT-qPCR) comparisons of strains indicated a global role of SptRS Ss in repressing genes for H2O2 production (2.5- to 15-fold upregulation of spxB, spxR, vicR, tpk, and ackA in sptRSs and sptSSs mutants), biofilm formation, and/or evasion of host immunity (2.1- to 11.4-fold upregulation of srtA, pcsB, cwdP, iga, and nt5e). Compatible with the homology of SptR Ss with AraC-type regulators, duplicate to multiple conserved repeats were identified in 1,000-bp regulatory regions of downstream genes, suggesting that SptR Ss regulates transcription by DNA looping. Significant transcriptional changes in the regulatory genes vicR, spxR, comE, comX, and mecA in the sptRSs and sptSSs mutants further indicated that SptRS Ss is part of a regulatory network that coordinates cell wall homeostasis, H2O2 production, and competence. This study reveals that SptRS Ss is involved in the regulation of crucial functions for S. sanguinis persistence in the oral cavity.