Recognition of Streptococcal Promoters by the Pneumococcal SigA Protein

FUNDING This study was financially supported by grants BIO2016-76412- C2-2-R (AEI/FEDER, UE) to AB from the Spanish Ministry of Economy and Competitiveness, and PID2019-104553RB-C21 to AB from the Spanish Ministry of Science and Innovation. ACKNOWLEDGMENTS Thanks are due to F. W. Studier for his gift of the E. coli BL21 (DE3) strain and to L. Rodríguez for her technical help in protein purification.Peer reviewedPublisher PD

Promoter DNA recognition by the Enterococcus faecalis global regulator MafR

When Enterococcus faecalis is exposed to changing environmental conditions, the expression of many genes is regulated at the transcriptional level. We reported previously that the enterococcal MafR protein causes genome-wide changes in the transcriptome. Here we show that MafR activates directly the transcription of the OG1RF_10478 gene, which encodes a hypothetical protein of 111 amino acid residues. We have identified the P10478 promoter and demonstrated that MafR enhances the efficiency of this promoter by binding to a DNA site that contains the −35 element. Moreover, our analysis of the OG1RF_10478 protein AlphaFold model indicates high similarity to 1) structures of EIIB components of the bacterial phosphoenolpyruvate:carbohydrate phosphotransferase system, and 2) structures of receiver domains that are found in response regulators of two-component signal transduction systems. However, unlike typical EIIB components, OG1RF_10478 lacks a Cys or His residue at the conserved phosphorylation site, and, unlike typical receiver domains, OG1RF_10478 lacks a conserved Asp residue at the position usually required for phosphorylation. Different from EIIB components and receiver domains, OG1RF_10478 contains an insertion between residues 10 and 30 that, according to ColabFold prediction, may serve as a dimerization interface. We propose that OG1RF_10478 could participate in regulatory functions by protein-protein interactions

Structural basis of a histidine-DNA nicking/joining mechanism for gene transfer and promiscuous spread of antibiotic resistance

Relaxases are metal-dependent nucleases that break and join DNA for the initiation and completion of conjugative bacterial gene transfer. Conjugation is the main process through which antibiotic resistance spreads among bacteria, with multidrug-resistant staphylococci and streptococci infections posing major threats to human health. The MOBV family of relaxases accounts for approximately 85% of all relaxases found in Staphylococcus aureus isolates. Here, we present six structures of the MOBV relaxase MobM from the promiscuous plasmid pMV158 in complex with several origin of transfer DNA fragments. A combined structural, biochemical, and computational approach reveals that MobM follows a previously uncharacterized histidine/metal-dependent DNA processing mechanism, which involves the formation of a covalent phosphoramidate histidine-DNA adduct for cell-to-cell transfer. We discuss how the chemical features of the high-energy phosphorus-nitrogen bond shape the dominant position of MOBV histidine relaxases among small promiscuous plasmids and their preference toward Gram-positive bacteria

Structural basis of conjugative DNA transfer mediated by mobM, a prototype of the major relaxase family of Staphylococcus aureus

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Structural basis of conjugative DNA transfer mediated by MobM, a prototype of the major relaxase family of Staphylococcus aureus

MobM relaxase from the promiscuous antibiotic resistance plasmid pMV158 is a prototype of the Mob_Pre/MOBV family of relaxases, the major family of relaxases found in Staphylococcus aureus. Staphylococcal infections cause the highest number of lethal cases among antibiotic-resistant bacterial infections. Relaxases initiate the conjugative DNA transfer, a major route for the antibiotic resistance acquisition in bacteria, by nicking their substrate DNA through formation of a covalent DNA-relaxase adduct and terminate the transfer in the recipient cells by rejoining ends of the linearized plasmid. MobM forms a DNA-histidine adduct, unique to MOBV relaxases, instead of a DNA-tyrosine adduct, thus representing a distinct category of relaxases with specialization towards the transfer of short mobile genetic elements in Gram-positive pathogenic bacteria. MobM overall fold resembles the fold of other structurally characterized relaxases, although some important structural differences are present. Molecular basis for the MobM processing of plasmid origin of transfer and active site mechanism are described herein.La relaxasa MobM del promiscuo plásmido de resistencia a antibióticos pMV158 es un prototipo de la familia Mob_Pre/MOBV de relaxasas, la mayor familia de relaxasas se encuentran en Staphylococcu aureus. Las infecciones por estafilococos causan el mayor número de casos mortales entre las infecciones bacterianas resistentes a los antibióticos. Relaxases iniciar la transferencia conjugativa de ADN, una ruta el más frecuente para la adquisición de resistencia a antibióticos por bacterias, por mellar su ADN sustrato mediante la formación de un aducto covalente de ADN-relaxasa y terminan la transferencia en las células receptoras por reincorporarse extremos del plásmido linealizado. MobM forma un aducto de ADN-histidina, único para MOBV relaxases, en lugar de un aducto de ADN-tirosina, lo que representa una categoría distinta de relaxases con especialización hacia la transferencia de elementos genéticos móviles cortos en bacterias patógenas Gram-positivas. MobM estructura general se asemeja a la de otras veces relaxases caracterizan estructuralmente, aunque algunas diferencias estructurales importantes están presentes. Base molecular para el procesamiento de origen del plásmido por MobM y mecanismo de sitio activo se describe en esta thesis

Antisense and yet sensitive: Copy number control of rolling circle-replicating plasmids by small RNAs

24 p.-6 fig. Dedicated to Prof. Ramón Díaz-Orejas on occasion of his retirement.Bacterial plasmids constitute a wealth of shared DNA amounting to about 20% of the total prokaryotic pangenome. Plasmids replicate autonomously and control their replication by maintaining a fairly constant number of copies within a given host. Plasmids should acquire a good fitness to their hosts so that they do not constitute a genetic load. Here we review some basic concepts in plasmid biology, pertaining to the control of replication and distribution of plasmid copies among daughter cells. A particular class of plasmids is constituted by those that replicate by the rolling circle mode (rolling circle-replicating [RCR]-plasmids). They are small double-stranded DNA molecules, with a rather high number of copies in the original host. RCR-plasmids control their replication by means of a small short-lived antisense RNA, alone or in combination with a plasmid-encoded transcriptional repressor protein. Two plasmid prototypes have been studied in depth, namely the staphylococcal plasmid pT181 and the streptococcal plasmid pMV158, each corresponding to the two types of replication control circuits, respectively. We further discuss possible applications of the plasmid-encoded antisense RNAs and address some future directions that, in our opinion, should be pursued in the study of these small molecules. This article is categorized under: Regulatory RNAs/RNAi/Riboswitches > Regulatory RNAs RNA Structure and Dynamics > Influence of RNA Structure in Biological Systems.Peer reviewe

Nucleic acids and their complexes and assemblies with proteins Microsymposium

Trabajo presentado en la 29th European Crystallography Meeting, celebrada en Croacia, del 23 al 28 de agosto de 2015Peer Reviewe

The facts and family secrets of plasmids that replicate via the rolling-circle mechanism

90 p.-15 fig.-5 tab.Plasmids are self-replicative DNA elements that are transferred between bacteria. Plasmids encode not only antibiotic resistance genes but also adaptive genes that allow their hosts to colonize new niches. Plasmid transfer is achieved by conjugation (or mobilization), phage-mediated transduction, and natural transformation. Thousands of plasmids use the rolling-circle mechanism for their propagation (RCR plasmids). They are ubiquitous, have a high copy number, exhibit a broad host range, and often can be mobilized among bacterial species. Based upon the replicon, RCR plasmids have been grouped into several families, the best known of them being pC194 and pUB110 (Rep_1 family), pMV158 and pE194 (Rep_2 family), and pT181 and pC221 (Rep_trans family). Genetic traits of RCR plasmids are analyzed concerning (i) replication mediated by a DNA-relaxing initiator protein and its interactions with the cognate DNA origin, (ii) lagging-strand origins of replication, (iii) antibiotic resistance genes, (iv) mobilization functions, (v) replication control, performed by proteins and/or antisense RNAs, and (vi) the participating host-encoded functions. The mobilization functions include a relaxase initiator of transfer (Mob), an origin of transfer, and one or two small auxiliary proteins. There is a family of relaxases, the MOBV family represented by plasmid pMV158, which has been revisited and updated. Family secrets, like a putative open reading frame of unknown function, are reported. We conclude that basic research on RCR plasmids is of importance, and our perspectives contemplate the concept of One Earth because we should incorporate bacteria into our daily life by diminishing their virulence and, at the same time, respecting their genetic diversity.This review was supported by grant PID2019-104553RB-C21 to A.B. and grant PID2020-117923GB-I00 to M.P.G.-B. from the Spanish Ministry of Science and Innovation.Peer reviewe

Functional Properties and Structural Requirements of the Plasmid pMV158-encoded MobM relaxase domain

A crucial element in the horizontal transfer of mobilizable and conjugative plasmids is the relaxase, a single-stranded endonuclease that nicks the origin of transfer (oriT) of the plasmid DNA. The relaxase of the pMV158 mobilizable plasmid is MobM (494 residues). In solution, MobM forms a dimer through its C-terminal domain, which is proposed to anchor the protein to the cell membrane and to participate in type 4 secretion system (T4SS) protein-protein interactions. In order to gain a deeper insight into the structural MobM requirements for efficient DNA catalysis, we studied two endonuclease domain variants that include the first 199 or 243 amino acid residues (MobMN199 and MobMN243, respectively). Our results confirmed that the two proteins behaved as monomers in solution. Interestingly, MobMN243 relaxed supercoiled DNA and cleaved single-stranded oligonucleotides harboring oriTpMV158, whereas MobMN199 was active only on supercoiled DNA. Protein stability studies using gel electrophoresis and mass spectrometry showed increased susceptibility to degradation at the domain boundary between the N-and C-terminal domains, suggesting that the domains change their relative orientation upon DNA binding. Overall, these results demonstrate that MobMN243 is capable of nicking the DNA substrate independently of its topology and that the amino acids 200 to 243 modulate substrate specificity but not the nicking activity per se. These findings suggest that these amino acids are involved in positioning the DNA for the nuclease reaction rather than in the nicking mechanism itself. © 2013, American Society for Microbiology. [Journal]This work was supported by the Spanish Ministry of Science and Innovation (grants BFU2008-02372/BMC, CONSOLIDER CSD 2006-23, and BFU2011-22588 to M.C. and grants CSD2008-00013, INTERMODS, and BFU2010-19597 to M.E.), the Generalitat de Catalunya (grant SGR2009-1309 to M.C.), the “La Caixa”/IRB Barcelona International PhD Programme Fellowship (IRB Barcelona call 01/09/FLC to R.P.), and the European Commission (FP7 Cooperation Project SILVER-GA no. 260644 to M.C.)Peer Reviewe