The FtsK-like motor TraB is a DNA-dependent ATPase that forms higher-order assemblies

TraB is an FtsK-like DNA translocase responsible for conjugative plasmid transfer in mycelial Streptomyces Unlike other conjugative systems, which depend on a type IV secretion system, Streptomyces requires only TraB protein to transfer the plasmid as dsDNA. The ?-domain of this protein specifically binds to repeated 8-bp motifs on the plasmid sequence, following a mechanism that is reminiscent of the FtsK/SpoIIIE chromosome segregation system. In this work, we purified and characterized the enzymatic activity of TraB, revealing that it is a DNA-dependent ATPase that is highly stimulated by dsDNA substrates. Interestingly, we found that unlike the SpoIIIE protein, the ?-domain of TraB does not confer sequence-specific ATPase stimulation. We also found that TraB binds G-quadruplex DNA structures with higher affinity than TraB-recognition sequences (TRSs). An EM-based structural analysis revealed that TraB tends to assemble as large complexes comprising four TraB hexamers, which might be a prerequisite for DNA translocation across cell membranes. In summary, our findings shed light on the molecular mechanism used by the DNA-translocating motor TraB, which may be shared by other membrane-associated machineries involved in DNA binding and translocation.Funding: This work was supported by the Spanish Ministerio de Economia y Competitividad (MINECO) grants BFU2016-78521-R (to E.C. and I.A.) and Deutsche Forschungsgemeinschaft SFB766 (to G.M)

Conjugation Inhibitors and Their Potential Use to Prevent Dissemination of Antibiotic Resistance Genes in Bacteria

Antibiotic resistance has become one of the most challenging problems in health care. Bacteria conjugation is one of the main mechanisms whereby bacteria become resistant to antibiotics. Therefore, the search for specific conjugation inhibitors (COINs) is of interest in the fight against the spread of antibiotic resistances in a variety of laboratory and natural environments. Several compounds, discovered as COINs, are promising candidates in the fight against plasmid dissemination. In this review, we survey the effectiveness and toxicity of the most relevant compounds. Particular emphasis has been placed on unsaturated fatty acid derivatives, as they have been shown to be efficient in preventing plasmid invasiveness in bacterial populations. Biochemical and structural studies have provided insights concerning their potential molecular targets and inhibitory mechanisms. These findings open a new avenue in the search of new and more effective synthetic inhibitors. In this pursuit, the use of structure-based drug design methods will be of great importance for the screening of ligands and binding sites of putative targets.

Monitoring Bacterial Conjugation by Optical Microscopy

Bacterial conjugation is the main mechanism for horizontal gene transfer, conferring plasticity to the genome repertoire. This process is also the major instrument for the dissemination of antibiotic resistance genes. Hence, gathering primary information of the mechanism underlying this genetic transaction is of a capital interest. By using fluorescent protein fusions to the ATPases that power conjugation, we have been able to track the localization of these proteins in the presence and absence of recipient cells. Moreover, we have found that more than one copy of the conjugative plasmid is transferred during mating. Altogether, these findings provide new insights into the mechanism of such an important gene transfer device.This work was supported by the Spanish Ministerio de Ciencia e Innovación (MINECO) Grants BFU2016-78521-R and PID2019-104251GB-I00

Conjugation inhibitors compete with palmitic acid for binding to the conjugative traffic ATPaseTrwD, providing a mechanism to inhibit bacterial conjugation

Bacterial conjugation is a key mechanism by which bacteria acquire antibiotic resistance. Therefore, conjugation inhibitors (COINs) are promising compounds in the fight against the spread of antibiotic resistance genes among bacteria. Unsaturated fatty acids (uFAs) and alkynoic fatty acid derivatives, such as 2-hexadecanoic acid (2-HDA), have been reported previously as being effective COINs. The traffic ATPase TrwD, a VirB11 homolog in plasmid R388, is the molecular target of these compounds, which likely affect binding of TrwD to bacterial membranes. In this work, we demonstrate that COINs are abundantly incorporated into Escherichia coli membranes, replacing palmitic acid as the major component of the membrane. We also show that TrwD binds palmitic acid, thus facilitating its interaction with the membrane. Our findings also suggest that COINs bind TrwD at a site that is otherwise occupied by palmitic acid. Accordingly, molecular docking predictions with palmitic acid indicated that it shares the same binding site as uFAs and 2-HDA, although it differs in the contacts involved in this interaction. We also identified 2-bromopalmitic acid, a palmitate analog that inhibits many membrane-associated enzymes, as a compound that effectively reduces TrwD ATPase activity and bacterial conjugation. Moreover, we demonstrate that 2-bromopalmitic and palmitic acids both compete for the same binding site in TrwD. Altogether, these detailed findings open up a new avenue in the search for effective synthetic inhibitors of bacterial conjugation, which may be pivotal for combating multidrug-resistant bacteria.This work was supported by Spanish Ministerio de Economia y Competitividad (MINECO) Grants BFU2016-78521-R (to E. C. and I. A.) and BFU2014-55534 (to F. d. l. C.) and by Grant P20GM103475-16 from the National Center for Research Resources and NIGMS, National Institutes of Health (to D. S. R.). The authors declare that they have no conflicts of interest withthe contents of this article. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health

Nanopore sensing reveals a preferential pathway for the co-translocational unfolding of a conjugative relaxase-DNA complex

Bacterial conjugation is the main mechanism for the dissemination of antibiotic resistance genes. A single DNA strand of the conjugative plasmid is transferred across bacterial membranes covalently bound to a large multi-domain protein, named relaxase, which must be unfolded to traverse the secretion channel. Two tyrosine residues of the relaxase (Y18 and Y26 in relaxase TrwC) play an important role in the processing of conjugative DNA. We have used nanopore technology to uncover the unfolding states that take place during translocation of the relaxase-DNA complex. We observed that the relaxase unfolding pathway depends on the tyrosine residue involved in conjugative DNA binding. Transfer of the nucleoprotein complex is faster when DNA is bound to residue Y18. This is the first time in which a protein-DNA complex that is naturally translocated through bacterial membranes has been analyzed by nanopore sensing, opening new horizons to apply this technology to study protein secretion.ACKNOWLEDGEMENTS. We thank Dr Rodríguez-Larrea for allowing us to use his α-HL nanopore device at the Biofisika Institute (CSIC, UPV/EHU) and for his help on data collection. FUNDING. Spanish Ministerio de Ciencia e Innovación Grant [PID2019-104251GB-I00]. Funding for open access charge: Spanish Ministerio de Ciencia e Innovación Grant [PID2019-104251GB-I00]. Conflict of interest statement. None declared