In Situ Visualization of the pKM101-Encoded Type IV Secretion System Reveals a Highly Symmetric ATPase Energy Center

Bacterial type IV secretion systems (T4SSs) play central roles in antibiotic resistance spread and virulence. By cryo-electron tomography (CryoET), we solved the structure of the plasmid pKM101-encoded T4SS in the native context of the bacterial cell envelope.

Mutagenic Study of Benzimidazole Derivatives with (+S9) and without (−S9) Metabolic Activation

Benzimidazole derivatives have a diverse range of biological activities, including antiulcer, antihypertensive, antiviral, antifungal, anti-inflammatory, and anticancer. Despite these activities, previous studies have revealed that some of the derivatives can induce mutations. This study aimed to screen for potential mutagenic activities of novel benzimidazole derivatives 1–4 using the Ames test and to study their structure–activity relationship (SAR). An Ames test was carried out on two strains of Salmonella typhimurium (TA98 and TA100) in the absence and presence of metabolic activation. Genetic analysis was performed prior to the Ames test to determine the genotypes of the bacterial tester strains. Both bacterial strains showed dependency on histidine with the presence of rfa mutation, uvrB deletion, and plasmid pKM101. Further, all derivatives tested showed no mutagenic activity in the absence of metabolic activation in both tester strains. However, in the presence of metabolic activation, compound 1 appeared to induce mutation at 2.5 µg/plate when tested against the TA98 strain. These results suggest that the absence of the -OH group at the ortho-position over the phenyl ring might be the cause of increased mutagenic activity in compound 1. Additionally, the presence of mutagenic activity in compound 1 when it was metabolically activated indicates that this compound is a promutagen.

VirB8 homolog TraE from plasmid pKM101 forms a hexameric ring structure and interacts with the VirB6 homolog TraD

Type IV secretion systems (T4SSs) are multiprotein assemblies that translocate macromolecules across the cell envelope of bacteria. X-ray crystallographic and electron microscopy (EM) analyses have increasingly provided structural information on individual T4SS components and on the entire complex. As of now, relatively little information has been available on the exact localization of the inner membrane-bound T4SS components, notably the mostly periplasmic VirB8 protein and the very hydrophobic VirB6 protein. We show here that the membrane-bound, full-length version of the VirB8 homolog TraE from the plasmid pKM101 secretion system forms a high-molecular-mass complex that is distinct from the previously characterized periplasmic portion of the protein that forms dimers. Full-length TraE was extracted from the membranes with detergents, and analysis by size-exclusion chromatography, cross-linking, and size exclusion chromatography (SEC) multiangle light scattering (MALS) shows that it forms a high-molecular-mass complex. EM and small-angle X-ray scattering (SAXS) analysis demonstrate that full-length TraE forms a hexameric complex with a central pore. We also overproduced and purified the VirB6 homolog TraD and show by cross-linking, SEC, and EM that it binds to TraE. Our results suggest that TraE and TraD interact at the substrate translocation pore of the secretion system.

Biochemical and structural characterization of TraE from the plasmid pKM101

In all organisms, secretion systems mediate the passage of macromolecules across cellular membranes. The bacterial type IV secretion system (T4SS) family can be divided into three functional groups. First, as typified by the Brucella suis system, T4SSs deliver effector macromolecules into eukaryotic cells during the course of infection. Second, in some Gram-negative bacteria, such as in Helicobacter pylori (ComB system), T4SSs mediate DNA uptake from and release into the extracellular environment. Thirdly, as in the IncN plasmid pKM101, T4SSs can mediate the conjugative transfer of plasmid DNA or transposons into a wide range of bacterial species. This conjugation phenomenon contributes to the spread of antibiotic resistance genes among pathogenic bacteria, leading to the emergence of multidrug-resistant pathogenic strains. TraE of the IncN plasmid pKM101 belongs to the VirB8 family of proteins, an essential component of most T4SSs that form functional dimmers in the T4SS core. Here, we present the X-ray crystallographic structure of the periplasmic domain of TraE at 2.4 Å resolution. The structure shows many similarities to the known VirB8-like protein structures from Brucella suis [1] and Agrobacterium tumefaciens [2]. However, the nature and the number of residues implicated in the dimerization interface differ considerably from those in the TraE structure [2]. Similar to other VirB8 homologs we have shown by analytical gel filtration that there is a concentration dependant equilibrium between monomeric and dimeric forms of TraE. Moreover, using a bacterial two-hybrid assay, in vivo dimerization has been demonstrated with full-length TraE and key residues for dimerization were identified by site-directed mutagenesis. Our work adds novel insights into the growing body of knowledge on VirB8-like proteins and it will inform future strategies aimed at developing inhibitors of TraE protein interactions and of plasmid transfer.

TraC of IncN Plasmid pKM101 Associates with Membranes and Extracellular High-Molecular-Weight Structures inEscherichia coli

ABSTRACT Conjugative transfer of IncN plasmid pKM101 is mediated by the TraI-TraII region-encoded transfer machinery components. Similar to the case for the related Agrobacterium tumefaciens T-complex transfer apparatus, this machinery is needed for assembly of pili to initiate cell-to-cell contact preceding DNA transfer. Biochemical and cell biological experiments presented here show extracellular localization of TraC, as suggested by extracellular complementation of TraC-deficient bacteria by helper cells expressing a functional plasmid transfer machinery (S. C. Winans, and G. C. Walker, J. Bacteriol. 161:402–410, 1985). Overexpression of TraC and its export in large amounts into the periplasm of Escherichia coliallowed purification by periplasmic extraction, ammonium sulfate precipitation, and column chromatography. Whereas TraC was soluble in overexpressing strains, it partly associated with the membranes in pKM101-carrying cells, possibly due to protein-protein interactions with other components of the TraI-TraII region-encoded transfer machinery. Membrane association of TraC was reduced in strains carrying pKM101 derivatives with transposon insertions in genes coding for other essential components of the transfer machinery,traM, traB, traD, andtraE but not eex, coding for an entry exclusion protein not required for DNA transfer. Cross-linking identified protein-protein interactions of TraC in E. coli carrying pKM101 but not derivatives with transposon insertions in essentialtra genes. Interactions with membrane-bound Tra proteins may incorporate TraC into a surface structure, suggested by its removal from the cell by shearing as part of a high-molecular-weight complex. Heterologous expression of TraC in A. tumefaciens partly compensated for the pilus assembly defect in strains deficient for its homolog VirB5, which further supported its role in assembly of conjugative pili. In addition to its association with high-molecular-weight structures, TraC was secreted into the extracellular milieu. Conjugation experiments showed that secreted TraC does not compensate transfer deficiency of TraC-deficient cells, suggesting that extracellular complementation may rely on cell-to-cell transfer of TraC only as part of a bona fide transfer apparatus.

Inhibition of Homologous Recombination by the Plasmid MucA′B Complex

ABSTRACT By its functional interaction with a RecA polymer, the mutagenic UmuD′C complex possesses an antirecombination activity. We show here that MucA′B, a functional homolog of the UmuD′C complex, inhibits homologous recombination as well. In F− recipients expressing MucA′B from a P tac promoter, Hfr × F−recombination decreased with increasing MucA′B concentrations down to 50-fold. In damage-induced pKM101-containing cells expressing MucA′B from the native promoter, recombination between a UV-damaged F lac plasmid and homologous chromosomal DNA decreased 10-fold. Overexpression of MucA′B together with UmuD′C resulted in a synergistic inhibition of recombination. RecA[UmuR] proteins, which are resistant to UmuD′C inhibition of recombination, are inhibited by MucA′B while promoting MucA′B-promoted mutagenesis efficiently. The data suggest that MucA′B and UmuD′C contact a RecA polymer at distinct sites. The MucA′B complex was more active than UmuD′C in promoting UV mutagenesis, yet it did not inhibit recombination more than UmuD′C does. The enhanced mutagenic potential of MucA′B may result from its inherent superior capacity to assist DNA polymerase intrans-lesion synthesis. In the course of this work, we found that the natural plasmid pKM101 expresses around 45,000 MucA and 13,000 MucB molecules per lexA(Def) cell devoid of LexA. These molecular Muc concentrations are far above those of the chromosomally encoded Umu counterparts. Plasmid pKM101 belongs to a family of broad-host-range conjugative plasmids. The elevated levels of the Muc proteins might be required for successful installation of pKM101-like plasmids into a variety of host cells.