Plasmid R1 Conjugative DNA Processing Is Regulated at the Coupling Protein Interface

Mihajlović, Sanja; Lang, Silvia; Sut, Marta V.; Strohmaier, Heimo; Gruber, Christian J.; Koraimann, Günther; Cabezón, Elena; Moncalián, Gabriel; Cruz, Fernando de la; Zechner, Ellen L.

doi:10.1128/jb.00918-09

Cited by 34 publications

(60 citation statements)

References 80 publications

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“…Although a lot of information has been gathered over the years about the activity, oligomerization state and structure as well as the importance of VirD4 with respect to substrate recognition and processing, its location within the T4S system was unknown (Cascales & Christie, 2004; Mihajlovic et al , 2009; Lang et al , 2010; de Paz et al , 2010; Whitaker et al , 2016). This is the issue we set out to address in this study.…”

Section: Resultsmentioning

confidence: 99%

“…VirB11 has been reported as a hexamer in different systems (Machon et al , 2002; Savvides et al , 2003; Hare et al , 2006). VirD4 and VirB4, though expected to form hexamers, have been identified in monomeric and dimeric forms as well (Gomis‐Ruth et al , 2001; Schroder et al , 2002; Rabel et al , 2003; Arechaga et al , 2008; Mihajlovic et al , 2009; Durand et al , 2011; Pena et al , 2012; Wallden et al , 2012). All three ATPases interact with one another and these interactions likely direct the two processes in which T4S systems are involved: pilus biogenesis and substrate secretion (Atmakuri et al , 2004; Ripoll‐Rozada et al , 2013).…”

Section: Introductionmentioning

confidence: 99%

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Structure of a VirD4 coupling protein bound to a VirB type IV secretion machinery

et al. 2017

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Type IV secretion (T4S) systems are versatile bacterial secretion systems mediating transport of protein and/or DNA. T4S systems are generally composed of 11 VirB proteins and 1 VirD protein (VirD4). The VirB1‐11 proteins assemble to form a secretion machinery and a pilus while the VirD4 protein is responsible for substrate recruitment. The structure of VirD4 in isolation is known; however, its structure bound to the VirB1‐11 apparatus has not been determined. Here, we purify a T4S system with VirD4 bound, define the biochemical requirements for complex formation and describe the protein–protein interaction network in which VirD4 is involved. We also solve the structure of this complex by negative stain electron microscopy, demonstrating that two copies of VirD4 dimers locate on both sides of the apparatus, in between the VirB4 ATPases. Given the central role of VirD4 in type IV secretion, our study provides mechanistic insights on a process that mediates the dangerous spread of antibiotic resistance genes among bacterial populations.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structure of a VirD4 coupling protein bound to a VirB type IV secretion machinery

et al. 2017

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“…The VirB4 tree showed a more scattered distribution of relaxase families, especially among MPF T plasmids. From a functional point of view, although T4CPs interact with components of both the relaxosome and the T4SS, the T4CP-relaxosome interactions seem to be more system specific (94,96,97,101). Besides, T4CP-encoding genes are usually adjacent to the genes coding for the relaxosome components (50,57), with gene order conservation being another sign of coevolution and functional relatedness.…”

Section: Coevolution Of Mobilization and Conjugationmentioning

confidence: 99%

“…This includes, besides the above-mentioned relaxosome components, the type IV coupling protein (T4CP) and the components of the mating channel that assemble a T4SS. The T4CP is involved in the connection between the relaxosome and the transport channel (11,41,94,101). It is also thought to energize the process of DNA transport (135,136).…”

Section: General Properties Of Plasmid Mobilitymentioning

confidence: 99%

Mobility of Plasmids

Smillie

Garcillán-Barcia

Francia

et al. 2010

Microbiol Mol Biol Rev

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921

1,037

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International audiencePlasmids are key vectors of horizontal gene transfer and essential genetic engineering tools. They code for genes involved in many aspects of microbial biology, including detoxication, virulence, ecological interactions, and antibiotic resistance. While many studies have decorticated the mechanisms of mobility in model plasmids, the identification and characterization of plasmid mobility from genome data are unexplored. By reviewing the available data and literature, we established a computational protocol to identify and classify conjugation and mobilization genetic modules in 1,730 plasmids. This allowed the accurate classification of proteobacterial conjugative or mobilizable systems in a combination of four mating pair formation and six relaxase families. The available evidence suggests that half of the plasmids are nonmobilizable and that half of the remaining plasmids are conjugative. Some conjugative systems are much more abundant than others and preferably associated with some clades or plasmid sizes. Most very large plasmids are nonmobilizable, with evidence of ongoing domestication into secondary chromosomes. The evolution of conjugation elements shows ancient divergence between mobility systems, with relaxases and type IV coupling proteins (T4CPs) often following separate paths from type IV secretion systems. Phylogenetic patterns of mobility proteins are consistent with the phylogeny of the host prokaryotes, suggesting that plasmid mobility is in general circumscribed within large clades. Our survey suggests the existence of unsuspected new relaxases in archaea and new conjugation systems in cyanobacteria and actinobacteria. Few genes, e.g., T4CPs, relaxases, and VirB4, are at the core of plasmid conjugation, and together with accessory genes, they have evolved into specific systems adapted to specific physiological and ecological contexts

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“…In F-TraD, it was determined that its C terminus is essential for relaxosomal specificity, probably through an interaction with TraM (4,39,48). The cytoplasmic domain of the related TraD protein of plasmid R1 stimulates both transesterase and helicase activities of its cognate relaxase, TraI (41,51). A series of random mutations were shown to affect TraD oligomerization (23).…”

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confidence: 99%

Functional Dissection of the Conjugative Coupling Protein TrwB

et al. 2010

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The conjugative coupling protein TrwB is responsible for connecting the relaxosome to the type IV secretion system during conjugative DNA transfer of plasmid R388. It is directly involved in transport of the relaxase TrwC, and it displays an ATPase activity probably involved in DNA pumping. We designed a conjugation assay in which the frequency of DNA transfer is directly proportional to the amount of TrwB. A collection of point mutants was constructed in the TrwB cytoplasmic domain on the basis of the crystal structure of TrwB⌬N70, targeting the nucleotide triphosphate (NTP)-binding region, the cytoplasmic surface, or the internal channel in the hexamer. An additional set of transfer-deficient mutants was obtained by random mutagenesis. Most mutants were impaired in both DNA and protein transport. We found that the integrity of the nucleotide binding domain is absolutely required for TrwB function, which is also involved in monomer-monomer interactions. Polar residues surrounding the entrance and inside the internal channel were important for TrwB function and may be involved in interactions with the relaxosomal components. Finally, the N-terminal transmembrane domain of TrwB was subjected to random mutagenesis followed by a two-hybrid screen for mutants showing enhanced protein-protein interactions with the related TrwE protein of Bartonella tribocorum. Several point mutants were obtained with mutations in the transmembranal helices: specifically, one proline from each protein may be the key residue involved in the interaction of the coupling protein with the type IV secretion apparatus.

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Plasmid R1 Conjugative DNA Processing Is Regulated at the Coupling Protein Interface

Cited by 34 publications

References 80 publications

Structure of a VirD4 coupling protein bound to a VirB type IV secretion machinery

Structure of a VirD4 coupling protein bound to a VirB type IV secretion machinery

Mobility of Plasmids

Functional Dissection of the Conjugative Coupling Protein TrwB

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