AUTHOR=Bischof Karin , Schiffer Doris , Trunk Sarah , Höfler Thomas , Hopfer Anja , Rechberger Gerald , Koraimann Günther 

TITLE=Regulation of R1 Plasmid Transfer by H-NS, ArcA, TraJ, and DNA Sequence Elements

JOURNAL=Frontiers in Microbiology

VOLUME=11

YEAR=2020

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2020.01254

DOI=10.3389/fmicb.2020.01254

ISSN=1664-302X

ABSTRACT=<p>In conjugative elements such as integrating conjugative elements (ICEs) or conjugative plasmids (CPs) transcription of DNA transfer genes is a prerequisite for cells to become transfer competent, i.e., capable of delivering plasmid DNA via bacterial conjugation into new host bacteria. In the large family of F-like plasmids belonging to the MobF<sub>12</sub>A group, transcription of DNA transfer genes is tightly controlled and dependent on the activation of a single promoter, designated P<sub>Y</sub>. Plasmid encoded TraJ and chromosomally encoded ArcA proteins are known activators, whereas the nucleoid associated protein heat-stable nucleoid structuring (H-NS) silences the P<sub>Y</sub> promoter. To better understand the role of these proteins in P<sub>Y</sub> promoter activation, we performed <italic>in vitro</italic> DNA binding studies using purified H-NS, ArcA, and TraJ<sub>R</sub><sub>1</sub> (TraJ encoded by the conjugative resistance plasmid R1). All proteins could bind to R1P<sub>Y</sub> DNA with high affinities; however, only ArcA was found to be highly sequence specific. DNase I footprinting studies revealed three H-NS binding sites, confirmed the binding site for ArcA, and suggested that TraJ contacts a dyad symmetry DNA sequence located between −51 and −38 in the R1P<sub>Y</sub> promoter region. Moreover, TraJ<sub>R</sub><sub>1</sub> and ArcA supplied together changed the H-NS specific protection pattern suggesting that these proteins are able to replace H-NS from R1P<sub>Y</sub> regions proximal to the transcription start site. Our findings were corroborated by P<sub>Y</sub>-<italic>lacZ</italic> reporter fusions with a series of site specific R1P<sub>Y</sub> promoter mutations. Sequential changes of some critical DNA bases in the TraJ binding site (<italic>jbs</italic>) from plasmid R1 to plasmid F led to a remarkable specificity switch: The P<sub>Y</sub> promoter became activatable by F encoded TraJ whereas TraJ<sub>R</sub><sub>1</sub> lost its activation function. The R1P<sub>Y</sub> mutagenesis approach also confirmed the requirement for the host-encoded response-regulator ArcA and indicated that the sequence context, especially in the −35 region is critical for P<sub>Y</sub> regulation and function.</p>