Nascent transcripts in Escherichia coli that fail to be simultaneously translated are subject to a factordependent mechanism of termination (also termed a polarity) that involves the proteins Rho and NusG. In this study, we found that overexpression of YdgT suppressed the polarity relief phenotypes and restored the efficiency of termination in rho or nusG mutants. YdgT and Hha belong to the H-NS and StpA family of proteins that repress a large number of genes in Gram-negative bacteria. Variants of H-NS defective in one or the other of its two dimerization domains, but not those defective in DNA binding alone, also conferred a similar suppression phenotype in rho and nusG mutants. YdgT overexpression was associated with derepression of proU, a prototypical H-NS-silenced locus. Polarity relief conferred by rho or nusG was unaffected in a derivative completely deficient for both H-NS and StpA, although the suppression effects of YdgT or the oligomerizationdefective H-NS variants were abolished in this background. Transcription elongation rates in vivo were unaffected in any of the suppressor-bearing strains. Finally, the polarity defects of rho and nusG mutants were exacerbated by Hha and YdgT deficiency. A model is proposed that invokes a novel role for the polymeric architectural scaffold formed on DNA by H-NS and StpA independent of the gene-silencing functions of these nucleoid proteins, in modulating Rho-dependent transcription termination such that interruption of the scaffold (as obtained by expression either of the H-NS oligomerization variants or of YdgT) is associated with improved termination efficiency in the rho and nusG mutants.Translation is a cotranscriptional process in both eubacteria and archaebacteria (1,9,25,45,50), and it has been proposed that such coupling is a defining characteristic of prokaryotic life (34, 64). The maintenance of transcription-translation coupling in a prokaryotic cell would require dynamic inter-regulation between the binding and progression of a pioneer ribosome on the nascent transcript on the one hand and the rate of transcription elongation on the other (9, 45); however, the detailed mechanisms by which such regulation is achieved are not known. Furthermore, in bacteria such as Escherichia coli, nascent transcripts that are not simultaneously translated are subject to a mechanism of factor-dependent transcription termination (also referred to as transcriptional polarity) (reviewed in references 1, 6, 15, 40, 44, 47, and 52), so that the occurrence of translation-uncoupled transcription is minimized within the cells (11, 43).Factor-dependent (also called Rho-dependent) transcription termination is mediated by, among others, the Rho and NusG proteins (1,6,15,39,40,44,47,52). Although the structures of the two proteins have been determined and several of their biochemical properties have been characterized, the precise mechanisms of their action in transcription termination remain unclear, even controversial. Rho is an RNAbinding protein and possesses RNA-dependent ATPa...
