The oligomeric structure of nucleoid protein H-NS is necessary for recognition of intrinsically curved DNA and for DNA bending.

Escherichia coli hns, encoding the abundant nucleoid protein H-NS, was subjected to site-directed mutagenesis either to delete Pro115 or to replace it with alanine. Unlike the wild-type protein, hyperproduction of the mutant proteins did not inhibit macromolecular syntheses, was not toxic to cells and caused a less drastic compaction of the nucleoid. Gel shift and ligase-mediated circularization tests demonstrated that the mutant proteins retained almost normal affinity for non-curved DNA, but lost the wild-type capacity to recognize preferentially curved DNA and to actively bend non-curved DNA, a property of wild-type H-NS demonstrated here for the first time. DNase I foot-printing and in vitro transcription experiments showed that the mutant proteins also failed to recognize the intrinsically bent site of the hns promoter required for H-NS transcription autorepression and to inhibit transcription from the same promoter. The failure of the Pro115 mutant proteins to recognize curved DNA and to bend DNA despite their near normal affinity for non-curved DNA can be attributed to a defect in protein-protein interaction resulting in a reduced capacity to form oligomers observed in vitro and by a new in vivo test based on functional replacement by H-NS of the oligomerization domain (C-domain) of bacteriophage lambda cI repressor.