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Vol. 13, No. 10, pp. 1251-1262, May 15, 1999
Laboratory of Molecular Biology, National Cancer Institute, National
Institutes of Health, Bethesda, Maryland 20892-4255 USA
Transcription repression of the galactose operon of Escherichia
coli requires (1) the binding of the GalR repressor to tandem operators flanking the promoters, (2) the binding of histone-like protein, HU, to a site between the GalR-binding sites, and (3) negatively supercoiled DNA. Under these conditions, protein-protein interactions mediate the formation of a nucleoprotein complex in the
form of a DNA loop, which we have termed a repressosome. To analyze the
structure of the repressosome, we have screened and isolated
galR mutants in which single amino acid substitutions in GalR
lead to defects in loop formation while the protein's operator-binding
activity is retained. The mutant proteins were purified and their
properties confirmed in vitro. We verified that in the case of the two
stronger mutations, the proteins had secondary structures that were
identical to that of wild-type GalR as reflected by circular dichroism
spectroscopy. Homology-based modeling of GalR by use of the crystal
structures of PurR and LacI has enabled us to place the three sites of
mutation in a structural context. They occur in the carboxy-terminal
subdomain of the GalR core, are surface exposed, and, therefore, may be involved in protein-protein interactions. On the basis of our model of
GalR and its structural alignment with LacI and PurR, we have
identified additional residues, the substitution of which leads to a
specific defect in repression by looping. The effects of the mutations
are the same in the presence of HMG-17, a eukaryotic protein unrelated
to HU, which can also mediate GalR-dependent repression of the
gal promoter. This observation suggests that the mutations
define sites of GalR-GalR interaction rather than HU-GalR interaction
in the repressosome.
[Key Words: Repressosome; transcription; galR mutants; protein-protein interactions; DNA looping; GalR; repression]
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