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Probing the role of water in the tryptophan repressor-operator complex

Published online by Cambridge University Press:  01 June 1999

MARTHA P. BROWN
Affiliation:
The University of Wisconsin-Madison, School of Pharmacy, 425 N. Charter St., Madison, Wisconsin 53706
ADEOLA O. GRILLO
Affiliation:
The University of Wisconsin-Madison, School of Pharmacy, 425 N. Charter St., Madison, Wisconsin 53706
MIREILLE BOYER
Affiliation:
Centre de Biochimie Structurale, INSERM U414, Faculte de Pharmacie, 15, Avenue Charles Flahault, 34060 Montpellier Cedex 01, France.
CATHERINE A. ROYER
Affiliation:
The University of Wisconsin-Madison, School of Pharmacy, 425 N. Charter St., Madison, Wisconsin 53706 Centre de Biochimie Structurale, INSERM U414, Faculte de Pharmacie, 15, Avenue Charles Flahault, 34060 Montpellier Cedex 01, France.
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Abstract

The Escherichia coli tryptophan repressor protein (TR) represses the transcription of several genes in response to the concentration of tryptophan in the environment. In the co-crystal structure of TR bound to a DNA fragment containing its target very few direct contacts between TR and the DNA were observed. In contrast, a number of solvent mediated contacts were apparent. NMR solution structures, however, did not resolve any solvent mediated bonds at the complex interface. To probe for the role of water in TR operator recognition, the effect of osmolytes on the interactions between TR and a target oligonucleotide bearing the operator site was examined. In the absence of specific solvent mediated hydrogen bonding interactions between the protein and the DNA, increasing osmolyte concentration is expected to strongly stabilize the TR operator interaction due to the large amount of macromolecular surface area buried upon complexation. The results of our studies indicate that xylose did not alter the binding affinity significantly, while glycerol and PEG had a small stabilizing effect. A study of binding as a function of betaine concentration revealed that this osmolyte at low concentration results in a stabilization of the 1:1 TR/operator complex, but at higher concentrations leads to a switching between binding modes to favor tandem binding. Analysis of the effects of betaine on the 1:1 complex suggest that this osmolyte has about 78% of the expected effect. If one accepts the analysis in terms of the number of water molecules excluded upon complexation, these results suggest that about 75 water molecules remain at the interface of the 1:1 dimer/DNA complex. This value is consistent with the number of water molecules found at the interface in the crystallographically determined structure and supports the notion that interfacial waters play an important thermodynamic role in the specific complexation of one TR dimer with its target DNA. However, the complexity of the effects of betaine and the small or negligible effects of the other osmolytes could also arise from osmolyte induced competition between antagonistic coupled reactions.

Type
Research Article
Copyright
© 1999 The Protein Society

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