Linkage between Operator Binding and Dimer to Octamer Self-Assembly of Bacteriophage λ cI Repressor†


Cooperative binding of the bacteriophage λ cI repressor dimer to specific sites of the phage operators OR and OL controls the developmental state of the phage. Cooperativity has long been thought to be mediated by self-assembly of repressor dimers to form tetramers which can bind simultaneously to adjacent operators. More recently, we demonstrated that when free repressor dimers self-associate in solution, tetramer is an intermediate in a concerted assembly reaction leading to octamer as the predominant higher order species [Senear, D. F., et al. (1993) Biochemistry 32, 6179−6189]. Even as a minority component in the assembly reaction, tetramer can account for pairwise cooperativity. In a similar manner, were it able to bind all three operators simultaneously, octamer could account for three-way cooperativity. In fact, based solely on repressor self-assembly, the naive prediction is that the repressor−OR interactions should be substantially more cooperative than they are. Evidently, there are unfavorable contributions to cooperativity from processes other than repressor self-assembly. Here, we focus on coupling between repressor self-association and operator binding as one possible unfavorable contribution to cooperativity. Sedimentation equilibrium analysis was used to compare the dimer−octamer association reactions of a repressor dimer−OR1 complex and free repressor dimer. Fluorescence anisotropy was used to investigate OR1 binding to free dimers and dimers assembled as higher order species. The results of these experiments indicate a significant and salt-dependent unfavorable contribution generated by such coupling. Since the oligonucleotides used in these experiments are the size of single operator sites, this coupling is mediated by the protein, not by the DNA. This mechanism does not account for an additional, salt-independent, unfavorable contribution which we presume is transmitted via the DNA. Thus, unfavorable contributions generated by structural transitions in both macromolecules serve to moderate the effect of self-association alone. We speculate that this is a general feature of cooperative protein−DNA interactions.


Molecular, Cellular and Biomedical Sciences

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ACS Publications

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© 1997 American Chemical Society