Abstract

Genetic switches frequently include DNA loops secured by proteins. Recent studies of the lambda bacteriophage repressor (CI), showed that this arrangement in which the protein links two sets of three operators separated by approximately 2.3 kbp, optimizes both the stability and dynamics of DNA loops, compared to an arrangement with just two sets of two operators. Because adjacent dimers interact pairwise, we hypothesized that the odd number of operators in each set of the lambda regulatory system might have evolved to allow for semi-specific, pair-wise interactions that add stability to the loop while maintaining it dynamic. More generally, additional CI dimers may bind non-specifically to flanking DNA sequences making the genetic switch more sensitive to CI concentration. Here, we tested this hypothesis using spectroscopic and imaging approaches to study the binding of the lambda repressor (CI) dimer protein to DNA fragments. For fragments with only one operator and a short flanking sequence, fluorescence correlation spectroscopy measurements clearly indicated the presence of two distinct DNA-CI complexes; one is thought to have a non-specifically bound CI dimer on the flanking sequence. Scanning force micrographs of CI bound to DNA with all six operators revealed wild-type or mutant proteins bound at operator positions. The number of bound, wild-type proteins increased with CI concentration and was larger than expected for strictly specific binding to operators. In contrast, a mutant that fails to oligomerize beyond a dimer, D197G, only bound to operators. These data are evidence that CI cooperativity promotes oligomerization that extends from operator sites to influence the thermodynamics and kinetics of CI-mediated looping.

Highlights

  • When the λ bacteriophage infects the E. coli bacterium, it propagates in either a lytic or lysogenic mode

  • Facilitated non-specific binding by the lambda repressor (CI) despite the fact that during the cell cycle, and through cell division, CI concentration varies ten-fold [1]

  • A detailed description of the strategy for fitting the fluorescence correlation spectroscopy (FCS) data obtained for complexes between the OL1-wild DNA construct and increasing concentrations of wild-type CI protein is provided in S1 Text and S6 Fig

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Summary

Introduction

When the λ bacteriophage infects the E. coli bacterium, it propagates in either a lytic (virulent) or lysogenic (quiescent) mode. With 0, 250, or 500 nM CI protein, the FCS data for Alexa488-labeled DNA fragments could be well fit with Eq 1 including just one diffusive species (S4 Fig).

Results
Conclusion

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