Abstract
The molecular events in the cAMP-induced allosteric activation of cAMP receptor protein (CRP) involve interfacial communications between subunits and domains. However, the roles of intersubunit and interdomain interactions in defining the selectivity of cAMP against other cyclic nucleotides and cooperativity in ligand binding are still not known. Natural occurring CRP mutants with different phenotypes were employed to address these issues. Thermodynamic analyses of subunit association, protein stability, and cAMP and DNA binding as well as conformational studies of the mutants and wild-type CRPs lead to an identification of the apparently dominant roles of residues 128 and 141 in the cAMP-modulated DNA binding activity of CRP. Serine 128 and the C-helix were implicated as playing a critical role in modulating negative cooperativity of cyclic nucleotide binding. A correlation was established between a weak affinity for subunit assembly and the relaxation of cyclic nucleotide selectivity in the G141Q and S128A/G141Q mutants. These results imply that intersubunit interaction is important for cyclic nucleotide discrimination in CRP. The double mutant S128A/G141Q, constructed from two single mutations of S128A and G141Q, which exhibit opposite phenotypic characteristics of CRP- and CRP*, respectively, assumes a CRP* phenotype and has biochemical properties similar to those of the G141Q mutant. These observations suggest that mutation G141Q exerts a dominant effect over mutation S128A and that the subunit realignment induced by the G141Q mutation can override the local structural disruption created by mutation S128A.
Highlights
The expression of many genes involved in different cellular functions in Escherichia coli is regulated by cAMP receptor protein (CRP)1 and cAMP [1,2,3]
The molecular events associated with the allosteric activation of CRP are characterized by negative cooperativity in cAMP binding and a differentiation among the various cyclic nucleotides present in the cell
How does CRP differentiate among the various cyclic nucleotides? What structural element is responsible for establishing a tight coupling between intersubunit and interdomain interactions? CRP mutants generated by site-specific mutagenesis are employed to address these outstanding issues
Summary
The expression of many genes involved in different cellular functions in Escherichia coli is regulated by cAMP receptor protein (CRP) and cAMP [1,2,3]. The molecular events associated with the allosteric activation of CRP are characterized by negative cooperativity in cAMP binding and a differentiation among the various cyclic nucleotides present in the cell. The only observable major structural changes are associated with the doubly liganded CRP [11,12,13,14,15,16] These observations imply that conformational changes during CRP activation most likely involve rigid body movements between subunits and domains without major structural changes or a change in the dynamics of various structural elements without any significant conversion of secondary structures. A global conformational switch is consistent with the proposed mechanisms involving either subunit realignment and domain rearrangement or a change in structural dynamics. The role of residue 141 in defining cyclic nucleotide specificity and the mutual influence of residues 128 and 141 in the allosteric control of CRP toward binding to
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