Abstract
Many allosteric proteins form homo-oligomeric complexes to regulate a biological function. In homo-oligomers, subunits establish communication pathways that are modulated by external stimuli like ligand binding. A challenge for dissecting the communication mechanisms in homo-oligomers is identifying intermediate liganded states, which are typically transiently populated. However, their identities provide the most mechanistic information on how ligand-induced signals propagate from bound to empty subunits. Here, we dissected the directionality and magnitude of subunit communication in a reengineered single-chain version of the homodimeric transcription factor cAMP receptor protein. By combining wild-type and mutant subunits in various asymmetric configurations, we revealed a linear relationship between the magnitude of cooperative effects and the number of mutant subunits. We found that a single mutation is sufficient to change the global allosteric behavior of the dimer even when one subunit was wild type. Dimers harboring two mutations with opposite cooperative effects had different allosteric properties depending on the arrangement of the mutations. When the two mutations were placed in the same subunit, the resulting cooperativity was neutral. In contrast, when placed in different subunits, the observed cooperativity was dominated by the mutation with strongest effects over cAMP affinity relative to wild type. These results highlight the distinct roles of intrasubunit interactions and intersubunit communication in allostery. Finally, dimers bound to either one or two cAMP molecules had similar DNA affinities, indicating that both asymmetric and symmetric liganded states activate DNA interactions. These studies have revealed the multiple communication pathways that homo-oligomers employ to transduce signals.
Highlights
This work was supported with startup funds from Georgetown University
Our results show that CRP single-chain dimer (CRPSC) is indistinguishable from the wild-type cAMP receptor protein (CRP) homodimer based on solution structure, thermodynamic stability, and cAMP binding affinities and cooperativity
We find that asymmetric mutants bound to one cAMP molecule have indistinguishable DNA binding affinity constants compared with the doubly liganded CRPSC, which suggests that a single cAMP molecule bound to CRP is sufficient to allosterically drive the conformational changes required for robust interactions with DNA, and it underscores the role of asymmetric liganded states in the regulation of gene expression [19]
Summary
This work was supported with startup funds from Georgetown University. The authors declare that they have no conflicts of interest with the contents of this article. The mutations S62F and D53H have been shown to reduce and enhance cAMP binding cooperativity, respectively By placing these two mutations in various asymmetric configurations, we dissected the directionality and magnitude of mutational perturbations from one subunit to another, thereby providing a unique opportunity to examine communication pathways within and across CRP subunits. The molecular architecture of CRP is ideal for quantitative studies on the mechanisms of transduction of allosteric signals because: 1) cAMP binding reports on intersubunit communication and cooperative interactions, and 2) DNA binding reports on intrasubunit interactions and cAMP-induced conformational changes of the protein [13, 18]
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