Abstract
How signals between the kinesin active and cytoskeletal binding sites are transmitted is an open question and an allosteric question. By extracting correlated evolutionary changes within 700+ sequences, we built a model of residues that are energetically coupled and that define molecular routes for signal transmission. Typically, these coupled residues are located at multiple distal sites and thus are predicted to form a complex, non-linear network that wires together different functional sites in the protein. Of note, our model connected the site for ATP hydrolysis with sites that ultimately utilize its free energy, such as the microtubule-binding site, drug-binding loop 5, and necklinker. To confirm the calculated energetic connectivity between non-adjacent residues, double-mutant cycle analysis was conducted with 22 kinesin mutants. There was a direct correlation between thermodynamic coupling in experiment and evolutionarily derived energetic coupling. We conclude that energy transduction is coordinated by multiple distal sites in the protein rather than only being relayed through adjacent residues. Moreover, this allosteric map forecasts how energetic orchestration gives rise to different nanomotor behaviors within the superfamily.
Highlights
Biological motors function by converting the chemical energy of ATP hydrolysis into mechanical work in the cell
It is anticipated that this set of residues couples components that catalyze the free energy-donating reaction with the free energy-accepting ones that result in directed motion
These data led to the conclusion that (i) specific, distal residues in the protein were thermodynamically and energetically linked and (ii) Statistical coupling analysis (SCA) could uncover a network of linked residues that mediate an allosteric response
Summary
We use SCA to map a residue network for energy transduction that evolves across kinesin isoforms. We tested whether such identified residues, which are 7–30 Å apart in the motor domain, were thermodynamically coupled. Our mathematical and experimental results provide new information about the interrelation of energy from ATP hydrolysis to allosteric changes in this motor
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