Multivariate analysis of conserved sequence-structure relationships in kinesins: Coupling of the active site and a tubulin-binding sub-domain

Barry J. Grant, J. Andrew McCammon, Leo S. D. Caves, Robert A. Cross

Research output: Contribution to journalArticlepeer-review

Abstract

An extensive computational analysis of available sequence and crystal structure data was used to identify functionally important residue interactions within the motor domain of the kinesin molecular motor. Principal component analysis revealed that all current kinesin crystal structures reside in one of two main conformations, which differ at the active site, and in the position of a microtubule-binding sub-domain relative to a rigid central core. This sub-domain consists of secondary structure elements alpha 4-loop12-alpha 5-loop13 and contains a conserved hydrophilic surface patch that may be involved in strong binding to microtubules. A hinge point for the sub-domain motion lies near a conserved glycine at position 292. Statistical coupling analysis revealed a network of co-evolving positions that link this region to the nucleotide-binding site, via a highly conserved histidine in the switch I loop. The data are consistent with a model in which the nucleotide status of the active site shifts kinesin between weak and strong binding conformations via reconfiguration of the identified sub-domain. Our data provide a statistically supported framework for further examination of this and other structure-function relationships in the kinesin family. (C) 2007 Elsevier Ltd. All rights reserved.

Original languageEnglish
Pages (from-to)1231-1248
Number of pages18
JournalJournal of Molecular Biology
Volume368
Issue number5
DOIs
Publication statusPublished - 18 May 2007

Keywords

  • kinesin
  • molecular motors
  • sequence analysis
  • structure analysis
  • structure-function relationships
  • SPINDLE PROTEIN KSP
  • MICROTUBULE-BASED MOTILITY
  • X-RAY-STRUCTURE
  • CRYSTAL-STRUCTURE
  • NUCLEOTIDE-BINDING
  • MOTOR-PROTEIN
  • MOLECULAR-DYNAMICS
  • CONFORMATIONAL-CHANGES
  • NECK-LINKER
  • ALLOSTERIC COMMUNICATION

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