• Title of article

    Putative implication of (alpha)-amylase loop 7 in the mechanism of substrate binding and reaction products release

  • Author/Authors

    André، G. نويسنده , , Tran، V. H. نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2004
  • Pages
    -94
  • From page
    95
  • To page
    0
  • Abstract
    (alpha)-Amylases are widespread endo-enzymes involved in the hydrolysis of internal (alpha)-(1,4) glycosidic linkages of starch polymers. Molecular modeling of amylose-amylase interactions is a step toward enzymatic mechanism understanding and rational design of new enzymes. From the crystallographic complex of barley (alpha)amylase AMY2-acarbose, the static aspects of amylose-amylase docking have been characterized with a model of maltododecaose (DP12) (G. Andre, A. Buleon, R. Haser, and V. Tran, Biopolymers 1999, Vol. 50, pp. 751-762; G. Andre and V. Tran, Special Publication no. 246 1999, The Royal Society of Chemistry, H. J. Gilbert, G. J. Davies, B. Henrissat, and B. Svensson, Eds., Cambridge, pp. 165-174). These studies, consistent with the experimental subsite mapping (K. Bak-Jensen, G. Andre, V. Tran, and B. Svensson, Journal of Biological Chemistry, to be published), propose a propagation scheme for an amylose chain in the active cleft of AMY2. The topographical overview of (alpha)-amylases identified loop 7 as a conserved segment flanking the active site. Since some crystallographic experiments suspected its high flexibility, its putative motion was explored through a robotic scheme, an alternate route to dynamics simulations that consume CPU time. The present article describes the characteristics of the flexibility of loop 7: location and motion in AMY2. A back-and-forth motion with a large amplitude of more than 0.6 nm was evaluated. This movement could be triggered by two hinge residues. It results in the loop flipping over the active site to enhance the docking of the native helical substrate through specific interactions, it positions the catalytic residues, it distorts the substrate towards its transition state geometry, and finally monitors the release of the products after hydrolysis. The residues involved in the process are now rational mutation points in the hands of molecular biologists.
  • Keywords
    barley (alpha)-amylase , substrate distortion , hinge resi , molecular modeling , robotic calculations , loop motion
  • Journal title
    BIOPOLYMERS (ORIGINAL RESEARCH ON BIOMOLECULES)
  • Serial Year
    2004
  • Journal title
    BIOPOLYMERS (ORIGINAL RESEARCH ON BIOMOLECULES)
  • Record number

    120748