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Mesoscopic statistical properties of multistep enzyme-mediated reactions

Mesoscopic statistical properties of multistep enzyme-mediated reactions

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  • Author(s): W.H. de Ronde 1 ; B.C. Daniels 2 ; A. Mugler 3 ; N.A. Sinitsyn 4 ; I. Nemenman 4
    • View affiliations
    • Affiliations: 1: FOM Institute for Atomic and Molecular Physics, Amsterdam, The Netherlands
      2: Laboratory of Atomic and Solid State Physics, Cornell University, Ithaca, USA
      3: Department of Physics, Columbia University, New York, USA
      4: Center for Nonlinear Studies, Computer, Computational and Statistical Sciences Division, Los Alamos National Laboratory, Los Alamos, USA
  • Source: Volume 3, Issue 5, September 2009, p. 429 – 437
    DOI:  10.1049/iet-syb.2008.0167 , Print ISSN 1751-8849, Online ISSN 1751-8857
© The Institution of Engineering and Technology
Published

Enzyme-mediated reactions may proceed through multiple intermediate conformational states before creating a final product molecule, and one often wishes to identify such intermediate structures from observations of the product creation. In this study, the authors address this problem by solving the chemical master equations for various enzymatic reactions. A perturbation theory analogous to that used in quantum mechanics allows the determination of the first (〈n〉) and the second (σ2) cumulants of the distribution of created product molecules as a function of the substrate concentration and the kinetic rates of the intermediate processes. The mean product flux V=d〈n〉/dt (or ‘dose–response’ curve) and the Fano factor F2/〈n〉 are both realistically measurable quantities, and whereas the mean flux can often appear the same for different reaction types, the Fano factor can be quite different. This suggests both qualitative and quantitative ways to discriminate between different reaction schemes, and the authors explore this possibility in the context of four sample multistep enzymatic reactions. Measuring both the mean flux and the Fano factor can not only discriminate between reaction types, but can also provide some detailed information about the internal, unobserved kinetic rates, and this can be done without measuring single-molecule transition events.

Inspec keywords: quantum theory; electron spin polarisation; molecular biophysics; reaction kinetics; statistical analysis; perturbation theory; photoemission; biochemistry; enzymes

Other keywords: multistep enzyme-mediated reactions; mesoscopic statistical property; chemical master equations; quantum mechanics; Fano factor; perturbation theory; kinetic rates; cumulants; intermediate processes; conformational states; single-molecule transition; substrate concentration

Subjects: Probability theory, stochastic processes, and statistics; Model reactions in molecular biophysics; Biomolecular interactions, charge transfer complexes; Chemical kinetics and reactions: special regimes; Quantum theory; quantum mechanics

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