Cation-Dependent Stability of Subtilisin

Subtilisin BPN‘ contains two cation binding sites. One specifically binds calcium (site A), and the other can bind both divalent and monovalvent metals (site B). By binding at specific sites in the tertiary structure of subtilisin, cations contribute their binding energy to the stability of the nati...

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Veröffentlicht in:Biochemistry (Easton) 2001-09, Vol.40 (35), p.10634-10639
Hauptverfasser: Alexander, Patrick A, Ruan, Biao, Bryan, Philip N
Format: Artikel
Sprache:eng
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Zusammenfassung:Subtilisin BPN‘ contains two cation binding sites. One specifically binds calcium (site A), and the other can bind both divalent and monovalvent metals (site B). By binding at specific sites in the tertiary structure of subtilisin, cations contribute their binding energy to the stability of the native state and increase the activation energy of unfolding. Deconvoluting the influence of binding sites A and B on the inactivation rate of subtilisin is complicated, however. This paper examines the stabilizing effects of cation binding at site B by using a mutant of subtilisin BPN‘ which lacks calcium site A. Using this mutant, we show that calcium binding at site B has relatively little effect on stability in the presence of moderate concentrations of monovalent cations. At [NaCl] =100 mM, site B is ≥98% occupied with sodium, and therefore its net occupancy with a cation varies little as subtilisin is titrated with calcium. Exchanging sodium for calcium results in a 5-fold decrease in the rate of inactivation. In contrast, because of the high selectivity of site A for calcium, its occupancy changes dramatically as calcium concentration is varied, and consequently the inactivation rate of subtilisin decreases ∼200-fold as site A becomes saturated with calcium, irrespective of the concentration of monovalent cations.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi010797m