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Protein Science (2007), 16:99-109. Published by Cold Spring Harbor Laboratory Press. Copyright © 2007 The Protein Society
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A phosphate-binding subsite in bovine pancreatic ribonuclease A can be converted into a very efficient catalytic site

Mohammed Moussaoui, Claudi M. Cuchillo, and M. Victòria Nogués

Departament de Bioquímica i Biologia Molecular, Facultat de Ciències, Universitat Autònoma de Barcelona, 08193-Bellaterra, Spain

(RECEIVED March 28, 2006; FINAL REVISION October 11, 2006; ACCEPTED October 11, 2006)

A general acid–base catalytic mechanism is responsible for the cleavage of the phosphodiester bonds of the RNA by ribonuclease A (RNase A). The main active site is formed by the amino acid residues His12, His119, and Lys41, and the process follows an endonucleolytic pattern that depends on the existence of a noncatalytic phosphate-binding subsite adjacent, on the 3'-side, to the active site; in this region the phosphate group of the substrate establishes electrostatic interactions through the side chains of Lys7 and Arg10. We have obtained, by means of site-directed mutagenesis, RNase A variants with His residues both at positions 7 and 10. These mutations have been introduced with the aim of transforming a noncatalytic binding subsite into a putative new catalytic active site. The RNase activity of these variants was determined by the zymogram technique and steady-state kinetic parameters were obtained by spectrophotometric methods. The variants showed a catalytic efficiency in the same order of magnitude as the wild-type enzyme. However, we have demonstrated in these variants important effects on the substrate's cleavage pattern. The quadruple mutant K7H/R10H/H12K/H119Q shows a clear increase of the exonucleolytic activity; in this case the original native active site has been suppressed, and, as consequence, its activity can only be associated to the new active site. In addition, the mutant K7H/R10H, with two putative active sites, also shows an increase in the exonucleolytic preference with respect to the wild type, a fact that may be correlated with the contribution of the new active site.

Keywords: ribonuclease A; active site; enzyme kinetics; catalytic mechanism; protein engineering; artificial enzymes


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