Structural properties of trimers and tetramers of ribonuclease A

doi:10.1110/ps.14101

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Structural properties of trimers and tetramers of ribonuclease A

Arianna Nenci, Giovanni Gotte, Mariarita Bertoldi and Massimo Libonati

Dipartimento di Scienze Neurologiche e della Visione, Sezione di Chimica Biologica, Università di Verona, Verona, Italy

Reprint requests to: M. Libonati, Dipartimento di Scienze Neurologiche, Sezione di Chimica Biologica, Borgo Roma, Strada Le Grazie 8, I-37134 Verona, Italy; e-mail: massimo.libonati{at}univr.it; fax: 39-045-8027170.

Ribonuclease A aggregates (dimers, trimers, tetramers, pentamers)can be obtained by lyophilization from 40% acetic acid solutions.Each aggregate forms two conformational isomers distinguishableby different basic net charge. The crystal structure of thetwo dimers has recently been determined; the structure of thehigher oligomers is unknown. The results of the study of thetwo trimeric and tetrameric conformers can be summarized asfollows: (1) RNase A trimers and tetramers form by a 3D domain-swappingmechanism. N-terminal and C-terminal types of domain swappingcould coexist; (2) the secondary structures of the trimericand tetrameric conformers do not show significant differencesif compared with the secondary structure of monomeric RNaseA or its two dimers; (3) a different exposure of tyrosine residuesindicates that in the aggregates they have different microenvironments;(4) the two trimeric and tetrameric conformers show differentsusceptibility to digestion by subtilisin; (5) dimers, trimers,and tetramers of RNase A show unwinding activity on double-helicalpoly(dA-dT) • poly(dA-dT), that increases as a functionof the size of the oligomers; (6) the less basic conformersare more stable than the more basic ones, and a low concentrationin solution of trimers and tetramers favors their stability,which is definitely increased by the interaction of the aggregateswith poly(dA-dT) • poly(dA-dT); (7) the products of thermaldissociation of the two trimers indicate that their structurescould be remarkably different. The dissociation products ofthe two tetramers allow the proposal of two models for theirputative structures.

Keywords: RNase A oligomers; trimers and tetramers of RNase A; properties of trimeric and tetrameric RNase A; RNase A aggregates higher than dimers

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