Flexible Segments Modulate Co-folding of DUTPase and Nucleocapsid Proteins

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2006 Dec 16

PMID 17169987

Citations 20

Authors

Veronika Nemeth-Pongracz

Orsolya Barabas

Monika Fuxreiter

Istvan Simon

Iva Pichova

Michalea Rumlova

Helena Zabranska

Dmitri Svergun

Maxim Petoukhov

Veronika Harmat

Eva Klement

Eva Hunyadi-Gulyas

Katalin F Medzihradszky

Emese Konya

Beata G Vertessy

Affiliations

Soon will be listed here.

Abstract

The homotrimeric fusion protein nucleocapsid (NC)-dUTPase combines domains that participate in RNA/DNA folding, reverse transcription, and DNA repair in Mason-Pfizer monkey betaretrovirus infected cells. The structural organization of the fusion protein remained obscured by the N- and C-terminal flexible segments of dUTPase and the linker region connecting the two domains that are invisible in electron density maps. Small-angle X-ray scattering reveals that upon oligonucleotide binding the NC domains adopt the trimeric symmetry of dUTPase. High-resolution X-ray structures together with molecular modeling indicate that fusion with NC domains dramatically alters the conformation of the flexible C-terminus by perturbing the orientation of a critical beta-strand. Consequently, the C-terminal segment is capable of double backing upon the active site of its own monomer and stabilized by non-covalent interactions formed with the N-terminal segment. This co-folding of the dUTPase terminal segments, not observable in other homologous enzymes, is due to the presence of the fused NC domain. Structural and genomic advantages of fusing the NC domain to a shortened dUTPase in betaretroviruses and the possible physiological consequences are envisaged.

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