Abstract
Crystal structure of RNA helicase domain from genotype 1b hepatitis C virus has been determined at 2.3 A resolution by the multiple isomorphous replacement method. The structure consists of three domains that form a Y-shaped molecule. One is a NTPase domain containing two highly conserved NTP binding motifs. Another is an RNA binding domain containing a conserved RNA binding motif. The third is a helical domain that contains no beta-strand. The RNA binding domain of the molecule is distinctively separated from the other two domains forming an interdomain cleft into which single stranded RNA can be modeled. A channel is found between a pair of symmetry-related molecules which exhibit the most extensive crystal packing interactions. A stretch of single stranded RNA can be modeled with electrostatic complementarity into the interdomain cleft and continuously through the channel. These observations suggest that some form of this dimer is likely to be the functional form that unwinds double stranded RNA processively by passing one strand of RNA through the channel and passing the other strand outside of the dimer. A "descending molecular see-saw" model is proposed that is consistent with directionality of unwinding and other physicochemical properties of RNA helicases.
Highlights
Crystal structure of RNA helicase domain from genotype 1b hepatitis C virus has been determined at 2.3 Å resolution by the multiple isomorphous replacement method
Rep DNA helicase, for example, is a stable monomer in solution in the absence of DNA, a dimeric form of Rep is induced in the presence of DNA which is known as the functional form [6, 8]
Its genome consists of about 9400 nucleotides with the gene order of NЈ-CE1-E2-NS2-NS3-NS4A-NS4B-NS5A-NS5B-CЈ [10] encoding a viral polyprotein of about 3010 residues [11]
Summary
(Received for publication, January 26, 1998, and in revised form, March 18, 1998). Hyun-Soo Cho‡§¶, Nam-Chul Ha‡¶, Lin-Woo Kang‡, Kyung Min Chung‡, Sung Hoon Back‡, Sung Key Jang‡, and Byung-Ha Oh‡§ʈ. The RNA binding domain of the molecule is distinctively separated from the other two domains forming an interdomain cleft into which single stranded RNA can be modeled. Oligomeric forms, generally dimers or hexamers, were observed for some DNA helicases [8, 9] These oligomers are believed to provide the helicases with multiple nucleic acid binding sites necessary for the helicase function [6]. Based on a modeling experiment we propose a mechanism of processive unwinding of the duplex RNA consistent with previously observed physicochemical properties of the enzyme.
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