Abstract
The influenza virus polymerase complex contains a metal ion-dependent endonuclease activity, which generates short capped RNA primer molecules from capped RNA precursors. Previous studies have provided evidence for a two-metal ion mechanism of RNA cleavage, and the data are consistent with a direct interaction of a divalent metal ion with the catalytic water molecule. To refine the model of this active site, we have generated a series of DNA, RNA, and DNA-RNA chimeric molecules to study the role of the 2'-hydroxy groups on nucleic acid substrates of the endonuclease. We could observe specific cleavage of nucleic acid substrates devoid of any 2'-hydroxy groups if they contained a cap structure (m7GpppG) at the 5'-end. The capped DNA endonuclease products were functional as primers for transcription initiation by the influenza virus polymerase. The apparent cleavage rates were about 5 times lower with capped DNA substrates as compared with capped RNA substrates. Cleavage rates with DNA substrates could be increased to RNA levels by substituting the deoxyribosyl moieties immediately 5' and 3' of the cleavage site with ribosyl moieties. Similarly, cleavage rates of RNA substrates could be lowered to DNA levels by exchanging the same two ribosyl groups with deoxyribosyl groups at the cleavage site. These results demonstrate that the 2'-hydroxy groups are not essential for binding and cleavage of nucleic acids by the influenza virus endonuclease, but small differences of the nucleic acid conformation in the endonuclease active site can influence the overall rate of hydrolysis. The observed relative cleavage rates with DNA and RNA substrates argue against a direct interaction of a catalytic metal ion with a 2'-hydroxy group in the endonuclease active site.
Highlights
The influenza virus contains a negative strand RNA genome consisting of eight RNA segments encoding a total of 10 viral proteins
We used a panel of DNA, RNA, and DNA-RNA chimeric oligonucleotides to define the role of 2Ј-hydroxy groups on the influenza virus endonuclease substrates
A DNA substrate containing a ribosyl moiety at the cleavage site nucleotide 11 was cleaved by the influenza virus endonuclease, and the cleavage product was elongated by the polymerase in the presence of CTP with an apparent Km virtually identical to the value obtained with Gem20-M RNA (G20) RNA substrate
Summary
Materials—Influenza virus A/PR/8/34 RNPs were prepared from purified influenza virus particles on glycerol gradients as described [4]. The chimeric oligonucleotides were named according to the parent molecule, G20 for Gem RNA or dG20 for Gem DNA, with an added number for the position of the substitution and a suffix, R or D, depending on whether the substitution was a ribo- or a deoxyribonucleotide. Endonuclease and Transcription Initiation Reactions—Except when indicated so in the figure legends, endonuclease reactions were performed in 5-l reaction mixtures containing 1 nM RNP, 50 mM Tris-HCl, pH 8, 100 mM KCl, 0.5 units/l RNasin, 0.25 g/l bovine serum albumin, 0.3% Triton X-100, 0.015– 0.15 nM 32P-cap-labeled nucleic acid substrate. 10 M CTP-Mg was added to the samples prior to the RNPs under the same reaction and incubation conditions as described above. Km(app) and kapp values were calculated from fitting hyperbolic standard curves to the data sets using the equation A ϭ (kapp S)/ (Km(app) ϩ S), where S represents the concentration of CTP in the transcription initiation reaction
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