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Enzyme
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Query: EC:3.1.26.4 (
RNase H
)
2,751
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Several oligo(ribodeoxyribo)nucleotides to be used as probes in the
RNase H
-induced hydrolyses of 5S ribosomal RNA E. coli were synthesized on the Victoria-4M automatic gene synthesizer by the phosphoramidite approach, which allows for introducing ribonucleotides into any position of the oligomer. 2'-
Hydroxy
function was protected by tert-butyldimethylsilyl group whose hydrophobicity simplified isolation of the oligonucleotides by reverse-phased HPLC.
...
PMID:[Hybridase cleavage of RNA. II. Automatic synthesis of mixed oligonucleotide probes]. 208 26
Molecular characterization of eight distinct, difficult-to-clone RNA plant viruses was accomplished after the development of a reverse transcriptase-based first- and second-strand cDNA synthesis method. Double-stranded (ds) RNA templates isolated from strawberry and blackberry and several herbaceous hosts (mint, pea and tobacco) were cloned using this method. Templates, combined with random primers, were denatured with methyl mercuric
hydroxide
. Reverse transcriptase was added followed by the addition of
RNase H
. The resulting dsDNA was then digested with restriction endonucleases to produce shorter fragments that could be cloned efficiently into a T-tailed vector after adding an A-overhang using Taq polymerase. This procedure resulted in a high number of cloned fragments and allowed insert sizes up to three kilobase-pairs. Unlike traditional cDNA construction methods, there is no need for additional enzymes/steps for second-strand synthesis, PCR amplification or prior sequence information. Synthesis and cloning of cDNA derived from dsRNA templates is much more efficient than with previously described methods. This procedure also worked well for cloning gel-purified dsRNA and with single-stranded RNA templates.
...
PMID:The use of reverse transcriptase for efficient first- and second-strand cDNA synthesis from single- and double-stranded RNA templates. 1566 53
Ribonuclease H (
RNase H
) belongs to the nucleotidyl-transferase (NT) superfamily and hydrolyzes the phosphodiester linkages that form the backbone of the RNA strand in RNA x DNA hybrids. This enzyme is implicated in replication initiation and DNA topology restoration and represents a very promising target for anti-HIV drug design. Structural information has been provided by high-resolution crystal structures of the complex
RNase H
/RNA x DNA from Bacillus halodurans (Bh), which reveals that two metal ions are required for formation of a catalytic active complex. Here, we use classical force field-based and quantum mechanics/molecular mechanics calculations for modeling the nucleotidyl transfer reaction in
RNase H
, clarifying the role of the metal ions and the nature of the nucleophile (water versus
hydroxide
ion). During the catalysis, the two metal ions act cooperatively, facilitating nucleophile formation and stabilizing both transition state and leaving group. Importantly, the two Mg(2+) metals also support the formation of a meta-stable phosphorane intermediate along the reaction, which resembles the phosphorane intermediate structure obtained only in the debated beta-phosphoglucomutase crystal (Lahiri, S. D.; et al. Science 2003, 299 (5615), 2067-2071). The nucleophile formation (i.e., water deprotonation) can be achieved in situ, after migration of one proton from the water to the scissile phosphate in the transition state. This proton transfer is actually mediated by solvation water molecules. Due to the highly conserved nature of the enzymatic bimetal motif, these results might also be relevant for structurally similar enzymes belonging to the NT superfamily.
...
PMID:Phosphodiester cleavage in ribonuclease H occurs via an associative two-metal-aided catalytic mechanism. 1866
We describe a method for the systematic improvement of reaction coordinates in quantum mechanical/molecular mechanical (QM/MM) calculations of reaction free-energy profiles. In umbrella-sampling free-energy calculations, a biasing potential acting on a chosen reaction coordinate is used to sample the system in reactant, product, and transition states. Sharp, nearly discontinuous changes along the resulting reaction path are used to identify coordinates that are relevant for the reaction but not properly sampled. These degrees of freedom are then included in an extended reaction coordinate. The general formalism is illustrated for the catalytic cleavage of the RNA backbone of an RNA/DNA hybrid duplex by the
RNase H
enzyme of Bacillus halodurans. We find that in the initial attack of the phosphate diester by water, the oxygen-phosphorus distances alone are not sufficient as reaction coordinates, resulting in substantial hysteresis in the proton degrees of freedom and a barrier that is too low (approximately 10 kcal/mol). If the proton degrees of freedom are included in an extended reaction coordinate, we obtain a barrier of 21.6 kcal/mol consistent with the experimental rates. As the barrier is approached, the attacking water molecule transfers one of its protons to the O1P oxygen of the phosphate group. At the barrier top, the resulting
hydroxide
ion forms a penta-coordinated phosphate intermediate. The method used to identify important degrees of freedom, and the procedure to optimize the reaction coordinate are general and should be useful both in classical and in QM/MM free-energy calculations.
...
PMID:Artificial reaction coordinate "tunneling" in free-energy calculations: the catalytic reaction of RNase H. 1946 98
