Mechanism of action of Moloney murine leukemia virus RNA-directed DNA polymerase associated RNase H (RNase H I)

The mechanism of action of the ribonuclease H (RNase H) activity associated with Moloney murine leukemia virus RNA-directed DNA polymerase (RNase H I) and the two-subunit (alpha beta) form of avian myeloblastosis virus DNA polymerase were compared by utilizing the model substrate (A)n.(dT)n and polyacrylamide gel electrophoresis in 7 M urea to analyze digestion products. Examination on 25% polyacrylamide gels revealed that a larger proportion of the RNase H I oligonucleotide products generated by limited digestion of [3H](A)(1100).(dT)n were acid insoluble (15-26 nucleotides long) than acid soluble (less than 15 nucleotides long), while the opposite was true for products generated by alpha beta RNase H. RNase H I was capable of attacking RNA in RNA.DNA in the 5' to 3' and 3' to 5' directions, as demonstrated by the use of [3H,3'- or 5'-32P](A)(380).(dT)n and cellulose--[3H](A)n.(dT)n. Both RNase H I and alpha beta RNase H degraded [3H]-(A)n.(dT)n with a partially processive mechanism, based upon classical substrate competition experiments and analyses of the kinetics of degradation of [3H,3'- or 5'-32P](A)(380).(dT)n. That is, both enzymes remain bound to a RNA.DNA substrate through a finite number of hydrolytic events but dissociate before the RNA is completely degraded. Both RNase H I and alpha beta RNase H were capable of degrading [14C](A)n in [3H](C)n-[14C](A)n-[32P](dA)n.(dT)n, suggesting that retroviral RNase H is capable of removing the tRNA primer at the 5' terminus of minus strand DNA at the appropriate time during retroviral DNA synthesis in vitro.     

Solution structure of DNA/RNA hybrid duplex with C8-propynyl 2′-deoxyadenosine modifications: Implication of RNase H and DNA/RNA duplex interaction

Solution structures of DNA/RNA hybrid duplexes, d(GCGCA*AA*ACGCG): r(cgcguuuugcg)d(C) (designated PP57), containing two C8-propynyl 2′-deoxyadenosines (A*) and unmodified hybrid (designated U4A4) are solved. The C8-propynyl groups on 2′-deoxyadenosine perturb the local structure of the hybrid duplex, but overall the structure is similar to that of canonical DNA/RNA hybrid duplex except that Hoogsteen hydrogen bondings between A* and U result in lower thermal stability. RNase H is known to cleave RNA only in DNA/RNA hybrid duplexes. Minor groove widths of hybrid duplexes, sugar puckerings of DNA are reported to be responsible for RNase H mediated cleavage, but structural requirements for RNase H mediated cleavage still remain elusive. Despite the presence of bulky propynyl groups of PP57 in the minor groove and greater flexibility, the PP57 is an RNase H substrate. To provide an insight on the interactions between RNase H and substrates we have modeled Bacillus halodurans RNase H-PP57 complex, our NMR structure and modeling study suggest that the residue Gly(15) and Asn(16) of the loop residues between first β sheet and second β sheet of RNase HI of Escherichia coli might participate in substrate binding.     

Structural biochemistry of a type 2 RNase H: RNA primer recognition and removal during DNA replication

DNA replication and cellular survival requires efficient removal of RNA primers during lagging strand DNA synthesis. In eukaryotes, RNA primer removal is initiated by type 2 RNase H, which specifically cleaves the RNA portion of an RNA-DNA/DNA hybrid duplex. This conserved type 2 RNase H family of replicative enzymes shares little sequence similarity with the well-characterized prokaryotic type 1 RNase H enzymes, yet both possess similar enzymatic properties. Crystal structures and structure-based mutational analysis of RNase HII from Archaeoglobus fulgidus, both with and without a bound metal ion, identify the active site for type 2 RNase H enzymes that provides the general nuclease activity necessary for catalysis. The two-domain architecture of type 2 RNase H creates a positively charged binding groove and links the unique C-terminal helix-loop-helix cap domain to the active site catalytic domain. This architectural arrangement apparently couples directional A-form duplex binding, by a hydrogen-bonding Arg-Lys phosphate ruler motif, to substrate-discrimination, by a tyrosine finger motif, thereby providing substrate-specific catalytic activity. Combined kinetic and mutational analyses of structurally implicated substrate binding residues validate this binding mode. These structural and mutational results together suggest a molecular mechanism for type 2 RNase H enzymes for the specific recognition and cleavage of RNA in the RNA-DNA junction within hybrid duplexes, which reconciles the broad substrate binding affinity with the catalytic specificity observed in biochemical assays. In combination with a recent independent structural analysis, these results furthermore identify testable molecular hypotheses for the activity and function of the type 2 RNase H family of enzymes, including structural complementarity, substrate-mediated conformational changes and coordination with subsequent FEN-1 activity.     

Crystal structures of RNase H2 in complex with nucleic acid reveal the mechanism of RNA-DNA junction recognition and cleavage

Two classes of RNase H hydrolyze RNA of RNA/DNA hybrids. In contrast to RNase H1 that requires four ribonucleotides for cleavage, RNase H2 can nick duplex DNAs containing a single ribonucleotide, suggesting different in vivo substrates. We report here the crystal structures of a type 2 RNase H in complex with substrates containing a (5')RNA-DNA(3') junction. They revealed a unique mechanism of recognition and substrate-assisted cleavage. A conserved tyrosine residue distorts the nucleic acid at the junction, allowing the substrate to function in catalysis by participating in coordination of the active site metal ion. The biochemical and structural properties of RNase H2 explain the preference of the enzyme for junction substrates and establish the structural and mechanistic differences with RNase H1. Junction recognition is important for the removal of RNA embedded in DNA and may play an important role in DNA replication and repair.     

Target‐Activated DNA Polymerase Activity for Sensitive RNase H Activity Assay

Herein, the ribonuclease H (RNase H) activity assay based on the target‐activated DNA polymerase activity is described. In this method, a detection probe composed of two functional sequences, a binding site for DNA polymerase and a catalytic substrate for RNase H, serves as a key component. The detection probe, at its initial state, suppresses the DNA polymerase activity, but it becomes destabilized by RNase H, which specifically hydrolyzes RNA in RNA/DNA hybrid duplexes. As a result, DNA polymerase recovers its activity and initiates multiple primer extension reactions in a separate TaqMan probe‐based signal transduction module, leading to a significantly enhanced fluorescence “turn‐on” signal. This assay can detect RNase H activity as low as 0.016 U mL^?1 under optimized conditions. Furthermore, its potential use for evaluating RNase H inhibitors, which have been considered potential therapeutic agents against acquired immune deficiency syndrome (AIDS), is successfully explored. In summary, this approach is quite promising for the sensitive and accurate determination of enzyme activity and inhibitor screening.     

The sequence of the RNA primer and the DNA template influence the initiation of plus-strand DNA synthesis in hepatitis B virus

For hepadnaviruses, the RNA primer for plus-strand DNA synthesis is generated by the final RNase H cleavage of the pregenomic RNA at an 11 nt sequence called DR1 during the synthesis of minus-strand DNA. This RNA primer initiates synthesis at one of two distinct sites on the minus-strand DNA template, resulting in two different end products; duplex linear DNA or relaxed circular DNA. Duplex linear DNA is made when initiation of synthesis occurs at DR1. Relaxed circular DNA, the major product, is made when the RNA primer translocates to the sequence complementary to DR1, called DR2 before initiation of DNA synthesis. We studied the mechanism that determines the site of the final RNase H cleavage in hepatitis B virus (HBV). We showed that the sites of the final RNase H cleavage are always a fixed number of nucleotides from the 5' end of the pregenomic RNA. This finding is similar to what was found previously for duck hepatitis B virus (DHBV), and suggests that all hepadnaviruses use a similar mechanism. Also, we studied the role of complementarity between the RNA primer and the acceptor site at DR2 in HBV. By increasing the complementarity, we were able to increase the level of priming at DR2 over that seen in the wild-type virus. This finding suggests that the level of initiation of plus-strand DNA synthesis at DR2 is sub-maximal for wild-type HBV. Finally, we studied the role of the sequence at the 5' end of the RNA primer that is outside of the DR sequence. We found that substitutions or insertions in this region affected the level of priming at DR1 and DR2.     

Model RNA-directed DNA synthesis by avian myeloblastosis virus DNA polymerase and its associated RNase H.

A model RNA template-primer system is described for the study of RNA-directed double-stranded DNA synthesis by purified avian myeloblastosis virus DNA polymerase and its associated RNase H. In the presence of complementary RNA primer, oligo(rI), and the deoxyribonucleoside triphosphates dGTP, dTTP, and dATP, 3'-(rC)30-40-poly(rA) directs the sequential synthesis of poly(dT) and poly(dA) from a specific site at the 3' end of the RNA template. With this model RNA template-primer, optimal conditions for double-stranded DNA synthesis are described. Analysis of the kinetics of DNA synthesis shows that initially there is rapid synthesis of poly(dT). After a brief time lag, poly(dA) synthesis and the DNA polymerase-associated RNase H activity are initiated. While poly(rA) is directing the synthesis of poly(dT), the requirements for DNA synthesis indicate that the newly synthesized poly(dT) is acting as template for poly(dA) synthesis. Furthermore, selective inhibitor studies using NaF show that activation of RNase H is not just a time-related event, but is required for synthesis of the anti-complementary strand of DNA. To determine the specific role of RNase H in this synthetic sequence, the primer for poly(dA) synthesis was investigated. By use of formamide--poly-acrylamide slab gel electrophoresis, it is shown that poly(dT) is not acting as both template and primer for poly(dA) synthesis since no poly(dT)-poly(dA) covalent linkages are observed in radioactive poly(dA) product. Identification of 2',3'-[32P]AMP on paper chromatograms of alkali-treated poly(dA) product synthesized with [alpha-32P]dATP as substrate demonstrates the presence of rAMP-dAMP phosphodiester linkages in the poly(dA) product. Therefore, a new functional role of RNase H is demonstrated in the RNA-directed synthesis of double-stranded DNA. Not only is RNase H responsible for the degradation of poly(rA) following formation of a poly(rA)-poly(dT) hybrid but also the poly(rA)fragments generated are serving as primers for initiation of synthesis of the second strand of the double-stranded DNA.     

Insights into RNA/DNA hybrid recognition and processing by RNase H from the crystal structure of a non-specific enzyme-dsDNA complex

Ribonuclease HI (RNase H) is a member of the nucleotidyl-transferase superfamily and endo-nucleolytically cleaves the RNA portion in RNA/DNA hybrids and removes RNA primers from Okazaki fragments. The enzyme also binds RNA and DNA duplexes but is unable to cleave either. Three-dimensional structures of bacterial and human RNase H catalytic domains bound to RNA/DNA hybrids have revealed the basis for substrate recognition and the mechanism of cleavage. In order to visualize the enzyme’s interactions with duplex DNA and to establish the structural differences that afford tighter binding to RNA/DNA hybrids relative to dsDNA, we have determined the crystal structure of Bacillus halodurans RNase H in complex with the B-form DNA duplex [d(CGCGAATTCGCG)]2. The structure demonstrates that the inability of the enzyme to cleave DNA is due to the deviating curvature of the DNA strand relative to the substrate RNA strand and the absence of Mg2+ at the active site. A subset of amino acids engaged in contacts to RNA 2′-hydroxyl groups in the substrate complex instead bind to bridging or non-bridging phosphodiester oxygens in the complex with dsDNA. Qualitative comparison of the enzyme’s interactions with the substrate and inhibitor duplexes is consistent with the reduced binding affinity for the latter and sheds light on determinants of RNase H binding and cleavage specificity.