Investigating the structure of human RNase H1 by site-directed mutagenesis

In this study we examine for the first time the roles of the various domains of human RNase H1 by site-directed mutagenesis. The carboxyl terminus of human RNase H1 is highly conserved with Escherichia coli RNase H1 and contains the amino acid residues of the putative catalytic site and basic substrate-binding domain of the E. coli RNase enzyme. The amino terminus of human RNase H1 contains a structure consistent with a double-strand RNA (dsRNA) binding motif that is separated from the conserved E. coli RNase H1 region by a 62-amino acid sequence. These studies showed that although the conserved amino acid residues of the putative catalytic site and basic substrate-binding domain are required for RNase H activity, deletion of either the catalytic site or the basic substrate-binding domain did not ablate binding to the heteroduplex substrate. Deletion of the region between the dsRNA-binding domain and the conserved E. coli RNase H1 domain resulted in a significant loss in the RNase H activity. Furthermore, the binding affinity of this deletion mutant for the heteroduplex substrate was approximately 2-fold tighter than the wild-type enzyme suggesting that this central 62-amino acid region does not contribute to the binding affinity of the enzyme for the substrate. The dsRNA-binding domain was not required for RNase H activity, as the dsRNA-deletion mutants exhibited catalytic rates approximately 2-fold faster than the rate observed for wild-type enzyme. Comparison of the dissociation constant of human RNase H1 and the dsRNA-deletion mutant for the heteroduplex substrate indicates that the deletion of this region resulted in a 5-fold loss in binding affinity. Finally, comparison of the cleavage patterns exhibited by the mutant proteins with the cleavage pattern for the wild-type enzyme indicates that the dsRNA-binding domain is responsible for the observed strong positional preference for cleavage exhibited by human RNase H1.     

Oligodeoxynucleoside phosphoramidates (P-NH2): synthesis and thermal stability of duplexes with DNA and RNA targets.

Syntheses of non ionic oligodeoxynucleoside phosphoramidates (P-NH2) and mixed phosphoramidate- phosphodiester oligomers were accomplished on automated solid supported DNA synthesizer using both H-phosphonate and phosphoramidite chemistries, in combination with t-butylphenoxyacetyl for N-protection of nucleoside bases, an oxalyl anchored solid support and a final treatment with methanolic ammonia. Thermal stabilities of the hybrids formed between these new analogues and their DNA and RNA complementary strands were determined and compared with those of the corresponding unmodified oligonucleotides, as well as of the phosphorothioate and methylphosphonate derivatives. Dodecathymidines containing P-NH2 links form less stable duplexes with DNA targets, d(C2A12C2) (deltaTm/modification -1.4 degrees C) and poly dA (deltaTm/modification -1.1 degrees C) than the corresponding phosphodiester and methylphosphonate analogues, but the hybrids are slightly more stable than the one obtained with phosphorothioate derivative. The destabilization is more pronounced with poly rA as the target (deltaTm/modification -3 degrees C) and could be compared with that found with the dodecathymidine methylphosphonate. The modification is less destabilizing in an heteropolymer-RNA duplex (deltaTm/modification -2 degrees C). As expected, the P-NH2 modifications are highly resistant towards the action of various nucleases. It is also demonstrated that an all P-NH2 oligothymidine does not elicit Escherichia coli RNase H hydrolysis of the poly rA target but that the modification may be exploited in chimeric oligonucleotides combining P-NH2 sections with a central phosphodiester section.     

Kinetic analysis of Escherichia coli RNase H using DNA-RNA-DNA/DNA substrates.

The kinetic properties of Escherichia coli ribonuclease H (RNase H) were investigated using oligonucleotide substrates that consist of a short stretch of RNA, flanked on either side by DNA (DNA-RNA-DNA). In the presence of a complementary DNA strand, RNase H cleavage is restricted to the short ribonucleotide stretch of the DNA/RNA heteroduplex. The DNA-RNA-DNA substrate utilized for kinetic studies: (formula; see text) is cleaved at a single site (decreases) in the presence of a complementary DNA strand, to generate (dT)7-(rA)2-OH and p-(rA)2-(dT)9. Anion exchange high performance liquid chromatography was used to separate and quantitate the cleavage products. Under these conditions, RNase H-specific and nonspecific degradation products could be resolved. Kinetic parameters were measured under conditions of 100% hybrid formation (1.2-1.5 molar excess of complementary DNA, T much less than Tm). A linear double reciprocal plot was obtained, yielding a Km of 4.2 microM and a turnover number of 7.1 cleavages per s per RNase H monomer. The kinetic properties of substrate analogs containing varying lengths of RNA (n = 3-5) and 2'-O-methyl modifications were also investigated. Maximal turnover was observed with DNA-RNA-DNA substrates containing a minimum of four RNA residues. Kcat for the rA3 derivative was decreased by more than 100-fold. The Km appeared to decrease with the size of the internal RNA stretch (n = 3-5). No significant difference in turnover number of Km was observed when the flanking DNA was replaced with 2'-O-methyl RNA, suggesting that RNase H does not interact with this region of the heteroduplex.     

Expression, purification, and characterization of a recombinant ribonuclease H from Thermus thermophilus HB8.

Thermus thermophilus ribonuclease H was overexpressed and purified from Escherichia coli. The determination of the complete amino acid sequence allowed modification of that predicted from the DNA sequence, and the enzyme was shown to be composed of 166 amino acid residues with a molecular weight of 18,279. The isoelectric point of the enzyme was 10.5, and the specific absorption coefficient A0.1%(280) was 1.69. The enzymatic and physicochemical properties as well as the thermal and conformational stabilities of the enzyme were compared with those of E. coli RNase HI, which shows 52% amino acid sequence identity. Comparison of the far and near UV circular dichroism spectra suggests that the two enzymes are similar in the main chain folding but different in the spatial environments of tyrosine and tryptophan residues. The enzymatic activities of T. thermophilus RNase H at 37 and 70 degrees C for the hydrolysis of either an M13 DNA/RNA hybrid or a nonanucleotide duplex were approximately 5-fold lower and 3-fold higher, respectively, as compared with E. coli RNase HI at 37 degrees C. The melting temperature, Tm, of T. thermophilus RNase H was 82.1 degrees C in the presence of 1.2 M guanidine hydrochloride, which was 33.9 degrees C higher than that observed for E. coli RNase HI. The free energy changes of unfolding in the absence of denaturant, delta G[H2O], of T. thermophilus RNase H increased by 11.79 kcal/mol at 25 degrees C and 14.07 kcal/mol at 50 degrees C, as compared with E. coli RNase HI.     

Boranophosphate nucleic acids--a versatile DNA backbone.

Important chemical and biochemical properties of boranophosphate DNA and RNA oligonucleotides are reviewed. Stereoregular boranophosphate oligomers can be synthesized enzymatically and form stable duplexes with DNA. Fully boronated, non-stereoregular oligothymidylates, synthesized chemically, form hybrids with poly(A) that have lower melting points than oligothymidylate:poly(A), yet they nevertheless can support the RNase H mediated cleavage of RNA.     

Boranophosphate Nucleic Acids - A Versatile DNA Backbone

Abstract

Important chemical and biochemical properties of boranophosphate DNA and RNA oligonucleotides are reviewed. Stereoregular boranophosphate oligomers can be synthesized enzymatically and form stable duplexes with DNA. Fully boronated, non-stereoregular oligothymidylates, synthesized chemically, form hybrids with poly(A) that have lower melting points than oligothymidylate:poly(A), yet they nevertheless can support the RNase H mediated cleavage of RNA.     

Human RNase H1 uses one tryptophan and two lysines to position the enzyme at the 3'-DNA/5'-RNA terminus of the heteroduplex substrate

In a previous study, we showed that the RNA-binding domain of human RNase H1 is responsible for the positional preference for cleavage exhibited by the enzyme (Wu, H., Lima, W. F., and Crooke, S. T. (2001) J. Biol. Chem. 276, 23547-23553). Here, we identify the substituents on the heteroduplex substrate and the amino acid residues within the RNA-binding domain of human RNase H1 involved in positioning of the enzyme. The human RNase H1 cleavage patterns observed for heteroduplexes with various 3'-DNA/5'-RNA and 5'-DNA/3'-RNA termini indicate that the 5'-most cleavage site on the oligoribonucleotide is positioned 7 bp from the first 3'-DNA/5'-RNA base pair. The presence or absence of phosphate or hydroxyl groups at either the 3'-DNA or 5'-RNA terminus had no effect on the human RNase H1 cleavage pattern. Substitution of the 3'-deoxynucleotide with a ribonucleotide, 2'-methoxyethyl nucleotide, or mismatched deoxyribonucleotide resulted in the ablation of the 5'-most cleavage site on the oligoribonucleotide. Mutants in which Trp43 and Lys59-Lys60 of the RNA-binding domain were substituted with alanine showed a loss of the positional preference for cleavage. Comparison of the kcat, Km, and Kd for the alanine-substituted mutants with those for human RNase H1 suggests that Lys59 and Lys60 are involved in binding to the heteroduplex and that Trp43 is responsible for properly positioning the enzyme on the substrate for catalysis. These data suggest that Trp43, Lys59, and Lys60 constitute an extended nucleic binding surface for the RNA-binding domain of human RNase H1, with the entire interaction taking place at the 3'-DNA/5'-RNA pole of the heteroduplex. These results offer further insights into the interaction between human RNase H1 and the heteroduplex substrate as well as approaches to enhance the design of effective antisense oligonucleotides.     

Deoxydodecanucleotide heteroduplex d(TTTTATAATAAA). d(TTTATTATAAAA) containing the promoter Pribnow sequence TATAAT. I. Double-helix stability by UV spectrophotometry and calorimetry

Thermally induced structural transition in the d(TTTTATAATAAA) d(TTTATTATAAAA) heteroduplex is characterized by UV-spectroscopy and differential scanning calorimetry. At low salt (less than 0.1 M) the occurrence of a cooperative transition in the lower temperature range, followed by a broad transition connected with small increase in absorbance is observed. At high salt (greater than or equal to 0.2 M) a single, monophasic transition appears. Linear dependence of the latter on log of salt concentration (dTm:dlogM = 14.2 degrees C) and of 1/Tm on log of oligomer concentration [derived therefrom delta H (v.H.) = 77.1 kcal/mole (duplex)] allows relating it to the melting of the heteroduplex helix. The non-cooperative transition, independent of oligomer concentration and similar to that of the single chain, was attributed to melting of short hairpin helices upon heteroduplex dissociation. Calorimetric enthalpy: 75.6 kcal/mole (duplex) proved significantly lower than predicted from known calorimetric data for poly[d(AT)] and poly d(A) X poly d(T).     

Purification and characterization of the DNA polymerase and RNase H activities in Moloney murine sarcoma-leukemia virus.

Two RNase H (RNA-DNA hybrid ribonucleotidohydrolase, EC 3.1.4.34) activities separable by Sephadex G-100 gel filtration were identified in lysates of Moloney murine sarcoma-leukemia virus (MSV). The larger enzyme, which we have called RNase H-I, represented about 10% of the RNase H activity in the virion. RNase H-I (i) copurified with RNA-directed DNA polymerase from the virus, (ii) had a sedimentation coefficient of 4.4S (corresponds to an apparent mol wt of 70,000), (iii) required Mn-2+ (2 mM optimum) for activity with a [3-h]poly(A)-poly(dT) substrate, (iv) eluted from phosphocellulose at 0.2 M KC1, and (v) degraded [3-H]poly(A)-poly(dT) and [3-H]poly(C)-poly(dG) at approximately equal rates. The smaller enzyme, designated RNase H-II, which represented the majority of the RNase H activity in the virus preparation, was shown to be different since it (i) had no detectable, associated DNA polymerase activity, (ii) had a sedmimentation coefficient of 2.6S (corresponds to an apparent mol wt of 30,000), (iii) preferred Mg-2+ (10 to 15 mM optimum) over Mn-2+ (5 to 10 mM optimum) 2.5-fold for the degradation of [3-H]poly(A)-poly(dT), and (iv) degraded [3-H]poly(A)-poly(dT) 6 and 60 times faster than [3-H]poly(C)-poly(dG) in the presence of Mn-2+ and Mg-2+, respectively. Moloney MSV DNA polymerase (RNase H-I), purified by Sephadex G-100 gel filtration followed by phosphocellulose, poly(A)-oligo(dT)-cellulose, and DEAE-cellulose chromatography, transcribed heteropolymeric regions of avian myeloblastosis virus 70S RNA at a rate comparable to avian myeloblastosis virus DNA polymerase purified by the same procedure.     

Purification and Properties of a Ribonuclease in Human Urine that Hydrolyses Polycytidylic Acid

Human urine RNase was purified about 2000-fold. The preparation is free from phosphatase, phosphodiesterase and DNase activities. On electrophoresis through polyacrylaraide gel at pH 8.3, it migrates toward the anode and stains with periodic acid-Schiff reagent, suggesting that it is aci c and glycoprotein in nature. Its isoelectric point is at pH 4.1. It has a molecular weight of about 21, 500.

It is thermostable at pH 4.2 and thermolabile at pH 8.5. It has a pH optimum at 6.5. It exhibits highest preference for cytidine 3′-phosphate linkages. Its activity on poly (C) is endonucleolytic. It cleaves poly (C) via intramolecular transphosphorylation. It has no action on cytidine 2′: 3′-cyclic phosphate or uridine 2′:3′-cyclic phosphate.

Its rate of hydrolysis of poly (U) is less than 2% of that of poly (C). Poly (A) and poly (G) are totally inert to its action. Its action on poly (C) is inhibited by poly (G), poly (A) and poly (U).

It differs from bovine pancreatic RNase A in its physical, chemical and catalytic properties. It is, however, similar to human serum and pancreatic RNase in all its properties, suggesting that pancreas is its likely source.     

Structural requirements at the catalytic site of the heteroduplex substrate for human RNase H1 catalysis

Human RNase H1 cleaves RNA exclusively in an RNA/DNA duplex; neither double-strand DNA nor double-strand RNA is a viable substrate. Previous studies suggest that the helical geometry and sugar conformation of the DNA and RNA may play a role in the selective recognition of the heteroduplex substrate by the enzyme. We systematically evaluated the influence of sugar conformation, minor groove bulk, and conformational flexibility of the heteroduplex on enzyme efficiency. Modified nucleotides were introduced into the oligodeoxyribonucleotide at the catalytic site of the heteroduplex and consisted of southern, northern, and eastern biased sugars with and without 2'-substituents, non-hydrogen bonding base modifications, abasic deoxyribonucleotides, intranucleotide hydrocarbon linkers, and a ganciclovir-modified deoxyribonucleotide. Heteroduplexes containing modifications exhibiting strong northern or southern conformational biases with and without a bulky 2'-substituent were cleaved at a significantly slower rate than the unmodified substrate. Modifications imparting the greatest degree of conformational flexibility were the poorest substrates, resulting in dramatically slower cleavage rates for the ribonucleotide opposing the modification and the surrounding ribonucleotides. Finally, modified heteroduplexes containing modifications predicted to mimic the sugar pucker and conformational flexibility of the deoxyribonucleotide exhibited cleavage rates comparable with those of the unmodified substrate. These data suggest that sugar conformation, minor groove width, and the relative positions of the intra- and internucleotide phosphates are the crucial determinants in the selective recognition of the heteroduplex substrate by human RNase H1 and offer immediate steps to improve the performance of DNA-like antisense oligonucleotides.     

Effects of antisense DNA against the alpha-sarcin stem-loop structure of the ribosomal 23S rRNA.

Antisense DNAs complementary against various sequences of the alpha-sarcin domain (C2646-G2674) of 23S rRNA from Escherichia coli were hybridized to naked 23S rRNA as well as to 70S ribosomes. Saturation levels of up to 0.4 per 70S ribosome were found, the identical fraction was susceptible to the attack of the RNase alpha-sarcin. The hybridization was specific as demonstrated with RNase H digestion, sequencing the resulting fragments and blockage of the action of alpha-sarcin. The RNase alpha-sarcin seems to approach its cleavage site from the 3' half of the loop of the alpha-sarcin domain. Hybridization is efficiently achieved at 37 degrees C and can extend at least into the 3' strand of the stem of the alpha-sarcin domain. However, the inhibition of alpha-sarcin activity is observed at 30 degrees C but not at 37 degrees C. For a significant inhibition of poly(Phe) synthesis the temperature had to be lowered to 25 degrees C. The results imply that the alpha-sarcin domain changes its conformation during protein synthesis and that the conformational changes may include a melting of the stem of the alpha-sarcin domain.     

Purification and properties of a ribonuclease in human urine that hydrolyses polycytidylic acid.

Human urine RNase was purified about 2000-fold. The preparation is free from phosphatase, phosphodiesterase and DNase activities. On electrophoresis through polyacrylamide gel at pH 8.3, it migrates toward the anode and stains with periodic acid-Schiff reagent, suggesting that it is acidic and glycoprotein in nature. Its isoelectric point is at pH 4.1. It has a molecular weight of about 21,500. It is thermostable at pH 4.2 and thermolabile at pH 8.5. It has a pH optimum at 6.5. It exhibits highest preference for cytidine 3'-phosphate linkages. Its activity on poly (C) is endonucleolytic. It cleaves poly (C) via intramolecular transphosphorylation. It has no action on cytidine 2': 3'-cyclic phosphate or uridine 2':3'-cyclic phosphate. Its rate of hydrolysis of poly (U) is less than 2% of that of poly C). Poly (A) and poly (G) are totally inert to its action. Its action on poly (C) is inhibited by poly (G), poly (A) and poly (U). It differs from bovine pancreatic Rnase A in its physical, chemical and catalytic properties. It is, however, similar to human serum and pancreatic RNase in all its properties, suggesting that pancreas is its likely source.     

Ribonuclease H from K562 human erythroleukemia cells. Purification, characterization, and substrate specificity.

The major ribonuclease H from K562 human erythroleukemia cells has been purified more than 4,000-fold. This RNase H, now termed RNase H1, is an endoribonuclease whose products contain 5'-phosphoryl and 3'-hydroxyl termini. The enzyme has a native molecular weight of 89,000 based on its sedimentation and diffusion coefficients. Human RNase H1 has an absolute requirement for a divalent cation. Maximal activity is obtained with either 10 mM Mg2+, 5 mM Co2+, or 0.5 mM Mn2+. The pH optimum is between 8.0 and 8.5 in the presence of 10 mM Mg2+. The isoelectric point is 6.4. RNase H1 lacks double-stranded and single-stranded RNase and DNase activities, and it will not hydrolyze the DNA moiety of an RNA.DNA heteroduplex. Unlike the Escherichia coli enzyme, which requires a heteroduplex that contains at least four consecutive ribonucleotides for activity, human RNase H1 can hydrolyze a DNA.RNA.DNA/DNA heteroduplex that contains a single ribonucleotide. Cleavage occurs at the 5' phosphodiester of this residue. This substrate specificity suggests that human RNase H1 could play a role in ribonucleotide excision from genomic DNA during replication.     

5′-O-Methylphosphonate nucleic acids—new modified DNAs that increase the Escherichia coli RNase H cleavage rate of hybrid duplexes

Several oligothymidylates containing various ratios of phosphodiester and isopolar 5′-hydroxyphosphonate, 5′-O-methylphosphonate and 3′-O-methylphosphonate internucleotide linkages were examined with respect to their hybridization properties with oligoriboadenylates and their ability to induce RNA cleavage by ribonuclease H (RNase H). The results demonstrated that the increasing number of 5′-hydroxyphosphonate or 5′-O-methylphosphonate units in antisense oligonucleotides (AOs) significantly stabilizes the heteroduplexes, whereas 3′-O-methylphosphonate AOs cause strong destabilization of the heteroduplexes. Only the heteroduplexes with 5′-O-methylphosphonate units in the antisense strand exhibited a significant increase in Escherichia coli RNase H cleavage activity by up to 3-fold (depending on the ratio of phosphodiester and phosphonate linkages) in comparison with the natural heteroduplex. A similar increase in RNase H cleavage activity was also observed for heteroduplexes composed of miRNA191 and complementary AOs containing 5′-O-methylphosphonate units. We propose for this type of AOs, working via the RNase H mechanism, the abbreviation MEPNA (MEthylPhosphonate Nucleic Acid).     

Human RNase H1 activity is regulated by a unique redox switch formed between adjacent cysteines

Human RNase H1 is active only under reduced conditions. Oxidation as well as N-ethylmaleimide (NEM) treatment of human RNase H1 ablates the cleavage activity. The oxidized and NEM alkylated forms of human RNase H1 exhibited binding affinities for the heteroduplex substrate comparable with the reduced form of the enzyme. Mutants of human RNase H1 in which the cysteines were either deleted or substituted with alanine exhibited cleavage rates comparable with the reduced form of the enzyme, suggesting that the cysteine residues were not required for catalysis. The cysteine residues responsible for the observed redox-dependent activity of human RNase H1 were determined by site-directed mutagenesis to involve Cys(147) and Cys(148). The redox states of the Cys(147) and Cys(148) residues were determined by digesting the reduced, oxidized, and NEM-treated forms of human RNase H1 with trypsin and analyzing the cysteine containing tryptic fragments by micro high performance liquid chromatography-electrospray ionization-Fourier transform ion cyclotron mass spectrometry. The tryptic fragment Asp(131)-Arg(153) containing Cys(147) and Cys(148) was identified. The mass spectra for the Asp(131)-Arg(153) peptides from the oxidized and reduced forms of human RNase H1 in the presence and absence of NEM showed peptide masses consistent with the formation of a disulfide bond between Cys(147) and Cys(148). These data show that the formation of a disulfide bond between adjacent Cys(147) and Cys(148) residues results in an inactive enzyme conformation and provides further insights into the interaction between human RNase H1 and the heteroduplex substrate.     

Hybridization specificity, enzymatic activity and biological (Ha-ras) activity of oligonucleotides containing 2,4-dideoxy-beta-D-erythro-hexopyranosyl nucleosides.

Antisense oligonucleotides with a 2,4-dideoxyhexopyranosyl nucleoside incorporated at the 3'-end and at a mutation site of the Ha-ras oncogene mRNA were synthesized. Melting temperature studies revealed that an A*-G mismatch is more stable than an A*-T mismatch with these hexopyranosyl nucleosides incorporated at the mutation site. The oligonucleotides are stable against enzymatic degradation. RNase H mediated cleavage studies revealed selective cleavage of mutated Ha-ras mRNA. The oligonucleotide containing two pyranose nucleosides at the penultimate position activates RNase H more strongly than natural oligonucleotides. No correlation, however, was found between DNA - DNA or RNA - DNA melting temperatures and RNase H mediated cleavage capacity. Although the A*-G mismatch gives more stable hybridization than the A*-T base pairing, only the oligonucleotides containing an A*-T base pair are recognized by RNase H. This modification is situated 3 base pairs upstream to the cleavage site. Finally, the double pyranose modified oligonucleotide was able to reduce the growth of T24 cells (bladder carcinoma) while the unmodified antisense oligonucleotide was not.