Kinetic Parameters of Cleavage of CpA and UpA Sequences in an Oligoribonucleotide by Compounds Functionally Mimicking Ribonuclease A

Kinetic parameters of cleavage of CpA and UpA sites in an oligoribonucleotide under the action of artificial ribonuclease ABL3C1 were measured. The compounds were built of RNA-binding domain B, catalytic fragment C, linker L3 comprising 3 methylene groups, and aliphatic fragment A. The rate of cleavage of phosphodiester bonds in the CpA site within decaribonucleotide UUCAUGUAAA was shown to be 3.4 ± 0.2 times higher than in UpA. The rate of cleavage of phosphodiester bonds was found to depend on substrate length: a thousandfold increase in cleavage rate constant was observed for the CpA site in decaribonucleotide as compared with diribonucleoside monophosphate CpA. A slight decrease in the cleavage rates was observed for the reactions proceeding in different buffers at pH 7.0: imidazole > HEPES > phosphate > cacodylate. At the same time, the ratio of cleavage rates for CpA and UpA sites remained constant.     

Self-cleavage of p2Sp1 RNA with Mg2+ and non-ionic detergent (Brij 58)

The precursor of an RNA molecule from T4-infected E. coli cells (p2Sp1 RNA) has the capacity to cleave itself at specific positions [(UpA (139-140) and CpA (170-171)], within a putative loop and stem structure. This sequence-specific cleavage requires at least a monovalent cation and non-ionic detergents. We studied the self-cleavage reaction of an RNA fragment (GUUUCGUACAAAC) (R1) with the sequence corresponding to the p2Sp1 RNA in the presence of Mg2+ and non-ionic detergents. It requires Mg2+ and is aided by a non-ionic detergent, Brij 58. The cleavage reaction is time, temperature, and pH-dependent. The cleavage occurs at the phosphodiester bond between UpA and CpA on the RNA fragment (GUUUCGUACAAAC) (R1). Furthermore, the maximum of cleavage of R1 occurs at a very low Mg2+ concentration (< or = 5 mM).     

Sequence-specific ultrasonic cleavage of DNA

We investigated the phenomenon of ultrasonic cleavage of DNA by analyzing a large set of cleavage patterns of DNA restriction fragments using polyacrylamide gel electrophoresis. The cleavage intensity of individual phosphodiester bonds was found to depend on the nucleotide sequence and the position of the bond with respect to the ends of the fragment. The relative intensities of cleavage of the central phosphodiester bond in 16 dinucleotides and 256 tetranucleotides were determined by multivariate statistical analysis. We observed a remarkable enhancement of the mean values of the relative intensities of cleavage (cleavage rates) in phosphodiester bonds following deoxycytidine, which diminished in the row of dinucleotides: d(CpG) > d(CpA) > d(CpT) >> d(CpC). The cleavage rates for all pairs of complementary dinucleotides were significantly different from each other. The effect of flanking nucleotides in tetranucleotides on cleavage rates of all 16 types of central dinucleotides was also statistically significant. The sequence-dependent ultrasonic cleavage rates of dinucleotides are consistent with reported data on the intensity of the conformational motion of their 5′-deoxyribose. As a measure of local conformational dynamics, cleavage rates may be useful for characterizing functional regions of the genome.     

Enhanced RNA cleavage within bulge-loops by an artificial ribonuclease

Cleavage of phosphodiester bonds by small ribonuclease mimics within different bulge-loops of RNA was investigated. Bulge-loops of different size (1–7 nt) and sequence composition were formed in a 3′ terminal fragment of influenza virus M2 RNA (96 nt) by hybridization of complementary oligodeoxynucleotides. Small bulges (up to 4 nt) were readily formed upon oligonucleotide hybridization, whereas hybridization of the RNA to the oligonucleotides designed to produce larger bulges resulted in formation of several alternative structures. A synthetic ribonuclease mimic displaying Pyr–Pu cleavage specificity cleaved CpA motifs located within bulges faster than similar motifs within the rest of the RNA. In the presence of 10 mM MgCl₂, 75% of the cleavage products resulted from the attack of this motif. Thus, selective RNA cleavage at a single target phosphodiester bond was achieved by using bulge forming oligonucleotides and a small ribonuclease A mimic.     

Autolytic processing of a phosphorothioate diester bond.

A small satellite RNA of tobacco ringspot virus replicates in tissues infected with tobacco ringspot virus and accumulates in virus capsids, forming virus-like particles. Previous research showed that multimeric forms of this satellite RNA have tandem repeats of the "monomeric" satellite RNA sequence of 359 or 360 nucleotide residues. The multimeric RNAs undergo autolytic processing at a specific CpA phosphodiester bond, the junction, to generate the monomeric RNA. We substituted phosphorothioate diester bonds for various sets of phosphodiester bonds, in dimeric and truncated forms of the satellite RNA. The degree of reduction in autolytic cleavage varied both with the sites of substitution and the size of the RNA molecules. Analyses of a product of the autolysis reaction suggest that one phosphorothioate diester bond most strongly interferes with processing, the one introduced at the CpA junction during its synthesis from adenosine-5'-0-(1-thiotriphosphate). However, extensive introduction of phosphorothioate diester bonds elsewhere in the molecule also decreased processing, possibly by altering conformation.     

Limits to Catalysis by Ribonuclease A

Bovine pancreatic ribonuclease A (RNase A) catalyzes the cleavage of the P-O(5') bond in RNA. Although this enzyme has been the object of much landmark work in bioorganic chemistry, the nature of its rate-limiting transition state and its catalytic rate enhancement had been unknown. Here, the value of k(cat)/K(m) for the cleavage of UpA by wild-type RNase A was found to be inversely related to the concentration of added glycerol. In contrast, the values of k(cat)/K(m) for the cleavage of UpA by a sluggish mutant of RNase A and the cleavage of the poor substrate UpOC(6)H(4)-p-NO(2) by wild-type RNase A were found to be independent of glycerol concentration. Yet, UpA cleavage by the wild-type and mutant enzymes was found to have the same dependence on sucrose concentration, indicating that catalysis of UpA cleavage by RNase A is limited by desolvation. The rate of UpA cleavage by RNase A is maximal at pH 6.0, where k(cat) = 1.4 × 10(3) s(-1) and k(cat)/K(m) = 2.3 × 10(6) M(-1)s(-1) at 25°C. At pH 6.0 and 25°C, the uncatalyzed rate of [5,6-(3)H]Up[3,5,8-(3)H]A cleavage was found to be k(uncat) = 5 × 10(-9) s(-1) (t(1/2) = 4 years). Thus, RNase A enhances the rate of UpA cleavage by 3 × 10(11)-fold by binding to the transition state for P-O(5') bond cleavage with a dissociation constant of <2 × 10(-15) M.     

Cleavage of 3',5'-pyrophosphate-linked dinucleotides by ribonuclease A and angiogenin

Recently, 3',5'-pyrophosphate-linked 2'-deoxyribodinucleotides were shown to be >100-fold more effective inhibitors of RNase A superfamily enzymes than were the corresponding monophosphate-linked (i.e., standard) dinucleotides. Here, we have investigated two ribo analogues of these compounds, cytidine 3'-pyrophosphate (P'-->5') adenosine (CppA) and uridine 3'-pyrophosphate (P'-->5') adenosine (UppA), as potential substrates for RNase A and angiogenin. CppA and UppA are cleaved efficiently by RNase A, yielding as products 5'-AMP and cytidine or uridine cyclic 2',3'-phosphate. The k(cat)/K(m) values are only 4-fold smaller than for the standard dinucleotides CpA and UpA, and the K(m) values (10-16 microM) are lower than those reported for any earlier small substrates (e.g., 500-700 microM for CpA and UpA). The k(cat)/K(m) value for CppA with angiogenin is also only severalfold smaller than for CpA, but the effect of lengthening the internucleotide linkage on K(m) is more modest. Ribonucleotide 3',5'-pyrophosphate linkages were proposed previously to exist in nature as chemically labile intermediates in the pathway for the generation of cyclic 2',3'-phosphate termini in various RNAs. We demonstrate that in fact they are relatively stable (t(1/2) > 15 days for uncatalyzed degradation of UppA at pH 6 and 25 degrees C) and that cleavage in vivo is most likely enzymatic. Replacements of the RNase A catalytic residues His12 and His119 by alanine reduce activity toward UppA by approximately 10(5)-and 10(3.3)-fold, respectively. Thus, both residues play important roles. His12 probably acts as a base catalyst in cleavage of UppA (as with RNA). However, the major function of His119 in RNA cleavage, protonation of the 5'-O leaving group, is not required for UppA cleavage because the pK(a) of the leaving group is much lower than that for RNA substrates. A crystal structure of the complex of RNase A with 2'-deoxyuridine 3'-pyrophosphate (P'-->5') adenosine (dUppA), determined at 1.7 A resolution, together with models of the UppA complex based on this structure suggest that His119 contributes to UppA cleavage through a hydrogen bond with a nonbridging oxygen atom in the pyrophosphate and through pi-pi stacking with the six-membered ring of adenine.     

An RNA sequence determines the speed of its cleavage by artificial ribonucleases

Phosphodiester bonds in RNA situated between similar nucleotides but in different sequences (context) were cleaved under the action of artificial and natural ribonucleases with different speeds, and the reason for this phenomenon has not yet been fully revealed. In this study, the influence of one-nucleotide substitution on the sensitivity to cleavage of the phosphodiester bonds in linear and structured RNA with homologous sequences is studied for the first time. It is indicated that the introduction of one-nucleotide substitution in the RNA sequence significantly (up to 10 times) changes the speed of the cleavage of the bonds that are separated from the substitution point not only by 1–3, but also 6–8 nucleotides, by artificial ribonucleases. The observed regularities may be explained by the fact that the introduction of a one-nucleotide substitution significantly changes the stacking interactions and the net of hydrogen bonds in the RNA molecule. The applied value of this study consists of the ability of using low-molecular artificial ribonucleases with the aim of choosing the region of the binding of the oligonucleotide in the construction of a conjugate for the site-directed cutting of RNA, because the choice of a phosphodiester bond (motif) easily subjected to cleavage significantly determines the efficacy of artificial ribonucleases of directed action.     

The reactivity of phosphodiester bonds within linear single-stranded oligoribonucleotides is strongly dependent on the base sequence

The cleavage of short chimeric oligonucleotides containing only one reactive ribonucleoside unit, all other nucleosides being 2′-O-methylated, has been studied at pH 8.5 and 35°C. Among the 20 different sequences that did not exhibit any tendency to form a defined secondary structure, the scissile 5′-UpA-3′ and 5′-CpA-3′ phosphodiester bonds experienced >100- and up to 35-fold reactivity differences, respectively. Compared with dinucleoside monophosphates, both rate accelerations and retardations of more than one order of magnitude were observed. Even a change of a single base several nucleosides away from the scissile bond markedly affected the reaction rate. Duplex formation at the 3′- and/or 5′-side of the scissile bond was also studied and observed to be strongly rate retarding. The origin of the high sensitivity of phosphodiester bonds to the molecular environment is discussed.     

Synthetic constructs functionally mimicking ribonuclease A

The mechanism of hydrolysis of RNA substrates—diribonucleoside monophosphate CpA and decaribonucleotide UUCAUGUAAA—by chemical constructs functionally mimicking ribonuclease A was studied. It is shown that RNA cleavage by chemical RNases 2L2 and 2D3 proceeds similar to the RNase A-induced RNA hydrolysis through 2′,3′-cyclophosphate as an intermediate product. A comparison of hydrolyses of CpA in water and D₂O revealed an isotope effect (K _H/K _D=2.28), which implies acid-base catalysis at the limiting stage of the reaction. Two feasible mechanisms of RNA hydrolysis by chemical RNases (linear and adjacent) are discussed.     

Effect of ionic strength on the hybridization of oligodeoxynucleotides with reduced charge due to methylphosphonate linkages to unmodified oligodeoxynucleotides containing the complementary sequence

A 12-mer oligodeoxynucleotide containing 10 methylphosphonate bonds and 1 phosphodiester bond was shown to bind specifically to the restriction endonuclease fragment containing complementary DNA in a Southern blot. This 12-mer as well as 14-mer oligodeoxynucleotides containing 3 methylphosphonate and 10 phosphodiester bonds was used to examine the effect of reduced charge on the thermodynamics of binding to complementary DNA or complementary oligodeoxynucleotides with additional nucleotides overlapping both the 3' and 5' ends. The 14-mer oligodeoxynucleotides were synthesized with one methylphosphonamidite (A, C, G, or T). Melting profiles were examined by spectrophotometry for the 14-mers and by a gel-shift assay for the 12-mer. Nearest-neighbor free energy values were compiled for predicting concentration-dependent melting temperatures for all oligodeoxynucleotide hybridizations, including those involving adjacent dG residues. The free energy contribution to duplex formation from the dangling ends was about 1 kcal/mol. The free energy decrement due to introduction of each methylphosphonate linkage was -0.75 kcal/mol in high salt independent of the methylphosphonamidite used for synthesis of the oligodeoxynucleotide. However, the change in charge per nearest-neighbor base pair decreased from 0.26 to 0.0 when the nearest-neighbor base pair contained one methylphosphonate. Thus at very low salt, methylphosphonate-substituted oligodeoxynucleotides form more stable hybrids than analogous phosphodiester sequences. The 12-mer with 10 methylphosphonate bonds outcompetes the analogous phosphodiester 12-mer below 0.01 M NaCl. The temperature of 50% dissociation of bound oligodeoxynucleotide after being washed for 30 min was measured with a dot-blot assay. These results, together with the thermodynamic results, indicate that the substitution of methylphosphonate linkages at high salt only affects the reverse rate constant.     

Identification of a non-junction phosphodiester that influences an autolytic processing reaction of RNA.

Oligoribonucleotides with specific sequences derived from the satellite RNA of tobacco ringspot virus undergo autolytic cleavage at the CpA phosphodiester that is the junction between unit sequences of multimeric satellite RNA. Buzayan et al. (Nucleic Acids Res., 16, 4009-4023 (1988)) showed that an oligoribonucleotide with 97 satellite RNA-derived nucleotide residues self-cleaved with greatly reduced efficiency when it was synthesized in vitro from adenosine-5'-O-(1-thiotriphosphate) (abbreviated rATP alpha S) and three rNTPs. No other substitution of one rNTP by the corresponding rNTP alpha S had this effect, suggesting that a phosphorothioate CpA junction inhibits self-cleavage. Here, we replaced the usual CpA junction of a small self-cleaving oligoribonucleotide with a CpU junction. Self-cleavage of this molecule was reduced not only by rUTP alpha S-substitution, as expected, but also by partial and complete rATP alpha S-substitution. By analysis of the locations of rAMPS residues in cleavage products derived from partially rATP alpha S-substituted oligoribonucleotides, we identified A26 as the residue contributing the non-junction phosphorothioate diester that most strongly inhibited self-cleavage. Manganese ions strongly stimulated the self-cleavage of the rATP alpha S-substituted, CpU-junction oligoribonucleotide but was less effective when the junction was CpA.     

Kinetics of intermolecular cleavage by hammerhead ribozymes.

The hammerhead catalytic RNA effects cleavage of the phosphodiester backbone of RNA through a transesterification mechanism that generates products with 2'-3'-cyclic phosphate and 5'-hydroxyl termini. A minimal kinetic mechanism for the intermolecular hammerhead cleavage reaction includes substrate binding, cleavage, and product release. Elemental rate constants for these steps were measured with six hammerhead sequences. Changes in substrate length and sequence had little effect on the rate of the cleavage step, but dramatic differences were observed in the substrate dissociation and product release steps that require helix-coil transitions. Rates of substrate binding and product dissociation correlated well with predictions based on the behavior of simple RNA duplexes, but substrate dissociation rates were significantly faster than expected. Ribozyme and substrate alterations that eliminated catalytic activity increased the stability of the hammerhead complex. These results suggest that substrate destabilization may play a role in hammerhead catalysis.     

Construction of DNA substrates modified with psoralen at a unique site and study of the action mechanism of ABC excinuclease on these uniformly modified substrates

Psoralens bind to DNA noncovalently and upon exposure to near UV (320-400 nm) light produce covalent adducts. Thymidine residues in DNA, especially those at 5'-TpA-3' sequences, are most susceptible to the photochemical reaction. This property of the reaction and the recent advances in oligonucleotide synthesis and separation has enabled us to construct DNA fragments containing psoralen adducts at a specific site. The octanucleotide 5'-TCGTAGCT-3' was photoreacted (in the presence of the complementary strand) with the synthetic psoralen 4'-hydroxymethyl-4,5',8-trimethylpsoralen to obtain oligonucleotides adducted via the furan or pyrone ring at the internal thymine. These modified octanucleotides were ligated to nonmodified oligonucleotides to obtain a 40-base pair DNA fragment containing a psoralen adduct at a central location. The modified fragment having the thymine-furan side 4'-hydroxymethyl-4,5',8-trimethylpsoralen adduct was irradiated with 360 nm of light to produce an interstrand cross-link, and this cross-linked DNA was purified to homogeneity. These uniquely modified DNAs were used as substrates for Escherichia coli ABC excinuclease to determine its incision mechanism unambiguously and to determine the contact sites of the enzyme. ABC excinuclease mediates the cleavage of the 8th and 5th phosphodiester bonds 5' and 3', respectively, to psoralen monoadducts, and the 9th (5') and 3rd (3') phosphodiester bonds to the furan-side thymine of the cross-link. Preliminary DNaseI footprinting studies show that ABC excinuclease protects the whole 40-base pair fragment from DNaseI, and binding of the A and B subunits to the furan side-monoadducted substrate produces two hypersensitive phosphodiester bonds in the vicinity of the 5' incision site of ABC excinuclease.     

Strand scission of deoxyribonucleic acid by neocarzinostatin, auromomycin, and bleomycin: studies on base release and nucleotide sequence specificity

The nucleotide sequence specificity of neocarzinostatin (NCS), auromomycin (AUR), bleomycin (Blm), phleomycin (Phlm), and tallysomycin (Tlm) has been determined by using these antibiotics and their associated chromophores to create strand scissions in end-labeled restriction fragments of DNA and then determining the base sequence of the oligonucleotides formed. NCS and the NCS chromophore induce similar patterns of cleavage in DNA fragments labeled at the 5' terminus. The pattern produced by the AUR chromophore also resembles that of its holoantibiotic. Dithiothreitol enhances the rate of cleavage of DNA by the AUR chromophore but does not alter the sequence specificity. The results suggest that the polypeptide component of AUR and NCS serves primarily as a carrier for the chromophore. When tested with a fragment labeled at the 3' terminus, the products of NCS and AUR cleavage do not display the patterns of chemically produced oligonucleotides cleaved at phosphodiester bonds, suggesting that the 5' terminus is modified by a sugar fragment. NCS primarily attacks thymine (75% of the total bases attacked) and, to a lesser extent, adenine (19%) and cytosine (6%). AUR preferentially attacks guanine (67% of total bases), while attacking less often thymine (24%) and adenine (9%). Bleomycin and its analogues preferentially cleave purine--pyrimidine (5' leads to 3') and pyrimidine--pyrimidine (3' leads to 5') sequences. All (5' leads to 3') GT and GC sequences were cleaved. Phlm G and Phlm-Pep are less active than bleomycin toward purines while Tlm was more active. The patterns of cleavage produced by Blm A2 and Blm B6 are similar, while those produced by Phlm-Pep, Phlm G, Blm-B1', and Blm-Pep resemble one another. The cleavage pattern of Tlm shows quantitative differences from the other analogues tested. Differences between bleomycin and its analogues may be related to structural differences in these molecules.     

Ribonuclease activity of cationic structures conjugated to lipophilic groups

Cationic compounds containing benzene ring substituted with the bis-quaternary salt of diazabicyclo[2.2.2]octane (DABCO) bearing a polymethylene fragment at the bridge positions display ribonuclease activity. Efficacy of the catalysis is affected by geometry of the cationic structures and the size of the attached aliphatic fragment. The cleavage occurs primarily within CA sequences. The compounds do not possess tradition groups participating in the transesterification step of RNA cleavage reaction, therefore a speculative mechanism of cleavage could be inducing a conformational stress on the RNA sugar phosphate backbone providing fragility to phosphodiester bonds.     

A covalent angiogenin/ribonuclease hybrid with a fourth disulfide bond generated by regional mutagenesis

Human angiogenin is a blood vessel inducing protein whose primary structure displays 33% identity to that of bovine pancreatic ribonuclease A (RNase A). Angiogenin catalyzes limited cleavage of 18S and 28S ribosomal RNA and is several orders of magnitude less potent than RNase A toward conventional substrates. A striking structural difference between angiogenin and RNase is the virtual absence of sequence similarity within the region of RNase that contains the Cys-65--Cys-72 disulfide bond. Indeed, angiogenin lacks this disulfide linkage. The present report describes the use of regional mutagenesis to generate a covalent angiogenin/RNase hybrid protein, ARH-I, where residues 58-70 of angiogenin have been replaced by the corresponding segment of RNase A (residues 59-73). The protein expressed in Escherichia coli readily folds at pH 8.5 to form the four expected disulfide bonds. The in vivo angiogenic potency of ARH-I is markedly diminished compared with that of angiogenin when examined using the chick chorioallantoic membrane assay. In contrast, its enzymatic activity is dramatically increased. With high molecular weight wheat germ RNA and tRNA, ARH-I is 660- and 300-fold more active than angiogenin, respectively, while with poly(uridylic acid), poly(cytidylic acid), cytidylyl(3'----5')adenosine (CpA), and uridylyl(3'----5')adenosine (UpA) activity is enhanced by about 200-fold. In addition, the specificity of ARH-I toward dinucleoside 3',5'-phosphates is qualitatively similar to RNase A; while angiogenin prefers cytidylyl(3'----5')guanosine (CpG) to UpA, both RNase and the hybrid prefer UpA to CpG. ARH-I also displays greater than 10-fold enhanced activity toward rRNA in intact ribosomes, while abolishing the capacity of the ribosome to support cell-free protein synthesis. The enhanced enzymatic properties of ARH-I parallel a 2-fold increase in chemical reactivity of active-site lysine and histidine residues based on rates of chemical modification. The data indicate that introduction of a region of RNase A containing the Cys-65--Cys-72 disulfide bond into angiogenin dramatically increases RNase-like enzymatic activity while reducing its angiogenicity.     

Ribonuclease Activity of Cationic Structures Conjugated to Lipophilic Groups

Cationic compounds containing benzene ring substituted with the bis‐quaternary salt of diazabicyclo[2.2.2]octane (DABCO) bearing a polymethylene fragment at the bridge positions display ribonuclease activity. Efficacy of the catalysis is affected by geometry of the cationic structures and the size of the attached aliphatic fragment. The cleavage occurs primarily within CA sequences. The compounds do not possess tradition groups participating in the transesterification step of RNA cleavage reaction, therefore a speculative mechanism of cleavage could be inducing a conformational stress on the RNA sugar phosphate backbone providing fragility to phosphodiester bonds.     

Computer modeling of human angiogenin-dinucleotide substrate interaction

Structures of substrate bound human angiogenin complexes have been obtained for the first time by computer modeling. The dinucleotides CpA and UpA have been docked onto human angiogenin using a systematic grid search procedure in torsion and Eulerian angle space. The docking was guided throughout by the similarity of angiogenin-substrate interactions with interactions of RNase A and its substrate. The models were subjected to 1 nanosecond of molecular dynamics to access their stability. Structures extracted from MD simulations were refined by simulated annealing. Stable hydrogen bonds that bridged protein and ligand residues during the MD simulations were taken as restraints for simulated annealing. Our analysis on the MD structures and annealed models explains the substrate specificity of human angiogenin and is in agreement with experimental results. This study also predicts the B2 binding site residues of angiogenin, for which no experimental information is available so far. In the case of one of the substrates, CpA, we have also identified the presence of a water molecule that invariantly bridges the B2 base with the protein. We have compared our results to the RNase A-substrate complex and highlight the similarities and differences.