The Effect of Divalent Cations and Core Polymerase in the Abortive Initiation by Escherichia Coli Dna-Dependent Rna Polymerase Using Phosphonate Dinucleotide Primers

The effect of divalent Mg²⁺ and Mn²⁺ cations on the elongation of ApU, UpA and their 3'-O- and 5'-O-phosphonylmethyl analogues by RNA polymerase holoenzyme to the corresponding trinucleo-tides on a poly(dA-dT) template was investigated. In contrast to Mg^z+ ions, Mn²⁺ ions enhance abortive trinucleotide synthesis. This effect is more pronounced with phosphonylmethyl analogues. The core enzyme cannot catalyze the elongation of either (2'-5') UpA or phosphonylmethyl analogues. The localization of the divalent cation activator, as well as the role of the σ subunit at the catalytic centre of the holoenzyme, is discussed.     

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.     

Phosphonate and thiophosphate nucleotide analogues in studies of some enzyme reactions

Enzymes which cleave P-O bonds can be blocked by phosphonate analogues of biological phosphates. alpha-Fluorophosphonates are more electronegative at the bridging carbon than simple methylenephosphonates which improves their use for the study of enzymes. Thus, the beta,gamma-difluoromethylene analogue of ATP is a viable substrate for (2----5)An synthetase which converts it into (2----5)An species having a 5'-beta,gamma-difluoromethylene-trisphosphate. This binds strongly to RNase L but does not activate it. The unsymmetrical Ap4Aases from Artemia and lupin are strongly inhibited by P2,P3-fluoromethylenebisphosphonate- and by P1,P4-dithiophosphate-analogues of diadenosyl-5',5"-P1,P4-tetraphosphate while anomalous, non-regiospecific cleavage of some P2,P3-bridged mimics is observed. Certain such analogues inhibit both platelet aggregation in vitro and arterial blood-clotting in rabbits. Separation of the diastereo-isomers of P1,P4-dithiophosphate analogues of Ap4A is achieved using reverse-phase hplc which provides direct access to beta,gamma-CHF-bridged analogues of ATP with resolved stereochemistry at the CHF centre.     

Determinants of substrate specificity for saccharopine dehydrogenase from Saccharomyces cerevisiae

A survey of NADH, alpha-Kg, and lysine analogues has been undertaken in an attempt to define the substrate specificity of saccharopine dehydrogenase and to identify functional groups on all substrates and dinucleotides important for substrate binding. A number of NAD analogues, including NADP, 3-acetylpyridine adenine dinucleotide (3-APAD), 3-pyridinealdehyde adenine dinucleotide (3-PAAD), and thionicotinamide adenine dinucleotide (thio-NAD), can serve as a substrate in the oxidative deamination reaction, as can a number of alpha-keto analogues, including glyoxylate, pyruvate, alpha-ketobutyrate, alpha-ketovalerate, alpha-ketomalonate, and alpha-ketoadipate. Inhibition studies using nucleotide analogues suggest that the majority of the binding energy of the dinucleotides comes from the AMP portion and that distinctly different conformations are generated upon binding of the oxidized and reduced dinucleotides. Addition of the 2'-phosphate as in NADPH causes poor binding of subsequent substrates but has little effect on coenzyme binding and catalysis. In addition, the 10-fold decrease in affinity of 3-APAD in comparison to NAD suggests that the nicotinamide ring binding pocket is hydrophilic. Extensive inhibition studies using aliphatic and aromatic keto acid analogues have been carried out to gain insight into the keto acid binding pocket. Data suggest that a side chain with three carbons (from the alpha-keto group up to and including the side chain carboxylate) is optimal. In addition, the distance between the C1-C2 unit and the C5 carboxylate of the alpha-keto acid is also important for binding; the alpha-oxo group contributes a factor of 10 to affinity. The keto acid binding pocket is relatively large and flexible and can accommodate the bulky aromatic ring of a pyridine dicarboxylic acid and a negative charge at the C3 but not the C4 position. However, the amino acid binding site is hydrophobic, and the optimal length of the hydrophobic portion of the amino acid carbon side chain is three or four carbons. In addition, the amino acid binding pocket can accommodate a branch at the gamma-carbon, but not at the beta-carbon.     

Role of the ribose residue of substrates in reactions catalyzed by ribonuclease

The rate constants and Km for the hydrolysis of the optically active nonglycosidic analogues of the CpA and C greater than p catalysed by RNase A and RNase BS-I were measured. The rate of hydrolysis of the model substrates in 10(5) and 10(3) slower that for the appropriate dinucleoside phosphate and nucleoside cyclophosphate. However, substitution of the relatively rigid ribofuranose ring with flexible alifatic chains is accompanied by little variation in binding constants. The analyses based on the single substrate system indicate that the observed difference in rate constants must be accounted for by a difference between the binding of the substrates in the transition state to the RNase active site. Consequently, the "rigidity" of the ribose rings in RNA leads to large decreases in the free energy of activation for the reactions catalysed by RNases.     

Synthesis of phosphono analogues of dihydroxyacetone phosphate and glyceraldehyde 3-phosphate.

The present paper describes the synthetic routes of six phosphono analogues of dihydroxyacetone phosphate and five phosphono analogues of glyceraldehyde 3-phosphate through alpha-, beta- and gamma-hydroxyphosphonate esters precursors containing a protected carbonyl group. In some situations, depending on the sequence used for the deprotection of the phosphonate and carbonyl groups, the aldol/ketol rearrangement allowed the synthesis of either dihydroxyacetone phosphate or glyceraldehyde 3-phosphate analogues from the same precursors. All these analogues are of interest both as active-site probes and as potential substrates for glycolytic enzymes such as fructose 1,6-diphosphate aldolases (EC 4.1.2.13).     

Synthesis and Potent Anti-HCMV Activity of 2′,5′,5′-trifluoro-3′-hydroxy-apiosyl Nucleoside Phosphonic Acid Analogues

As antiviral nucleosides containing a fluorine atom at 2′-position are endowed with increased stabilization of glycosyl bond, it was of interest to investigate the influence of three fluorine atoms at 2′- and 5′-positions of apiosyl nucleoside phosphonate analogues. Various pyrimidine and purine 2′,5′,5′-trifluoro-3′-hydroxy-apiose nucleoside phosphonic acid analogues were synthesized from 1,3-dihydroxyacetone. Electrophilic fluorination of lactone was performed using N-fluorodibenzenesulfonimide. Difluorophosphonation was performed by direct displacement of triflate intermediate with diethyl(lithiodifluoromethyl) phosphonate to give the corresponding (α,α-difluoroalkyl) phosphonate. Condensation successfully proceeded from a glycosyl donor with persilylated bases to yield nucleoside phosphonate analogues. Deprotection of diethyl phosphonates provided the final phosphonic acid sodium salts. The synthesized nucleoside analogues were subjected to antiviral screening against various viruses.     

Structural basis of cleavage by RNase H of hybrids of arabinonucleic acids and RNA

The origins of the substrate specificity of Escherichia coli RNase H1 (termed RNase H here), an enzyme that hydrolyzes the RNA strand of DNA-RNA hybrids, are not understood at present. Although the enzyme binds double-stranded RNA, no cleavage occurs with such duplexes [Lima, W. F., and Crooke, S. T. (1997) Biochemistry 36, 390]. Therefore, the hybrid substrates may not adopt a canonical A-form geometry. Furthermore, RNase H is exquisitely sensitive to chemical modification of the DNA strands in hybrid duplexes. This is particularly relevant to the RNase H-dependent pathway of antisense action. Thus, only very few of the modifications currently being evaluated as antisense therapeutics are tolerated by the enzyme, among them phosphorothioate DNA (PS-DNA). Recently, hybrids of RNA and arabinonucleic acid (ANA) as well as the 2'F-ANA analogue were shown to be substrates of RNase H [Damha, M. J., et al. (1998) J. Am. Chem. Soc. 120, 12976]. Using X-ray crystallography, we demonstrate here that ANA analogues, such as 2'F-ANA [Berger, I., et al. (1998) Nucleic Acids Res. 26, 2473] and [3.3.0]bicyclo-ANA (bc-ANA), may not be able to adopt sugar puckers that are compatible with pure A- or a B-form duplex geometries, but rather prefer the intermediate O4'-endo conformation. On the basis of the observed conformations of these ANA analogues in a DNA dodecamer duplex, we have modeled a duplex of an all-C3'-endo RNA strand and an all-O4'-endo 2'F-ANA strand. This duplex exhibits a minor groove width that is intermediate between that of A-form RNA and B-form DNA, a feature that may be exploited by the enzyme in differentiating between RNA duplexes and DNA-RNA hybrids. Therefore, the combination of the established structural and functional properties of ANA analogues helps settle existing controversies concerning the discrimination of substrates by RNase H. Knowlegde of the structure of an analogue that exhibits enhanced RNA affinity while not interfering with RNase H activity may prove helpful in the design of future antisense modifications.     

Phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate as substrates or inhibitors of procaryotic and eucaryotic enzymes degrading dinucleoside tetraphosphates

The substrate specificity of procaryotic and eucaryotic AppppA-degrading enzymes was investigated with phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate (AppppA). App(CH2)ppA (I), App(CHBr)ppA (II), and Appp(CH2)pA (III), but not Ap(CH2)pp(CH2)pA (IV), are substrates for lupin AppppA hydrolase (EC 3.6.1.17) and phosphodiesterase I (EC 3.1.4.1). None of the four analogues is hydrolyzed by bacterial AppppA hydrolase (EC 3.6.1.41), and only analogue III is degraded by yeast AppppA phosphorylase (EC 2.7.7.53). The analogues are competitive inhibitors of all four enzymes. The affinity of analogue IV is 3-40-fold lower than that of analogues I-III for all four enzymes. Introduction of one methylene (as in I and III) [or bromomethylene (as in II)] group into AppppA results in a 3-15-fold increase of its affinity for lupin and Escherichia coli AppppA hydrolases. The same modifications only negligibly (10-30%) affect its affinity for yeast AppppA phosphorylase and decrease its affinity for lupin phosphodiesterase I about 2.5-fold. The data provide further evidence for the heterogeneity among catalytic sites of all four AppppA-degrading enzymes.     

Enzymic properties of phosphonic analogues of D-erythrose 4-phosphate

4-Deoxy-D-$\text{erythro}$ tetrose 4-phosphonate and 4,5 dideoxy D-$\text{erythro}$ pentose 5-phosphonate, the phosphonic analogues of D-erythrose 4-phosphate, have been prepared by oxidation of the corresponding analogues of glucose 6-phosphate and tested as substrates of 3-deoxy-D-$\text{arabino}$ heptulosonate 7-phosphate synthetase, transaldolase and transketolase. Kinetic parameters of the reaction with the phosphonate analogues and the natural substrate have been compared.     

Activation and evasion of the antiviral 2'-5' oligoadenylate synthetase/ribonuclease L pathway by hepatitis C virus mRNA

Chronic hepatitis C virus (HCV) infections are a significant cause of morbidity and mortality worldwide. Interferon-alpha2b treatment, alone or in combination with ribavirin, eliminates HCV from some patients, but patients infected with HCV genotype 1 viruses are cured less frequently than patients infected with HCV genotype 2 or 3 viruses. We report that HCV mRNA was detected and destroyed by the interferon-regulated antiviral 2'-5' oligoadenylate synthetase/ ribonuclease L pathway present in cytoplasmic extracts of HeLa cells. Ribonuclease L cleaved HCV mRNA into fragments 200 to 500 bases in length. Ribonuclease L cleaved HCV mRNA predominately at UA and UU dinucleotides within loops of predicted stem-loop structures. HCV mRNAs from relatively interferon-resistant genotypes (HCV genotypes 1a and 1b) have fewer UA and UU dinucleotides than HCV mRNAs from more interferon-sensitive genotypes (HCV genotypes 2a, 2b, 3a, and 3b). HCV 2a mRNA, with 73 more UA and UU dinucleotides than HCV 1a mRNA, was cleaved by RNase L more readily than HCV 1a mRNA. In patients, HCV 1b mRNAs accumulated silent mutations preferentially at UA and UU dinucleotides during interferon therapy. These results suggest that the sensitivity of HCV infections to interferon therapy may correlate with the efficiency by which RNase L cleaves HCV mRNA.     

Identification of c-myc coding region determinant RNA sequences and structures cleaved by an RNase1-like endoribonuclease

The coding region of c-myc mRNA encompassing the coding region determinant (CRD) nucleotides (nts) 1705-1792 is critical in regulating c-myc mRNA stability. This is in part due to the susceptibility of c-myc CRD RNA to attack by an endoribonuclease. We have previously purified and characterized a mammalian endoribonuclease that cleaves c-myc CRD RNA in vitro. This enzyme is tentatively identified as a 35 kDa RNase1-like endonuclease. In an effort to understand the sequence and secondary structure requirements for RNA cleavage by this enzyme, we have determined the secondary structure of the c-myc CRD RNA nts 1705-1792 using RNase probing technique. The secondary structure of c-myc CRD RNA possesses five stems; two of which contain 4 base pairs (stems I and V) and three consisting of 3 base pairs (stems II, III, and IV). Endonucleolytic assays using the c-myc CRD and several c-myc CRD mutants as substrates led to the following conclusions: (i) the enzyme prefers to cleave in between the dinucleotides UA, CA, and UG in single-stranded regions; (ii) the enzyme is more specific towards UA dinucleotides. These properties further distinguish the enzyme from previously described mammalian endonuclease that cleaves c-myc mRNA in vitro.     

Kinetic Properties of Adenine Nucleotide Analogues Against Purified 5-Phosphoribosyl-1-pyrophosphate Synthetases from E. coli,Rat Liver and Human Erythrocytes

Abstract

The nucleoside analogue 2′,3′-dideoxyadenosine (ddA), the phosphonate isostere of 2′,3′-dideoxy-2′,3′-didehydro-adenosine (d4A) 5′-monophosphate (d4API), and the acyclic nucleoside phosphonates PMEoA, PMEA, FPMPA and PMPA are potent and selective antiretroviral agents. We found that these compounds are recognized as substrates by the PRPP synthetases from E. coli, rat liver and human erythrocytes, as their monophosphate and triphosphate form in the reverse and forward reaction, respectively. In particular, ddA-5′-monophosphate (ddAMP) and ddA-5′-triphosphate proved to be excellent substrates for the enzymes. D4API was a relatively good substrate of the rat liver and human erythrocyte PRPP synthetases. The acyclic nucleoside phosphonates were rather poor substrates, as evident from their low V_max values. None of the PRPP synthetases are found to act stereospecifically: they recognized both the S- and R-enantiomers of FPMPA and PMPA in a comparably efficient manner. Our data indicate that PRPP synthetase may recognize a much broader range of adenine nucleotide analogues than previously thought.     

The exo- or endonucleolytic preference of bovine pancreatic ribonuclease A depends on its subsites structure and on the substrate size

The cleavage pattern of oligocytidylic acid substrates by bovine pancreatic ribonuclease A (RNase A) was studied by means of reversed-phase HPLC. Oligocytidylic acids, ranging from dinucleotides to heptanucleotides, were obtained by RNase A digestion of poly(C). They were identified by MALDI-TOF mass spectrometry; it was confirmed that all of them corresponded to the general structure (Cp)(n)C>p, in which C>p indicates a 2',3'-cyclic phosphate. This is a confirmation of the proposed mechanism for RNase A, wherein the so-called hydrolytic (or second) step is in fact a special case of the reverse of transphosphorylation (first step). The patterns of cleavage for the oligonucleotide substrates show that the native enzyme has no special preference for endonucleolytic or exonucleolytic cleavage, whereas a mutant of the enzyme (K7Q/R10Q-RNase A) lacking p(2) (a phosphate binding subsite adjacent, on the 3' side, to the main phosphate binding site p(1)) shows a clear exonucleolytic pattern; a mutant (K66Q-RNase A) lacking p(0) (a phosphate binding subsite adjacent, on the 5' side, to the main phosphate binding site p(1)) shows a more endonucleolytic pattern. This indicates the important role played by the subsites on the preference for the bond cleaved. Molecular modeling shows that, in the case of the p(2) mutant, the amide group of glutamine can form a hydrogen bond with the 2',3'-cyclic terminal phosphate, whereas the distance to a 3',5'-phosphodiester bond is too long to form such a hydrogen bond. This could explain the preference for exonucleolytic cleavage shown by the p(2) mutant.     

Effect of diadenosine oligophosphates (Ap4A and Ap3A) and their phosphonate analogs on catalytic properties of phenylalanyl-tRNA synthetase from E. coli

The influence of P1,P3-bis(5'-adenosyl)triphosphate (Ap3A), P1,P4-bis(5'-adenosyl)tetraphosphate (Ap4A) and its analogues, containing a residue of methylenediphosphonic acid in various positions of the oligophosphate chain, on the reactions catalysed by phenylalanyl-tRNA synthetase from E. coli MRE-600 has been studied. The compounds do not affect significantly the rate of ATP-[32P]PPi-exchange nor maintain this reaction in the absence of ATP. The diadenosineoligophosphates are shown to be noncompetitive inhibitors of ATP in the tRNA aminoacylation by phenylalanine (for Ap4A Ki = 1,45.10(-3) M). The phosphonate analogues of Ap4A inhibit the synthesis of Ap3A depending on their structure. The conclusion is thus drawn that the E. coli MRE-600 phenylalanyl-tRNA synthetase does not interact property with Ap4A and its phosphonate analogues.     

Bis(sulfonamide) isosters of mycophenolic adenine dinucleotide analogues: inhibition of inosine monophosphate dehydrogenase

Synthesis of novel inhibitors of human IMP dehydrogenase is described. These inhibitors are isosteric methylenebis(sulfonamide) analogues 5-8 of earlier reported mycophenolic adenine methylenebis(phosphonate)s 1-3. The parent bis(phosphonate) 1 and its bis(sulfonamide) analogue 5 showed similar sub-micromolar inhibitory activity against IMPDH2 (K(i) approximately 0.2 microM). However, the bis(sulfonamide) analogues 6 and 8 substituted at the position 2 of adenine were approximately 3- to 10-fold less potent inhibitors of IMPDH2 (K(i)=0.3-0.4 microM) than the corresponding parent bis(phosphonate)s 2 and 3 (K(i)=0.04-0.11 microM), respectively.     

The tendency to recreate ancestral CG dinucleotides in the human genome

Background  

The CG dinucleotides are known to be deficient in the human genome, due to a high mutation rate from 5-methylated CG to TG and its complementary pair CA. Meanwhile, many cellular functions rely on these CG dinucleotides, such as gene expression controlled by cytosine methylation status. Thus, CG dinucleotides that provide essential functional substrates should be retained in genomes. How these two conflicting processes regarding the fate of CG dinucleotides - i.e., high mutation rate destroying CG dinucleotides, vs. functional processes that require their preservation remains an unsolved question.     

Substrate recognition and catalysis by the exoribonuclease RNase R

RNase R is a processive, 3' to 5' hydrolytic exoribonuclease that together with polynucleotide phosphorylase plays an important role in the degradation of structured RNAs. However, RNase R differs from other exoribonucleases in that it can by itself degrade RNAs with extensive secondary structure provided that a single-stranded 3' overhang is present. Using a variety of specifically designed substrates, we show here that a 3' overhang of at least 7 nucleotides is required for tight binding and activity, whereas optimum binding and activity are achieved when the overhang is 10 or more nucleotides in length. In contrast, duplex RNAs with no overhang or with a 4-nucleotide overhang bind extremely poorly to RNase R and are inactive as substrates. A duplex RNA with a 10-nucleotide 5' overhang also is not a substrate. Interestingly, this molecule is bound only weakly, indicating that RNase R does not simply recognize single-stranded RNA, but the RNA must thread into the enzyme with 3' to 5' polarity. We also show that ribose moieties are required for recognition of the substrate as a whole since RNase R is unable to bind or degrade single-stranded DNA. However, RNA molecules with deoxyribose or dideoxyribose residues at their 3' termini can be bound and degraded. Based on these data and a homology model of RNase R, derived from the structure of the closely related enzyme, RNase II, we present a model for how RNase R interacts with its substrates and degrades RNA.     

Phosphonate analogue substrates for enolase

Phosphonate analogues in which the bridge between C-2 and phosphorus is a CH2 group are slow substrates for yeast enolase. The pH variation of the kinetic parameters for the methylene analogue of 2-phosphoglycerate suggests that the substrate binds as a dianion and that Mg2+ can bind subsequently only if a metal ligand and the catalytic base are unprotonated. Primary deuterium isotope effects of 4-8 on V/KMg, but ones of only 1.15-1.32 on V for dehydration, show that proton removal to give the carbanion intermediate largely limits V/KMg and that a slow step follows which largely limits V (presumably carbanion breakdown). Since there is a D2O solvent isotope effect on V for the reverse reaction of 5, but not an appreciable one on the forward reaction, it appears that the slow rates with phosphonate analogues result from the fact that the carbanion intermediate is more stable than that formed from the normal substrates, and its reaction in both directions limits V. Increased stability as a result of replacement of oxygen by carbon at C-2 of the carbanion is the expected chemical behavior.