Purine nucleoside phosphorylase of rabbit liver. Mechanism of catalysis.

Initial velocity studies and product inhibition patterns for purine nucleoside phosphorylase from rabbit liver were examined in order to determine the predominant catalytic mechanism for the synthetic (forward) and phosphorolytic (reverse) reactions of the enzyme. Initial velocity studies in the absence of products gave intersecting or converging linear double reciprocal plots of the kinetic data for both the synthetic and phosphorolytic reactions of the enzyme. The observed kinetic pattern was consistent with a sequential mechanism, requiring that both substrates add to the enzyme before products may be released. The product inhibition patterns showed mutual competitive inhibition between guanine and guanosine as variable substrates and inhibitors. Ribose 1-phosphate and inorganic orthophosphate were also mutually competitive toward each other. Other combinations of substrates and products gave noncompetitive inhibition. Apparent inhibition constants calculated for guanine as competitive inhibitor and for ribose 1-phosphate as noncompetitive inhibitor of the enzyme, with guanosine as variable substrate, did not vary significantly with increasing concentrations of inorganic orthophosphate as fixed substrate. These results suggest that the mechanism was order and that substrates add to the enzyme in an obligatory order. Dead end inhibition studies carried out in the presence of the products guanine and ribose 1-phosphate, respectively, showed that the kinetically significant abortive ternary complexes of enzyme-guanine-inorganic orthophosphate (EQB) and enzyme-guanose-ribose 1-phosphate (EAP) are formed. The results of dead end inhibition studies are consistent with an obligatory order of substrate addition to the enzyme. The nucleoside or purine is probably the first substrate to form a binary complex with the enzyme, and with which inorganic orthophosphate or ribose 1-phosphate may interact as secondary substrates. The evidences presented in this investigation support an Ordered Theorell-Chance mechanism for the enzyme.     

Purine salvage in Entamoeba histolytica

Pulse-labeling of the nucleotide pool in Entamoeba histolytica with radioactive precursors, and subsequent high performance liquid chromatographic (HPLC) analysis of the radiolabeled nucleotides, indicate that E. histolytica is incapable of de novo synthesis of purine nucleotides. Hypoxanthine, inosine and xanthine could not be converted to nucleotides in E. histolytica, which suggests the absence of interconversion between adenine nucleotides and guanine nucleotides through formation of IMP. Adenosine was actively incorporated into nucleotides at an initial rate of 130 pmoles per minute per 10(6) trophozoites. Adenine, guanosine and guanine were also incorporated at much lower rates. The rate of adenine incorporation was enhanced by the presence of guanosine; the rate of guanine incorporation was significantly increased by adenosine. These stimulatory effects suggest that the ribose moiety of adenosine or guanosine can be transferred to another purine base to form a new nucleoside, and that the purine nucleosides are the immediate precursors of E. histolytica nucleotides. HPLC results showed that the radiolabel in adenine was exclusively incorporated into adenine nucleotides and that guanine was found only among guanine nucleotides, whereas the radioactivity associated with the ribose moiety of adenosine or guanosine was distributed among both adenine and guanine nucleotides.     

Tissue distribution and metabolism of guanosine in rats following intraperitoneal injection

Guanosine has long been known as an endogenous purine nucleoside deeply involved in the modulation of several intracellular processes, especially G-protein activity. More recently, it has been reported to act as an extracellular signaling molecule released from neurons and, more markedly, from astrocytes either in basal conditions or after different kinds of stimulation including hypoxia. Moreover, in vivo studies have shown that guanosine plays an important role as both a neuroprotective and neurotrophic agent in the central nervous system. Specific high-affinity binding sites for this nucleoside have been found on membrane preparations from rat brain. The present study was undertaken to investigate the distribution and metabolic profiles of guanosine after administering the nucleoside to gain a better understanding of the biological effects of this potential drug candidate. Rats were given an intraperitonal (i.p.) injection of 2, 4, 8 or 16 mg/kg of guanosine combined with 0.05% of [3H]guanosine. Plasma samples were collected 7.5, 15, 30, 60 and 90 min after the guanosine-mixture administration and analyzed by either a liquid scintillation counter or by HPLC connected to a UV and to an on-line radiochemical detector to measure the levels of guanosine and its metabolic products guanine, xanthine and uric acid. The levels of guanosine, guanine and xanthine were also measured in brain, lung, heart, kidney and liver tissue homogenates at the defined time points after the injection of 8 mg/kg of the guanosine-mixture. We found that the levels of radioactivity in plasma increased linearly in a dose- and time-dependent manner. Guanosine was widely distributed in all tissues examined in the present study, at almost twice its usual levels. In addition, guanine levels dramatically increased in all the organs. Interestingly, enzymatic analysis of the plasma samples showed the presence of a soluble purine nucleoside phosphorylase, a key enzyme in the purine salvage pathway and nucleoside catabolism. Since guanosine has been shown to be neuroprotective and astrocytes have been reported to play critical roles in mediating neuronal survival and functions in different neurodegenerative disorders, we also performed uptake and release.     

Preservation of red blood cells with purines and nucleosides. II. Uptake and utilization of purines and nucleosides by stored red blood cells

The uptake of adenine, guanine, guanosine and inosine by stored red cells was investigated in whole blood and red cell resuspensions at initial concentrations of 0.25, 0.5 and 0.75 mM for adenine and 0.5 mM for the other additives using a rapid ion-exchange chromatographic microanalysis of purines and nucleosides in plasma and whole blood. Increasing adenine concentrations from 0.25 to 0.75 mM in blood elevated the adenine uptake from 0.3 up to 0.8 mmol/l red cells during 2 hours after collecting blood. The intra-/extracellular distribution ratio changed from 1 : 1.3 to 1: 1.7. Some 2 hours after withdrawing blood into CPD--solution with purines and nucleosides the uptake of adenine and guanine resulted in 40 per cent and 70 per cent respectively and of guanosine and inosine in 80 and 90 per cent respectively. The replacement of plasma by a resuspending solution gave the same uptake rates for purines and nucleosides. The nucleosides were rapidly split to purines and R-1-P and disappeared from blood during one week. Adenine and guanine were utilized to 80 to 90 per cent only after 3 weeks. During the same period the utilization of guanine was smaller by 40 per cent than that of adenine due to the different activity of the purine nucleoside phosphorylase for these substrates. The plasma of all analyzed blood samples contained hypoxanthine and inosine, but guanine and guanosine were detected only in those samples to which one of them was added. After 3 weeks of storage the highest concentration of hypoxanthine was found in CPD-AI blood with 600 microM in plasma and the highest concentration of synthesized inosine in CPD-AG blood with a concentration of 100 microM in plasma. Three ways of utilization of purines by stored red cells were discussed : the synthesis of nucleotide monophosphates, the formation of nucleosides, and the deamination. The portions of these ways change during storage. The most effective concentrations of adenine and guanosine in stored blood seems to be 0.25 and 0.5 mM respectively. The full utilization of the nucleoside requires the addition of inorganic phosphate.     

Guanosine Deaminase and Guanine Deaminase from Tea Leaves

Guanosine deaminase and guanine deaminase were partially purified from tea leaves. The optimum activity of guanosine deaminase was observed at pH 7.5 and that of guanine deaminase was at pH 7.0–7.5 and 8.5. Guanosine deaminase was an unstable enzyme. The activities of these deaminases were significantly inhibited by heavy metals. Molecular weights of guanosine deaminase and guanine deaminase as measured by gel filtration were about 18,000 and 54,000, respectively. The K_m for the respective substrates, guanosine and guanine, were 9.5 μm and 41.7 μm. Guanosine deaminase was considered to catalyze the deamination of 2′-deoxyguanosine besides guanosine. It is suggested that guanosine deaminase as well as guanine deaminase in tea leaves not only acts on the catabolic pathway, but also is involved in the biosynthesis of caffeine from guanosine or guanine nucleotides.     

Pentatrichomonas hominis: purine salvage pathway

1. Pentatrichomonas hominis was found incapable of de novo synthesis of purines. 2. Pentatrichomonas hominis can salvage adenine, guanine, hypoxanthine, adenosine, guanosine and inosine, but not xanthine for the synthesis of nucleotides. 3. HPLC tracing of radiolabelled purines or purine nucleosides revealed that adenine, adenosine and hypoxanthine are incorporated into adenine nucleotides and IMP through a similar channel while guanine and guanosine are salvaged into guanine nucleotides via another route. There appears to be no direct interconversion between adenine and guanine nucleotides. Interconversion between AMP and IMP was observed. 4. Assays of purine salvage enzymes revealed that P. hominis possess adenosine kinase; adenosine, guanosine and inosine phosphotransferases; adenosine, guanosine and inosine phosphorylases and AMP deaminase.     

Hormone-stimulated polyphosphoinositide breakdown in rat liver plasma membranes. Roles of guanine nucleotides and calcium

Calcium-sensitive inositide release in a purified rat liver plasma membrane preparation is increased by calcium-mobilizing hormones in the presence of guanine nucleotides. Vasopressin-stimulated inositide release is evident in the presence of GTP or its nonhydrolyzable analogs guanyl-5'-yl imidodiphosphate and guanosine 5'-(3-O-thio)triphosphate (GTP gamma S). The stimulation of inositide release by (-)-epinephrine (alpha 1), angiotensin II, or vasopressin in the presence of either 1 microM or 10 microM GTP gamma S correlates with the number of receptors present for each hormone. The guanine nucleotide and hormonal stimulation is evident on both inositol trisphosphate production and phosphatidylinositol bisphosphate degradation. Ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (1 mM) completely abolishes stimulation by guanine nucleotides and hormone. Prior treatment of plasma membranes with cholera toxin or islet activating protein or prior injection of animals with islet activating protein does not affect stimulation of inositide release by GTP gamma S or GTP gamma S plus vasopressin. Stimulation by GTP gamma S is dependent upon magnesium and is inhibitable by guanosine 5'-(2-O-thio) diphosphate. Inositide release from the plasma membrane exhibits half-maximal stimulation by calcium at approximately 100 nM free calcium in the presence of 1.5 mM MgCl2 and at approximately 10 microM free calcium in the presence of 10 mM MgCl2. Addition of guanine nucleotides decreases the requirement for calcium and also increases the activity at saturating calcium. The results presented suggest that calcium-mobilizing hormones stimulate polyphosphoinositide breakdown in rat liver plasma membranes through a novel guanine nucleotide binding protein.     

Quisqualate-Stimulated Phosphatidylinositol Breakdown in Rat Cerebellar Membranes

The effect of quisqualate, an excitatory amino acid agonist, on the breakdown of exogenously added phosphatidylinositol was investigated in a membrane preparation from the cerebellum of young rats. Quisqualate stimulated phospholipase C activity in a dose-dependent manner in the presence of guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S). Half-maximal activation of the quisqualate response required 0.15 microM GTP gamma S and was optimal at a free Ca2+ concentration of 300 nM. Phosphoinositide breakdown was also stimulated by quisqualate using either exogenous phosphatidylinositides 4,5-bisphosphate or endogenous labeled phosphoinositides as the substrate for phospholipase C in cerebellar membranes. In the presence of guanine nucleotides, other excitatory amino acid agonists, such as L-glutamate, trans-D,L-1-aminocyclopentyl-1,3-dicarboxylic acid, and ibotenate, but not N-methyl-D-aspartate, stimulated phosphatidylinositol breakdown. However, quisqualate displayed the highest response among these excitatory amino acid agonists. These data indicate that there is a direct activation of phosphoinositide-specific phospholipase C by excitatory amino acids through a process dependent on the presence of guanine nucleotides.     

Guanosine 5'-O-thiotriphosphate stimulates phospholipase C activity in plasma membranes of rat hepatocytes

The guanine nucleotide analogue, guanosine 5'-O-thiotriphosphate (GTP gamma S) stimulated plasma membrane-associated phospholipase C. Phosphoinositides were the substrates for the reaction. Significant losses of phosphatidylinositol bisphosphate and phosphatidylinositol phosphate occurred at lower doses of GTP gamma S than did significant loss of phosphatidylinositol. Loss of 32P-labeled phosphatidylinositol bisphosphate was equal when plasma membranes were treated with either 100 microM GTP or 100 microM GTP gamma S, but accumulation of inositol trisphosphate was more apparent when the nonhydrolyzable analogue was used. The action of GTP gamma S alone was not dependent on Ca2+ although loss of 32P-labeled phosphoinositides was stimulated by Ca2+ alone or with GTP gamma S. The results are consistent with a role for guanine nucleotide binding proteins in the activation of membrane-bound phosphoinositide-specific phospholipase C.     

Regulation of purine utilization in bacteria. VI. Characterization of hypoxanthine and guanine uptake into isolated membrane vesicles from Salmonella typhimurium.

Uptake of hypoxanthine and guanine into isolated membrane vesicles of Salmonella typhimurium TR119 was stimulated by 5'-phosphoribosyl-1'-pyrophosphate (PRPP). For strain proAB47, a mutant that lacks guanine phosphoribosyltransferase, PRPP stimulated uptake of hypoxanthine into membrane vesicles. No PRPP-stimulated uptake of guanine was observed. For strain TR119, guanosine 5'-monophosphate and inosine 5'-monophosphate accumulated intravesicularly when guanine and hypoxanthine, respectively, were used with PRPP as transport substrates. For strain proAB47, IMP accumulated intravesicularly with hypoxanthine and PRPP as transport substrates. For strain TR119, hypoxanthine also accumulated when PRPP was absent. This free hypoxanthine uptake was completely inhibited by N-ethylmaleimide, but the PRPP-stimulated uptake of hypoxanthine was inhibited only 20% by N-ethylmaleimide. Hypoxanthine and guanine phosphoribosyltransferase activity paralleled uptake activity in both strains. But, when proAB47 vesicles were sonically treated to release the enzymes, a three- to sixfold activation of phosphoribosyltransferase molecules occurred. Since proAB47 vessicles lack the guanine phsophoribosyltransferase gene product and since hypoxanthine effectively competes out the phosphoribosylation of guanine by proAB47 vesicles, it was postulated that the hypoxanthine phosphoribosyltransferase gains specificity for both guanine and hypoxanthine when released from the membrane. A group translocation as the major mechanism for the uptake of guanine and hypoxanthine was proposed.     

Remyelination after chronic spinal cord injury is associated with proliferation of endogenous adult progenitor cells after systemic administration of guanosine

Axonal demyelination is a consistent pathological sequel to chronic brain and spinal cord injuries and disorders that slows or disrupts impulse conduction, causing further functional loss. Since oligodendroglial progenitors are present in the demyelinated areas, failure of remyelination may be due to lack of sufficient proliferation and differentiation of oligodendroglial progenitors. Guanosine stimulates proliferation and differentiation of many types of cells in vitro and exerts neuroprotective effects in the central nervous system (CNS). Five weeks after chronic traumatic spinal cord injury (SCI), when there is no ongoing recovery of function, intraperitoneal administration of guanosine daily for 2 weeks enhanced functional improvement correlated with the increase in myelination in the injured cord. Emphasis was placed on analysis of oligodendrocytes and NG2-positive (NG2+) cells, an endogenous cell population that may be involved in oligodendrocyte replacement. There was an increase in cell proliferation (measured by bromodeoxyuridine staining) that was attributable to an intensification in progenitor cells (NG2+ cells) associated with an increase in mature oligodendrocytes (determined by Rip+ staining). The numbers of astroglia increased at all test times after administration of guanosine whereas microglia only increased in the later stages (14 days). Injected guanosine and its breakdown product guanine accumulated in the spinal cords; there was more guanine than guanosine detected. We conclude that functional improvement and remyelination after systemic administration of guanosine is due to the effect of guanosine/guanine on the proliferation of adult progenitor cells and their maturation into myelin-forming cells. This raises the possibility that administration of guanosine may be useful in the treatment of spinal cord injury or demyelinating diseases such as multiple sclerosis where quiescent oligodendroglial progenitors exist in demyelinated plaques.     

Mitochondrial metabolism of guanine nucleotides. Possible role of guanosine

The catabolism of intramitochondrial guanine nucleotides was examined. During 30 min incubation of rat liver mitochondria at 37 degrees C in the presence of oligomycin and carboxyatractyloside, guanine and xanthine were formed and appeared in the medium. Under these conditions, the direct conversion of GMP to guanine by hypoxanthine-guanine phosphoribosyltransferase is suggested to be the main catabolic route within the organelles. Only very small amounts of guanosine were produced and detected both inside and outside the organelles. [14C]Guanosine and [14C]inosine were taken up by the mitochondria. Therefore, guanosine is suggested to be a precursor of intramitochondrial guanine nucleotides.     

Interconversion and uptake of nucleotides, nucleosides, and purine bases by the marine bacterium MB22.

Whole cells and isolated membranes of the marine bacterium MB22 converted nucleotides present in the external medium rapidly into nucleosides and then into bases. Nucleosides and purine bases formed were taken up by distinct transport systems. We found a high-affinity common transport system for adenine, guanine, and hypoxanthine, with a Km of 40 nM. This system was inhibited noncompetitively by purine nucleosides. In addition, two transport systems for nucleosides were present: one for guanosine with a Km of 0.8 microM and another one for inosine and adenosine with a Km of 1.4 microM. The nucleoside transport systems exhibited both mixed and noncompetitive inhibition by different nucleosides other than those translocated; purine and pyrimidine bases had no effect. The transport of nucleosides and purine bases was inhibited by dinitrophenol or azide, thus suggesting that transport is energy dependent. Inside the cell all of the substrates were converted mainly into guanosine, xanthine, and uric acid, but also anabolic products, such as nucleotides and nucleic acids, could be found.     

Guanosine Formation from Guanine by Bacillus licheniformis

Adenine-auxotrophic mutant of Bacillus licheniformis formed considerable amount of guanosine from guanine. The guanosine formation was stimulated by the addition of penicillin to the growing cells and by the presence of uridine in the crude extract. The crude extract preserved for long time showed the changes of the enzyme actions for added guanine.     

Ethanol does not stimulate guanine nucleotide-induced activation of phospholipase C in permeabilized hepatocytes

Guanine nucleotides are thought to mediate the interaction of the receptors for calcium-mobilizing hormones and phosphoinositide-specific phospholipase C. In the present study the characteristics of guanine nucleotide-dependent phospholipase C activation were studied in [3H]inositol-labeled permeabilized hepatocytes. The nonhydrolyzable GTP analogs guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) and guanyl-5'-yl imidodiphosphate stimulated the production of inositol phosphates by phospholipase C. The effect was concentration-dependent with half-maximal and maximal stimulation occurring with 0.6 and 10 microM GTP gamma S, respectively. The guanine nucleotide-induced stimulation of phosphoinositide breakdown was selective for phosphatidylinositol (4,5)-bisphosphate over phosphatidylinositol (4)-phosphate. The individual inositol phosphates formed after maximal GTP gamma S exposure were analyzed by high-performance liquid chromatography. Inositol 1,4,5-trisphosphate was rapidly produced, followed by the formation of inositol 1,3,4,5-tetrakisphosphate and inositol 1,3,4-trisphosphate. Ethanol is known to activate hormone-sensitive phospholipase C in intact rat hepatocytes. Ethanol (0.3 M) was ineffective in altering the characteristics of GTP gamma S-stimulated phospholipase C activation, in both digitonin-treated and sonicated hepatocytes. The metabolism of the various inositol phosphate isomers was unaffected by ethanol. The findings demonstrate the potential for the use of permeabilized hepatocytes in the analysis of phospholipase C activation by guanine nucleotides. Ethanol does not activate phospholipase C by altering this process.     

Covalent binding of LTA(4) to nucleosides and nucleotides

Leukotriene A(4) (LTA(4)) is a chemically reactive conjugated triene epoxide that is formed by 5-lipoxygenase and is an intermediate in the formation of the biologically active eicosanoids leukotriene B(4) and leukotriene C(4). The present study was undertaken to determine whether or not LTA(4) could serve as an electrophilic species that nucleosides and nucleotides could attack, ultimately resulting in a covalent adduct. Electrospray ionization mass spectrometry and tandem mass spectrometry were used to study the covalent binding of LTA(4) with uridine, cytidine, adenosine, and guanosine. The reaction with guanosine was found to yield five major and at least six minor adduct species. Reversed phase HPLC and mass spectrometric data suggested that the guanosine attacked LTA(4) either at carbon-12 or carbon-6 with opening the epoxide at carbon-5 to yield a series of adducts characterized by the molecular anion [M-H](-) at m/z 600.3. Reactions of LTA(4) with mixtures of nucleosides and nucleotides revealed that guanine-containing nucleosides were the most reactive toward LTA(4). The facility of the reaction of guanine with LTA(4) raises the possibility that this intermediate of leukotriene biosynthesis formed on or near the cellular nuclear envelope may react with nucleosides and nucleotides present in RNA or DNA.     

Purine metabolism and urate biosynthesis in isolated chicken hepatocytes

The metabolism of some purine compounds to urate and their effects on de novo urate synthesis in chicken hepatocytes were investigated. The purines, listed in descending order of rates of catabolism to urate, were hypoxanthine, xanthine, inosine, guanosine, guanine, IMP, GMP, adenosine, AMP, and adenine. During a 1-h incubation period, conversion to urate accounted for more than 80% of the total quantities of guanine, guanosine, and inosine metabolized, but only 42% of the adenosine and 23% of the adenine metabolism. Adenine, adenosine, and AMP inhibited de novo urate synthesis [( 14C]formate incorporation into urate), whereas the other purines, especially guanine, guanosine, and GMP, stimulated de novo urate synthesis. When hepatocytes were incubated with glutamine and adenosine, AMP, guanine, guanosine, or GMP, the rates of de novo urate synthesis were lower than the additive effects of glutamine and the purine in separate incubations. Increasing phosphate concentrations had no effect on urate synthesis in the absence of added purines but, in combination with adenosine, AMP, guanosine, or GMP, increased urate synthesis. These results indicate that the ratio of adenine to guanine nucleotides and the interaction between substrates and purine nucleotides are involved in the regulation of urate biosynthesis in chicken liver.     

Binding of Substrates by Purine Nucleoside Phosphorylase (PNP) from Cellulomonas Sp. - Kinetic and Spectrofluorimetric Studies

Abstract

Dissociation constants and stoichiometry of binding for interaction of Cellulomonas sp. purine nucleoside phosphorylase with its substrates: inosine/guanosine, orthophosphate, guanine/hypoxanthine and D-ribose-1-phosphate were studied by kinetic and spectrofluorimetric methods.     

Nucleotide sequence of a yeast tRNAArg3A gene and its transcription in a homologous in vitro system

Neutrophil homogenates contained a high affinity guanosine triphosphatase (GTPase) that was stimulatable (+27%) by the addition of 100 nM N-formyl chemotactic peptide (CHO-pep), but not by 1 microgram X ml-1 phorbolmyristate acetate (PMA). Kinetic analysis of the stimulation demonstrated an apparent lagtime of 14.3 +/- 6.9 s between the addition of CHO-pep and the optimal GTPase stimulation. The GTPase activity (but not CHO-pep-stimulated GTPase activity) was preserved in a highly purified plasma membrane fraction of the homogenate. From these observations we suggest that both a high affinity guanine nucleotide binding protein and GTPase are closely associated with the plasma membrane CHO-pep receptor. The possibility that GTPase activity may influence guanine nucleotide regulation of adenylate cyclase during CHO-pep stimulation of neutrophils is discussed.     

"Asymmetric" opening reaction mechanism of Z-DNA base pairs: a hydrogen exchange study

With the tritium-Sephadex method, the hydrogen-exchange kinetics of the five NH protons of guanine and cytosine residues in Z-form poly(dG-dC) X poly (dG-dC) were measured as a function of temperature and catalyst concentration. Over the measured temperature range from 0 to 34 degrees C, two classes of protons with constant amplitudes are found. The three protons of the fast class, which were assigned to the guanine amino and imino protons, have an exchange half-time in the minute time range (at 20 degrees C the half-time is 2.5 min) and an activation energy of 18 kcal mol-1. Since these two types of protons exchange at the same rate in spite of their grossly different pK values, the exchange of these protons must be limited by the same nucleic acid conformational change. The two cytosine amino protons of the slow class are especially slow with exchange half-times in the hour time range (at 20 degrees C the exchange half-time is 1 h) and the activation energy is 20 kcal mol-1. The exchange of these two protons is not limited by some nucleic acid conformational change as shown by the marked exchange acceleration of these protons upon addition of 0.2 M imidazole. In addition, we have also reexamined the hydrogen-deuterium exchange kinetics of the amino protons of guanosine cyclic 2',3'-monophosphate by a spectral difference method using a stopped-flow spectrophotometer. The measured kinetic process is monophasic with a rate constant of 3 s-1 at 20 degrees C, which is in the same range as the predicted rate constant of the guanine amino protons.(ABSTRACT TRUNCATED AT 250 WORDS)