A massive rock and ice avalanche caused the 2021 disaster at Chamoli, Indian Himalaya.

On 7 February 2021, a catastrophic mass flow descended the Ronti Gad, Rishiganga, and Dhauliganga valleys in Chamoli, Uttarakhand, India, causing widespread devastation and severely damaging two hydropower projects. More than 200 people were killed or are missing. Our analysis of satellite imagery, seismic records, numerical model results, and eyewitness videos reveals that ~27 × 106 cubic meters of rock and glacier ice collapsed from the steep north face of Ronti Peak. The rock and ice avalanche rapidly transformed into an extraordinarily large and mobile debris flow that transported boulders greater than 20 meters in diameter and scoured the valley walls up to 220 meters above the valley floor. The intersection of the hazard cascade with downvalley infrastructure resulted in a disaster, which highlights key questions about adequate monitoring and sustainable development in the Himalaya as well as other remote, high-mountain environments.

5-Ethyldeoxyuridine, a thymidine analog: photochemical transformation.

Irradiation at 254 millimicrons transforms 5-ethyldeoxyuridine to deoxyuridine by way of photohydration of the 5,6 bond and elimination of ethanol. At wavelengths to the red side of 265 millimicrons, photodimerization is the principal reaction, with a pronounced oxygen effect. The results are related to the photochemistry of thymidine and of bacteriophages containing incorporated 5-ethyluracil in place of thymine.

Photochemical transformation of 5-alkyluracils and their nucleosides.

Irradiation at 254 nm of aqueous solutions of 5-ethyl-, 5-propyl-, and 5-isopropyluracils (or their nulcleosides) leads to cleavage of the 5-alkyl substituents, via an intramolecular electrocyclic photoaddition intermediate, with formation of uracil (or its nucleoside). The plhotoaddition intermediates represent a new class of dihydropyrimidines, namely analogs of 5,6-dihydro-5,6-cyclobutanyluracil and its nucleosides; the biological significance is discussed.

Geomorphic and geologic controls of geohazards induced by Nepal's 2015 Gorkha earthquake.

The Gorkha earthquake (magnitude 7.8) on 25 April 2015 and later aftershocks struck South Asia, killing ~9000 people and damaging a large region. Supported by a large campaign of responsive satellite data acquisitions over the earthquake disaster zone, our team undertook a satellite image survey of the earthquakes' induced geohazards in Nepal and China and an assessment of the geomorphic, tectonic, and lithologic controls on quake-induced landslides. Timely analysis and communication aided response and recovery and informed decision-makers. We mapped 4312 coseismic and postseismic landslides. We also surveyed 491 glacier lakes for earthquake damage but found only nine landslide-impacted lakes and no visible satellite evidence of outbursts. Landslide densities correlate with slope, peak ground acceleration, surface downdrop, and specific metamorphic lithologies and large plutonic intrusions.

Formycins A and B and some analogues: selective inhibitors of bacterial (Escherichia coli) purine nucleoside phosphorylase.

Formycin B (FB), a moderate inhibitor (Ki approximately 100 microM) of mammalian purine nucleoside phosphorylase (PNP), and formycin A (FA), which is totally inactive vs. the mammalian enzyme, are both effective inhibitors of the bacterial (Escherichia coli) enzyme (Ki approximately 5 microM). Examination of a series of N-methyl analogues of FA and FB led to the finding that N(6)-methyl-FA, virtually inactive vs. the mammalian enzyme, is the most potent inhibitor of E. coli purine nucleoside phosphorylase (Ki approximately 0.3 uM) at neutral pH. Inhibition is competitive not only with respect to Ino, but also relative to 7-methyl-Guo and 7-methyl-Ado, as substrates. Both oxoformycins A and B are relatively poor inhibitors. For the most potent inhibitor, N(6)-methyl-FA, it was shown that the enzyme preferentially binds the neutral, and not the cationic, form. In accordance with this the neutral, but not the cationic form, of the structurally related N(1)-methyl-Ado was found to be an excellent substrate. Reported data on tautomerism of formycins were profited from, and extended, to infer which tautomeric species and ionic forms are the active inhibitors. A commercially available (Sigma) bacterial PNP, of unknown origin, was shown to differ from the E. coli enzyme by its inability to phosphorylase Ado; this enzyme was also resistant to FA and FB. These findings have been extended to provide a detailed comparison of the substrate/inhibitor properties of PNP from various microorganisms.

Benzimidazole nucleoside analogues as inhibitors of plant (maize seedling) casein kinases.

Halogeno benzimidazole and benzimidazole nucleoside analogues have been screened for inhibitory activity vs. purified plant (maize seedling) casein kinases I, IIA and IIB, and the results compared with those previously reported for some of the compounds as inhibitors of the corresponding mammalian CK-1 and CK-2 (Meggio et al. (1990) Eur. J. Biochem. 187, 89-94). One new analogue, the riboside of 5,7-dibromobenzimidazole, which is sterically constrained to the anti conformation about the glycosidic bond, and is a good inhibitor, exhibited appreciable (5-7-fold) discrimination between the type I and type II enzymes. An increase in the number of halogen substituents on the benzene ring of benzimidazole from two to three led to marked enhancement of inhibitory activity, particularly against the type II enzymes, with a decrease in Ki from 24 to 4 microM. The 2-aza analogue of 5,6-dichlorobenzimidazole, i.e. 5,6-dichlorobenzotriazole, as the free base, even more effectively discriminated between the two types of plant casein kinases, with Ki approximately 100 microM for CK-I, and Ki approximately 9 microM for CK-IIA and CK-IIB. Inhibition in all instances was competitive with respect to ATP (for CK-I), and ATP and GTP (for CK-IIA and CK-IIB). The results are compared with those for halogenated isoquinolinesulfonamide inhibitors reported by Chijiwa et al. (J. Biol. Chem. (1989) 264, 4924-4927), leading to proposals for the synthesis of potentially more effective and more discriminating inhibitors. Attention is drawn to the significant role of the halogen substituents in the mechanism(s) of action of the structurally related benzimidazole, benzotriazole and naphthalene and isoquinoline, inhibitors of protein kinases.

Interaction of Escherichia coli purine nucleoside phosphorylase (PNP) with the cationic and zwitterionic forms of the fluorescent substrate N(7)-methylguanosine.

Steady-state and time-resolved fluorescence spectroscopy, and enzyme kinetics, were applied to study the reaction of purine nucleoside phosphorylase (PNP) from Escherichia coli with its substrate N(7)-methylguanosine (m7Guo), which consists of an equilibrium mixture of cationic and zwitterionic forms (pK(a)=7.0), each with characteristic absorption and fluorescence spectra, over the pH range 6-9, where absorption and intrinsic fluorescence of the enzyme are virtually unchanged. The pH-dependence of kinetic constants for phosphorolysis of m7Guo were studied under condition where the population of the zwitterion varied from 10% to 100%. This demonstrated that, whereas the zwitterion is a 3- to 6-fold poorer substrate, if at all, than the cation for the mammalian enzymes, both ionic species are almost equally good substrates for E. coli PNP. The imidazole-ring-opened form of m7Guo is neither a substrate nor an inhibitor of phosphorolysis. Enzyme fluorescence quenching, and concomitant changes in absorption and fluorescence spectra of the two ionic species of m7Guo on binding, showed that both forms are bound by the enzyme, the affinity of the zwitterion being 3-fold lower than that of the cation. Binding of m7Guo is bimodal, i.e., an increase in ligand concentration leads to a decrease in the association constant of the enzyme-ligand complex, typical for negative cooperativity of enzyme-ligand binding, with a Hill constant <1. This is in striking contrast to interaction of the enzyme with the parent Guo, for which the association constant is independent of concentration. The weakly fluorescent N(7)-methylguanine (m7Gua), the product of phosphorolysis of m7Guo, is a competitive non-substrate inhibitor of phosphorolysis (K(i)=8+/-2 microM) and exhibits negative cooperativity on binding to the enzyme at pH 6.9. Quenching of enzyme emission by the ligands is a static process, inasmuch as the mean excited-state lifetime, =2.7 ns, is unchanged in the presence of the ligands, and the constants K(SV) may therefore be considered as the association constants for the enzyme-ligand complexes. In the pH range 9.5-11 there is an instantaneous reversible decrease in PNP emission of approximately 15%, corresponding to one of the six tyrosine residues per subunit readily accessible to solvent, and OH- ions. Relevance of the overall results to the mechanism of phosphorolysis, and binding of substrates/inhibitors is discussed.

Human pancreatic-type ribonucleases with activity against double-stranded ribonucleic acids.

Purified acid-thermostable ribonuclease (Ribonucleate 3'-pyrimidino-oligonucleotidohydrolase, EC 3.1.4.22) from human pancreas degrades double-stranded RNA at 2% the rate for single-stranded RNA. The activities against single-stranded RNA and double-stranded RNA were shown to be due to a single enzyme with properties similar to bovine pancreatic RNAase A. For purposes of comparison the activities against double-stranded RNA of crystalline ribonucleases of the whale, rat and cow were assayed and found to be 0.4%, 0.03% and 0.003%, respectively, of their activities against single-stranded RNA. Both human serum and urine contain RNAse components of pancreatic origin which hydrolyze double-stranded RNA at 2% and 0.4%, respectively, of the rates against single-stranded RNA. By contrast, purified acid-thermostable RNAases from human spleen and liver hydrlyze double-stranded RNA at least 20-fold more slowly than human pancreatic RNAase, relative to the corresponding rates against single-stranded RNA. The human pancreatic and serum enzymes exhibit appreciable activity against the poly(C) component of the double-stranded poly(I)-poly(C); they also attack poly(C) itself at approximately 25 times the rate for poly(U) and at more than 50 times the rate for single-stranded RNA.

Novel activity of potato nucleotide pyrophosphatase.

The classical Kornberger-Pricer procedure for purification of potato nucleotide pyrophosphatase (EC 3.6.1.9) has been modified to yield a preparation purified 2500-fold. In addition to the known activity against pyrophosphate linkages in pyrophosphates located at the 5'-OH of nucleosides, and phosphodiester linkages in aryl esters of nucleoside-5'-phosphates, the enzyme has now been shown to catalyze the cleavage of: (a) aryl esters of nucleoside-3'-phosphates and orthophosphates, (b) nucleotide pyrophosphate linkages of the type (3')-pp-(3'), and (c) pm7G from m7GpppGm-terminated fragments of viral mRNA. Activities against aryl esters of nucleoside-3'- and 5'-phosphates, and NAD, were shown to be due to the same protein by three criteria: (a) constant ratio of activities during purification and gel electrophoresis, (b) identical chromatographic properties in various systems, and (c) similarities in pH-dependence, heat inactivation, and the effects of cations and other substances. Since potato nucleotide pyrophosphatase does not exhibit exonuclease or phosphatase activities against natural substrates for the latter enzymes, but does cleave synthetic aryl esters of nucleotide-3'- and 5'-phosphates and of orthophosphate, it follows that these substrates are not suitable for detection of such activities in higher plants.

A purine nucleoside unequivocally constrained in the syn form. Crystal structure and conformation of 8-(alpha-hydroxyisopropyl)-adenosine.

Crystals of 8-(alpha-hydroxyisopropyl)-adenosine dihydrate, C13H19N5O5.2H2O, belong to the monoclinic space group P21. Cell dimensions are a = 8.259 (1), b = 11.117 (2), c = 9.663 (1) A, beta = 109.65 (2) degrees. Intensity data were collected on a four-circle diffractometer and the structure was solved by direct methods. Block diagonal least-squares refinement led to R = 0.031 for 1467 reflections. The glycosyl torsion angle chiCN is 241.4 degrees, corresponding to a syn conformation. The conformation of the exocyclic C(4')-C(5') bond is gauche-gauche and the sugar pucker is C(2') endo. It is considered that the bulky, tetrahedral, neutral 8-substituent, with an effective van der Waals radius of 3.5--4.0 A, provides an adenosine analogue which should exhibit the syn conformation about the glycosidic bond in solution as well as in solid state, irrespective of the nature of the sugar pucker. It should therefore be suitable for studies of interactions with enzyme systems requiring the anti conformation of the nucleoside or nucleotide.

Comparison of theoretical and experimental approaches to determination of conformation of nucleosides about the glycosidic bond.

A study has been made by means of 1H-NMR spectroscopy of the syn in equilibrium anti dynamic equilibrium about the glycosidic bond for 5'-deoxyadenosine and some 8-substituted analogues, in different solvents. The results are compared with those previously obtained for the parent adenosine and its 8-substituted analogues. Quantum chemical calculations, with the aid of the Classical Potential and PCILO procedures, were applied to obtain the energies for different conformations of the base in adenosine and 5'-deoxyadenosine, and their 8-methyl and 8-halogeno derivatives. Good agreement was found between experimentally determined conformations in solution and those corresponding theoretically to the energy minima, particularly those calculated by the PCILO method. Comparison of the quantitative experimental data with the theoretical results was used to evaluate the validity of the latter and their applicability to studies of nucleoside conformation. The experimental and theoretical findings pointed to the existence of a marked flexibility about the glycosidic bond of the parent nucleosides and their 8-substituted analogues, when the 8-substituents were not too bulky, such as methyl or bromine. Considerations is given to possible correlations between conformational parameters in nucleosides and their 5'-deoxy analogues. It is shown that the proposed stabilization of the conformation syn by intramolecular hydrogen bonding, 5'-OH...N(3), is not in accord with the results of the present study.

Correlations of conformational parameters and equilibrium conformational states in a variety of beta-D-arabinonucleosides and their analogues.

H nuclear magnetic resonance spectroscopy has been applied to a study of the conformations of a variety of purine and pyrimidine beta-D-arabinofuranosyl nucleosides. The experimental results, together with data collected from the literature, demonstrated the existence of reasonably good correlations between the coupling constants made it possible to define more accurately, than hitherto possible, the conformational states between which equilibria exist in solution. The equilibrium for the arabinonucleosides differs from that previously established for ribonucleosides; in particular, structural modifications and solvent effects may appreciably modify the conformational states between which equilibria exist. Preliminary measurements on some arabinosides in the syn conformation about the glycosidic bond indicated that these do not conform to the foregoing correlations, and will require separate study. A correlation has also been established between the conformation of the arabinose ring and that of the exocyclic 5'-CH2OH group. For both purine and pyrimidine arabinonucleosides, the conformational state 3E of the arabinose ring coexists to some extent with a gauche-gauche conformation of the exocyclic 5'-CH2OH, as in the case of pyrimidine (but not purine) ribonucleosides. Application of the foregoing to some biological problems is described.

Properties of two unusual, and fluorescent, substrates of purine-nucleoside phosphorylase: 7-methylguanosine and 7-methylinosine.

The properties of two unusual substrates of calf spleen purine-nucleoside phosphorylase (purine-nucleoside:orthophosphate ribosyltransferase, EC 2.4.2.1), 7-methylguanosine and 7-methylinosine, are described. The corresponding bases, 7-methylguanine and 7-methylhypoxanthine, are neither substrates in the reverse, synthetic reaction, nor inhibitors of the phosphorolysis reaction. Both nucleosides exhibit fluorescence, which disappears on cleavage of the glycosidic bond, providing a new convenient procedure for continuous fluorimetric assay of enzymatic activity. For 7-methylguanosine at neutral pH and 25 degrees C, Vmax = 3.3 mumol/min per unit enzyme and Km = 14.7 microM, so that Vmax/Km = 22 X 10(-2)/min per unit as compared to 8 X 10(-2) for the commonly used substrate inosine. The permissible initial substrate concentration range is 5-100 microM. Enzyme activity may also be monitored spectrophotometrically. For 7-methylinosine, Vmax/Km is much lower, 2.4 X 10(-2), but its 10-fold higher fluorescence partially compensates for this, and permits the use of initial substrate concentrations in the range 1-500 microM. At neutral pH both substrates are mixtures of cationic and zwitterionic forms. Measurements of pH-dependence of kinetic constants indicated that the cationic forms are the preferred substrates, whereas the monoanion of inosine appears to be almost as good a substrate as the neutral form. With 7-methylguanosine as substrate, and monitoring of activity fluorimetrically and spectrophotometrically, inhibition constants were measured for several known inhibitors, and the results compared with those obtained with inosine as substrate, and with results reported for the enzyme from other sources.

Structure and conformation of the cyclic phosphate of Ganciclovir, a broad-spectrum antiviral agent.

The title compound, the cyclic phosphate of the antiviral acyclonucleoside Ganciclovir (2'-NDG, DHPG), is itself a potent broad-spectrum antiviral agent, but with a different mechanism of action. The cyclic phosphate, 9-[[[(2-hydroxy-1,3,2-dioxophosphorinan-5-yl)oxy]methyl]-P- oxide]guanine (2'-nor-cGMP,DHPG-cMP), crystallizes in the monoclinic space group P2(1)/n with unit cell dimensions a = 6.612(1) A, b = 11.562(4) A, c = 19.231(5) A and beta = 91.786(2) degrees at -165 degrees C. The N7 of the guanine base is protonated, so that the molecule is in a zwitterionic form, with two water molecules in the asymmetric unit. The principal conformational features of DHPG-cMP in the crystal are as follows: the acyclic chain is partially folded; the six-membered cyclic phosphate ring is in a chair form with C3', O3', C5' and O5' in a plane; P and C4' are displaced in diametrically opposite directions from this plane; the O4' is in the axial orientation with respect to this ring; and the aglycon is in the high syn conformation about the glycosidic bond. The conformation of the cyclic phosphate ring in aqueous medium, determined by means of 1H-NMR spectroscopy, is similar to that in the crystalline form. The conformational features of DHPG-cMP were compared with those of the parent DHPG and other related compounds and, in particular, with those of the second messenger 3':5'-cGMP, of which it is a close structural analogue. Previously reported substrate/inhibitor properties of these compounds in several enzyme systems are examined in relation to the possible mechanism of antiviral activity of DHPG-cMP as a second messenger analogue of cGMP.

Fluorescence emission properties of 8-azapurines and their nucleosides, and application to the kinetics of the reverse synthetic reaction of purine nucleoside phosphorylase.

An extensive study has been made of the fluorescence emission properties of the neutral and ionic forms in aqueous medium of the azapurine nucleosides, 8-azaadenosine (8-azaAdo), 8-azainosine (8-azaIno), 8-azaguanosine (8-azaGuo), and their aglycons. The fluorescence of 8-azaGuo at pH 7 originates from its anionic species (pKa = 8.05, phi= 0.55), as is also the case for 8-azaIno (pKa = 8.0, phi = 0.02), whereas 8-azaAdo is a strong emitter (phi = 0.06) as the neutral species. By contrast the corresponding free 8-azapurines are only weakly fluorescent in aqueous medium, with the exception of 8-azaguanine (8-azaG). Examination of the emission properties of N-substituted 8-azaguanines demonstrated that the observed blue emission of the neutral form of 8-azaG (phi = 0.05 to 0.33, dependent on lambda exc) originates from a minor tautomer of the compound, the N(8)-H form, present to the extent of 10-15%; while the principal N(9)-H tautomer is virtually nonfluorescent. The 8-azapurines are substrates of purine nucleoside phosphorylase (PNP), leading to their irreversible conversion to the corresponding nucleosides in the synthetic pathway of this enzyme. The fluorescent properties of these compounds, together with spectrophotometric methods, were applied to determine the basic kinetic parameters for synthesis of 8-azapurine nucleosides by PNP from mammalian (calf spleen) and bacterial (Escherichia coli) sources. The fluorimetric method was also used to determine the kinetic parameters for the second substrate, alpha-D-ribose 1-phosphate, and for the analytical titration of the latter in solution. The pH optimum of the reverse synthetic PNP reaction with 8-azapurines as substrates is below pH 7, due to their enhanced acidity in comparison with natural purines. The 8-azapurine nucleosides, but not their aglycons, are reasonably good inhibitors of phosphorolysis of Ino and Guo by E. coli PNP. The most effective is 8-azaIno (Ki approximately 20 microM), also the only one to inhibit phosphorolysis by the calf spleen enzyme (Ki approximately 40 microM). The nature of this inhibition is apparently uncompetitive.

Conformation in aqueous medium of the neutral, protonated and anionic forms of 9-beta-D-arabinofuranosyladenine.

Proton magnetic resonance spectroscopy was employed to study the solution conformations of the neutral, protonated and dissociated forms of the therapeutically active 9-beta-D-arabinofuranosyladenine (araA). In particular, in strongly basic medium, increasing alkalinity led to pronounced changes in chemical shifts and coupling constants of some pentose protons, due to ionization of the pentose hydroxyls, especially the 2'-OH. The neutral form of araA may be characterized as approx. 25% C(2')endo and approx. 60% gauche-gauche, hence somewhat different from that of the therapeutically active 1-beta-D-arabinofuranosylcytosine (araC). By contrast, the conformations of the anionic forms of both of these are identical, predominantly (greater than 80%) C(2')endo and gauche-gauche. With the aid of the 3'-O-methyl derivatives of araA and araC, where only the 2'-OH ionizes, and the accompanying conformational changes are similar, it follows that the conformation C(2')endo and gauche-gauche for all the foregoing is constrained to this form via a strong intramolecular hydrogen bond, viz. O(5')H...O(2')(-). The influence of the foregoing hydrogen bond on the chemical shifts of the adenine H(8) in the araA anion points to the existence of the latter in the form anti. A similar effect of the doubly ionized phosphate group on H(8) in 5'-araAMP shows the nucleotide to also prefer the form anti, as previously demonstrated for 5'-AMP. The conformations of the sugar rings of the neutral forms of araA and adenosine in aqueous medium differ appreciably, whereas in the solid state they are very similar. PMR spectroscopy is shown to be an effective method for following sugar hydroxyl dissociation. The extent of ionization of a given hydroxyl is provided by the resulting chemical shifts of neighbouring (geminal and vicinal) protons. When ionization is accompanied by a change in conformation, the process may be followed also by changes in proton-proton vicinal coupling constants.

Mechanism of hydroxylamine mutagenesis. Crystal structure and conformation of 1,5-dimethyl-N4-hydroxycytosine.

The crystal structure of the title compound, which is a formal analogue of 5-methyl-N4-hydroxycytosine nucleosides, has been determined by X-ray diffraction. The space group is P2(1)/c with a = 7.368 (2), b = 12.096 (3), c = 9.192 (4) A, beta = 113.94 (3) degrees. Three-dimensional intensity data were collected with a four-circle diffractometer, and the structure was refined by block-diagonal least-squares to R = 0.053. The compound is in the imino form, and the exocyclic N4-OH is located essentially in the plane of the pyrimidine ring, and syn to the ring (N(3). There is an intramolecular hydrogen bond involving the N(3)-H as donor and O(4) as acceptor, viz. N(3)-H(31)----O(4)-H. With this conformation, which probably prevails also in solution, the compound would be unable to participate in normal Watson-Crick base pairing. It is shown that a similar situation may prevail for N4-hydroxycytosine nucleosides. The implications with regard to the molecular mechanism of hydroxylamine mutagenesis, with particular reference to the T-even bacteriophages, are discussed. Analogous considerations are applied to an examination of the possible behaviour of hydroxylamine-modified adenine nucleosides.

Formycin A and its N-methyl analogues, specific inhibitors of E. coli purine nucleoside phosphorylase (PNP): induced tautomeric shifts on binding to enzyme, and enzyme-->ligand fluorescence resonance energy transfer.

Steady-state and time-resolved emission spectroscopy were used to study the interaction of Escherichia coli purine nucleoside phosphorylase (PNP) with its specific inhibitors, viz. formycin B (FB), and formycin A (FA) and its N-methylated analogues, N(1)-methylformycin A (m(1)FA), N(2)-methylformycin A (m(2)FA) and N(6)-methylformycin A (m(6)FA), in the absence and presence of phosphate (P(i)). Complex formation led to marked quenching of enzyme tyrosine intrinsic fluorescence, with concomitant increases in fluorescence of FA and m(6)FA, independently of the presence of P(i). Fluorescence of m(1)FA in the complex increased only in the presence of P(i), while the weak fluorescence of FB appeared unaffected, independently of P(i). Analysis of the emission, excitation and absorption spectra of enzyme-ligand mixtures pointed to fluorescence resonance energy transfer (FRET) from protein tyrosine residue(s) to FA and m(6)FA base moieties, as a major mechanism of protein fluorescence quenching. With the non-inhibitor m(2)FA, fluorescence emission and excitation spectra were purely additive. Effects of enzyme-FA, or enzyme-m(6)FA, interactions on nucleoside excitation and emission spectra revealed shifts in tautomeric equilibria of the bound ligands. With FA, which exists predominantly as the N(1)-H tautomer in solution, the proton N(1)-H is shifted to N(2), independently of the presence of P(i). Complex formation with m(6)FA in the absence of P(i) led to a shift of the amino-imino equilibrium in favor of the imino species, and increased fluorescence at 350 nm; by contrast, in the presence of P(i), the equilibrium was shifted in favor of the amino species, accompanied by higher fluorescence at 430 nm, and a higher affinity for the enzyme, with a dissociation constant K(d)=0.5+/-0.1 microM, two orders of magnitude lower than that for m(6)FA in the absence of P(i) (K(d)=46+/-5 microM). The latter was confirmed by analysis of quenching of enzyme fluorescence according to a modified Stern-Volmer model. Fractional accessibility values (f(a)) varied from 0.31 for m(1)FA to 0.70 for FA, with negative cooperative binding of m(1)FA and FB, and non-cooperative binding of FA and m(6)FA. For all nucleoside ligands, the best model describing binding stoichiometry was one ligand per native enzyme hexamer. Fluorescence decays of PNP, FA and their mixtures were best fitted to a sum of two exponential terms, with average lifetimes () affected by their interactions. Complex formation resulted in a 2-fold increase in of FA, and a 2-fold decrease in of enzyme fluorescence. The amplitude of the long-lifetime component also increased, confirming the shift of the tautomeric equilibrium in favor of the N(2)-H species. The findings have been examined in relation to enzyme-nucleoside binding deduced from structural studies.

alpha-Nucleosides in biological systems. Crystal structure and conformation of alpha-cytidine.

The structure of alpha-cytidine, C9H13N3O5, monoclinic with space group C2 and cell parameters a = 20.064 (3) A, b = 7.100 (1) A, c = 7.860 (2) A, beta = 104.60 (2) degrees, Z = 4, was determined by X-ray diffraction using a combination of direct methods, Patterson and difference Fourier techniques and refined by block-diagonal least-squares to a final R of 0.033 for 1002 reflections measured on a diffractometer. The glycosidic torsional angle, chiCN = -28.4 degrees, is in the anti region; the sugar pucker is C(2')exo-C(3')endo in a nearly pure 32H twist; and the conformation of C(4')-C(5') is gauche-gauche. The molecules are bound by hydrogen bonds in the lattice with little likelihood of base-stacking interactions. The molecular features of the compound are compared and contrasted with those of its naturally occurring beta-anomer, and some biological implications of this structure, and alpha-nucleosides in general, are discussed.

Specific inhibition of hnRNA synthesis by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole. Requirement of a free 3'-hydroxyl group, but not 2'- or 5'-hydroxyls.

Five structural analogues of 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), all with modified sugar moieties, have been examined for their inhibitory activities on RNA transcription in salivary glands of Chironomus tentans. The well-known ability of the parent DRB at 65 microM concentration to selectively inhibit hnRNA/mRNA synthesis by approx. 90% was essentially abolished on methylation of the 3'-OH; but, at an overdose the analogue suppressed labeling of all RNA classes examined (hnRNA/mRNA, rRNA, 4-5 S RNA) by 70-80%. By contrast, the 2'-O-methyl derivative of DRB was almost as effective as DRB itself in blocking transcription of hnRNA/mRNA genes. Blocking of both the 2' and 3' hydroxyls (2',3'-O-isopropylidene-DRB) completely abolished inhibitory activity, irrespective of the concentration employed. The 5'-deoxy-5'-chloro derivative of DRB was only slightly less effective than the parent DRB. An unusual aspect of the activities of 2'-O-methyl-DRB and 5'-deoxy-5'-chloro-DRB was their ability to stimulate synthesis of 4-5 S RNA by 25-45%. Also investigated was the influence of the various analogues on the rate of formation of [3H]UTP from [3H]uridine used as an RNA precursor. The rate of such formation of [3H]UTP was suppressed 2-6-fold by treatment with 2'-O-methyl or 3'-O-methyl-DRB, but was unaffected by 5'-deoxy-5'-chloro-DRB or 5,6-dichloro-1-alpha-D-arabinofuranosylbenzimidazole. The overall data point to the importance of a free 3'-OH in the ribose moiety of DRB for selective inhibitory activity. The alpha-D-arabinofuranosyl analogue, although less selective in inhibition of RNA transcription, still exhibits about 50% of the activity of DRB.