The crystal and molecular structure of 8-methyladenosine 3'-monophosphate dihydrate.

8-Methyladenosine 3'-monophosphate dihydrate was synthesized and crystallized in the monoclinic space group P21 with the unit cell dimensions: a = 9.095(2) A, b = 16.750(3) A, c = 5.405(2) A and beta = 97.61(3) degrees. The structure was determined by the application of the heavy atom method and refined to give a final R factor of 0.047. The pertinent conformations are as follows: the syn conformation about the glycosyl bond (chiCN = 216.8 degrees), the C(2')-endo sugar puckering with the displacement of 0.55 A; and the gauche-gauche conformation about the C(4')-C(5') bond capable of forming an intramolecular hydrogen bonding between N(3) of adenine base and O(5') of the hydroxymethylene group on the ribose. The molecule exists in the zwitterionic form with the N(1) of the adenine base protonated by a phosphate proton and is stabilized by three-dimensional networks of hydrogen bonding through the crystalline water molecules or directly between the adjacent nucleotide molecules; no base stacking was observed.     

Interaction of La (III) and Tb (III) ions with purine nucleotides: evidence for metal chelation (N-7-M-PO3) and the effect of macrochelate formation on the nucleotide sugar conformation.

The interaction of the La (III) and Tb (III) ions with adenosine-5'-monophosphate (5'-AMP), guanosine-5'-monophosphate (5'-GMP), and 2'-deoxyguanosine-5'-monophosphate (5'-dGMP) anions with metal/nucleotide ratios of 1 and 2 has been studied in aqueous solution in acidic and neutral pHs. The solid complexes were isolated and characterized by Fourier transform ir and 1H-nmr spectroscopy. The lanthanide (III)-nucleotide complexes are polymeric in nature both in the solid and aqueous solutions. In the metal-nucleotide complexes isolated from acidic solution, the nucleotide binding is via the phosphate group (inner sphere) and an indirect metal-N-7 interaction (outer-sphere) with the adenine N-1 site protonated. In the complexes obtained from neutral solution, metal chelation through the N-7 and the PO3(2-) group is prevailing. In aqueous solution, an equilibrium between the inner and outer sphere metal-nucleotide interaction has been observed. The ribose moiety shows C2'-endo/anti pucker in the free AMP anion and in the lanthanide (III)-AMP complexes, whereas the GMP anion with C2'-endo/anti sugar conformation exhibits a mixture of the C2'-endo/anti and C3'-endo/anti sugar puckers in the lanthanide (III)-GMP salts. The deoxyribose has O4'-endo/anti sugar pucker in the free dGMP anion and a C3'-endo/anti, in the lanthanide (III)-dGMP complexes.     

A Raman spectroscopic study of the interaction of divalent metal ions with adenine moiety of adenosine 5'-triphosphate.

Raman spectra of ATP at various pH values are affected by addition of equimolar solution of divalent metal ions such as Ca2+, Mg2+, Co2+, Cu2+, and Hg2+. The changes in frequency and intensity have been used to construct models describing the nature of metal-adenine and metal-triphosphate interactions under different conditions. The metal ions are found to co-ordinate the triphosphate group in the entire pH range studies (pH to 12). Calcium (II) and magnesium (II) interact strongly with the phosphate moiety at neutral pH, although a weak interaction with the ring occur at low pH values. Around neutrality, several Raman spectral changes are observed to implicate the interaction of cobalt (II) ion with the five-membered ring of the adenine. The changes in Raman frequency are too small to suggest a direct Co(II)-N7 binding. At least six different Cu(II)-ATP species are identified between pH 3 and 12. At pH approximately 7.0 Raman data are explained better by Cu(II) interacting with N7 simultaneously with the amino group of the adenine ring. However, a Cu(II) binding to N3 at pH 10 to 11 is indicated by the enhancement of the 760 and 1360 cm-1 vibrations. At neutral pH, mercury (II) ion shows a direct coordination at N1 while at low pH with N1 blocked by protonation, mercury (II) does not interact with the adenine moiety.     

Crystal structure of the alpha, beta, gamma-tridentate manganese complex of adenosine 5'-triphosphate cocrystallized with 2,2'-dipyridylamine

The 1:1:1 complex of Mn2+, ATP, and 2,2'-dipyridylamine (DPA) crystallizes as Mn-(HATP)2.Mn(H2O)6.(HDPA)2.12H2O in the orthorhombic space group C222(1) with unit cell dimensions a = 10.234 (3) A, b = 22.699 (3) A, and c = 31.351 (4) A. The structure was solved by the multisolution technique and refined by the least-squares method to a final R index of 0.072 using 3516 intensities. The structure is composed of two ATP molecules sharing a common manganese atom. The metal exhibits alpha, beta, gamma coordination to the triphosphate chains of two dyad-related ATP molecules, resulting in a hexacoordinated Mn2+ ion surrounded by six phosphate groups. The metal to oxygen distances are 2.205 (6), 2.156 (4), and 2.144 (5) A for the alpha-, beta-, and gamma-phosphate groups, respectively. No metal-base interactions are observed. There is a second hexaaqua-coordinated Mn2+ ion that is also located on a dyad axis. The hydrated manganese ions sandwich the phosphate-coordinated manganese ions in the crystal with a metal-metal distance of 5.322 A. The ATP molecule is protonated on the N(1) site of the adenine base and exhibits the anti conformation (chi = 66.0 degrees). The ribofuranose ring is in the 2/3 T conformation with pseudorotation parameters P = 179 (1) degrees and tau m = 34.1 (6) degrees. The adenine bases form hydrogen-bonded self-pairs across a crystallographic dyad axis and stack with both DPA molecules to form a column along the dyad. The structure of the metal-ATP complex provides information about the possible metal coordination, conformation, and environment of the nucleoside triphosphate substrate in the enzyme.     

X-ray crystallographic conformational study of 5'-O-[N-(L-alanyl)-sulfamoyl]adenosine, a substrate analogue for alanyl-tRNA synthetase

In order to elucidate the substrate specificity of alanyl-tRNA synthetase, 5'-O-[N-(L-alanyl)sulfamoyl]adenosine (Ala-SA), an analogue of alanyl-AMP, was chemically synthesized. Its binding ability is similar to that of the substrate based on the inhibitory activity for the aminoacylation of alanyl-tRNA synthetase. Taking advantage of the stable sulfamoyl bond of Ala-Sa, compared with the highly labile aminoacyl bond of alanyl-AMP, the molecular conformation of the former inhibitor was studied by X-ray single crystal analysis. Crystal data are as follows: C13H19N7O7S.2H2O, space group C2, a = 39.620(6), b = 5.757(1), c = 20.040(3) A, beta = 117.2(1) degrees, V = 4065(9) A3, Z = 8, and final R = 0.065 for 2785 independent reflections of F(2)0 greater than or equal to 2 sigma (F0)2. In the crystal, the molecule is in a zwitterionic state with the terminal amino group protonated and sulfamoyl group deprotonated, and takes an open conformation, where the L-alanine moiety is located far from the adenosine moiety with gauche/trans and trans orientations about the exocyclic C(4')-C(5') and C(5')-O(5') bonds, respectively. The conformation of the adenosine moiety is anti for the glycosyl bond and C(3')-endo for the ribose puckering, and alanine is in the usually observed trans region for the psi torsion angle. The molecular dimensions of the sulfamoyl group are nearly the same as those of the phosphate group. The biological significance of the observed Ala-SA conformation is discussed in relation with the molecular conformation of tyrosyl-AMP complexed with tyrosyl-tRNA synthetase.     

Orally active CCR5 antagonists as anti-HIV-1 agents. Part 3: Synthesis and biological activities of 1-benzazepine derivatives containing a sulfoxide moiety

In order to develop orally active CCR5 antagonists, 1-propyl- or 1-isobutyl-1-benzazepine derivatives containing a sulfoxide moiety have been designed, synthesized, and evaluated for their biological activities. Sulfoxide compounds containing a 2-pyridyl group were first investigated, which led to discovering that the presence of a methylene group between the sulfoxide moiety and 2-pyridyl group was necessary for increased inhibitory activity in a binding assay. After further chemical modification, it was found that replacement of the pyridyl group with an imidazolyl or 1,2,4-triazolyl group enhanced activity in the binding assay and that S-sulfoxide compounds were more active than R-isomers. Particularly, compounds (S)-4r, (S)-4s, and (S)-4w exhibited highly potent CCR5 antagonistic activities (IC50=1.9, 1.7, 1.6 nM, respectively) and inhibitory effects (IC50=1.0, 2.8, 7.7 nM, respectively) in the HIV-1 envelope mediated membrane fusion assay, together with good pharmacokinetic properties in rats. In addition, we established the synthesis of (S)-4r and (S)-4w by asymmetric oxidation with titanium-(S)-(-)-1,1'-bi-2-naphthol complex.     

Raman spectroscopy study of acid-base and structural properties of 9-[2-(phosphonomethoxy)ethyl]adenine in aqueous solutions

The acid-base properties of the acyclic antiviral nucleotide analogue 9- [2-(phosphonomethoxy)ethyl] adenine (PMEA) in aqueous solutions are studied by means of Raman spectroscopy in a pH range of 1-11 and compared with the properties of its common adenosine monophosphate counterparts (5'-AMP, 3'-AMP, and 2'-AMP). Factor analysis is used to separate the spectra of pure ionic species (PMEA2-, HPMEA-, H2PMEA, H3PMEA+) in order to determine their abundance, sites of protonation, and corresponding spectroscopic pK(a) values. The characteristic Raman features of the neutral adenine moiety in PMEA2- and HPMEA- species resemble those of neutral adenine in the AMPs, whereas significant differences are observed between the Raman spectra of the N1-protonated adenine of the solute zwitterionic H2PMEA and its N1-protonated AMP counterparts. On the contrary, the spectrum of crystalline H2PMEA, adopting an "anti-like" conformation, is found to be similar to the N1-protonated AMPs in solution. To explain peculiar Raman features a "syn-like" conformation is suggested for N1-protonated PMEA species in aqueous solutions instead of an anti-like one adopted by H2PMEA in crystals or by common AMPs in aqueous solutions. A physical mechanism of the anti-like to syn-like conformational transition of the solute PMEA that is due to adenine protonation and the flexibility of the (phosphonomethoxy)ethyl group is proposed and discussed.     

Reactions of l-ergothioneine and some other aminothiones with 2,2′- and 4,4′-dipyridyl disulphides and of l-ergothioneine with iodoacetamide. 2-Mercaptoimidazoles, 2- and 4-thiopyridones, thiourea and thioacetamide as highly reactive neutral sulphur nucleophiles

1. The reactions of 2,2'- and 4,4'-dipyridyl disulphide (2-Py-S-S-2-Py and 4-Py-S-S-4-Py) with l-ergothioneine (2-mercapto-l-histidine betaine), 2-mercaptoimidazole, 1-methyl-2-mercaptoimidazole, thiourea, thioacetamide, 2-thiopyridone (Py-2-SH) and 4-thiopyridone (Py-4-SH) were investigated spectrophotometrically in the pH range approx. 1-9. 2. These reactions involve two sequential reversible thiol-disulphide interchanges. 3. The reaction of l-ergothioneine with 2-Py-S-S-2-Py and/or with the l-ergothioneine-Py-2-SH mixed disulphide, both of which provide Py-2-SH, is characterized by at least three reactive protonic states. This provides definitive evidence that neutral l-ergothioneine is a reactive nucleophile, particularly towards the highly electrophilic protonated disulphides. 4. A similar situation appears to obtain in the reactions of l-ergothioneine and Py-2-SH with 4-Py-S-S-4-Py and in the reactions of the other 2-mercaptoimidazoles, thiourea and Py-4-SH with 2-Py-S-S-2-Py. The nucleophilic reactivity of Py-4-SH suggests that general base catalysis provided by the disulphide in a cyclic or quasi-cyclic transition state is not necessary to generate nucleophilic reactivity in the other amino-thiones whose geometry could permit such catalysis. 5. The existence of a positive deuterium isotope effect in the l-ergothioneine-2-Py-S-S-2-Py system at pH6-7 provides no evidence for general base catalysis but is in accord with a mechanism involving specific acid catalysis and post-transition-state proton transfer. 6. The pH-dependences of the overall equilibrium positions of the various thiol-disulphide interchanges are described. 7. Reaction of thioacetamide with a stoicheiometric quantity of 2-Py-S-S-2-Py at pH1 provides 2 molecules of Py-2-SH per molecule of thioacetamide and elemental sulphur; these findings can be accounted for by thiol-disulphide interchange to provide a thioacetamide-Py-2-SH mixed disulphide followed by fragmentation to provide CH(3)CN, S and Py-2-SH. 8. Provision of high reactivity in the neutral forms of the members of this series of sulphur nucleophiles by electron donation by the amino group is compared with the well known alpha effect that provides enhanced nucleophilicity in compounds containing an electronegative atom adjacent to the nucleophilic atom. 9. The decrease in the u.v. absorption of l-ergothioneine at 257nm consequent on transformation of its aminothione moiety into an S-alkyl-2-mercaptoimidazole moiety provides a convenient method of following the alkylation of l-ergothioneine by iodoacetamide. 10. The pH dependence of the extinction coefficient of l-ergothioneine at 257nm is described by epsilon(257)={8x10(3)/(1+K(a)/[H(+)]} +6x10(3)m(-1).cm(-1) in which pK(a)=10.8. 11. In the pH range 3-11 the reaction is characterized by two reactive protonic states (X and XH). 12. The X state, reaction of the ionized 2-mercaptoimidazole moiety of the l-ergothioneine dianion with neutral iodoacetamide, is characterized by the second-order rate constant 4.0m(-1).s(-1) (25.0 degrees C, I=0.05). The XH state, characterized by the second-order rate constant 0.03m(-1).s(-1), is interpreted as reaction of the thione form of the neutral 2-mercaptoimidazole moiety of the l-ergothioneine monoanion with neutral iodoacetamide. 13. The XH state of the alkylation reaction does not exhibit a deuterium isotope effect.     

Intramolecular hydrogen bonding as a determinant of the inhibitory potency of N-unsubstituted imidazole derivatives towards mammalian hemoproteins

Enzymes involved in the mammalian microsomal metabolism of drugs are, in numerous cases, inhibited by compounds bearing an imidazolyl scaffold. However, the inhibition potency is highly dependent upon the accessibility of the imidazolyl nitrogen lone pair. In order to highlight some structural parameters of inhibitors that control this phenomenon, a series of compounds containing a nitrogen unsubstituted imidazolyl moiety with varying degrees of nitrogen lone pair accessibility was tested on human and rat hepatic cytochromes P450 and microperoxidase 8, an enzymatically active peptide derived from cytochrome c. In each case, we have shown that the accessibility of the imidazole lone pair determined the extent of inhibition. Nitrogen accessibility was tuned not only by varying the steric hindrance in the vicinity of the imidazolyl ring but also by modifying its surrounding hydrogen bonding network. Compounds in which there exists intramolecular hydrogen bonding between the imidazole moiety and an H-bond acceptor, such as an appropriately positioned amide carbonyl group, demonstrated enhanced inhibitory effects. Conversely, imidazole moieties which are in proximity to H-bond donors, such as an amide NH group, displayed reduced potency. This trend was observed in cyclo-peptide derivatives in which the intramolecular H-bond network was adjusted through the modification of the stereochemistry of a dehydrohistidine residue. It was observed that (Z)-isomers weakly bind heme, whereas (E)-isomers demonstrated higher degrees of metal binding. Therefore, enzymatic inhibition of heme-containing proteins by compounds bearing a dehydrohistidine motif seems to be closely related to its stereochemistry and hydrogen binding propensity. At neutral pH, these differences in binding affinities can be confidently attributed to the ambident H-bond properties of imidazole nitrogen atoms. This structure-activity relationship may be of use for the design of novel imidazolyl compounds as new P450 inhibitors or drug candidates.     

Exchange mechanisms for hydrogen bonding protons of cytidylic and guanylic acids.

The pH dependence of buffer catalysis of exchange of the C-4 amino protons of cyclic cytosine 2',3'-monophosphate (cCMP) and the N-1 proton of cyclic guanosine 2',3'-monophosphate (cGMP) conforms to an exchange mechanism, in which protonation of the nucleobases at C(N-3) AND G(N-7) establishes the important intermediates at neutral to acidic pH. Rate constants for transfer of the G(N-1) proton to H2O, OH-, phosphate, acetate, chloracetate, lactate, and cytosine (N-3) were obtained from 1H nuclear magnetic resonance line width measurements at 360 MHz and were used to estimate the pK or acidity of the exchange site in both the protonated and unprotonated nucleobase. These estimates reveal an increase in acidity of the G(N-1) site corresponding to 2 to 3 pK units as the G(N-7) site is protonated: At neutral pH the G(N-1) site of the protonated purine would be ionized (pK = 6.3). Determinations of phosphate, imidazole, and methylimidazole rate constants for transfer of the amino protons of cCMP provide a more approximate estimate of pK = 7 to 9 for the amino of the protonated pyrimidine. A comparison of the intrinsic amino acidity in the neutral and protonated cytosine is vitiated by the observation that OH- catalyzed exchange in the neutral base is not diffusion limited. This leads to the conclusion that protonation of the nucleobase effects a qualitative increase in the ability of the amino protons to form hydrogen bonds: from very poor in the neutral base to "normal" in the conjugate acid.     

Complexes of amino acids with a crown-ether derivative of 4-styrylpyridine. Monotopic or ditopic?

An E-4-styrylpyridine derivative endowed with 18-crown-6 as a substituent (E-1) was prepared and evaluated in acetonitrile as a potential ditopic ligand for protonated amino acids. The interactions of E-1 with the protonated amino acid perchlorates, ClO(4)(-) H(3)N(+)(CH(2))(n)COOH (n = 2, 5 and 10, A2, A5 and A10, respectively), were studied by optical methods, (1)H NMR and mass spectroscopy. Complex formation involves coordination of the ammonium ion at the crown ether moiety of E-1. The spectral changes were evaluated by comparison with results obtained on protonation of E-1 with HClO(4) and on association with ammonium perchlorate. Protonation by the protonated amino acid perchlorates was thwarted due to reversal of carboxyl/pyridinium pK(A) order in acetonitrile relative to water. Evidence for ditopic hydrogen bonding complex formation was especially sought for A10 because its CH(2) chain is sufficiently long to bridge the distance between the crown ether and pyridyl N sites of E-1. Despite some subtle hints to the contrary, the absence of NOE interaction between the pyridyl protons of E-1 and the methylene protons of A10 indicates that the E-1·A10 complex is in the main monotopic, as is the case for A2 and A5. The photophysical and photochemical behaviour of the complexes change significantly on protonation by HClO(4). The optical response of E-1 on binding the amino acids as ammonium salts allows convenient monitoring of complex formation.     

Tautomerism and conformation of the promutagenic analogue N6-methoxy-2'',3'',5''-tri-O-methyladenosine

N6-Methoxy-2',3',5'-tri-O-methyladenosine crystallizes in space group P2(1)2(1)2(1) with cell dimensions a = 4.693, b = 11.412, c = 31.741 A. Least-squares refinement of diffractometer data converged at R = 0.038. The location of a hydrogen atom at N1 and the observed bond lengths and bond angles indicate unequivocally the imino tautomer of the adenine moiety. The N6-methoxy group is oriented syn to N1 and the glycosidic torsion angle XCN is -3.6 degrees, i.e. in the anti range. The furanose ring has a C2'-exo/C3'- endo pucker (P = 0.9 degrees) and is unusually flattened (tau m = 30.0 degrees). The conformations of the O-methyl groups of the ribose ring are compared with those of monomethylated nucleosides, including the biologically important 2'-O-methyl nucleosides. Evidence is presented for the existence of C-H ... N intermolecular hydrogen bonds between adenine moieties. Bearing in mind that N6-methoxyadenosine is a promutagenic analogue, the results are compared with those for the corresponding promutagenic N4-methoxycytidine. They are also discussed in relation to the tautomerism, the conformation of the N6-methoxy group, and the associated base-pairing abilities in the absence and presence of polymerases.     

Intramolecular stacking interactions in ternary copper(II) complexes formed by a heteroaromatic amine and 9-[2-(2-phosphonoethoxy)ethyl]adenine, a relative of the antiviral nucleotide analogue 9-[2-(phosphonomethoxy)ethyl]adenine

The stability constants of the mixed-ligand complexes formed between Cu(Arm)2+, where Arm=2,2'-bipyridine (Bpy) or 1,10-phenanthroline (Phen), and the dianions of 9-[2-(2-phosphonoethoxy)ethyl]adenine (PEEA2-) and (2-phosphonoethoxy)ethane (PEE2-), also known as [2-(2-ethoxy)ethyl]phosphonate, were determined by potentiometric pH titrations in aqueous solution (25 degrees C; I=0.1 M, NaNO3). The ternary Cu(Arm)(PEEA) complexes are considerably more stable than the corresponding Cu(Arm)(R-PO3) species, where R-PO3(2-) represents a phosph(on)ate ligand with a group R that is unable to participate in any kind of interaction within the complexes. The increased stability is attributed to intramolecular stack formation in the Cu(Arm)(PEEA) complexes and also, to a smaller extent, to the formation of 6-membered chelates involving the ether oxygen atom present in the -CH2-O-CH2-CH2-PO3(2-) residue of PEEA2-. This latter interaction is separately quantified by studying the ternary Cu(Arm)(PEE) complexes which can form the 6-membered chelates but where no intramolecular ligand-ligand stacking is possible. Application of these results allows a quantitative analysis of the intramolecular equilibria involving three structurally different Cu(Arm)(PEEA) species; e.g., of the Cu(Bpy)(PEEA) system about 11% exist with the metal ion solely coordinated to the phosphonate group, 4% as a 6-membered chelate involving the ether oxygen atom of the -CH2-O-CH2CH2-PO3(2-) residue, and 85% with an intramolecular stack between the adenine moiety of PEEA2- and the aromatic rings of Bpy. In addition, the Cu(Arm)(PEEA) complexes may be protonated, leading to Cu(Arm)(H;PEEA)+ species for which it is concluded that the proton is located at the phosphonate group and that the complexes are mainly formed (50 and 70%) by a stacking adduct between Cu(Arm)2+ and the adenine residue of H(PEEA)-. Finally, the stacking properties of adenosine 5'-monophosphate (AMP2-), of the dianion of 9-[2-(phophonomethoxy)ethyl]adenine (PMEA2-) and of several of its analogues (=PA2-) are compared in their ternary Cu(Arm)(AMP) and Cu(Arm)(PA) systems. Conclusions regarding the antiviral properties of several acyclic nucleoside phosphonates are shortly discussed.     

Inhibition of ricin A-chain with pyrrolidine mimics of the oxacarbenium ion transition state

Ricin A-chain (RTA) catalyzes the hydrolytic depurination of a specific adenosine at position 4324 of 28S rRNA. Kinetic isotope effects on the hydrolysis of a small 10mer stem-tetraloop oligonucleotide substrate established the mechanism of the reaction as D(N)*A(N), involving an oxacarbenium ion intermediate in a highly dissociative transition state. An inhibitor with a protonated 1,4-dideoxy-1,4-imino-D-ribitol moiety, a 4-azasugar mimic, at the depurination site in the tetraloop of a 14mer oligonucleotide with a 5 bp duplex stem structure had previously been shown to bind to RTA with a K(d) of 480 nM, which improved to 12 nM upon addition of adenine. Second-generation stem-tetraloop inhibitors have been synthesized that incorporate a methylene bridge between the nitrogen of a 1-azasugar mimic, namely, (3S,4R)-3-hydroxy-4-(hydroxymethyl)pyrrolidine, and substituents, including phenyl, 8-aza-9-deazaadenyl, and 9-deazaadenyl groups, that mimic the activated leaving group at the transition state. The values for the dissociation constants (K(i)) for these were 99 nM for the phenyl 10mer, 163 and 94 nM for the 8-aza-9-deazaadenyl 10- and 14mers, respectively, and 280 nM for the 9-deazaadenyl 14mer. All of these compounds are among the tightest binding molecules known for RTA. A related phenyl-substituted inhibitor with a deoxyguanosine on the 5'-side of the depurination site was also synthesized on the basis of stem-loop substrate specificity studies. This molecule binds with a K(i) of 26 nM and is the tightest binding "one-piece" inhibitor. 8-Aza-9-deaza- and 9-deazaadenyl substituents provide an increased pK(a) at N7, a protonation site en route to the transition state. The binding of these inhibitors is not improved relative to the binding of their phenyl counterpart, however, suggesting that RTA might also employ protonation at N1 and N3 of the adenine moiety to activate the substrate during catalysis. Studies with methylated adenines support this argument. That the various stem-loop inhibitors have similar potencies suggests that an optimal one-piece inhibitor remains to be identified. The second-generation inhibitors described here incorporate ribose mimics missing the 2-hydroxy group. On the basis of inhibition data and substrate specificity studies, the 2'-hydroxyl group at the depurination site seems to be critical for recruitment as well as catalysis by RTA.     

Molecular recognition of adenophostin, a very potent Ca2+ inducer, at the D-myo-inositol 1,4,5-trisphosphate receptor.

The recognition mode of adenophostin A at the D-myo-inositol 1,4, 5-trisphosphate [Ins(1,4,5)P(3)] receptor was investigated. Comparison of conformations of Ins(1,4,5)P(3) and adenophostin A by using the combination of NMR and molecular mechanics (MM) calculations demonstrated that adenophostin A adopted a moderately extended conformation regarding the distance between the 2'-phosphoryl group and the 3' ',4' '-bisphosphate motif, as suggested previously [Wilcox, R. A. et al. (1995) Mol. Pharmacol. 47, 1204-1211]. Based on the nuclear Overhauser effect (NOE) observed between 3'-H and 1' '-H and on MM calculations, the molecular shape of adenophostin A proved to be an extended form at least in solution, in contrast to Wilcox's compactly folded, preliminary hairpin model. GlcdR(2,3',4')P(3), an adenophostin analogue without adenine moiety, was found to be less potent than adenophostin A and almost equipotent to Ins(1,4,5)P(3). We propose the possibility that (i) the optimal spatial arrangement of the three phosphoryl groups and/or (ii) the interaction of the adenine moiety of adenophostin A with the putative binding site, if it exists in the vicinity of the Ins(1,4,5)P(3)-binding site, might account for the exceptional potency of adenophostin A.     

Alkylation by propylene oxide of deoxyribonucleic acid, adenine, guanosine and deoxyguanylic acid

1. Propylene oxide reacts with DNA in aqueous buffer solution at about neutral pH to yield two principal products, identified as 7-(2-hydroxypropyl)guanine and 3-(2-hydroxypropyl)adenine, which hydrolyse out of the alkylated DNA at neutral pH values at 37 degrees C. 2. These products were obtained in quantity by reactions between propylene oxide and guanosine or adenine respectively. 3. The reactions between propylene oxide and adenine in acetic acid were parallel to those between dimethyl sulphate and adenine in neutral aqueous solution; the alkylated positions in adenine in order of decreasing reactivity were N-3, N-1 and N-9. A method for separating these alkyladenines is described. 4. Deoxyguanylic acid sodium salt was alkylated at N-7 by propylene oxide in neutral aqueous solution. 5. The nature of the side chain in the principal alkylation products was established by mass spectrometry, and the nature of the products is consistent with their formation by the bimolecular reaction mechanism.     

Production of a precursor to the pyrimidine moiety of thiamine.

The supernatant fluid from cultures of Escherichia coli W-11, a pur E mutant, prevented the inhibition of growth of E. coli B in a medium containing adenine or adenosine. Adenine inhibition was prevented more readily than adenosine inhibition. More than 90% of the biological activity of the supernatant fluid was recovered in the anionic fraction after treatment with Dowex-50 (NH4+). The cationic fraction, containing large amounts of 5-aminoimidazole ribonucleoside (AIRS), did not prevent adenine inhibition. The W-11 supernatant fluid was shown by bioautography to contain only one compound that prevented adenine inhibition. Proliferating and non-proliferating cultures produced only one compound that prevented adenine inhibition. The compound was shown to be an intermediate (int-1) in the biosynthesis of the pyrimidine moiety of thiamine, Int-1 was stable during sterilization at 121 C for 15 min, during concentration by either flask evaporation or lyophilization, and after storage for several days at 4 C or at -- 20 C. Int-1 was distinguishable from other known derivatives or intermediates of the pyrimidine moiety. A scheme is presented that illustrates the proposed relationship between int-1 and the synthesis of thiamine.     

Crystal structure of L-2-oxothiazolidine-4-carboxylic acid

Crystals of the title compound, L-2-oxothiazolidine-4-carboxylic acid, OTC (C4H5NO3S), grown from an aqueous solution are orthorhombic, space group P2(1)2(1)2(1) with the following cell parameters at 22 +/- 3 degrees: a = 5.381(1), b = 5.961(1), c = 17.929(3)A, V = 575.1A(3), Mr = 146.2, Dc = 1.688 g.cm-3, mu = 43.9 cm-1 and Z = 4. The crystal structure was solved by the application of direct methods and refined to an R value of 0.032 for 596 reflections with I greater than 3 sigma(I). The thiazolidine ring adopts a "twist" conformation. This structure contains a short (2.619(3)A) intermolecular hydrogen bond between the carboxyl OH and the oxygen of the 2-oxo moiety, a feature common to most acyl amino acids and acyl peptides.     

A probe of the active site acidity of carboxypeptidase A

The substrate analogue 2-(1-carboxy-2-phenylethyl)-4-phenylazophenol is a potent competitive inhibitor of carboxypeptidase A. Upon ligation to the active site, the azophenol moiety undergoes a shift of pKa from a value of 8.76 to a value of 4.9; this provides an index of the Lewis acidity of the active site zinc ion. Examination of the pH dependence of Ki for the inhibitor shows maximum effectiveness in neutral solution (limiting Ki = 7.6 X 10(-7) M), with an increase in Ki in acid (pK1 = 6.16) and in alkaline solution (pK2 = 9.71, pK3 = 8.76). It is concluded that a proton-accepting enzymic functional group with the lower pKa (6.2) controls inhibitor binding, that ionization of this group is also manifested in the hydrolysis of peptide substrates (kcat/Km), and that the identity of this group is the water molecule that binds to the active site metal ion in the uncomplexed enzyme (H2OZn2+L3). Reverse protonation state inhibition is demonstrated, and conventional concepts regarding the mechanism of peptide hydrolysis by the enzyme are brought into question.     

Conformational preferences of hypermodified nucleoside lysidine (k2C) occurring at "wobble" position in anticodon loop of tRNA(Ile)

Conformational preferences of hypermodified nucleoside, 4-amino-2-(N(6)-lysino)-1-(beta-D-ribofuranosyl) pyrimidinium (Lysidine or 2-lysyl cytidine), usually designated as k(2)C, have been investigated theoretically by the quantum chemical perturbative configuration interaction with localized orbitals (PCILO) method. The zwitterionic, non-zwitterionic, neutral, and tautomeric forms have been studied. Automated geometry optimization using molecular mechanics force field (MMFF), semi-empirical quantum chemical PM3, and ab initio molecular orbital Hartree-Fock SCF quantum mechanical calculations have also been made to compare the salient features. The predicted most stable conformations of zwitterionic, non-zwitterionic, neutral, and tautomeric form are such that in each of these molecules the orientation of lysidine moiety (R) is trans to the N(1) of cytidine. The preferred base orientation is anti (chi = 3 degrees ) and the lysine substituent folds back toward the ribose ring. This results in hydrogen bonding between the carboxyl oxygen O(12a) of lysine moiety and the 2'-hydroxyl group of ribose sugar. In all these four forms of lysidine O(12a)...H-C(9) and O(12b)...H-N(11) interactions provide stability to respective stable conformers. Watson-Crick base pairing of lysidine with A is feasible only with the tautomeric form of usual anti oriented lysidine. This can help in recognition of AUA codon besides in avoiding misrecognition of AUG.