The structure of the guanine cation: ESR/ENDOR of cyclic guanosine monophosphate single crystals after X irradiation at 10 K.

Following X irradiation of 3',5'-cyclic guanosine monophosphate single crystals at 10 K, several free radicals were trapped and detected by ESR/ENDOR/FSE spectroscopy. The two dominant species both have unpaired spin located on the guanine base. One is the product of net hydrogen atom loss from the exocyclic amino group. The spectroscopic characteristics of this resonance leave this assignment unambiguous. The experimental conditions make it likely that this species was formed by deprotonation of the guanine base cation. The nature of the other species is more uncertain. However, the evidence is consistent with the assignment that it is a net OH adduct to the C4 position of the base. Several species in which the unpaired spin was located on the sugar-phosphate region of the molecule were also observed. The mechanisms for the decay of the primary radicals, also leading to the well-known C8 hydrogen addition radical of the guanine base, are described and discussed.     

Biosynthesis of Riboflavine in Corynebacterium Species: the Purine Precursor

Corynebacterium species lacks the ability to convert either xanthine or guanine to adenine. This defect and the use of the purine nucleoside antibiotic decoyinine, which blocks the conversion of xanthosine monophosphate --> guanosine monophosphate, permit an experimental design in which the interconversion of purines is largely prevented. Cultures of this organism were grown in the presence of decoyinine and various purine supplements. Data obtained by comparing the radioactivity incorporated from guanine-2-(14)C or xanthine-2-(14)C into bacterial guanine, xanthine, and riboflavine indicate that guanine or a close derivative of guanine is the purine precursor of riboflavine.     

Electrocatalytic oxidation of guanine, guanosine, and guanosine monophosphate

The electrochemical behavior of guanine, guanosine, and guanosine monophosphate (GMP) at redox polymer film modified indium tin oxide electrodes is examined by voltammetry and redox titration. Utilizing the redox polymer-coated electrodes as indicator electrodes, a new method for measuring the oxidation potentials, based on monitoring their catalytic oxidation by different redox polymer coated electrodes at different pH, was proposed in this work. The oxidation potentials of 0.81 V and 1.02 V versus normal hydrogen electrode were determined for guanine and guanosine/GMP under physiological conditions, the lowest oxidation potentials ever reported, to our knowledge.     

Guanine salvage by organ cultures of mouse tooth germs

The effect of mycophenolic acid (MPA) which inhibits the biosynthesis of guanosine monophosphate (GMP) in organ cultures of mouse tooth germs can be partially counteracted by adding guanine to the MPA cultures. This may be due to salvaging guanine by the enzyme hypoxanthine guanine phosphoribosyl transferase (HGPRT), or to competition for a common membrane carrier involved in mediated transport of both guanine and hypoxanthine in normal biosynthesis and also of MPA. Experiments were carried out to compare the effect of either hypoxanthine or guanine on the MPA-caused inhibition. While addition of guanine to the MPA cultures (MPAG) supports growth equal to controls and development of dental-enamel junction (DEJ) to a level intermediate between control and MPA the addition of hypoxanthine (MPAHX) supports growth and DEJ development not better than MPA. This indicates that guanine is salvaged by HGPRT to GMP while hypoxanthine, salvaged to inosinic acid (inosinic monophosphate, IMP) is ineffective because the MPA inhibition is on the pathway from IMP to GMP.     

Determination of the mutations responsible for the Lesch-Nyhan syndrome in 17 subjects

Hypoxanthine--guanine phosphoribosyltransferase (HPRT) is a purine salvage enzyme that catalyzes the conversion of hypoxanthine to inosine monophosphate and guanine to guanosine monophosphate. Previous studies of mutant HPRT proteins analyzed at the molecular level have shown a significant heterogeneity. This investigation further verifies this heterogeneity and identifies insertions, deletions, and point mutations. The direct sequencing of the polymerase chain reaction-amplified product of reverse-transcribed HPRT mRNA enabled the rapid identification of the mutations found in 17 previously uncharacterized cell lines derived from patients with the Lesch-Nyhan syndrome.     

Triplet state of the primary donor in reaction centers of the phototrophic bacterium Rhodobacter sphaeroides R26 with active photoinduced electron transfer

EPR characteristics of transient paramagnetic states photoinduced in isolated reaction centers of Rhodobacter sphaeroides R26 with intact electron transfer have been studied. It was demonstrated that the detected weak triplet state EPR signal belongs to the primary donor molecule and is populated via the conventional mechanism of radical pair S-T0 mixing. The distortion of the spectral shape of this signal is explained by the triplet quantum yield anisotropy brought about by the short lifetime of precursor radical pairs. The angular dependence of the anisotropy was evaluated. It was shown that the spectral shape of the triplet state of photosystem II reaction center observed in the case of singly-reduced primary quinone acceptor can also be described by the anisotropic quantum yield of the triplet, with practically the same angular dependence. These properties confirm the conclusions on the mechanism of photoinduced electron transfer in photosystem II, made in previous publications. The peculiarities in the functioning of photosystem II reaction centers are probably determined by strict limitations on the triplet state generation.     

Purine metabolism in Acholeplasma laidlawii B: novel PPi-dependent nucleoside kinase activity

Acholeplasma laidlawii B-PG9 was examined for 16 cytoplasmic enzymes with activity for purine salvage and interconversion. Phosphoribosyltransferase activities for adenine, guanine, xanthine, and hypoxanthine were shown. Adenine, guanine, xanthine, and hypoxanthine were ribosylated to their nucleoside. Adenosine, inosine, xanthosine, and guanosine were converted to their base. No ATP-dependent phosphorylation of nucleosides to mononucleotides was found. However, PPi-dependent phosphorylation of adenosine, inosine, and guanosine to AMP, inosine monophosphate, and GMP, respectively, was detected. Nucleotidase activity for AMP, inosine monophosphate, xanthosine monophosphate, and GMP was also found. Interconversion of GMP to AMP was detected. Enzyme activities for the interconversion of AMP to GMP were not detected. Therefore, A. laidlawii B-PG9 cannot synthesize guanylates from adenylates or inosinates. De novo synthesis of purines was not detected. This study demonstrates that A. laidlawii B-PG9 has the enzyme activities for the salvage and limited interconversion of purines and, except for purine nucleoside kinase activity, is similar to Mycoplasma mycoides subsp. mycoides. This is the first report of a PPi-dependent nucleoside kinase activity in any organism.     

Contrasting observations on buffer catalysis of guanosine amino proton exchange.

The two amino protons of 3', 5'-cyclic guanosine monophosphate are shown to differ drastically in their solvent exchange properties: One is rapidly exchanging and sensitive to buffer catalysis; the other slow and insensitive. This observation accounts for the marked contrast between stopped-flow and NMR observations on buffer catalysis of amino proton exchange in guanosine monophosphates. The amino protons of guanine compounds traverse a "fast" solvent exchange position through the process of amino rotation, which together with kinetic considerations and comparative data on adenine and cytosine compounds, supports proposals of solvent exchange mediated by events at the guanine (N-3) site, rather than the (N-7) site. Exchange does not conform to rate expressions used by different workers for amino proton exchange.     

A light-induced spin-polarized triplet detected by EPR in photosystem II reaction centers

A light-induced spin-polarized triplet state has been detected in a purified Photosystem II preparation by electron paramagnetic resonance spectroscopy at liquid helium temperature. The electron spin polarization pattern is interpreted to indicate that the triplet originates from radical pair recombination between the oxidized primary donor chlorophyll, P-680+, and the reduced intermediate pheophytin, I-, as has been previously demonstrated in bacterial reaction centers. The dependence of the triplet signal on the redox state of I and the primary acceptor, Q, are consistent with the origin of the triplet signal from the triplet state of P-680. Redox-poising experiments indicate the presence of an endogenous donor (or donors) which operates at 3-5 K and 200 K. The zero field-splitting parameters of the triplet are very similar to those of monomeric chlorophyll a however, this alone does not allow a distinction to be made between monomeric and dimeric structures for P-680.     

Triplet state of the primary donor in reaction centers of the phototrophic bacterium <Emphasis Type="Italic">Rhodobacter sphaeroides</Emphasis> R26 with active photoinduced electron transfer

EPR characteristics of transient paramagnetic states photoinduced in isolated reaction centers of Rhodobacter sphaeroides R26 with intact electron transfer have been studied. It was demonstrated that the detected weak triplet state EPR signal belongs to the primary donor molecule and is populated via the conventional mechanism of radical pair S-T₀ mixing. The distortion of the spectral shape of this signal is explained by the triplet quantum yield anisotropy brought about by the short lifetime of precursor radical pairs. The angular dependence of the anisotropy was evaluated. It was shown that the spectral shape of the triplet state of photosystem II reaction center observed in the case of singly-reduced primary quinone acceptor can also be described by the anisotropic quantum yield of the triplet, with practically the same angular dependence. These properties confirm the conclusions on the mechanism of photoinduced electron transfer in photosystem II, made in previous publications. The peculiarities in the functioning of photosystem II reaction centers are probably determined by strict limitations on the triplet state generation.     

The rates of electron transfer from ClUra- and ClUraH-to p-nitroacetophenone.

Pulse-radiolysis experiments demonstrate that both the radical ion CIUra-/- and the protonated radical CIUraH- Of chlorouracil will transfer electrons to p-nitroacetophenone (PNAP). The reaction of CIUraH- is complicated by unknown reaction with PNAP below pH 4-4. Rate constants measured for reactions (2) and (3) are kappa2=5-3 x 109 and kappa3=3-3 x 109 M-1 sec -1. See article. An independent determination of the rate-constant for dissociation of the radical ion (equation (1)) was also obtained (kappa1=0-7 x 105 sec -1). See article.     

Pathways of electron transfer photosensitized by thiacyanine dimers

Pathways of electron transfer reaction between p-nitroacetophenone (p-NAP) and ascorbic acid (AA) photosensitized by dimers of 3,3'-disulfopropyl-5,5'-dichlorothiacyanine triethylammonium (TC) and 3,3'-disulfopropyl-5,5'-dichloro-9,11-[ββ-dimethyltrimethylene]thiadicarbocyanine triethylammonium (TDC) are considered. In aqueous solution the dyes are present as an equilibrated mixture of monomers (M(-)) and dimers (M(2)(2-)). In contrast to monomers, the dimers of TC are characterized by a noticeable yield of intersystem crossing, whereas for TDC the triplet-triplet absorption of both monomers and dimers is easily observed upon ns-laser pulse. In the presence of p-NAP and AA the triplet state of the dimers of both dyes is mostly quenched by p-NAP yielding the radical pair [M(2)(-)˙p-NAP(-)˙] with subsequent dissociation of M(2)(-)˙ into M(-) and M˙ followed by one-electron reduction of M˙ by AA. These steps constitute a pathway of photosensitization by the dimers. For TDC an additional pathway of photosensitization was found to occur. The primary step consists of electron transfer in the excited singlet state of the dimer resulting in the formation of the radicals M˙ and M(2-)˙. The next steps involve one-electron reduction of M˙ by AA and one-electron oxidation of M(2-)˙ by p-NAP which results in the formation of M(-) followed by dimerization.     

Purine requirements for the expression of Cape buffalo serum trypanocidal activity

Cape buffalo serum contains xanthine oxidase which generates trypanocidal H₂O₂ during the catabolism of hypoxanthine and xanthine. The present studies show that xanthine oxidase-dependent trypanocidal activity in Cape buffalo serum was also elicited by purine nucleotides, nucleosides, and bases even though xanthine oxidase did not catabolize those purines. The paradox was explained in part, by the presence in serum of purine nucleoside phosphorylase and adenosine deaminase, that, together with xanthine oxidase, catabolized adenosine, inosine, hypoxanthine, and xanthine to uric acid yielding trypanocidal H₂O₂. In addition, purine catabolism by trypanosomes provided substrates for serum xanthine oxidase and was implicated in the triggering of xanthine oxidase-dependent trypanocidal activity by purines that were not directly catabolized to uric acid in Cape buffalo serum, namely guanosine, guanine, adenine monophosphate, guanosine diphosphate, adenosine 3′:5-cyclic monophosphate, and 1-methylinosine. The concentrations of guanosine and guanine that elicited xanthine oxidase-dependent trypanocidal activity were 30–270-fold lower than those of other purines requiring trypanosome-processing which suggests differential processing by the parasites.     

The inter-relationship between triplet energies and spin chemistry.

Triplet energies play a considerable role in optical spectroscopy, and can be determined from phosphorescence or the quenching thereof. Their role in spin chemistry may not be as obvious, but the triplet state has always had an important function or utility, namely of reaction intermediates such as radical pairs, their precursors, of carbenes, and of the final products. In situ NMR spectroscopy represents a useful tool to explore certain properties of the triplet state, especially in cases with no phosphorescence. The 'phase' of CIDNP resonances, i.e., emission or enhanced absorption, reflects the spin selectivity of electron transfer reactions. In radical ion pairs the spin selectivity is determined by the relation between the change of the standard free enthalpy DeltaG degrees during the electron back transfer and the triplet energies (E(T)) of the products. If triplet recombination is energetically feasible (DeltaG degrees > E(T)), it is typically the more efficient process in agreement with the Marcus theory.     

Stimulation of Cu2+-catalyzed Oxidation of Norepinephrine by Nucleic Acid Components

Oxidation of norepinephrine catalyzed by Cu²⁺ was variously regulated with nucleic acid components. The reaction proceeded by a mechanism of sequential random ordered reaction via formation of the mixed complex of nucleic acid component, Cu²⁺ and aromatic reductone. Using norepinephrine as an aromatic reductone, the promoting activities of nucleic acid components on the oxidation of norepinephrine were compared and the effect of these components to the specific stage of the oxidation process was kinetically investigated. The results indicated that velocity of the oxidation was most remarkably stimulated in the presence of adenine. The velocity was followed by guanine, guanosine monophosphate, cytosine, cytidine, NAD⁺, adenosine, cytidine monophosphate, uridine monophosphate, then adenosine monophosphate in that order. It was also discussed that adenine was the most plausible nucleic acid component which could participate in the in vivo oxidation of norepinephrine, taking into account the concentration of Cu²⁺ and nucleic acid components in living tissues.     

EPR characterisation of the triplet state in photosystem II reaction centers with singly reduced primary acceptor Q(A)

The triplet states of photosystem II core particles from spinach were studied using time-resolved cw EPR technique at different reduction states of the iron--quinone complex of the reaction center primary electron acceptor. With doubly reduced primary acceptor, the well-known photosystem II triplet state characterised by zero-field splitting parameters |D|=0.0286 cm(-1), |E|=0.0044 cm(-1) was detected. When the primary acceptor was singly reduced either chemically or photochemically, a triplet state of a different spectral shape was observed, bearing the same D and E values and characteristic spin polarization pattern arising from RC radical pair recombination. The latter triplet state was strongly temperature dependent disappearing at T=100 K, and had a much faster decay than the former one. Based on its properties, this triplet state was also ascribed to the photosystem II reaction center. A sequence of electron-transfer events in the reaction centers is proposed that explains the dependence of the triplet state properties on the reduction state of the iron--quinone primary acceptor complex.     

Purine transport by Malpighian tubules of pteridine-deficient eye color mutants of Drosophila melanogaster

Uptakes of guanine into Malpighian tubules of wild-type Drosophila and the eye color mutants white (w), brown (bw), and pink-peach (p ^p) have been compared. Tubules for each of these mutants are unable to concentrate guanine intracellularly. The transport of xanthine and riboflavin is also deficient in w tubules. The transport of guanosine, adenine, hypoxanthine, and guanosine monophosphate is similar in wild-type and white Malpighian tubules. These data and other information about these mutants make it likely that these pteridine-deficient eye color mutants do not produce pigments because of the inability to transport a pteridine precursor. This view supports the hypothesis that mutants which lack both pteridine and ommochromes do so because precursors to both classes of pigments share a common transport system.This work was supported by Grant GM22366 from NIH.     

GTP degradation to guanine catalyzed by ribosomal subunits and microsomal-wash factors.

Ribosomes from stringent strains of bacteria generate (p)ppGpp if incubated with uncharged tRNA, a ribosomal wash fraction, GTP and ATP. By contrast, an analogous system from rat liver does not transform GTP to (p)ppGpp but degrades it to guanine. The reaction requires the ribosomal subunits, a 40 000-Mr and a 60 000-Mr microsomal wash protein factor and is inhibited if the ribosomal A-site is charged with aminoacyl tRNA. The degradation of GTP to guanine occurs in the following four distinct reaction steps: (a) hydrolysis of GTP to GDP plus Pi, (b) hydrolysis of GDP to GMP plus Pi, (c) hydrolysis of GMP to guanosine plus Pi, (d) hydrolysis of guanosine to guanine plus ribose. The reaction step (a) is inhibited by fusidic acid, cycloheximide, emetine, tetracycline and puromycin. The hydrolysis of GDP is inhibited strongly by fusidic acid, emetine and tetracycline. A putative physiological significance of this ribosome-dependent pathway in the processes of growth control of animal cells under conditions of amino acid deprivation is discussed.     

F.t.-i.r. and laser-Raman spectra of guanine and guanosine

Fourier-transform infrared (F.t.-i.r.) and laser-Raman spectra have been obtained for solid guanine. The F.t.-i.r. spectrum of guanosine in the solid state was also recorded. Assignments are proposed for the i.r. bands. The molecular basis of the spectral differences between guanine and guanosine are discussed.