Synthesis of a new N-9 ribityl analogue of cyclic inosine diphosphate ribose (cIDPR) as a mimic of cyclic ADP ribose (cADPR)

A new analogue of cyclic inosine diphosphate ribose (cIDPR), in which the N-1 and N-9 ribosyl moieties were substituted by a carbocyclic moiety and a hydroxyl-alkyl chain, has been synthesized and characterized.     

Solid phase synthesis of nucleobase and ribose modified inosine nucleoside analogues

The synthesis and the use of new N-1-dinitrophenyl-inosine based solid support is reported. The support, which binds the nucleoside by a 5'-O-monomethoxytrityl function, reacting with N-nucleophiles allowed the synthesis of a small library of N-1 alkylated inosine and AICAR derivatives. Moreover, the obtained supports, after the cleavage of the 2' -3' ribose bond, furnished a set of new N-1 alkylated-2' -3' -secoinosine derivatives in high yields.     

West Nile virus 5'-cap structure is formed by sequential guanine N-7 and ribose 2'-O methylations by nonstructural protein 5

Many flaviviruses are globally important human pathogens. Their plus-strand RNA genome contains a 5'-cap structure that is methylated at the guanine N-7 and the ribose 2'-OH positions of the first transcribed nucleotide, adenine (m(7)GpppAm). Using West Nile virus (WNV), we demonstrate, for the first time, that the nonstructural protein 5 (NS5) mediates both guanine N-7 and ribose 2'-O methylations and therefore is essential for flavivirus 5'-cap formation. We show that a recombinant full-length and a truncated NS5 protein containing the methyltransferase (MTase) domain methylates GpppA-capped and m(7)GpppA-capped RNAs to m(7)GpppAm-RNA, using S-adenosylmethionine as a methyl donor. Furthermore, methylation of GpppA-capped RNA sequentially yielded m(7)GpppA- and m(7)GpppAm-RNA products, indicating that guanine N-7 precedes ribose 2'-O methylation. Mutagenesis of a K(61)-D(146)-K(182)-E(218) tetrad conserved in other cellular and viral MTases suggests that NS5 requires distinct amino acids for its N-7 and 2'-O MTase activities. The entire K(61)-D(146)-K(182)-E(218) motif is essential for 2'-O MTase activity, whereas N-7 MTase activity requires only D(146). The other three amino acids facilitate, but are not essential for, guanine N-7 methylation. Amino acid substitutions within the K(61)-D(146)-K(182)-E(218) motif in a WNV luciferase-reporting replicon significantly reduced or abolished viral replication in cells. Additionally, the mutant MTase-mediated replication defect could not be trans complemented by a wild-type replicase complex. These findings demonstrate a critical role for the flavivirus MTase in viral reproduction and underscore this domain as a potential target for antiviral therapy.     

Identification by modification-interference of purine N-7 and ribose 2'-OH groups critical for catalysis by bacterial ribonuclease P.

The RNA subunit of bacterial ribonuclease P is a catalytic RNA that cleaves precursor tRNAs to generate mature tRNA 5' ends. A self-cleaving RNase P RNA-substrate conjugate was used in modification-interference analysis to identify purine N-7 and ribose 2'-hydroxyl functional groups that are critical to catalysis. We identify six adenine N-7 groups and only one 2'-hydroxyl that, when substituted with 7-deazaadenine or 2'-deoxy analogues, respectively, reduce the RNase P catalytic rate approximately 10-fold at pH 8 and limiting concentration of magnesium. Two sites of low-level interference by phosphorothioate modification were detected in addition to the four sites of strong interference documented previously. These modification-interference results, the absolute phylogenetic conservation of these functional groups in bacterial RNase P RNA, their proximity to the substrate-phosphate in the tertiary structure of the ribozyme-substrate complex, and the importance of some of the sites for binding of catalytic magnesium all implicate these functional groups as components of the RNase P active site. Five of the 7-deazaadenine interferences are suppressed at pH 6, where the hydrolytic step is rate-limiting, or at saturating concentrations of magnesium. We propose, therefore, that these base functional groups are specifically engaged in the catalytic center of RNase P RNA, possibly by involvement in magnesium-dependent folding. One 7-deazaadenine interference and one 2'-deoxy-interference, although partially suppressed at pH 6, are not suppressed at saturating magnesium concentrations. This implicates these groups in magnesium-independent folding of the catalytic substructure of the ribozyme.     

Effects of ribose as an ergogenic aid

The amount of adenosine triphosphate (ATP) stored in the muscle available for immediate use is limited, and once used, must be resynthesized in the muscle. Ribose, a naturally occurring pentose sugar, helps resynthesize ATP for use in muscles. There have been claims that ribose supplements increase ATP levels and improve performance. Other studies have provided mixed results on the effectiveness of ribose as an ergogenic aid at high doses. None of these studies have compared the impact of the recommended dose of ribose on athletes and nonathletes under exercise conditions that are most conducive for effectiveness. The purpose of this study was to evaluate the effectiveness of ribose as an ergogenic aid at the dose recommended for supplements currently on the market during an exercise trial to maximize its efficacy. Male subjects (n = 11) performed 2 trials 1 week apart. Each trial consisted of three 30-second Wingate tests with a 2-minute recovery between each test. Trials were counterbalanced, with 1 trial being performed with 625 mg of ribose and the other with a placebo. Peak power, mean power, and percent decrease in power were recorded during each Wingate test. Repeated-measures analysis of variance (p > 0.05) found no significant differences between ribose and placebo. These results suggest that ribose had no effect on performance when taken orally, at the dose suggested by the distributor.     

Molecular interactions in ribose transport: the binding protein module symmetrically associates with the homodimeric membrane transporter.

The Escherichia coli high-affinity ribose transporter is composed of the periplasmic ribose-binding protein (RBP or RbsB), the membrane component (RbsC) and the ATP-binding protein (RbsA). In order to dissect the molecular interactions initiating the transport process, RbsC suppressors for transport-defective rbsB mutations were isolated. These suppressors are localized in two regions of RbsC, which are allele-specific to N- or C-terminal domain mutations of RBP, suggesting that there are two distinct regions of RbsC, each interacting with one of the two domains of RBP. To demonstrate that these two regions provide a homodimeric binding surface for RBP we constructed a dimeric rbsC in which two genes are joined tandemly from head to tail with the addition of a linker. The dimeric RbsC protein is stable and functional in growth and ribose uptake. By exploiting the allele specificity between the domain-specific mutations and their suppressors, we generated all mutation-suppressor combinations in a single rbsB plus the dimeric rbsC genes. Their phenotypes are consistent with the proposal that the binding protein module interacts symmetrically with homodimeric RbsC. The mode of association proposed here for the ribose transport components could be extended to other ABC transporters with similar structural organizations.     

Labeling of functionally sensitive sulfhydryl-containing domains of acetylcholine receptor from Torpedo californica membranes

N-(1-Pyrene)maleimide, a fluorescent, lipophilic, alkylating agent, was used as a probe for the nicotinic acetylcholine receptor (AChR). Preincubation with N-(1-pyrene)maleimide under nonreducing conditions inhibits agonist-induced cation permeability of AChR-enriched membranes. This inhibition is dependent on the concentration of N-(1-pyrene)maleimide used. This correlation was also exhibited by resonance energy transfer of tryptophan fluorescence to N-(1-pyrene)maleimide and by the labeling stoichiometries. However, agonist-induced desensitization, as based on the time-dependent inhibition of alpha-bungarotoxin binding upon preincubation with the agonist carbamylcholine, was unaffected by N-(1-pyrene)maleimide. Alkylation of the AChR by N-(1-pyrene)maleimide is pH-dependent with an apparent pKa of 7.5 and is unaffected by preincubation with carbamylcholine, alpha-bungarotoxin, tubocurarine, or decamethonium. Preincubation with a 25-fold molar excess of N-ethylmaleimide partially protects against N-(1-pyrene)maleimide, yet simultaneous incubation with an equimolar concentration does not protect. In contrast, simultaneous incubation with equimolar concentrations of phenylmaleimide or naphthylmaleimide inhibited N-(1-pyrene)maleimide alkylation by 52 and 67%, respectively. Each AChR subunit is labeled by N-(1-pyrene)maleimide. Prior alkylation with N-ethylmaleimide does not alter the labeling profile but lowers the amount of labeling of all subunits. Reductive methylation of membranes under conditions which dimethylate all or most protein amino groups does not inhibit alkylation by N-(1-pyrene)maleimide. The above results, as well as amino acid analysis of N-(1-pyrene)maleimide-alkylated receptor, indicate that a homologous class of cysteines, which reside in each subunit within the AChR domain embedded in the membrane, are involved in the reaction with N-(1-pyrene)maleimide.     

Profiling of RNA ribose methylation in Arabidopsis thaliana

Eukaryotic rRNAs and snRNAs are decorated with abundant 2′-O-methylated nucleotides (Nm) that are predominantly synthesized by box C/D snoRNA-guided enzymes. In the model plant Arabidopsis thaliana, C/D snoRNAs have been well categorized, but there is a lack of systematic mapping of Nm. Here, we applied RiboMeth-seq to profile Nm in cytoplasmic, chloroplast and mitochondrial rRNAs and snRNAs. We identified 111 Nm in cytoplasmic rRNAs and 19 Nm in snRNAs and assigned guide for majority of the detected sites using an updated snoRNA list. At least four sites are directed by guides with multiple specificities as shown in yeast. We found that C/D snoRNAs frequently form extra pairs with nearby sequences of methylation sites, potentially facilitating the substrate binding. Chloroplast and mitochondrial rRNAs contain five almost identical methylation sites, including two novel sites mediating ribosomal subunit joining. Deletion of FIB1 or FIB2 gene reduced the accumulation of C/D snoRNA and rRNA methylation with FIB1 playing a bigger role in methylation. Our data reveal the comprehensive 2′-O-methylation maps for Arabidopsis rRNAs and snRNAs and would facilitate study of their function and biosynthesis.     

Thermodynamic and EPR characterization of iron-sulfur centers in the NADH-ubiquinone segment of the mitochondrial respiratory chain in pigeon heart.

Several iron-sulfur centers in the NADH-ubiquinone segment of the respiratory chain in pigeon heart mitochondria and in submitochondrial particles were analyzed by the combined application of cryogenic EPR (between 30 and 4.2 degrees K) and potentiometric titration. Center N-1 (iron-sulfur centers associated with NADH dehydrogenase are designated with the prefix "N") resolves into two single electron titratins with EM7.2 values of minus 380 plus or minus 20 mV and minus 240 plus or minus 20 mV (Centers N-1a and N-1b, respectively). Center N-1a exhibits an EPR spectrum of nearly axial symmetry with g parellel = 2.03, g = 1.94, while that of Center N-1b shows more apparent rhombic symmetry with gz = 2.03, gy = 1.94 and gx = 1.91. Center N-2 also reveals EPR signals of axial symmetry at g parallel = 2.05 and g = 1.93 and its principal signal overlaps with those of Centers N-1a and N-1b. Center N-2 can be easily resolved from N-1a and N-1b because of its high EM7.2 value (minus 20 plus or minus 20 mV). Resolution of Centers N-3 and N-4 was achieved potentiometrically in submitochondrial particles. The component with EM7.2 = minus 240 plus or minus 20 mV is defined as Center N-3 (gz = 2.10, (gz = 2.10, (gy = 1.93?), GX = 1.87); the minus 405 plus or minus 20 mV component as Center N-4 (gz = 2.11, (gy = 1.93?), gx = 1.88). At temperatures close to 4.2 degrees K, EPR signals at g = 2.11, 2.06, 2.03, 1.93, 1.90 and 1.88 titrate with EM7.2 = minus 260 plus or minus 20 mV. The multiplicity of peaks suggests the presence of at least two different iron-sulfur centers having similar EM7.2 values (minus 260 plus or minus 20 mV); HENCE, tentatively assigned as N-5 and N-6. Consistent with the individual EM7.2 values obtained, addition of succinate results in the partial reduction of Center N-2, but does not reduce any other centers in the NADH-ubiquinone segment of the respiratory chain. Centers N-2, N-1b, N-3, N-5 and N-6 become almost completely reduced in the presence of NADH, while Centers N-1a and N-4 are only slightly reduced in pigeon heart submitochondrial particles. In pigeon heart mitochondria, the EM7.2 of Center N-4 lies much closer to that of Center N-3, so that resolution of the Center N-3 and N-4 spectra is not feasible in mitochondrial preparations. EM7.2 values and EPR lineshapes for the other iron-sulfur centers of the NADH-ubiquinone segment in the respiratory chain of intact mitochondria are similar to those obtained in submitochondrial particle preparations. Thus, it can be concluded that, in intact pigeon heart mitochondria, at least five iron-sulfur centers show EM7.2 values around minus 250 mV; Center N-2 exhibits a high EM7.2 (minus 20 plus or minus 20 mV), while Center N-1a shows a very low EM7.2 (minus 380 plus or minus 20 mV).     

Neuroblastoma Cell Membranes: Specificity for Cell Fusion Mediated by a Temperature-Sensitive Mutant of Vesicular Stomatitis Virus

Abstract: Temperature-sensitive mutant G3 1 of vesicular stomatitis virus induces mouse neuroblastoma N-18 cells to fuse during infections that are nonpermissive for virus replication, but BHK-21 cells do not undergo the viral glycoprotein-mediated cell fusion. The viral glycoprotein was expressed at the cell surface of both N-18 and BHK-21 cells; therefore, the host cell specificity did not stem from an absence of the viral glycoprotein at the surface of BHK-21 cells. Cell fusion readily occurred between infected and uninfected N-18 cells in mixed cultures, demonstrating that the viral glycoprotein was interacting with an uninfected cell for the initial cell-cell interaction of the cell fusion. Mixing infected BHK-21 cells with uninfected N-18 cells resulted in cell fusion initiated by BHK-21 cell-synthesized viral glycoprotein, but 88% of the nucleiin polykaryocytes were N-18 nuclei. The N-18 cell fusion specificity was readily apparent when infected N-18 cells were mixed with uninfected BHK-21 cells; 98% of the nuclei in polykaryocytes were N-18 nuclei. Similar results also were obtained with mixed cultures of N-18 cells and primary astroglial cells. Thus, the viral glycoprotein synthesized in any of the cell types could initiate cell fusion, but the properties of plasma membranes of neuroblastoma cells appeared to be much more suitable for cell-cell fusion.     

Determination of N-7-[2H3]methyl guanine in rat urine by gas chromatography-mass spectrometry following administration of trideuteromethylating agents or precursors

A gas chromatographic-mass spectrometric method has been developed for the determination of N-7-[2H3]methyl guanine in urine in the presence of large natural levels of N-7-methyl guanine. Urine is fractionated on heptanesulfonic acid-treated C-18 Sep-pak cartridges, followed by derivatization to give a volatile N-heptafluorobutyryl-O6-2,3,4,5, 6-pentafluorobenzyl derivative which is separated on an SE52 fused silica capillary column. Using N-7-ethyl guanine as an internal standard, the total amount of N-7-methyl guanine is determined by gas chromatography-flame ionization detection. The percentage of N-7-[2H3]methyl guanine is then measured by gas chromatography-mass spectrometry, enabling the amount of deuterated base to be determined. Preliminary experiments with [2H3]methyl methanesulfonate in rats showed measurable excretion of N-7-[2H3]methyl guanine. 4-(Di[2H3]methylamino)antipyrine alone gave no detectable amount of alkylated base, but coadministration of nitrite resulted in excretion of deuterated N-7-methyl guanine.     

Mass spectral characterization of fatty acid amides from alfalfa trichomes and their deterrence against the potato leafhopper

A homologous series of N-(3-methylbutyl)amides of normal saturated C14, C15, C16, C17 and C18 fatty acids were identified as major components of glandular trichome extracts from Medicago sativa G98A, an alfalfa genotype resistant to the potato leafhopper, Empoasca fabae. A second homologous series of N-(2-methylpropyl)amides of C14 through C18 normal fatty acids were minor components. Saturated free fatty acids C12, C13, C14, C15, C16, C17 and C18 were present in trace amounts, as was the N-(3-methylbutyl)amide of linoleic acid (C18:2). N-(3-methylbutyl)amides and N-(2-methylpropyl)amides of C14 through C18 fatty acids, along with the N-(3-methylbutyl)amide of linoleic acid, were synthesized and bioassayed for leafhopper deterrence by applying the compounds to the surface of a sachet containing an artificial diet. Leafhoppers were then offered a two-way choice between diet surfaces treated with the synthetic amides or an untreated control. N-(3-methylbutyl)amides and N-(2-methylpropyl)amides of C14 through C18 fatty acids did not deter leafhopper settling in a dose-dependent fashion. In contrast, when tested singly, N-(3-methylbutyl)amide of linoleic acid exhibited dose-dependent deterrence against leafhopper settling. Fatty acid amides localized in alfalfa glandular trichomes likely contribute to leafhopper resistance.