Chemical reactivity of matched cytosine and thymine bases near mismatched and unmatched bases in a heteroduplex between DNA strands with multiple differences.

The chemical reactivity of matched T and C bases to osmium tetroxide and hydroxylamine near mismatched and unmatched bases in a heteroduplex between two strands of DNA with multiple differences was examined. Data was available for matched bases one or two positions away from 24 mismatches. Reactive bases were found near 16 of the mismatches and were usually one or two bases away. This reactivity is consistent with structural studies indicating perturbation of the duplex around mismatches and will allow another mode of study of the effect of mismatches. The reactivity of these bases was found not to be strongly correlated with mismatch type or GC basepair content of the basepairs around the mismatches. Extra reactivity may have been promoted by the presence of either T or C in the mismatch allowing increased reactivity of nearby T or C. The utility of the phenomenon for the detection of mutations is discussed. Unmatched bases in the heteroduplex also gives rise to reactive matched bases nearby.     

Forbidden synonymous substitutions in coding regions

In the evolution of highly conserved genes, a few "synonymous" substitutions at third bases that would not alter the protein sequence are forbidden or very rare, presumably as a result of functional requirements of the gene or the messenger RNA. Another 10% or 20% of codons are significantly less variable by synonymous substitution than are the majority of codons. The changes that occur at the majority of third bases are subject to codon usage restrictions. These usage restrictions control sequence similarities between very distant genes. For example, 70% of third bases are identical in calmodulin genes of man and trypanosome. Third-base similarities of distant genes for conserved proteins are mathematically predicted, on the basis of the G+C composition of third bases. These observations indicate the need for reexamination of methods used to calculate synonymous substitutions.      

Real-time evidence for EF-G-induced dynamics of helix 44 in 16S rRNA

The penultimate stem-loop of 16S ribosomal RNA (rRNA), helix 44, plays a central role in ribosome function. Using time-resolved dimethyl sulfate (DMS) probing, we have analyzed time-dependent modifications that occur at specific bases in this helix near the decoding region, resulting from the binding of elongation factor G (EF-G) in various forms. When EF-G-GTP is bound to 70S ribosomes, bases A1492 and A1493 are immediately protected, while other bases in the region show either no change or enhanced modification. When apo-EF-G is bound to 70S ribosomes and GTP is added, substantial transient time-dependent enhancement occurs at bases A1492 and A1493, with somewhat less enhancement occurring at base A1483, all in the first 45 ms. When mRNA and deacylated tRNAs are bound to the 70S ribosome and EF-G-GTP is added, bases A1492 and A1493 again show substantial and continued enhancement, while bases A1408, A1413, and A1418 all show time-dependent protection. These results provide primary, real-time evidence that EF-G induces direct or indirect structural changes in this region as EF-G is bound and as GTP is hydrolyzed.     

Identification of 10-methylsphinganine in cerebrosides of the guinea pig harderian gland

A large amount of branched long chain bases was detected in the cerebrosides of guinea pig Harderian gland. The long chain bases of cerebrosides were analyzed by GLC as trimethylsilyl derivatives. The branched long chain bases were separated into four peaks (I, II, III, IV) according to the number of carbon atoms and the position of branching. In the present work, the structures of long chain bases in the four peaks were analyzed by GLC and GC-MS after conversion of them to aldehydes, alcohols, and fatty acids. Furthermore the main component of long chain bases (Peak II) was isolated by HPLC as N-acetyl derivatives and analyzed by NMR. The structures of branched long chain bases in Peaks I, II, III, and IV are as follows. Branched long chain bases of Peak I are 2-amino-10- (main component), 2-amino-9-, and 2-amino-8-methylhexadecane-1,3-diol. Branched long chain bases of Peak II also consist of a mixture of 2-amino-10-, 2-amino-9-, and 2-amino-8-methyl-heptadecane-1,3-diol. The branched long chain base of Peak III is 2-amino-10-methyl-octadecane-1,3-diol, while that of Peak IV is 2-amino-16-methyloctadecane-1,3-diol. Among these branched long chain bases, 10-methylsphinganines are dominant though the chain lengths are different. These branched long chain bases, in which the substituted positions exist in the middle part of aliphatic chain (10-, 9-, or 8-methylsphinganine) are novel long chain bases in mammals.     

Parallel multiplex thermodynamic analysis of coaxial base stacking in DNA duplexes by oligodeoxyribonucleotide microchips

Parallel thermodynamic analysis of the coaxial stacking effect of two bases localized in one strand of DNA duplexes has been performed. Oligonucleotides were immobilized in an array of three-dimensional polyacrylamide gel pads of microchips (MAGIChips‘). The stacking effect was studied for all combinations of two bases and assessed by measuring the increase in melting temperature and in the free energy of duplexes formed by 5mers stacked to microchip-immobilized 10mers. For any given interface, the effect was studied for perfectly paired bases, as well as terminal mismatches, single base overlaps, single and double gaps, and modified terminal bases. Thermodynamic parameters of contiguous stacking determined by using microchips closely correlated with data obtained in solution. The extension of immobilized oligonucleotides with 5,6-dihydroxyuridine, a urea derivative of deoxyribose, or by phosphate, decreased the stacking effect moderately, while extension with FITC or Texas Red virtually eliminated stacking. The extension of the immobilized oligonucleotides with either acridine or 5-nitroindole increased stacking to mispaired bases and in some GC-rich interfaces. The measurements of stacking parameters were performed in different melting buffers. Although melting temperatures of AT- and GC-rich oligonucleotides in 5 M tetramethylammonium chloride were equalized, the energy of stacking interaction was significantly diminished.     

Free sphingoid bases in normal murine tissues

Free sphingoid bases, which have been considered not to occur naturally, were detected in murine tissues by derivatization with o-phthalaldehyde and the use of high-performance liquid chromatography. The concentrations were 10-30 pmol/mg tissue. The lung contained the largest amounts of sphingoid bases. In the molecular species of sphingoid bases, the most abundant was C18-sphingenine followed by C18-sphinganine, 4-hydroxysphinganine and C20-sphingenine, in that order. The central nervous tissues contained relatively high amounts of C20-sphingenine and there was a high concentration of 4-hydroxysphinganine in the kidney. In addition, galactosylsphingenine was detected simultaneously in the spinal cord and sciatic nerve. Sphingoid bases were purified from normal murine lungs using lipid-extraction, cation-exchange and silicic acid column chromatographies, alkaline saponification and preparative thin-layer chromatography. In the purified sphingoid bases, erythro-C18-sphingenine and erythro-C18-sphinganine were identified using thin-layer chromatography, high-performance liquid chromatography and fast-atom-bombardment mass spectrometry. Free sphingoid bases occurring in normal tissues may be metabolic intermediates required for the synthesis or be products of degradation of the sphingolipids and function to regulate cellular metabolism.     

Base coupling in sequence-specific site recognition by the ETS domain of murine PU.1

The ETS domain of murine PU.1 tolerates a large number of DNA cognates bearing a central consensus 5'-GGAA-3' that is flanked by a diverse combination of bases on both sides. Previous attempts to define the sequence selectivity of this DNA binding domain by combinatorial methods have not successfully predicted observed patterns among in vivo promoter sequences in the genome, and have led to the hypothesis that energetic coupling occurs among the bases in the flanking sequences. To test this hypothesis, we determined, using thermodynamic cycles, the complex stabilities and base coupling energies of the PU.1 ETS domain for a set of 26 cognate variants (based on the lambdaB site of the Ig(lambda)2-4 enhancer, 5'-AATAAAAGGAAGTGAAACCAA-3') in which flanking sequences up to three bases upstream and/or two bases downstream of the core consensus are substituted. We observed that both cooperative and anticooperative coupling occurs commonly among the flanking sequences at all the positions investigated. This phenomenon extends at least three bases in the 5' side and is, at least on our experimental data, due exclusively to pairwise interactions between the flanking bases, and not changes in the local environment of the DNA groove floor. Energetic coupling also occurs between the flanking sides across the core consensus, suggesting long-range conformational effects along the DNA target and/or in the protein. Our data provide an energetic explanation for the pattern of flanking bases observed among in vivo promoter sequences and reconcile the apparent discrepancies raised by the combinatorial experiments. We also discuss the significance of base coupling in light of an indirect readout mechanism in ETS/DNA site recognition.     

Accumulation of phosphorylated sphingoid long chain bases results in cell growth inhibition in Saccharomyces cerevisiae

Sphingolipid metabolites in mammals can function as signaling molecules with cell-specific functions. In Saccharomyces cerevisiae, phosphorylated long chain bases, such as dihydrosphingosine 1-phosphate and phytosphingosine 1-phosphate, have also been implicated in stress responses. To further explore the biological roles of these molecules, we created disruption mutants for LCB4, LCB5, DPL1, YSR2, YSR3, and SUR2. LCB4 and LCB5 encode kinases that phosphorylate long chain bases. DPL1 and YSR2/YSR3 are involved in degradation of the phosphorylated long chain bases. SUR2 catalyzes conversion of dihydrosphingosine to phytosphingosine. We adapted an HPLC method to measure intracellular concentrations of the phosphorylated long chain bases. Double mutants of dpl1 and ysr2 were inviable, whereas dpl1 ysr2 lcb4 triple mutants were viable. Further, growth inhibition associated with accumulated phosphorylated long chain bases was observed in the triple mutant dpl1 ysr2 lcb4 overexpressing LCB4 or LCB5. These results indicate that phosphorylated long chain bases can inhibit cell growth. Mutants defective in both YSR2 and SUR2, which accumulated dihydrosphingosine 1-phosphate only, grew poorly. The phenotypes of the ysr2 sur2 mutants were suppressed by overexpression of DPL1. Our results clearly show that elevated levels of phosphorylated long chain bases have an antiproliferative effect in yeast.     

A computational study of expanded heterocyclic nucleosides in DNA

The first molecular dynamics study of a series of heterospacer-expanded tricyclic bases in DNA using modified force field parameters in AMBER is detailed. The expanded purine nucleoside monomers have been designed to probe the effects of a heteroaromatic spacer ring on the structure, function, and dynamics of the DNA helix. The heterobase scaffold has been expanded with a furan, pyrrole, or thiophene spacer ring. This structural modification increases the polarizability of the bases and provides an additional hydrogen bond donor with the amine hydrogen of the pyrrole ring or hydrogen bond acceptor with the furan or thiophene ring free electron pairs. The polarizability of the expanded bases were determined by AM1 calculations and the results of the MD simulations of 20-mers predict that the modified curvature of the expanded base leads to a much larger major groove, while the effect on the minor groove is negligible. Overall, the structure resembles A-DNA. MD simulations of 10-mers suggest that the balance between base pairing vs. base stacking and intercalation can be shifted towards the latter due to the increased surface area and polarizability of the expanded bases.     

Additional possibilities of the formation of incorrect nucleotide pairs

Calculations of intermolecular interaction energies for the systems consisting of two nitrogen bases and one or two molecules of water have been performed by the atom--atom potential function method. In some energy minima corresponding to the arrangement of the bases with one of the bases being in the syn-orientation with respect to the sugar two bases are linked through one H-bond and one or two water bridges. Such pairs provide an additional possible pathway for the appearance of errors during template biosynthesis.     

Antiviral activity of polynucleotides: copolymers of inosinic acid and N2-dimethylguanylic of 2-methylthioinosinic acid.

Complexes of poly(C) with copolymers of inosinic acid containing various amounts of mismatched bases (see journal for formula) have been examined for direct resistance to virus infection, interferon induction and toxicity in two different cell cultures (primary rabbit kidney cells and mouse L-929 cells). Complexes in which 20% of the hypoxanthine bases were replaced by (see journal for formula) or ms-2I were partially active whereas complexes in which 40% or more of the hypoxanthine bases were replaced by the odd bases were entirely inactive. The decrease in biological activity observed upon intrusion of (see journal for formula) or ms-2I in the poly(I) strand of poly(I) with poly(C) closely paralleled the amount of odd bases introduced irrespective of the system employed to assess the biological activity (resistance to virus infection, interferon induction or toxicity).     

Recognition of the tRNA-like structure in tobacco mosaic viral RNA by ATP/CTP:tRNA nucleotidyltransferases from Escherichia coli and Saccharomyces cerevisiae

The 3'-terminal tRNA-like structure of the tobacco mosaic virus RNA interacts with ATP/CTP:tRNA nucleotidyltransferases from Escherichia coli or yeast in much the same manner as do tRNAs. Primary sites of interaction cluster near the 3' end and in the loop proposed to be analogous to the psi-loop of a tRNA. Some modified bases in the tRNA-like structure inhibit interaction with nucleotidyltransferase, yet the analogous bases in a tRNA do not. The location of some of these nucleotides within the analog to the psi-loop suggests that this structure differs slightly from its counterpart in a tRNA. The location of other such bases in the helical stem near the 3' end can be explained if the pseudoknot is disrupted by these modified bases or if the tertiary structure of the RNA is altered in the enzyme-RNA complex. A partially denatured secondary structure that persists on denaturing gels is proposed.     

Comparative reactivity of mismatched and unpaired bases in relation to their type and surroundings. Chemical cleavage of DNA mismatches in mutation detection analysis

Systematic study of chemical reactivity of non-Watson–Crick base pairs depending on their type and microenvironment was performed on a model system that represents two sets of synthetic DNA duplexes with all types of mismatched and unmatched bases flanked by T·A or G·C pairs. Using comparative cleavage pattern analysis, we identified the main and additional target bases and performed quantitative study of the time course and efficacy of DNA modification caused by potassium permanganate or hydroxylamine. Potassium permanganate in combination with tetraethylammonium chloride was shown to induce DNA cleavage at all mismatched or bulged T residues, as well as at thymines of neighboring canonical pairs. Other mispaired (bulged) bases and thymine residues located on the second position from the mismatch site were not the targets for KMnO₄ attack. In contrast, hydroxylamine cleaved only heteroduplexes containing mismatched or unmatched C residues, and did not modify adjacent cytosines. However when G·C pairs flank bulged C residue, neighboring cytosines are also attacked by hydroxylamine due to defect migration. Chemical reactivity of target bases was shown to correlate strongly with the local disturbance of DNA double helix at mismatch or bulge site. With our model system, we were able to prove the absence of false-negative and false-positive results. Portion of heteroduplex reliably revealed in a mixture with corresponding homoduplex consists of 5% for bulge bases and “open” non-canonical pairs, and 10% for wobble base pairs giving minimal violations in DNA structure. This study provides a complete understanding of the principles of mutation detection methodology based on chemical cleavage of mismatches and clarifies the advantages and limitations of this approach in various biological and conformational studies of DNA.     

Purine metabolism in Trypanosoma brucei gambiense

The procyclic forms of Trypanosoma brucei gambiense do not incorporate glycine or serine into ribonucleotides. Although de novo purine synthesis does not occur, all purine bases and ribonucleotides are interconverted, indicating the presence of active salvage pathways. Guanine is actively deaminated to xanthine by guanase activity. Purine ribonucleosides are cleaved to their respective free bases. The order of salvage efficiency for purine bases and their respective ribonucleotides is: adenine > hypoxanthine > guanine > xanthine.     

Current chemical concepts of acids and bases and their application to anionic ("acid") and cationic ("basic") dyes

In biomedical studies, dyes are divided into "acid" and "basic" dyes. This classification cannot be reconciled with current chemical definitions of acids and bases. Br?nsted-Lowry acids are compounds that can donate protons; bases are proton acceptors. The definition of acids and bases is independent of the electric charge, i.e. acids and bases can be neutral, anionic or cationic. Reactions between acids and bases result in formation of new acid-base pairs. Lewis acids and bases do not depend on a particular element, but are characterized by their electronic configurations. Lewis bases are electron donors; Lewis acids are electron acceptors. This classification is also unrelated to the electric charge. Lewis acids and bases interact by formation of coordinate covalent bonds. In histochemistry and histology, dyes containing -SO3-, -COO- and/or -O- groups are classified as "acid" dyes. However, such compounds are electron pair donors and hence Br?nsted-Lowry and Lewis anionic bases. Dyes carrying a positive charge are termed "basic" dyes. Chemically, many cationic dyes are Lewis acids because they can add a base, e.g. OH-, acetate, halides. The hypothesis that transformation of -NH2 into ammonium groups imparts "basic" properties to dyes is untenable; ammonium groups are proton donors and hence acids. Furthermore, conversion of an amino into an ammonium group blocks a lone electron pair and the color of the dye changes drastically, e.g. from violet to green and yellow. It appears therefore highly unlikely that ammonium groups are responsible for binding of cationic ("basic") dyes. In histochemistry, it is usually not of critical importance whether anionic or cationic dyes are chemically acids or bases.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the Formation of Uricase by Streptomyces

The induced formation of uricase by the cultured cells of Streptomyces sp. and the effect of purine bases on the enzyme formation were studied. The microorganism was grown in media containing urate and/or purine bases (adenine, guanine, hypoxanthine or xanthine) and the development of the uricase activity of the cells were measured at intervals. The disappearance of urate and purine bases from the media was also determined. Without the purine bases, the production of uricase was significantly low even in the presence of urate and the disappearance of urate from the medium was in a slow rate. Upon the addition of hypoxanthine or xanthine in the presence of urate, a significant increase in the uricase activity of the cells and a concomitant rapid decrease of urate in the medium were observed. The purine bases added to the media were incorporated into the cells at a relatively early period of the culture and appeared to be converted into urate within the cells. The repression of uricase formation in the cultured cells and the derepression by the addition of the purine bases were discussed.     

Conformations of flanking bases in HIV-1 RNA DIS kissing complexes studied by molecular dynamics

Explicit solvent molecular dynamics simulations (in total almost 800 ns including locally enhanced sampling runs) were applied with different ion conditions and with two force fields (AMBER and CHARMM) to characterize typical geometries adopted by the flanking bases in the RNA kissing-loop complexes. We focus on flanking base positions in multiple x-ray and NMR structures of HIV-1 DIS kissing complexes and kissing complex from the large ribosomal subunit of Haloarcula marismortui. An initial x-ray open conformation of bulged-out bases in HIV-1 DIS complexes, affected by crystal packing, tends to convert to a closed conformation formed by consecutive stretch of four stacked purine bases. This is in agreement with those recent crystals where the packing is essentially avoided. We also observed variants of the closed conformation with three stacked bases, while nonnegligible populations of stacked geometries with bulged-in bases were detected, too. The simulation results reconcile differences in positions of the flanking bases observed in x-ray and NMR studies. Our results suggest that bulged-out geometries are somewhat more preferred, which is in accord with recent experiments showing that they may mediate tertiary contacts in biomolecular assemblies or allow binding of aminoglycoside antibiotics.     

Regulation of purine utilization in bacteria. VII. Involvement of membrane-associated nucleoside phosphorylase in the uptake and the base-mediated loss of the ribose moiety of nucleosides by Salmonella typhimurium membrane vesicles.

Although uridine and adenosine are converted by membrane-associated nucleoside phosphorylases to ribose-1-phosphate (ribose-1-P) and the corresponding bases (uracil and adenine), only ribose -1-P is accumulated within Salmonella typhimurium LT2 membrane vesicles. In accordance with these observations, no uptake is observed when the vesicles are incubated with the bases or nucleosides labeled in their base moieties. The vesicles lack a transport system for ribos-1-P, since excess ribose-1-P does not inhibit the uptake of the ribose moiety of uridine. In addition, there is no exchange with preaccumulatedribose-1-P. Thus, uridine, rather than ribose-1-P, must serve as the initially transported substrate. The uptake of the ribose portion of uridine is coupled to electron transport, and the levels to which ribose-1-P are accumulated may be reduced by adding various bases to the reaction mixtures. The bases appear to inhibit the uridine phosphorylase reaction and/or cause an efflux of ribose-1-P from the vesicles. This loss of ribose-1-P reflects the accumulation of nucleosides in the external medium after being synthesized within the membranes. Synthesis of the nucleosides from intravesicular ribose-1-P and exogenous base proceeds even though the bases are not accumulated by the vesicles. Furthermore, ribose-1-P cannot significantly inhibit uridine phosphorylase activity unless the membranes are disrupted. These observations indicate that the membrane-associated nucleoside phosphorylases may have a transmembranal orientation with their base and ribose-1-P binding sites on opposite sides of the membranes. Such an asymmetric arrangement of these enzymes may facilitate the uptake of the ribosyl moiety of nucleosides by a group translocation mechanism. Thus, nucleosides may be cleaved during the membrane transport process, with the resultant bases delivered to the external environment while ribose-1-P is shunted to the intravesicular space.     

Quantitative determination of 5-methylcytosine in DNA by reverse-phase high-performance liquid chromatography

A method to separate the four major bases (cytosine, guanine, thymine and adenine) and the two minor modified bases (5-methylcytosine and 6N-methyladenine) in DNA has been developed. For optimal separation, several different buffer systems are available for isocratic elution. The 12 5-methylcytosine (5-mC) residues in the plasmid pBR322 can be determined with a deviation of less than 3% of the expected value and have been used for internal standardization. Formic acid hydrolysis of bases and probably of DNA does not lead to the deamination of cytosine or 5-mC and thus can be used routinely for DNA hydrolysis. Adenovirus or baculovirus DNA does not contain detectable amounts of 5-mC. The distribution of 5-mC in hamster cell DNA appears to be nonrandom in that different 5'-CpG-3'-containing restriction sites are methylated to different extents.     

Conformational changes induced in DNA by the in vitro reaction with the mutagenic amine: 3-N,N-acetoxyacetylamino-4,6-dimethyldipyrido (1,2-a: 3', 2'-d) imidazole.

The conformation of synthetic or natural DNAs modified in vitro by covalent binding of N-AcO-A-Glu-P-3 was investigated by fluorescence and circular dichroism. In all cases, substitution occurs mainly on the C8 of guanine residues. In modified poly(dG-dC).poly(dG-dC) or poly(dA-dC).poly(dG-dT) in B conformation, A-Glu-P-3 residues interact strongly with the bases whereas in Z conformation these residues are largely exposed to the solvent and interact weakly with the bases. A-Glu-P-3 and N-acetyl-2-aminofluorene (AAF) residues are equally efficient to induce the B-Z transition of poly(dG-dC).poly(dG-dC) and of poly(dA-dC).poly(dG-dT). Modifications of poly(dG).poly(dC) and calf thymus DNA indicate strong interactions between A-Glu-P-3 and the bases.