Carbodiimide modification of superhelical PM2 DNA: considerations regarding reaction at unpaired bases and the unwinding of superhelical DNA with chemical probes

Mass spectrometry of the fifth nucleoside: a review of the identification of pseudouridine in nucleic acids

Pseudouridine, the so-called fifth nucleoside due to its ubiquitous presence in ribonucleic acids (RNAs), remains among the most challenging modified nucleosides to characterize. As an isomer of the major nucleoside uridine, pseudouridine cannot be detected by standard reverse-transcriptase-based DNA sequencing or RNase mapping approaches. Thus, over the past 15 years, investigators have focused on the unique structural properties of pseudouridine to develop selective derivatization or fragmentation strategies for its determination. While the N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide p-tosylate (CMCT)-reverse transcriptase assay remains both a popular and powerful approach to screen for pseudouridine in larger RNAs, mass-spectrometry-based approaches are poised to play an increasingly important role in either confirming the findings of the CMCT-reverse transcriptase assay or in characterizing pseudouridine sequence placement and abundance in smaller RNAs. This review includes a brief discussion of pseudouridine including a summary of its biosynthesis and known importance within various RNAs. The review then focuses on chemical derivatization approaches that can be used to selectively modify pseudouridine to improve its detection, and the development of mass-spectrometry-based assays for the identification and sequencing of pseudouridine in various RNAs.

Improving CMC-derivatization of pseudouridine in RNA for mass spectrometric detection

A protocol that utilizes matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) and N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide (CMC) derivatization to detect the post-transcriptionally modified nucleoside, pseudouridine, in RNA has been optimized for RNase digests. Because pseudouridine is mass-silent (i.e., the mass of pseudouridine is the same as the mass of uridine), after CMC-derivatization and alkaline treatment, all pseudouridine residues exhibit a mass shift of 252 Da that allows its presence to be easily detected by mass spectrometry. This protocol is illustrated by the direct MALDI-MS identification of pseudouridines within Escherichia coli tRNA(TyrII) starting from microgram amounts of sample. During this optimization study, it was discovered that the post-transcriptionally modified nucleoside 2-methylthio-N(6)-isopentenyladenosine, which is present in bacterial tRNAs, also retains a CMC unit after derivatization and incubation with base. Thus, care must be exercised when applying this MALDI-based CMC-derivatization approach for pseudouridine detection to samples containing transfer RNAs to minimize the misidentification of pseudouridine.

Quantitative analysis of carbodiimide modified DNA and immunoprobing by adduct specific antibodies

Antibodies have been raised against N-cyclohexyl-N-(4-methylmorpholinium)ethyl carbodiimide (CMC) modified single-stranded DNA and characterized by competitive and non-competitive immunoassays to be highly specific for CMC base adduct in homopolymers poly(dG), poly(dT) and DNA. The antibodies recognize picogram concentrations of CMC treated DNA with no cross reactivity to at least 1000-fold excess of unmodified DNA or CMC treated poly(dA). The detection limit of antibodies at 1.4 fmol CMC adduct allows quantitation at a CMC/base ratio of 4.6.10(-7). Based upon single modified base-containing synthetic oligomers, a 7-fold higher binding preference is observed for CMC modified thymine than guanine bases. CMC binding to supercoiled DNA is found to depend upon reaction temperature and ionic strength. CMC-modified supercoiled SV40 and ColE1 DNA, exhibit specific antibody binding proportional to the DNA concentration and extent of CMC modification. However, antibody binding observed is independent of the conformation or strandedness of CMC-modified DNA. DNA extensively modified with CMC retains its inherent capacity to specifically and quantitatively hybridize with complementary DNA immobilized to membranes upon direct blotting or Southern transfers from gels. Hybridized CMC-DNA, through antibody binding, provides for the sensitive and non-isotopic detection of the target DNA sequences.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Base-specific binding of adenosine antibodies to double-stranded DNA

Antibodies raised against adenosine have been reported to react with single-stranded DNA but not with double-stranded DNA. Using a highly sensitive avidin-biotin microELISA we report that these antibodies also react with double-stranded DNA. The binding was specific as it was completely inhibited by the homologous hapten. The results indicate that the antibody populations binding to ssDNA and dsDNA are not cross-reactive. The antibodies were shown to react with the topoisomers of plasmid DNA as assessed by gel retardation assay. The antibodies showed differential binding to restriction fragments of DNA indicating that some of the A residues in dsDNA are accessible to the antibodies.

Immunoassays for carbodiimide modified DNA-detection of unpairing transitions in supercoiled ColE1 DNA

The water soluble reagent N-cyclohexyl-N'-beta-(4-methylmorpholinium) ethyl carbodiimide-p-toluene sulphonate (CMC) can be used to probe for unpaired and mismatched sites in DNA. Polyclonal antibodies for CMC modified DNA were produced in order to develop immunological assays for the localization and quantitation of CMC adducts. Immunoslot blot analysis of modified DNA exhibited antibody binding proportional to the extent of CMC modification with adduct detection in the femtamole range. Unmodified DNA did not cross react under the conditions of the assay. The distribution of CMC reactivity for supercoiled ColE1 DNA modified at 100, 200 and 300 mM NaCl was determined by immunoanalysis of EcoRI-Hae2-NruI restriction fragments Southern transferred to nylon membranes. Reactivity above random expectation occurred in the A2-II fragment which can be accounted for by its high A-T content of 71.3%. Reactivity below random expectation occurred in the C fragment which can be accounted for by its low AT content of 43%. CMC modification for the other restriction fragments appeared random.

Antibodies raised against denatured DNA bind to double-stranded DNA

Antibodies raised against denatured DNA complexed with methylated bovine serum albumin have been reported to react with ssDNA but not with dsDNA. Using a highly sensitive avidin-biotin microELISA, we report that such antibodies also bind to dsDNA. Antibodies which reacted with ssDNA and dsDNA were found to be of IgG type. The antibodies did not react with tRNA and rRNA. The binding of antibodies to dsDNA was partially inhibited by individual deoxyribonucleotides. ssDNA as well as dsDNA inhibited the binding of antibodies to dsDNA. The binding of these antibodies to supercoiled and relaxed forms of pBR322 DNA was demonstrated by gel retardation assay. The cross-reaction with ssDNA was observed even after affinity purification on native DNA-cellulose. The antibodies were also shown to bind to poly(dA-dT).poly(dA-dT).

The influence of tertiary structural restraints on conformational transitions in superhelical DNA

This paper examines theoretically the effects that restraints on the tertiary structure of a superhelical DNA domain exert on the energetics of linking and the onset of conformational transitions. The most important tertiary constraint arises from the nucleosomal winding of genomic DNA in vivo. Conformational transitions are shown to occur at equilibrium at less extreme superhelicities in DNA whose tertiary structure is restrained than in unrestrained molecules where the residual linking difference alpha res (that part of the superhelical deformation which is not absorbed by transitions) may be freely partitioned between twisting and bending. In the extreme case of a rigidly held tertiary structure, this analysis predicts that the B-Z transition will occur at roughly half the superhelix density needed to drive the same transition in solution, other factors remaining fixed. This suggests that superhelical transitions may occur at more moderate superhelical deformations in vivo than in solution. The influence on transition behavior of the tertiary structural restraints imposed by gel conditions also are discussed.

Detection of single base-pair mismatches in DNA by chemical modification followed by electrophoresis in 15% polyacrylamide gel

We have developed a method for distinguishing fragments of DNA that contain single-base mismatches from their perfectly paired homologues. Single-stranded regions within a duplex fragment are accessible to 1-cyclohexyl-3-(2-[4-(4-methyl)morpholinyl]ethyl)carbodiimide, which reacts with unpaired guanidylate and thymidylate residues in DNA. Intact linear duplex DNA molecules do not react with carbodiimide, whereas DNA molecules containing single-base mismatches react quantitatively. After carbodiimide reaction, the DNA molecules are electrophoresed in high-percentage polyacrylamide gels so that modified and unmodified fragments can be resolved. Application of this technique should make it possible to locate and purify DNA fragments that exhibit sequence differences from those that do not; these might be used to signal phenotypic variation as well as to diagnose inherited disease.

Modulation of gene expression in Escherichia coli infected with single-stranded bacteriophage phi X174

Synthesis of tryptophanase, D-serine deaminase and alkaline phosphatase in Escherichia coli C was repressed as the result of infection with the single-stranded DNA bacteriophage phi X174. However, the degree of repression differed, the more catabolite-sensitive the operon was, the more severe was the repression. For the catabolite-sensitive enzymes it was found that cyclic adenosine 3'5' monophosphate (cyclic AMP or cAMP) was unable to release or reduce the phage-induced inhibition. Experiments with amber mutants of phi X174 revealed that A, product of cistron A, was responsible for the inhibition. The cistron A product probably acted at the level of transcription. The possible role of A in the observed modulation of gene expression is discussed.

Aspects of the secondary and tertiary structure of DNA

DNA is the primary genetic material of most organisms. A wide variety of naturally occurring duplex DNA's are known to exist as covalently closed circles. This covalent continuity introduces a topological constraint, and consequently these molecules possess aspects of tertiary and even higher-order structure. Virtually every physical, chemical and biological property of DNA - its transcription, hydrodynamic behaviour, energetics, enzymology and so on - are related to these structural features. We describe the parameters describing the topology and conformation of covalently-closed, duplex DNA's (form I DNA's), the conservation relationship between them and its implications.

Structural perturbation in supercoiled DNA: hypersensitivity to modification by a single-strand-selective chemical reagent conferred by inverted repeat sequences

Bromoacetaldehyde, a reagent which modifies unpaired adenine residues, selectively modifies supercoiled DNA in the region of inverted repeats which are known targets for single-strand-specific nucleases. The reaction is dependent upon the topological state of the molecule, and the absolute importance of the inverted repeat has been demonstrated. Finer mapping of the distribution of the modification pattern reveals significant and interesting differences from the S1 nuclease target positions. Bromoacetaldehyde modification is distributed over a wider region covering the whole inverted repeat, with greatest extent of reaction in the regions which flank the inverted repeat. It is suggested that an altered conformation may be propagated into these sequences. These results further support the contention that inverted repeats adopt an altered conformation when negatively supercoiled, for which the principal suggestion remains the cruciform structure.

Effect of bacteriophage phi X174 infection on the conformation of Escherichia coli DNA

The cistron A proteins of bacteriophage phi X174 inhibit the synthesis of beta-galactosidase of host Escherichia coli. A drastic reduction in the rate of transcription of the lac gene is observed in infected cells. This loss in the efficiency of transcription is due to conformational changes in the host DNA. Probably the host DNA is nicked at a few sites along its length and some of its negative superhelical twists are released.

Determination of the number of superhelical turns by the hyperchromicity of partially denatured covalently-closed DNA molecules

A novel method of determining the number of superhelical turns of a covalently-closed plasmid DNA is described. It relies on the determination of the hyperchromicity, and hence the proportion of unstacked basepairs, of a partially heat-denatured sample which co-migrates during electrophoresis with nicked circular duplex DNA. The values obtained for plasmid pBR beta G DNA at 4 degrees C (-29.8 and -33.5 in the two buffers used) agree closely with the values obtained in parallel by topoisomer band-counting. Our method is less precise than band-counting but is readily applicable to determining the superhelicity of very large DNA molecules. Our results confirm earlier findings that magnesium-containing buffers cause an increase in the duplex winding angle, and hence an increase in the number of negative superhelical turns.

Electrophoretic mobility of PM2 DNA treated with ultimate chemical carcinogens or with ultraviolet light

Superhelical DNA of the Pseudomonas phage PM2 was irradiated with UV-light or reacted with covalently binding carcinogens, such as 7-bromomethyl-benz[a]anthracene, (Ac)2ONFln, K-region epoxides, and alkylating agents. Migration velocity of the DNA products was determined using agarose gel electrophoresis. In gels of more than 1.3%-1.9% agarose, modified PM2 DNA exhibited a dose-(concentration-)dependent decrease of migration velocity. This phenomenon is probably due to a decrease in superhelix density which caused the compact DNA coil to assume eventually an open-circular conformation. Comparison of the extent of DNA modification with the decrease of migration velocity revealed that the superhelical structure sensitively reflected the chemical DNA alterations. DNA species exhibiting, in 1.6% agarose gels, a migration velocity of up to 30% of that of control DNA showed an increase of velocity in 0.4% agarose. Therefore, in 1.3%-1.9% agarose gels, the decrease os superhelix density is accompanied by an increase of the frictional coefficient, whereas in 0.4%-0.9% agarose gels the same decrease of superhelix density apparently led to a higher degree of flexibility of the macromolecule and/or exposure of additional electric charges.

Conformational transitions in closed circular DNA molecules. I. Topological and energetical considerations

A theory of conformational transitions in closed circular DNA as a function of topological linking number of the molecule (alpha) is elaborated taking into account topological and energetical considerations. The theory predicts a step-like dependence of a number of superhelical turns in DNA molecules (tau) on delta alpha. Thus, the number of superhelical turns tau = delta alpha for small values of delta alpha. For a large delta alpha (when conformational begin to occur) tau = delta alpha - sigma phi ij, where sigma phi ij is the total angle of conformational transitions for a given delta alpha. This prediction is in good agreement with published data on the dependence of the sedimentation coefficient of circular DNA molecules on their topological linking number. The results also allow to explain the disagreement between a number of titratable superhelical turns in circular DNA molecules and a number of supercoiles seen on electron micrographs for molecules with sufficiently large delta alpha.

DNA gyrase stimulates transcription

The nuclear DNA of HeLa cells can now be isolated unbroken and supercoiled. Using DNA gyrase and the untwisting enzyme, we have prepared an allomorphic series of templates derived from this nuclear DNA, and also from the circular DNA of the bacterial virus, PM2. We have then transcribed these templates using 2 different RNA polymerases--from wheat germ and Escherichia coli. Relaxed DNA is transcribed slowly by both polymerases. Supertwisting the naturally-supercoiled templates with gyrase slightly inhibits transcription by the bacterial polymerase but stimulates dramatically transcription by RNA polymerase II from wheat germ.

Ethidium bromide-mediated renaturation of denatured closed circular DNAs. The nature of denaturation-resistant fractions of bacteriophage PM2 closed circular DNA

Addition of the intercalating dye ethidium bromide (EtdBr) to a solution of alkali-denatured double-stranded closed circular PM2, PhiX174, or lambdab(2)b(5)c phage DNAs, under conditions such that the solution remains strongly alkaline, can result in the renaturation of up to 100% of the DNA upon neutralization of the solution. For a fixed time of incubation of the alkaline dye-containing solution before neutralization, there exists a minimum concentration of the dye below which no EtdBr-mediated renaturation is observed for each species of closed circular DNA examined. These minimum concentrations increase, for a given DNA, with increasing ionic strength and temperature. The kinetics of accumulation of forms renaturing upon neutralization of alkaline solutions, at fixed concentrations of dye and DNA, are dependent upon the molecular weight and superhelix density of the starting DNA. After extended periods of incubation at a fixed ionic strength and temperature, however, the profiles of percentage of DNA renatured as a function of ethidium concentration become very similar for all the closed circular DNAs tested and display a transition from an absence of dye-mediated renaturation to virtually 100% renaturation upon neutralization over a small range of dye concentration. Circular DNA containing one or more strand scissions remains strand-separated under all the conditions used to effect the renaturation of closed circular DNA. These findings indicate that configurations of closed circular DNA, in which at least some of the complementary bases are apposed, can be selectively stabilized and accumulate in the presence of ethidium in solutions containing 0.19 N hydroxide ion. The closed circular DNA of bacteriophage PM2 has properties distinct from those of the other DNAs of this study in that it has been shown to contain fractions which exist in the base-paired duplex form after neutralization of strongly alkaline solutions of this DNA incubated at ambient temperature, while no duplex DNA is observed after exposure to alkali and neutralization of solutions of closed circular DNA from other sources. (1,2) The fraction of denaturation-resistant PM2 DNA is shown in the present work to depend upon the temperature and time of incubation in alkali, but not upon the superhelix density of the starting DNA. PM2 closed circular DNA also behaves anomalously with respect to its kinetics of accumulation of forms renaturing upon neutralization of alkaline, EtdBr-containing solutions. Evidence is presented that the translocation of one of the strands of a closed circular molecule relative to the other, which is required for the molecule to exist in the denatured form at neutral pH, is a process to which PM2 DNA is less labile than the other closed circular DNAs of this study.

Cloning of bacteriophage PM2 DNA in Escherichia coli K12

DNA fragments of phage PM2 restricted with Hin dIII endonuclease was cloned in the vector pBR 322 in an Escherichia coli K12 host. The attempt to clone full length PM2 DNA restricted with PstI endonuclease has been unsuccesful. From six randomly chosen recombinant clones DNA was purified and analysed with EcoRI, PstI and Hin dIII endonucleases. The physical map of three chimeric plasmids was unequivocally established. It was shown, that the whole PM2 genome was cloned, although in separate fragments. However, most of the recombinant clones were instable in the absence of selective pressure.

Fluctuations in superhelical DNA

The effect of superhelicity on the base-pair opening probability and on the probability of occurrence of cruciform states in palindromic regions is theoretically treated. The calculations show that below the superhelix density value of -sigma=0.05 superhelicity does not appreciably affect the characteristics of DNA secondary structure fluctuations. In the range of physiological superhelix densities sigma (-sigma=0.05-0.09) the base-pair opening probability markedly increases. However, within this range of sigma the base-pairs are opened only transiently and permanently open regions are not formed. Permanently opened regions appear at higher negative superhelix densities (-sigma greater than 0.10). At the values of -sigma higher than 0.06 a cruciform structure in the palindromic region centred in position 3965 proves to be the most probable fluctuational disturbance in the 0x174 duplex DNA. Different experimental approaches used for probing the fluctuations in superhelical DNA have been analysed. The results suggest that most direct quantitative information can be derived from data on the nicking of closed DNA by single strand-specific endonucleases. Such data (Wang, 1974) accord with the results of theoretical calculations. Calculations show that, due to base-pair opening, the total free energy of superhelical DNA should depend parabolically on sigma only up to some critical value of sigma=sigmac. If negative superhelicity exceeds this critical value, which under physiological conditions proves to be -sigma=0.085, the free energy should increase linearly with -sigma. The biological role of supercoiling is discussed in the light of obtained results.

Extracellular nucleases of Alteromonas espejiana BAL 31.IV. The single strand-specific deoxyriboendonuclease activity as a probe for regions of altered secondary structure in negatively and positively supercoiled closed circular DNA

The dependence of the initial rate of introduction of the first single-chain scission (initial nicking rate) into covalently closed circular phage PM2 DNA by the single strand-specific nuclease from Alteromonas espejiana BAL 31 upon the superhelix density (sigma) of the DNA has been examined. The initial nicking rate decreases with decreasing numbers of negative superhelical turns (decreasing values of -sigma), which behavior is characteristic of other single strand-specific nucleases as reported earlier. In contrast to earlier work, the initial nicking rates of closed circular DNAs by the action of the Alteromonas nuclease have been shown to be readily measurable at values of -sigma as low as 0.02. However, even at the elevated concentrations of enzyme and extended digestion periods required to cause nicking at an appreciable rate at near-zero values of sigma, closed circular DNA containing very few superhelical turns (form IO DNA) is not cleaved at a detectable rate. When this DNA is rendered positively supercoiled by ethidium bromide (EtdBr), it is not affected by the nuclease until very high positive values of sigma are attained, at which low rates of cleavage can be detected at elevated enzyme concentrations. The effects of EtdBr on the enzyme activity have been tested and are entirely insufficient to allow the interpretation of zero nicking rates as the result of inhibition of the nuclease activity by the dye. Positively supercoiled DNA is concluded not to contain regions having significant single-stranded character until values of sigma are reached which are very much higher than the values of -sigma for which negatively supercoiled DNAs behave as if they contain unpaired or weakly paired bases.

Effect of chemical modification of supercoiled simian virus 40 DNA on the rate of in vitro transcription

Superhelical simian virus 40 FI DNA could be modified with the single-strand-specific reagent N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide (CMC). A limited reaction, of less than 2% of the base pairs, resulted in almost total inhibition of in vitro transcription by DNA-dependent RNA polymerase from Escherichia coli. This effect was shown to be due to DNA modification and not to inhibition of polymerase activity by the reagent. Inhibition of enzyme activity occurred if the contaminating reagent was not absorbed with another protein before polymerase addition. No inhibition was observed when DNA and polymerase were incubated together to allow the formation of pre-initiation complexes before CMC was added. Studies of template saturation with polymerase showed that the inhibition of transcription by DNA modification was due to a loss of binding ability of the enzyme to the reacted, supercoiled DNA when reaction times of less than 2 h were used.