Inhibition of eucaryotic DNA polymerases by phosphonoacetate and phosphonoformate

Phosphonoacetate was found to be an inhibitor of the DNA polymerase α from three human cells, HeLa, Wi-38, and phytohemagglutinin-stimulated lymphocytes. The inhibition patterns were determined. The apparent inhibition constants (K_ii) were about 30 μm. Thus the DNA polymerase α is 15 to 30 times less sensitive to Phosphonoacetate than the herpesvirus-induced DNA polymerase. The DNA polymerase α from Chinese hamster ovary cells and calf thymus was also inhibited. The DNA polymerases β and γ from the eucaryotic cells were relatively insensitive to phosphonoacetate. The sensitivity of the DNA polymerase α and the relative insensitivity of the DNA polymerase β and γ appeared to be general characteristics of the vertebrate polymerases, DNA polymerases from two other eucaryotic cells, yeast DNA polymerase A and B and tobacco cell DNA polymerase, were inhibited by phosphonoacetate, and to about the same extent as the α-polymerases. Fourteen phosphonate analogs were examined for inhibition of the HeLa DNA polymerase α. Only one, phosphonoformate, was an inhibitor. The mechanism of inhibition for phosphonoformate was analogous to that for phosphonoacetate.     

DNA binding properties of DAPI (4',6-diamidino-2-phenylindole) analogs having an imidazoline ring or a tetrahydropyrimidine ring: groove-binding and intercalation.

DAPI analogs containing an imidazoline ring or a tetrahydropyrimidine ring have been synthesized to study DNA binding properties. Spectroscopic (absorption, CD, flow dichroism and fluorescence) and viscosity measurements indicate that DAPI analogs interact with DNA both by intercalation and by groove binding. The solution structures of complexes between DAPI analog and DNA oligomers have been characterized by proton NMR spectroscopy.     

The thermodynamic advantage of DNA oligonucleotide 'stacking hybridization' reactions: energetics of a DNA nick.

'Stacking hybridization reactions' wherein two or more short DNA oligomers hybridize in a contiguous tandem orientation onto a longer complementary DNA single strand have been employed to enhance a variety of analytical oligonucleotide hybridization schemes. If the short oligomers anneal in perfect head-to-tail register the resulting duplex contains a nick at every boundary between hybridized oligomers. Alternatively, if the short oligomers do not hybridize precisely in register, i.e. single strand regions on the longer strand are left unbound, gaps are formed between regions where short oligomers bind. The resulting gapped DNA duplexes are considerably less stable than their nicked duplex analogs. Formation of base pair stacking interactions between neighboring oligomers at the nicks that do not occur in gapped duplexes has been proposed as the source of the observed added stability. However, quantitative evidence supporting this hypothesis for DNA has not been reported. Until now, a direct comparison of the thermodynamics of DNA nicks versus DNA gaps has not been performed. In this communication we report such a comparison. Analysis of optical melting experiments in a well defined molecular context enabled quantitative evaluations of the relative thermodynamic difference between nicked and gapped DNA duplexes. Results of the analysis reveal that a nick may be energetically favored over a gap by at least 1.4 kcal/mol and perhaps as much as 2.4 kcal/mol. The presence of a 5'phosphate at a nick or gap fails to significantly affect their stabilities.     

Synthesis of Chiral Heteronucleotide ONA Sequences by a Fmoc/Boc-Based Submonomeric Strategy

Peptide nucleic acid (PNA) is a DNA analog able to form hybridization complexes with complementary DNA or RNA strands. Many PNAs have been described in recent years, particularly chiral PNA analogs. Chiral heteronucleotide ONA (Orn backbone PNA) is an important tool in the antisensing field, but was not been fully explored yet. In the present work, we performed studies toward the synthesis of chiral heteronucleotide ONA sequences by utilizing a Fmoc/Boc-based submonomer approach on solid support. The desired oligomers with different nucleic content and length were obtained in very good yields and high purity. Specific binding to the complimentary ssDNA oligomers was demonstrated.     

Achiral Nucleotide Analogs: 5,5-Disubstituted Pyrimidines Related to Barbituric Acid

Abstract

Achiral nucleotide analogs are of potential interest in origin of life studies. Four new 5,5-diphosphoethylpyrimidine analogs were prepared by condensation of urea or guanidine with a, a-di(2-[ethoxy-I-ethoxy]ethyl)malononitrile or a, a-di(2-[ethoxy-1-ethoxy]ethyl)ethyl cyanoacetate respectively, followed by removal of the protecting groups and bisphosphorylation. Oligomers of two potentially complementary analogs have been prepared. Interactions between these oligomers appear to be weak in aqueous solution.     

Interactions of oligonucleotide analogs containing methylphosphonate internucleotide linkages and 2'-O-methylribonucleosides.

The interactions of oligonucleotide analogs, 12-mers, which contain deoxyribo- or 2'-O-methylribose sugars and methylphosphonate internucleotide linkages with complementary 12-mer DNA and RNA targets and the effect of chirality of the methylphosphonate linkage on oligomer-target interactions was studied. Oligomers containing a single Rp or Sp methylphosphonate linkage (type 1) or oligomers containing a single phosphodiester linkage at the 5'-end followed by 10 contiguous methylphosphonate linkages of random chirality (type 2) were prepared. The deoxyribo- and 2'-O-methylribo- type 1 12-mers formed stable duplexes with both the RNA and DNA as determined by UV melting experiments. The melting temperatures, Tms, of the 2'-O-methylribo-12-mer/RNA duplexes (49-53 degrees C) were higher than those of the deoxyribo-12mer/RNA duplexes (31-36 degrees C). The Tms of the duplexes formed by the Rp isomers of these oligomers were approximately 3-5 degrees C higher than those formed by the corresponding Sp isomers. The deoxyribo type 2 12-mer formed a stable duplex, Tm 34 degrees C, with the DNA target and a much less stable duplex with the RNA target, Tm < 5 degrees C. In contrast, the 2'-O-methylribo type 2 12-mer formed a stable duplex with the RNA target, Tm 20 degrees C, and a duplex of lower stability with the DNA target, Tm < 5 degrees C. These results show that the previously observed greater stability of oligo-2'-O-methylribonucleotide/RNA duplexes versus oligodeoxyribonucleotide/RNA duplexes extends to oligomers containing methylphosphonate linkages and that the configuration of the methylphosphonate linkage strongly influences the stability of the duplexes.     

DNA computing

Biocomputers can be an alternative for traditional "silicon-based" computers, which continuous development may be limited due to further miniaturization (imposed by the Heisenberg Uncertainty Principle) and increasing the amount of information between the central processing unit and the main memory (von Neuman bottleneck). The idea of DNA computing came true for the first time in 1994, when Adleman solved the Hamiltonian Path Problem using short DNA oligomers and DNA ligase. In the early 2000s a series of biocomputer models was presented with a seminal work of Shapiro and his colleguas who presented molecular 2 state finite automaton, in which the restriction enzyme, FokI, constituted hardware and short DNA oligomers were software as well as input/output signals. DNA molecules provided also energy for this machine. DNA computing can be exploited in many applications, from study on the gene expression pattern to diagnosis and therapy of cancer. The idea of DNA computing is still in progress in research both in vitro and in vivo and at least promising results of these research allow to have a hope for a breakthrough in the computer science.     

Aldehyde Functions in Synthetic Oligonucleotides

Abstract

new nucleoside analogs with a masked aldehyde function have been synthesized and incorporated in oligodeoxyribonucléotides. After unmasking the aldehyde function, the oligomers were easily coupled to biotin derivatives by reductive amination. Reversed phase HPLC proved to be an unvaluable tool to characterize and purify these conjugates.     

Concentration and Extinction Coefficient Determination for Oligonucleotides and Analogs Using a General Phosphate Analysis

A general phosphate analysis (GPA) is developed which assays the concentration of nucleic acid oligomers and their analogs based on stoichiometric phosphorus in the sequence. The method involves complete digestion of the oligomer sample to orthophosphate using acid at high temperature and subsequent colorimetric analysis by phosphomolybdate complex formation. GPA is applied to oligomers having phosphodiester, methylphosphonate, and phosphorothioate backbone linkages. Given the absorption spectra of oligomers having these backbones, extinction coefficients are obtained and compared to other quantitative and predictive methods. In addition to sequences having the usual nucleoside residues found in naturally occurring nucleic acids, oligomers having base analog residues can be readily quantified by GPA.     

A new synthetic protocol for labeled oligonucleotides, using a chemically cleavable universal linker

A two-step general method for labeling of synthetic oligonucleotides is described. The protocol employs a cleavable universal linker, 5'-O-(4,4'-dimethoxytrityl)-3'-O-benzoyl-2'-O-(2-cyanoethyl-N,N-diisopropyl)-uridine phosphoramidite, to effect coupling to polymer-bound oligonucleotide chains. Sequentially, coupling with commercially available phosphoramidite reagent of an appropriate label (Biotin, HEX etc.) in an automated DNA synthesizer is carried out. The labeled oligomers, obtained after cleavage and deprotection reactions, are analyzed on RP-HPLC. A distinctive feature of this protocol is the recovery of free oligomers from their labeled analogs under mild conditions. The oligomers obtained are comparable to the corresponding standard oligonucleotides (HPLC).     

Petite induction in Saccharomyces cerevisiae by ethidium analogs. Action on mitochondrial genome

Petite induction of ethidium analogs was examined in both resting and growing yeast cells. All of the analogs used in these experiments were active in dividing cells of Saccharomyces cerevisiae; only the parent ethidium bromide was mutagenic under resting conditions. Incorporation of adenine into mitochondrial DNA appeared to be prevented completely by ethidium and partially inhibited by other analogs. Treatment of growing cells with analogs affected fragmentation of pre-existing DNA as seen by the loss of a mitochondrial antibiotic resistance marker. The rates of elimination of the marker were different; ethidium generated greater loss than the monoamino analogs (3-amino and 8-amino-); and the deaminated analog was least effective. However, in resting yeast the marker was partially eliminated only with treatment of the parent ethidium. The degradation of the mitochondrial DNA by exposure to ethidium compounds was confirmed by agarose gel electrophoresis. Electrophoretic patterns of the mitochondrial DNA treated with each of the analogs under growing conditions and only with ethidium under resting conditions showed degradation of the mitochondrial DNA.     

A Raman spectroscopic study on the sequence dependent conformations of DNA oligomers

Eighteen kinds of oligodeoxyribonucleic acids have been examined to reveal their structures in aqueous solutions at different ionic strengths by Raman spectroscopy. The structures in solutions were found to be very polymorphic depending on their sequences as well as on the salt concentrations. At a low salt condition a DNA oligomer assumes a unique B form within a B family, for examples Ba, Bh, B', or Bn form. Amongst these DNA oligomers, d(CGCG)2 showed a salt induced Ba-Z transition, while d(GGGGCCCC)2 showed a salt induced Bh-A transition. DNA oligomers with AA/TT sequences were found to prefer B' form even at high salt condition. From comparing the structures of DNA oligomers in solutions with their crystal structures, it is safe to say that the crystal structure of a DNA oligomer is very similar to the structure in the high salt solution.     

Differential inhibition of human placental DNA polymerases delta and alpha by BuPdGTP and BuAdATP.

The p-n-butylphenyl- and p-n-butylanilino- substituted analogs of dGTP and dATP, respectively, were tested as inhibitors of purified human placental DNA polymerases alpha and delta. It was observed that DNA polymerase alpha activity was potently inhibited by these analogs with I0.5 values as low as the nanomolar range, whereas DNA polymerase delta activity was poorly inhibited, with I0.5 values of ca. 100 micromolar. These results argue for a distinct identity of these two enzymes, and demonstrate the usefulness of these analogs as probes of DNA polymerase structures. In addition, these analogs provide a rapid method for the discrimination of the two enzyme activities and a means for the selective assay of DNA polymerase delta. Aphidicolin inhibited both DNA polymerases.     

Incorporation of nucleoside analogs into nuclear or mitochondrial DNA is determined by the intracellular phosphorylation site

Nucleoside analogs used in cancer chemotherapy and in treatment of virus infections are phosphorylated in cells by nucleoside and nucleotide kinases to their pharmacologically active form. The phosphorylated nucleoside analogs are incorporated into DNA and cause cell death or inhibit viral replication. Cellular DNA is replicated both in the nucleus and in the mitochondria, and nucleoside analogs may interfere with DNA replication in both these subcellular locations. In the present study we created a cell model system where nucleoside analogs were phosphorylated, and thereby pharmacologically activated, in either the nucleus, cytosol, or mitochondria of cancer cells. The system was based on the reconstitution of deoxycytidine kinase (dCK)-deficient Chinese hamster ovary cells with genetically engineered dCK targeted to the different subcellular compartments. The nucleoside analogs phosphorylated by dCK in the mitochondria were predominantly incorporated into mitochondrial DNA, whereas the nucleoside analogs phosphorylated in the nucleus or cytosol were incorporated into nuclear DNA. We further show that the nucleoside analogs phosphorylated in the mitochondria induced cell death by an apoptotic program. These data showed that the subcellular site of nucleoside analog phosphorylation is an important determinant for incorporation of nucleoside analogs into nuclear or mitochondrial DNA.     

DNA primase-DNA polymerase alpha assembly from mouse FM3A cells. Purification of constituting enzymes, reconstitution, and analysis of RNA priming as coupled to DNA synthesis

The mouse DNA primase-DNA polymerase alpha complex can be resolved with buffer containing 50% ethylene glycol (Suzuki, M., Enomoto, T., Hanaoka, F., and Yamada, M. (1985) J. Biochem. (Tokyo) 98, 581-584). The dissociated primase and DNA polymerase alpha have been purified sufficiently that there was no cross-contamination with each other. By the use of thus isolated DNA primase and DNA polymerase alpha in addition to DNA primase-DNA polymerase alpha complex, we have studied primer RNA synthesis and DNA elongation separately as well as the coupled reaction of the initiation and elongation of DNA chains. In the absence of deoxyribonucleoside triphosphates, the isolated primase synthesized oligoribonucleotides of an apparent length of 7-11 nucleotides (monomeric oligomer) and multiples of a modal length of 9-10 nucleotides (multimeric oligomer) and fd phage single-stranded circular DNA. Monomeric and dimeric oligomers were synthesized processively, and trimeric and larger oligomers were produced by repeated cycles of processive synthesis. The primase complexed with DNA polymerase alpha mainly synthesized monomeric and a small amount of dimeric oligomers. In the presence of deoxyribonucleoside triphosphates at concentrations above 10 microM, the DNA primase-DNA polymerase alpha complex exclusively synthesized monomeric oligomers only, which were utilized as primers for DNA synthesis. On the other hand, the products synthesized by the isolated primase were qualitatively unchanged as compared with those synthesized in the absence of DNA precursors. When the synthesis of oligomers by the isolated primase was coupled with DNA elongation by the addition of the primase-free DNA polymerase alpha, the synthesis of dimeric oligomers was inhibited as a result of efficient DNA elongation from monomeric oligomers.     

Two sides of the coin: affinity and specificity of nucleic acid interactions

During the past decade, synthetic nucleobase oligomers have found wide use in biochemical sciences, biotechnology and molecular medicine, both as research and/or diagnostic tools and as therapeutics. Numerous applications of common and modified oligonucleotides and oligonucleotide mimics rely on their ability to sequence-specifically recognize nucleic acid targets (DNA or RNA) by forming duplexes or triplexes. In general, these applications would benefit significantly from enhanced binding affinities of nucleobase oligomers in the formation of various secondary structures. However, for high-affinity probes, the selectivity of sequence recognition must also be improved to avoid undesirable associations with mismatched DNA and RNA sites. Here, we review recent progress in understanding the molecular mechanisms of nucleic acid interactions and the development of new high-affinity plus high-specificity oligonucleotides and their mimics, with particular emphasis on peptide nucleic acids.     

Betaine structure and the presence of hydroxyl groups alters the effects on DNA melting temperatures

Betaine lowers the melting temperature of deoxyribonucleic acid (DNA) and decreases its dependence on base composition. The effects of synthetic betaine analogs on the melting of DNA samples with different GC content were measured. Since many polyhydroxy compounds also lower DNA melting temperatures, hydroxyl-substituted betaine analogs were included. Some synthetic sulfonate analogs of betaine lowered the DNA melting temperatures by twice as much at the same molar concentration. They were up to twice as effective at decreasing the base pair dependence. Some carboxylate homologs of betaine, substituted with hydroxyl groups, increased the melting temperature. This effect was greater with low GC content DNA. Sulfonate analogs of betaine with hydroxyl groups usually destabilize the DNA, while their carboxylate analogs stabilize the DNA. Distances between the charges of these synthetic zwitterionic solutes influence the effect on DNA, with the optimum separation being two or three methylene groups. A betaine with two hydroxyl groups on one N-alkyl group had a greater effect than an isomer with two hydroxyl groups on separate N-alkyl substituents. We suggest that the effect of these solutes depends on structuring the hydration water of DNA, as well as interactions with the DNA structure itself.     

Synthesis of S-adenosyl-L-methionine analogs and their use for sequence-specific transalkylation of DNA by methyltransferases

Here we describe a one-step synthetic procedure for the preparation of S-adenosyl-L-methionine (AdoMet) analogs with extended carbon chains replacing the methyl group. These AdoMet analogs function as efficient cofactors for DNA methyltransferases (MTases), and we provide a protocol for sequence-specific transfer of extended side chains from these AdoMet analogs to DNA by DNA MTases. Direct chemoselective allylation or propargylation of S-adenosyl-L-homocysteine (AdoHcy) at sulfur is achieved under the acidic conditions needed to protect other nucleophilic positions in AdoHcy. The unsaturated bonds in beta position to the sulfonium center of the resulting AdoMet analogs are designed to stabilize the transition state formed upon DNA MTase-catalyzed nucleophilic attack at the carbon next to the sulfonium center and lead to efficient transfer of the extended side chains to DNA. Using these protocols, sequence-specific functionalized DNA can be obtained within one to two weeks.     

Information transfer from DNA to peptide nucleic acids by template-directed syntheses.

Peptide nucleic acids (PNAs) are analogs of nucleic acids in which the ribose-phosphate backbone is replaced by a backbone held together by amide bonds. PNAs are interesting as models of alternative genetic systems because they form potentially informational base paired helical structures. Oligocytidylates have been shown to act as templates for formation of longer oligomers of G from PNA G2 dimers. In this paper we show that information can be transferred from DNA to PNA. DNA C4T2C4 is an efficient template for synthesis of PNA G4A2G4 using G2 and A2 units as substrates. The corresponding synthesis of PNA G4C2G4 on DNA C4G2C4 is less efficient. Incorporation of PNA T2 into PNA products on DNA C4A2C4 is the least efficient of the three reactions. These results, obtained using PNA dimers as substrates, parallel those obtained using monomeric activated nucleotides.