[G4-quadruplexes and genome instability].

A comparative analysis in silico of distribution of nucleotide sequences that predispose to formation of non-canonical DNA structure of G-quadruplexes, closely related with gene expression regulation and double strand DNA breaks, within vertebrata and yeast nuclear and mitochondrial genomes was carried out. Data on preferable localization of potential quadruplexes within non-coding sequences, their evolutionary conservation, and existing homology between them in mitochondrial and nuclear genomes were obtained. A possible interrelation between quadruplexes, Pif1 helicase and genomic instability is discussed.

Helicase-catalysed translocation and strand separation.

Helicases are molecular-motor enzymes that manipulate DNA or RNA during replication, repair, recombination, transcription, translation and processing of nucleic acids. The mechanisms for helicase activity have been studied intensely over the past decade. Recent advances in our understanding of the helicase mode of action have led to a general convergence of models that describe this diverse class of enzymes. One mechanism has been proposed that appears to have withstood the test of time, namely the inchworm mechanism. As the name implies, this mechanism involves a process whereby a helicase maintains at least two sites of contact with the nucleic acid. These binding sites can move relative to one another in a sequential fashion, resulting in net movement of the enzyme along the nucleic acid. The inchworm mechanism appears to be applicable to oligomeric states beyond the simple monomeric molecular motor. Although there are certainly many pertinent questions that remain unanswered, striking similarities in both form and function of seemingly disparate enzymes are becoming evident.

Measurement of steady-state kinetic parameters for DNA unwinding by the bacteriophage T4 Dda helicase: use of peptide nucleic acids to trap single-stranded DNA products of helicase reactions.

Measurement of steady-state rates of unwinding of double-stranded oligonucleotides by helicases is hampered due to rapid reannealing of the single-stranded DNA products. Including an oligonucleotide in the reaction mixture which can hybridize with one of the single strands can prevent reannealing. However, helicases bind to single-stranded DNA, therefore the additional oligonucleotide can sequester the enzyme, leading to slower observed rates for unwinding. To circumvent this problem, the oligonucleotide that serves as a trap was replaced with a strand of peptide nucleic acid (PNA). Fluorescence polarization was used to determine that a 15mer PNA strand does not bind to the bacteriophage T4 Dda helicase. Steady-state kinetic parameters of unwinding catalyzed by Dda were determined by using PNA as a trapping strand. The substrate consisted of a partial duplex with 15 nt of single-stranded DNA and 15 bp. In the presence of 250 nM substrate and 1 nM Dda, the rate of unwinding in the presence of the DNA trapping strand was 0.30 nM s(-1) whereas the rate was 1.34 nM s(-1) in the presence of the PNA trapping strand. PNA prevents reannealing of single-stranded DNA products, but does not sequester the helicase. This assay will prove useful in defining the complete kinetic mechanism for unwinding of oligonucleotide substrates by this helicase.

Evidence for a functional monomeric form of the bacteriophage T4 DdA helicase. Dda does not form stable oligomeric structures.

The active form of many helicases is oligomeric, possibly because oligomerization provides multiple DNA binding sites needed for unwinding of DNA. In order to understand the mechanism of the bacteriophage T4 Dda helicase, the potential requirement for oligomerization was investigated. Chemical cross-linking and high pressure gel filtration chromatography provided little evidence for the formation of an oligomeric species. The specific activity for ssDNA stimulated ATPase activity was independent of Dda concentration. Dda was mutated to produce an ATPase-deficient protein (K38A Dda) by altering a residue within a conserved, nucleotide binding loop. The helicase activity of K38A Dda was inactivated, although DNA binding properties were similar to Dda. In the presence of limiting DNA substrate, the rate of unwinding by Dda was not changed; however, the amplitude of product formation was reduced in the presence of increasing concentrations of K38A Dda. The reduction was between that expected for a monomeric or dimeric helicase based on simple competition for substrate binding. When unwinding of DNA was measured in the presence of excess DNA substrate, addition of K38A Dda caused no reduction in the observed rate for strand separation. Taken together, these results indicate that oligomerization of Dda is not required for DNA unwinding.

Biotin-streptavidin-labeled oligonucleotides as probes of helicase mechanisms.

Helicases use the energy from ATP hydrolysis to catalyze formation of single-stranded nucleic acids by unwinding double-stranded nucleic acids. The ATP-dependent reaction can be broken down into at least two steps: melting of the duplex and translocation of the enzyme along the nucleic acid lattice. Each step presents difficulties for study because clear end points for the reactions are not always available. For example, translocation involves the movement of the enzyme from one point along the lattice to a new position, with no net change in chemical structure of the nucleic acid. Hence, new assays have been developed in which the nucleic acid is modified to contain a "protein block" that impedes translocation of the enzyme. To prepare such protein blocks, biotin-streptavidin has been used due to the ease with which the biotin can be incorporated into nucleic acids by chemical synthesis. Several applications of oligonucleotides labeled with biotin-streptavidin for the study of helicase mechanisms are described.

Unwinding of nucleic acids by HCV NS3 helicase is sensitive to the structure of the duplex.

Hepatitis C virus (HCV) helicase, non-structural protein 3 (NS3), is proposed to aid in HCV genome replication and is considered a target for inhibition of HCV. In order to investigate the substrate requirements for nucleic acid unwinding by NS3, substrates were prepared by annealing a 30mer oligonucleotide to a 15mer. The resulting 15 bp duplex contained a single-stranded DNA overhang of 15 nt referred to as the bound strand. Other substrates were prepared in which the 15mer DNA was replaced by a strand of peptide nucleic acid (PNA). The PNA-DNA substrate was unwound by NS3, but the observed rate of strand separation was at least 25-fold slower than for the equivalent DNA-DNA substrate. Binding of NS3 to the PNA-DNA substrate was similar to the DNA-DNA substrate, due to the fact that NS3 initially binds to the single-stranded overhang, which was identical in each substrate. A PNA-RNA substrate was not unwound by NS3 under similar conditions. In contrast, morpholino-DNA and phosphorothioate-DNA substrates were utilized as efficiently by NS3 as DNA-DNA substrates. These results indicate that the PNA-DNA and PNA-RNA heteroduplexes adopt structures that are unfavorable for unwinding by NS3, suggesting that the unwinding activity of NS3 is sensitive to the structure of the duplex.

Unwinding of unnatural substrates by a DNA helicase.

Helicases separate double-stranded DNA into single-stranded DNA intermediates that are required during replication and recombination. These enzymes are believed to transduce free energy available from ATPase activity to unwind the duplex and translocate along the nucleic acid lattice. The nature of enzyme-substrate interactions between helicases and duplex DNA substrates has not been well-defined. Most helicases require a single-stranded DNA overhang adjacent to duplex DNA in order to initiate unwinding. The strand containing the overhang is referred to as the loading strand whereas the complementary strand is referred to as the displaced strand. We have investigated the interactions between a DNA helicase and the DNA substrate by replacing the displaced strand with a nucleic acid mimic, peptide nucleic acid (PNA). PNA is capable of forming duplex structures with DNA according to Watson-Crick base pairing rules, but contains a N-(2-aminoethyl)glycine backbone in place of the deoxyribose phosphates. The PNA-DNA hybrids had higher melting temperatures than their DNA-DNA counterparts. Dda helicase, from bacteriophage T4, was able to unwind the DNA-PNA substrates at similar rates as DNA-DNA substrates. The results indicate that the rate-limiting step for unwinding is relatively insensitive to the chemical nature of the displaced strand and the thermal stability of oligonucleotide substrates.

Enhanced pneumocystis carinii activity of new primaquine analogues.

New analogues of the venerable antimalarial drug primaquine have been synthesized and bioassayed in vivo against Pneumocystis carinii, a life-threatening infection common among immunosuppressed patients. Two of these new compounds are significantly more active than primaquine itself, and provide new information for future drug design and development in this area.

Inhibition of human telomerase by PNA-cationic peptide conjugates.

The inhibition of human telomerase has been explored using peptide conjugated derivatives of a PNA pentamer directed at the RNA template of telomerase. It is demonstrated that the presence of cationic peptides at the N-terminus of the PNA results in enhanced inhibition of telomerase activity. Furthermore, inhibition depended on the specificity of PNA recognition.

DNA helicases displace streptavidin from biotin-labeled oligonucleotides.

Helicases are enzymes that use energy derived from nucleoside triphosphate hydrolysis to unwind double-stranded (ds) DNA, a process vital to virtually every phase of DNA metabolism. The helicases used in this study, gp41 and Dda, are from the bacteriophage T4, an excellent system for studying enzymes that process DNA. gp41 is the replicative helicase and has been shown to form a hexamer in the presence of ATP. In this study, protein cross-linking was performed in the presence of either linear or circular single-stranded (ss) DNA substrates to determine the topology of gp41 binding to ssDNA. Results indicate that the hexamer binds ssDNA by encircling it, in a manner similar to that of other hexameric helicases. A new assay was developed for studying enzymatic activity of gp41 and Dda on single-stranded DNA. The rate of dissociation of streptavidin from various biotinylated oligonucleotides was determined in the presence of helicase by an electrophoretic mobility shift assay. gp41 and Dda were found to significantly enhance the dissociation rate of streptavidin from biotin-labeled oligonucleotides in an ATP-dependent reaction. Helicase-catalyzed dissociation of streptavidin from the 3'-end of a biotin-labeled 62-mer oligonucleotide occurred with a first-order rate of 0.17 min-1, which is over 500-fold faster than the spontaneous dissociation rate of biotin from streptavidin. Dda activity leads to even faster displacement of streptavidin from the 3' end of the 62-mer, with a first-order rate of 7.9 s-1. This is more than a million-fold greater than the spontaneous dissociation rate. There was no enhancement of streptavidin dissociation from the 5'-biotin-labeled oligonucleotide by either helicase. The fact that each helicase was capable of dislodging streptavidin from the 3'-biotin label suggests that these enzymes are capable of imparting a force on a molecule blocking their path. The difference in displacement between the 5' and 3' ends of the oligonucleotide is also consistent with the possibility of a 5'-to-3' directional bias in translocation on ssDNA for each helicase.

A simple procedure for solid-phase synthesis of peptide nucleic acids with N-terminal cysteine.

Problems were encountered during attempts to prepare N-terminal cysteine-substituted peptide nucleic acids (PNAs) from commercially available, Fmoc-protected monomers. These problems have been surmounted by the use of an S-t-butylmercapto protecting group on the cysteine moiety. The solid-phase syntheses are carried out via a simplified procedure which should be generally useful for manual PNA synthesis.

Stoichiometry and DNA unwinding by the bacteriophage T4 41:59 helicase.

The bacteriophage T4 41 protein is a replicative helicase that forms a hexamer in the presence of ATP and associates with the T4 59 protein. The stoichiometry of the 41:59 helicase complex and its mechanism for DNA unwinding have been investigated using steady-state and single-turnover kinetics. A partial duplex DNA fork containing two regions of single-stranded DNA (ssDNA) of 30 nucleotides each, and 30 base pairs served as the substrate. 59 was found to increase the steady-state unwinding rate of the substrate by 200-fold over the rate of 41 alone. Maximum unwinding occurred when 59 and 41 were equimolar, revealing a 1:1 stoichiometry for the complex. Varying 41 while holding 59 constant resulted in sigmoidal kinetics suggesting strong cooperativity for formation of the 41 hexamer and providing a lower limit for hexamer assembly of 65 nM. Substrates were prepared that contained a biotin-streptavidin block in either the leading or lagging strand of the duplex region of the substrate. The first order rate constant for unwinding was reduced only when the block was placed in the lagging strand of the DNA fork, indicating that the helicase interacts primarily with the lagging DNA strand.

Bacteriophage T4 Dda helicase translocates in a unidirectional fashion on single-stranded DNA.

The T4 bacteriophage Dda helicase is believed to be involved in early events in T4 DNA replication and has been shown to stimulate genetic recombination processes in vitro. Dda unwinds double-stranded DNA with 5' to 3' polarity but its ability to translocate on DNA has not been established. The DNA stimulated ATPase activity of Dda helicase has been used to probe translocation on single-strand DNA (ssDNA). Dda exhibits higher ATPase activity in the presence of poly(dT) than oligo(dT)16, indicating that Dda translocates on ssDNA. Oligonucleotides containing biotin/streptavidin blocks on the 5' or 3' end were used to probe directionality of translocation. The Kact (Km for DNA) for Dda ATPase activity was reduced in the presence of a streptavidin block on the 3' end, whereas a streptavidin block on the 5' end had only a small effect on the steady-state ATPase parameters. These results suggest that Dda translocates unidirectionally in a 5' to 3' manner and upon encountering the block remains bound to the oligonucleotide rather than sliding off the 3' end. The direction of translocation on ssDNA is consistent with the direction in which Dda unwinds duplex DNA and is not dependent on duplex structure.

Interactions of ingested food, beverage, and tobacco components involving human cytochrome P4501A2, 2A6, 2E1, and 3A4 enzymes.

Human cytochrome P450 (P450) enzymes are involved in the oxidation of natural products found in foods, beverages, and tobacco products and their catalytic activities can also be modulated by components of the materials. The microsomal activation of aflatoxin B1 to the exo-8,9-epoxide is stimulated by flavone and 7,8-benzoflavone, and attenuated by the flavonoid naringenin, a major component of grapefruit. P4502E1 has been demonstrated to play a potentially major role in the activation of a number of very low-molecular weight cancer suspects, including ethyl carbamate (urethan), which is present in alcoholic beverages and particularly stone brandies. The enzyme (P4502E1) is also known to be inducible by ethanol. Tobacco contains a large number of potential carcinogens. In human liver microsomes a significant role for P4501A2 can be demonstrated in the activation of cigarette smoke condensate. Some of the genotoxicity may be due to arylamines. P4501A2 is also inhibited by components of crude cigarette smoke condensate. The tobacco-specific nitrosamines are activated by a number of P450 enzymes. Of those known to be present in human liver, P4501A2, 2A6, and 2E1 can activate these nitrosamines to genotoxic products.

A fluorescence-based assay for monitoring helicase activity.

A continuous fluorescence-based assay is described for measuring helicase-mediated unwinding of duplex DNA. The assay utilizes an oligonucleotide substrate containing the fluorescent adenine analog, 2-aminopurine, at regular intervals. 2-Aminopurine forms a Watson-Crick-type base pair with thymine and does not distort normal B-form DNA. Fluorescence of the 2-aminopurines within this oligonucleotide is quenched 2-fold upon its hybridization to a complementary strand. Unwinding of this substrate by the T4 dda helicase restores the fluorescence of the 2-aminopurines and is easily followed using stopped-flow or steady-state fluorescence spectroscopy. The flourescence-based assay provides rate data comparable to that obtained from conventional discontinuous assays using labeled substrates and additionally furnishes a means for following a single turnover. This assay should prove useful for defining the mechanism by which helicases unwind duplex DNA.

Elucidation of catalytic specificities of human cytochrome P450 and glutathione S-transferase enzymes and relevance to molecular epidemiology.

A number of different approaches have been used to determine the catalytic selectivity of individual human enzymes toward procarcinogens. Studies with cytochrome P450 (P450) enzymes and glutathione S-transferases are summarized here, and recent work with pyrrolizidine alkaloids, aflatoxins, 4,4'-methylenebis(2-chloroaniline), and ethyl carbamate is discussed. In some cases a single enzyme can catalyze both activation and detoxication reactions of a chemical. The purification and characterization of human lung P4501A1 and the development of a noninvasive assay for human P4502E1 are also described.

Glutathione conjugation of aflatoxin B1 exo- and endo-epoxides by rat and human glutathione S-transferases.

Much evidence supports the view that the rate of conjugation of glutathione (GSH) with aflatoxin B1 (AFB1) exo-epoxide is an important factor in determining the species variation in risk to aflatoxins and that induction of GSH S-transferases can yield a significant protective effect. An assay has been developed in which the enzymatic formation of the conjugates of GSH and AFB1 exo-epoxide and the recently described AFB1 endo-epoxide is measured directly. 1H NMR spectra are reported for both the AFB1 exo- and endo-epoxide-GSH conjugates. Structural assignments were made by comparison with AFB1 exo- and endo-epoxide-ethanethiol conjugates, for which nuclear Overhauser effects were measured to establish relative configurations. The endo-epoxide was found to be a good substrate for GSH conjugate formation in rat liver cytosol while mouse liver cytosol conjugated the exo-epoxide almost exclusively. Human liver cytosol conjugated both epoxide isomers to much lower extents than did cytosols prepared from rats or mice. Purified rat GSH S-transferases catalyzed the formation of the AFB1 exo-epoxide-GSH conjugate in the order 1-1 approximately 4-4 approximately 3-3 greater than 2-2 greater than 4-6 (7-7 and 8-8 did not form the exo-epoxide-GSH conjugate at levels above the nonenzymatic rate). The only rat GSH S-transferases that conjugated the endo-epoxide were 4-4 and 4-6, with 4-4 being the more active.(ABSTRACT TRUNCATED AT 250 WORDS)