Pyrrolo-C as a fluorescent probe for monitoring RNA secondary structure formation

Pyrrolo-C (PC), or 3-[beta-D-2-ribofuranosyl]-6-methylpyrrolo[2,3-d]pyrimidin-2(3H)-one, is a fluorescent analog of the nucleoside cytidine that retains its Watson-Crick base-pairing capacity with G. Due to its red-shifted absorbance, it can be selectively excited in the presence of natural nucleosides, making it a potential site-specific probe for RNA structure and dynamics. Similar to 2-aminopurine nucleoside, which base-pairs with uridine (or thymidine), PC's fluorescence becomes reversibly quenched upon base-pairing, most likely due to stacking interactions with neighboring bases. To test its utility as an RNA probe, we examined PC's fluorescent properties over a wide range of ionic strengths, pH, organic cosolvents, and temperatures. Incorporation of PC into a single-stranded RNA results in an approximately 60% reduction of fluorescence intensity, while duplex formation reduces the fluorescence by approximately 75% relative to the free ribonucleoside. We find that the fluorescence intensity of PC is only moderately affected by ionic strength, pH, and temperature, while it is slightly enhanced by organic cosolvents, making it a versatile probe for a broad range of buffer conditions. We demonstrate two applications for PC: fluorescent measurements of the kinetics of formation and dissociation of an RNA/DNA complex, and fluorescent monitoring of the thermal denaturation of the central segment of an RNA duplex. Taken together, our data showcase the potential of pyrrolo-C as an effective fluorescent probe to study RNA structure, dynamics, and function, complementary to the popular 2-aminopurine ribonucleoside.

The mechanism of DNA replication primer synthesis by RNA polymerase

RNA primers for DNA replication are usually synthesized by specialized enzymes, the primases. However, some replication systems have evolved to use cellular DNA-dependent RNA polymerase for primer synthesis. The main requirement for the replication primer, an exposed RNA 3' end annealed to the DNA template, is not compatible with known conformations of the transcription elongation complex, raising a question of how the priming is achieved. Here we show that a previously unrecognized kind of transcription complex is formed during RNA polymerase-catalysed synthesis of the M13 bacteriophage replication primer. The complex contains an overextended RNA-DNA hybrid bound in the RNA-polymerase trough that is normally occupied by downstream double-stranded DNA, thus leaving the 3' end of the RNA available for interaction with DNA polymerase. Transcription complexes with similar topology may prime the replication of other bacterial mobile elements and may regulate transcription elongation under conditions that favour the formation of an extended RNA-DNA hybrid.

Base−Base Interactions in the Minor Groove of Double-Stranded DNA

A method has been developed for the synthesis of bisheaded nucleosides with thymine and adenine base moieties. We have demonstrated that, when incorporated in oligonucleotides, extrahelical A-T base interactions are possible when the bisheaded nucleosides are positioned in opposite strands of the duplex and are separated from each other by one regular base pair.

A Standard Reference Material to determine the sensitivity of techniques for detecting low-frequency mutations, SNPs, and heteroplasmies in mitochondrial DNA

Human mitochondrial DNA (mtDNA) mutations are important for forensic identifications and mitochondrial disease diagnostics. Low-frequency mutations, heteroplasmies, or SNPs scattered throughout the DNA in the presence of a majority of mtDNA with the Cambridge Reference Sequence (CRS) are almost impossible to detect. Therefore, the National Institute of Science and Technology has developed heteroplasmic human mtDNA Standard Reference Material (SRM) 2394 to allow scientists to determine their sensitivity in detecting such differences. SRM 2394 is composed of mixtures ranging from 1/99 to 50/50 of two 285-bp PCR products from two cell lines that differ at one nucleotide position. Twelve laboratories using various mutation detection methods participated in a blind interlaboratory evaluation of a prototype of SRM 2394. Most of these procedures were unable to detect the mutation when present below 20%, an indication that, in many real-life cases, low-frequency mutations remain undetected and that more sensitive mutation detection techniques are urgently needed.

Temperature-mediated heteroduplex analysis for the detection of drug-resistant gene mutations in clinical isolates of Mycobacterium tuberculosis by denaturing HPLC, SURVEYOR nuclease

Denaturing high-performance liquid chromatography (DHPLC) is a relatively new technique, which utilizes heteroduplex formation between wild-type and mutated DNA strands to identify point mutations. Heteroduplex molecules are separated from homoduplex molecules by ion-pair, reverse-phase liquid chromatography on a special column matrix with partial heat denaturation of the DNA strands. In order to investigate the application of this method for point mutation detection in drug-resistant genes of Mycobacterium tuberculosis, katG, rpoB, embB, gyrA, pncA and rpsL genes, which are responsible for isoniazid, rifampicin, ethambutol, fluoroquinolone, pyrazinamide and streptomycin resistance, respectively, were detected by temperature-mediated DHPLC in 10 multidrug-resistant and 10 drug-susceptible clinical isolates. The DHPLC data were compared with those from a conventional MIC test. The results show that DHPLC is cost-effective with high capacity and accuracy, and is potentially useful for genotypic screening for mutations associated with anti-tuberculosis drug resistance.

Hydration and conformational transitions in DNA, RNA, and mixed DNA-RNA triplexes studied by gravimetry and FTIR spectroscopy

We have studied by gravimetric measurements and FTIR spectroscopy the hydration of duplexes and triplexes formed by combinations of dA(n), dT(n), rA(n), and rU(n) strands. Results obtained on hydrated films show important differences in their hydration and in the structural transitions which can be induced by varying the water content of the samples. The number of water molecules per nucleotide (w/n) measured at high relative humidity (98% R.H.) is found to be 21 for dA(n).dT(n) and 15 for rA(n).rU(n). Addition of a third rU(n) strand does not change the number of water molecules per nucleotide: w/n=21 for rU(n)*dA(n).dT(n) and w/n=15 for rU(n)*rA(n).rU(n). On the contrary, the addition of a third dT(n) strand changes the water content but in a different way, depending whether the duplex is DNA or RNA. Thus, a loss of four water molecules per nucleotide is measured for dT(n)*dA(n).dT(n) while an increase of two water molecules per nucleotide is observed for dT(n)*rA(n).rU(n). The final hydration is the same for both triplexes (w/n=17). The desorption profiles obtained by gravimetry and FTIR spectroscopy are similar for the rA(n).rU(n) duplex and the rU(n)*rA(n).rU(n) triplex. On the contrary, the desorption profiles of the dA(n).dT(n) duplex and the triplexes formed with it (rU(n)*dA(n).dT(n) and dT(n)*dA(n).dT(n)) are different from each other. This is correlated with conformational transitions induced by varying the hydration content of the different structures, as shown by FTIR spectroscopy. Modifications of the phosphate group hydration and of the sugar conformation (S to N type repuckering) induced by decrease of the water content are observed in the case of triplexes formed on the dA(n).dT(n) duplex.

Engineering DNA topology with locked nucleosides: a structural study

DNA dodecamers modified with nucleotide building blocks based on a bicyclo[3. 1.0]hexane system that effectively locks the ribose template into an RNA-like or North (N) conformation were analyzed by various biophysical techniques including high field nuclear magnetic resonance (NMR). Replacement of either one or both of the center thymidines in the Dickerson Drew dodecamer (CGCGAAT*T*CGCG) caused a progressive shift in the bending propensity of the double helix as shown by a newly developed rapid technique that compares the residual dipolar coupling (RDC) values of the modified duplexes with those previously determined for the native DNA.

Perylene attached to DNA through stiff or flexible linker: duplex stability and FRET

Two fluorescent nucleosides, 5-(perylen-3-ylethynyl)-2'-deoxyuridine and 5-[(perylen-3-yl)methoxypropyn-1-yl]-2'-deoxyuridine, were incorporated into synthetic oligodeoxyribonucleotides and spectral properties of the conjugates and their duplexes were studied.

Interaction of porphyrin with G-quadruplex structures

Isothermal titration calorimetry (ITC) is a sensitive technique for probing bimolecular processes and can provide direct information about the binding affinity and stoichiometry and the key thermodynamic parameters involved. ITC has been used to investigate the interaction of the ligand H2TMPyP to the two DNA quadruplexes, [d(AGGGT)]4 and [d(TGGGGT)]. Analysis of the ITC data reveals that porphyrin/quadruplex binding stoichiometry under saturating conditions is 1:2 for [d(AGGGT)]4 and 2:1 for [d(TGGGGT)], respectively.

Synthesis and characterization of DNA duplexes containing an N3T-ethyl-N3T interstrand crosslink in opposite orientations

DNA duplexes containing an ethyl interstrand crosslink that bridges the N3 atoms of thymidines on the opposite strands have been synthesized using an approach that combines conventional solid phase oligonucleotide synthesis and the selective removal of protecting groups of a crosslinked thymidine dimer. This approach allows for the assembly of a crosslinked duplex directly on the solid support. Duplexes that contain a N3T-ethyl-N3T interstrand crosslink in a staggered orientation at either a -TA- or -AT-step in a duplex have been prepared. When placed in an -AT- step of a duplex the effect was stabilizing relative to the non-crosslinked control duplex (deltaTm= +24 degrees C) and this crosslinked duplex was found to efficiently form multimers in the presence of T4 ligase. In the case of the -TA- crosslinked duplex the stabilizing effect was less pronounced (deltaT.= +6 degrees C) and likewise did not undergo self ligation under identical conditions. Molecular modeling studies suggested that the -AT- containing lesion had little deviation in structure relative to the non-crosslinked duplex DNA control, whereas the -TA- crosslinked duplex exhibited significant buckling of the base pairs flanking the lesion.

Gold DNA-conjugates: ion specific self-assembly of gold nanoparticles via the dG-quartet

The Oxytricha telomere DNA hairpin 5'-d(G4T4G4) immobilized on 13 nm gold nanoparticles forms a supramolecular assembly via dGC-quartets, as determined by the color change and by SEM. The aggregation is ion-dependent and selective for sodium ions. K+ is less efficient while Li+ and Cs+ do not drive the aggregation. This work is the first effort exploring the use of secondary structures of DNA (quadruplexes) for producing self-assemblies of gold nanoparticles.

Expansion of triplex recognition codes by the use of novel bicyclic nucleoside derivatives (WNA)

Recently, we have developed new base analogs (WNA) and demonstrated that WNA-[see text];T with thymine and WNA-[see text];C with cytosine stabilize n on-natural antiparallel triplexes with a TA or CG interrupting site, respectively. However, limitations in recognizable sequences with the WNA-containing TFO were also found. The objective of this study is to search better WNA analogs for expansion of triplex recognition codes to general duplex sequences. In this study, we designed new WNA analogs by systematic modification of the aromatic part and the recognition part. The new WNA analogs with the benzene ring substituted with bromide or cyanide have determined for selective stabilization of triplexes at a TA interrupting site, and general formation of triplexes having a TA interrupting site has been achieved.

Effects of acrolein on the quadruplex forming d(TTAGGG)4 telomeric repeat sequence

HPLC and ESI-MS analysis have been used to investigate the effect of acrolein exposure on d(TITAGGG)4 human telomeric repeat. Preliminary results disclosed a novel relationship between the structure assumed by oligodeoxynucleotides (ODNs) and the capability of their nucleobase residues to react with acrolein.

3'-modified oligo (2'-O-methylribonucleotides) as improved probes for hybridization with RNA

A series of octa (2-O-methylribonucleotides) with an additional 3'-terminal deoxynucleoside (T, dC, dA or dG) linked by the 3'-3' (inverted) bond was synthesized. The exceptional stability of these oligomers to a 3'-exonuclease (SVP) and nucleases in culture medium containing 10% heat-inactivated fetal calf serum was demonstrated. It was shown that the addition of the 3'-dangling inverted deoxynucleoside increases substantially the thermal stability of the duplexes of oligo(2'-O-methylribonucleotides) with complementary RNA and DNA in the case of a relatively weak terminal AmU(T) pair and enhances the mismatch sensitivity.

Relative stability of quadruplexes containing different number of G-tetrads

The aim of this work is to compare the physicochemical properties of three oligonucleotidic sequences, d(TGGGT), d(TGGGGT) and d(TGGGGGT), which assemble to form quadruplex structures with the same molecularity, but containing three, four, and five G-quartets, respectively. The addition of one or two G-tetrads greatly increases both the enthalpy and Tm values of the quadruplex dissociation.

Structural studies on LNA quadruplexes

LNAs (locked nucleic acids) are new DNA analogues with higher binding affinities toward nucleic acids than the canonical counterparts mainly due to the characteristic conformational restriction arising from the 2'-O, 4'-C methylene bridge. In light of the promising therapeutic applications and considering the advantageous characteristics of LNAs, such as their high water solubility, easy handling, and synthetic accessibility through the conventional phosphoramidite chemistry, we undertook a study concerning the capability of these nucleic acid analogues to form quadruplex structures. Particularly, we have been investigating the LNA/DNA chimeras corresponding to the well-known DNA sequences 5-GGTTGGTGTGGTTGG-3', capable of forming an unimolecular quadruplex. This article deals with the study of the sequence 5'-ggTTggTGTggTTgg-3' (upper and lower case letters represent DNA and LNA residues, respectively), which, according to CD spectroscopy, is able to fold into a quadruplex structure.

A study of H-bonding of 3- and 5-substituted 6-aminouracils in duplex and triplex structures

All possible dimers of the title modified bases with native nucleobases [10 dimers from 3-methylated 6-aminouracils (3sau) and 20 from 5-methyled 6-aminouracils (5sau), respectively have been calculated by ab initio method (Hartree-Fock method, 3 21G basis set). We have found two potential duplexes of 5sau and three possible duplexes of 3sau. Altogether seven dimers containing one or two bifurcating H-bonds have been found. Later on, five triplexes from ten possible calculated dimers have been found. In two of them the amino group of 6-aminouracil moiety takes part in H-bonding and there are H-bonds, too, between the first and third base of the triplexes causing an extra stabilization.

Multiple Epstein-Barr virus strains in patients with infectious mononucleosis: comparison of ex vivo samples with in vitro isolates by use of heteroduplex tracking assays

Recent work using a heteroduplex tracking assay (HTA) to identify resident viral sequences has suggested that patients with infectious mononucleosis (IM) who are undergoing primary Epstein-Barr virus (EBV) infection frequently harbor different EBV strains. Here, we examine samples from patients with IM by use of a new Epstein-Barr nuclear antigen 2 HTA alongside the established latent membrane protein 1 HTA. Coresident allelic sequences were detected in ex vivo blood and throat wash samples from 13 of 14 patients with IM; most patients carried 2 or more type 1 strains, 1 patient carried 2 type 2 strains, and 1 patient carried both virus types. In contrast, coresident strains were detected in only 2 of 14 patients by in vitro B cell transformation, despite screening >20 isolates/patient. We infer that coacquisition of multiple strains is common in patients with IM, although only 1 strain tends to be rescued in vitro; whether nonrescued strains are present in low abundance or are transformation defective remains to be determined.

DNA reassociation using oscillating phenol emulsions

Reassociating double-stranded DNA from single-stranded components is necessary for many molecular genetics experiments. The choice of a DNA reassociation method is dictated by the complexity of the starting material. Reassociation of simple oligomers needs only slow cooling in an aqueous environment, whereas reannealing the many single-stranded DNAs of complex genomic mixtures requires both a phenol emulsion to accelerate DNA reassociation and dedicated equipment to maintain the emulsion. We present a method that is equally suitable for reassociating either simple or complex DNA mixtures. The Oscillating Phenol Emulsion Reassociation Technique (OsPERT) was primarily developed to prepare heteroduplex DNA from alkali-denatured high molecular weight human genomic DNA samples in which hundreds of thousands of fragments need to be reannealed, but the simplicity of the technique makes it practical for less demanding DNA reassociation applications.

Nick-directed repair of palindromic loop mismatches in human cell extracts

Palindromic sequences present in DNA may form secondary structures that block DNA replication and transcription causing adverse effects on genome stability. It has been suggested that hairpin structures containing mispaired bases could stimulate the repair systems in human cells. In this study, processing of variable length of palindromic loops in the presence or absence of single-base mismatches was investigated in human cell extracts. Our results showed that hairpin structures were efficiently processed through a nick-directed mechanism. In a similar sequence context, mismatch-containing hairpins have higher repair efficiencies. We also found that shorter hairpins are generally better repaired. A strand break located either 3' or 5' to the loop is sufficient to activate hairpin repair on the nicked strand. The reaction requires Mg(2+), the four dNTPs and hydrolysis of ATP for efficient repair on both palindromic loop insertions and deletions. Correction of each of these heteroduplexes was abolished by aphidicolin but was relatively insensitive to the presence of ddTTP, suggesting involvement of polymerase(s) alpha and/or delta. These findings are most consistent with the nick-directed loop repair pathway being responsible for processing hairpin heterologies in human cells.

Effect of E-Ring Modifications in Camptothecin on Topoisomerase I Inhibition: A Quantum Mechanics Treatment

Camptothecins (CPTs) are the prototypical class of topoisomerase I (Top1) inhibitors with significant anticancer activities. Structure-activity relationship studies have demonstrated that inverting the stereochemistry at C-20 (R-CPT) or changing the E-ring lactone to a lactam (CPT-lactam) abolishes the Top1 inhibitory activity. The explanations that have been advanced for these effects are that there is either a failure of hydrogen bond formation involving the C-20 hydroxyl group of R-CPT or a failure of E-ring opening of the lactam, which have been proposed to be required for Top1 inhibition. We demonstrate here that the preferred conformation for the CPTs has the 20-Et pseudoaxial, while the 20-OH is pseudoequatorial, and therefore, the 20-OH groups in all the three CPT analogues (S-CPT, R-CPT, and CPT-lactam) are able to hydrogen bond with Asp533. The loss of the Top1 inhibitory activity by the latter two CPT analogues is attributed to the decreased pi-pi stacking interaction energy with the neighboring base pairs compared to the natural S-CPT. The differences in pi-pi stacking interaction energies are derived from the differential electrostatics on the E-ring.

Analbuminemia in a Slovak Romany (gypsy) family: case report and mutational analysis

BACKGROUND

Analbuminemia is a rare autosomal recessive disorder manifested by the absence, or severe reduction, of circulating serum albumin. Here we report three new cases of hereditary analbuminemia, fortuitously detected in three Slovak Romany children, members of the same family, and define the molecular defect that causes the analbuminemic trait.

METHODS

Total DNA, extracted from peripheral blood samples from six members of the family, was PCR-amplified using oligonucleotide primers designed to amplify the 14 exons of the human albumin gene and the flanking intron regions. The products were screened for mutations by single-strand conformation polymorphism (SSCP) and heteroduplex analyses (HA). HA allowed the identification of the abnormal fragment, which was then sequenced.

RESULTS

In the 3 patients the analbuminemic trait was caused by the same mutation, an AT deletion at nucleotides 2430-31, the 91 th and 92 th bases of exon 3. This defect, previously identified as Kayseri mutation, produces a frameshift leading to a premature stop, two codons downstream. The predicted translation product would consist of 54 amino acid residues. The parents were found to be heterozygous for the mutation.

CONCLUSIONS

Our results confirm that the combination of SSCP and HA represents a powerful tool to study the molecular defects causing analbuminemia in humans.

[PCR products with heterozygous mutations containing two types of heteroduplexes]

OBJECTIVE

To confirm that PCR products with heterozygous mutations contain not only wide-type and mutant homoduplexes, but also two types of heteroduplexes.

METHODS

An insertion-deletion mutation in the exon 1 of KRT9 gene (497delAinsGGCT), which caused Chinese epidermolytic palmoplantar keratoderma (EPPK) was investigated by polymerase chain reaction (PCR), polyacrylamide gel electrophoresis (PAGE) and denaturing high-performance liquid chromatography(DHPLC).

RESULTS

Two heteroduplexes and two homoduplexes in the PCR product from the heterozygous mutation of the exon 1 of KRT9 (497delAinsGGCT) were detected.

CONCLUSION

PCR products from KRT9 gene with heterozygous mutations contain two types of heteroduplexes. It is without the need to perform heating and cooling PCR products obtained from heterozygous mutations in advance before the mutation screening steps such as denaturing gradient gel electrophoresis (DGGE), temperature gradient gel electrophoresis (TGGE), conformation-sensitive gel electrophoresis (CSGE), DHPLC and heteroduplex analysis (HA), etc.

Use of denaturing HPLC to provide efficient detection of mutations causing guanidinoacetate methyltransferase deficiency

Guanidinoacetate methyltransferase (GAMT) deficiency is an autosomal recessive error of creatine synthesis characterized by cerebral creatine deficiency, accumulation of guanidinoacetate, mental retardation, epilepsy, and extrapyramidal symptoms. To date, 14 mutations of the GAMT gene in 27 patients have been reported. Mutation analysis was done using direct sequencing of PCR products and denaturing gradient gel electrophoresis in combination with direct sequencing. In contrast, we evaluated the efficiency of a newly developed DHPLC method to detect mutations in the GAMT gene by analysing DNA from 14 GAMT patients with known mutations. PCR amplification of both patient and control DNA was followed by formation of homoduplices and heteroduplices, and their detection by DHPLC. DHPLC identified all mutations tested and is the preferred choice of analytical method.

Target-assembled tandem oligonucleotide systems based on exciplexes for detecting DNA mismatches and single nucleotide polymorphisms

We report the first exciplex-based split-probe system for DNA detection. The detector is split at a molecular level into signal-silent components which, before a signal is generated, must be assembled correctly into a particular three-dimensional arrangement. The model system comprises of two 8-mer oligonucleotides, complementary to neighbouring sites of a 16-mer DNA target, each equipped with moieties able to form an exciplex on correct, contiguous hybridization. The exciplex emits at approximately 480 nm with a large Stokes shift (135 nm). The extremely rigorous structural demands for exciplex formation and emission were achieved by careful structural design and by the discovery that high levels of certain organic solvents (especially trifluoroethanol) specifically favour emission of the DNA-mounted exciplex, probably the net result of the particular duplex structure and specific solvation of the exciplex partners. Inserts and mismatches can be effectively detected by this exciplex construct giving potential for single nucleotide polymorphism detection.

Gene sensors based on peptide nucleic acid (PNA) probes: relationship between sensor sensitivity and probe/target duplex stability

Gene sensors based on peptide nucleic acid (PNA) probes were prepared and the relationship between sensor sensitivity and the duplex stability of the probe PNAs and target complementary DNAs was studied using five synthesized PNAs (10-, 15-, 17-, 20-, and 22-mers). It was found that the association constants for the probe PNA/target DNA pairs depend not only on the length but also on the base pair sequence, and that the trend in the sensor responses was the same as that in the association constants for the corresponding pairs. In addition, by using two kinds of probe PNAs with different lengths, it was demonstrated that fabrication of sensors based on probe PNAs with comparable association constants yielded similar response curves and sensor sensitivities.

Measuring allelic heterogeneity in Plasmodium falciparum by a heteroduplex tracking assay

We developed a novel Plasmodium falciparum genotyping strategy based on the heteroduplex tracking assay (HTA) method commonly used to genotype viruses. Because it can detect both sequence and size polymorphisms, we hypothesized that HTA is more sensitive than current methods. To test this hypothesis, we compared the ability of HTA and a nested polymerase chain reaction (PCR) to detect genetic diversity in 17 Thai samples. The HTA detected more MSP1 sequence variants in eight isolates (47%), less sequence variants in three isolates (18%), and an equal number of sequence variants in six isolates (35%), suggesting that HTA is equal to or more sensitive than the nested PCR. This study is a proof of concept that HTA is a sensitive allelic discrimination method able to determine genetic diversity in P. falciparum and warrants its use in studies of antimalarial drug efficacy.

RecQ family members combine strand pairing and unwinding activities to catalyze strand exchange

RecQ helicases are critical for maintaining genomic integrity. In this study, we show that three RecQ members (WRN, deficient in the Werner syndrome; BLM, deficient in the Bloom syndrome; and Drosophila melanogaster RecQ5b (dmRecQ5b)) possess a novel strand pairing activity. Furthermore, each of these enzymes combines this strand pairing activity with its inherent DNA unwinding capability to perform coordinated strand exchange. In this regard, WRN and BLM are considerably more efficient than dmRecQ5b, apparently because dmRecQ5b lacks conserved sequences C-terminal to the helicase domain that contribute to DNA binding, strand pairing, and strand exchange. Based on our findings, we postulate that certain RecQ helicases are structurally designed to accomplish strand exchange on complex replication and recombination intermediates. This is highly consistent with proposed roles for RecQ members in DNA metabolism and the illegitimate recombination and cancer-prone phenotypes associated with RecQ defects.

Genetic linkage maps of the red flour beetle, Tribolium castaneum, based on bacterial artificial chromosomes and expressed sequence tags

A genetic linkage map was constructed in a backcross family of the red flour beetle, Tribolium castaneum, based largely on sequences from bacterial artificial chromosome (BAC) ends and untranslated regions from random cDNA's. In most cases, dimorphisms were detected using heteroduplex or single-strand conformational polymorphism analysis after specific PCR amplification. The map incorporates a total of 424 markers, including 190 BACs and 165 cDNA's, as well as 69 genes, transposon insertion sites, sequence-tagged sites, microsatellites, and amplified fragment-length polymorphisms. Mapped loci are distributed along 571 cM, spanning all 10 linkage groups at an average marker separation of 1.3 cM. This genetic map provides a framework for positional cloning and a scaffold for integration of the emerging physical map and genome sequence assembly. The map and corresponding sequences can be accessed through BeetleBase (http://www.bioinformatics.ksu.edu/BeetleBase/).

Physics of RecA-mediated homologous recognition

To accomplish its DNA strand exchange activities, the Escherichia coli protein RecA polymerizes onto DNA to form a stiff helical nucleoprotein filament within which the DNA is extended by 50%. Homology search and recognition occurs between ssDNA within the filament and an external dsDNA molecule. We show that stretching the internal DNA greatly enhances homology recognition by increasing the probability that the homologous regions of a stretched DNA molecule and a parallel, unstretched DNA molecule will be "in register" at some position. We also show that the stretching and stiffness of the filament act together to ensure that initiation of homologous exchange between the substrate DNA molecules at one position precludes initiation of homologous exchange at any other position. This prevents formation of multiple exchange site "topological traps" which would prevent completion of the exchange reaction and resolution of the products.

Rapid heteroduplex analysis by capillary electrophoresis

The very important parameters for mutation screening are short time of analysis and high throughput. The analytical platform which fulfills these criteria most satisfactorily is capillary electrophoresis. Here we show the influence of several parameters such as temperature, presence of glycerol, capillary length and polymer concentration on the electrophoretic properties of DNA duplexes and evaluate their contribution to the overall time of analysis. The careful optimization of analyzed conditions allowed us to significantly decrease the time required for the detection of the 185delAG and 4153delA mutations by heteroduplex analysis. It enabled us to analyze these typical BRCA1 gene deleterious mutations in several minutes only by using very popular and widely accessible capillary electrophoresis instrumentation.

A comparative binding study of BIV Tat peptide against its TAR RNA duplex, RNA–DNA heteroduplex and DNA duplex

Association between RNA and DNA strands to form RNA-DNA heteroduplex is important in many biological processes such as transcription, DNA replication and reverse transcription. Herein, binding affinities of a 17-mer BIV Tat peptide is compared with TAR DNA duplex, TAR RNA-DNA heteroduplex and TAR RNA duplex. It was observed that binding affinities of Tat peptide is comparable against DNA-RNA heteroduplex and RNA duplex, whereas DNA duplex binding is decidedly poor.

Mutations in the nucleotide-binding domain of MutS homologs uncouple cell death from cell survival

After genotoxic insult, the decision to repair or undergo cell death is pivotal for undamaged cell survival, and requires a highly controlled coordination of both pathways. Disruption of this regulation results in tumorigenesis and failure of cancer therapy. Mismatch repair (MMR) proteins have a unique role by contributing to both pathways, though direct evidence for their function in the DNA damage response is ambiguous. We report separation of function mutants in the ATPase domains of yeast MutS homologous (MSH) proteins that uncouple MMR-dependent DNA repair from damage response to cisplatin. While mutations in the ATPase domain have devastating effects on the mutation rate of the cell, ATPase processing is mostly dispensable for the cell death phenotype; only limited processing by the MSH6 subunit is required in DNA damage response. Different DNA binding patterns and nucleotide sensitivity of Msh2/Msh6-DNA adduct and protein-mismatch complexes, respectively, suggest that the presence of different DNA lesions influences the requirement for ATP. Limited proteolysis of purified protein gives first indications for differences in nucleotide-induced conformational changes in the presence of platinated DNA. Structural modeling of bacterial MutS proteins reinforces nucleotide-dependent differences in structures that contribute to the distinction between DNA damage response and repair. Our results demonstrate the uncoupling of MMR-dependent damage response from repair and present first indications for the involvement of distinct conformational changes in MSH proteins in this process. These data present evidence for a mechanism of MMR-dependent damage response that differs from MMR; these results have strong implications for the chemotherapeutic treatment of MMR-defective tumors.

Multiple roles for the T7 promoter nontemplate strand during transcription initiation and polymerase release

Transcription initiation begins with recruitment of an RNA polymerase to a promoter. Polymerase-promoter interactions are retained until the nascent RNA is extended to 8-12 nucleotides. It has been proposed that accumulation of "strain" in the transcription complex and RNA displacement of promoter-polymerase interactions contribute to releasing the polymerase from the promoter, and it has been further speculated that too strong a promoter interaction can inhibit the release step, whereas a weak interaction may facilitate release. We examined the effects of partial deletion of the nontemplate strand on release of T7 RNA polymerase from the T7 promoter. T7 polymerase will initiate from such partially single-stranded promoters but binds them with higher affinity than duplex promoters. We found that release on partially single-stranded promoters is strongly inhibited. The inhibition of release is not due to an indirect effect on transcription complex structure or loss of specific polymerase-nontemplate strand interactions, because release on partially single-stranded templates is recovered if the interaction with the promoter is weakened by a promoter base substitution. This same substitution also appears to allow the polymerase to escape more readily from a duplex promoter. Our results further suggest that template-nontemplate strand reannealing drives dissociation of abortive transcripts during initial transcription and that loss of interactions with either the nontemplate strand or duplex DNA downstream of the RNA lead to increased transcription complex slippage during initiation.

Facile formation of an intrastrand cross-link lesion between cytosine and guanine upon pyrex-filtered UV light irradiation of d((Br)CG) and duplex DNA containing 5-bromocytosine

Pyrex-filtered UV light irradiation of d(BrCG) and 5-bromocytosine-containing duplex DNA leads to facile formation of a cross-link lesion between the C5 carbon atom of cytosine and the C8 carbon atom of its adjacent guanine. A similar cross-link lesion has been previously found in the X-ray irradiation mixture of d(CGTA).

Properties of ferrocene-polyamide compounds as redox active DNA binding molecules toward the SNPs detection

Ferrocene-polyamides having not only sequence discrimination ability but also a redox mediator were synthesized. The affinity and selectivity of these compounds for a DNA duplex having a cognate GCG sequence were investigated by CD spectroscopy. Furthermore, the binding of the ferrocene-polyamides to DNA duplexes immobilized to a gold electrode was detected by cyclic voltammetry (CV) experiments. The electrochemical studies revealed that the fully matched DNA duplex having a GCG sequence showed the largest electric current, and the introduction of a mismatch site decreased the current significantly. These results suggested the potential of the ferrocene-polyamide compounds as new electrochemical ligands for electrochemical SNPs detection.

Screening of HIV-1 Isolates by Reverse Heteroduplex Mobility Assay and Identification of Non-B Subtypes in Italy

OBJECTIVE

The increasing prevalence of HIV-1 transmission through heterosexual contacts and the growing number of immigrants from non-Western countries, where non-B subtypes and recombinant forms are prevalent, suggest the possible emergence in Italy of a new epidemic wave of HIV-1 non-B subtypes as well as recombinant forms.

METHODS

The distribution of HIV-1 subtypes has been evaluated in 63 seropositive individuals residing in Italy, most of whom were infected through a sexual route during the last 5 years. A modified heteroduplex mobility assay (HMA) strategy, reverse HMA (rHMA), has been developed in our laboratory, allowing rapid identification of divergent-from-B-subtype isolates, which have been subsequently characterized by detailed molecular and phylogenetic analyses.

RESULTS

Five samples show, on rHMA, an electrophoretic pattern compatible with a non-B subtype classification. Their phylogenetic analysis, performed on both env and gag regions, confirms the rHMA subtyping prediction, given that 3 samples fall into the "A-family" subtype and 2 into the G subtype. The 5 non-B-subtype HIV-1 isolates have been identified among 23 variants (prevalence, 21.74%) isolated during the 2000 to 2001 period in heterosexuals. In parallel, B-subtype isolates show high levels of intrasubtype nucleotide divergence, compatible with a constant HIV-1 molecular diversification.

CONCLUSION

The Italian HIV-1 epidemic is still mostly attributable to the B subtype, which shows an increasing nucleotide heterogeneity. Heterosexual transmission and the interracial blending, however, are slowly introducing novel HIV-1 subtypes, and the data indicate that rHMA represents a powerful tool for HIV-1 biomolecular screening in epidemics characterized by a mono-/dual-subtype predominance.

Enzymatically Amplified Surface Plasmon Resonance Imaging Method Using RNase H and RNA Microarrays for the Ultrasensitive Detection of Nucleic Acids

A novel surface enzymatic amplification method that utilizes RNA microarrays in conjunction with the enzyme RNase H is developed for the ultrasensitve detection and analysis of target DNA molecules. The enzyme RNase H is shown to selectively and repeatedly destroy RNA from RNA-DNA heteroduplexes on gold surfaces; when used in conjunction with the label-free technique of surface plasmon resonance imaging, multiple DNA targets can be detected at a concentration of 10 fM on a single chip. In addition, this method is utilized for the sequence-specific detection of the TSPY gene in both purified and unpurified PCR products. Finally, in a series of kinetics measurements, the initial rate of hydrolysis is shown to depend directly on the surface concentration of DNA-RNA heteroduplexes.

The human T locus and spina bifida risk

The transcription factor T is essential for mesoderm formation and axial development during embryogenesis. Embryonic genotype for a single-nucleotide polymorphism in intron 7 of T ( TIVS7 T/C) has been associated with the risk of spina bifida in some but not all studies. We developed a novel genotyping assay for the TIVS7 polymorphism using heteroduplex generator methodology. This assay was used to genotype spina bifida case-parent trios and the resulting data were analyzed using the transmission disequilibrium test and log-linear analyses. Analyses of these data demonstrated that heterozygous parents transmit the TIVS7-C allele to their offspring with spina bifida significantly more frequently than expected under the assumption of Mendelian inheritance (63 vs 50%, P=0.02). Moreover, these analyses suggest that the TIVS7-C allele acts in a dominant fashion, such that individuals carrying one or more copies of this allele have a 1.6-fold increased risk of spina bifida compared with individuals with zero copies. In silico analysis of the sequence surrounding this polymorphism revealed a potential target site for olfactory neuron-specific factor-1, a transcription factor expressed in the neural tube during development, spanning the polymorphic site. Several other putative, developmentally important and/or environmentally responsive transcription factor-binding sites were also identified close to the TIVS7 polymorphism. The TIVS7 polymorphism or a variant that is in linkage disequilibrium with the TIVS7 polymorphism may, therefore, play a role in T gene expression and influence the risk of spina bifida.

Sequencing-based detection of low-frequency human immunodeficiency virus type 1 drug-resistant mutants by an RNA/DNA heteroduplex generator-tracking assay

Drug-resistant viruses may be present as minority variants during early treatment failures or following discontinuation of failed antiretroviral regimens. A limitation of the traditional direct PCR population sequencing method is its inability to detect human immunodeficiency virus type 1 (HIV-1) variants present at frequencies lower than 20%. A drug resistance genotyping assay based on the isolation and DNA sequencing of minority HIV protease variants is presented here. A multiple-codon-specific heteroduplex generator probe was constructed to improve the separation of HIV protease genes varying in sequence at 12 codons associated with resistance to protease inhibitors. Using an RNA molecule as probe allowed the simple sequencing of protease variants isolated as RNA/DNA heteroduplexes with different electrophoretic mobilities. The protease gene RNA heteroduplex generator-tracking assay (RNA-HTA) was tested on plasma quasispecies from 21 HIV-1-infected persons in whom one or more protease resistance mutations emerged during therapy or following initiation of salvage regimens. In 11 of 21 cases, RNA-HTA testing of virus from the first episode of virologic failure identified protease resistance mutations not seen by population-based PCR sequencing. In 8 of these 11 cases, all of the low-frequency drug resistance mutations detected exclusively by RNA-HTA during the first episode became detectable by population-based PCR sequencing at the later time point. Distinct sets of protease mutations could be linked on different genomes in patients with high-frequency protease gene lineages. The enhanced detection of minority drug resistance variants using a sequencing-based assay may improve the efficacy of genotype-assisted salvage therapies.

Interaction of Nick-directed DNA Mismatch Repair and Loop Repair in Human Cells

In human cells, large DNA loop heterologies are repaired through a nick-directed pathway independent of mismatch repair. However, a 3'-nick generated by bacteriophage fd gene II protein heterology is not capable of stimulating loop repair. To evaluate the possibility that a mismatch near a loop could induce both repair types in human cell extracts, we constructed and tested a set of DNA heteroduplexes, each of which contains a combination of mismatches and loops. We have demonstrated that a strand break generated by restriction endonucleases 3' to a large loop is capable of provoking and directing loop repair. The repair of 3'-heteroduplexes in human cell extracts is very similar to that of 5'-heteroduplex repair, being strand-specific and highly biased to the nicked strand. This observation suggests that the loop repair pathway possesses bidirectional repair capability similar to that of the bacterial loop repair system. We also found that a nick 5' to a coincident mismatch and loop can apparently stimulate the repair of both. In contrast, 3'-nick-directed repair of a G-G mismatch was reduced when in the vicinity of a loop (33 or 46 bp between two sites). Increasing the distance separating the G-G mismatch and loop by 325 bp restored the efficiency of repair to the level of a single base-base mismatch. This observation suggests interference between 3'-nick-directed large loop repair and conventional mismatch repair systems when a mispair is near a loop. We propose a model in which DNA repair systems avoid simultaneous repair at adjacent sites to avoid the creation of double-stranded DNA breaks.

Gene targeting in Drosophila

DNA double-strand breaks provide a powerful means to modify the genome. This chapter describes how to generate and use these breaks to target specific sequences, or other modifications to the Drosophila genome. Both P element dependent gene conversion, in which the chromosomal DNA is broken, and the Rong and Golic gene-targeting technique, in which the targeting vector contains the DNA break are explained. The strengths and limitations of both methods are presented so that the user can choose the appropriate method for their particular situation. The efficiency of both methods depends upon the genomic location being modified, although few, if any, genomic locations are refractory to either method. It cannot be emphasized strongly enough that the investigator should be prepared to invest sufficient time into setting up and running these experiments properly.

Unfaithful DNA polymerase caught in the act

The 3D structures of all 12 mispairs formed in the active site of a DNA polymerase help explain their differential effects on polymerase stalling and on translocation of the primer terminus to the enzyme's proofreading site.

Solution structure of a DNA duplex containing an alpha-anomeric adenosine: insights into substrate recognition by endonuclease IV

The cytotoxic alpha anomer of adenosine, generated in situ by radicals, must be recognized and repaired to maintain genomic stability. Endonuclease IV (Endo IV), a member of the base excision repair (BER) enzyme family, in addition to acting on abasic sites, has the auxiliary function of removing this mutagenic nucleotide in Escherichia coli. We have employed enzymatic, thermodynamic, and structural studies on DNA duplexes containing a central alpha-anomeric adenosine residue to characterize the role of DNA structure on recognition and catalysis by Endo IV. The enzyme recognizes and cleaves our alphaA-containing DNA duplexes at the site of the modification. The NMR solution structure of the DNA decamer duplex establishes that the single alpha-anomeric adenosine residue is intrahelical and stacks in a reverse Watson-Crick fashion consistent with the slight decrease in thermostability. However, the presence of this lesion confers significant changes to the global duplex conformation, resulting from a kink of the helical axis into the major groove and an opening of the minor groove emanating from the alpha-anomeric site. Interestingly, the conformation of the flanking base-paired segments is not greatly altered from a B-type conformation. The global structural changes caused by this lesion place the DNA along the conformational path leading to the DNA structure observed in the complex. Thus, it appears that the alpha-anomeric lesion facilitates recognition by Endo IV.

FinO is an RNA chaperone that facilitates sense-antisense RNA interactions

The protein FinO represses F-plasmid conjugative transfer by facilitating interactions between the mRNA of the major F-plasmid transcriptional activator, TraJ, and an antisense RNA, FinP. FinO is known to bind stem-loop structures in both FinP and traJ RNAs; however, the mechanism by which FinO facilitates sense-antisense pairing is poorly understood. Here we show that FinO acts as an RNA chaperone to promote strand exchange and duplexing between minimal RNA targets derived from FinP. This strongly suggests that FinO may function to destabilize internal secondary structures within FinP and traJ RNAs that would otherwise act as a kinetic trap to sense-antisense pairing. The energy for FinO-catalyzed base-pair destabilization does not arise from ATP hydrolysis but appears to be supplied directly from FinO RNA binding free energy. An analysis of the activities of mutants that are specifically deficient in strand exchange but not RNA-binding activity demonstrates that strand exchange is essential to the ability of FinO to mediate sense-antisense RNA recognition, and that this function also plays a role in repression of conjugation in vivo.

Diagnostic difficulties with common SURF1 mutations in patients with cytochrome oxidase-deficient Leigh syndrome

In three unrelated patients with systemic cytochrome oxidase deficiency resulting from mutations in the SURF1 gene, the same mutation in the splice donor site of intron 3 was identified. All three patients were compound heterozygotes, two for the common insertion/deletion mutation in exon 4. In all three cases, complete definition of the causative mutations was only resolved by combined analysis of cDNA and genomic DNA. Several factors were identified that contributed to the diagnostic difficulties: preferential amplification of deleted cDNA, significant formation of heteroduplexes in cDNA PCR amplification and unequal representation of heterozygous peaks in genomic DNA sequences. These patients emphasize the need to perform mutation analysis on both cDNA and genomic DNA wherever possible.

Integration of combined heteroduplex/restriction fragment length polymorphism analysis on an electrophoresis microchip for the detection of hereditary haemochromatosis

This work describes an integrated method of enzymatic digestion, heteroduplex analysis (HA) and electrophoretic sizing on a microfluidic chip. HA techniques based on microchip electrophoresis are capable of the high sensitivity detection of subtle mutations such as single nucleotide polymorphisms (SNPs) but are not readily able to detect homozygous mutant genotypes. Such homozygous conditions are commonly encountered with the gene implicated in hereditary haemochromatosis, HFE. We employed the restriction fragment length polymorphism (RFLP) method of mutation detection to complement the HA method in a rapid novel on-chip procedure that separated digested PCR fragments to reliably determine the presence or absence of the most important mutations associated with haemochromatosis. This method was able to distinguish the homozygous mutant, heterozygous and homozygous wildtype genotypes. The mutations investigated here (C282Y, H63D and S65C) are often the mutation targets used in the genetic testing for haemochromatosis. This method provides the extremely specific digestion methods needed for the analysis of the known and relatively common mutations that have a significant probability of occurring in a homozygous form. However, the high sensitivity of the HA method is useful in detecting other mutations of lesser likelihood which, by virtue of their rarity, are likely to be present only in a heterozygous form. Although the conventional methods of analysing these mutations require as much as a day to perform, this microchip method, even without robotics or multiplexed operation, can be performed in about 10 min per sample.

Preparation of interstrand cross-linked DNA oligonucleotide duplexes

Reaction of cellular DNA with environmental and chemotherapeutic agents can give rise to a variety of lesions including interstrand cross-links. Because interstrand cross-links can prevent DNA strand separation and thus DNA transcription and replication, they represent a serious impediment to cell survival. Cells have developed mechanisms to repair interstrand cross-links in their DNA and in the case of tumor cells, this can lead to resistance to chemotherapeutic agents. Efforts to investigate the mechanisms by which interstrand cross-links are repaired have been hampered by the difficulty of preparing sufficient quantities of well characterized substrates for physical and biochemical studies. This review will describe synthetic strategies that have been developed to synthesize short DNA oligonucleotide duplexes that contain interstrand cross-links. These short duplexes can be used to study the effects of the cross-link on DNA structure or they can be ligated with larger DNA molecules to produce substrates for repair studies. This review will focus on examples of cross-linked duplexes that have been designed specifically to further our understanding of interstrand cross-link structure and repair.