The contrasting structures of mismatched DNA sequences containing looped-out bases (bulges) and multiple mismatches (bubbles)

Interaction of dinuclear Co(III) cylinders with higher-order DNA structures

Alternative DNA structures play critical roles in fundamental biological processes linked to human diseases. Thus, targeting and stabilizing these structures by specific ligands could affect the progression of cancer and other diseases. Here, we describe, using methods of molecular biophysics, the interactions of two oxidatively locked [Co2L3]6+ cylinders, rac-2 and meso-1, with diverse alternative DNA structures, such as junctions, G quadruplexes, and bulges. This study was motivated by earlier results demonstrating that both Co(III) cylinders exhibit potent and selective activity against cancer cells, accumulate in the nucleus of cancer cells, and prove to be efficient DNA binders. The results show that the bigger cylinder rac-2 stabilizes all DNA structures, while the smaller cylinder meso-1 stabilizes just the Y-shaped three-way junctions. Collectively, the results of this study suggest that the stabilization of alternative DNA structures by Co(III) cylinders investigated in this work might contribute to the mechanism of their biological activity.

A pair of primers facing at the double-strand break site enables to detect NHEJ-mediated indel mutations at a 1-bp resolution

The introduction of small insertion/deletion (indel) mutations in the coding region of genes by the site-specific nucleases such as Cas9 allows researchers to obtain frameshift null mutants. Technically simple and costly reasonable genotyping methods are awaited to efficiently screen the frameshift null mutant candidates. Here, we developed a simple genotyping method called DST-PCR (Double-strand break Site-Targeted PCR) using “face-to-face” primers where the 3’ ends of forward and reverse primers face each other at the position between 3-bp and 4-bp upstream of the PAM sequence, which is generally the Cas9-mediated double-strand break site. Generated amplicons are directly subjected to TBE-High-Resolution PAGE, which contains a high concentration of bis-acrylamide, for mutant clones detection with 1-bp resolution. We present actual cases of screening of CRISPR/Cas9-engineered knockout (KO) cells for six genes, where we screen indels to obtain potential KO cell clones utilizing our approach. This method allowed us to detect 1-bp to 2-bp insertion and 1-bp to 4-bp deletion in one or both alleles of mutant cell clones. In addition, this technique also allowed the identification of heterozygous and homozygous biallelic functional KO candidates. Thus, DST-PCR is a simple and fast method to screen KO candidates generated by the CRISPR/Cas9 system before the final selection of clones with sequencing.

PRIMA: a rapid and cost-effective genotyping method to detect single-nucleotide differences using probe-induced heteroduplexes

Targeted mutagenesis by programmable site-specific nucleases like CRISPR typically produce 1-base pair (bp) insertion or deletion (indel) mutations. Although several methods have been developed to detect such 1-bp indels, each method has pros and cons in terms of cost and/or resolution. Heteroduplex mobility assay (HMA) is a traditional technique detecting small base pair differences but it has a limited resolution of mutation size and the band patterns are often complex. Here, we developed a new method called PRIMA (Probe-Induced HMA) using a short single-stranded DNA molecule as a probe in HMA. By utilizing a 40-mer probe containing a 5-nucleotide deletion, we assessed the mobility of a heteroduplex with a target DNA fragment from a plant, bacterium, and human. This method allowed us to detect a 1-bp indel mutation consistently. We also showed that SNPs can be detected using PRIMA. PRIMA provides a rapid and cost-effective solution for the genotyping.

Increasing the length of poly-pyrimidine bulges broadens RNA conformational ensembles with minimal impact on stacking energetics

Helical elements separated by bulges frequently undergo transitions between unstacked and coaxially stacked conformations during the folding and function of noncoding RNAs. Here, we examine the dynamic properties of poly-pyrimidine bulges of varying length (n = 1-4, 7) across a range of Mg²⁺ concentrations using HIV-1 TAR RNA as a model system and solution NMR spectroscopy. In the absence of Mg²⁺, helices linked by bulges with n ≥ 3 residues adopt predominantly unstacked conformations (stacked population <15%), whereas one-bulge and two-bulge motifs adopt predominantly stacked conformations (stacked population >74%). In the presence of 3 mM Mg²⁺, the helices predominantly coaxially stack (stacked population >84%), regardless of bulge length, and the midpoint for the Mg²⁺-dependent stacking transition is within threefold regardless of bulge length. In the absence of Mg²⁺, the difference between free energy of interhelical coaxial stacking across the bulge variants is estimated to be ∼2.9 kcal/mol, based on an NMR chemical shift mapping with stacking being more energetically disfavored for the longer bulges. This difference decreases to ∼0.4 kcal/mol in the presence of Mg²⁺ NMR RDCs and resonance intensity data show increased dynamics in the stacked state with increasing bulge length in the presence of Mg²⁺ We propose that Mg²⁺ helps to neutralize the growing electrostatic repulsion in the stacked state with increasing bulge length thereby increasing the number of coaxial conformations that are sampled. Energetically compensated interhelical stacking dynamics may help to maximize the conformational adaptability of RNA and allow a wide range of conformations to be optimally stabilized by proteins and ligands.

The sequence preference of DNA cleavage by T4 endonuclease VII

The enzyme T4 endonuclease VII is a resolvase that acts on branched DNA intermediates during genetic recombination, by cleaving DNA with staggered cuts approximately 3-6 bp apart. In this paper, we investigated the sequence preference of this cleavage reaction utilising two different DNA sequences. For the first time, the DNA sequence preference of T4 endonuclease VII cleavage sites has been examined without the presence of a known DNA substrate to mask any inherent nucleotide preference. The use of the ABI3730 platform enables the cleavage site to be determined at nucleotide resolution. We found that T4 endonuclease VII cleaves DNA with a sequence preference. We calculated the frequency of nucleotides surrounding the cleavage sites and found that following nucleotides had the highest incidence: AWTAN*STC, where N* indicates the cleavage site between positions 0 and 1, N is any base, W is A or T, and S is G or C. An A at position -1 and T at position +2 were the most predominant nucleotides at the cleavage site. Using a Sequence Logo method, the sequence TATTAN*CT was derived at the cleavage site. Note that A and T nucleotides were highly preferred 5' to the cleavage sites in both methods of analysis. It was proposed that the enzyme recognises the narrower minor groove of these consecutive AT base pairs and cleaves DNA 3' to this feature.

Mutations in the Juxtamembrane Domain of c-KIT Are Associated with Higher Grade Mast Cell Tumors in Dogs

Mast cell tumors are among the most commonly seen tumors of the skin in dogs and are more highly aggressive than mast cell tumors of other species. Some breeds display a markedly higher incidence of mast cell tumor development than others and appear to have some genetic predisposition. Recently, mutations have been found in canine mast cell tumor tissues and cell lines within the juxtamembrane domain of the protooncogene c- KIT. In previous studies utilizing a small number of cases, no association between the presence of a mutation and the breed of dog or grade of the tumor could be identified. An expanded study with a larger sample set was performed to explore this possibility. The juxtamembrane domain of c- KIT was amplified using the polymerase chain reaction from genomic DNA preparations of 88 paraffin-embedded mast cell tumors from selected breeds. Mutations, consisting of duplications and deletions, were found in 12 of the tumors. A significant association was found between the presence of a mutation and a higher grade of tumor but not between breed and grade or between breed and the presence of a mutation.

Rational design of a quantitative, pH-insensitive, nucleic acid based fluorescent chloride reporter

Chloride plays a major role in cellular homeostasis by regulating the lumenal pH of intracellular organelles. We have described a pH-independent, fluorescent chloride reporter called Clensor that has successfully measured resting chloride in organelles of living cells. Here, we describe the rational design of Clensor. Clensor integrates a chloride sensitive fluorophore called 10,10'-bis[3-carboxypropyl]-9,9'-biacridinium dinitrate (BAC) with the programmability, modularity and targetability available to nucleic acid scaffolds. We show that simple conjugation of BAC to a DNA backbone fails to yield a viable chloride-sensitive reporter. Fluorescence intensity and lifetime investigations on a series of BAC-functionalized structural variants yielded molecular insights that guided the rational design and successful realization of the chloride sensitive fluorescent reporter, Clensor. This study provides some general design principles that would aid the realization of diverse ion-sensitive nucleic acid reporters based on the sensing strategy of Clensor.

Analysis of DNA structure and sequence requirements for Pseudomonas aeruginosa MutL endonuclease activity

The hallmark of the mismatch repair system in bacterial and eukaryotic organisms devoid of MutH is the presence of a MutL homologue with endonuclease activity. The aim of this study was to analyse whether different DNA structures affect Pseudomonas aeruginosa MutL (PaMutL) endonuclease activity and to determine if a specific nucleotide sequence is required for this activity. Our results showed that PaMutL was able to nick covalently closed circular plasmids but not linear DNA at high ionic strengths, while the activity on linear DNA was only found below 60 mM salt. In addition, single strand DNA, ss/ds DNA boundaries and negatively supercoiling degree were not required for PaMutL nicking activity. Finally, the analysis of the incision sites revealed that PaMutL, as well as Bacillus thuringiensis MutL homologue, did not show DNA sequence specificity.

High prevalence of B and G aflatoxin-producing fungi in sugarcane field soil in Japan: heteroduplex panel analysis identifies a new genotype within Aspergillus Section Flavi and Aspergillus nomius

Heteroduplex panel analysis (HPA) was previously developed for genetic identification of Aspergillus Section Flavi strains, utilizing polymerase chain reaction-amplified fragments of the internal transcribed spacer (ITS) regions of the rRNA gene. Application of HPA to a field study demonstrated that a new type of FP-1 strains belonging to Section Flavi is predominantly distributed throughout sugarcane field soil in the southernmost islands of Japan, and such a trend may also be the case in Vietnam. All of the 71 tested isolates of type FP-1 were able to produce aflatoxins B and G. The morphological observations of the type FP-1 isolates showed that a major part of them had broad interfaces with Aspergillus parasiticus and the remainder with Aspergillus flavus. Phylogenetic analysis based on the ITS sequences indicated that type FP-1 formed an independent clade positioned between A. parasiticus and A. flavus, and was more closely related to the former species. This is also the first report on the distribution of Aspergillus nomius in sugarcane field soil and/or sugarcane stems in Japan and Vietnam.

Stiffened yeast telomerase RNA supports RNP function in vitro and in vivo

The 1157-nt Saccharomyces cerevisiae telomerase RNA, TLC1, in addition to providing a 16-nt template region for reverse transcription, has been proposed to act as a scaffold for protein subunits. Although accessory subunits of the telomerase ribonucleoprotein (RNP) complex function even when their binding sites are relocated on the yeast telomerase RNA, the physical nature of the RNA scaffold has not been directly analyzed. Here we explore the structure-function organization of the yeast telomerase RNP by extensively stiffening the three long arms of TLC1, which connect essential and important accessory protein subunits Ku, Est1, and Sm(7), to its central catalytic hub. This 956-nt triple-stiff-arm TLC1 (TSA-T) reconstitutes active telomerase with TERT (Est2) in vitro. Furthermore, TSA-T functions in vivo, even maintaining longer telomeres than TLC1 on a per RNA basis. We also tested functional contributions of each stiffened arm within TSA-T and found that the stiffened Est1 and Ku arms contribute to telomere lengthening, while stiffening the terminal arm reduces telomere length and telomerase RNA abundance. The fact that yeast telomerase tolerates significant stiffening of its RNA subunit in vivo advances our understanding of the architectural and functional organization of this RNP and, more broadly, our conception of the world of lncRNPs.

A novel denaturing heteroduplex tracking assay for genotypic prediction of HIV-1 tropism

Human immunodeficiency virus type 1 (HIV-1) is characterized by sequence variability. The third variable region (V3) of the HIV-1 envelope glycoprotein gp120 plays a key role in determination of viral coreceptor usage (tropism) and pathogenesis. This report describes a novel denaturing heteroduplex tracking assay (HTA) to analyze the genetic variation of HIV-1 V3 DNA. It improved upon previous non-denaturing HTA approaches to distinguish HIV-1 CCR5 and CXCR4 tropic viruses in mixed populations. The modifications included the use of a single-stranded fluorescent probe based on the consensus V3 sequence of HIV-1 CCR5 tropic viruses, Locked Nucleic Acid (LNA) "clamps" at both ends of heteroduplex DNA, and denaturing gel electrophoresis using Mutation Detection Enhancement (MDE(®)) as matrix. The analysis demonstrated that the LNA "clamps" increased its melting temperature (T(m)) and the thermal stability of heteroduplex DNA. The partially denaturing gel used a defined concentration of formamide, and significantly induced mobility shifts of heteroduplex DNA that was dependent on the number and patterns of DNA mismatches and insertions/deletions. This new technique successfully detected tropisms of 53 HIV-1 V3 clones of known tropism, and was able to separate and detect multiple V3 DNA variants encoding tropisms for CCR5 or CXCR4 in a mixture. The assay had the sensitivity to detect 0.5% minority species. This method may be useful as a research tool for analysis of viral quasispecies and for genotypic prediction of HIV-1 tropism in clinical specimens.

Conformation and dynamics of nucleotides in bulges and symmetric internal loops in duplex DNA studied by EPR and fluorescence spectroscopies

The dynamics and conformation of base bulges and internal loops in duplex DNA were studied using the bifunctional spectroscopic probe Ç, which becomes fluorescent (Ç(f)) upon reduction of the nitroxide functional group, along with EPR and fluorescence spectroscopies. A one-base bulge was in a conformational equilibrium between looped-out and stacked states, the former favored at higher temperature and the latter at lower temperature. Stacking of bulge bases was favored in two- and three-base bulges, independent of temperature, resulting in DNA bending as evidenced by increased fluorescence of Ç(f). EPR spectra of Ç-labeled three-, four- and five-base symmetrical interior DNA bulges at 20 °C showed low mobility, indicating that the spin-label was stacked within the loop. The spin-label mobility at 37 °C increased as the loops became larger. A considerable variation in fluorescence between different loops was observed, as well as a temperature-dependence within constructs. Fluorescence unexpectedly increased as the size of the loop decreased at 2 °C. Fluorescence of the smallest loops, where a single T·T mismatch was located between the stem region and the probe, was even larger than for the single strand, indicating a considerable local structural deformation of these loops from regular B-DNA. These results show the value of combining EPR and fluorescence spectroscopy to study non-helical regions of nucleic acids.

New insights into the fundamental role of topological constraints as a determinant of two-way junction conformation

Recent studies have shown that topological constraints encoded at the RNA secondary structure level involving basic steric and stereochemical forces can significantly restrict the orientations sampled by helices across two-way RNA junctions. Here, we formulate these topological constraints in greater quantitative detail and use this topological framework to rationalize long-standing but poorly understood observations regarding the basic behavior of RNA two-way junctions. Notably, we show that the asymmetric nature of the A-form helix and the finite length of a bulge provide a physical basis for the experimentally observed directionality and bulge-length amplitude dependence of bulge induced inter-helical bends. We also find that the topologically allowed space can be modulated by variations in sequence, particularly with the addition of non-canonical GU base pairs at the junction, and, surprisingly, by the length of the 5′ and 3′ helices. A survey of two-way RNA junctions in the protein data bank confirms that junction residues have a strong preference to adopt looped-in, non-canonically base-paired conformations, providing a route for extending our bulge-directed framework to internal loop motifs and implying a simplified link between secondary and tertiary structure. Finally, our results uncover a new simple mechanism for coupling junction-induced topological constraints with tertiary interactions.

Canine and human gastrointestinal stromal tumors display similar mutations in c-KIT exon 11

Background

Gastrointestinal stromal tumors (GISTs) are common mesenchymal neoplasms in the gastrointestinal tract of humans and dogs. Little is known about the pathogenesis of these tumors. This study evaluated the role of c-KIT in canine GISTs; specifically, we investigated activating mutations in exons 8, 9, 11, 13, and 17 of c-KIT and exons 12, 14, and 18 of platelet-derived growth factor receptor, alpha polypeptide (PDGFRA), all of which have been implicated in human GISTs.

Methods

Seventeen canine GISTs all confirmed to be positive for KIT immunostaining were studied. Exons 8, 9, 11, 13 and 17 of c-KIT and exons 12, 14, and 18 of PDGFRA, were amplified from DNA isolated from formalin-fixed paraffin-embedded samples.

Results

Of these seventeen cases, six amplicons of exon 11 of c-KIT showed aberrant bands on gel electrophoresis. Sequencing of these amplicons revealed heterozygous in-frame deletions in six cases. The mutations include two different but overlapping six base pair deletions. Exons 8, 9, 13, and 17 of c-KIT and exons 12, 14, and 18 of PDGFRA had no abnormalities detected by electrophoresis and sequencing did not reveal any mutations, other than synonymous single nucleotide polymorphisms (SNPs) found in exon 11 of c-KIT and exons 12 and 14 of PDGFRA.

Conclusions

The deletion mutations detected in canine GISTs are similar to those previously found in the juxtamembrane domain of c-KIT in canine cutaneous mast cell tumors in our laboratory as well as to those reported in human GISTs. Interestingly, none of the other c-KIT or PDGFRA exons showed any abnormalities in our cases. This finding underlines the critical importance of c-KIT in the pathophysiology of canine GISTs. The expression of KIT and the identification of these activating mutations in c-KIT implicate KIT in the pathogenesis of these tumors. Our results indicate that mutations in c-KIT may be of prognostic significance and that targeting KIT may be a rational approach to treatment of these malignant tumors. This study further demonstrates that spontaneously occurring canine GISTs share molecular features with human GISTs and are an appropriate model for human GISTs.

Barcode-like heteroduplex DNA pattern as an aid for rapid identification of anthracnose fungi

We have shown the usefulness of the heteroduplex mobility assay (HMA) for phylogenetic analysis and for the discrimination of closely related Colletotrichum species. Because the heteroduplex mobility of a tested strain shows a unique banding pattern that is the function of the sequence of the referred strain, we further explored the potential use of heteroduplex DNA patterns (HPs) as DNA fingerprints for the identification of these fungi. The 29 Colletotrichum strains previously identified by HMA to be taxonomic members of CG, CA, CM, CC and CL species groups were re-examined with an emphasis on their unique heteroduplex banding patterns. The species attributes of these tested strains were characterized by HMA using ITS fragments amplified from six representative Colletotrichum strains as pairwise compared references. By comparing the unique homoduplex and heteroduplex banding patterns of each tested strain on a polyacrylamide gel with those of the respective reference strain, the species identity of tested strains was determined. The obtained barcode-like HPs classified these 29 Colletotrichum strains into 6 distinctive groups: CG1, CG2, CA, CM, CC and CL. Notably, the HPs differentiated strains CG1 and CG2, which differed in their ITS sequences by only six bases. The presented results revealed that the species-characteristic barcode-like HP classification of ITS regions is a relatively rapid and valuable system for species identification of Colletotrichum species. The potential use of the established barcode-like system for the identification of anthracnose fungi and other fungal pathogens is discussed.

Binding of a Flexibly-linked Dinuclear Ruthenium(II) Complex to Adenine-bulged DNA Duplexes

Using 1H NMR spectroscopy and molecular modelling, the DNA binding of a chiral dinuclear ruthenium(ii) complex {Δ,Δ-[{Ru(phen)2}2(μ-bb7)]4+; phen = 1,10-phenanthroline, bb7 = 1,7-bis[4(4′-methyl-2,2′-bipyridyl)]-heptane} involving a bridging ligand containing a flexible aliphatic chain has been studied. The binding of the ruthenium(ii) complex was examined with the non-self-complementary duplexes d(CCGAGAATCGGCC):d(GGCCGATTCCGG) (containing a single adenine bulge: designated SB) and d(CCGAGCCGTGCC):d(GGCACGAGCCGG) (containing two adenine bulge sites separated by two base-pairs: designated DB). The NMR data indicated that the ruthenium(ii) complex bound at the bulge site of SB, with one ruthenium centre located at the bulge site with the second metal centre binding with lower affinity and selectivity in the duplex region adjacent to the bulge site. Less specific binding is inferred from chemical shift changes of nucleotide protons two to five base pairs from the single adenine bulge. The ruthenium(ii) complex selectively bound the DB duplex with one metal centre located at each bulge site. The NMR results also suggested that the metal complex binding induced greater changes to the structure of the SB duplex, compared with the DB duplex. Modelling indicates the bridging ligand allowed each ruthenium(ii) metal centre to bind one adenine bulge of the doubly-bulged duplex without disrupting the DNA structure, using the additional torsional flexibility conferred by the aliphatic bridging ligand. However, the second ruthenium(ii) metal centre is not able to bind in the minor groove of the singly-bulged duplex without disrupting the structure, as the metal centre is too bulky. The results of this study suggest dinuclear ruthenium(ii) complexes have considerable potential as probes for DNA and RNA sequences that contain two bulge sites separated by a small number of base-pairs.

[Bent dsDNA with defined geometric characteristics in terms of complexes of bridged oligonucleotides]

An opportunity of designing nontypical double-stranded DNA structures containing nonnatural inserts in a regular nucleotide DNA sequence has been investigated. The looped nucleotide inserts on the basis of adenylates and thymidilates, and nonnucleotide inserts on the basis of phosphodiesters of diethyleneglycol, 1,10-decanediol, and 3-hydroxy-2-hudroxymethyltetrahydrofuran were introduced into the backbone of a 32-mer native DNA duplex. These inserts formed the internal loops in the modified double-stranded DNA fragments which were shown to lead to bending of the linear duplex structure by 16 to 83 degrees. The dependencies of the bend angle of dsDNA on the composition and the length of the looped regions were determined. It was established that the bend of the irregular region of dsDNA depended on the electrostatic interaction of the phosphate residues. The tension in the complex structure could be reduced by the introduction of additional nucleotide units opposite the loop, which led to some relaxation of the bent helix. The resulting parameters of the bend values were shown to be in a good agreement with the published data obtained by NMR spectroscopy. It was demonstrated that the variation of the nature or the length of the insert allowed one to regulate the level of the local perturbation of the duplex structure and, thereby, influence both the bend level of the double helix and the destabilization of the modified complex.

Analysis of branched nucleic acid structure using comparative gel electrophoresis

Electrophoresis in polyacrylamide gels provides a simple yet powerful means of analyzing the relative disposition of helical arms in branched nucleic acids. The electrophoretic mobility of DNA or RNA with a central discontinuity is determined by the angle subtended between the arms radiating from the branchpoint. In a multi-helical branchpoint, comparative gel electrophoresis can provide a relative measure of all the inter-helical angles and thus the shape and symmetry of the molecule. Using the long-short arm approach, the electrophoretic mobility of all the species with two helical arms that are longer than all others is compared. This can be done as a function of conditions, allowing the analysis of ion-dependent folding of branched DNA and RNA species. Notable successes for the technique include the four-way (Holliday) junction in DNA and helical junctions in functionally significant RNA species such as ribozymes. Many of these structures have subsequently been proved correct by crystallography or other methods, up to 10 years later in the case of the Holliday junction. Just as important, the technique has not failed to date. Comparative gel electrophoresis can provide a window on both fast and slow conformational equilibria such as conformer exchange in four-way DNA junctions. But perhaps the biggest test of the approach has been to deduce the structures of complexes of four-way DNA junctions with proteins. Two recent crystallographic structures show that the global structures were correctly deduced by electrophoresis, proving the worth of the method even in these rather complex systems. Comparative gel electrophoresis is a robust method for the analysis of branched nucleic acids and their complexes.

Altered dynamics of DNA bases adjacent to a mismatch: a cue for mismatch recognition by MutS

The structural deviations as well as the alteration in the dynamics of DNA at mismatch sites are considered to have a crucial role in mismatch recognition followed by its repair utilizing mismatch repair family proteins. To compare the dynamics at a mismatch and a non-mismatch site, we incorporated 2-aminopurine, a fluorescent analogue of adenine next to a G.T mismatch, a C.C mismatch, or an unpaired T, and at several other non-mismatch positions. Rotational diffusion of 2-aminopurine at these locations, monitored by time-resolved fluorescence anisotropy, showed distinct differences in the dynamics. This alteration in the motional dynamics is largely confined to the normally matched base-pairs that are immediately adjacent to a mismatch/ unpaired base and could be used by MutS as a cue for mismatch-specific recognition. Interestingly, the enhanced dynamics associated with base-pairs adjacent to a mismatch are significantly restricted upon MutS binding, perhaps "resetting" the cues for downstream events that follow MutS binding. Recognition of such details of motional dynamics of DNA for the first time in the current study enabled us to propose a model that integrates the details of mismatch recognition by MutS as revealed by the high-resolution crystal structure with that of observed base dynamics, and unveils a minimal composite read-out involving the base mismatch and its adjacent normal base-pairs.

A loop loop interaction and a K-turn motif located in the lysine aptamer domain are important for the riboswitch gene regulation control

The lysine riboswitch is associated to the lysC gene in Bacillus subtilis, and the binding of lysine modulates the RNA structure to allow the formation of an intrinsic terminator presumably involved in transcription attenuation. The complex secondary structure of the lysine riboswitch aptamer is organized around a five-way junction that undergoes structural changes upon ligand binding. Using single-round transcription assays, we show that a loop-loop interaction is important for lysine-induced termination of transcription. Moreover, upon close inspection of the secondary structure, we find that an unconventional kink-turn motif is present in one of the stems participating in the loop-loop interaction. We show that the K-turn adopts a pronounced kink and that it binds the K-turn-binding protein L7Ae of Archaeoglobus fulgidus in the low nanomolar range. The functional importance of this K-turn motif is revealed from single-round transcription assays, which show its importance for efficient transcription termination. This motif is essential for the loop-loop interaction, and consequently, for lysine binding. Taken together, our results depict for the first time the importance of a K-turn-dependent loop-loop interaction for the transcription regulation of a lysine riboswitch.

Nucleosome Positioning Determinants

A previous report demonstrated that one site in a nucleosome assembled onto a synthetic positioning sequence known as Fragment 67 is hypersensitive to permanganate. The site is required for positioning activity and is located 1.5 turns from the dyad, which is a region of high DNA curvature in the nucleosome. Here, the permanganate sensitivity of the nucleosome positioning Fragment 601 was examined in order to expand the dataset of nucleosome sequences containing KMnO(4) hypersensitive sites. The hyperreactive T residue in the six sites detected as well as the one in Fragment 67 and three in the 5 S rDNA positioning sequence were contained within a TA step. Seven of the ten sequences were of the form CTAGPuG or the related sequence TTAAPu. These motifs were also found in the binding sites of several transcriptional regulatory proteins that kink DNA. In order to assess the significance of these sites, the 10 bp positioning determinant in Fragment 67 was removed and replaced by the nine sequences from the 5 S rDNA and Fragment 601. The results demonstrated that these derivative fragments promoted high nucleosome stability and positioning as compared to a control sequence that contained an AT step in place of the TA step. The importance of the TA step was further tested by making single base-pair substitutions in Fragment 67 and the results revealed that stability and positioning activity followed the order: TA>TG>TT>/=TC approximately GG approximately GA approximately AT. Sequences flanking the TA step were also shown to be critical for nucleosome stability and positioning. Nucleosome positioning was restored to near wild-type levels with (CTG)(3), which can form slipped stranded structures and with one base bulges that kink DNA. The results of this study suggest that local DNA structures are important for positioning and that single base-pair changes at these sites could have profound effects on those genomic functions that depend on ordered nucleosomes.

Affordable assays for genotyping single nucleotide polymorphisms in insects

Insect genome projects and DNA sequence databases are providing unprecedented amounts of information about variation at specific nucleotides in protein- and RNA-coding genes. Single nucleotide polymorphisms (SNPs) are abundant in all insect species so far examined and are proving useful in population genetics, linkage mapping and marker-assisted selection. A number of studies has already identified SNPs associated with insecticide resistance, especially mutations conferring reduced target site sensitivity. Unfortunately, most modern, high-throughput, automated SNP detection technologies are expensive or require the use of expensive equipment and are therefore not accessible to laboratories on a limited budget or to our colleagues in developing countries. In this review, we provide a chronological and comprehensive list of all SNP methods. We emphasize and explain those techniques in which genotypes can be identified by eye or that only require agarose gel electrophoresis. We provide examples where these techniques have or are currently being applied to insects.

Identification of Human Immunodeficiency Virus Type-1 Subtypes by Heteroduplex Mobility Assay

BACKGROUND

Human immunodeficiency virus type-1 (HIV-1) has developed marked genomic sequence differences over the course of an epidemic because of an error prone reverse transcriptase (RT), which rapidly incorporates mutations resulting in genomic diversity, altered cell tropism, immune escape and variable resistance to antiretroviral drugs. The best preventive strategy for HIV control is development of an efficacious prophylactic vaccine using the most appropriate (antigenically related) subtypes. On the basis of phylogenetic analysis, HIV strains can be separated into major group "M" consisting of genetic subtypes A-K, "N", the new group and "O", the outlier group.

METHODS

Heteroduplex mobility assay (HMA) is a rapid, economical and reliable technique of subtyping HIV-1. It is based on the principle of determining the genomic relatedness and divergence of the unknown sample with the known reference plasmid HIV-1 subtypes by studying the mobility patterns of the resulting heteroduplexes formed on the polyacrylamide gel.

RESULT

A total of 70 HIV-1 seropositive samples obtained from service personnel, their families and civilians from service hospitals were analyzed and their subtype distribution studied. 66 (94.28%) were HIV-1 subtype C and two (2.85%) subtype B. In two (2.85%) samples, the subtype distribution was homotypic recombinant, one each of subtype C1 & C2 and C2 & C4 respectively.

CONCLUSION

Service personnel and their families represent a divergent population from different regions of India. An analysis of subtypes in these HIV-1 seropositive individuals will help in understanding the geographical distribution and evolution of the virus. Determination of HIV-1 subtypes has significant implications for development of candidate vaccine for India.

Heteroduplex analysis of minisatellite variability

Minisatellites are tandem repeat arrays of middle size (5-100 bp) repeat units widely distributed in eukaryotic genomes. They have been related to several important features of human genome biology, including gene regulation, chromosomal fragile sites, and imprinting. In this report, we have critically assessed and employed heteroduplex analysis (HA) for the identification of different human minisatellite MsH43 alleles. This minisatellite is organized as a repeat array of 5-6 bp units spanning 0.5 kbp. Our results demonstrate that this procedure is an easy, rapid, and reliable method to document allelic diversity for this locus. This work suggests that HA will also be a useful tool for studying the polymorphism of other minisatellites with small repeat units.

Bulge defects do not destabilize negatively supercoiled DNA

The conformational properties of DNA lesions such as extrahelical bulges are presumed to be essential for recognition of defects in DNA structure by a cell's genomic repair machinery. Efficient recognition and repair of lesions by DNA-repair systems occurs despite the wide range of normal heterogeneities in DNA structure, including features such as sequence-dependent bends. The effects of global negative supercoiling on the structure of DNA lesions have been largely unexplored. We have investigated the behavior of several plasmid DNAs containing bulge defects with up to five extrahelical adenine residues. Using two-dimensional agarose-gel electrophoresis, we show that there is no spontaneous cooperative unwinding of these bulge loci up to native levels of negative supercoiling (sigma = -0.055) under our conditions.

DDB1-DDB2 (xeroderma pigmentosum group E) protein complex recognizes a cyclobutane pyrimidine dimer, mismatches, apurinic/apyrimidinic sites, and compound lesions in DNA

The DDB protein complex, comprising the subunits DDB1 and DDB2, binds tightly to UV light-irradiated DNA. Mutations in DDB2 are responsible for xeroderma pigmentosum group E, a disorder with defects in nucleotide excision repair of DNA. Both subunits are also components of a complex involved in ubiquitin-mediated proteolysis. Cellular defects in DDB2 disable repair of the major UV radiation photoproduct in DNA, a cyclobutane pyrimidine dimer, but no significant direct binding of DDB to this photoproduct in DNA has ever been demonstrated. Thus, it has been uncertain how DDB could play a specific role in DNA repair of such damage. We investigated DDB function using highly purified proteins. Co-purified DDB1-DDB2 or DDB reconstituted with individual DDB1 and DDB2 subunits binds to damaged DNA as a ternary complex. We found that DDB can indeed recognize a cyclobutane pyrimidine dimer in DNA with an affinity (K(app)a) 6-fold higher than that of nondamaged DNA. The DDB1-DDB2 complex also bound with high specificity to a UV radiation-induced (6-4) photoproduct and to an apurinic site in DNA. Unexpectedly, DDB also bound avidly to DNA containing a 2- or 3-bp mismatch (and does not bind well to DNA containing larger mismatches). These data indicate that DDB does not detect lesions per se. It instead recognizes other structural features of damaged DNA, acting as a sensor that probes DNA for a subset of conformational changes. Lesions recognized may include those arising when translesion polymerases such as POLH incorporate bases across from DNA lesions caused by UV radiation.

Intrinsic curvature in the VP1 gene of SV40: comparison of solution and gel results

DNA restriction fragments that are stably curved are usually identified by polyacrylamide gel electrophoresis because curved fragments migrate more slowly than normal fragments containing the same number of basepairs. In free solution, curved DNA molecules can be identified by transient electric birefringence (TEB) because they exhibit rotational relaxation times that are faster than those of normal fragments of the same size. In this article, the results observed in free solution and in polyacrylamide gels are compared for a highly curved 199-basepair (bp) restriction fragment taken from the VP1 gene in Simian Virus 40 (SV40) and various sequence mutants and insertion derivatives. The TEB method of overlapping fragments was used to show that the 199-bp fragment has an apparent bend angle of 46 +/- 2 degrees centered at sequence position 1922 +/- 2 bp. Four unphased A- and T-tracts and a mixed A3T4-tract occur within a span of approximately 60 bp surrounding the apparent bend center; for brevity, this 60-bp sequence element is called a curvature module. Modifying any of the A- or T-tracts in the curvature module by site-directed mutagenesis decreases the curvature of the fragment; replacing all five A- and T-tracts by random-sequence DNA causes the 199-bp mutant to adopt a normal conformation, with normal electrophoretic mobilities and birefringence relaxation times. Hence, stable curvature in this region of the VP1 gene is due to the five unphased A- and T- tracts surrounding the apparent bend center. Discordant solution and gel results are observed when long inverted repeats are inserted within the curvature module. These insertion derivatives migrate anomalously slowly in polyacrylamide gels but have normal, highly flexible conformations in free solution. Discordant solution and gel results are not observed if the insert does not contain a long inverted repeat or if the long inverted repeat is added to the 199-bp fragment outside the curvature module. The results suggest that long inverted repeats can form hairpins or cruciforms when they are located within a region of the helix backbone that is intrinsically curved, leading to large mobility anomalies in polyacrylamide gels. Hairpin/cruciform formation is not observed in free solution, presumably because of rapid conformational exchange. Hence, DNA restriction fragments that migrate anomalously slowly in polyacrylamide gels are not necessarily stably curved in free solution.

The kink-turn motif in RNA is dimorphic, and metal ion-dependent

The kink-turn (K-turn) is a new motif in RNA structure that was identified by examination of the crystal structures of the ribosome. We examined the structural and dynamic properties of this element in free solution. The K-turn RNA exists in a dynamic equilibrium between a tightly kinked conformation and a more open structure similar to a simple bulge bend. The highly kinked form is stabilized by the noncooperative binding of metal ions, but a significant population of the less-kinked form is present even in the presence of relatively high concentrations of divalent metal ions. The conformation of the tightly kinked population is in excellent agreement with that of the K-turn structures observed in the ribosome by crystallography. The end-to-end FRET efficiency of this species agrees closely with that of the ribosomal K-turn, and the direction of the bend measured by comparative gel electrophoresis also corresponds very well. These results show that the tightly kinked conformation of the K-turn requires stabilization by other factors, possibly by protein binding, for example. The K-turn is therefore unlikely to be of itself a primary organizing feature in RNA.

A deoxyribozyme that harnesses light to repair thymine dimers in DNA

In vitro selection was used to investigate whether nucleic acid enzymes are capable of catalyzing photochemical reactions. The reaction chosen was photoreactivation of thymine cyclobutane dimers in DNA by using serotonin as cofactor and light of wavelengths longer than the absorption spectrum of DNA. Curiously, the dominant single-stranded DNA sequence selected, UV1A, was found to repair its internal thymine dimer substrate efficiently even in the absence of serotonin or any other cofactor. UV1C, a 42-nucleotide fragment of UV1A, repaired the thymine dimer substrate in trans (k(cat)/k(uncat) = 2.5 x 10(4)), showing optimal activity with 305 nm light and thus resembling naturally occurring photolyase enzymes. Mechanistic investigation of UV1C indicated that its catalytic role likely exceeded the mere positioning of the substrate in a conformation favorable for photoreactivation. A higher-order structure, likely a quadruplex, formed by specific guanine bases within the deoxyribozyme, was implicated as serving as a light-harvesting antenna, with photoreactivation of the thymine dimer proceeding possibly via electron donation from an excited guanine base. In a primordial "RNA world," self-replicating nucleic acid populations may have been vulnerable to deactivation via UV light-mediated pyrimidine dimer formation. Photolyase nucleic acid enzymes such as the one described here could thus have played a role in preserving the integrity of such an RNA world.

Evaluation of multiplex capillary heteroduplex analysis: a rapid and sensitive mutation screening technique

Bardet-Biedl syndrome (BBS) is a heterogeneous disease; to date seven loci have been mapped and five identified (BBS1, BBS2, BBS4, BBS6, and BBS7). Inheritance in some families is complex with multiallelic participation making linkage analysis difficult. Previous mutation screens have been carried out by direct sequencing but with an increasing number of patients to be screened for five relatively large genes, a more rapid and cost-effective mutation assay for BBS was required. We have adapted the technique of heteroduplex analysis for use on the MegaBACE 1000, a capillary-based DNA fragment analyser, to improve the resolution and sensitivity of the system. Twelve known alterations (insertions, deletions, missenses, and SNPs) in BBS1, BBS2, BBS4, and BBS6 were used to test the sensitivity of the assay and subsequently used to screen new patients for mutations. We achieved a 100% detection rate while dramatically increasing the sample throughput by virtue of multiplexing up to six PCR products in each capillary. In addition, four novel variants were identified: two in BBS2 [c.522T>A (p.D174E) and c.805-20A>G] and two in BBS4 [c.332+27_28insA and c.1414A>G (p.M472V)]. Compared with sequencing and alternative screening methods, multiplex capillary heteroduplex analysis (MCHA) is extremely cost effective. Hum Mutat 22:151-157, 2003.

Turnover of env variable region 1 and 2 genotypes in subjects with late-stage human immunodeficiency virus type 1 infection

The env gene of human immunodeficiency virus type 1 (HIV-1) includes some of the most genetically diverse regions of the viral genome, which are called variable regions 1 through 5 (V1 through V5). We have developed a heteroduplex tracking assay to detect changes in variable regions 1 and 2 of env (V1/V2-HTA). Using sequences from two molecular clones as probes, we have studied the nature of longitudinal virus population changes in a cohort of HIV-1-infected subjects. Viral sequences present in 21 subjects with late-stage HIV-1 infection were initially screened for stability of the virus population by V1/V2-HTA. The virus populations at entry comprised an average of five coexisting V1/V2 genotypic variants (as identified by HTA). Eight of the 21 subjects were examined in detail because of the dynamic behavior of their env variants over an approximately 9-month period. In each of these cases we detected a single discrete transition of V1/V2 genotypes based on monthly sampling. The major V1/V2 genotypes (those present at >10% abundance) from the eight subjects were cloned and sequenced to define the nature of V1/V2 variability associated with a discrete transition. Based on a comparison of V1/V2 genotypic variants present at entry with the newly emerged variants we categorized the newly emerged variants into two groups: variants without length differences and variants with length differences. Variants without length differences had fewer nucleotide substitutions, with the changes biased to either V1 or V2, suggestive of recent evolutionary events. Variants with length differences included ones with larger numbers of changes that were distributed, suggestive of recall of older genotypes. Most length differences were located in domains where the codon motif AVT (V = A, G, C) had become enriched and fixed. Finally, recombination events were detected in two subjects, one of which resulted in the reassortment of V1 and V2 regions. We suggest that turnover in V1/V2 populations was largely driven by selection on either V1 or V2 and that escape was accomplished either through changes focused in the region under selection or by the appearance of a highly divergent variant.

Fluorescent heteroduplex assay for monitoring Bacillus anthracis and close relatives in environmental samples

A fluorescent heteroduplex method was developed to assess the presence of 16S rRNA gene (rDNA) sequences from Bacillus anthracis and close relatives in PCR-amplified 16S rDNA sequence mixtures from environmental samples. The method uses a single-stranded, fluorescent DNA probe, 464 nucleotides in length, derived from a B. anthracis 16S rRNA gene. The probe contains a unique, engineered deletion such that all probe-target duplexes are heteroduplexes with an unpaired G at position 343 (deltaG343). Heteroduplex profiles of sequences >/=85% similar to the probe were produced using an ABI 377 sequencer in less than 3 h. The method divides strains of the Bacillus cereus-Bacillus thuringiensis-B. anthracis group into two subgroups. Each subgroup is defined by a specific 16S rRNA gene sequence type. Sequence type A, containing one mismatch with the probe, occurs in B. anthracis and a small number of closely related clonal lineages represented mostly by food-borne pathogenic isolates of B. cereus and B. thuringiensis. Sequence type B, containing two mismatches with the probe, is found in the majority of B. cereus and B. thuringiensis strains examined to date. Sequence types A and B, when hybridized to the probe, generate two easily differentiated heteroduplexes. Thus, from heteroduplex profiles, the presence of B. cereus-B. thuringiensis-B. anthracis subgroups in environmental samples can be inferred unambiguously. The results show that fluorescent heteroduplex analysis is an effective profiling technique for detection and differentiation of sequences representing small phylogenetic or functional groups in environmental samples.

Solution structure of the Bacillus subtilis T-box antiterminator RNA: seven nucleotide bulge characterized by stacking and flexibility

The T-box transcription antitermination regulatory system is an important mechanism for regulation of expression of aminoacyl-tRNA synthetase, amino acid biosynthesis and transporter gene expression in Gram-positive bacteria. Antitermination is dependent on a complex set of interactions between uncharged tRNA and the leader region of the mRNA of the regulated gene. Here, we report the solution structure of a model RNA, based on the Bacillus subtilis tyrS antiterminator, determined to an rmsd of 3.47A for all nine converged structures and 2.66A for the seven structures representing the consensus family. The antiterminator is comprised of two short helices with an intervening 7nt bulge. The bulge region of the antiterminator, which ultimately interacts with the acceptor end of tRNA, exhibits extensive stacking at the 3' end (encompassing the highly conserved ACC residues) and is the site of a pronounced kink between the two flanking helices. The 5' end of the bulge exhibits evidence of conformational flexibility. On the basis of the structural studies, there is no indication that the bases at the 5' end of the bulge that ultimately base-pair with tRNA are pre-organized for binding. Instead, the data are consistent with a model in which the stacking-induced structure at the 3' end of the bulge may facilitate the pre-selection of a set of conformations for the tRNA to sample during binding.

Identification of Epstein-Barr virus strain variants in hairy leukoplakia and peripheral blood by use of a heteroduplex tracking assay

Epstein-Barr virus (EBV) strains can be distinguished by specific sequence variations in the LMP1 gene. In this study, a heteroduplex tracking assay (HTA) specific for LMP1 was developed to precisely identify the prototypic undeleted strain B958, other undeleted strains (Ch2, AL, NC, and Med-), and strains with the 30-bp deletion (Med+ and Ch1). This technique also provides an estimate of the relative abundance of strains in patient samples. In this study, EBV strains were identified in 25 hairy leukoplakia (HLP) biopsies and six matched peripheral blood samples and throat washes with the LMP1-HTA. To investigate the relationship of the virus found in the peripheral blood to that in the HLP lesion, the strain variants in the peripheral blood B lymphocytes and those present within the epithelial cells in the HLP lesion and in throat washes were identified. In many of the subjects, compartmental differences in the EBV strain profiles in the oral cavity and peripheral blood were readily apparent. The throat wash specimens usually had a strain profile similar to that within the corresponding HLP sample, which was distinct from the strain profile detected in the peripheral blood. These analyses reveal that the nature of EBV infection can be very dynamic, with changes in relative strain abundance over time as well as the appearance of new strains. The patterns of abundance in the blood and oral cavity provide evidence for compartmentalization and for the transmission of strains between the blood and oropharynx.

Site-selective reactions of imperfectly matched DNA with small chemical molecules: applications in mutation detection

The last decade has witnessed many exciting scientific publications associated with site-selective reactions of small chemical molecules with imperfectly matched DNA. Typical examples are carbodiimide, hydroxylamine, potassium permanganate, osmium tetroxide, chemical tagging probes, biotinylated, chemiluminescent and fluorescent probes, and all of them selectively react with imperfectly matched DNA. More recently, some therapeutic agents including DNA intercalating drugs and groove binders have been found to promote the in vivo repair system to recognize and repair the mismatch more effectively. The results have established a novel method for detection of mismatches. Development of new chemical reactions for detection of imperfectly matched DNA and mutations is a rapidly growing field and has attracted significant interest of scientists from both chemical and biological fields and it is the main focus of this review.

Conformation sensitive gel electrophoresis for detection of factor X gene mutations

Fifteen patients from five families with laboratory data suggesting factor X (FX) deficiency were screened for causative mutations by conformation sensitive gel electrophoresis (CSGE) followed by sequencing. All exonic and flanking intronic regions of factor X gene were amplified using PCR. After heteroduplex formation, samples were analyzed onto a polyacrylamide gel for possible mismatch. An abnormal CSGE profile indicating an heteroduplex was identified in 10/15 cases. All the 10 patients with a patter of migration suggesting a mismatch had a laboratoristic pattern of FX deficiency whereas the five cases with a normal CSGE aspect referred to the normal components of the families who did not carry any FX defect. Sequencing demonstrated that the 10 exons, which showed a suspect CSGE pattern, harbored a mutation responsible for the factor X defect. Of the five mutation identified, two were recognized to be novel mutations (a 871C>T substitution and a 1169G>T transversion in exon 8), both located in the catalytic portion of FX. CSGE may be an effective and simple procedure for screening factor X gene mutations.

Recognition of bulged DNA by a neocarzinostatin product via an induced fit mechanism

The binding of the wedge-shaped isostructural analogue of the biradical species of the chromphore of antitumor antibiotic neocarzinostatin to sequence-specific bulged DNAs results in alterations in ellipticity of the DNAs. Circular dichroism (CD) spectroscopic results suggest that the drug specifically recognizes bulges of DNA via a combination of conformational selection and induced fit, not by binding to a preorganized site. Analysis of circular dichroism spectra indicates that the degree of induced fit observed is primarily a consequence of optimising van der Waals contacts with the walls of the bulge cavity. The effective recognition of the bulge site on duplex DNA appears to depend to a significant extent on the bent groove space being flexible enough to be able to adopt the geometrically optimal conformation compatible with the wedge-shaped drug molecule, rather than involving 'lock and key' recognition. The spectroscopic results indicate a change of DNA conformation, consistent with an allosteric binding model. Spectroscopic studies with various bulged DNAs also reveal that the binding strength directly correlates with the stability of the bulge structures.

An update on conformation sensitive gel electrophoresis

Conformation-sensitive gel electrophoresis (CSGE) was developed as a method of heteroduplex analysis to screen large multi-exon genes for sequence variation. The novelty of the method was in the use of a non-proprietary acrylamide gel matrix that used 1,4-bis (acrolyl) piperazine (BAP) as a cross linker with ethylene glycol and formamide as mildly denaturing solvents. The denaturing environment enhances the conformation polymorphism present in DNA heteroduplexes containing variations as small as single nucleotide polymorphisms (SNPs). CSGE has also been adapted for use on a fluorescent platform (F-CSGE) that resulted in higher throughput and sensitivity. Variation in sensitivity of CSGE has been studied extensively. The results demonstrate that the nature of the mismatched base in a defined sequence context has the most profound effect on the conformation of the heteroduplex. Additionally, the size of the PCR product, as well as the location of the mismatch within the PCR product, are two important parameters that determine the resolution of the mismatch-containing heteroduplexes during CSGE. Like any other mutation scanning technique, CSGE can have limited resolution of two closely linked sequence variations. For specific genes, like BRCA1 and BRCA2 where multiple SNPs are present in the coding sequence, each CSGE shift has to be sequenced to define the exact nature of the sequence change. In conclusion, CSGE scanning provides a powerful, cost-efficient way to scan genes with high sensitivity and specificity.

Distinguishing "looped-out" and "stacked-in" DNA bulge conformation using fluorescent 2-aminopurine replacing a purine base

The conformation of a bulged DNA base, whether looped-out of the DNA helix or stacked-in between the flanking bases, can be distinguished using fluorescence spectroscopy of an inserted fluorescent base. If 2-aminopurine, a structural analog of adenine and guanine, is placed in duplex DNA as the bulged base replacing an adenine or guanine, it loops out of the DNA helix into solution. This is determined by the decrease or increase of 2-aminopurine fluorescence during DNA thermomelting: if the 2-aminopurine base stacks into the helix, its fluorescence increases or remains about the same during DNA duplex melting, but if the 2-aminopurine base loops out of the helix, its fluorescence decreases upon melting of the DNA duplex.

Novel cross-strand three-purine stack of the highly conserved 5'-GA/AAG-5' internal loop at the 3'-end termini of Parvovirus genomes

We have used two-dimensional nuclear magnetic resonance (2D-NMR), distance geometry (DG) and molecular dynamics / energy minimization (MD/EM) methods to study a 2 x 3 asymmetric internal loop structure of the highly conserved 5'-(GA)/(AAG)-5' bubble' present at the 3'-end hairpin of the single-stranded DNA genome of parvoviruses. This motif contains an unpaired adenosine stacked between two bracketed sheared G.A pairs. However, the phenomenal cross-strand G-G and A-A stacking in the tandem sheared G.A pairs has undergone considerable change. A novel three-purine stacking pattern is observed instead; the inserted A18 base is completely un-stacked from its neighboring G 17 and A 19 bases, but well stacked with the cross-strand A4 and G3 bases to form a novel A4/A18/G3 stack that is different from the double G/G, A/A or quadruple G/G/G/G stack present in the 5'-(GA)/(AG)-5' or 5'-(GGA)/(AGG)-5' motifs. Unlike the bulged purine residue that usually causes about 20 degree kink in the helical axis of the parent helix when bracketed by canonical G.C or A.T base pairs, no significant kink is observed in the present helix containing a bulged-adenine that is bracketed by sheared G.A pairs. The phosphodiesters connecting G3-A4 and G17-A18 residues adopt unusual zeta torsional angles close to the trans domain, yet that connecting A18-A19 residues resumes the normal zeta(g-) value. The well structured '5'-(GAA)/(AG)-5" internal loop in the parvovirus genomes explains its resistance to single-strand specific endonuclease susceptibility.

MutS recognition: multiple mismatches and sequence context effects

Escherichia coli MutS is a versatile repair protein that specifically recognizes not only various types of mismatches but also single stranded loops of up to 4 nucleotides in length. Specific binding, followed by the next step of tracking the DNA helix that locates hemi-methylated sites, is regulated by the conformational state of the protein as a function of ATP binding/hydrolysis. Here, we study how various molecular determinants of a heteroduplex regulate mismatch recognition by MutS, the critical first step of mismatch repair. Using classical DNase I footprinting assays, we demonstrate that the hierarchy of MutS binding to various types of mismatches is identical whether the mismatches are present singly or in multiples. Moreover, this unique hierarchy is indifferent both to the differential level of DNA helical flexibility and to the unpaired status of the mismatched bases in a heteroduplex. Surprisingly, multiple mismatches exhibit reduced affinity of binding to MutS, compared to that of a similar single mismatch. Such a reduction in the affinity might be due to sequence context effects, which we established more directly by studying two identical single mismatches in an altered sequence background. A mismatch, upon simply being flipped at the same location, elicits changes in MutS specific contacts, thereby underscoring the importance of sequence context in modulating MutS binding to mismatches.

Heteroduplex panel analysis, a novel method for genetic identification of Aspergillus Section Flavi strains

For genetic identification of Aspergillus Section Flavi isolates and detection of intraspecific variation, we developed a novel method for heteroduplex panel analysis (HPA) utilizing fragments of the internal transcribed spacer (ITS) regions (ITS1-5.8S-ITS2) of the rRNA gene that was PCR amplified with universal primers. The method involves formation of heteroduplexes with a set of reference fragments amplified from Aspergillus flavus, A. parasiticus, A. tamarii, and A. nomius and subsequent minislab vinyl polymer gel electrophoresis. The test panel is compared with species-specific standard panels (F-1, P-1, T-1, and N-1) generated by pairwise reannealing among four reference fragments. Of 90 test panels, 89 succeeded in identifying the species and 74 were identical to one of the four standard panels. Of the 16 new panels, 11 A. flavus/A. oryzae panels were identical and typed as F-2 and 4 of 5 A. nomius panels were typed as N-2 or N-3. The other strain, A. nomius IMI 358749, was unable to identify the species because no single bands were formed with any of the four reference strains. DNA sequencing revealed that our HPA method has the highest sensitivity available and is able to detect as little as one nucleotide of diversity within the species. When Penicillium or non-Section Flavi Aspergillus was subjected to HPA, the resulting bands of heteroduplexes showed apparently lower mobility and poor heteroduplex formation. This indicates that HPA is a useful identification method without morphological observation and is suitable for rapid and inexpensive screening of large numbers of isolates. The HPA typing coincided with the taxonomy of Section Flavi and is therefore applicable as an alternative to the conventional methods (Samson, R. A., E. S. Hoekstra, J. C. Frisvad, and O. Filtenborg, p. 64-97, in Introduction to Food- and Airborne Fungi, 6th ed., 2000).

Conformations of an adenine bulge in a DNA octamer and its influence on DNA structure from molecular dynamics simulations

Molecular dynamics simulations have been applied to the DNA octamer d(GCGCA-GAAC). d(GTTCGCGC), which has an adenine bulge at the center to determine the pathway for interconversion between the stacked and extended forms. These forms are known to be important in the molecular recognition of bulges. From a total of ~35 ns of simulation time with the most recent CHARMM27 force field a variety of distinct conformations and subconformations are found. Stacked and fully looped-out forms are in excellent agreement with experimental data from NMR and x-ray crystallography. Furthermore, in a number of conformations the bulge base associates with the minor groove to varying degrees. Transitions between many of the conformations are observed in the simulations and used to propose a complete transition pathway between the stacked and fully extended conformations. The effect on the surrounding DNA sequence is investigated and biological implications of the accessible conformational space and the suggested transition pathway are discussed, in particular for the interaction of the MS2 replicase operator RNA with its coat protein.

Fluorescence energy transfer analysis of DNA structures containing several bulges and their interaction with CAP

DNA molecules with three bulges separated by double-stranded helical sections of B-DNA were constructed to be used as substrates for DNA-protein binding assays. Fluorescence resonance energy transfer (FRET) between dye molecules attached to the 5'-ends of the DNA molecules is used to monitor the protein binding. The A5 bulge, which consists of five unpaired adenine nucleotides, alters the direction of the helical axis by approximately 80 to 90 at every bulge site. Computer molecular modeling facilitated a pre-selection of suitable helix lengths that bring the labeled ends of the three-bulge DNA molecules (60 to 70 base-pairs long) into close proximity. The FRET experiments verified that the labeled ends of the helices of these long molecules were indeed close. A series of FRET experiments was carried out with two A5 and two A7 bulge molecules. The relative positions of the bulges were varied along the central helical DNA sequence (between the bulges) in order to determine the relative angular juxtapositions of the outlying helical arms flanking the central helical region. The global structural features of the DNA molecules are manifested in the FRET data. The FRET experiments, especially those of the two-bulge series, could be interpreted remarkably well with molecular models based on the NMR structure of the A5 bulge. These models assume that the DNA molecules do not undergo large torsional conformational fluctuations at the bulge sites. The magnitude of the FRET efficiency attests to a relatively rigid structure for many of the long 5'-end-labeled molecules. The changes in the FRET efficiency of three-bulge structures containing the specific binding sequence of the catabolite activator protein (CAP) demonstrated significant deformation of the DNA upon binding of CAP. No direct interaction of CAP with the dyes was observed.

Rapid detection of deletion, insertion, and substitution mutations via heteroduplex analysis using capillary- and microchip-based electrophoresis

In this report, we explore the potential of capillary and microchip electrophoresis for heteroduplex analysis- (HDA) based mutation detection. Fluorescent dye-labeled primers (6-FAM-tagged) were used to amplify the DNA fragments ranging from 130 to 400 bp. The effects of DNA fragment length, matrix additives, pH, and salt were evaluated for capillary electrophoresis- (CE) and/or microchip electrophoresis-based HDA, using six heterozygous mutations, 185delAG, E1250X (3867GT), R1443G (4446CG), 5382insC, 5677insA in BRCA1, and 6174delT in BRCA2. For this system, the effective fragment size for CE-based HDA was found in the range of 200-300 bp, however, the effective range was 150-260 bp for microchip-based HDA. Sensitivity studies show CE-based HDA could detect a mutated DNA present at only 1%-10% of the total DNA. Discrimination between wild-type and deletion or insertion mutations in BRCA1 and BRCA2 with CE-based HDA could be achieved in <8 min, while the substitution mutations required 14 min of analysis time. For each mutation region, 15 samples were run to confirm the accuracy and reproducibility of the method. Using the method described, two previously reported mutations, E1038G (3232AG, missense) and 4427 C/T (4427CT, polymorphism), were detected in the tested samples and confirmed by DNA sequencing. Translation of the CE-based methodology to the microchip format allowed the analysis time for each mutation to be decreased to 130 sec. Based on the results obtained with this model system, it is possible that CE-based HDA methodologies can be developed and used effectively in genetic testing. The fast separation time and automated operation afforded with CE instrumentation provide a powerful system for screening mutations that include small deletions, insertions, and point mutations. Translation to the microchip platform, especially to a multichannel microchip system, would allow for screening mutations with high throughput.

Viral genome characterisation by the heteroduplex mobility and heteroduplex tracking assays

The heteroduplex mobility assay (HMA) is a means of comparing two PCR amplicons or, in the variation known as the heteroduplex tracking assay (HTA), a means of estimating the quasispecies diversity of a viral genome. Heteroduplex assays have many applications including subtyping viral genomes, screening for low frequency variants in a population, scanning the relative genetic diversity across a genome and screening for recombinant clones. They can be used to detect dual infections, superinfections, contaminated blood products and laboratory contaminations. PCR amplicons of about 65% sequence similarity or greater will form heteroduplexes under appropriate conditions, and phylogenetic trees can be drawn from heteroduplex mobility data. While homoduplexes indicate more than 98% similarity between two DNA sequences, heteroduplexes indicate at least seven mismatches in a 500-bp amplicon, or a three-base pair gap in 1000-bp. Minority variants comprising 1% to 5% of the genome population can be detected and quantified by HTA. Thus far, heteroduplex assays have been described for HIV and other lentiviruses, hepatitis C and G viruses, Norwalk-like viruses, influenza, measles and poliovirus. They could be applied to a wide range of other viral species.

DNA recognition, strand selectivity, and cleavage mode during integrase family site-specific recombination

We have probed the association of Flp recombinase with its DNA target using protein footprinting assays. The results are consistent with the domain organization of the Flp protein and with the general features of the protein-DNA interactions revealed by the crystal structures of the recombination intermediates formed by Cre, the Flp-related recombinase. The similarity in the organization of the Flp and Cre target sites and in their recognition by the respective recombinases implies that the overall DNA-protein geometry during strand cleavage in the two systems must also be similar. Within the functional recombinase dimer, it is the interaction between two recombinase monomers bound on either side of the strand exchange region (or spacer) that provides the allosteric activation of a single active site. Whereas Cre utilizes the cleavage nucleophile (the active site tyrosine) in cis, Flp utilizes it in trans (one monomer donating the tyrosine to its partner). By using synthetic Cre and Flp DNA substrates that are geometrically restricted in similar ways, we have mapped the positioning of the active and inactive tyrosine residues during cis and trans cleavage events. We find that, for a fixed substrate geometry, Flp and Cre cleave the labile phosphodiester bond at the same spacer end, not at opposite ends. Our results provide a model that accommodates local heterogeneities in peptide orientations in the two systems while preserving the global functional architecture of the reaction complex.