Base Changes and Triple-Helix Hybridization Properties of GT Containing Third Strands: A Systematical Study

Abstract

Triple-helix recognition of the DNA major grove offers a powerful approach for the design of sequence specific DNA binding molecules. Although the triple-helix binding of pyrimidine containing third strands is well characterized now, the factors governing the recognition of double stranded DNA by GT containing third strands are poorly understood. Oligonucleotides with a variable amount of G and GpT or TpG steps have been synthesized here. A systematical study was performed to determine the influence of these changes on the triple-helix hybridization properties of these oligonucleotides. Large difference in the hybridization properties have been observed by band shift experiments.     

Design and evaluation of single-stranded DNA carrier molecules for DNA-directed assembly

Due to the exceptional molecular recognition properties of nucleic acids, the computational design of DNA sequence motifs is of paramount interest for a wide variety of applications, ranging from DNA-based nanotechnology and DNA computing to the broad field of DNA microarray technologies. These applications rely on the specificity of Watson-Crick base-pairing, and thus, are highly sensitive to non-specific interactions and the formation of any undesired secondary structures, which contradict an efficient intermolecular hybridization. Here we report on the in silico design and in vitro evaluation of single-stranded DNA (ssDNA) carrier strands for the directional DNA-based positioning of streptavidin (STV) conjugates covalently tagged with short ssDNA oligonucleotides. Each such carrier strand consists of four hybridization sites complementary to the conjugate DNA strands. The high and homogeneous hybridization efficiency measured in vitro by microarray hybridization assays confirms the quality of our in silico sequence design method. Hybridization efficiency of DNA-STV-conjugates depends on the position of the hybridization site in the carrier sequence, where the positions nearest to and farthest from the microarray surface proved to be most favorable.     

Monoclonal antibodies targeted to alpha-oligonucleotides. Characterisation and application in nucleic acid detection.

The aim of the present study was to test the antigenicity of alpha-deoxyribonucleotides in order to develop a new tool for the detection of nucleic acid sequences for use in diagnostic applications. We describe four monoclonal antibodies (Mabs) which recognize alpha-deoxyribonucleotides. Two were raised against a poly(alpha-dT) sequence and specifically recognized the alpha-dT nucleotide. Two were raised against a sequence containing all four common nucleotides as alpha-nucleotides and, surprisingly, only recognized the alpha-dG nucleotide. For all four Mabs, no cross reactivity was observed with beta-oligonucleotides. These Mabs were reactive with alpha-oligonucleotide sequences whether these sequences were single-stranded or hybridized to DNA or RNA. The four Mabs were tested in a sandwich hybridization assay that consisted of an alpha-oligonucleotide (for target sequence recognition), one of the four Mabs (for recognition of the hybridized alpha-oligonucleotide), and goat anti-mouse antibody conjugated to horse radish peroxidase (HRP) (for detection). One of the monoclonal antibodies, Mab 2E11D7, was directly conjugated to HRP and used in sandwich hybridization to detect PCR fragments of HPV 18 DNA. The sensitivity of this reaction was 1 pg of plasmid DNA containing the HPV 18 fragment. The specificity of the detection was demonstrated using HPV 6/11 and 16 DNA sequences.     

Strand invasion by DNA-peptide conjugates and peptide nucleic acids.

Peptide nucleic acids (PNAs) and conjugates between oligonucleotides and cationic peptides possess superior potential for strand invasion at complementary sequences. We discovered that oligonucleotide-peptide conjugates and PNAs fall into three classes based on their hybridization efficiency; i) those complementary to inverted repeats within AT-rich region hybridize with highest efficiency; ii) those complementary to areas adjacent to inverted repeats or near AT-rich regions hybridize with moderate efficiency; and iii) those complementary to other regions do not detectably hybridize. The correlations between oligomer chemistry, DNA target sequence, and hybridization efficiency that we report here have important implications for the recognition of duplex DNA.     

Restriction endonuclease recognition and Southern hybridization of bromodeoxyuridine-substituted genomic DNA

Abstract. Human glioma cell lines exposed to various concentrations of bromode-oxyuridine (BrdUrd) were studied to determine the effect of BrdUrd substitution on restriction endonuclease recognition and Southern hybridization of genomic DNA. BrdUrd substitution had no effect on the recognition of restriction endonucleases. When the exposure to BrdUrd was 2 h or less and the BrdUrd substitution rate was less than 40%, there was no difference in the density of hybridized bands after Southern hybridization using human non-recombinant complementary DNA as a probe. Hybridization was suppressed significantly by exposures longer than 24 h or BrdUrd substitution rates greater than 40%. These results suggest that the BrdUrd substitution rate and the exposure time to BrdUrd influence the hybridization reaction by a DNA probe. Brief exposure (up to 2 h) to BrdUrd does not influence restriction endonuclease recognition or Southern hybridization of genomic DNA.     

Fluorescent and photochemical properties of a single zinc finger conjugated to a fluorescent DNA-binding probe

A single zinc finger derived from the DNA-binding domain of the glucocorticoid receptor (GR) has been tethered to the intercalating fluorophore thiazole orange, and the DNA recognition characteristics of the conjugate have been examined. DNA sequence specificity for the peptide-dye conjugate, determined by steady-state fluorescence measurements and photoactivated DNA cleavage experiments, reproduce the binding features of response element recognition found in the native GR. The thiazole orange is able to intercalate and fluoresce when the conjugate binds, at concentrations where little fluorescence is observed from either the conjugate alone or the conjugate mixed with DNA lacking the zinc finger target sequence. The conjugate preferentially targets a 5'-TGTTCT-3' sequence (the native glucocorticoid receptor element) with a dissociation constant of about 25 nM. Lower binding affinities (up to 10-fold) are observed for single site variants of this sequence, and much lower affinity (40-50-fold) is observed for binding to the estrogen response element (which differs from the glucocorticoid receptor element at two positions) as well as to nonspecific DNA. Footprinting reactions show a 4-6 base pair region that is protected by the zinc finger moiety. Photocleavage assays reveal a several base pair region flanking the recognition sequence where the tethered thiazole orange moiety is able to intercalate and subsequently cleave DNA upon visible light exposure. Thiazole orange is also shown to oxidize the 5'-G of remote GG sequences, depending on the details of the intervening DNA sequence. Small synthetic protein-dye conjugates such as this one are potentially useful for a variety of purposes including sequence-specific probes that work under physiological conditions (without melting and hybridization of DNA), sequence-specific photocleavage agents, and self-assembling components in electron and energy transfer systems that utilize DNA as a scaffold and/or photochemical medium.     

Metal-enhanced biosensor for genetic mismatch detection

DNA biosensors are increasingly used in hybridization reactions, mutation detection, genomic sequencing, and identification of pathogens. However, the inability to monitor the recognition signals without resorting to the use of labels or electroactive mediators has led to DNA devices with inadequate sensitivity. Moreover, some electroactive species require high redox potentials that often destroy the DNA complementarity. This article presents the concept of metal-enhanced detection (MED) for the determination of DNA-DNA reactions and presents the application of this concept for mismatch detection. The MED concept relies on the idea that metallic films deposited as a continuous layer or monolayer onto a solid electrode, or even electrostatically held, could greatly enhance the rate of electron transfer by reducing the distance between the donor and acceptor species and could lead to label-free assays during DNA hybridization reactions. The MED concept has been tested for voltammetric detection of gene sequence of Microcystis spp. The resulting biosensor involved the immobilization of a 17-mer DNA probe that is complementary to a specific gene sequence of Microcystis spp. on a gold electrode via avidin-biotin chemistry. Electrochemical reduction and oxidation of DNA-captured Ag(+) ions provided the detection signals for the target gene sequence in solution. A linear response of silver cathodic peak current with concentration of the target oligonucleotide sequence was observed with a detection limit of 7 x 10(-9)M. This label-free approach was successfully applied to detecting two-base-pair mismatches in the gene sequence of Microcystis spp.     

PNA beacons for duplex DNA

We report here on the hybridization of peptide nucleic acid (PNA)-based molecular beacons (MB) directly to duplex DNA sites locally exposed by PNA openers. Two stemless PNA beacons were tested, both featuring the same recognition sequence and fluorophore-quencher pair (Fluorescein and DABCYL, respectively) but differing in arrangement of these groups and net electrostatic charge. It was found that one PNA beacon rapidly hybridized, with the aid of openers, to its complementary target within duplex DNA at ambient conditions via formation of a PD-like loop. In contrast, the other PNA beacon bound more slowly to preopened duplex DNA target and only at elevated temperatures, although it readily hybridized to single-stranded (ss) DNA target. Besides a higher selectivity of hybridization provided by site-specific PNA openers, we expect this approach to be very useful in those MB applications when denaturation of the duplex DNA analytes is unfavorable or undesirable. Furthermore, we show that PNA beacons are advantageous over DNA beacons for analyzing unpurified/nondeproteinized DNA samples. This feature of PNA beacons and our innovative hybridization strategy may find applications in emerging fluorescent DNA diagnostics.     

Isolation of a repeated DNA sequence from Bordetella pertussis

A repeated DNA sequence in the genome of Bordetella pertussis has been demonstrated. At least 20 copies of this sequence could be observed in either BamHI or EcoRI restriction enzyme digests of chromosomal DNA; fragments carrying the repeated DNA sequence ranged in size from about 1.5 to 20 kbp. The repeated DNA sequence was cloned from two separate regions of the B. pertussis genome, as shown by restriction enzyme site maps of the two clones and by hybridization studies. A small number of differences in the pattern of hybridization of the repeated DNA sequence to chromosomal DNA from several strains of B. pertussis was observed. No repeated DNA sequences were observed in one strain each of B. parapertussis and B. bronchiseptica, and there was no hybridization of B. pertussis DNA to Escherichia coli chromosomal DNA. The repeated DNA sequence was subcloned on a 2.54 kbp BamHI fragment from one of the two original clones. Restriction enzyme digests and hybridization studies showed that the repeated DNA sequence was about 1 kbp in size and had a single, internal ClaI site.     

Hybridization methods for DNA sequencing.

I have conducted a general analysis of the practicability of using oligonucleotide hybridization to sequence DNA. Any DNA sequence may be sequenced by hybridization with a complete panel of oligonucleotides. However, sequencing DNA segments over 2 kb long requires an unrealistic number of hybridization reactions. The optimal protocol is to hybridize 7-mer or 8-mer mixed oligonucleotide probes to immobilized DNA fragments 80 bp long: should this prove impractical, hybridization of labeled 270-bp fragments to immobilized mixed 10-mers is a potential alternative. Both protocols require no more experiments to sequence large regions of DNA than conventional m13-based sequencing and are much easier to automate, thus reducing the requirements for skilled personnel. In the ideal case, hybridization sequencing reduces the number of experiments required to sequence megabase DNA by 90%.     

Studies on the human chromosome 3 centromere with a newly cloned alphoid DNA probe

Starting from a chromosome-specific DNA library, we have isolated a human chromosome-specific satellite DNA sequence. This sequence of 635 base pairs (bp) consists of 3.7 alpha DNA monomers of 170-171 bp. Under high stringency it hybridizes to the centromere of chromosome 3 in a region composed of 2,750 bp tandem repeats characterized by the regular spacing of Hind III and TaqI restriction enzyme recognition sites. It has diverged and undergone amplification after the human speciation. The amplification allows an easy monitoring of the chromosome 3 centromere by in situ hybridization with a nonradioactive probe.     

Peptide nucleic acids: deoxyribonucleic acid mimics with a peptide backbone

This tutorial briefly describes a new class of synthetic biopolymer, which is referred to as peptide nucleic acid (PNA). In PNA, individual nucleobases are linked to an achiral neutral peptide backbone. PNA exhibits the hybridization characteristic (e.g., Watson—Crick duplex formation) of DNA. The achiral peptide backbone provides similar interbase distances as natural DNA, and adequate flexibility to permit base pair interactions with complementary RNA or DNA strands. Several potential applications of PNA oligomers in biotechnology are suggested. These include the use of PNAs as a probe for specific recognition of a DNA or RNA sequence selective, purification of nucleic acids via designed high affinity binding to PNA, screening for DNA mutations, and as possible therapeutic agents.     

Strategies for optimizing DNA hybridization on surfaces

Specific and predictable hybridization of the polynucleotide sequences to their complementary counterparts plays a fundamental role in the rational design of new nucleic acid nanodevices. Generally, nucleic acid hybridization can be performed using two major strategies, namely hybridization of DNA or RNA targets to surface-tethered oligonucleotide probes (solid-phase hybridization) and hybridization of the target nucleic acids to randomly distributed probes in solution (solution-phase hybridization). Investigations into thermodynamic and kinetic parameters of these two strategies showed that hybridization on surfaces is less favorable than that of the same sequence in solution. Indeed, the efficiency of DNA hybridization on surfaces suffers from three constraints: (1) electrostatic repulsion between DNA strands on the surface, (2) steric hindrance between tethered DNA probes, and (3) nonspecific adsorption of the attached oligonucleotides to the solid surface. During recent years, several strategies have been developed to overcome the problems associated with DNA hybridization on surfaces. Optimizing the probe surface density, application of a linker between the solid surface and the DNA-recognizing sequence, optimizing the pH of DNA hybridization solutions, application of thiol reagents, and incorporation of a polyadenine block into the terminal end of the recognizing sequence are among the most important strategies for enhancing DNA hybridization on surfaces.     

Cloning of human immunoglobulin mu gene and comparison with mouse mu gene

We have cloned a 12 kb DNA segment containing human mu gene and its flanking sequence from human fetal liver DNA library using mouse mu gene as a probe. Partial nucleotide sequence determination shows that the cloned DNA contains the sequence encoding human mu chain. This is the first constant region gene of the human heavy chain that is cloned. We have compared human and mouse mu genes by heteroduplex analysis and Southern blot hybridization. The results clearly show that not only the sequence encoding the CH4 domain but also the 5'-flanking (S mu) sequence is conserved between human and mouse mu genes, suggesting that the nucleotide sequence in the S mu region has an important biological function, presumably a recognition signal for the class switch recombinant as proposed previously.     

Rapid identification of clones using the same degenerate oligonucleotide mixture for both screening and sequencing

A simple and rapid strategy for distinguishing between positively hybridizing colonies and false positive-hybridization signals is described. The isolation of a specific DNA sequence depends on the ability to distinguish between a clone that contains the correct sequence and a false hybridization-positive or background signal. This procedure utilizes the same oligonucleotide mixture both as a screening probe and as a sequencing primer. The mixture of oligonucleotides is used as a primer to obtain sequence information directly from double-stranded DNA. Conditions for sequencing with oligonucleotides having up to 64-fold degeneracy are described. Since the sequence information obtained is directly adjacent to the site of oligonucleotide:DNA hybridization, it is necessary to know only a minimal length of DNA or peptide sequence to both design oligonucleotide probes and confirm the authenticity of the hybridization positives. The advantages of the degenerate oligonucleotide sequencing method include the rapid, reliable identification of authentic versus false hybridization positives made directly without subcloning into single-stranded M13 phage, without sequencing large regions of DNA, or without synthesizing sequence-specific primers.     

Amplification and characterization of a beta-globin gene synthesized in vitro.

Full-length, double-stranded globin DNA was synthesized in vitro starting from rabbit globin mRNA. Several restriction endonuclease cleavage sites with known recognition sequences were mapped on this DNA as a means of assessing the accuracy of in vitro synthesis. By comparing this map with the nucleotide sequences known or predicted from the amino acid sequences of alpha-and beta-chain rabbit hemoglobin, it was possible to show that the synthetic globin DNA is a faithful copy of beta-globin mRNA. Amplification of the synthetic globin DNA was achieved by inserting the molecule into the plasmid PMB9 using the poly(dA)-(dT) joining procedure, and transforming E. coli with the hybrid DNA. Transformants carrying beta-globin DNA were identified by colony hybridization using purified 125I-beta-mRNA probe. Comparison of the restriction maps of the synthetic and inserted globin DNAs showed that the entire synthetic globin DNA molecule was amplified without sequence rearrangements. Both the synthetic and the cloned DNA include the entire coding sequence of the beta-globin gene plus a substantial portion of the untranslated regions flanking the structural gene.     

Chemistry of locked nucleic acids (LNA): Design, synthesis, and bio-physical properties

Preparation of LNA nucleosides requires a number of synthetic steps but very efficient procedures have been developed, as have protocols for synthesis of LNA oligonucleotides on automated DNA synthesizers. In all cases, LNA oligonucleotides have exhibited good aqueous solubility as would be expected from their close structural resemblance to the natural nucleic acids. The universality of LNA mediated high-affinity and specific hybridization has been demonstrated extensively with a large number of duplex forming LNA-oligonucleotides. Most importantly, most of the members of the LNA molecular family have been shown to exert their substantial affinity increase (i) in combination with standard DNA, RNA and contemporary analogues and (ii) whether inserted as single nucleosides in an oligonucleotide or as blocks of contiguous nucleotides, an important point. The works on TFO's is expanding the usefulness of LNA to double strand recognition and it has been demonstrated that LNA it is a promising structure for further base modifications in the pursuit of global sequence specific recognition of DNA.     

Chemistry of locked nucleic acids (LNA): Design, synthesis, and bio-physical properties

Summary Preparation of LNA nucleosides requires a number of synthetic steps but very efficient procedures have been developed, as have protocols for synthesis of LNA oligonucleotides on automated DNA synthesizers. In all cases, LNA oligonucleotides have exhibited good aqueous solubility as would be expected from their close structural resemblance to the natural nucleic acids. The universality of LNA mediated high-affinity and specific hybridization has been demonstrated extensively with a large number of duplex forming LNA-oligonucleotides. Most importantly, most of the members of the LNA molecular family have been shown to exert their substantial affinity increase (i) in combination with standard DNA, RNA and contemporary analogues and (ii) whether inserted as single nucleosides in an oligonucleotide or as blocks of contiguous nucleotides, an important point. The works on TFO's is expanding the usefulness of LNA to double strand recognition and it has been demonstrated that LNA it is a promising structure for further base modifications in the pursuit of global sequence specific recognition of DNA.     

Generalized Poland-Scheraga model for DNA hybridization

The Poland-Scheraga (PS) model for the helix-coil transition of DNA considers the statistical mechanics of the binding (or hybridization) of two complementary strands of DNA of equal length, with the restriction that only bases with the same index along the strands are allowed to bind. In this article, we extend this model by relaxing these constraints: We propose a generalization of the PS model that allows for the binding of two strands of unequal lengths N1 and N2 with unrelated sequences. We study in particular (i) the effect of mismatches on the hybridization of complementary strands, (ii) the hybridization of noncomplementary strands (as resulting from point mutations) of unequal lengths N1 and N2. The use of a Fixman-Freire scheme scales down the computational complexity of our algorithm from O(N1(2)N2(2) to O(N1N2). The simulation of complementary strands of a few kilo base pairs yields results almost identical to the PS model. For short strands of equal or unequal lengths, the binding displays a strong sensitivity to mutations. This model may be relevant to the experimental protocol in DNA microarrays, and more generally to the molecular recognition of DNA fragments. It also provides a physical implementation of sequence alignments.     

Construction, analysis, and application to 46,XY gonadal dysgenesis of a recombinant phage DNA library from flow-sorted human Y chromosomes

The analysis of a recombinant human Y-enriched Hind III total digest phage library prepared from the DNA of flow sorted human Y chromosomes is described. Out of 43 phage inserts from the library thus far mapped, 25 revealed hybridization with Y chromosomal DNA. These inserts may be divided into five groups according to their degree of Y specific hybridization: inserts that hybridize with one single copy or slightly repeated Y-specific DNA sequence, Y-specific repeated sequences of various restriction fragment lengths, Y-chromosomal DNA sequence(s) shared by a sequence on the X and/or on autosomes, Y-specific DNA sequences in addition to multiple X and/or autosomal sequences, or Y-specific repeated DNA in addition to multiple X and/or autosomal sequences. Application of probes from this library for diagnostic purposes is shown in two 46,XY patients with gonadal dysgenesis and small deletions of the Y short arm.