Biotin-streptavidin-labeled oligonucleotides as probes of helicase mechanisms

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

In vitro DNA synthesis opposite oxazolone and repair of this DNA damage using modified oligonucleotides

Emphasis was placed in this work on the assessment of biological features of 2,2,4-triaminooxazolone, a major one-electron and ^·OH-mediated oxidation product of guanine. For this purpose, two oligonucleotides that contain a unique oxazolone residue were synthesized. Herein we report the mutagenic potential of oxazolone during in vitro DNA synthesis and its behavior towards DNA repair enzymes. Nucleotide insertion opposite oxazolone, catalyzed by Klenow fragment exo^– and Taq polymerase indicates that the oxazolone lesion induces mainly dAMP insertion. This suggests that the formation of oxazolone in DNA may lead to G→T transversions. On the other hand, oxazolone represents a blocking lesion when DNA synthesis is performed with DNA polymerase β. Interestingly, DNA repair experiments carried out with formamidopyrimidine DNA N-glycosylase (Fpg) and endonuclease III (endo III) show that oxazolone is a substrate for both enzymes. Values of k_cat/K_m for the Fpg-mediated removal of oxidative guanine lesions revealed that 8-oxo-7,8-dihydroguanine is only a slightly better substrate than oxazolone. In the case of endo III-mediated cleavage of modified bases, the present results suggest that oxazolone is a better substrate than 5-OHC, an oxidized pyrimidine base. Finally, MALDI-TOF-MS analysis of the DNA fragments released upon digestion of an oxazolone-containing oligonucleotide by Fpg gave insights into the enzymatic mechanism of oligonucleotide cleavage.     

Bridged oligonucleotides as molecular probes for investigation of enzyme-substrate interaction and allele-specific analysis of DNA

The efficiency of enzymatic conversion of DNA complexes containing non-nucleotide inserts has been studied. T4 DNA ligase and Taq DNA polymerase have been included in the study as examples of widely used DNA-dependent enzymes. A series of substrate DNA complexes have been formed using native oligonucleotides and bridged ones bearing non-nucleotide inserts based on phosphodiesters of di-, tetra-, or hexaethylene glycol, 1,5-pentanediol, 1,10-decanediol, and 3-hydroxy-2(hydroxymethyl)-tetrahydrofuran. The perturbation in DNA located far from the site of the enzyme action had almost no influence on the substrate properties of the complex, while insertion near this site significantly deteriorated them. The use of a series of modified duplexes allows one to locate the position of the enzyme-binding site on DNA substrate with the accuracy of 1–2 nucleotides. The presence of a non-nucleotide insert in the complex has been also shown to enhance the efficiency of single mismatch discrimination upon both template-directed ligation and extension of oligonucleotides.     

The use of synthetic oligonucleotides as hybridization probes. II. Hybridization of oligonucleotides of mixed sequence to rabbit beta-globin DNA.

Two oligonucleotides 14-bases long were synthesized, one complementary to rabbit beta-globin DNA (R beta G14A) and the other with the same sequence except for a single base change (T for C) (R beta G14B). Hybridization conditions were established such that R beta G14A would hybridize to globin DNA while R beta G14B would not. We also synthesized a mixture of 13-base long oligonucleotides (R beta G13Mix), representing eight of the possible coding sequences for amino acids 15-19 of rabbit beta-globin. One of the eight is complementary to globin DNA. R beta G13Mix was found to hybridize specifically to globin DNA under conditions where oligonucleotides forming single base pair mismatches do not. Furthermore, R beta G13Mix was shown to hybridize specifically to colonies containing a plasmid with a globin DNA insert. These results are discussed with respect to a general procedure for screening recombinant clones for those containing DNA coding for a protein of known amino acid sequence.     

A modular approach to the synthesis of new reagents useful in the chemical synthesis of modified DNA probes: derivatives of 3-(tert-butyldimethylsiloxy)glutaric anhydride as versatile building blocks in the synthesis of new phosphoramidites and modified solid supports

We present a flexible and cost-efficient synthetic strategy for the preparation of a new family of phosphoramidite and solid-support reagents that can introduce a broad range of modifications into DNA probes. The key intermediate material 3 is synthesized using the inexpensive and commercially available 3-(tert-butyldimethylsiloxy)glutaric anhydride 1 and can be used as common starting material for the preparation of new labeling reagents.     

3'-modified oligonucleotides by reverse DNA synthesis

Reverse DNA oligonucleotide synthesis (i.e. from 5′→3′) is a strategy that has yet to be exploited fully. While utilized previously for the construction of alternating 3′-3′- and 5′-5′-linked antisense oligonucleotides, the use of nucleoside 5′-phosphoramidites has not generally been used for the elaboration of (modified) oligonucleotides. Presently, the potential of reverse oligonucleotide synthesis for the facile synthesis of 3′-modified DNAs is illustrated using a phosphoramidite derived from tyrosine. The derived oligonucleotide was shown to have chromatographic and electrophoretic properties identical with the modified oligonucleotide resulting from the proteinase K digestion of the vaccinia topoisomerase I–DNA covalent complex. The results confirm the nature of the structure previously assigned to this product, and establish the facility with which proteinase K is able to complete the digestion of the polypeptide backbone of the DNA oligonucleotide-linked topoisomerase I.     

Hierarchical gene synthesis using DNA microchip oligonucleotides

High-cost of oligonucleotides is one of the major problems to low-cost gene synthesis. Although DNA oligonucleotides from cleavable DNA microchips has been adopted for the low-cost gene synthesis, construction of DNA molecules larger than 1 kb has been largely hampered due to the difficulties of DNA assembly associated with the negligible quantity of chip oligonucleotides. Here we report a hierarchical method for the synthesis of large genes using oligonucleotides from programmable DNA microchips. Using this hierarchical method, we successfully synthesized 1056 bp Dpo4 and 2325 bp Pfu DNA polymerase genes as models. This hierarchical strategy can be further expanded for the syntheses of multiple large genes in a scalable manner.     

Biotinylated oligonucleotides as probes in the method of molecular hybridization

The chemical approaches to the preparation of non-radioactive and biotinylated probes based on synthetic oligonucleotides and their applicability to the molecular hybridization method are discussed.     

Total synthesis of multi-kilobase DNA sequences from oligonucleotides

A method for synthesizing DNA from 40-mer oligonucleotides, which we used to generate a 32-kb DNA fragment, is explained. DNA sequences are synthesized as approximately 500 bp fragments (synthons) in a two-step PCR reaction and cloned using ligation-independent cloning (LIC). Synthons are then assembled into longer full-length sequences in a stepwise manner. By initially synthesizing smaller fragments (synthons), the number of clones sequenced is low compared with synthesizing complete multi-kilobase DNA sequences in a single step. LIC eliminates the need for purification of fragments before cloning, making the process amenable to high-throughput operation and automation. Type IIs restriction enzymes allow seamless assembly of synthons without placing restrictions on the sequence being synthesized. Synthetic fragments are assembled in pairs to generate the final construct using vectors that allow selection of desired clones with two unique antibiotic resistance markers, and this eliminates the need for purification of fragments after digestion with restriction endonucleases.     

DNA conjugates as novel functional oligonucleotides

Oligodeoxynucleotides with RNA cleavage activity 1) were conjugated with amines and peptides by solid phase fragment condensation (SPFC). It was found that 29 mer DNA enzyme conjugated with spermine at its 5'-end showed higher affinity to the target RNA sequence and 40 times higher activity of cleavage than native DNA enzyme. It is also to be noted that conjugate DNA enzymes showed increased resistance against nuclease digestion.     

Electrochemically directed synthesis of oligonucleotides for DNA microarray fabrication

We demonstrate a new method for making oligonucleotide microarrays by synthesis in situ. The method uses conventional DNA synthesis chemistry with an electrochemical deblocking step. Acid is delivered to specific regions on a glass slide, thus allowing nucleotide addition only at chosen sites. The acid is produced by electrochemical oxidation controlled by an array of independent microelectrodes. Deblocking is complete in a few seconds, when competing side-product reactions are minimal. We demonstrate the successful synthesis of 17mers and discrimination of single base pair mismatched hybrids. Features generated in this study are 40 μm wide, with sharply defined edges. The synthetic technique may be applicable to fabrication of other molecular arrays.     

A new method of synthesis of fluorescently labelled oligonucleotides and their application in DNA sequencing.

A new approach to the chemical synthesis of oligodeoxynucleotides bearing reporter functional groups at base residues of 3'-end nucleosides is reported. Applications of the 3'-end fluorescently labelled primers for automated DNA sequencing are shown.     

Optimal conditions for hybridization with oligonucleotides: a study with myc-oncogene DNA probes

We present a study on the refinement of filter-hybridization conditions for a series of synthetic oligonucleotides in the range from 17 to 50 base residues in length. Experimental conditions for hybridization and the subsequent washing steps of the filter were optimized for different lengths of the synthetic oligonucleotides by varying the formamide concentration and washing conditions (temperature and monovalent cation concentration). Target DNA was immobilized to the nitrocellulose filter with the slot blot technique. The sequences of the synthetic oligonucleotides are derived from the third exon of the human oncogene c-myc and the corresponding viral gene v-myc and the G + C content was between 43 and 47%. Optimal conditions for hybridization with a 82% homologous 30-mer and 100% homologous 17-, 20-, 25-, 30-, and 50-mers were found to be a concentration of formamide of 15, 15, 30, 30, 40, and 50%, respectively. Optimal conditions for washing were 0.5X standard sodium citrate (SSC) at 42 degrees C for 2 X 15 min. The melting temperature for these optimal hybridization and washing conditions was calculated to be up to 11 degrees C below the hybridization temperature actually used. This confirms that the duplexes are more stable than expected. The melting points for 17-, 20-, and 30-mers were measured in the presence of 5X SSC and found to be 43, 58, and 60 degrees C, respectively. Competition between double- and single-stranded DNA probes to the target DNA was investigated. The single-stranded DNA probes were about 30- to 40-fold more sensitive than the double-stranded DNA probes.     

Chloroplast lysates support directed mutagenesis via modified DNA and chimeric RNA/DNA oligonucleotides

Chimeric RNA/DNA and modified DNA oligonucleotides have been shown to direct gene-conversion events in vitro through a process involving proteins from several DNA-repair pathways. Recent experiments have extended the utility of these molecules to plants, and we previously demonstrated that plant cell-free extracts are competent to support oligonucleotide-directed genetic repair. Using this system, we are studying Arabidopsis DNA-repair mutants and the role of plant proteins in the DNA-repair process. Here we describe a method for investigating mechanisms of plastid DNA-repair pathways. Using a genetic readout system in bacteria and chimeric or modified DNA oligonucleotides designed to direct the conversion of mutations in antibiotic resistance genes, we have developed an assay for genetic repair of mutations in a spinach chloroplast lysate system. We report genetic repair of point and frameshift mutations directed by both types of modified oligonucleotides. This system enables the mechanistic study of plastid gene repair and facilitates the direct comparison between plant nuclear and organelle DNA-repair pathways.     

Thermolytic CpG-containing DNA oligonucleotides as potential immunotherapeutic prodrugs

A CpG-containing DNA oligonucleotide functionalized with the 2-(N-formyl-N-methyl)aminoethyl thiophosphate protecting group (CpG ODN fma1555) was prepared from phosphoramidites 1a–d using solid-phase techniques. The oligonucleotide behaved as a prodrug by virtue of its conversion to the well-studied immunomodulatory CpG ODN 1555 through thermolytic cleavage of the 2-(N-formyl-N-methyl)aminoethyl thiophosphate protecting group. Such a conversion occurred at 37°C with a half-time of 73 h. The immunostimulatory properties of CpG ODN fma1555 were evaluated in two in vivo assays, one of which consisted of mice challenged in the ear with live Leishmania major metacyclic promastigotes. Local intradermal administration of CpG ODN fma1555 was as effective as that of CpG ODN 1555 in reducing the size of Leishmania lesions over time. In a different infectious model, CpG ODN 1555 prevented the death of Tacaribe-infected mice (43% survival) when administered between day 0 and 3 post infection. Administration of CpG ODN fma1555 three days before infection resulted in improved immunoprotection (60–70% survival). Moreover, co-administration of CpG ODN fma1555 and CpG ODN 1555 in this model increased the window for therapeutic treatment against Tacaribe virus infection, and thus supports the use of thermolytic oligonucleotides as prodrugs in the effective treatment of infectious diseases.     

A reliable method for the use of oligonucleotides as probes in blot-hybridization experiments

We have developed a ligation and specificprimer radiolabeling method that allows the use of oligonucleotides as probes in blot-hybridization experiments. The major advantage of the protocol is that standard hybridization and washing conditions may be used and yield high signals and low background. The observed increase in the stability and intensity of the hybridization signals appears to result from both increased length and specific radioactivity of the hybridization probe.     

Guidelines for incorporating non-perfectly matched oligonucleotides into target-specific hybridization probes for a DNA microarray

Sequence-specific oligonucleotide probes play a crucial role in hybridization techniques including PCR, DNA microarray and RNA interference. Once the entire genome becomes the search space for target genes/genomic sequences, however, cross-hybridization to non-target sequences becomes a problem. Large gene families with significant similarity among family members, such as the P450s, are particularly problematic. Additionally, accurate single nucleotide polymorphism (SNP) detection depends on probes that can distinguish between nearly identical sequences. Conventional oligonucleotide probes that are perfectly matched to target genes/genomic sequences are often unsuitable in such cases. Carefully designed mismatches can be used to decrease cross-hybridization potential, but implementing all possible mismatch probes is impractical. Our study provides guidelines for designing non-perfectly matched DNA probes to target DNA sequences as desired throughout the genome. These guidelines are based on the analysis of hybridization data between perfectly matched and non-perfectly matched DNA sequences (single-point or double-point mutated) calculated in silico. Large changes in hybridization temperature predicted by these guidelines for non-matched oligonucleotides fit independent experimental data very well. Applying the guidelines to find oligonucleotide microarray probes for P450 genes, we confirmed the ability of our point mutation method to differentiate the individual genes in terms of thermodynamic calculations of hybridization and sequence similarity.