Characterization of oligodeoxyribonucleotide synthesis on glass plates

Achieving high fidelity chemical synthesis on glass plates has become increasingly important, since glass plates are substrates widely used for miniaturized chemical and biochemical reactions and analyses. DNA chips can be directly prepared by synthesizing oligonucleotides on glass plates, but the characterization of these micro-syntheses has been limited by the sub-picomolar amount of material available. Most DNA chip syntheses have been assayed using in situ coupling of fluorescent molecules to the 5′-OH of the synthesized oligonucleotides. We herein report a systematic investigation of oligonucleotide synthesis on glass plates with the reactions carried out in an automated DNA synthesizer using standard phosphoramidite chemistry. The analyses were performed using ³²P gel electrophoresis of the oligonucleotides cleaved from glass plates to provide product distribution profiles according to chain length of oligonucleotides. 5′-Methoxythymidine was used as the chain terminator, which permits assay of coupling reaction yields as a function of chain length growth. The results of this work reveal that a major cause of lower fidelity synthesis on glass plates is particularly inefficient reactions of the various reagents with functional groups close to glass plate surfaces. These problems cannot be detected by previous in situ fluorescence assays. The identification of this origin of low fidelity synthesis on glass plates should help to achieve improved synthesis for high quality oligonucleotide microarrays.     

A simple, rapid, high-fidelity and cost-effective PCR-based two-step DNA synthesis method for long gene sequences

Chemical synthesis of DNA sequences provides a powerful tool for modifying genes and for studying gene function, structure and expression. Here, we report a simple, high-fidelity and cost-effective PCR-based two-step DNA synthesis (PTDS) method for synthesis of long segments of DNA. The method involves two steps. (i) Synthesis of individual fragments of the DNA of interest: ten to twelve 60mer oligonucleotides with 20 bp overlap are mixed and a PCR reaction is carried out with high-fidelity DNA polymerase Pfu to produce DNA fragments that are ~500 bp in length. (ii) Synthesis of the entire sequence of the DNA of interest: five to ten PCR products from the first step are combined and used as the template for a second PCR reaction using high-fidelity DNA polymerase pyrobest, with the two outermost oligonucleotides as primers. Compared with the previously published methods, the PTDS method is rapid (5–7 days) and suitable for synthesizing long segments of DNA (5–6 kb) with high G + C contents, repetitive sequences or complex secondary structures. Thus, the PTDS method provides an alternative tool for synthesizing and assembling long genes with complex structures. Using the newly developed PTDS method, we have successfully obtained several genes of interest with sizes ranging from 1.0 to 5.4 kb.     

Diastereomeric Process Control in the Synthesis of Oligodeoxyribonucleotide Phosphorothioates

Abstract

The emergence of antisense and antigene oligonucleotides as potential sequenceselective inhibitors of gene expression is evidenced by the growing number of ongoing clinicals trials against a variety of diseases. First generation antisense therapeutics utilize a uniformly modified oligodeoxyribonucleotide phosphorothioate where one non-bridging oxygen atom is formally replaced by sulfur, because natural DNA is unstable towards extra- and intracellular enzymes. Phosphoramidite chemistry has been widely used for the synthesis of phosphorothioate oligonucleotides because of its potential for automation, high coupling efficiency, ease of site-specific thioate linkage incorporation, and ready scalability. The large scale solid-supported synthesis of phosphorothioates is presently carried out by initial formation of the internucleotidic phosphite linkage followed by sulfurization of the phosphite triester to phosphorothioate using the Beaucage reagent. The resulting O,O-linked phosphorothioate diester linkage in the oligonucleotide is a chiral functional group. For a typical 20-mer there are 524,288 (2¹⁹) possible diastereoisomers. Separation and individual quantification of this number of diastereomers is currently not feasible. In addition, the best reported methods for stereocontrolled synthesis of phosphorothioate oligomers are not presently useful for drug synthesis; that is, since net 100% enantiomeric excess is not achieved in the coupling step, the oligomeric product still consists of the same mixture of Sp and Rp diastereomers, except that the levels of all but one isomer are reduced to low individual levels. As a result, even a small change in the and Sp phosphorothioate diesters, due to racemization during coupling, indicating that the overall synthetic process is stereo reproducible and under inherent process control.     

Synthesis and Evaluation of Oligonucleotides of High Purity

Abstract

We have developed and evaluated methods for the production of highly pure oligonucleotides.

Presently the solid phase synthesis in an automated DNA synthesiser applying the phosphoramidite chemistry can be regarded as a standard. During the synthesis several undesirable by-products arise:

- incomplete coupling (1%) leads to 5′-truncated sequences. These sequences are acetylated at their 5′-hydroxyl group to prevent further elongation in subsequent coupling steps, but this “capping step” is incomplete, the capping-yield is 90%, leading to accumulation of sequences of the length n-1 with internal deletions.

- the glycosidic bond to N-protected purines, especially adenine, is susceptible to acid leading to depurination and subsequently to strand scission during alkaline deprotection of the oligonucleotide. This gives rise to 3′- and to 5′-truncated sequences. The 3′-truncated sequences will not be removed by standard Rp HPLC as they are tritylated.

- the reactions involved in synthesis and deprotection may cause base modifications (full length product with damaged bases).

- insufficient deprotection procedures may result in incomplete removal of protecting groups, especially from the bases (full length products with altered bases).

We have set up two different schemes (Fig. 1 and Fig. 2) for synthesis and purification, which should provide highly pure oligonucleotides with the potential of adapting to large scale production:

- accumulation of n-1 sequences (failure of capping) will be avoided by a double capping procedure using phosphite in the first capping step and an acetic anhydride capping reagent in the second capping step, as described in the literature¹.

- 3′-truncated sequences are removed by different methqds in the two schemes. In scheme I (Fig. 1) the 3′-truncated sequences can be washed off, as the 3′-full length product still is anchored to the solid support after deprotection. In scheme II (Fig. 2) the 3′truncated sequences are digested by snake venom phosphodiesterase. The 3′-full length product is protected against digestion by a 3′ - 3′-inverted end. An oligo with a correct 3′-end is, in both schemes, eventually obtained by cleaving with RNase between the ribo unit and the requested DNA-sequence.

- 5′-truncated sequences are removed by Rp HPLC using the DMTr group of the last coupling step (trityl-on synthesis) as a hydrophobic tag.

Very labile protecting groups will be used to avoid problems with deprotection.     

Selenium derivatization and crystallization of DNA and RNA oligonucleotides for X-ray crystallography using multiple anomalous dispersion

We report here the solid phase synthesis of RNA and DNA oligonucleotides containing the 2′-selenium functionality for X-ray crystallography using multiwavelength anomalous dispersion. We have synthesized the novel 2′-methylseleno cytidine phosphoramidite and improved the accessibility of the 2′-methylseleno uridine phosphoramidite for the synthesis of many selenium-derivatized DNAs and RNAs in large scales. The yields of coupling these Se-nucleoside phosphoramidites into DNA or RNA oligonucleotides were over 99% when 5-(benzylmercapto)-1H-tetrazole was used as the coupling reagent. The UV melting study of A-form dsDNAs indicated that the 2′-selenium derivatization had no effect on the stability of the duplexes with the 3′-endo sugar pucker. Thus, the stems of functional RNA molecules with the same 3′-endo sugar pucker appear to be the ideal sites for the selenium derivatization with 2′-Se-C and 2′-Se-U. Crystallization of the selenium-derivatized oligonucleotides is also reported here. The results demonstrate that this 2′-selenium functionality is suitable for RNA and A-form DNA derivatization in X-ray crystallography.     

New oligodeoxyribonucleotide derivatives bearing internucleotide <Emphasis Type="Italic">N</Emphasis>-tosyl phosphoramidate groups: Synthesis and complementary binding to DNA and RNA

N-Sulfonyl phosphoramidate derivatives of oligodeoxyribonucleotides containing N-tosyl phosphoramidate groups are first reported. The synthesis is based on Staudinger reaction between tosyl azide and 3′,5′-dinucleoside β-cyanoethyl phosphite comprising the immobilized oligonucleotide, which is obtained by the phosphoramidite coupling during the solid-phase oligonucleotide synthesis. The N-tosyl phosphoramidate group was stable under conditions of the oligonucleotide synthesis, in particular, upon acidic detritylation followed by the removal of protective groups and cleavage from the polymer support by the treatment with concentrated aqueous ammonia at 55°C. The stability of DNA and RNA duplexes of the model oligonucleotides containing N-tosyl phosphoramidate groups was only slightly lower than that of native DNA:DNA and DNA:RNA duplexes, respectively.     

Ferrocene conjugated oligonucleotide for electrochemical detection of DNA base mismatch

We describe the synthesis, binding, and electrochemical properties of ferrocene-conjugated oligonucleotides (Fc-oligos). The key step for the preparation of Fc-oligos contains the coupling of vinylferrocene to 5-iododeoxyuridine via Heck reaction. The Fc-conjugated deoxyuridine phosphoramidite was used in the Fc-oligonucleotide synthesis. We show that thiol-modified Fc-oligos deposited onto gold electrodes possess potential ability in electrochemical detection of DNA base mismatch.     

The reaction of Tetrazole with Phosphoramidites as a Model for the Nucleotide Coupling Step

Abstract

The mechanism of the tetrazole-activated coupling step in the synthesis of oligonucleotides via phosphorami-dites is studied with the help of model reactions.     

Removal of mismatched bases from synthetic genes by enzymatic mismatch cleavage

The success of long polynucleotide de novo synthesis is largely dependent on the quality and purity of the oligonucleotides used. Generally, the primary product of any synthesis reaction is directly cloned, and clones with correct products have to be identified. In this study, a novel strategy has been established for removing undesired sequence variants from primary gene synthesis products. Single base-pair mismatches, insertions and deletions were cleaved with specific endonucleases. Three different enzymes—T7 endonuclease I, T4 endonuclease VII and Escherichia coli endonuclease V—have been tested. As a model, a synthetic polynucleotide encoding the bacterial chloramphenicol-acetyltransferase (cat) was synthesized using different methods for one step polynucleotide synthesis based on ligation of oligonucleotides. The influence of enzymatic mismatch cleavage (EMC) as an error correction step on the frequency of correct products was analyzed by functional cloning of the synthetic cat and comparing the error rate with that of untreated products. Significant reduction of all mutation types was observed. Statistical analysis revealed that the T4 and E.coli endonucleases reduced the occurrence of mutations in cloned synthetic gene products. The EMC treatment was successful especially in the removal of deletions and insertions from the primary ligation products.     

Direct adenylation from 5′-OH-terminated oligonucleotides by a fusion enzyme containing Pfu RNA ligase and T4 polynucleotide kinase

5′-Adenylated oligonucleotides (AppOligos) are widely used for single-stranded DNA/RNA ligation in next-generation sequencing (NGS) applications such as microRNA (miRNA) profiling. The ligation between an AppOligo adapter and target molecules (such as miRNA) no longer requires ATP, thereby minimizing potential self-ligations and simplifying library preparation procedures. AppOligos can be produced by chemical synthesis or enzymatic modification. However, adenylation via chemical synthesis is inefficient and expensive, while enzymatic modification requires pre-phosphorylated substrate and additional purification. Here we cloned and characterized the Pfu RNA ligase encoded by the PF0353 gene in the hyperthermophilic archaea Pyrococcus furiosus. We further engineered fusion enzymes containing both Pfu RNA ligase and T4 polynucleotide kinase. One fusion enzyme, 8H-AP, was thermostable and can directly catalyze 5′-OH-terminated DNA substrates to adenylated products. The newly discovered Pfu RNA ligase and the engineered fusion enzyme may be useful tools for applications using AppOligos.     

Simple, efficient protocol for enzymatic synthesis of uniformly 13C, 15N-labeled DNA for heteronuclear NMR studies.

The use of uniformly 13C,15N-labeled RNA has greatly facilitated structural studies of RNA oligonucleotides by NMR. Application of similar methodologies for the study of DNA has been limited, primarily due to the lack of adequate methods for sample preparation. Methods for both chemical and enzymatic synthesis of DNA oligonucleotides uniformly labeled with 13C and/or 15N have been published, but have not yet been widely used. We have developed a modified procedure for preparing uniformly 13C,15N-labeled DNA based on enzymatic synthesis using Taq DNA polymerase. The highly efficient protocol results in quantitative polymerization of the template and approximately 80% incorporation of the labeled dNTPs. Procedures for avoiding non-templated addition of nucleotides or for their removal are given. The method has been used to synthesize several DNA oligonucleotides, including two complementary 15 base strands, a 32 base DNA oligonucleotide that folds to form an intramolecular triplex and a 12 base oligonucleotide that dimerizes and folds to form a quadruplex. Heteronuclear NMR spectra of the samples illustrate the quality of the labeled DNA obtained by these procedures.     

Improved PCR-based gene synthesis method and its application to the Citrobacter freundii phytase gene codon modification

Gene synthesis technologies provide a powerful tool for increasing protein expression through codon optimization and gene modification. Here we describe an improved PCR-based gene synthesis technology, which is accurate, simple and cheap. The improved PCR-based gene synthesis (IPS) method consists of two steps. The first one is the synthesis of 300-400 bp fragments by PCR reaction with Pfu DNA polymerase from 60-mer and 30-mer oligonucleotides with a 15 bp overlap. The second one is assembling of fragments from the first step into the full-length gene by PCR reaction. Using this approach, we have successfully synthesized a modified phytase gene with 1256 bp in length with optimal codons for expression in Pichia pastoris. P. pastoris strain that expressed the modified phytase gene (phyA-mod) showed a 50% increase in phytase activity level. In addition, we propose an inexpensive method for error correction, based on overlap-extension PCR (OE-PCR).     

Sequential gene function in the initiation of Saccharomyces cerevisiae DNA synthesis

Four steps are known to be required for the initiation of DNA synthesis in Saccharomyces cerevisiae. Three of these are mediated by the products of genes cdc 4, 7, and 28 and the fourth is identified by the inhibition exerted on haploid α cells by the mating pheromone, α factor. These four steps have been ordered by a combination of two methods and found to be:

initiation of DNA synthesis The two sequencing methods are described in detail. Experiments involving the shift of mutant cells from the restrictive to the permissive temperature in the presence of cycloheximide demonstrated that the protein synthesis requirement for yeast DNA replication can be completed before the cdc 7-mediated step.     

Enzymatic synthesis of biphenyl-DNA oligonucleotides

The incorporation of nucleotides equipped with C-glycosidic aromatic nucleobases into DNA and RNA is an alluring strategy for a number of practical applications including fluorescent labelling of oligonucleotides, expansion of the genetic alphabet for the generation of aptamers and semi-synthetic organisms, or the modulation of excess electron transfer within DNA. However, the generation of C-nucleoside containing oligonucleotides relies mainly on solid-phase synthesis which is quite labor intensive and restricted to short sequences. Here, we explore the possibility of constructing biphenyl-modified DNA sequences using enzymatic synthesis. The presence of multiple biphenyl-units or biphenyl residues modified with electron donors and acceptors permits the incorporation of a single dBphMP nucleotide. Moreover, templates with multiple abasic sites enable the incorporation of up to two dBphMP nucleotides, while TdT-mediated tailing reactions produce single-stranded DNA oligonucleotides with four biphenyl residues appended at the 3′-end.     

Chemical and photochemical error rates in light-directed synthesis of complex DNA libraries

Nucleic acid microarrays are the only tools that can supply very large oligonucleotide libraries, cornerstones of the nascent fields of de novo gene assembly and DNA data storage. Although the chemical synthesis of oligonucleotides is highly developed and robust, it is not error free, requiring the design of methods that can correct or compensate for errors, or select for high-fidelity oligomers. However, outside the realm of array manufacturers, little is known about the sources of errors and their extent. In this study, we look at the error rate of DNA libraries synthesized by photolithography and dissect the proportion of deletion, insertion and substitution errors. We find that the deletion rate is governed by the photolysis yield. We identify the most important substitution error and correlate it to phosphoramidite coupling. Besides synthetic failures originating from the coupling cycle, we uncover the role of imperfections and limitations related to optics, highlight the importance of absorbing UV light to avoid internal reflections and chart the dependence of error rate on both position on the array and position within individual oligonucleotides. Being able to precisely quantify all types of errors will allow for optimal choice of fabrication parameters and array design.     

Simple methods for the 3′ biotinylation of RNA

Biotinylation of RNA allows its tight coupling to streptavidin and is thus useful for many types of experiments, e.g., pull-downs. Here we describe three simple techniques for biotinylating the 3′ ends of RNA molecules generated by chemical or enzymatic synthesis. First, extension with either the Schizosaccharomyces pombe noncanonical poly(A) polymerase Cid1 or Escherichia coli poly(A) polymerase and N6-biotin-ATP is simple, efficient, and generally applicable independently of the 3′-end sequences of the RNA molecule to be labeled. However, depending on the enzyme and the reaction conditions, several or many biotinylated nucleotides are incorporated. Second, conditions are reported under which splint-dependent ligation by T4 DNA ligase can be used to join biotinylated and, presumably, other chemically modified DNA oligonucleotides to RNA 3′ ends even if these are heterogeneous as is typical for products of enzymatic synthesis. Third, we describe the use of ϕ29 DNA polymerase for a template-directed fill-in reaction that uses biotin-dUTP and, thanks to the enzyme''s proofreading activity, can cope with more extended 3′ heterogeneities.     

A New Method of Synthesis of Fluorescently Labelled Oligonucleotides and Their Application in DNA Sequencing

Abstract

A new approach to the chemical synthesis of oligonucleotides bearing reporter functional groups based on the modification of cytosine residues during the final deprotection step is reported. The application of the fluorescently labelled primer for the automated DNA sequencing is shown.     

'Protected DNA Probes' capable of strong hybridization without removal of base protecting groups

We propose a new strategy called the ‘Protected DNA Probes (PDP) method’ in which appropriately protected bases selectively bind to the complementary bases without the removal of their base protecting groups. Previously, we reported that 4-N-acetylcytosine oligonucleotides (ac⁴C) exhibited a higher hybridization affinity for ssDNA than the unmodified oligonucleotides. For the PDP strategy, we created a modified adenine base and synthesized an N-acylated deoxyadenosine mimic having 6-N-acetyl-8-aza-7-deazaadenine (ac⁶az⁸c⁷A). It was found that PDP containing ac⁴C and ac⁶az⁸c⁷A exhibited higher affinity for the complementary ssDNA than the corresponding unmodified DNA probes and showed similar base recognition ability. Moreover, it should be noted that this PDP strategy could guarantee highly efficient synthesis of DNA probes on controlled pore glass (CPG) with high purity and thereby could eliminate the time-consuming procedures for isolating DNA probes. This strategy could also avoid undesired base-mediated elimination of DNA probes from CPG under basic conditions such as concentrated ammonia solution prescribed for removal of base protecting groups in the previous standard approach. Here, several successful applications of this strategy to single nucleotide polymorphism detection are also described in detail using PDPs immobilized on glass plates and those prepared on CPG plates, suggesting its potential usefulness.     

Oligonucleotide Array for Identification and Detection of Pythium Species

A DNA array containing 172 oligonucleotides complementary to specific diagnostic regions of internal transcribed spacers (ITS) of more than 100 species was developed for identification and detection of Pythium species. All of the species studied, with the exception of Pythium ostracodes, exhibited a positive hybridization reaction with at least one corresponding species-specific oligonucleotide. Hybridization patterns were distinct for each species. The array hybridization patterns included cluster-specific oligonucleotides that facilitated the recognition of species, including new ones, belonging to groups such as those producing filamentous or globose sporangia. BLAST analyses against 500 publicly available Pythium sequences in GenBank confirmed that species-specific oligonucleotides were unique to all of the available strains of each species, of which there were numerous economically important ones. GenBank entries of newly described species that are not putative synonyms showed no homology to sequences of the spotted species-specific oligonucleotides, but most new species did match some of the cluster-specific oligonucleotides. Further verification of the specificity of the DNA array was done with 50 additional Pythium isolates obtained by soil dilution plating. The hybridization patterns obtained were consistent with the identification of these isolates based on morphology and ITS sequence analyses. In another blind test, total DNA of the same soil samples was amplified and hybridized on the array, and the results were compared to those of 130 Pythium isolates obtained by soil dilution plating and root baiting. The 13 species detected by the DNA array corresponded to the isolates obtained by a combination of soil dilution plating and baiting, except for one new species that was not represented on the array. We conclude that the reported DNA array is a reliable tool for identification and detection of the majority of Pythium species in environmental samples. Simultaneous detection and identification of multiple species of soilborne pathogens such as Pythium species could be a major step forward for epidemiological and ecological studies.     

Covalent attachment of oligodeoxyribonucleotides to amine-modified Si (001) surfaces

A recently described reaction for the UV-mediated attachment of alkenes to silicon surfaces is utilized as the basis for the preparation of functionalized silicon surfaces. UV light mediates the reaction of t-butyloxycarbonyl (t-BOC) protected ω-unsaturated aminoalkane (10-aminodec-1-ene) with hydrogen-terminated silicon (001). Removal of the t-BOC protecting group yields an aminodecane-modified silicon surface. The resultant amino groups can be coupled to thiol-modified oligodeoxyribonucleotides using a heterobifunctional crosslinker, permitting the preparation of DNA arrays. Two methods for controlling the surface density of oligodeoxyribonucleotides were explored: in the first, binary mixtures of 10-aminodec-1-ene and dodecene were utilized in the initial UV-mediated coupling reaction; a linear relationship was found between the mole fraction of aminodecene and the density of DNA hybridization sites. In the second, only a portion of the t-BOC protecting groups was removed from the surface by limiting the time allowed for the deprotection reaction. The oligodeoxyribonucleotide-modified surfaces were extremely stable and performed well in DNA hybridization assays. These surfaces provide an alternative to gold or glass for surface immobilization of oligonucleotides in DNA arrays as well as a route for the coupling of nucleic acid biomolecular recognition elements to semiconductor materials.