Production of complex nucleic acid libraries using highly parallel in situ oligonucleotide synthesis

Generation of complex libraries of defined nucleic acid sequences can greatly aid the functional analysis of protein and gene function. Previously, such studies relied either on individually synthesized oligonucleotides or on cellular nucleic acids as the starting material. As each method has disadvantages, we have developed a rapid and cost-effective alternative for construction of small-fragment DNA libraries of defined sequences. This approach uses in situ microarray DNA synthesis for generation of complex oligonucleotide populations. These populations can be recovered and either used directly or immortalized by cloning. From a single microarray, a library containing thousands of unique sequences can be generated. As an example of the potential applications of this technology, we have tested the approach for the production of plasmids encoding short hairpin RNAs (shRNAs) targeting numerous human and mouse genes. We achieved high-fidelity clone retrieval with a uniform representation of intended library sequences.     

Multiple oligonucleotide synthesis in tandem on solid-phase supports for small and large scale synthesis

Multiple oligonucleotides linked end-to-end in tandem can be synthesized by adding a nucleoside to the 5'-OH end of a prior sequence. Nucleosides with 3'-succinyl or Q-Linker arms are coupled with HBTU/DMAP. Alternatively, new phosphoramidite reagents with 3'-ester linkages can be used. Hydroxyl or amino supports can also be used as universal starting materials. Treatment with NH4OH cleaves the 3'-ester to yield only 3'-OH groups and no unwanted 3'-phosphorylated products occur.     

Ultrasensitive nucleic acid biosensors for early cancer diagnostics

We have developed ultrasensitive nucleic acid detection systems involving an amplification step where the analytical signal correlates directly to the amount of nucleic acid in the solution So far, we have performed nucleic acid quantification on several breast cancer susceptibility genes and were able to detect nucleic acid amounts that ranged from 0.1–1.0 fg of nucleic acid, which is at least 1000 times more sensitive than conventional fluorescent detection methods. The biosensors are so sensitive that they can be used for direct detection of breast cancer susceptibility genes in mRNA without involving a PCR step.     

Versatile solid supports for oligonucleotide synthesis that incorporate urea bridge

The universal solid support, USIII, representing a new and improved version of commercial USII, as well as 2 '-deoxynucleoside and 2 '-deoxy-2 '-fluoronucleoside bound supports, incorporating a labile phenoxyacetyl fragment, was synthesized by an aminomethyl polystyrene carbamoylation with corresponding azides in the presence of aqueous triethylammonium bicarbonate. All three solid phases incorporate a stable urea tether, thus bridging the polymer and functional linker. These new matrices proved to be potent solid phases for the synthesis of DNA, RNA, or modified oligonucleotides as well as randomized mixed 2 '-ribo/2 '-deoxy-2 '-fluoro-RNA libraries and/or DNA libraries, randomized with trinucleotides (codons).     

Nucleotide metabolism and nucleic acid synthesis in mouse thymocytes.

Nucleotide pool sizes, DNA polymerizing enzymes, and DNA synthesis were studied in mouse thymocytes over a 24-hr period of culture in Marbrook chambers. The initial rate of cell division was high with an average mitotic index of 1.6%/hr for 12 hr, followed by a decline to 0.14%/hr at 24 hr. The decline in DNA synthesis was not closely correlated with the activities of DNA-dependent DNA polymerases-α or -β or with the activity of terminal deoxynucleotidyl transferase. The amounts of several ribo- and deoxyribonucleotides per thymocyte were measured using high performance liquid chromatography and DNA polymerase. Pool sizes of ATP, GTP, dATP, and dTTP were less than 10% of pool sizes commonly observed in mammalian cells. The rates of DNA and RNA synthesis in thymocytes may be critically affected by minor changes in the availability of nucleotides. Cultures of thymocytes serve as useful experimental systems for investigation of nucleotide and nucleic acid metabolism during lymphoid differentiation.     

PNA-related oligonucleotide mimics and their evaluation for nucleic acid hybridization studies and analysis

DNA mimics containing phosphonate analogues of PNAs (pPNAs), particularly PNA-pPNA hybrids as well as hetero-oligomers consisted of pPNA units and PNA-like molecules on the base of trans-4-hydroxy-L-proline (HypNA) have been synthesized. The evaluation of their effectiveness in assays based on the hybridization technique in the comparison with natural oligonucleotides and classical PNAs has shown a high potential of these mimics as sensor molecules for nucleic acid based diagnostics and as molecular probes for mRNA isolation.     

Pyrophosphate-condensing activity linked to nucleic acid synthesis.

In some preparations of DNA dependent RNA polymerase a new enzymatic activity has been found which catalyzes the condensation of two pyrophosphate molecules, liberated in the process of RNA synthesis, to one molecule of orthophosphate and one molecule of Mg (or Mn) - chelate complex with trimetaphosphate. This activity can also cooperate with DNA-polymerase, on condition that both enzymes originate from the same cells. These results point to two general conclusions. First, energy is conserved in the overall process of nucleic acid synthesis and turnover, so that the process does not require an energy influx from the cell's general resources. Second, the synthesis of nucleic acids is catalyzed by a complex enzyme system which contains at least two separate enzymes, one responsible for nucleic acid polymerization and the other for energy conservation via pyrophosphate condensation.     

Effect of picroliv on protein and nucleic acid synthesis.

Oral administration of picroliv, a standardised fraction of roots and rhizomes of Picrorhiza kurroa, showed stimulation of nucleic acid and protein synthesis in rat liver. Results are comparable with a standard hepatoprotective agent, silymarin.     

High-density multiplex detection of nucleic acid sequences: oligonucleotide ligation assay and sequence-coded separation.

We describe a non-isotopic, semi-automated method for large-scale multiplex analysis of nucleic acid sequences, using the cystic fibrosis transmembrane regulator (CFTR) gene as an example. Products of a multiplex oligonucleotide ligation assay (OLA) are resolved electrophoretically from one another and from unligated probes under denaturing conditions with fluorescence detection. One ligation probe for each OLA target carries a fluorescent tag, while the other probe carries an oligomeric non-nucleotide mobility modifier. Each OLA product has a unique electrophoretic mobility determined by the ligated oligonucleotides and the mobility-modifier oligomer arbitrarily assigned (coded) to its target. The mobility range for practical mobility modifiers is much wider than the accessible range from unmodified ligated oligonucleotides of practical length. Each mobility modifier is built from phosphoramidite monomers in a stepwise manner on its associated oligonucleotide using an automated synthesizer. The resulting mobility modifiers lower the probe-target duplex Tm by less than 3 degrees C and retard probe-target annealing by less than 50%, with negligible effect on OLA yield and specificity. This method is especially useful for allelic discrimination in highly polymorphic genes such as CFTR.     

Design and synthesis of conformationally frozen peptide nucleic acid backbone: chiral piperidine PNA as a hexitol nucleic acid surrogate

The design and facile synthesis of novel chiral piperidine PNA from naturally occurring 4-hydroxy-L-proline is reported. The stereospecific ring-expansion reaction to get six-membered piperidine derivative from 5-membered pyrrolidine derivative is exploited for this synthesis. The resulting conformationally constrained PNA is utilized for the synthesis of PNA mixmers and the concept is substantiated by UV-Tm studies of the resulting PNA(2):DNA complexes.     

Chemical synthesis and characterization of branched oligodeoxyribonucleotides (bDNA) for use as signal amplifiers in nucleic acid quantification assays.

The divergent synthesis of bDNA structures is described. This new type of branched DNA contains one unique oligonucleotide, the primary sequence, covalently attached through a comb-like branching network to many identical copies of a different oligonucleotide, the secondary sequence. The bDNA comb molecules were assembled on a solid support using parameters optimized for bDNA synthesis. The chemistry was used to synthesize bDNA comb molecules containing 15 secondary sequences. The bDNA comb molecules were elaborated by enzymatic ligation into branched amplification multimers, large bDNA molecules (a total of 1068 nt) containing an average of 36 repeated DNA oligomer sequences, each capable of hybridizing specifically to an alkaline phosphatase-labeled oligonucleotide. The bDNA comb molecules were characterized by electrophoretic methods and by controlled cleavage at periodate-cleavable moieties incorporated during synthesis. The branched amplification multimers have been used as signal amplifiers in nucleic acid quantification assays for detection of viral infection. It is possible to detect as few as 50 molecules with bDNA technology.     

Synthesis of polyamide supports for use in peptide synthesis and as peptide-resin conjugates for antibody production.

We have synthesized beaded, hydrophilic cross-linked, aminoalkyl polydimethylacrylamide supports upon which peptides have been assembled using standard Boc or Fmoc chemistry in automated equipment. The resins were prepared by the free radical-initiated co-polymerization of N,N-dimethylacrylamide, N,N'-bisacrylyl-1,3-diaminopropane, and a functional monomer which were contained in a reverse-phase, detergent-emulsified suspension. The functional monomers used were N-(2-(methylsulfonyl)ethyloxycarbonyl)-allyl-amine (MSC-allylamine), N-acrylyl-1,6-diaminohexane hydrochloride or N-methacrylyl-1,3-diamino-propane hydrochloride. The MSC protecting group was removed by treatment of the resin with methanolic base during workup. After coupling of N-alpha-t-butyloxycarbonyl-alanine (Boc-alanine), amino acid analyses gave resin loading capacities between 0.15 mmol/g and 1.4 mmol/g, depending on the concentration and composition of the functional monomer. The resulting polymers were highly swollen by polar solvents including aqueous buffers. Peptides were synthesized on these supports after attaching the first amino acid directly or through a cleavable ester linker. When the carboxyl-terminal amino acid was coupled as the 4-oxymethylbenzoic acid derivative, the peptide could be deprotected and remain attached to the hydrophilic polymer since the peptide-benzyl ester bond was stable to HF deprotection at 0 degrees in the presence of 10% anisole and 1% ethanedithiol. The resulting peptidyl-resin could be swollen in aqueous buffers and injected into animals for the production of antibodies.     

Rapid esterification of nucleosides to solid-phase supports for oligonucleotide synthesis using uronium and phosphonium coupling reagents

Nucleosides can be esterified to solid-phase supports using uronium or phosphonium coupling reagents and a coupling additive, such as 1-hydroxybenzotriazole (HOBT), 7-aza-1-hydroxybenzotriazole (HOAT), N-methylimidazole (NMI), or 4-(dimethylamino)pyridine (DMAP). However, DMAP was far superior to other additives and high nucleoside loadings (up to 60 micromol/g) and rapid coupling reactions (< or = 10 min) were possible. Hydroxyl-derivatized CPG was attached to nucleosides with 3'-succinyl or 3'-hydroquinone-O, O'-diacetic acid (HQDA or Q-Linker) carboxyl groups through a primary ester linkage. Alternatively, supports derivatized with succinic acid or the Q-Linker were attached directly to the 3'-OH group of nucleosides through a secondary ester linkage. Uronium reagents (HATU or HBTU) gave the best results with the HQDA linker arm, while the bromophosphonium (BrOP or PyBrOP) reagents were best with the succinyl linker arm. In all cases, the coupling reactions were much faster than previous methods using carbodiimide coupling reagents. The ease and speed of the reaction make this support derivatization procedure suitable for automated in situ couplings on DNA synthesizers.     

Pyrimidine nucleotide and nucleic acid synthesis in human monocytes and macrophages.

In most cell types, the production of deoxynucleotides is tightly coupled to the pace of cell division, and nearly all deoxynucleotides are used for semiconservative DNA synthesis. The capacity of peripheral blood monocytes and macrophages to proliferate is controversial. However, these cells have been reported to produce and release thymidine, which can serve as a precursor or regulator of DNA synthesis by lymphocytes and other cells. To determine to what extent de novo pyrimidine nucleotide synthesis is linked to cell division in peripheral blood monocytes and macrophages, compared to human U937 promonocytes and CEM lymphoblasts, we used a precise precursor-product labeling method. The results showed that in all three cell types, the pace of pyrimidine deoxynucleotide production, and of thymidylate synthesis, was in proportion to the rate of DNA synthesis. The human blood monocytes and macrophages, in contrast to U937 cells, had extraordinarily low deoxyribonucleotide pools (less than 1 pmol/10(6) cells) and synthesized neither thymidylate nor DNA de novo during 7 days culture. Colony-stimulating factors augmented RNA synthesis in monocyte-derived macrophages, and enhanced cell survival, without inducing either DNA or thymidylate synthesis. We conclude that the thymidine released by macrophages derives from dead or dying cells, and not from de novo synthesis.     

Oligonucleotide hybridizations on glass supports: a novel linker for oligonucleotide synthesis and hybridization properties of oligonucleotides synthesised in situ.

A novel linker for the synthesis of oligonucleotides on a glass support is described. Oligonucleotides synthesised on the support remain tethered to the support after ammonia treatment and are shown to take part in sequence specific hybridisation reactions. These hybridizations were carried out with oligonucleotides synthesised on 'ballotini' solid sphere glass beads and microscope slides. The linker has a hexaethylene glycol spacer, bound to the glass via a glycidoxypropyl silane, terminating in a primary hydroxyl group that serves as starting point for automated or manual oligonucleotide synthesis.