Recent patents on oligonucleotide synthesis and gene synthesis

Gene synthesis is an emerging field which has widespread implications in synthetic biology and molecular biology. The field is constantly evolving which has led to key advances in oligonucleotide synthesis and gene synthesis technologies, with simplicity, cost effectiveness and high throughput. The miniaturization, multiplexing, microfluidic processing and the integrated microchip engineering will drive down cost and increase productivity without compromising DNA synthesis fidelity, whereas the gigantic amount of genome information provides infinite source of DNA elements and genes as raw material for synthetic biology. This article describes some of the recent patents on oligonucleotide synthesis and gene synthesis.     

In situ synthesis of oligonucleotide microarrays.

This contribution presents a brief overall look of the methods for the preparation of various types of DNA microarrays and a thorough examination of the methods for in situ synthesis of oligonucleotide microarrays.     

Recent advances in oligonucleotide synthesis and their applications

Short synthetic oligonucleotides are finding wide variety of applications in area of genomics and medicinal chemistry. Since the isolation of nucleic acids to the mapping of human genome, chemical synthesis of nucleic acids has undergone tremendous advancements. Further improvements in this area such as, introduction of high throughput synthesizers, better coupling reagents, improved polymer supports, newer sets of protecting groups for exocyclic amino groups of nucleic bases and introduction of universal polymer supports have completely revolutionized the entire field of nucleic acids chemistry. Most of these developments have been targeted to assemble these molecules more efficiently in a cost-effective manner and rapidly. Preparation of oligonucleotide conjugates has further helped in identifying the newer areas of their applications. A number of conjugates with biological and abiological ligands have been discussed in this article along with their possible wide spectrum of applications. Recently developed microarray technology, which refers to attachment of short oligonucleotides on a solid/polymeric surface, has proved to be useful for screening of genetic mutations, study of polymorphism, as diagnostics, etc. The major developments in these areas are presented in the review.     

Effects of stray light on the fidelity of photodirected oligonucleotide array synthesis

Fabrication of high density oligonucleotide arrays using metal on glass photolithographic masks is inflexible and expensive. Maskless methods using computer-controlled projection have been proposed and implemented, but associated stray light effects on photodirected oligonucleotide synthesis and their analysis have not been reported. We have developed a theoretical approach: it predicts that the stray light content of the output of digital micromirror devices and other spatial light modulators of similar performance (contrast ratio ~400) will cause extensive random base insertions. For example, use of a digital micromirror device for synthesis of a 20mer array will result in the majority of oligonucleotide chains being 21mers or 22mers. This chain lengthening effect of stray light would not be preventable when synthesis involves a directly photosensitive 5′-blocking group. If the 5′-blocking group is acid labile and released with photogenerated acid, the presence of low concentrations of weak base will prevent the effect of stray light. We have demonstrated experimentally the anticipated chain lengthening effect of stray light on photoacid-dependent synthesis of oligonucleotides and prevention of the effect by low concentrations of n-octylamine. The application of these findings should facilitate the development of maskless fabrication and availability of high density and high fidelity user-designed arrays for research applications.     

Analysis of DNA-microarrays produced by inverse in situ oligonucleotide synthesis.

5'-Phosphoramidites protected by 2-nitrophenylethyl (NPE) and 2-(4-nitrophenyl)ethoxy carbonyl (NPEOC) functions were employed for in situ synthesis of oligonucleotides in 5'-->3' direction on flat glass surfaces. By this inverse synthesis format, the oligonucleotides are attached to the solid support via their 5'-ends while the free 3'-hydroxyl groups are available as substrates for enzymatic reactions such as elongation by polymerases, thereby adding another feature to the portfolio of chip-based applications. Having a fluorescence dye present at the first base during synthesis, the quality of the oligonucleotides was analysed quantitatively by capillary electrophoresis after release from the solid support. With about 95% yield per condensation, it was found to be equivalent to synthesis results achieved on CPG support. The chip-bound oligonucleotides could be extended enzymatically upon hybridisation of a DNA-template. Surprisingly, however, only 63% of the oligonucleotides were elongated in polymerase reactions, while oligonucleotides that were released from the support behaved normally in standard PCR amplifications. This rate of 63% nevertheless compares favourably with an extension rate of only 50%, which was achieved under identical conditions, if pre-fabricated oligonucleotides of identical sequence had been spotted to the glass support.     

In situ oligonucleotide synthesis on carbon materials: stable substrates for microarray fabrication

Glass has become the standard substrate for the preparation of DNA arrays. Typically, glass is modified using silane chemistries to provide an appropriate functional group for nucleic acid synthesis or oligonucleotide immobilization. We have found substantial issues with the stability of these surfaces as manifested in the unwanted release of oligomers from the surface when incubated in aqueous buffers at moderate temperatures. To address this issue, we have explored the use of carbon-based substrates. Here, we demonstrate in situ synthesis of oligonucleotide probes on carbon-based substrates using light-directed photolithographic phosphoramidite chemistry and evaluate the stabilities of the resultant DNA arrays compared to those fabricated on silanized glass slides. DNA arrays on carbon-based substrates are substantially more stable than arrays prepared on glass. This superior stability enables the use of high-density DNA arrays for applications involving high temperatures, basic conditions, or where serial hybridization and dehybridization is desired.     

A portable generic DNA bioassay system based on in situ oligonucleotide synthesis and hybridization detection

In this study, we present a portable and generic DNA bioassay system based on in situ oligonucleotide synthesis followed by hybridization based detection. The system include two main parts, an oligonucleotide synthesizer and a fluorescence detection system. The oligonucleotide synthesizer is based on microfluidic technology and capable of synthesizing any desired oligonucleotide which can be either used as a primer for PCR based detection (external) or a probe for hybridization based detection (integrated) of a target DNA analyte. The oligonucleotide sequence can be remotely sent to the system. The integrated fluorescence detection system is based on a photodiode to detect Texas Red fluorophore as low as 0.5 fmol. The complete system, integrating the oligonucleotide synthesizer and fluorescence detection system, was successfully used to distinguish DNA from two different bacteria strains. The presented generic portable instrument has the potential to detect any desired DNA target sequence in the field. Potential applications are for homeland security and fast responses to emerging bio-threats.     

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.     

In situ oligonucleotide synthesis on poly(dimethylsiloxane): a flexible substrate for microarray fabrication

In this paper, we demonstrate in situ synthesis of oligonucleotide probes on poly(dimethylsiloxane) (PDMS) microchannels through use of conventional phosphoramidite chemistry. PDMS polymer was moulded into a series of microchannels using standard soft lithography (micro-moulding), with dimensions <100 μm. The surface of the PDMS was derivatized by exposure to ultraviolet/ozone followed by vapour phase deposition of glycidoxypropyltrimethoxysilane and reaction with poly(ethylene glycol) spacer, resulting in a reactive surface for oligonucleotide coupling. High, reproducible yields were achieved for both 6mer and 21mer probes as assessed by hybridization to fluorescent oligonucleotides. Oligonucleotide surface density was comparable with that obtained on glass substrates. These results suggest PDMS as a stable and flexible alternative to glass as a suitable substrate in the fabrication and synthesis of DNA microarrays.     

Recent highlights in the chemurgy of xerophytic plants

The practical economy of the utilization of the xerophytic plants is dependent upon a fairly complete utilization of the extractives of the particular species involved. For example, agaves (century plants) yield fiber, sapogenins, and some miscellaneous extractives, which vary with the species.     

Photo-cross-linkable oligonucleotide probes for in situ hybridization assays

In situ hybridization techniques have been an important research tool since first introduced 30 years ago, and more recently clinical applications have been expanding greatly. Still, further improvements in the assay sensitivity and protocols that are amenable to routine clinical use are desired. We use a novel photo-cross-linking technology to irreversibly bind short oligonucleotide probes to the target sequence following a hybridization period. The cross-linking agent is incorporated into the backbone of the probe and is activated to react with pyrimidines in the opposite strand by near-UV (300-370 nm) irradiation. By locking the probe to the target, very stringent wash conditions can be used that would otherwise completely remove probes that are hybridized but not cross-linked to the target. Consequently, the probe-specific signal is maximized, while the background signal is minimized to the greatest extent possible with the stringency of the wash. The use of short, photo-cross-linkable probes presents a new strategy for maximizing the sensitivity of probe hybridization or signal amplification-based in situ techniques.     

Computer simulation in template-directed oligonucleotide synthesis

Summary A computer simulation (KINSIM) modeling up to 33 competing reactions was used in order to investigate the product distribution in a template-directed oligonucleotide synthesis as a function of time and concentration of the reactants. The study is focused on the poly(C)-directed elongation reaction of an oligoguanylate (a 7-mer is chosen) with guanosine 5-monophosphate-2-methylimidazolide (2-MeImpG), the activated monomer. It is known that theelongation of oligoguanylates to form oligomeric products such as 8-mer, 9-mer, 10-mer, etc., is in competition with (1) thedimerization and further oligomerization reaction of 2-MeImpG that leads to the formation of dimers and short oligomers, and (2) thehydrolysis of 2-MeImpG that forms inactive guanosine 5-monophosphate, 5-GMP. Experimentally determined rate constants for the above three processes at 37°C and pH 7.95 were used in the simulation; the initial concentrations of 2-MeImpG, [M]_o, and of the oligoguanylate primer, [7-mer]_o, were varied, and KINSIM calculated the distribution of products as a function of time until equilibration was reached, i.e., when all the activated monomer has been consumed. In order to sort out how strongly the elongation reaction may be affected by the competing hydrolysis and dimerization, we also simulated the idealized situation in which these competing reactions do not occur. Simulation of the idealized system suggests that (1) the fraction of [7-mer]_o that has reacted as well as the product distribution after equilibration do not depend on the absolute concentrations of the reactants, but only on their ratio, [M]_o/[7-mer]_o; (2) the rate of elongation is proportional to [7-mer]_o and not to [M]_o; and (3) as the [M]_o/[7-mer]_o ratio increases longer oligomers are formed. The results of the computer simulation with the experimental system, i.e., elongation in the presence of both hydrolysis and dimerization, are similar to the ones obtained with the idealized system as long as dimerization and hydrolysis are not responsible for consuming a substantial fraction of 2-MeImpG.     

Recent highlights in antimalarial drug resistance and chemotherapy research

This review summarizes recent investigations into antimalarial drug resistance and chemotherapy, including reports of some of the many exciting talks and posters on this topic that were presented at the third Molecular Approaches to Malaria meeting held in Lorne, Australia, in February 2008 (MAM 2008). After surveying this area of research, we focus on two important questions: what is the molecular contribution of pfcrt to chloroquine resistance, and what is the mechanism of action of artemisinin? We conclude with thoughts about the current state of antimalarial chemotherapy and priorities moving forward.     

Nucleophilic catalysis in the oligonucleotide synthesis

Rapid procedure for the synthesis of oligonucleotides by the phosphotriester method has been developed. It is based on the use of O-nucleophilic intramolecular catalysis. The application of this method to automated solid-phase oligonucleotide synthesis allows to perform one elongation cycle for 6-7 min.