Quikgene: a gene synthesis method integrated with ligation-free cloning

Gene synthesis is a convenient tool that is widely used to make genes for a variety of purposes. All current protocols essentially take inside-out approaches to assemble complete genes using DNA oligonucleotides or intermediate fragments. Here we present an efficient method that integrates gene synthesis and cloning into one step. Our method, which is evolved from QuikChange mutagenesis, can modify, extend, or even de novo synthesize relatively large genes. The genes are inserted directly into vectors without ligations or subcloning. We de novo synthesized a 600-bp gene through multiple steps of polymerase chain reaction (PCR) directly into a bacterial expression vector. This outside-in gene synthesis method is called Quikgene. Furthermore, we have defined an overlap region of a minimum of nine nucleotides in insertion primers that is sufficient enough to circularize PCR products for efficient transformation, allowing one to significantly reduce the lengths of primers. Taken together, our protocol greatly extends the current length limit for QuikChange insertion. More importantly, it combines gene synthesis and cloning into one step. It has potential applications for high-throughput structural genomics.     

Experimental analysis of gene assembly with TopDown one-step real-time gene synthesis

Herein we present a simple, cost-effective TopDown (TD) gene synthesis method that eliminates the interference between the polymerase chain reactions (PCR) assembly and amplification in one-step gene synthesis. The method involves two key steps: (i) design of outer primers and assembly oligonucleotide set with a melting temperature difference of >10°C and (ii) utilization of annealing temperatures to selectively control the efficiencies of oligonucleotide assembly and full-length template amplification. In addition, we have combined the proposed method with real-time PCR to analyze the step-wise efficiency and the kinetics of the gene synthesis process. Gel electrophoresis results are compared with real-time fluorescence signals to investigate the effects of oligonucleotide concentration, outer primer concentration, stringency of annealing temperature, and number of PCR cycles. Analysis of the experimental results has led to insights into the gene synthesis process. We further discuss the conditions for preventing the formation of spurious DNA products. The TD real-time gene synthesis method provides a simple and efficient method for assembling fairly long DNA sequence, and aids in optimizing gene synthesis conditions. To our knowledge, this is the first report that utilizes real-time PCR for gene synthesis.     

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).     

New insights into the de novo gene synthesis using the automatic kinetics switch approach

Here we present a simple, highly efficient, universal automatic kinetics switch (AKS) gene synthesis method that enables synthesis of DNA up to 1.6 kbp from 1 nM oligonucleotide with just one polymerase chain reaction (PCR) process. This method eliminates the interference between the PCR assembly and amplification in one-step gene synthesis and simultaneously maximizes the amplification of emerged desired DNA by using a pair of flanked primers. In addition, we describe an analytical model of PCR gene synthesis based on the thermodynamics and kinetics of DNA hybridization. The kinetics difference between standard PCR amplification and one-step PCR gene synthesis is analyzed using this model and is validated using real-time gene synthesis with eight gene segments (318-1656 bp). The effects of oligonucleotide concentration, stringency of annealing temperature, annealing time, extension time, and PCR buffer conditions are examined systematically. Analysis of the experimental results leads to new insights into the gene synthesis process and aids in optimizing gene synthesis conditions. We further extend this method for multiplexing gene assembly with a total DNA length up to 5.74 kbp from 1 nM oligonucleotide.     

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.     

Patch oligodeoxynucleotide synthesis (POS): a novel method for synthesis of long DNA sequences and full-length genes

Synthesis of long DNA fragments is often associated with mutations and requires multiple DNA manipulation steps. A novel DNA synthesis method, referred to as patch oligodeoxynucleotide synthesis (POS) to assembly long DNA fragments is presented here. This method involves connection of two types of oligodeoxynucleotides: long constructional oligonucleotides (COs) and short patch oligonucleotides (POs). Long COs were connected by a ligase with the aid of POs, which were complementary to both adjacent COs to help remove secondary structures during assembly. The partial double-stranded DNA template that was formed was then amplified by PCR. Accordingly, we synthesized SV40 polyadenylation signal sequences (187 bp), a codon-optimized yellow fluorescent protein gene (678 bp), and Rattus norvegicus catenin β1 (2,352 bp). This presented method can be broadly applied to synthesize DNA fragments of varying lengths with great convenience.     

A modified method for PCR-directed gene synthesis from large number of overlapping oligodeoxyribonucleotides

Here we report an improved, reproducible, simple, rapid, and cost-effective PCR-based DNA synthesis method using short (25–40 bp) overlapping oligodeoxyribonucleotides (oligos). The method involves two steps; (1) assembly of multiple/overlapping oligos by PCR to generate the template DNA and (2) amplification of the template DNA sequence with the two outermost oligos as primers. We have tested this method by synthesizing approximately 35 genes ranging in size between 300 bp and 1700 bp and G + C content from moderate (30%) to high (65%). In addition, we used the method to introduce 29 mutations simultaneously into a single gene. Key to the success of this method is the use of optimized oligo concentrations and the type of DNA polymerase used. This simplified and highly reproducible method is expected to be beneficial for the synthesis of a wide variety of genes.     

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.     

A direct and efficient PAGE-mediated overlap extension PCR method for gene multiple-site mutagenesis

A simple, two-step efficient method to perform multiple-site mutagenesis of a gene from bacterial genome was developed. The method was named polyacrylamide gel electrophoresis (PAGE)-mediated overlap extension polymerase chain reaction (PCR) (POEP). The first step involves synthesis of individual fragments containing mutant sites with 15- to 25-bp overlap between two adjacent fragments. Mutations were introduced into the overlapping oligonucleotide primers which ensured the particular primer-template annealing. PAGE was used to remove contaminating parental templates, mispriming fragments, and leftover primers. The second step involves synthesis of the mutant full-length fragment. All purified PCR products from the first step were combined and used as the template for a second PCR using high-fidelity DNA polymerase, with the two outermost flanking oligonucleotides as primers. Using the POEP method, we have successfully introduced eight EcoRI sites into the Escherichia coli β-galactosidase (Lac Z) gene. The overall rate of obtaining the multiple mutant sites was 100%. The POEP method is simple, involving only two steps, and reliable for multiple-site mutagenesis and is promising to be widely used in gene modification.     

DNAWorks: an automated method for designing oligonucleotides for PCR-based gene synthesis

The availability of sequences of entire genomes has dramatically increased the number of protein targets, many of which will need to be overexpressed in cells other than the original source of DNA. Gene synthesis often provides a fast and economically efficient approach. The synthetic gene can be optimized for expression and constructed for easy mutational manipulation without regard to the parent genome. Yet design and construction of synthetic genes, especially those coding for large proteins, can be a slow, difficult and confusing process. We have written a computer program that automates the design of oligonucleotides for gene synthesis. Our program requires simple input information, i.e. amino acid sequence of the target protein and melting temperature (needed for the gene assembly) of synthetic oligonucleotides. The program outputs a series of oligonucleotide sequences with codons optimized for expression in an organism of choice. Those oligonucleotides are characterized by highly homogeneous melting temperatures and a minimized tendency for hairpin formation. With the help of this program and a two-step PCR method, we have successfully constructed numerous synthetic genes, ranging from 139 to 1042 bp. The approach presented here simplifies the production of proteins from a wide variety of organisms for genomics-based studies.     

Gene synthesis technology: recent developments and future prospects

Gene synthesis is a potentially powerful tool in molecular biology that has not yet reached widespread use because of the relatively high cost and labor-intensive nature of the process. This paper reviews some recent technological developments and current research activities of this laboratory which promise to greatly reduce the cost of gene synthesis and to increase the speed and efficiency of the process. We recently developed an improved device for "segmented" synthesis of oligonucleotides, which utilizes porous Teflon wafers containing derivatized controlled pore glass supports to simultaneously synthesize up to 100 different DNA sequences. The stepwise coupling efficiency with the "wafer synthesis device" is as high as that attained with current automated "gene machines" producing 1-4 oligonucleotides at a time, whereas the reagent usage is only 20-50% that of the current DNA synthesizers. At present, we are optimizing the conditions for rapid, efficient assembly of genes on a solid-phase support, wherein ordered, stepwise annealing/washing is performed to segmentally elongate a "starting" oligonucleotide attached to a solid-phase support. We expect that the wafer synthesis device (operated at reduced scale of synthesis), together with solid-phase gene assembly, will permit the synthesis and assembly of an average size gene (1 kb) in one week at a cost of less than $1000. These developments should make gene synthesis a routine and powerful tool in molecular biology.     

Rational de novo gene synthesis by rapid polymerase chain assembly (PCA) and expression of endothelial protein-C and thrombin receptor genes

The assembly of synthetic oligonucleotides into genes and genomes is an important methodology. Several methodologies for such synthesis have been developed, but they have two drawbacks: (1) the processes are slow and (2) the error frequencies are high (typically 1-3 errors/kb of DNA). Thermal damage is a major contributor to biosynthetic errors. In this paper, we elucidate the advantages of rapid gene synthesis by polymerase chain assembly (PCA) when used in combination with smart error control strategies. We used a high-speed thermocycler (PCRJet) to effectively minimize thermal damage and to perform rapid assembly of synthetic oligonucleotides to construct two different genes: endothelial protein C receptor (EPCR) and endothelial cell thrombin receptor, thrombomodulin (TM). First, the intact EPCR gene (EPCR-1, 612 bp) and a mutant EPCR-2 (576 bp) that lacked 4 N-linked glycosylation sites were constructed from 35 and 33 oligonucleotides, respectively. Next, for direct error comparison, another longer gene, the 1548 bp TM gene was constructed from 87 oligonucleotides by both rapid and conventional PCA. The fidelity and accuracy of the synthetic genes generated in this manner were confirmed by sequencing. The combined steps of PCA and DNA amplification are completed in about 10 and 22 min for EPCR-1, 2 and TM genes, respectively with comparable low errors in the DNA sequence. Furthermore, we subcloned synthetic TM, EPCR-1, EPCR-2 and native EPCR-1 (amplified from cDNA) into a Pichia pastoris expression vector to evaluate the expression ability, and to compare them with the native gene. Here, we illustrate that the synthetic genes, assembled by rapid PCA, successfully directed the expression of functional proteins. And, importantly, the synthetic and the native genes expressed proteins with the same efficiency.     

Scalable gene synthesis by selective amplification of DNA pools from high-fidelity microchips

Development of cheap, high-throughput and reliable gene synthesis methods will broadly stimulate progress in biology and biotechnology. Currently, the reliance on column-synthesized oligonucleotides as a source of DNA limits further cost reductions in gene synthesis. Oligonucleotides from DNA microchips can reduce costs by at least an order of magnitude, yet efforts to scale their use have been largely unsuccessful owing to the high error rates and complexity of the oligonucleotide mixtures. Here we use high-fidelity DNA microchips, selective oligonucleotide pool amplification, optimized gene assembly protocols and enzymatic error correction to develop a method for highly parallel gene synthesis. We tested our approach by assembling 47 genes, including 42 challenging therapeutic antibody sequences, encoding a total of ～35 kilobase pairs of DNA. These assemblies were performed from a complex background containing 13,000 oligonucleotides encoding ～2.5 megabases of DNA, which is at least 50 times larger than in previously published attempts.     

Utilization of ribonucleotides and RNA primers by Tetrahymena telomerase.

Telomerase is a ribonucleoprotein (RNP) DNA polymerase involved in telomere synthesis. A short sequence within the telomerase RNA component provides a template for de novo addition of the G-rich strand of a telomeric simple sequence repeat onto chromosome termini. In vitro, telomerase can elongate single-stranded DNA primers processively: one primer can be extended by multiple rounds of template copying before product dissociation. Telomerase will incorporate dNTPs or ddNTPs and will elongate any G-rich, single-stranded primer DNA. In this report, we show that Tetrahymena telomerase was able to incorporate a ribonucleotide, rGTP, into product polynucleotide. Synthesis of the product [d(TT)r(GGGG)]n was processive, suggesting that the chimeric product remained associated with the enzyme both at the active site and at a second, previously characterized, template-independent product binding site. As predicted by this finding, RNA-containing oligonucleotides served as primers for elongation. More than 3 nt of RNA at a primer 3' end decreased the quantity of product synthesis but increased the affinity of the primer for telomerase. Thus, RNA-containing primers were effective as competitive inhibitors of DNA primer elongation by telomerase. These results support the possible evolutionary origin of telomerase as an RNA-dependent RNA polymerase.     

Dual asymmetric PCR: one-step construction of synthetic genes.

We have developed a one-step process for constructing synthetic genes. Four adjacent oligonucleotides 17-100 bases in length having short overlaps of 15-17 bases are used as primers in a PCR mixture. The quantity of the two internal primers is highly limited, and the resultant reaction causes an asymmetric single-stranded amplification of the two halves of the total sequence due to an excess of the two flanking primers. In subsequent PCR cycles, these dual asymmetrically amplified fragments, which overlap each other, yield a double-stranded, full-length product.     

Amplification and assembly of chip-eluted DNA (AACED): a method for high-throughput gene synthesis

A basic problem in gene synthesis is the acquisition of many short oligonucleotide sequences needed for the assembly of genes. Photolithographic methods for the massively parallel synthesis of high-density oligonucleotide arrays provides a potential source, once appropriate methods have been devised for their elution in forms suitable for enzyme-catalyzed assembly. Here, we describe a method based on the photolithographic synthesis of long (>60mers) single-stranded oligonucleotides, using a modified maskless array synthesizer. Once the covalent bond between the DNA and the glass surface is cleaved, the full-length oligonucleotides are selected and amplified using PCR. After cleavage of flanking primer sites, a population of unique, internal 40mer dsDNA sequences are released and are ready for use in biological applications. Subsequent gene assembly experiments using this DNA pool were performed and were successful in creating longer DNA fragments. This is the first report demonstrating the use of eluted chip oligonucleotides in biological applications such as PCR and assembly PCR.     

Rapid gene splicing and multi-sited mutagenesis by one-step overlap extension polymerase chain reaction

Gene splicing and site-directed mutagenesis (SDM) are important to introduce desired sequences in target DNA. However, introducing mutations at multiple sites requires multiple steps of DNA manipulation, which is time-consuming and labor-intensive. Here, we present a rapid efficient gene splicing and multi-sited mutagenesis method that introduces mutations at two distant sites via sequential connection of DNA fragments by one-step overlap extension polymerase chain reaction (OE-PCR). This bottom-up approach for DNA engineering can be broadly used to study protein structure-function, to optimize codon use for protein expression, and to assemble genes of interest.     

Microfluidic PicoArray synthesis of oligodeoxynucleotides and simultaneous assembling of multiple DNA sequences

Large DNA constructs of arbitrary sequences can currently be assembled with relative ease by joining short synthetic oligodeoxynucleotides (oligonucleotides). The ability to mass produce these synthetic genes readily will have a significant impact on research in biology and medicine. Presently, high-throughput gene synthesis is unlikely, due to the limits of oligonucleotide synthesis. We describe a microfluidic PicoArray method for the simultaneous synthesis and purification of oligonucleotides that are designed for multiplex gene synthesis. Given the demand for highly pure oligonucleotides in gene synthesis processes, we used a model to improve key reaction steps in DNA synthesis. The oligonucleotides obtained were successfully used in ligation under thermal cycling conditions to generate DNA constructs of several hundreds of base pairs. Protein expression using the gene thus synthesized was demonstrated. We used a DNA assembly strategy, i.e. ligation followed by fusion PCR, and achieved effective assembling of up to 10 kb DNA constructs. These results illustrate the potential of microfluidics-based ultra-fast oligonucleotide parallel synthesis as an enabling tool for modern synthetic biology applications, such as the construction of genome-scale molecular clones and cell-free large scale protein expression.     

A PCR-mediated gene synthesis strategy involving the assembly of oligonucleotides representing only one of the strands.

A modification of PCR-mediated gene synthesis strategy is introduced. This modification enables the synthesis of a gene from oligonucleotides comprising only one of the two strands. Bridging oligonucleotides (approximately 20-mers in length) complementary to the junctions of template strand oligonucleotides and two outer primers are also needed for PCR. A two-step PCR containing a first step of 10 cycles, followed by a second step of 20 cycles, differing only in the annealing conditions was used. A single-step PCR combining the two different cycle conditions could also be used successfully. Optimal conditions for gene synthesis (and amplification) are described. Human and porcine colipase genes (297 and 309 bp, respectively) have been successfully synthesized, cloned into the Invitrogen TA cloning vector and sequenced. There was absolutely no error in the clones that were sequenced.