Non-polymerase-cycling-assembly-based chemical gene synthesis: strategies, methods, and progress.

Chemical gene synthesis is a powerful tool for basic biological research and biotechnology applications. During the last 30 years, major advances have been made in the chemical synthesis of DNA sequences ranging from fragments of <1 kb to multi-gene sequences of >30 kb. There is a need for simple, reproducible, less error-prone and cost-effective methods that guarantee successful synthesis of the desired genes and are amenable to automation. Many polymerase chain reaction (PCR)-based and non-polymerase-cycling-assembly (PCA)-based strategies have been developed for chemical gene synthesis. The PCR-based method has been the subject of several recent reviews. Here, we provide an overview of the progress in non-PCA-based chemical gene synthesis using different strategies and methods, including enzymatic gene synthesis, annealing and ligation reaction, simultaneous synthesis of two genes via a hybrid gene, shotgun ligation and co-ligation, insertion gene synthesis, gene synthesis via one strand of DNA, template-directed ligation, ligase chain reaction, microarray-mediated gene synthesis, Blue Heron solid support technology and Sloning building block technology. The fundamental principle underlying each strategy, an example where applicable, and the advantages and disadvantages are discussed. The emphasis is on discussion of the most recent technologies and their potential applications, particularly for microarray-based genomics research.

Concurrent mutations in six amino acids in beta-glucuronidase improve its thermostability.

To achieve a thermostable beta-glucuronidase (GUS) and identify key mutation sites, we applied in vitro directed evolution strategy through DNA shuffling and obtained a highly thermostable mutant GUS gene, gus-tr, after four rounds of DNA shuffling and screening. This variant had mutations in 15 nucleic acid sites, resulting in changes in 12 amino acids (AAs). Using gus-tr as the template, we further performed site-directed mutagenesis to reverse the individual mutation to the wild-type protein. We found that six sites (Q493R, T509A, M532T, N550S, G559S and N566S) present in GUS-TR3337, were the key AAs needed to confer its high thermostability. Of these, Q493R and T509A were not reported previously as important residues for thermostability of GUS. Furthermore, all of these six mutations must be present concurrently to confer the high thermostability. We expressed the gus-tr3337 gene and purified the GUS-TR3337 protein that contained the six AA mutations. Compared with the wild-type protein which lost its activity completely after 10 min at 70 degrees C, the mutant GUS-TR3337 protein retained 75% of its activity when heated at 80 degrees C for 10 min. The GUS-TR3337 exhibited high activity even heated at 100 degrees C for 30 min on nitrocellulose filter. The comparison of molecular models of the mutated and wild-type enzyme revealed the relation of protein function and these structural modifications.

Directed evolution of beta-galactosidase from Escherichia coli into beta-glucuronidase.

In vitro directed evolution through DNA shuffling is a powerful molecular tool for creation of new biological phenotypes. E. coli beta-galactosidase and beta-glucuronidase are widely used, and their biological function, catalytic mechanism, and molecular structures are well characterized. We applied an in vitro directed evolution strategy through DNA shuffling and obtained five mutants named YG6764, YG6768, YG6769, YG6770 and YG6771 after two rounds of DNA shuffling and screening, which exhibited more beta-glucuronidase activity than wild-type beta-galactosidase. These variants had mutations at fourteen nucleic acid sites, resulting in changes in ten amino acids: S193N, T266A, Q267R, V411A, D448G, G466A, L527I, M543I, Q626R and Q951R. We expressed and purified those mutant proteins. Compared to the wild-type protein, five mutant proteins exhibited high beta-glucuronidase activity. The comparison of molecular models of the mutated and wildtype enzymes revealed the relationship between protein function and structural modification.

Isolated and characterization of a cDNA encoding ethylene-responsive element binding protein (EREBP)/AP2-type protein, RCBF2, in Oryza sativa L.

A transcription factor RCBF2 which interacts with C-repeat/DRE was isolated from Oryza sativa L. by a yeast one-hybrid method. Analysis of the deduced RCBF2 amino acid sequence revealed that RCBF2 contained a conserved ethylene-responsive element binding protein (EREBP)/AP2 domain of 59 amino acids and a potential nuclear localization sequence. RCBF2 showed a high level of homology with other CBF family members only in AP2 domain. Phylogenetic analysis showed that RCBF2 might be different from other eight DRE-binding proteins on evolutionary relationship. The semi-quantitative RT-PCR (s-Q RT-PCR) analysis indicated the expression of RCBF2 gene was induced by cold, dehydration and high-salinity, but not by abscisic acid, and the transcription of RCBF2 gene accumulated primarily in rice immature seeds, growing point and shoots.

[Rational evolutionary design and modification of gene: a short-path of direct evolution].

Directed evolution is a powerful means in academic study and industrial application to modified and functionally improved proteins. There have been significant and impressive advances using the artificial method. Rational Evolutionary Design utilizes structural and sequence alignment information to create new genes and proteins. Rational Evolutionary Design has recently emerged as an attractive approach for studying function of proteins. The review mainly introduced four aspects: preferred codon usage, structural and sequence alignment, key domain analysis, site-directed recombination.

Isolation and characterization of a cDNA encoding two novel heat-shock factor OsHSF6 and OsHSF12 in Oryza sativa L.

As a crucial transcription factor family, heat-shock factors were mainly analyzed and characterized in tomato and Arabidopsis. In this study, we isolated two putative heatshock factors OsHSF6 and OsHSF12 that interact specifically with heat-shock element (HSE) from Oryza sativa L by yeast one-hybrid method. The full-length cDNA of OsHSF6 and OsHSF12 have 1074bp and 920bp open reading frame (ORF), respectively. Analysis of the deduced amino acid sequences revealed that OsHSF6 was a class A heat shock factor (HSF) with all the conserved sequence elements characteristic of heat stress transcription factor, while OsHSF12 was a class B HSF with C-terminal domain (CTD) lacking of AHA motif. Bioinformatic analysis showed that the sequences and structures of two HSFs' DNA binding domain (DBD) had a high similarity with LpHSF24. The results of RT-PCR indicated OsHSF6 gene was expressed immediately after rice plants exposure to heat stress, and the transcription of OsHSF6 gene accumulated primarily in immature seeds, roots and leaves. However, we did not find the transcription of OsHSF12 gene in different organs and growth periods. Our results implied that OsHSF6 might be function as a HSF regulating early expression of stress genes in response to heat shock, and OsHSF12 might be act as a synergistic factor to regulate the expression of down-stream genes.

OsAREB1, an ABRE-binding protein responding to ABA and glucose, has multiple functions in Arabidopsis.

Expression patterns of OsAREB1 revealed that expression of OsAREB1 gene can be induced by ABA, PEG and heat. Yeast one-hybrid assay demonstrated it can bind to ABA-responsive element (ABRE), which was found in most stress-induced genes. Transgenic Arabidopsis over-expressing OsAREB1 had different responses to ABA and glucose compared to wild-type plants, which suggest OsAREB1 might have a crucial role in these two signaling pathways. Further analysis indicate that OsAREB1 have multiple functions in Arabidopsis. First, OsAREB1 transgenic plants had higher resistance to drought and heat, and OsAREB1 up-regulated the ABA/stress related gene such as RD29A and RD29B. Second, it delayed plant flowering time by down-regulating the expression of flowering-related genes, such as FT, SOC1, LFY and AP1. Due to the dates, OsAREB1 may function as a positive regulator in drought/heat stresses response, but a negative regulator in flowering time in Arabidopsis. [BMB reports 2010; 43(1): 34-39].

OsHSF7 gene in rice, Oryza sativa L., encodes a transcription factor that functions as a high temperature receptive and responsive factor.

Three novel Class A genes that encode heat shock transcription factor (HSF) were cloned from Oryza Sativa L using a yeast hybrid method. The OsHSF7 gene was found to be rapidly expressed in high levels in response to temperature, which indicates that it may be involved in heat stress reception and response. Over-expression of OsHSF7 in transgenic Arabidopsis could not induced over the expression of most target heat stress-inducible genes of HSFs; however, the transcription of some HSF target genes was more abundant in transgenic plants following two hours of heat stress treatment. In addition, those transgenic plants also had a higher basal thermotolerance, but not acquired thermotolerance. Collectively, the results of this study indicate that OsHSF7 might play an important role in the response to high temperature. Specifically, these findings indicate that OsHSF7 may be useful in the production of transgenic monocots that can over-express protective genes such as HSPs in response to heat stress, which will enable such plants to tolerate high temperatures. [BMB reports 2009; 42(1): 16-21].

Kamchatka crab duplex-specific nuclease-mediated transcriptome subtraction method for identifying long cDNAs of differentially expressed genes.

The subtraction method is a quick and economical technique to scan differential gene expression. However, most subtraction methods are limited by the complexity and length of cDNA samples. To overcome this problem, we developed a novel method to identify the unique full-length cDNAs in two complicated tissue or cell types. This method, duplex-specific nuclease (DSN)-mediated transcriptome subtraction (DTS), is based on the normalization strategy of the crab duplex-specific nuclease and the subtraction method of suppression subtractive hybridization. DSN eliminates nearly all of the common sequences in the tester and driver cDNA samples after the first hybridization step, ensures accurate discrimination between the tester and the driver cDNA samples, and enriches the full-length differential cDNAs from the tester. Using the DTS method, we have successfully identified an 1812-bp additional GUS gene from the complicated Arabidopsis seedling cDNA library. We also employed DTS to detect the differences in mRNA expression of salt-treated Arabidopsis seedlings to illustrate further the efficiency of the subtraction method.

[Cloning and bioinformatic analysis of the cDNA encoding a novel heat-shock factor OsHSF13 in Oryza sative L].

As a crucial transcription factor family,heat-shock factors were mainly analyzed and characterized in tomato and Arabidposis. In this study, we isolated a putative heat-shock factor OsHSF13 that interacted specifically with heat-shock element (HSE) from Oryza sativa L. by yeast one-hybrid method. The full-length cDNA of OsHSF13 has a 1047bp open reading frame (ORF). It has HSF special DNA-binding domain (DBD) and oligomerization domain (OD). Analysis of the deduced amino acid sequences revealed that OsHSF13 was a class C heat shock factor (HSF) with all the conserved sequence elements characteristic of heat stress transcription factor. Bioinformatic analysis showed that the sequence and structure of OsHSF13's DNA binding domain had a high similarity with LpHSF24.

A semi-rational design strategy of directed evolution combined with chemical synthesis of DNA sequences.

Directed evolution in vitro is a powerful molecular tool for the creation of new biological phenotypes. It is unclear whether it is more efficient to mutate an enzyme randomly or to mutate just the active sites or key sites. In this study, the strategy of a semi-rational design of directed evolution combined with whole sequence and sites was developed. The 1553 bp gene encoding the thermostable beta-galactosidase of Pyrococcus woesei was chemically synthesized and optimized for G+C content and mRNA secondary structures. The synthesized gene product was used as a template or as a wild-type control. On the basis of the first round of DNA shuffling, library construction and screening, one mutant of YH6754 was isolated with higher activity. Eight potential key sites were deduced from the sequence of the shuffled gene, and 16 degenerate oligonucleotides were designed according to those eight amino acids. Two variants of YG6765 and YG8252 were screened in the second part of DNA shuffling, library construction and screening. For comparison, one mutant of YH8757 was screened through the same routine rounds of directed evolution with YH6754 as template. The purified beta-galactosidase from YH8757 exhibited a lower specific activity at 25 degrees C than those purified from mutated YG6755 and YG8252.

Isolation and characterization of a novel cDNA encoding ERF/AP2-type transcription factor OsAP25 from Oryza sativa L.

Using a yeast one-hybrid method, a transcription factor, OsAP25, which interacts specifically with a GCC box was isolated from rice. The OsAP25 protein contained a conserved ethylene-responsive element binding factor (ERF) domain which shared identity with other reported ERF domains. Phylogenetic analysis showed that OsAP25 could be categorized into class III ERF of the previously characterized ERF proteins on an evolutionary relationship. The semi-quantitative RT-PCR analysis revealed that OsAP25 gene was constitutively expressed in leaves, roots, growing points, flower, bolting stage and grain filling stage. In addition, OsAP25 gene was induced by NaCl, cold, drought, abscisic acid and exogenous ethylene.

Directed evolution of a beta-galactosidase from Pyrococcus woesei resulting in increased thermostable beta-glucuronidase activity.

We performed directed evolution on a chemically synthesized 1,533-bp recombinant beta-galactosidase gene from Pyrococcus woesei. More than 200,000 variant colonies in each round of directed evolution were screened using the pYPX251 vector and host strain Rosetta-Blue (DE3). One shifted beta-galactosidase to beta-glucuronidase mutant, named YG6762, was obtained after four rounds of directed evolution and screening. This mutant had eight mutated amino acid residues. T29A, V213I, L217M, N277H, I387V, R491C, and N496D were key mutations for high beta-glucuronidase activity, while E414D was not essential because the mutation did not lead to a change in beta-glucuronidase activity. The amino acid site 277 was the most essential because mutating H back to N resulted in a 50% decrease in beta-glucuronidase activity at 37 degrees C. We also demonstrated that amino acid 277 was the most essential site, as the mutation from N to H resulted in a 1.5-fold increase in beta-glucuronidase activity at 37 degrees C. Although most single amino acid changes lead to less than a 20% increase in beta-glucuronidase activity, the YG6762 variant, which was mutated at all eight amino acid sites, had a beta-glucuronidase activity that was about five and seven times greater than the wild-type enzyme at 37 and 25 degrees C, respectively.

High efficiency and throughput system in directed evolution in vitro of reporter gene.

In vitro directed evolution, especially with DNA shuffling, is a powerful means in biological studies of protein structure and function, and consequently for industrial applications. Escherichia coli beta-glucuronidase (gusA) gene, a versatile and efficient reporter gene, was the model for studying in vitro directed evolution because of its stability, easy analysis of the enzyme properties and conveniently visible phenotype. We developed a high efficiency, throughput system for in vitro directed evolution using gusA reporter gene as the model. The system consisted mainly of three aspects: a prokaryotic expression vector pYPX251, an easy method for obtaining the mutated gene from DNA shuffling and a suitable selected strategy. The vector pYPX251 carried the moderately strong aacC1 gene promoter and T1T2 transcription terminator that allowed expression in E. coli. Over 10,000 individuals could be selected individually in a 9 cm Petri dish after colonies were absorbed on a nitrocellulose filter. A library, which contained 100,000 individuals was screened by incubating ten filter papers with X-Glu. The polymerase chain reaction products of the gusA gene, the fragments of 50-100 bp, with high mutation rates were purified using a dialysis bag from 10% PAGE after electrophoresis. The possibility of obtaining desirable mutations was increased dramatically as the size of the library expanded. A GUS variant, named GUS-TR, was obtained through this system, which is significantly more resistant to high temperature than the wild type enzyme. GUS-TR maintained its high activity even when the nitrocellulose filter containing the variant colony was heated at 100 degrees C for 30 min.

High level expression of a synthetic gene encoding Peniophora lycii phytase in methylotrophic yeast Pichia pastoris.

Phytase is widespread in nature. It has been used as a cereal feed additive that can enhance the phosphorus and mineral absorption in monogastric animals to reduce the level of phosphorus output in manure. Phytase of Peniophora lycii is a 6'-phytase, which owns high specific activity. To achieve a high expression level of 6'-phytase in Pichia pastoris, the 1,230-bp phytase gene of P. lycii was synthesized and optimized for codon usage, G+C content, as well as mRNA secondary structures. The gene constructs containing wild type or modified phytase gene coding sequences under the control of the highly-inducible alcohol oxidase gene (AOX1) promoter, the synthetic signal peptide (designated MF4I), which is a codon-modified Saccharomyces cerevisiae mating factor alpha-prepro-leader sequence, were used to transform P. pastoris. The P. pastoris strain that expressed the modified phytase gene (phy-pl-sh) with MF4I sequence produced 12.2 g phytase per liter of fluid culture, with the phytase activity of 10,540 U ml(-1). The yield of the modified phytase gene, with bias codon usage and MF4I signal, is 4.4 times higher than that of the wild type gene with MF4I signal and 13.6 times higher than that of the wild type gene with wild type S. cerevisiae signal. The recombinant phytase had one optimum pH (pH 4.5) and an optimum temperature of 50 degrees C. The P. pastoris strain expressed the modified 6-phytase gene, with the MF4I signal peptide showing great potential as a commercial phytase production system.