A new approach to directed gene evolution by recombined extension on truncated templates (RETT)

We describe a new approach to in vitro DNA recombination technique termed recombined extension on truncated templates (RETT). RETT generates random recombinant gene library by template-switching of unidirectionally growing polynucleotides from primers in the presence of unidirectional single-stranded DNA fragments used as templates. RETT was applied to the recombination of two homologous chitinase genes from S. marcescens ATCC 21074 and S. liquefaciens GM1403. When the shuffled genes were examined by restriction mapping and sequence analysis, it was found that chimeric genes were produced at a high frequency (more than 70%) between two chitinase genes with 83% of sequence identity. The number of crossovers within each chimeric gene ranged from one to four, and the recombination points were randomly distributed along entire DNA sequence. We also applied RETT to directed evolution of a chitinase variant for enhancing thermostability. Chimeric chitinases that were more thermostable than the parental enzyme were successfully obtained by RETT-based recombination.     

Recombination and chimeragenesis by in vitro heteroduplex formation and in vivo repair.

We describe a simple method for creating libraries of chimeric DNA sequences derived from homologous parental sequences. A heteroduplex formed in vitro is used to transform bacterial cells where repair of regions of non-identity in the heteroduplex creates a library of new, recombined sequences composed of elements from each parent. Heteroduplex recombination provides a convenient addition to existing DNA recombination methods ('DNA shuffling') and should be particularly useful for recombining large genes or entire operons. This method can be used to create libraries of chimeric polynucleotides and proteins for directed evolution to improve their properties or to study structure-function relationships. We also describe a simple test system for evaluating the performance of DNA recombination methods in which recombination of genes encoding truncated green fluorescent protein (GFP) reconstructs the full-length gene and restores its characteristic fluorescence. Comprising seven truncated GFP constructs, this system can be used to evaluate the efficiency of recombination between mismatches separated by as few as 24 bp and as many as 463 bp. The optimized heteroduplex recombination protocol is quite efficient, generating nearly 30% fluorescent colonies for recombination between two genes containing stop codons 463 bp apart (compared to a theoretical limit of 50%).     

Targeted gene repair and its application to neurodegenerative disorders

Synthetic DNA oligonucleotides can direct the exchange of single nucleotides within coding regions of mammalian genes by hybridizing to their complementary sequence in the chromosome and creating a recombination joint structure with a single mismatched base pair. Inherent DNA repair processes recognize the mismatch and resolve it using the DNA sequence of the oligonucleotide vector as the template. This gene surgery approach can be used to repair mutations or to disrupt tri-nucleotide repeats in dysfunctional genes responsible for neurological disorders.     

A method for high‐throughput production of sequence‐verified DNA libraries and strain collections

The low costs of array‐synthesized oligonucleotide libraries are empowering rapid advances in quantitative and synthetic biology. However, high synthesis error rates, uneven representation, and lack of access to individual oligonucleotides limit the true potential of these libraries. We have developed a cost‐effective method called Recombinase Directed Indexing (REDI), which involves integration of a complex library into yeast, site‐specific recombination to index library DNA, and next‐generation sequencing to identify desired clones. We used REDI to generate a library of ~3,300 DNA probes that exhibited > 96% purity and remarkable uniformity (> 95% of probes within twofold of the median abundance). Additionally, we created a collection of ~9,000 individually accessible CRISPR interference yeast strains for > 99% of genes required for either fermentative or respiratory growth, demonstrating the utility of REDI for rapid and cost‐effective creation of strain collections from oligonucleotide pools. Our approach is adaptable to any complex DNA library, and fundamentally changes how these libraries can be parsed, maintained, propagated, and characterized.     

Structure-based combinatorial protein engineering (SCOPE)

Presented here is the development a semi-rational protein engineering approach that uses information from protein structure coupled with established DNA manipulation techniques to design and create multiple crossover libraries from non-homologous genes. The utility of structure-based combinatorial protein engineering (SCOPE) was demonstrated by its application to two distantly related members of the X-family of DNA polymerases: rat DNA polymerase beta (Pol beta) and African swine fever virus DNA polymerase X (Pol X). These proteins share similar folds but have low sequence identity, and differ greatly in both size and activity. "Equivalent" subdomain elements of structure were designed on the basis of the tertiary structure of Pol beta and the corresponding regions of Pol X were inferred from homology modeling and sequence alignment analysis. Libraries of chimeric genes with up to five crossovers were synthesized in a series of PCR reactions by employing hybrid oligonucleotides that code for variable connections between structural elements. Genetic complementation in Escherichia coli enabled identification of several novel DNA polymerases with enhanced phenotypes. Both the composition of structural elements and the manner in which they were linked were shown to be essential for this property, indicating the importance of these aspects of design.     

Targeted gene transfer system using a streptavidin-transforming growth factor-alpha chimeric protein.

The previously reported streptavidin-TGFalpha chimeric protein-based delivery system (Ohno and Meruelo, DNA Cell Biol. 15:401-406, 1996) could efficiently transfer protein molecules into A431 cells via the epidermal growth factor (EGF) receptor. We have modified this delivery system for the transfer of DNA. For this purpose, we have linked the chimeric protein ST-TGFalpha to DNA through biotinylated polylysine molecules. We show with this system, in the presence of the endosome-destabilizing reagent chloroquine, an average of 50-fold increase in reporter gene expression in comparison with polylysine DNA complexes alone. This gene expression is specific for EGF receptor-expressing cells and is blocked by EGF-binding molecules. These results suggest that the ST-TGFalpha biotinylated polylysine system could be used to deliver DNA to targeted cells.     

Development of chimeric laccases by directed evolution

DNA recombination methods are useful tools to generate diversity in directed evolution protein engineering studies. We have designed an array of chimeric laccases with high‐redox potential by in vitro and in vivo DNA recombination of two fungal laccases (from Pycnoporus cinnabarinus and PM1 basidiomycete), which were previously tailored by laboratory evolution for functional expression in Saccharomyces cerevisiae. The laccase fusion genes (including the evolved α‐factor prepro‐leaders for secretion in yeast) were subjected to a round of family shuffling to construct chimeric libraries and the best laccase hybrids were identified in dual high‐throughput screening (HTS) assays. Using this approach, we identified chimeras with up to six crossover events in the whole sequence, and we obtained active hybrid laccases with combined characteristics in terms of pH activity and thermostability. Biotechnol. Bioeng. 2012; 109: 2978–2986. © 2012 Wiley Periodicals, Inc.     

A bacterial artificial chromosome (BAC) library for sunflower, and identification of clones containing genes for putative transmembrane receptors

Sunflower (Helianthus annuus L.) is an economically important oil seed crop with an estimated genome size of 3000 Mb. We have constructed a bacterial artificial chromosome (BAC) library for sunflower, which represents an estimated 4- to 5-fold coverage of the genome. Nuclei isolated from young leaves were used as a source of high-molecular-weight DNA and a partial restriction endonuclease digestion protocol was used to cleave the DNA. A random sample of 60 clones indicated an average insert size of 80 kb, implying a 95% probability of recovering any specific sequence of interest. The library was screened with chloroplast DNA probes. Only 0.1% of the clones were identified to be of chloroplast origin, indicating that contamination with organellar DNAs is very low. The utility of the library was evaluated by screening for the presence of genes for putative transmembrane receptors sharing epidermal growth factor (EGF) and integrin-like domains. First, a homologous sunflower EST (HaELP1) was obtained by degenerate RT-PCR cloning, using Arabidopsis thaliana genes (AtELP) as a source of consensus sequences. Three different BACs yielded positive hybridization signals when HaELP1 was used as a probe. BAC subcloning and sequencing demonstrated the presence of two different loci putatively homologous to genes for transmembrane proteins with EGF- and integrin-like domains from sunflower. This work demonstrates the suitability of the library for homology map-based cloning of sunflower genes and physical mapping of the sunflower genome.     

Chimeric gene library construction by a simple and highly versatile method using recombination-dependent exponential amplification

A simple and efficient method for the construction of chimeric gene libraries termed RDA-PCR (recombination-dependent exponential amplification polymerase chain reaction) was developed by modifying polymerase chain reaction. A chimeric gene library is generated from homologous parental genes with additional primer-annealing sequences at their "heads" and "tails". Two primers ("skew primers") are designed to exclusively anneal to either the heads of maternal genes or the tails of paternal genes. During the RDA-PCR, short annealing/extension periods facilitate homologous recombination. The chimeric sequences can be exponentially amplified to form the chimeric gene library, whereas parental sequences without crossovers are not amplified. As a model, we constructed a chimeric gene library of yellow and green fluorescent protein (yfp and gfp, respectively). The crossover point profile of RDA-PCR clones was compared with those obtained by (modified) family shuffling. PCR restriction fragment polymorphism (PCR-RFLP) analysis of the RDA-PCR clones showed a high content of chimeric genes in the library, whereas family shuffling required the modification using skew primers for selective enrichment of chimeric sequences. PCR-RFLP analysis also indicated that the crossover points of RDA-PCR chimeras were distributed over the entire protein-coding region. Moreover, as few as 2 bp of the continual identity of nucleotides were found at the crossover points at high frequency (30% of the tested clones), suggesting that RDA-PCR resulted in a higher diversity in crossover points than family shuffling.     

Identification of sequences of chromosome 7 that are expressed in sweat gland epithelial cells

Summary This paper describes an approach that can be used to identify specifically expressed coding sequences in defined regions of genomic DNA. We developed this method to identify expressed sequences from chromosome 7 located at or near the cystic fibrosis (CF) locus. Radioactively labelled single-stranded cDNAs derived from sweat gland epithelial cells and from fibroblasts were used to screen a genomic library constructed from flow-sorted chromosomes. Differential screening of phage lifts with these two probes yielded 36 different DNA segments. By using somatic cell hybrids containing different portions of chromosome 7, four of the clones were mapped to the 7q31 region in which the CF locus is located. These four clones and two others that gave strong differential epithelial signals but that were not within 7q31 were studied further. Restriction fragment length polymorphisms (RFLPs) were identified for two of the DNA segments within 7q31 and used for linkage analysis using a panel of CF families. One DNA segment was assigned to a location centromeric to the met locus. The other marker did not show recombination with CF but was subsequently excluded from the CF region by physical mapping. Three of the six DNA segments were found to hybridize to various RNAs using the Northern technique and therefore contain portions of genes. One of the clones showed strong differential expression when epithelial tissues were compared to fibroblasts and may represent an epithelium-specific gene.     

Genetic repair of mutations in plant cell-free extracts directed by specific chimeric oligonucleotides

Chimeric oligonucleotides are synthetic molecules comprised of RNA and DNA bases assembled in a double hairpin conformation. These molecules have been shown to direct gene conversion events in mammalian cells and animals through a process involving at least one protein from the DNA mismatch repair pathway. The mechanism of action for gene repair in mammalian cells has been partially elucidated through the use of a cell-free extract system. Recent experiments have expanded the utility of chimeric oligonucleotides to plants and have demonstrated genotypic and phenotypic conversion, as well as Mendelian transmission. Although these experiments showed correction of point and frameshift mutations, the biochemical and mechanistic aspects of the process were not addressed. In this paper, we describe the establishment of cell-free extract systems from maize (Zea mays), banana (Musa acuminata cv Rasthali), and tobacco (Nicotiana tabacum). Using a genetic readout system in bacteria and chimeric oligonucleotides designed to direct the conversion of mutations in antibiotic-resistant genes, we demonstrate gene repair of point and frameshift mutations. Whereas extracts from banana and maize catalyzed repair of mutations in a precise fashion, cell-free extracts prepared from tobacco exhibited either partial repair or non-targeted nucleotide conversion. In addition, an all-DNA hairpin molecule also mediated repair albeit in an imprecise fashion in all cell-free extracts tested. This system enables the mechanistic study of gene repair in plants and may facilitate the identification of DNA repair proteins operating in plant cells.     

QuikChange shuffling: a convenient and robust method for site-directed mutagenesis and random recombination of homologous genes

Here we describe a robust method, termed QuikChange shuffling, for efficient site-directed mutagenesis and random recombination of homologous genes. The homologous genes are fragmented, and the random fragments are reassembled in a self-priming polymerase reaction to obtain chimeric genes. The product is then mixed with linearized vector and two pairs of complementary mutagenic primers, followed by assembly of the chimeric genes and linearized vector through QuikChange-like amplification to introduce recombinant plasmids with a site-directed mutation. The method, which can yield 100% chimeric genes after library construction, is more convenient and efficient than current DNA shuffling methods.     

Genomic analysis of cultivated barley (Hordeum vulgare) using sequence-tagged molecular markers. Estimates of divergence based on RFLP and PCR markers derived from stress-responsive genes, and simple-sequence repeats (SSRs)

Three types of molecular markers have been compared for their utility in evaluating genetic diversity among cultivars of Hordeum vulgare. Restriction fragment length polymorphisms at 71 sites were scored with the aid of probes corresponding to stress-responsive genes from barley and wheat, coding for a low-molecular-weight heat shock protein, a dehydrin, an aldose reductase homolog, and a 18.9-kDa drought-induced protein of unknown function. Indexes of genetic diversity computed in the total sample and within groups of cultivars (two-rowed and six-rowed, winter and spring varieties) indicated high values of genetic differentiation ( F (ST) >15%). A second assessment of genetic diversity was performed by PCR amplification of genomic DNA using as primers 13 arbitrary oligonucleotides derived from sequences of the same stress-responsive genes. A high degree of polymorphism was uncovered using these markers also, but they yielded low values for F (ST) (<7%) among groups of cultivars. Finally, 15 different simple-sequence repeats (AC or AG) were amplified with primers based on unique flanking sequences. Levels of polymorphism and differentiation between groups of cultivars revealed by these markers were quite high. Ordination techniques applied to measures of genetic distance among cultivars demonstrated a remarkable ability of the RFLPs associated with stress-responsive genes to discriminate on the basis of growth habit. The correlation with production data for the cultivars in different environments was also significant. This "functional genomics" strategy was therefore as informative as the "structural genomics" (SSR-based) approach, but requires the analysis of fewer probes.     

Protein engineering by cDNA recombination in yeasts: shuffling of mammalian cytochrome P-450 functions

We have constructed, in the yeast Saccharomyces cerevisiae, a mosaic assembly of genes by in vivo recombination of partially homologous sequences. The approach was tested on cDNAs encoding functionally distinct mammalian cytochromes P-450 (P-450). The selection for recombinant cDNAs used the transformation of yeast cells, which required the recircularization of a linearized plasmid by recombination of two partially homologous cDNAs. Libraries of mosaic genes with bipartite or tripartite structures were generated by intramolecular and intermolecular recombination events. The presence of yeast promoter and terminator sequences on the flanking sides of the recombined cDNAs has allowed the synthesis of encoded mosaic proteins. A library of yeast clones producing recombinant mouse P-450 P1 and rabbit P-450 LM4 was screened using functional criteria to identify chimeras with shuffled substrate specificity. Restriction mapping of mosaic genes, biochemical analysis of the synthesized proteins, comparison of chimeric enzymes, and the alignment of sequences with bacterial P-450 camphor hydroxylase of known three-dimensional structure, all suggest that the P-450 P1 amino acid residues 203-238 play a major role in the control of cytochrome activity toward carcinogenic polycyclic aromatic hydrocarbons. Similar approaches to structure-function analysis are believed to be applicable to other protein families.     

Simultaneous synthesis of human-, mouse- and chimeric epidermal growth factor genes via ''hybrid gene synthesis'' approach.

Simultaneous synthesis of two DNA duplexes encoding human and mouse epidermal growth factors (EGF) was accomplished in a single step. A 174 b.p. DNA heteroduplex, with 16 single and double base pair mismatches, was designed. One strand encoded the human EGF, and the opposite strand indirectly encoded the mouse EGF. The heteroduplex DNA was synthesized by ligation of seven overlapping oligodeoxyribonucleotides with a linearized plasmid. After transformation in E. coli HB101 (recA 13), the resulting heteroduplex plasmid served as the template in plasmid replication. Two different plasmid progenies bearing either the human or mouse EGF-coding sequence were identified by colony hybridization using the appropriate probes. However, in E. coli JM103, the same process yielded plasmid progenies encoding different chimeric EGF molecules, presumably due to crossover of human and mouse EGF gene sequences.     

General method for sequence-independent site-directed chimeragenesis

We have developed a simple and general method that allows for the facile recombination of distantly related (or unrelated) proteins at multiple discrete sites. To evaluate the sequence-independent site-directed chimeragenesis (SISDC) method, we have recombined beta-lactamases TEM-1 and PSE-4 at seven sites, examined the quality of the chimeric genes created, and screened the library of 2(8) (256) chimeras for functional enzymes. Probe hybridization and sequencing analyses revealed that SISDC generated a random library with little sequence bias and in which all targeted fragments were recombined in the desired order. Sequencing the genes from clones having functional lactamases identified 14 unique chimeras. These chimeras are characterized by a lower level of disruption, as calculated by the SCHEMA algorithm, than the library as a whole. These results illustrate the use of SISDC in creating designed chimeric protein libraries and further illustrate the ability of SCHEMA to identify chimeras whose folded structures are likely not to be disrupted by recombination.     

Prospecting metagenomic enzyme subfamily genes for DNA family shuffling by a novel PCR-based approach

DNA family shuffling is a powerful method for enzyme engineering, which utilizes recombination of naturally occurring functional diversity to accelerate laboratory-directed evolution. However, the use of this technique has been hindered by the scarcity of family genes with the required level of sequence identity in the genome database. We describe here a strategy for collecting metagenomic homologous genes for DNA shuffling from environmental samples by truncated metagenomic gene-specific PCR (TMGS-PCR). Using identified metagenomic gene-specific primers, twenty-three 921-bp truncated lipase gene fragments, which shared 64-99% identity with each other and formed a distinct subfamily of lipases, were retrieved from 60 metagenomic samples. These lipase genes were shuffled, and selected active clones were characterized. The chimeric clones show extensive functional and genetic diversity, as demonstrated by functional characterization and sequence analysis. Our results indicate that homologous sequences of genes captured by TMGS-PCR can be used as suitable genetic material for DNA family shuffling with broad applications in enzyme engineering.     

Triple-helix formation induces recombination in mammalian cells via a nucleotide excision repair-dependent pathway

The ability to stimulate recombination in a site-specific manner in mammalian cells may provide a useful tool for gene knockout and a valuable strategy for gene therapy. We previously demonstrated that psoralen adducts targeted by triple-helix-forming oligonucleotides (TFOs) could induce recombination between tandem repeats of a supF reporter gene in a simian virus 40 vector in monkey COS cells. Based on work showing that triple helices, even in the absence of associated psoralen adducts, are able to provoke DNA repair and cause mutations, we asked whether intermolecular triplexes could stimulate recombination. Here, we report that triple-helix formation itself is capable of promoting recombination and that this effect is dependent on a functional nucleotide excision repair (NER) pathway. Transfection of COS cells carrying the dual supF vector with a purine-rich TFO, AG30, designed to bind as a third strand to a region between the two mutant supF genes yielded recombinants at a frequency of 0.37%, fivefold above background, whereas a scrambled sequence control oligomer was ineffective. In human cells deficient in the NER factor XPA, the ability of AG30 to induce recombination was eliminated, but it was restored in a corrected subline expressing the XPA cDNA. In comparison, the ability of triplex-directed psoralen cross-links to induce recombination was only partially reduced in XPA-deficient cells, suggesting that NER is not the only pathway that can metabolize targeted psoralen photoadducts into recombinagenic intermediates. Interestingly, the triplex-induced recombination was unaffected in cells deficient in DNA mismatch repair, challenging our previous model of a heteroduplex intermediate and supporting a model based on end joining. This work demonstrates that oligonucleotide-mediated triplex formation can be recombinagenic, providing the basis for a potential strategy to direct genome modification by using high-affinity DNA binding ligands.