Rapid generation of incremental truncation libraries for protein engineering using α-phosphothioate nucleotides

Incremental truncation for the creation of hybrid enzymes (ITCHY) is a novel tool for the generation of combinatorial libraries of hybrid proteins independent of DNA sequence homology. We herein report a fundamentally different methodology for creating incremental truncation libraries using nucleotide triphosphate analogs. Central to the method is the polymerase catalyzed, low frequency, random incorporation of α-phosphothioate dNTPs into the region of DNA targeted for truncation. The resulting phosphothioate internucleotide linkages are resistant to 3′→5′ exonuclease hydrolysis, rendering the target DNA resistant to degradation in a subsequent exonuclease III treatment. From an experimental perspective the protocol reported here to create incremental truncation libraries is simpler and less time consuming than previous approaches by combining the two gene fragments in a single vector and eliminating additional purification steps. As proof of principle, an incremental truncation library of fusions between the N-terminal fragment of Escherichia coli glycinamide ribonucleotide formyltransferase (PurN) and the C-terminal fragment of human glycinamide ribonucleotide formyltransferase (hGART) was prepared and successfully tested for functional hybrids in an auxotrophic E.coli host strain. Multiple active hybrid enzymes were identified, including ones fused in regions of low sequence homology.     

Theoretical distribution of truncation lengths in incremental truncation libraries

Incremental truncation is a method for constructing libraries of every one base pair truncation of a segment of DNA. Incremental truncation libraries can be created using a time-dependent nuclease method or through the incorporation of alpha-phosphothioate dNTPs by PCR or by primer extension (THIO(pcr) truncation and THIO(extension) truncation, respectively). Libraries created by the fusion of two truncation libraries, known as ITCHY libraries, can be created using the above methods or by the incremental truncation-like method SHIPREC. Knowing and being able to tailor the distribution of truncations in incremental truncation, ITCHY and SHIPREC libraries would be beneficial for their use in protein engineering and other applications. However, the experimental determination of the distributions would require extensive, cost-prohibitive, DNA sequencing to obtain statistically relevant data. Instead, a theoretical prediction of the distributions was developed. Time-dependent incremental truncation libraries had the most uniform distribution of truncation lengths, but were biased against longer truncations. Essentially uniform distribution over the desired truncation range (from zero to N(max) base pairs) required that truncations be prepared up to at least 1.2-1.5 N(max). THIO(pcr) and THIO(extension) truncation libraries had a very nonuniform distribution of truncation lengths with a bias against longer truncations. Such nonuniformity could be significantly diminished by decreasing the incorporation rate of alphaS-dNTPs but at the expense of having a large fraction of the DNA truncated beyond the desired range or completely degraded. ITCHY libraries created using time-dependent truncation had the most uniform distribution of possible fusions and had the highest fraction of the library being parental-length fusions. However, the distribution of parental-length fusions was biased against fusions near the beginning/ends of genes unless the truncation libraries are prepared with a uniform distribution up to N(max). In contrast, SHIPREC libraries and THIO(pcr) ITCHY libraries, by the very nature of the nonuniform distributions of the truncated DNA, are ensured of having a uniform distribution of fusion points in parental-length fusions. This comes at the expense of having a smaller fraction of the library being parental-length fusions; however, this limitation can be overcome by performing size selection on the library.     

Rapid generation of random mutant libraries

A simple and efficient method utilizing in vivo recombination to create recombinant libraries incorporating the products of PCR amplification is described. This will be especially useful for generating large pools of randomly mutagenized clones after error-prone PCR mutagenesis. Here we investigate various parameters to optimize this approach and we demonstrate that as little as 1 pmole of PCR fragment can generate a library with greater than 104 clones in a single transformation without ligation.     

High-efficiency generation of plasmid cDNA libraries using electro-transformation

A simple and efficient method for the construction of large cDNA libraries in plasmid vectors is described. Cloning efficiencies of greater than 1 x 10(6) recombinants per microgram starting RNA are easily obtained using electroporation. A detailed protocol for determining the optimal conditions using this novel approach is presented.     

A method for generation of arbitrary peptide libraries using genomic DNA

Random peptide libraries can be constructed either by in vitro synthesis of random peptides, or through translation of DNA sequences from synthetic random oligonucleotides. Here we describe an alternative way of making arbitrary peptide libraries with high diversity that can be used in screening as random peptide libraries. Genomic DNA digested with a frequent-cutting restriction enzyme recognizing four nucleotides will theoretically consist of small DNA pieces with average length of 256 nucleotides, and on average around 10⁷ fragments can be generated from a genome of 3 × 10⁹ bases. A peptide library translated from these fragments will have sufficient diversity for some protein interaction screening experiments. Moreover, the same genome digested with a different four-cutter enzyme or ligated into different reading frames will result in different nonoverlapping libraries. A series of such libraries could be generated with genomic DNAs from different species. In this study, human genomic DNA was digested with four-cutter restriction enzymes DpnII and Tsp509I, respectively, and cloned into yeast expression vector pGADT7 to generate arbitrary peptide libraries. These libraries were used in yeast two-hybrid assays to screen for binding motifs of the PDZ domain containing protein synectin. Our results showed that in addition to various native carboxy-terminal tails, synectin could also bind to many artificial ones, some of which contained a consensus sequence—(S/T)XC-COOH.     

Construction of block-shuffled libraries of DNA for evolutionary protein engineering: Y-ligation-based block shuffling

Evolutionary protein engineering is now proceeding to a new stage in which novel technologies, besides the conventional point mutations, to generate a library of proteins, are required. In this context, a novel method for shuffling and rearranging DNA blocks (leading to protein libraries) is reported. A cycle of processes for producing combinatorial diversity was devised and designated Y-ligation-based block shuffling (YLBS). Methodological refinement was made by applying it to the shuffling of module-sized and amino acid-sized blocks. Running three cycles of YLBS with module-sized GFP blocks resulted in a high diversity of an eight-block shuffled library. Partial shuffling of the central four blocks of GFP was performed to obtain in-effect shuffled protein, resulting in an intact arrangement. Shuffling of amino acid monomer-sized blocks by YLBS was also performed and a diversity of more than 10(10) shuffled molecules was attained. The deletion problems encountered during these experiments were shown to be solved by additional measures which tame type IIS restriction enzymes. The frequency of appearance of each block was skewed but was within a permissible range. Therefore, YLBS is the first general method for generating a huge diversity of shuffled proteins, recombining domains, exons and modules with ease.     

Rapid quantification of DNA libraries for next-generation sequencing

The next-generation DNA sequencing workflows require an accurate quantification of the DNA molecules to be sequenced which assures optimal performance of the instrument. Here, we demonstrate the use of qPCR for quantification of DNA libraries used in next-generation sequencing. In addition, we find that qPCR quantification may allow improvements to current NGS workflows, including reducing the amount of library DNA required, increasing the accuracy in quantifying amplifiable DNA, and avoiding amplification bias by reducing or eliminating the need to amplify DNA before sequencing.     

Rapid generation of subclones for DNA sequencing using the reverse cloning procedure

A fast and reliable procedure for generating subclones necessary for sequencing long stretches of DNA has been developed. The reverse cloning procedure involves cloning a fragment of DNA into a single-stranded plasmid or phage vector containing a polycloning region; synthesizing variable lengths of double-stranded DNA using a "Universal Primer"; isolating the double-stranded DNA; and force cloning the double-stranded DNA fragments into a complementary vector with the polycloning region in the reverse orientation. The resulting clones can be sequenced, using the same Universal Primer and T7 DNA polymerase, to provide overlapping DNA sequences. The reverse cloning procedure can be used to construct deletion mutations.     

Microsatellite primer development in elasmobranchs using next generation sequencing of enriched libraries

Molecular Biology Reports - Microsatellites are useful in studies of population genetics, sibship, and parentage. Here, we screened for microsatellites from multiple elasmobranch genomic libraries...     

Flexible genetic engineering using RecA protein

With the explosion in genetic information and almost complete sequencing of the human genome, a shift in the experimental goals of molecular biologists is occurring. Instead of focusing on single genes, current attempts seek to divine the interactions of several genes and sequences. This requires increasingly complex genetic constructs and manipulations, often of very large DNA constructs, and these can be made with RecA protein-based techniques. When RecA protein combined with an oligonucleotide acts as a sequence-specific "masking tape" to block DNA from the action of DNA modifying enzymes, and can be used to direct the cleavage of DNA at single predetermined restriction endonuclease sites. This reaction is called RecA-Assisted Restriction Endonuclease (RARE) Cleavage. The reverse reaction, known as RecA-Assisted Ligation, can be used to join any two desired fragments. When one of those fragments is a vector, a desired fragment can be cloned directly without constructing a genomic library. The reagents and equipment needed are relatively inexpensive, and almost any desired genetic construct up to about 300 kb in size can be made in a straightforward manner.     

Optimizing nucleotide sequence ensembles for combinatorial protein libraries using a genetic algorithm

Protein libraries are essential to the field of protein engineering. Increasingly, probabilistic protein design is being used to synthesize combinatorial protein libraries, which allow the protein engineer to explore a vast space of amino acid sequences, while at the same time placing restrictions on the amino acid distributions. To this end, if site-specific amino acid probabilities are input as the target, then the codon nucleotide distributions that match this target distribution can be used to generate a partially randomized gene library. However, it turns out to be a highly nontrivial computational task to find the codon nucleotide distributions that exactly matches a given target distribution of amino acids. We first showed that for any given target distribution an exact solution may not exist at all. Formulated as a constrained optimization problem, we then developed a genetic algorithm-based approach to find codon nucleotide distributions that match as closely as possible to the target amino acid distribution. As compared with the previous gradient descent method on various objective functions, the new method consistently gave more optimized distributions as measured by the relative entropy between the calculated and the target distributions. To simulate the actual lab solutions, new objective functions were designed to allow for two separate sets of codons in seeking a better match to the target amino acid distribution.     

High-throughput RNA interference screening using pooled shRNA libraries and next generation sequencing

RNA interference (RNAi) screening is a state-of-the-art technology that enables the dissection of biological processes and disease-related phenotypes. The commercial availability of genome-wide, short hairpin RNA (shRNA) libraries has fueled interest in this area but the generation and analysis of these complex data remain a challenge. Here, we describe complete experimental protocols and novel open source computational methodologies, shALIGN and shRNAseq, that allow RNAi screens to be rapidly deconvoluted using next generation sequencing. Our computational pipeline offers efficient screen analysis and the flexibility and scalability to quickly incorporate future developments in shRNA library technology.     

A reliable method for random mutagenesis: the generation of mutant libraries using spiked oligodeoxyribonucleotide primers

A new procedure for the production of a defined library of random mutants is described. Long spiked oligodeoxyribonucleotides (oligos), in which a predetermined level of the three 'wrong' phosphoramidites are used at each position, are made as primers for a standard oligo-directed mutagenesis protocol. Spiked oligo synthesis on a DNA synthesizer is achieved using an in-line mixing procedure that only requires five phosphoramidite reservoirs and which avoids contamination of any of the pure phosphoramidite reagents. Immutable positions (i.e., positions in the oligo for which pure reagents are used) can be specified, and a silent 'marker' base can be included that allows an early estimate of the mutagenesis efficiency. The randomness of the library in respect to the number, type, and position of the altered bases, is easily verified by DNA sequencing. This procedure has been used to generate a random mutant library of the gene encoding a sluggish triosephosphate isomerase. Among the transformants from this library, a number of second-site suppressor mutations have been found that increase the specific catalytic activity of the starting isomerase. This approach provides a more complete library than a method using chemical mutagenic reagents.     

Evaluation of protein farnesyltransferase substrate specificity using synthetic peptide libraries

Farnesylation, catalyzed by protein farnesyltransferase (FTase), is an important post-translational modification guiding cellular localization. Recently predictive models for identifying FTase substrates have been reported. Here we evaluate these models through screening of dansylated-GCaaS peptides, which also provides new insights into the protein substrate selectivity of FTase.