Generation Of Large Libraries Research Articles

Massive integration of large gene libraries in the chromosome of Escherichia coli.

Large gene libraries are frequently created in Escherichia coli plasmids, which can induce cell toxicity and expression instability due to the high gene dosage. To address these limitations, gene libraries can be integrated in a single copy into the bacterial chromosome. Here, we describe an efficient system for the massive integration (MAIN) of large gene libraries in the E. coli chromosome that generates in-frame gene fusions that are expressed stably. MAIN uses a thermosensitive integrative plasmid that is linearized invivo to promote extensive integration of the gene library via homologous recombination. Positive and negative selections efficiently remove bacteria lacking gene integration in the target site. We tested MAIN with a library of 107 VHH genes that encode nanobodies (Nbs). The integration of VHH genes into a custom target locus of the E. coli chromosome enabled stable expression and surface display of the Nbs. Next-generation DNA sequencing confirmed that MAIN preserved the diversity of the gene library after integration. Finally, we screened the integrated library to select Nbs that bind a specific antigen using magnetic and fluorescence-activated cell sorting. This allowed us to identify Nbs binding the epidermal growth factor receptor that were not previously isolated in a similar screening of a multicopy plasmid library. Our results demonstrate that MAIN enables large gene library integration into the E. coli chromosome, creating stably expressed in-frame fusions for functional screening.

Rapid directed molecular evolution of fluorescent proteins in mammalian cells.

In vivo imaging of model organisms is heavily reliant on fluorescent proteins with high intracellular brightness. Here we describe a practical method for rapid optimization of fluorescent proteins via directed molecular evolution in cultured mammalian cells. Using this method, we were able to perform screening of large gene libraries containing up to 2 × 107 independent random genes of fluorescent proteins expressed in HEK cells, completing one iteration of directed evolution in a course of 8 days. We employed this approach to develop a set of green and near‐infrared fluorescent proteins with enhanced intracellular brightness. The developed near‐infrared fluorescent proteins demonstrated high performance for fluorescent labeling of neurons in culture and in vivo in model organisms such as Caenorhabditis elegans, Drosophila, zebrafish, and mice. Spectral properties of the optimized near‐infrared fluorescent proteins enabled crosstalk‐free multicolor imaging in combination with common green and red fluorescent proteins, as well as dual‐color near‐infrared fluorescence imaging. The described method has a great potential to be adopted by protein engineers due to its simplicity and practicality. We also believe that the new enhanced fluorescent proteins will find wide application for in vivo multicolor imaging of small model organisms.

Directed evolution of VanR biosensor specificity in yeast

Allosterically regulated transcription factors (aTFs) based biosensors from prokaryotes have been widely used to screen large gene libraries, stabilize engineered microbes from evolutionary drifting, and for detection of soil pollutants, among many other applications. However, even though aTF-based biosensors have been established as successful tools for bioengineering and remediation, rational engineering of aTF small molecule-specificity have so far not been demonstrated, highlighting the need for a deeper understanding of the sequence-function relationships that govern aTF allostery. Here, by combining directed evolution of a naïve library of VanR, a vanillic acid transcriptional regulator from Caulobacter crescentus in yeast, followed by saturation mutagenesis of selected positions we identify residues required for vanillic acid responsiveness, while at the same time maintaining responsiveness to vanillin. Selected single-position VanR mutants show both complete repression of transcription in the absence of any ligand, complete loss of vanillic acid responsiveness, while still maintaining high derepression in the presence of vanillin. By computational ligand docking analyses we also discuss the structure-function relationship single mutations can have on aTF specificity, an attribute potentially accounting for the wide-spread arise of aTF members belonging to the GntR superfamily of transcriptional regulators.

Standardized cloning vectors for protein production and generation of large gene libraries in Escherichia coli.

Here, we modified the multiple cloning sites from commonly used expression vectors to create a new suite of cloning plasmids that simplify and speed up cloning procedures in Escherichia coli. Each of our standardized plasmids contains two BsaI restriction sites, allowing for highly efficient cloning of genes and bringing their expression under control of either a T7 (pET21a_BsaI, pET28a_BsaI, and pMAL-c5T_BsaI) or T5 promoter (pUR22 and pUR23). Another plasmid in our suite (pTNA_BsaI) allows for generation of large gene libraries containing >108 variants, which can be constitutively expressed in selection experiments using metabolic complementation of auxotrophic E. coli strains. Coupling restriction and ligation with the BsaI restriction enzyme minimizes hands-on time, while the need for only three different primers to clone a target gene into the six different vectors keeps overall cloning costs low.

Engineering and Directed Evolution of DNA Methyltransferases.

DNA methyltransferases (MTases) constitute an attractive target for protein engineering, thus opening the road to new ways of manipulating DNA in a unique and selective manner. Here, we review various aspects of MTase engineering, both methodological and conceptual, and also discuss future directions and challenges. Bacterial MTases that are part of restriction/modification (R/M) systems offer a convenient way for the selection of large gene libraries, both in vivo and in vitro. We review these selection methods, their strengths and weaknesses, and also the prospects for new selection approaches that will enable the directed evolution of mammalian DNA methyltransferases (Dnmts). We explore various properties of MTases that may be subject to engineering. These include engineering for higher stability and soluble expression (MTases, including bacterial ones, are prone to misfolding), engineering of the DNA target specificity, and engineering for the usage of S-adenosyl-L-methionine (AdoMet) analogs. Directed evolution of bacterial MTases also offers insights into how these enzymes readily evolve in nature, thus yielding MTases with a huge spectrum of DNA target specificities. Engineering for alternative cofactors, on the other hand, enables modification of DNA with various groups other than methyl and thus can be employed to map and redirect DNA epigenetic modifications.

Gateway-compatible vectors for high-throughput protein expression in pro- and eukaryotic cell-free systems

Although numerous techniques for protein expression and production are available the pace of genome sequencing outstrips our ability to analyze the encoded proteins. To address this bottleneck, we have established a system for parallelized cloning, DNA production and cell-free expression of large numbers of proteins. This system is based on a suite of pCellFree Gateway destination vectors that utilize a Species Independent Translation Initiation Sequence (SITS) that mediates recombinant protein expression in any in vitro translation system. These vectors introduce C or N terminal EGFP and mCherry fluorescent and affinity tags, enabling direct analysis and purification of the expressed proteins. To maximize throughput and minimize the cost of protein production we combined Gateway cloning with Rolling Circle DNA Amplification. We demonstrate that as little as 0.1ng of plasmid DNA is sufficient for template amplification and production of recombinant human protein in Leishmania tarentolae and Escherichia coli cell-free expression systems. Our experiments indicate that this approach can be applied to large gene libraries as it can be reliably performed in multi-well plates. The resulting protein expression pipeline provides a valuable new tool for applications of the post genomic era.

Selection of a T7 promoter mutant with enhanced in vitro activity by a novel multi-copy bead display approach for in vitro evolution

In vitro evolution of nucleic acids and proteins is a powerful strategy to optimize their biological and physical properties. To select proteins with the desired phenotype from large gene libraries, the proteins need to be linked to the gene they are encoded by. To facilitate selection of the desired phenotype and isolation of the encoding DNA, a novel bead display approach was developed, in which each member of a library of beads is first linked to multiple copies of a clonal gene variant by emulsion polymerase chain reaction. Beads are transferred to a second emulsion for an in vitro transcription–translation reaction, in which the protein encoded by each bead’s amplicon covalently binds to the bead present in the same picoliter reactor. The beads then contain multiple copies of a clonal gene variant and multiple molecules of the protein encoded by the bead’s gene variant and serve as the unit of selection. As a proof of concept, we screened a randomized library of the T7 promoter for high expression levels by flow cytometry and identified a T7 promoter variant with an ∼10-fold higher in vitro transcriptional activity, confirming that the multi-copy bead display approach can be efficiently applied to in vitro evolution.

Functional expression of lipase A from Candida antarctica in Escherichia coli—A prerequisite for high-throughput screening and directed evolution

We report for the first time the functional and heterologous expression of lipase A from Candida antarctica (CalA) in the cytoplasm of Escherichia coli Origami™ B cells. Expression under control of the lac promoter in the pUC18 vector yielded 0.7 U mg −1 lipase activity, whereas expression of a thioredoxin–CalA fusion protein using the pET-32b(+) vector yielded 1.7 U mg −1. The native enzyme was most efficiently expressed under control of the cspA promoter (9.63 U mg −1) using the pColdIII vector. Co-expression of various chaperones led to a significant increase in formation of active protein (up to 13.1 U mg −1). This expression strategy was validated in microtitre plates and therefore is suitable for high-throughput screening of large gene libraries and applications including directed evolution of CalA.

Enrichment of Open Reading Frames Presented on Bacteriophage M13 Using Hyperphage

The enrichment of open reading frames (ORFs) from large gene libraries and the presentation of the corresponding polypeptides on filamentous phage M13 (phage display) is frequently used to identify binding partners of unknown ORFs. In particular phage display is a valuable tool for the identification of pathogen-related antigens and a first step for the development of new diagnostics and therapeutics. Here, we introduce a significant improvement of phage-based ORF enrichment by using Hyperphage, a helperphage with a truncated gIII. The methods allow both the enrichment of ORFs from cDNA libraries and the display of the corresponding polypeptides on phage, thus combining ORF enrichment with a screening for binding in one step without any further subcloning steps. We demonstrated the benefits of the method by isolating the sequences encoding two predicted immunogenic epitopes of the outer membrane protein D encoding gene (ompD) of Salmonella typhimurium. Here, we showed that when using a mixture of three constructs with only one containing an ORF solely this correct construct could be reisolated in phage particles. Further; both epitopes were detected by enzyme-linked immunosorbent assay (ELISA), demonstrating correct translation of fusion proteins. Furthermore, the enrichment system was evaluated by the enrichment of ORFs from total cDNA of lymphocytes. Here, we could show that 60% of the phage contained ORFs, which is an increase of an order of magnitude compared with conventional phage expression system. Together these data show that the Hyperphage-based enrichment system significantly improves the enrichment of ORFs and directly allows the display of the corresponding polypeptide on bacteriophage M13.

Functional expression of Candida antarctica lipase B in the Escherichia coli cytoplasm—a screening system for a frequently used biocatalyst

In this paper, we report for the first time the functional expression of lipase B from the yeast Candida antarctica (CalB) in the Escherichia coli cytoplasm. The enzyme possessing three disulfide bonds was functionally expressed in the strain Origami B. Expression under the control of a lac promoter yielded 2 U mg(-1), whereas expression of a thioredoxin-CalB fusion protein yielded 17 U mg(-1). The native enzyme was most efficiently expressed under control of the cspA promoter (11 U mg(-1)). Coexpression of different chaperones led to a strong increase in active protein formation (up to 61 U mg(-1)). A codon-optimized synthetic variant of calb did not show significant effects on functional protein yield. Functional CalB expression was not only achieved in shake flasks but also in microtiter plate scale. Therefore, this CalB expression system is suitable for high-throughput applications, including the screening of large gene libraries as those derived from directed evolution experiments.

GigaMatrix™: An Ultra High-Throughput Tool for Accessing Biodiversity

Recombinant approaches for tapping into the biodiversity present in nature for the discovery of novel enzymes and biosynthetic pathways can result in large gene libraries. Likewise, laboratory evolution techniques can result in large but potentially valuable libraries. Thorough screening of these libraries requires ultra high-throughput methods. The GigaMatrix™ screening platform addresses this opportunity using reusable high-density plates with 100,000 to 1,000,000 through-hole wells in a microplate footprint. In addition to throughputs of over 107 wells per day, the platform offers a significant reduction in reagent use and waste, has fully integrated automated “cherry picking,” and uses no complicated dispensing equipment. Wells containing putative hits from targeted fluorescent liquid phase assays are revealed by a fluorescent imaging system. Vision-guided robotics are utilized to recover hits by accessing individual 200 μm and smaller wells with a disposable sterile needle. The GigaMatrix platform has proven to be an effective and efficient tool for screening gene libraries for both discovery and evolution applications.

In vitro compartmentalization by double emulsions: sorting and gene enrichment by fluorescence activated cell sorting

Water-in-oil (w/o) emulsions can be used to compartmentalize and select large gene libraries for a predetermined function. The aqueous droplets of the w/o emulsion function as cell-like compartments in each of which a single gene is transcribed and translated to give multiple copies of the protein (e.g., an enzyme) it encodes. While compartmentalization ensures that the gene, the protein it encodes, and the products of the activity of this protein remain linked, it does not directly afford a way of selecting for the desired activity. Here we show that re-emulsification of w/o emulsions gives water-in-oil-in-water (w/o/w) emulsions with an external (continuous) water phase through which droplets containing fluorescent markers can be isolated by fluorescence-activated cell sorting (FACS). These w/o/w emulsions can be sorted by FACS, while the content of the aqueous droplets of the primary w/o emulsion remains intact. Consequently, genes embedded in these water droplets together with a fluorescent marker can be isolated and enriched from an excess of genes embedded in water droplets without a fluorescent marker. The ability of FACS instruments to sort up to 40,000 events per second may endow this technology a wide potential in the area of high-throughput screening and the directed evolution of enzymes.