Preparation of chain-end clickable recombinant protein and its bio-orthogonal modification

Introducing unique functional group into protein is an attractive approach for site-selective protein modification applications. In this report, we systemically investigated four site-selective strategies to introduce azide functionality into recombinant thrombomodulin (TM₄₅₆), via direct recombinant expression with unnatural amino acid, chemical, and enzymatic modification for its bio-orthogonal modification application. First, a straightforward recombinant method to express TM₄₅₆ with azide functionality near C-terminus by replacing methionine with azidohomoanlanine from methionine auxotroph Escherichia coli cell was investigated. Next, a sortase-mediated ligation (SML) method to incorporate azide functionality into the C-terminus of recombinant TM₄₅₆ was demonstrated. The third is to add azide functionality to the N-terminal amine of recombinant TM₄₅₆ via amidation chemistry, and the fourth is tyrosine selective three-component Mannich reaction to introduce azide functionality to recombinant TM₄₅₆. Overall, SML of recombinant protein affords the highest overall yield for incorporating azide functionality into the C-terminus recombinant TM₄₅₆ since the key protein expression step uses natural amino acids. Also, single site modification facilitates the highest TM₄₅₆ activity.     

Chemical modification of enzymes for enhanced functionality.

The explosion in commercial and synthetic applications of enzymes has stimulated much of the interest in enhancing enzyme functionality and stability. Covalent chemical modification, the original method available for altering protein properties, has now re-emerged as a powerful complementary approach to site-directed mutagenesis and directed evolution for tailoring proteins and enzymes. Glutaraldehyde crosslinking of enzyme crystals and polyethylene glycol (PEG) modification of enzyme surface amino groups are practical methods to enhance biocatalyst stability. Whereas crosslinking of enzyme crystals generates easily recoverable insoluble biocatalysts, PEGylation increases solubility in organic solvents. Chemical modification has been exploited for the incorporation of cofactors onto protein templates and for atom replacement in order to generate new functionality, such as the conversion of a hydrolase into a peroxidase. Despite the breadth of applicability of chemically modified enzymes, a difficulty that has previously impeded their implementation is the lack of chemo- or regio-specificity of chemical modifications, which can yield heterogeneous and irreproducible product mixtures. This challenge has recently been addressed by the introduction of a unique position for modification by a site-directed mutation that can subsequently be chemically modified to introduce an unnatural amino acid sidechain in a highly chemo- and regio-specific manner.     

Evaluation and optimisation of unnatural amino acid incorporation and bioorthogonal bioconjugation for site-specific fluorescent labelling of proteins expressed in mammalian cells

Many biophysical techniques that are available to study the structure, function and dynamics of cellular constituents require modification of the target molecules. Site-specific labelling of a protein is of particular interest for fluorescence-based single-molecule measurements including single-molecule FRET or super-resolution microscopy. The labelling procedure should be highly specific but minimally invasive to preserve sensitive biomolecules. The modern molecular engineering toolkit provides elegant solutions to achieve the site-specific modification of a protein of interest often necessitating the incorporation of an unnatural amino acid to introduce a unique reactive moiety. The Amber suppression strategy allows the site-specific incorporation of unnatural amino acids into a protein of interest. Recently, this approach has been transferred to the mammalian expression system. Here, we demonstrate how the combination of unnatural amino acid incorporation paired with current bioorthogonal labelling strategies allow the site-specific engineering of fluorescent dyes into proteins produced in the cellular environment of a human cell. We describe in detail which parameters are important to ensure efficient incorporation of unnatural amino acids into a target protein in human expression systems. We furthermore outline purification and bioorthogonal labelling strategies that allow fast protein preparation and labelling of the modified protein. This way, the complete eukaryotic proteome becomes available for single-molecule fluorescence assays.     

The site-specific incorporation of p-iodo-L-phenylalanine into proteins for structure determination

A recently developed method makes it possible to genetically encode unnatural amino acids with diverse physical, chemical or biological properties in Escherichia coli and yeast. We now show that this technology can be used to efficiently and site-specifically incorporate p-iodo-L-phenylalanine (iodoPhe) into proteins in response to an amber TAG codon. The selective introduction of the anomalously scattering iodine atom into proteins should facilitate single-wavelength anomalous dispersion experiments on in-house X-ray sources. To illustrate this, we generated a Phe153 --> iodoPhe mutant of bacteriophage T4 lysozyme and determined its crystal structure using considerably less data than are needed for the equivalent experiment with cysteine and methionine. The iodoPhe residue, although present in the hydrophobic core of the protein, did not perturb the protein structure in any meaningful way. The ability to selectively introduce this and other heavy atom-containing amino acids into proteins should facilitate the structural study of proteins.     

Genetic incorporation of unnatural amino acids into proteins in mammalian cells

We developed a general approach that allows unnatural amino acids with diverse physicochemical and biological properties to be genetically encoded in mammalian cells. A mutant Escherichia coli aminoacyl-tRNA synthetase (aaRS) is first evolved in yeast to selectively aminoacylate its tRNA with the unnatural amino acid of interest. This mutant aaRS together with an amber suppressor tRNA from Bacillus stearothermophilus is then used to site-specifically incorporate the unnatural amino acid into a protein in mammalian cells in response to an amber nonsense codon. We independently incorporated six unnatural amino acids into GFP expressed in CHO cells with efficiencies up to 1 mug protein per 2 x 10(7) cells; mass spectrometry confirmed a high translational fidelity for the unnatural amino acid. This methodology should facilitate the introduction of biological probes into proteins for cellular studies and may ultimately facilitate the synthesis of therapeutic proteins containing unnatural amino acids in mammalian cells.     

Synthesis of bioorthogonal and crosslinking amino acids for use in peptide synthesis

The ability to incorporate non-canonical amino acids into proteins by genetic or chemical methods allows one to introduce novel chemical properties into a protein at a defined residue. Such a residue may then be modified using common organic transformations. In this way, the structure or function of the peptide may be altered without perturbing any of the other neighbouring amino acids in the peptide chain. Here, we describe the syntheses and potential applications of multiple para-substituted phenylalanine derivatives comprising an isothiocyanate, α-diazoketone, or nitrone functionality. In all, three novel amino acids were synthesized in good overall yields. These non-canonical amino acids permit the further development of in vitro and in vivo chemoselective and regioselective bioconjugate reactions not possible with other reagents.     

An efficient system for the evolution of aminoacyl-tRNA synthetase specificity

A variety of strategies to incorporate unnatural amino acids into proteins have been pursued, but all have limitations with respect to technical accessibility, scalability, applicability to in vivo studies, or site specificity of amino acid incorporation. The ability to selectively introduce unnatural functional groups into specific sites within proteins, in vivo, provides a potentially powerful approach to the study of protein function and to large-scale production of novel proteins. Here we describe a combined genetic selection and screen that allows the rapid evolution of aminoacyl-tRNA synthetase substrate specificity. Our strategy involves the use of an "orthogonal" aminoacyl-tRNA synthetase and tRNA pair that cannot interact with any of the endogenous synthetase-tRNA pairs in Escherichia coli. A chloramphenicol-resistance (Cm(r)) reporter is used to select highly active synthetase variants, and an amplifiable fluorescence reporter is used together with fluorescence-activated cell sorting (FACS) to screen for variants with the desired change in amino acid specificity. Both reporters are contained within a single genetic construct, eliminating the need for plasmid shuttling and allowing the evolution to be completed in a matter of days. Following evolution, the amplifiable fluorescence reporter allows visual and fluorimetric evaluation of synthetase activity and selectivity. Using this system to explore the evolvability of an amino acid binding pocket of a tyrosyl-tRNA synthetase, we identified three new variants that allow the selective incorporation of amino-, isopropyl-, and allyl-containing tyrosine analogs into a desired protein. The new enzymes can be used to produce milligram-per-liter quantities of unnatural amino acid-containing protein in E. coli.     

Chemical mutagenesis: selective post-expression interconversion of protein amino acid residues

The ability to alter protein structure by site-directed mutagenesis has revolutionized biochemical research. Controlled mutations at the DNA level, before protein translation, are now routine. These techniques allow specific, high fidelity interconversion largely between 20 natural, proteinogenic amino acids. Nonetheless, there is a need to incorporate other amino acids, both natural and unnatural, that are not accessible using standard site-directed mutagenesis and expression systems. Post-translational chemistry offers access to these side chains. Nearly half a century ago, the idea of a 'chemical mutation' was proposed and the interconversion between amino acid side chains was demonstrated on select proteins. In these isolated examples, a powerful proof-of-concept was demonstrated. Here, we revive the idea of chemical mutagenesis and discuss the prospect of its general application in protein science. In particular, we consider amino acids that are chemical precursors to a functional set of other side chains. Among these, dehydroalanine has much potential. There are multiple methods available for dehydroalanine incorporation into proteins and this residue is an acceptor for a variety of nucleophiles. When used in conjunction with standard genetic techniques, chemical mutagenesis may allow access to natural, modified, and unnatural amino residues on translated, folded proteins.     

Site-specific labeling of proteins with NMR-active unnatural amino acids

A large number of amino acids other than the canonical amino acids can now be easily incorporated in vivo into proteins at genetically encoded positions. The technology requires an orthogonal tRNA/aminoacyl-tRNA synthetase pair specific for the unnatural amino acid that is added to the media while a TAG amber or frame shift codon specifies the incorporation site in the protein to be studied. These unnatural amino acids can be isotopically labeled and provide unique opportunities for site-specific labeling of proteins for NMR studies. In this perspective, we discuss these opportunities including new photocaged unnatural amino acids, outline usage of metal chelating and spin-labeled unnatural amino acids and expand the approach to in-cell NMR experiments.     

Evolving new genetic codes

Although the genetic code is almost universal, natural variations exist that have caused evolutionary biologists to speculate about codon evolution. There are two predominant hypotheses that specify either a gradual (ambiguous intermediate) or stochastic (codon capture) change in the code. These hypotheses are similar to two biotechnology techniques that have been used to engineer the genetic code: a 'top down' approach, in which the whole organism is evolved for the ability to incorporate unnatural amino acids, and a 'bottom up' approach, in which aminoacyl-tRNA synthetases and their cognate tRNAs are engineered. The biotechnology experiments provide insights into natural codon evolution, and a combination of these approaches should enable the evolution of organisms that can incorporate unnatural amino acids throughout their proteomes.     

Adding amino acids to the genetic repertoire

Considerable progress has been made in expanding the number and nature of genetically encoded amino acids in Escherichia coli, yeast and mammalian cells in the past four years. To date, over 30 unnatural amino acids have been cotranslationally incorporated into proteins with high fidelity and efficiency by means of a unique codon and corresponding orthogonal tRNA-aminoacyl-tRNA synthetase pair. The incorporated amino acids contain spectroscopic probes, post-translational modifications, metal chelators, photoaffinity labels and unique functional groups. The ability to genetically encode additional amino acids, beyond the common 20, provides a powerful approach for probing protein structure and function both in vitro and in vivo, as well as generating proteins with new or enhanced properties.     

Mutations of ferritin H chain C-terminus produced by nucleotide insertions have altered stability and functional properties

Ferritin is an iron storage protein made of 24 subunits. Previous mutational analyses showed that ferritin C-terminal region has a major role in protein stability and assembly but is only marginally involved in the mechanism of iron incorporation. However, it has recently been shown that patients who carry alterations of ferritin C-terminal sequence caused by nucleotide insertions show neurological disorders possibly related to altered protein functionality and cellular iron deregulation. To re-evaluate the role of this region, five mutants of mouse H-ferritin were produced by 2-nucleotide insertions that modified the last 6-29 residues and extended the sequence of 14 amino acids. The mutants were expressed in Escherichia coli and analysed for solubility, stability and capacity to incorporate iron. The alteration of the last 6-residue non-helical extension had no evident effect on the properties of ferritin, while solubility and capacity to assemble in ferritin shells decreased progressively with the extension of the modified region. The results also showed that the modification of even a part of the terminal E-helix abolished the capacity of ferritin to incorporate iron during expression in the cells, probably caused by conformational modification of the hydrophobic channels. The data support the hypothesis that the pathogenic mutations alter cellular iron homeostasis.     

Crucial Optimization of Translational Components towards Efficient Incorporation of Unnatural Amino Acids into Proteins in Mammalian Cells

The ability to site-specifically incorporate unnatural amino acids (UAAs) into proteins is a powerful tool in protein engineering. While dozens of UAAs have been successfully introduced into proteins expressed by Escherichia coli cells, it has been much more challenging to create tRNA and tRNA-Synthetase pairs that enable UAAs incorporation, for use in mammalian systems. By altering the orthogonality properties of existing unnatural pairs, previously evolved pairs for use in E. coli could be used in mammalian cells. This would bypass the cumbersome step of having to evolve mutant synthetases and would allow for the rapid development of new mammalian pairs. A major limitation to the amount of UAA-containing proteins that can be expressed in the cell is the availability of UAA-charged orthogonal suppressor tRNA. By using a natural mammalian tRNA promoter, the amount of functional suppressor tRNA can be greatly increased. Furthermore, increasing recognition of the suppressor tRNA by the mutant synthetase will ultimately lead to the appearance of more UAA-charged tRNA.     

Synthetase polyspecificity as a tool to modulate protein function

The site-specific incorporation of unnatural amino acids (UAAs) into proteins in bacteria is made possible by the evolution of aminoacyl-tRNA synthetases that selectively recognize and aminoacylate the amino acid of interest. Recently we have discovered that some of the previously evolved aaRSs display a degree of polyspecificity and are capable of recognizing multiple UAAs. Herein we report the polyspecificity of an aaRS evolved to encode a comarin containing amino acid. This polyspecificity was then exploited to introduce several UAAs into the fluorophore of GFP, altering its photophysical properties.     

Artificial peptides with unnatural components designed for materializing protein function

In order to design functional peptides, we employed two strategies. The first one is to incorporate rigid unnatural amino acids into peptides to make the peptide backbone rigid. Functions were expected to appear through the conformational control by the strategy. A series of cyclic peptides constituted of alternating natural amino acids and 3-aminobenzoic acid, used as an unnatural amino acid, were synthesized. These cyclic peptides were found to function as strong binders for phosphomonoester, catalysts for ester hydrolysis, and/or ion channels. The second strategy is to conjugate peptides with unnatural and inherently functional molecules. Following this strategy, oligo(L-leucine)- or oligo(L-phenylalanine)-modified ruthenium tris(bipyridine) complexes were synthesized. Distance dependence of the photoinduced electron transfer from the ruthenium complexes and the function as sensors for phosphate anion (H(2)PO(-)(4)) are discussed.     

Unnatural amino acid incorporation onto adenoviral (Ad) coat proteins facilitates chemoselective modification and retargeting of Ad type 5 vectors

Surface modification of adenovirus vectors can improve tissue-selective targeting, attenuate immunogenicity, and enable imaging of particle biodistribution, thus significantly improving therapeutic potential. Currently, surface engineering is constrained by a combination of factors, including impact on viral fitness, limited access to functionality, or incomplete control over the site of modification. Here, we report a two-step labeling process involving an initial metabolic placement of a uniquely reactive unnatural amino acid, azidohomoalanine (Aha), followed by highly specific chemical modification. As genetic modification of adenovirus is unnecessary, vector production is exceedingly straightforward. Aha incorporation demonstrated no discernible impact on either virus production or infectivity of the resultant particles. "Click" chemical modification of surface-exposed azides was highly selective, allowing for the attachment of a wide range of functionality. Decoration of human adenovirus type 5 (hAd5) with folate, a known cancer-targeting moiety, provided an ～20-fold increase in infection of murine breast cancer cells (4T1) in a folate receptor-dependent manner. This study demonstrates that incorporation of unnatural amino acids can provide a flexible, straightforward route for the selective chemical modification of adenoviral vectors.     

Automatic Edman microsequencing of peptides containing multiple unnatural amino acids

It is now routine using automatic Edman microsequencing to determine the primary structure of peptides or proteins containing natural amino acids; however, a deficiency in the ability to readily sequence peptides containing unnatural amino acids remains. With the advent of synthetic peptide chemistry, combinatorial chemistry, and the large number of commercially available unnatural amino acids, there is a need for efficient and accurate structure determination of short peptides containing many unnatural amino acids. In this study, 35 commercially available alpha-unnatural amino acids were selected to determine their elution profile on an ABI protein sequencer. Using a slightly modified gradient program, 19 of these 35 PTH amino acids can be readily resolved and distinguished from common PTH amino acids at low picomole levels. These unnatural amino acids in conjunction with the 20 natural amino acids can be used as building blocks to construct peptide libraries, and peptide beads isolated from these libraries can be readily microsequenced. To demonstrate this, we synthesized a simple tripeptide "one-bead one-compound" combinatorial library containing 14 unnatural and 19 natural amino acids and screened this library for streptavidin-binding ligands. Microsequencing of the isolated peptide-beads revealed the novel motif Bpa-Phe(4-X)-Aib, wherein X = H, OH, and CH3.     

Translational incorporation of multiple unnatural amino acids in a cell-free protein synthesis system

Nature uses 20 canonical amino acids as the standard building blocks of proteins; however, the incorporation of unnatural amino acids (Uaas) can endow polypeptide sequences with new structural and functional features. Although aminoacyl-tRNA synthetases (aaRSs) can accept an array of Uaas in place of their natural counterparts, Uaas generally are charged to tRNAs with substantially lower efficiencies. This particularly makes it difficult to incorporate multiple Uaas into a protein sequence. In this study, we discuss the use of a cell-free protein synthesis system as a versatile platform for the efficient incorporation of multiple Uaas into proteins. Taking advantage of the open nature of cell-free protein synthesis that allows flexible manipulation of its ingredients, we explored the application of Uaas in 10 mM range of concentrations to kinetically overcome the low affinity of aaRSs towards unnatural amino acids. Supplementation of recombinant aaRSs was also investigated to further increase the Uaa-tRNA pools. As a result, under the modified reaction conditions, as many as five different Uaas could be incorporated into a single protein without compromising the yield of protein synthesis.     

无细胞体系非天然蛋白质合成研究进展

无细胞非天然蛋白质合成作为蛋白质研究的新兴手段,已成功用于表征蛋白质分子间、蛋白质与核酸分子间相互作用等基础科学研究及医药蛋白、蛋白质材料等工业生产领域。无细胞非天然蛋白质合成系统不需维持细胞的生长,无细胞膜阻碍,可依据研究目的添加基因元件或化学物质从而增强工程设计和过程调控的自由性;也可赋予蛋白质新的特性、结构及功能,如可实现蛋白翻译后修饰、反应手柄引入、生物物理探针及多聚蛋白质合成等。文中系统地综述了目前应用于无细胞蛋白质合成系统中的非天然氨基酸嵌入方法,包括全局抑制及基于正交翻译体系的终止密码子抑制、移码抑制、有义密码子再分配和非天然碱基等方法的研究进展,及非天然氨基酸在蛋白质修饰、生物物理探针、酶工程、蛋白质材料以及医药蛋白质生产等领域的应用进展,并分析了该体系的发展前景及广泛工业化应用的机遇与挑战。     

Multiple incorporation of non-natural amino acids into a single protein using tRNAs with non-standard structures

The ability to introduce non-natural amino acids into proteins opens up new vistas for the study of protein structure and function. This approach requires suppressor tRNAs that deliver the non-natural amino acid to a ribosome associated with an mRNA containing an expanded codon. The suppressor tRNAs must be absolutely protected from aminoacylation by any of the aminoacyl-tRNA synthetases in the protein synthesizing system, or a natural amino acid will be incorporated instead of the non-natural amino acid. Here, we found that some tRNAs with non-standard structures could work as efficient four-base suppressors fulfilling the above orthogonal conditions. Using these tRNAs, we successfully demonstrated incorporation of three different non-natural amino acids into a single protein.