Genetic Incorporation of a Thioxanthone-Containing Amino Acid for the Design of Artificial Photoenzymes

Genetically encodable photosensitizers allow the design of artificial photoenzymes to expand the scope of abiological reactions. Herein, we report the genetic incorporation of a thioxanthone-containing amino acid into a protein scaffold via an engineered pyrrolysyl-tRNA/pyrrolysyl-tRNA synthetase pair. The designer enzyme was engineered to catalyze a dearomative [2+2] cycloaddition reaction in high yields (up to>99 % yield) with excellent enantioselectivity (up to 98 : 2 e.r.). This work provides a robust and facile method for photoenzyme design and lays the foundation for the development of further photoenzymatic reactions.

Genetic Code Expansion: Recent Developments and Emerging Applications

The concept of genetic code expansion (GCE) has revolutionized the field of chemical and synthetic biology, enabling the site-specific incorporation of noncanonical amino acids (ncAAs) into proteins, thus opening new avenues in research and applications across biology and medicine. In this review, we cover the principles of GCE, including the optimization of the aminoacyl-tRNA synthetase (aaRS)/tRNA system and the advancements in translation system engineering. Notable developments include the refinement of aaRS/tRNA pairs, enhancements in screening methods, and the biosynthesis of noncanonical amino acids. The applications of GCE technology span from synthetic biology, where it facilitates gene expression regulation and protein engineering, to medicine, with promising approaches in drug development, vaccine production, and gene editing. The review concludes with a perspective on the future of GCE, underscoring its potential to further expand the toolkit of biology and medicine. Through this comprehensive review, we aim to provide a detailed overview of the current state of GCE technology, its challenges, opportunities, and the frontier it represents in the expansion of the genetic code for novel biological research and therapeutic applications.

Genetic Code Expansion of the Silkworm Bombyx mori Using a Pyrrolysyl-tRNA Synthetase/tRNAPyl Pair

The domesticated silkworm Bombyx mori, an essential industrial animal for silk production, has attracted attention as a host for protein production due to its remarkable protein synthesis capability. Here, we applied genetic code expansion (GCE) using a versatile pyrrolysyl-tRNA synthetase (PylRS)/tRNAPyl pair from Methanosarcina mazei to B. mori; GCE enables synthetic amino acid incorporation into proteins to give them non-natural functions. Transgenic B. mori lines expressing M. mazei PylRS and its cognate tRNAPyl were generated and cross-mated to obtain their F1 hybrid. Orally administering a click-compatible synthetic amino acid, trans-cyclooctene-lysine (TCO-Lys), to the F1 hybrid has led to the production of silk fiber incorporated with TCO-Lys. TCO-Lys incorporation in silk fiber was verified by selective labeling of the TCO group by click chemistry. The developed system is available for large-scale protein production with a wide variety of synthetic amino acids.

Pyrrolysine Aminoacyl-tRNA Synthetase as a Tool for Expanding the Genetic Code

In addition to the 20 canonical amino acids encoded in the genetic code, there are two non-canonical ones: selenocysteine and pyrrolysine. The discovery of pyrrolysine synthetases (PylRSs) was a key event in the field of genetic code expansion research. The importance of this discovery is mainly due to the fact that the translation systems involving PylRS, pyrrolysine tRNA (tRNAPyl) and pyrrolysine are orthogonal to the endogenous translation systems of organisms that do not use this amino acid in protein synthesis. In addition, pyrrolysine synthetases belonging to different groups are also mutually orthogonal. This orthogonality is based on the structural features of PylRS and tRNAPyl, which include identical elements, such as a condensed core, certain base pairs and the structural motifs of tRNAPyl. This suggests that targeted structural changes in these molecules enable changes in their specificity for the amino acid and the codon. Such modifications were successfully used to obtain different aaRS/tRNA pairs that allow the incorporation of unnatural amino acids into peptides. This review presents the results of recent studies related to the correlation between the structure and activity of PylRS and tRNAPyl and the use of pyrrolysine synthetases to extend the genetic code.

Predicting the polyspecificity of aminoacyl-tRNA synthetase for non-canonical amino acids using molecular dynamics simulation and MM/PBSA

With the advancement of genetic code expansion, the field is progressing towards incorporating multiple non-canonical amino acids (ncAAs). The specificity of aminoacyl-tRNA synthetases (aaRSs) towards ncAAs is a critical factor, as engineered aaRSs frequently show polyspecificity, complicating the precise incorporation of multiple ncAAs. To address this challenge, predicting binding affinity can be beneficial. In this study, we expressed sfGFP using an orthogonal aaRS/tRNA pair with 4-Azido-L-phenylalanine (AzF) and another four different ncAAs. The experimental results showed specificity with O-Methyl-L-tyrosine as well as AzF, and these results were compared with computational predictions. We constructed a mutant aaRS structure specific for AzF through homology modelling and conducted docking studies with tyrosine and five ncAAs, followed by molecular dynamics simulations. The binding affinity was calculated using the molecular mechanics/Poisson-Boltzmann surface area, focusing on nonpolar solvation terms. While the analysis is based on the incorporation of limited number of ncAAs, the cavity and dispersion term method showed consistency with experimental data, highlighting its potential utility compared to the surface area term method. These findings enhance understanding of the ncAA specificity of aaRS in relation to computer simulations and energy calculations, which can be utilized to rationally design or predict the specificity of aaRS.

Isoleucine-to-valine substitutions support cellular physiology during isoleucine deprivation

Aminoacyl-tRNA synthetases (ARSs) couple tRNAs with their corresponding amino acids. While ARSs can bind structurally similar amino acids, extreme specificity is ensured by subsequent editing activity. Yet, we found that upon isoleucine (I) restriction, healthy fibroblasts consistently incorporated valine (V) into proteins at isoleucine codons, resulting from misacylation of tRNAIle with valine by wildtype IARS1. Using a dual-fluorescent reporter of translation, we found that valine supplementation could fully compensate for isoleucine depletion and restore translation to normal levels in healthy, but not IARS1 deficient cells. Similarly, the antiproliferative effects of isoleucine deprivation could be fully restored by valine supplementation in healthy, but not IARS1 deficient cells. This indicates I > V substitutions help prevent translational termination and maintain cellular function in human primary cells during isoleucine deprivation. We suggest that this is an example of a more general mechanism in mammalian cells to preserve translational speed at the cost of translational fidelity in response to (local) amino acid deficiencies.

Human disease-causing missense genetic variants are enriched in the evolutionarily ancient domains of the cytosolic aminoacyl-tRNA synthetase proteins

All life depends on accurate and efficient protein synthesis. The aminoacyl-tRNA synthetases (aaRSs) are a family of proteins that play an essential role in protein translation, as they catalyze the esterification reaction that charges a transfer RNA (tRNA) with its cognate amino acid. However, new domains added to the aaRSs over the course of evolution in eukaryotes confer novel functions unrelated to protein translation. To date, damaging variants that affect aaRS-encoding genes have been linked to over 50 human diseases. In this study, we leverage the evolutionary history of the aaRS proteins to better understand the distribution of disease-causing missense variants in human cytosolic aaRSs. We hypothesized that disease-causing missense variants in human aaRSs were more likely to be located in the ancient domains of the aaRS, essential for the aminoacylation reaction, rather than in the evolutionarily more recent domains found in eukaryotes. We determined the locations of the modern and ancient domains in each aaRS protein found in humans. We then statistically assessed the positional conservation across each domain and examined the distribution of pathogenic and benign/unknown missense human genetic variants across these domains. We establish that pathogenic missense variants in the human aaRS proteins are enriched in the evolutionarily ancient domains while benign/unknown missense variants are enriched in the modern domains. In addition to defining the evolutionary history of human aaRS proteins through domain identification, we anticipate that this work will improve the ability to diagnose patients affected by damaging genetic variants in the aaRS protein family.

Aminoacyl-tRNA synthetase defects in neurological diseases

Aminoacyl-tRNA synthetases (aaRSs) are essential enzymes to support protein synthesis in all organisms. Recent studies, empowered by advancements in genome sequencing, have uncovered an increasing number of disease-causing mutations in aaRSs. Monoallelic aaRS mutations typically lead to dominant peripheral neuropathies such as Charcot-Marie-Tooth (CMT) disease, whereas biallelic aaRS mutations often impair the central nervous system (CNS) and cause neurodevelopmental disorders. Here, we review recent progress in the disease onsets, molecular basis, and potential therapies for diseases caused by aaRS mutations, with a focus on biallelic mutations in cytoplasmic aaRSs.

Photosynthetic demands on translational machinery drive retention of redundant tRNA metabolism in plant organelles

Eukaryotic nuclear genomes often encode distinct sets of translation machinery for function in the cytosol vs. organelles (mitochondria and plastids). This raises questions about why multiple translation systems are maintained even though they are capable of comparable functions and whether they evolve differently depending on the compartment where they operate. These questions are particularly interesting in plants because translation machinery, including aminoacyl-transfer RNA (tRNA) synthetases (aaRS), is often dual-targeted to the plastids and mitochondria. These organelles have different functions, with much higher rates of translation in plastids to supply the abundant, rapid-turnover proteins required for photosynthesis. Previous studies have indicated that plant organellar aaRS evolve more slowly compared to mitochondrial aaRS in eukaryotes that lack plastids. Thus, we investigated the evolution of nuclear-encoded organellar and cytosolic aaRS and tRNA maturation enzymes across a broad sampling of angiosperms, including nonphotosynthetic (heterotrophic) plant species with reduced plastid gene expression, to test the hypothesis that translational demands associated with photosynthesis constrain the evolution of enzymes involved in organellar tRNA metabolism. Remarkably, heterotrophic plants exhibited wholesale loss of many organelle-targeted aaRS and other enzymes, even though translation still occurs in their mitochondria and plastids. These losses were often accompanied by apparent retargeting of cytosolic enzymes and tRNAs to the organelles, sometimes preserving aaRS-tRNA charging relationships but other times creating surprising mismatches between cytosolic aaRS and mitochondrial tRNA substrates. Our findings indicate that the presence of a photosynthetic plastid drives the retention of specialized systems for organellar tRNA metabolism.

Assembly of the Human Multi-tRNA Synthetase Complex Through Leucine Zipper Motifs

Aminoacyl-tRNA synthetases (ARSs) are responsible for the ligation of amino acids to their cognate tRNAs. In human, nine ARSs form a multi-tRNA synthetase complex (MSC) with three ARS-interacting multifunctional proteins (AIMPs). Among the components of MSC, arginyl-tRNA synthetase 1 (RARS1) and two AIMPs (AIMP1 and AIMP2) have leucine zipper (LZ) motifs, which they utilize for their assembly in an MSC. RARS1 and AIMP1 have two LZ motifs (LZ1 and LZ2) in their N-terminus, respectively, while AIMP2 has one LZ motif between its lysyl-tRNA synthetase 1 (KARS1)-binding motif and glutathione transferase-homology domain, which links aspartyl-tRNA synthetase 1 (DARS1). Although the interaction mode between AIMP1 and RARS1, which also binds glutaminyl-tRNA synthetase 1 (QARS1), has been revealed, the mode in the presence of AIMP2 is still ambiguous since AIMP2 is known to not only bind to AIMP1 but also form a homodimer through its LZ. Here, we determined a crystal structure of the LZ complex of AIMP1 and AIMP2 and revealed the interaction mode of a heterotrimeric complex of RARS1, AIMP1, and AIMP2. The complex is established by a three-stranded coiled-coil structure with RARS1 LZ1, AIMP1 LZ1, and AIMP2 LZ and is completed with a two-stranded coiled-coil structure of RARS1 LZ2 and AIMP1 LZ2. In the human MSC, this heterotrimeric complex of RARS1, AIMP1, and AIMP2 allows for a subcomplex of fourteen protein molecules, in which two QARS1-RARS1-AIMP1-AIMP2-2 × KARS1 complexes are linked separately to a dimeric DARS1.

Simultaneous determination of cytosolic aminoacyl-tRNA synthetase activities by LC-MS/MS

In recent years, pathogenic variants in ARS genes, encoding aminoacyl-tRNA synthetases (aaRSs), have been associated with human disease. Patients harbouring pathogenic variants in ARS genes have clinical signs partly unique to certain aaRSs defects, partly overlapping between the different aaRSs defects. Diagnosis relies mostly on genetics and remains challenging, often requiring functional validation of new ARS variants. In this study, we present the development and validation of a method to simultaneously determine aminoacylation activities of all cytosolic aaRSs (encoded by ARS1 genes) in one single cell lysate, improving diagnosis in suspected ARS1 disorders and facilitating functional characterization of ARS1 variants of unknown significance. As proof of concept, we show enzyme activities of five individuals with variants in different ARS1 genes, demonstrating the usability and convenience of the presented method.

AARS Online: A collaborative database on the structure, function, and evolution of the aminoacyl-tRNA synthetases

The aminoacyl-tRNA synthetases (aaRS) are a large group of enzymes that implement the genetic code in all known biological systems. They attach amino acids to their cognate tRNAs, moonlight in various translational and non-translational activities beyond aminoacylation, and are linked to many genetic disorders. The aaRS have a subtle ontology characterized by structural and functional idiosyncrasies that vary from organism to organism, and protein to protein. Across the tree of life, the 22 coded amino acids are handled by 16 evolutionary families of Class I aaRS and 21 families of Class II aaRS. We introduce AARS Online, an interactive Wikipedia-like tool curated by an international consortium of field experts. This platform systematizes existing knowledge about the aaRS by showcasing a taxonomically diverse selection of aaRS sequences and structures. Through its graphical user interface, AARS Online facilitates a seamless exploration between protein sequence and structure, providing a friendly introduction to the material for non-experts and a useful resource for experts. Curated multiple sequence alignments can be extracted for downstream analyses. Accessible at www.aars.online, AARS Online is a free resource to delve into the world of the aaRS.

Comparative proteomics uncovers low asparagine content in Plasmodium tRip-KO proteins

tRNAs are not only essential for decoding the genetic code, but their abundance also has a strong impact on the rate of protein production, folding, and on the stability of the translated messenger RNAs. Plasmodium expresses a unique surface protein called tRip, involved in the import of exogenous tRNAs into the parasite. Comparative proteomic analysis of the blood stage of wild-type and tRip-KO variant of P. berghei parasites revealed that downregulated proteins in the mutant parasite are distinguished by a bias in their asparagine content. Furthermore, the demonstration of the possibility of charging host tRNAs with Plasmodium aminoacyl-tRNA synthetases led us to propose that imported host tRNAs participate in parasite protein synthesis. These results also suggest a novel mechanism of translational control in which import of host tRNAs emerge as regulators of gene expression in the Plasmodium developmental cycle and pathogenesis, by enabling the synthesis of asparagine-rich regulatory proteins that efficiently and selectively control the parasite infectivity.

Coexisting bacterial aminoacyl-tRNA synthetase paralogs exhibit distinct phylogenetic backgrounds and functional compatibility with Escherichia coli

Aminoacyl-tRNA synthetases (aaRSs) are universally essential enzymes that synthesize aminoacyl-tRNA substrates for protein synthesis. Although most organisms require a single aaRS gene for each proteinogenic amino acid to translate their genetic information, numerous species encode multiple gene copies of an aaRS. Growing evidence indicates that organisms acquire extra aaRS genes to sustain or adapt to their unique lifestyle. However, predicting and defining the function of repeated aaRS genes remains challenging due to their potentially unique physiological role in the host organism and the inconsistent annotation of repeated aaRS genes in the literature. Here, we carried out comparative, phylogenetic, and functional studies to determine the activity of coexisting paralogs of tryptophanyl-, tyrosyl-, seryl-, and prolyl-tRNA synthetases encoded in several human pathogenic bacteria. Our analyses revealed that, with a few exceptions, repeated aaRSs involve paralogous genes with distinct phylogenetic backgrounds. Using a collection of Escherichia coli strains that enabled the facile characterization of aaRS activity in vivo, we found that, in almost all cases, one aaRS displayed transfer RNA (tRNA) aminoacylation activity, whereas the other was not compatible with E. coli. Together, this work illustrates the challenges of identifying, classifying, and predicting the function of aaRS paralogs and highlights the complexity of aaRS evolution. Moreover, these results provide new insights into the potential role of aaRS paralogs in the biology of several human pathogens and foundational knowledge for the investigation of the physiological role of repeated aaRS paralogs across bacteria.

Reprogramming the genetic code with flexizymes

In the canonical genetic code, the 61 sense codons are assigned to the 20 proteinogenic amino acids. Advancements in genetic code manipulation techniques have enabled the ribosomal incorporation of nonproteinogenic amino acids (npAAs). The critical molecule for translating messenger RNA (mRNA) into peptide sequences is aminoacyl-transfer RNA (tRNA), which recognizes the mRNA codon through its anticodon. Because aminoacyl-tRNA synthetases (ARSs) are highly specific for their respective amino acid-tRNA pairs, it is not feasible to use natural ARSs to prepare npAA-tRNAs. However, flexizymes are adaptable aminoacylation ribozymes that can be used to prepare diverse aminoacyl-tRNAs at will using amino acids activated with suitable leaving groups. Regarding recognition elements, flexizymes require only an aromatic ring in either the leaving group or side chain of the activated amino acid, and the conserved 3'-end CCA of the tRNA. Therefore, flexizymes allow virtually any amino acid to be charged onto any tRNA. The flexizyme system can handle not only L-α-amino acids with side chain modifications but also various backbone-modified npAAs. This Review describes the development of flexizyme variants and discusses their structure and mechanism and their applications in genetic code reprogramming for the synthesis of unique peptides and proteins.

Noncanonical Amino Acid Tools and Their Application to Membrane Protein Studies

Methods rooted in chemical biology have contributed significantly to studies of integral membrane proteins. One recent key approach has been the application of genetic code expansion (GCE), which enables the site-specific incorporation of noncanonical amino acids (ncAAs) with defined chemical properties into proteins. Efficient GCE is challenging, especially for membrane proteins, which have specialized biogenesis and cell trafficking machinery and tend to be expressed at low levels in cell membranes. Many eukaryotic membrane proteins cannot be expressed functionally in E. coli and are most effectively studied in mammalian cell culture systems. Recent advances have facilitated broader applications of GCE for studies of membrane proteins. First, AARS/tRNA pairs have been engineered to function efficiently in mammalian cells. Second, bioorthogonal chemical reactions, including cell-friendly copper-free "click" chemistry, have enabled linkage of small-molecule probes such as fluorophores to membrane proteins in live cells. Finally, in concert with advances in GCE methodology, the variety of available ncAAs has increased dramatically, thus enabling the investigation of protein structure and dynamics by multidisciplinary biochemical and biophysical approaches. These developments are reviewed in the historical framework of the development of GCE technology with a focus on applications to studies of membrane proteins.

Reaching New Heights in Genetic Code Manipulation with High Throughput Screening

The chemical and physical properties of proteins are limited by the 20 canonical amino acids. Genetic code manipulation allows for the incorporation of noncanonical amino acids (ncAAs) that enhance or alter protein functionality. This review explores advances in the three main strategies for introducing ncAAs into biosynthesized proteins, focusing on the role of high throughput screening in these advancements. The first section discusses engineering aminoacyl-tRNA synthetases (aaRSs) and tRNAs, emphasizing how novel selection methods improve characteristics including ncAA incorporation efficiency and selectivity. The second section examines high-throughput techniques for improving protein translation machinery, enabling accommodation of alternative genetic codes. This includes opportunities to enhance ncAA incorporation through engineering cellular components unrelated to translation. The final section highlights various discovery platforms for high-throughput screening of ncAA-containing proteins, showcasing innovative binding ligands and enzymes that are challenging to create with only canonical amino acids. These advances have led to promising drug leads and biocatalysts. Overall, the ability to discover unexpected functionalities through high-throughput methods significantly influences ncAA incorporation and its applications. Future innovations in experimental techniques, along with advancements in computational protein design and machine learning, are poised to further elevate this field.

Structural Fluctuation in Homodimeric Aminoacyl-tRNA Synthetases Induces Half-of-the-Sites Activity

Enzymatic activity is regulated by various mechanisms to ensure biologically proper functions. Notable instances of such regulation in homodimeric enzymes include "all-of-the-sites activity" and "half-of-the-sites activity". The difference in these activities lies in whether one or both of the subunits are simultaneously active. Owing to its uniqueness, the mechanism of half-of-the-sites activity has been widely investigated. Consequently, structural asymmetry derived from cooperative motion is considered to induce half-of-the-sites activity. In contrast, recent investigations have suggested that subunit-intrinsic properties or structural fluctuation also induces structural asymmetry. Hence, the mechanism underlying half-of-the-sites activity has not been completely elucidated. Additionally, most previous studies have focused only on half-of-the-sites activity. Therefore, by comparing the structural and dynamical properties of two representative homodimers exhibiting all-of-the-sites and half-of-the-sites activities, respectively, we attempted to elucidate the mechanism of half-of-the-sites activity. Specifically, all-atom molecular dynamics simulations were applied to lysyl-tRNA synthetase and tyrosyl-tRNA synthetase. Our analysis revealed that structural fluctuation is sufficient to induce structural asymmetry in addition to the well-established factor of cooperative motion. Considering that structural fluctuation is a common characteristic of any enzyme, it could be a general factor in half-of-the-sites activity.

Uncovering substrate specificity determinants of class IIb aminoacyl-tRNA synthetases with machine learning

Specific amino acid (AA) binding by aminoacyl-tRNA synthetases (aaRSs) is necessary for correct translation of the genetic code. Sequence and structure analyses have revealed the main specificity determinants and allowed a partitioning of aaRSs into two classes and several subclasses. However, the information contributed by each determinant has not been precisely quantified, and other, minor determinants may still be unidentified. Growth of genomic data and development of machine learning classification methods allow us to revisit these questions. This work considered the subclass IIb, formed by the three enzymes aspartyl-, asparaginyl-, and lysyl-tRNA synthetase (LysRS). Over 35,000 sequences from the Pfam database were considered, and used to train a machine-learning model based on ensembles of decision trees. The model was trained to reproduce the existing classification of each sequence as AspRS, AsnRS, or LysRS, and to identify which sequence positions were most important for the classification. A few positions (5-8 depending on the AA substrate) sufficed for accurate classification. Most but not all of them were well-known specificity determinants. The machine learning models thus identified sets of mutations that distinguish the three subclass members, which might be targeted in engineering efforts to alter or swap the AA specificities for biotechnology applications.

Potential Piperolactam A Isolated From Piper betle as Natural Inhibitors of Brucella Species Aminoacyl-tRNA Synthetase for Livestock Infections: In Silico Approach

Brucellosis is an important global zoonosis caused by the bacterium Brucella sp. Brucellosis causes abortions, reproductive failure and reduced milk production, resulting in significant economic losses. Brucella species are reported to be resistant to antibiotics, which makes treatment difficult. The urgency of discovering new drug candidates to combat Brucella's infection necessitates the exploration of novel alternative agents with unique protein targets. Aminoacyl-tRNA synthetases (aaRSs), which have fundamental functions in translation, inhibit this process, stop protein synthesis and ultimately inhibit bacterial growth. The purpose of this study was to isolate piperolactam A compounds from the methanol extract of Piper betle leaves that have potential as antibacterials to inhibit the growth of Brucella sp. causing brucellosis in livestock and to analyse the mechanism of inhibitory activity of piperolactam A compounds against the aaRS enzyme through a molecular docking approach in silico. Piperolactam A was isolated from P. betle by column chromatography and characterized by UV, IR, 1D and 2D NMRs and MS, then tested for their inhibition mechanism against the enzymes threonyl-tRNA synthetase, leucyl-tRNA synthetase (LeuRS) and methionyl-tRNA synthetase in silico. The result in silico test is that piperolactam A has the potential to inhibit LeuRS enzyme with the greater binding affinity.

Tuning the Functionality of Designer Translating Organelles with Orthogonal tRNA Synthetase/tRNA Pairs

Site-specific incorporation of noncanonical amino acids (ncAAs) can be realized by genetic code expansion (GCE) technology. Different orthogonal tRNA synthetase/tRNA (RS/tRNA) pairs have been developed to introduce a ncAA at the desired site, delivering a wide variety of functionalities that can be installed into selected proteins. Cytoplasmic expression of RS/tRNA pairs can cause a problem with background ncAA incorporation into host proteins. The application of orthogonally translating organelles (OTOs), inspired by the concept of phase separation, provides a solution for this issue in mammalian cells, allowing site-specific and protein-selective ncAA incorporation. So far, only Methanosarcina mazei (Mm) pyrrolysyl-tRNA synthetase (PylRS) has been used within OTOs, limiting the method's potential. Here, we explored the implementation of four other widely used orthogonal RS/tRNA pairs with OTOs, which, to our surprise, were unsuccessful in generating mRNA-selective GCE. Next, we tested several experimental solutions and developed a new chimeric phenylalanyl-RS/tRNA pair that enables ncAA incorporation in OTOs in a site-specific and protein-selective manner. Our work reveals unaccounted design constraints in the spatial engineering of enzyme functions using designer organelles and presents a strategy to overcome those in vivo. We then discuss current limitations and future directions of in-cell engineering in general and protein engineering using GCE specifically.

Aligning fermentation conditions with non-canonical amino acid addition strategy is essential for Nε-((2-azidoethoxy)carbonyl)-L-lysine uptake and incorporation into the target protein

Protein engineering with non-canonical amino acids (ncAAs) holds great promises for diverse applications, however, there are still limitations in the implementation of this technology at manufacturing scale. The know-how to efficiently produce ncAA-incorporated proteins in a scalable manner is still very limited. In the present study, we incorporated the ncAA N6-[(2-azidoethoxy)carbonyl]-L-lysine (Azk) into an antigen binding fragment (Fab) in Escherichia coli. We used the orthogonal pyrrolysyl-tRNA synthetase/suppressor tRNACUAPyl pair from Methanosarcina mazei to incorporate Azk site-specifically. We characterized Azk uptake and Fab production at bench-scale under different fermentation conditions, varying timing and mode of Azk addition, Azk-to-cell ratio and induction time. Our results indicate that Azk uptake is comparatively efficient in the batch phase. We discovered that the time between Azk uptake and inducing its incorporation into the Fab must be kept short, which suggests that intracellular Azk is consumed and/or degraded. The results obtained in this study are an important step towards the development of efficient production methods for Azk-incorporated proteins in E. coli. The developed process is scalable and provides excellent yields of 2.95 mg functionalized Fab per g CDM, which corresponds to 80% of yield obtained with the wild type Fab. We also identified the cellular uptake of Azk being dependent on the physiological state of the cell as a potential bottleneck in production.

Biosynthesis of Halogenated Tryptophans for Protein Engineering Using Genetic Code Expansion

Genetic Code Expansion technology offers significant potential in incorporating noncanonical amino acids into proteins at precise locations, allowing for the modulation of protein structures and functions. However, this technology is often limited by the need for costly and challenging-to-synthesize external noncanonical amino acid sources. In this study, we address this limitation by developing autonomous cells capable of biosynthesizing halogenated tryptophan derivatives and introducing them into proteins using Genetic Code Expansion technology. By utilizing inexpensive halide salts and different halogenases, we successfully achieve the selective biosynthesis of 6-chloro-tryptophan, 7-chloro-tryptophan, 6-bromo-tryptophan, and 7-bromo-tryptophan. These derivatives are introduced at specific positions with corresponding bioorthogonal aminoacyl-tRNA synthetase/tRNA pairs in response to the amber codon. Following optimization, we demonstrate the robust expression of proteins containing halogenated tryptophan residues in cells with the ability to biosynthesize these tryptophan derivatives. This study establishes a versatile platform for engineering proteins with various halogenated tryptophans.

Engineering Pyrrolysine Systems for Genetic Code Expansion and Reprogramming

Over the past 16 years, genetic code expansion and reprogramming in living organisms has been transformed by advances that leverage the unique properties of pyrrolysyl-tRNA synthetase (PylRS)/tRNAPyl pairs. Here we summarize the discovery of the pyrrolysine system and describe the unique properties of PylRS/tRNAPyl pairs that provide a foundation for their transformational role in genetic code expansion and reprogramming. We describe the development of genetic code expansion, from E. coli to all domains of life, using PylRS/tRNAPyl pairs, and the development of systems that biosynthesize and incorporate ncAAs using pyl systems. We review applications that have been uniquely enabled by the development of PylRS/tRNAPyl pairs for incorporating new noncanonical amino acids (ncAAs), and strategies for engineering PylRS/tRNAPyl pairs to add noncanonical monomers, beyond α-L-amino acids, to the genetic code of living organisms. We review rapid progress in the discovery and scalable generation of mutually orthogonal PylRS/tRNAPyl pairs that can be directed to incorporate diverse ncAAs in response to diverse codons, and we review strategies for incorporating multiple distinct ncAAs into proteins using mutually orthogonal PylRS/tRNAPyl pairs. Finally, we review recent advances in the encoded cellular synthesis of noncanonical polymers and macrocycles and discuss future developments for PylRS/tRNAPyl pairs.

Aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases hold the key to the genetic code and assign nucleic acid-based codons to amino acids, the building blocks of proteins. In their ability to recognize identity elements on transfer RNAs (tRNAs), some as simple as a single base pair, they ensure that the same proteins are formed each time information embedded in DNA is transcribed into messenger RNA (mRNA) and translated into proteins (Figure 1A). Thus, aminoacyl-tRNA synthetase active sites are conserved; however, since their evolutionary origin, their functions have been co-opted, expanded on and played novel roles during evolution. Below, we provide an overview of the many functions of aminoacyl-tRNA synthetases - from their role in translation, one of the most fundamental processes of all life, to newly discovered, diverse functions.