Your search keyword '"protein engineering"' showing total 620 results

1. Data Science-Driven Analysis of Substrate-Permissive Diketopiperazine Reverse Prenyltransferase NotF: Applications in Protein Engineering and Cascade Biocatalytic Synthesis of (−)-Eurotiumin A

Author

Kelly, Samantha P, Shende, Vikram V, Flynn, Autumn R, Dan, Qingyun, Ye, Ying, Smith, Janet L, Tsukamoto, Sachiko, Sigman, Matthew S, and Sherman, David H

Subjects

Organic Chemistry, Chemical Sciences, Animals, Dimethylallyltranstransferase, Diketopiperazines, Data Science, Indole Alkaloids, Protein Engineering, Biological Products, Flavins, Mixed Function Oxygenases, Solvents, Carbon, Substrate Specificity, General Chemistry, Chemical sciences, Engineering

Abstract

Prenyltransfer is an early-stage carbon-hydrogen bond (C-H) functionalization prevalent in the biosynthesis of a diverse array of biologically active bacterial, fungal, plant, and metazoan diketopiperazine (DKP) alkaloids. Toward the development of a unified strategy for biocatalytic construction of prenylated DKP indole alkaloids, we sought to identify and characterize a substrate-permissive C2 reverse prenyltransferase (PT). As the first tailoring event within the biosynthesis of cytotoxic notoamide metabolites, PT NotF catalyzes C2 reverse prenyltransfer of brevianamide F. Solving a crystal structure of NotF (in complex with native substrate and prenyl donor mimic dimethylallyl S-thiolodiphosphate (DMSPP)) revealed a large, solvent-exposed active site, intimating NotF may possess a significantly broad substrate scope. To assess the substrate selectivity of NotF, we synthesized a panel of 30 sterically and electronically differentiated tryptophanyl DKPs, the majority of which were selectively prenylated by NotF in synthetically useful conversions (2 to >99%). Quantitative representation of this substrate library and development of a descriptive statistical model provided insight into the molecular origins of NotF's substrate promiscuity. This approach enabled the identification of key substrate descriptors (electrophilicity, size, and flexibility) that govern the rate of NotF-catalyzed prenyltransfer, and the development of an "induced fit docking (IFD)-guided" engineering strategy for improved turnover of our largest substrates. We further demonstrated the utility of NotF in tandem with oxidative cyclization using flavin monooxygenase, BvnB. This one-pot, in vitro biocatalytic cascade enabled the first chemoenzymatic synthesis of the marine fungal natural product, (-)-eurotiumin A, in three steps and 60% overall yield.

Published

2022

2. A Genetically Encoded Fluorosulfonyloxybenzoyl-l-lysine for Expansive Covalent Bonding of Proteins via SuFEx Chemistry.

Author

Liu, Jun, Cao, Li, Klauser, Paul C, Cheng, Rujin, Berdan, Viktoriya Y, Sun, Wei, Wang, Nanxi, Ghelichkhani, Farid, Yu, Bingchen, Rozovsky, Sharon, and Wang, Lei

Subjects

Animals, Humans, Escherichia coli, Proteins, Bacterial Proteins, Green Fluorescent Proteins, Cross-Linking Reagents, Protein Engineering, Protein Conformation, Protein Binding, Models, Molecular, ErbB Receptors, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Chemical Sciences, General Chemistry

Abstract

Genetically introducing novel chemical bonds into proteins provides innovative avenues for biochemical research, protein engineering, and biotherapeutic applications. Recently, latent bioreactive unnatural amino acids (Uaas) have been incorporated into proteins to covalently target natural residues through proximity-enabled reactivity. Aryl fluorosulfate is particularly attractive due to its exceptional biocompatibility and multitargeting capability via sulfur(VI) fluoride exchange (SuFEx) reaction. Thus far, fluorosulfate-l-tyrosine (FSY) is the only aryl fluorosulfate-containing Uaa that has been genetically encoded. FSY has a relatively rigid and short side chain, which restricts the diversity of proteins targetable and the scope of applications. Here we designed and genetically encoded a new latent bioreactive Uaa, fluorosulfonyloxybenzoyl-l-lysine (FSK), in E. coli and mammalian cells. Due to its long and flexible aryl fluorosulfate-containing side chain, FSK was particularly useful in covalently linking protein sites that are unreachable with FSY, both intra- and intermolecularly, in vitro and in live cells. In addition, we created covalent nanobodies that irreversibly bound to epidermal growth factor receptors (EGFR) on cells, with FSK and FSY targeting distinct positions on EGFR to counter potential mutational resistance. Moreover, we established the use of FSK and FSY for genetically encoded chemical cross-linking to capture elusive enzyme-substrate interactions in live cells, allowing us to target residues aside from Cys and to cross-link at the binding periphery. FSK complements FSY to expand target diversity and versatility. Together, they provide a powerful, genetically encoded, latent bioreactive SuFEx system for creating covalent bonds in diverse proteins in vitro and in vivo, which will be widely useful for biological research and applications.

Published

2021

3. De Novo Design, Solution Characterization, and Crystallographic Structure of an Abiological Mn-Porphyrin-Binding Protein Capable of Stabilizing a Mn(V) Species.

Author

Mann, Samuel, Nayak, Animesh, Gassner, George, Therien, Michael, and DeGrado, William

Subjects

Amino Acid Sequence, Crystallography, X-Ray, Hemeproteins, Manganese, Metalloporphyrins, Oxidation-Reduction, Protein Binding, Protein Engineering, Sulfides

Abstract

De novo protein design offers the opportunity to test our understanding of how metalloproteins perform difficult transformations. Attaining high-resolution structural information is critical to understanding how such designs function. There have been many successes in the design of porphyrin-binding proteins; however, crystallographic characterization has been elusive, limiting what can be learned from such studies as well as the extension to new functions. Moreover, formation of highly oxidizing high-valent intermediates poses design challenges that have not been previously implemented: (1) purposeful design of substrate/oxidant access to the binding site and (2) limiting deleterious oxidation of the protein scaffold. Here we report the first crystallographically characterized porphyrin-binding protein that was programmed to not only bind a synthetic Mn-porphyrin but also maintain binding site access to form high-valent oxidation states. We explicitly designed a binding site with accessibility to dioxygen units in the open coordination site of the Mn center. In solution, the protein is capable of accessing a high-valent Mn(V)-oxo species which can transfer an O atom to a thioether substrate. The crystallographic structure is within 0.6 Å of the design and indeed contained an aquo ligand with a second water molecule stabilized by hydrogen bonding to a Gln side chain in the active site, offering a structural explanation for the observed reactivity.

Published

2021

4. Computational-Based Mechanistic Study and Engineering of Cytochrome P450 MycG for Selective Oxidation of 16-Membered Macrolide Antibiotics

Author

Yang, Song, DeMars, Matthew D, Grandner, Jessica M, Olson, Noelle M, Anzai, Yojiro, Sherman, David H, and Houk, KN

Subjects

Chemical Sciences, Bioengineering, Anti-Bacterial Agents, Cytochrome P-450 Enzyme System, Macrolides, Molecular Conformation, Molecular Dynamics Simulation, Oxidation-Reduction, Protein Engineering, General Chemistry, Chemical sciences, Engineering

Abstract

MycG is a cytochrome P450 that performs two sequential oxidation reactions on the 16-membered ring macrolide M-IV. The enzyme evolved to oxidize M-IV preferentially over M-III and M-VI, which differ only by the presence of methoxy vs free hydroxyl groups on one of the macrolide sugar moieties. We utilized a two-pronged computational approach to study both the chemoselective reactivity and substrate specificity of MycG. Density functional theory computations determined that epoxidation of the substrate hampers its ability to undergo C-H abstraction, primarily due to a loss of hyperconjugation in the transition state. Metadynamics and molecular dynamics simulations revealed a hydrophobic sugar-binding pocket that is responsible for substrate recognition/specificity and was not apparent in crystal structures of the enzyme/substrate complex. Computational results also led to the identification of other interactions between the enzyme and its substrates that had not previously been observed in the cocrystal structures. Site-directed mutagenesis was then employed to test the effects of mutations hypothesized to broaden the substrate scope and alter the product profile of MycG. The results of these experiments validated this complementary effort to engineer MycG variants with improved catalytic activity toward earlier stage mycinamicin substrates.

Published

2020

5. Chemoinformatic-Guided Engineering of Polyketide Synthases

Author

Zargar, Amin, Lal, Ravi, Valencia, Luis, Wang, Jessica, Backman, Tyler William H, Cruz-Morales, Pablo, Kothari, Ankita, Werts, Miranda, Wong, Andrew R, Bailey, Constance B, Loubat, Arthur, Liu, Yuzhong, Chen, Yan, Chang, Samantha, Benites, Veronica T, Hernández, Amanda C, Barajas, Jesus F, Thompson, Mitchell G, Barcelos, Carolina, Anayah, Rasha, Martin, Hector Garcia, Mukhopadhyay, Aindrila, Petzold, Christopher J, Baidoo, Edward EK, Katz, Leonard, and Keasling, Jay D

Subjects

Medicinal and Biomolecular Chemistry, Chemical Sciences, Computational Biology, Molecular Structure, Polyketide Synthases, Protein Engineering, General Chemistry, Chemical sciences, Engineering

Abstract

Polyketide synthase (PKS) engineering is an attractive method to generate new molecules such as commodity, fine and specialty chemicals. A significant challenge is re-engineering a partially reductive PKS module to produce a saturated β-carbon through a reductive loop (RL) exchange. In this work, we sought to establish that chemoinformatics, a field traditionally used in drug discovery, offers a viable strategy for RL exchanges. We first introduced a set of donor RLs of diverse genetic origin and chemical substrates  into the first extension module of the lipomycin PKS (LipPKS1). Product titers of these engineered unimodular PKSs correlated with chemical structure similarity between the substrate of the donor RLs and recipient LipPKS1, reaching a titer of 165 mg/L of short-chain fatty acids produced by the host Streptomyces albus J1074. Expanding this method to larger intermediates that require bimodular communication, we introduced RLs of divergent chemosimilarity into LipPKS2 and determined triketide lactone production. Collectively, we observed a statistically significant correlation between atom pair chemosimilarity and production, establishing a new chemoinformatic method that may aid in the engineering of PKSs to produce desired, unnatural products.

Published

2020

6. Tailoring Tryptophan Synthase TrpB for Selective Quaternary Carbon Bond Formation

Author

Dick, Markus, Sarai, Nicholas S, Martynowycz, Michael W, Gonen, Tamir, and Arnold, Frances H

Subjects

Prevention, Alkylation, Carbon, Models, Molecular, Protein Conformation, Protein Engineering, Tryptophan Synthase, Chemical Sciences, General Chemistry

Abstract

We previously engineered the β-subunit of tryptophan synthase (TrpB), which catalyzes the condensation of l-serine and indole to l-tryptophan, to synthesize a range of noncanonical amino acids from l-serine and indole derivatives or other nucleophiles. Here we employ directed evolution to engineer TrpB to accept 3-substituted oxindoles and form C-C bonds leading to new quaternary stereocenters. Initially, the variants that could use 3-substituted oxindoles preferentially formed N-C bonds on N1 of the substrate. Protecting N1 encouraged evolution toward C-alkylation, which persisted when protection was removed. Six generations of directed evolution resulted in TrpB Pfquat with a 400-fold improvement in activity for alkylation of 3-substituted oxindoles and the ability to selectively form a new, all-carbon quaternary stereocenter at the γ-position of the amino acid products. The enzyme can also alkylate and form all-carbon quaternary stereocenters on structurally similar lactones and ketones, where it exhibits excellent regioselectivity for the tertiary carbon. The configurations of the γ-stereocenters of two of the products were determined via microcrystal electron diffraction (MicroED), and we report the MicroED structure of a small molecule obtained using the Falcon III direct electron detector. Highly thermostable and expressed at >500 mg/L E. coli culture, TrpB Pfquat offers an efficient, sustainable, and selective platform for the construction of diverse noncanonical amino acids bearing all-carbon quaternary stereocenters.

Published

2019

7. Genetically Targeted Optical Control of an Endogenous G Protein-Coupled Receptor

Author

Donthamsetti, Prashant C, Broichhagen, Johannes, Vyklicky, Vojtech, Stanley, Cherise, Fu, Zhu, Visel, Meike, Levitz, Joshua L, Javitch, Jonathan A, Trauner, Dirk, and Isacoff, Ehud Y

Subjects

Neurosciences, 1.1 Normal biological development and functioning, Underpinning research, Amino Acids, Animals, Azo Compounds, Cell Membrane, Glutamic Acid, HEK293 Cells, Humans, Ligands, Light, Molecular Biology, Neurons, Photochemical Processes, Protein Engineering, Rats, Receptors, G-Protein-Coupled, Receptors, Metabotropic Glutamate, Recombinant Proteins, Xanthenes, Chemical Sciences, General Chemistry

Abstract

G protein-coupled receptors (GPCRs) are membrane proteins that play important roles in biology. However, our understanding of their function in complex living systems is limited because we lack tools that can target individual receptors with sufficient precision. State-of-the-art approaches, including DREADDs, optoXRs, and PORTL gated-receptors, control GPCR signaling with molecular, cell type, and temporal specificity. Nonetheless, these tools are based on engineered non-native proteins that may (i) express at nonphysiological levels, (ii) localize and turnover incorrectly, and/or (iii) fail to interact with endogenous partners. Alternatively, membrane-anchored ligands (t-toxins, DARTs) target endogenous receptors with molecular and cell type specificity but cannot be turned on and off. In this study, we used a combination of chemistry, biology, and light to control endogenous metabotropic glutamate receptor 2 (mGluR2), a Family C GPCR, in primary cortical neurons. mGluR2 was rapidly, reversibly, and selectively activated with photoswitchable glutamate tethered to a genetically targeted-plasma membrane anchor (membrane anchored Photoswitchable Orthogonal Remotely Tethered Ligand; maPORTL). Photoactivation was tuned by adjusting the length of the PORTL as well as the expression level and geometry of the membrane anchor. Our findings provide a template for controlling endogenous GPCRs with cell type specificity and high spatiotemporal precision.

Published

2019

8. Genetically Encoding Photocaged Quinone Methide to Multitarget Protein Residues Covalently in Vivo

Author

Liu, Jun, Li, Shanshan, Aslam, Nayyar A, Zheng, Feng, Yang, Bing, Cheng, Rujin, Wang, Nanxi, Rozovsky, Sharon, Wang, Peng G, Wang, Qian, and Wang, Lei

Subjects

Generic health relevance, Cross-Linking Reagents, Escherichia coli, HeLa Cells, Humans, Light, Phenylalanine, Protein Engineering, Proteins, Hela Cells, Chemical Sciences, General Chemistry

Abstract

Genetically introducing covalent bonds into proteins in vivo with residue specificity is affording innovative ways for protein research and engineering, yet latent bioreactive unnatural amino acids (Uaas) genetically encoded to date react with one to few natural residues only, limiting the variety of proteins and the scope of applications amenable to this technology. Here we report the genetic encoding of (2 R)-2-amino-3-fluoro-3-(4-((2-nitrobenzyl)oxy) phenyl) propanoic acid (FnbY) in Escherichia coli and mammalian cells. Upon photoactivation, FnbY generated a reactive quinone methide (QM), which selectively reacted with nine natural amino acid residues placed in proximity in proteins directly in live cells. In addition to Cys, Lys, His, and Tyr, photoactivated FnbY also reacted with Trp, Met, Arg, Asn, and Gln, which are inaccessible with existing latent bioreactive Uaas. FnbY thus dramatically expanded the number of residues for covalent targeting in vivo. QM has longer half-life than the intermediates of conventional photo-cross-linking Uaas, and FnbY exhibited cross-linking efficiency higher than p-azido-phenylalanine. The photoactivatable and multitargeting reactivity of FnbY with selectivity toward nucleophilic residues will be valuable for addressing diverse proteins and broadening the scope of applications through exploiting covalent bonding in vivo for chemical biology, biotherapeutics, and protein engineering.

Published

2019

9. Genetically Introducing Biochemically Reactive Amino Acids Dehydroalanine and Dehydrobutyrine in Proteins

Author

Yang, Bing, Wang, Nanxi, Schnier, Paul D, Zheng, Feng, Zhu, He, Polizzi, Nicholas F, Ittuveetil, Avinash, Saikam, Varma, DeGrado, William F, Wang, Qian, Wang, Peng G, and Wang, Lei

Subjects

Biotechnology, Generic health relevance, Alanine, Aminobutyrates, Models, Molecular, Protein Engineering, Protein Structure, Secondary, Chemical Sciences, General Chemistry

Abstract

Expansion of the genetic code with unnatural amino acids (Uaas) has significantly increased the chemical space available to proteins for exploitation. Due to the inherent limitation of translational machinery and the required compatibility with biological settings, function groups introduced via Uaas to date are restricted to chemically inert, bioorthogonal, or latent bioreactive groups. To break this barrier, here we report a new strategy enabling the specific incorporation of biochemically reactive amino acids into proteins. A latent bioreactive amino acid is genetically encoded at a position proximal to the target natural amino acid; they react via proximity-enabled reactivity, selectively converting the latter into a reactive residue in situ. Using this Genetically Encoded Chemical COnversion (GECCO) strategy and harnessing the sulfur-fluoride exchange (SuFEx) reaction between fluorosulfate-l-tyrosine and serine or threonine, we site-specifically generated the reactive dehydroalanine and dehydrobutyrine into proteins. GECCO works both inter- and intramolecularly, and is compatible with various proteins. We further labeled the resultant dehydroalanine-containing protein with thiol-saccharide to generate glycoprotein mimetics. GECCO represents a new solution for selectively introducing biochemically reactive amino acids into proteins and is expected to open new avenues for exploiting chemistry in live systems for biological research and engineering.

Published

2019

10. Overriding Traditional Electronic Effects in Biocatalytic Baeyer–Villiger Reactions by Directed Evolution

Author

Li, Guangyue, Garcia-Borràs, Marc, Fürst, Maximilian JLJ, Ilie, Adriana, Fraaije, Marco W, Houk, KN, and Reetz, Manfred T

Subjects

Biocatalysis, Directed Molecular Evolution, Kinetics, Protein Engineering, Chemical Sciences, General Chemistry

Abstract

Controlling the regioselectivity of Baeyer-Villiger (BV) reactions remains an ongoing issue in organic chemistry, be it by synthetic catalysts or enzymes of the type Baeyer-Villiger monooxygenases (BVMOs). Herein, we address the challenging problem of switching normal to abnormal BVMO regioselectivity by directed evolution using three linear ketones as substrates, which are not structurally biased toward abnormal reactivity. Upon applying iterative saturation mutagenesis at sites lining the binding pocket of the thermostable BVMO from Thermocrispum municipale DSM 44069 (TmCHMO) and using 4-phenyl-2-butanone as substrate, the regioselectivity was reversed from 99:1 (wild-type enzyme in favor of the normal product undergoing 2-phenylethyl migration) to 2:98 in favor of methyl migration when applying the best mutant. This also stands in stark contrast to the respective reaction using the synthetic reagent m-CPBA, which provides solely the normal product. Reversal of regioselectivity was also achieved in the BV reaction of two other linear ketones. Kinetic parameters and melting temperatures revealed that most of the evolved mutants retained catalytic activity, as well as thermostability. In order to shed light on the origin of switched regioselectivity in reactions of 4-phenyl-2-butanone and phenylacetone, extensive QM/MM and MD simulations were performed. It was found that the mutations introduced by directed evolution induce crucial changes in the conformation of the respective Criegee intermediates and transition states in the binding pocket of the enzyme. In mutants that destabilize the normally preferred migration transition state, a reversal of regioselectivity is observed. This conformational control of regioselectivity overrides electronic control, which normally causes preferential migration of the group that is best able to stabilize positive charge. The results can be expected to aid future protein engineering of BVMOs.

Published

2018

11. Site-Specific Incorporation of Selenocysteine Using an Expanded Genetic Code and Palladium-Mediated Chemical Deprotection

Author

Liu, Jun, Zheng, Feng, Cheng, Rujin, Li, Shanshan, Rozovsky, Sharon, Wang, Qian, and Wang, Lei

Subjects

Codon, Terminator, Escherichia coli, Escherichia coli Proteins, Genetic Code, Glutathione Peroxidase, HeLa Cells, Humans, Models, Molecular, Palladium, Protein Biosynthesis, Protein Engineering, Selenocysteine, Selenoproteins, Thioredoxins, Glutathione Peroxidase GPX1, Hela Cells, Chemical Sciences, General Chemistry

Abstract

Selenoproteins containing the 21st amino acid selenocysteine (Sec) exist in all three kingdoms of life and play essential roles in human health and development. The distinct low p Ka, high reactivity, and redox property of Sec also afford unique routes to protein modification and engineering. However, natural Sec incorporation requires idiosyncratic translational machineries that are dedicated to Sec and species-dependent, which makes it challenging to recombinantly prepare selenoproteins with high Sec specificity. As a consequence, the function of half of human selenoproteins remains unclear, and Sec-based protein manipulation has been greatly hampered. Here we report a new general method enabling the site-specific incorporation of Sec into proteins in E. coli. An orthogonal tRNAPyl-ASecRS was evolved to specifically incorporate Se-allyl selenocysteine (ASec) in response to the amber codon, and the incorporated ASec was converted to Sec in high efficiency through palladium-mediated cleavage under mild conditions compatible with proteins and cells. This approach completely obviates the natural Sec-dedicated factors, thus allowing various selenoproteins, regardless of Sec position and species source, to be prepared with high Sec specificity and enzyme activity, as shown by the preparation of human thioredoxin and glutathione peroxidase 1. Sec-selective labeling in the presence of Cys was also demonstrated on the surface of live E. coli cells. The tRNAPyl-ASecRS pair was further used in mammalian cells to incorporate ASec, which was converted into Sec by palladium catalyst in cellulo. This robust and versatile method should greatly facilitate the study of diverse natural selenoproteins and the engineering of proteins in general via site-specific introduction of Sec.

Published

2018

12. Multiple Click-Selective tRNA Synthetases Expand Mammalian Cell-Specific Proteomics.

Author

Yang, Andrew, du Bois, Haley, Olsson, Niclas, Gate, David, Lehallier, Benoit, Berdnik, Daniela, Brewer, Kyle, Bertozzi, Carolyn, Elias, Joshua, and Wyss-Coray, Tony

Subjects

Alkynes, Amino Acids, Animals, Azides, Base Sequence, CHO Cells, Click Chemistry, Cricetulus, Cycloaddition Reaction, Female, HEK293 Cells, Humans, Methionine-tRNA Ligase, Mice, Mice, Inbred C57BL, Mutation, Protein Engineering, Proteome, Proteomics, Saccharomyces cerevisiae, Tyrosine-tRNA Ligase

Abstract

Bioorthogonal tools enable cell-type-specific proteomics, a prerequisite to understanding biological processes in multicellular organisms. Here we report two engineered aminoacyl-tRNA synthetases for mammalian bioorthogonal labeling: a tyrosyl ( ScTyrY43G) and a phenylalanyl ( MmPheT413G) tRNA synthetase that incorporate azide-bearing noncanonical amino acids specifically into the nascent proteomes of host cells. Azide-labeled proteins are chemoselectively tagged via azide-alkyne cycloadditions with fluorophores for imaging or affinity resins for mass spectrometric characterization. Both mutant synthetases label human, hamster, and mouse cell line proteins and selectively activate their azido-bearing amino acids over 10-fold above the canonical. ScTyrY43G and MmPheT413G label overlapping but distinct proteomes in human cell lines, with broader proteome coverage upon their coexpression. In mice, ScTyrY43G and MmPheT413G label the melanoma tumor proteome and plasma secretome. This work furnishes new tools for mammalian residue-specific bioorthogonal chemistry, and enables more robust and comprehensive cell-type-specific proteomics in live mammals.

Published

2018

13. Receptor-Mediated Delivery of CRISPR-Cas9 Endonuclease for Cell-Type-Specific Gene Editing

Author

Rouet, Romain, Thuma, Benjamin A, Roy, Marc D, Lintner, Nathanael G, Rubitski, David M, Finley, James E, Wisniewska, Hanna M, Mendonsa, Rima, Hirsh, Ariana, de Oñate, Lorena, Barrón, Joan Compte, McLellan, Thomas J, Bellenger, Justin, Feng, Xidong, Varghese, Alison, Chrunyk, Boris A, Borzilleri, Kris, Hesp, Kevin D, Zhou, Kaihong, Ma, Nannan, Tu, Meihua, Dullea, Robert, McClure, Kim F, Wilson, Ross C, Liras, Spiros, Mascitti, Vincent, and Doudna, Jennifer A

Subjects

Engineering, Chemical Sciences, Genetics, Digestive Diseases, Biotechnology, Gene Therapy, 5.2 Cellular and gene therapies, 1.1 Normal biological development and functioning, Cancer, Generic health relevance, CRISPR-Cas Systems, Cell Line, Tumor, Endonucleases, Gene Editing, Hep G2 Cells, Humans, Molecular Structure, Protein Engineering, General Chemistry, Chemical sciences

Abstract

CRISPR-Cas RNA-guided endonucleases hold great promise for disrupting or correcting genomic sequences through site-specific DNA cleavage and repair. However, the lack of methods for cell- and tissue-selective delivery currently limits both research and clinical uses of these enzymes. We report the design and in vitro evaluation of S. pyogenes Cas9 proteins harboring asialoglycoprotein receptor ligands (ASGPrL). In particular, we demonstrate that the resulting ribonucleoproteins (Cas9-ASGPrL RNP) can be engineered to be preferentially internalized into cells expressing the corresponding receptor on their surface. Uptake of such fluorescently labeled proteins in liver-derived cell lines HEPG2 (ASGPr+) and SKHEP (control; diminished ASGPr) was studied by live cell imaging and demonstrates increased accumulation of Cas9-ASGPrL RNP in HEPG2 cells as a result of effective ASGPr-mediated endocytosis. When uptake occurred in the presence of a peptide with endosomolytic properties, we observed receptor-facilitated and cell-type specific gene editing that did not rely on electroporation or the use of transfection reagents. Overall, these in vitro results validate the receptor-mediated delivery of genome-editing enzymes as an approach for cell-selective gene editing and provide a framework for future potential applications to hepatoselective gene editing in vivo.

Published

2018

14. A Bioorthogonal Precision Tool for Human N -Acetylglucosaminyltransferase V.

Author

Liu Y, Bineva-Todd G, Meek RW, Mazo L, Piniello B, Moroz O, Burnap SA, Begum N, Ohara A, Roustan C, Tomita S, Kjaer S, Polizzi K, Struwe WB, Rovira C, Davies GJ, and Schumann B

Subjects

Humans, Substrate Specificity, Protein Engineering, Models, Molecular, N-Acetylglucosaminyltransferases metabolism, N-Acetylglucosaminyltransferases chemistry

Abstract

Correct elaboration of N-linked glycans in the secretory pathway of human cells is essential in physiology. Early N-glycan biosynthesis follows an assembly line principle before undergoing crucial elaboration points that feature the sequential incorporation of the sugar N -acetylglucosamine (GlcNAc). The activity of GlcNAc transferase V (MGAT5) primes the biosynthesis of an N-glycan antenna that is heavily upregulated in cancer. Still, the functional relevance and substrate choice of MGAT5 are ill-defined. Here, we employ protein engineering to develop a bioorthogonal substrate analog for the activity of MGAT5. Chemoenzymatic synthesis is used to produce a collection of nucleotide-sugar analogs with bulky, bioorthogonal acylamide side chains. We find that WT-MGAT5 displays considerable activity toward such substrate analogues. Protein engineering yields an MGAT5 variant that loses activity against the native nucleotide sugar and increases activity toward a 4-azidobutyramide-containing substrate analogue. By such restriction of substrate specificity, we show that the orthogonal enzyme-substrate pair is suitable to bioorthogonally tag glycoproteins. Through X-ray crystallography and molecular dynamics simulations, we establish the structural basis of MGAT5 engineering, informing the design rules for bioorthogonal precision chemical tools.

Published

2024

15. Design and Evolution of an Artificial Friedel-Crafts Alkylation Enzyme Featuring an Organoboronic Acid Residue.

Author

Mou SB, Chen KY, Kunthic T, and Xiang Z

Subjects

Alkylation, Stereoisomerism, Molecular Structure, Palladium chemistry, Biocatalysis, Protein Engineering, Boronic Acids chemistry

Abstract

Creating artificial enzymes by the genetic incorporation of noncanonical amino acids with catalytic side chains would expand the enzyme chemistries that have not been discovered in nature. Here, we report the design of an artificial enzyme that uses p -boronophenylalanine as the catalytic residue. The artificial enzyme catalyzes Michael-type Friedel-Crafts alkylation through covalent activation. The designer enzyme was further engineered to afford high yields with excellent enantioselectivities. We next developed a practical method for preparative-scale reactions by whole-cell catalysis. This enzymatic C-C bond formation reaction was combined with palladium-catalyzed dearomative arylation to achieve the efficient synthesis of spiroindolenine compounds.

Published

2024

16. Production of Odd-Carbon Dicarboxylic Acids in Escherichia coli Using an Engineered Biotin–Fatty Acid Biosynthetic Pathway

Author

Haushalter, Robert W, Phelan, Ryan M, Hoh, Kristina M, Su, Cindy, Wang, George, Baidoo, Edward EK, and Keasling, Jay D

Subjects

Engineering, Chemical Sciences, Responsible Consumption and Production, Biosynthetic Pathways, Biotin, Carbon, Dicarboxylic Acids, Escherichia coli, Fatty Acids, Molecular Structure, Protein Engineering, General Chemistry, Chemical sciences

Abstract

Dicarboxylic acids are commodity chemicals used in the production of plastics, polyesters, nylons, fragrances, and medications. Bio-based routes to dicarboxylic acids are gaining attention due to environmental concerns about petroleum-based production of these compounds. Some industrial applications require dicarboxylic acids with specific carbon chain lengths, including odd-carbon species. Biosynthetic pathways involving cytochrome P450-catalyzed oxidation of fatty acids in yeast and bacteria have been reported, but these systems produce almost exclusively even-carbon species. Here we report a novel pathway to odd-carbon dicarboxylic acids directly from glucose in Escherichia coli by employing an engineered pathway combining enzymes from biotin and fatty acid synthesis. Optimization of the pathway will lead to industrial strains for the production of valuable odd-carbon diacids.

Published

2017

17. Orthogonal Luciferase–Luciferin Pairs for Bioluminescence Imaging

Author

Jones, Krysten A, Porterfield, William B, Rathbun, Colin M, McCutcheon, David C, Paley, Miranda A, and Prescher, Jennifer A

Subjects

Engineering, Chemical Sciences, Biomedical Imaging, Generic health relevance, Animals, Cells, Cultured, Fireflies, Firefly Luciferin, HEK293 Cells, Humans, Luciferases, Luminescent Measurements, Molecular Structure, Protein Engineering, General Chemistry, Chemical sciences

Abstract

Bioluminescence imaging with luciferase-luciferin pairs is widely used in biomedical research. Several luciferases have been identified in nature, and many have been adapted for tracking cells in whole animals. Unfortunately, the optimal luciferases for imaging in vivo utilize the same substrate and therefore cannot easily differentiate multiple cell types in a single subject. To develop a broader set of distinguishable probes, we crafted custom luciferins that can be selectively processed by engineered luciferases. Libraries of mutant enzymes were iteratively screened with sterically modified luciferins, and orthogonal enzyme-substrate "hits" were identified. These tools produced light when complementary enzyme-substrate partners interacted both in vitro and in cultured cell models. Based on their selectivity, these designer pairs will bolster multicomponent imaging and enable the direct interrogation of cell networks not currently possible with existing tools. Our screening platform is also general and will expedite the identification of more unique luciferases and luciferins, further expanding the bioluminescence toolkit.

Published

2017

18. In Vivo Biosynthesis of a β‑Amino Acid-Containing Protein

Author

Czekster, Clarissa Melo, Robertson, Wesley E, Walker, Allison S, Söll, Dieter, and Schepartz, Alanna

Subjects

Engineering, Chemical Sciences, 2.2 Factors relating to the physical environment, Aetiology, Amino Acyl-tRNA Synthetases, Escherichia coli, Escherichia coli Proteins, Molecular Dynamics Simulation, Mutation, Peptide Elongation Factor Tu, Phenylalanine, Phenylalanine-tRNA Ligase, Protein Engineering, RNA, Ribosomal, 23S, Substrate Specificity, Tetrahydrofolate Dehydrogenase, General Chemistry, Chemical sciences

Abstract

It has recently been reported that ribosomes from erythromycin-resistant Escherichia coli strains, when isolated in S30 extracts and incubated with chemically mis-acylated tRNA, can incorporate certain β-amino acids into full length DHFR in vitro. Here we report that wild-type E. coli EF-Tu and phenylalanyl-tRNA synthetase collaborate with these mutant ribosomes and others to incorporate β(3)-Phe analogs into full length DHFR in vivo. E. coli harboring the most active mutant ribosomes are robust, with a doubling time only 14% longer than wild-type. These results reveal the unexpected tolerance of E. coli and its translation machinery to the β(3)-amino acid backbone and should embolden in vivo selections for orthogonal translational machinery components that incorporate diverse β-amino acids into proteins and peptides. E. coli harboring mutant ribosomes may possess the capacity to incorporate many non-natural, non-α-amino acids into proteins and other sequence-programmed polymeric materials.

Published

2016

19. Discovery, Characterization and Engineering of the Free l-Histidine C4 -Prenyltransferase.

Author

Chen XW, Liu Z, Dai S, and Zou Y

Subjects

Protein Engineering, Models, Molecular, Substrate Specificity, Imidazoles chemistry, Imidazoles metabolism, Histidine chemistry, Histidine metabolism, Dimethylallyltranstransferase metabolism, Dimethylallyltranstransferase chemistry, Dimethylallyltranstransferase genetics

Abstract

Prenylation of amino acids is a critical step for synthesizing building blocks of prenylated alkaloid family natural products, where the corresponding prenyltransferase that catalyzes prenylation on free l-histidine (l-His) has not yet been identified. Here, we first discovered and characterized a prenyltransferase FunA from the antifungal agent fungerin pathway that efficiently performs C4 -dimethylallylation on l-His. Crystal structure-guided engineering of the prenyl-binding pocket of FunA, a single M181A mutation, successfully converted it into a C4 -geranyltransferase. Furthermore, FunA and its variant FunA-M181A show broad substrate promiscuity toward substrates that vary in substituents of the imidazole ring. Our work furthers our knowledge of free amino acid prenyltransferase and expands the arsenal of alkylation biocatalysts for imidazole-containing small molecules.

Published

2024

20. Kinetic Resolution of Epimeric Proteins Enables Stereoselective Chemical Mutagenesis.

Author

Ablat G, Lawton N, Alam R, Haynes BA, Hossain S, Hicks T, Evans SL, Jarvis JA, Nott TJ, Isaacson RL, and Müller MM

Subjects

Stereoisomerism, Kinetics, Alanine chemistry, Alanine analogs & derivatives, Protein Engineering, Histones chemistry, Histones metabolism, Proteins chemistry, Proteins metabolism, Proteins genetics, Mutagenesis

Abstract

Chemical mutagenesis via dehydroalanine (Dha) is a powerful method to tailor protein structure and function, allowing the site-specific installation of post-translational modifications and non-natural functional groups. Despite the impressive versatility of this method, applications have been limited, as products are formed as epimeric mixtures, whereby the modified amino acid is present as both the desired l-configuration and a roughly equal amount of the undesired d-isomer. Here, we describe a simple remedy for this issue: removal of the d-isomer via proteolysis using a d-stereoselective peptidase, alkaline d-peptidase (AD-P). We demonstrate that AD-P can selectively cleave the d-isomer of epimeric residues within histone H3, GFP, Ddx4, and SGTA, allowing the installation of non-natural amino acids with stereochemical control. Given the breadth of modifications that can be introduced via Dha and the simplicity of our method, we believe that stereoselective chemoenzymatic mutagenesis will find broad utility in protein engineering and chemical biology applications.

Published

2024

21. Chemoenzymatic Synthesis of Fluorinated Mycocyclosin Enabled by the Engineered Cytochrome P450-Catalyzed Biaryl Coupling Reaction.

Author

Li SH, Zhang X, Mei ZL, Liu Y, Ma JA, and Zhang FG

Subjects

Biocatalysis, Halogenation, Molecular Structure, Cytochrome P-450 Enzyme System metabolism, Cytochrome P-450 Enzyme System chemistry, Mycobacterium tuberculosis enzymology, Protein Engineering

Abstract

Installing fluorine atoms onto natural products holds great promise for the generation of fluorinated molecules with improved or novel pharmacological properties. The enzymatic oxidative carbon-carbon coupling reaction represents a straightforward strategy for synthesizing biaryl architectures, but the exploration of this method for producing fluorine-substituted derivatives of natural products remains elusive. Here, in this study, we report the protein engineering of cytochrome P450 from Mycobacterium tuberculosis ( Mt CYP121) for the construction of a series of new-to-nature fluorine-substituted Mycocyclosin derivatives. This protocol takes advantage of a "hybrid" chemoenzymatic procedure consisting of tyrosine phenol lyase-catalyzed fluorotyrosine preparation from commercially available fluorophenols, intermolecular chemical condensation to give cyclodityrosines, and an engineered Mt CYP121-catalyzed intramolecular biphenol coupling reaction to complete the strained macrocyclic structure. Computational mechanistic studies reveal that Mt CYP121 employs Cpd I to abstract a hydrogen atom from the proximal phenolic hydroxyl group of the substrate to trigger the reaction. Then, conformational change makes the two phenolic hydroxyl groups close enough to undergo intramolecular hydrogen atom transfer with the assistance of a pocket water molecule. The final diradical coupling process completes the intramolecular C-C bond formation. The efficiency of the biaryl coupling reaction was found to be influenced by various fluorine substitutions, primarily due to the presence of distinct binding conformations.

Published

2024

22. Engineered Methionine Adenosyltransferase Cascades for Metabolic Labeling of Individual DNA Methylomes in Live Cells.

Author

Gasiulė L, Stankevičius V, Kvederavičiu Tė K, Rimšelis JM, Klimkevičius V, Petraitytė G, Rukšėnaitė A, Masevičius V, and Klimašauskas S

Subjects

Animals, Mice, Protein Engineering, Epigenome, S-Adenosylmethionine metabolism, S-Adenosylmethionine chemistry, DNA (Cytosine-5-)-Methyltransferase 1 metabolism, DNA (Cytosine-5-)-Methyltransferase 1 genetics, Humans, Methionine Adenosyltransferase metabolism, Methionine Adenosyltransferase genetics, Methionine Adenosyltransferase chemistry, DNA Methylation

Abstract

Methylation, a widely occurring natural modification serving diverse regulatory and structural functions, is carried out by a myriad of S -adenosyl-l-methionine (AdoMet)-dependent methyltransferases (MTases). The AdoMet cofactor is produced from l-methionine (Met) and ATP by a family of multimeric methionine adenosyltransferases (MAT). To advance mechanistic and functional studies, strategies for repurposing the MAT and MTase reactions to accept extended versions of the transferable group from the corresponding precursors have been exploited. Here, we used structure-guided engineering of mouse MAT2A to enable biocatalytic production of an extended AdoMet analogue, Ado-6-azide, from a synthetic methionine analogue, S -(6-azidohex-2-ynyl)-l-homocysteine (N 3 -Met). Three engineered MAT2A variants showed catalytic proficiency with the extended analogues and supported DNA derivatization in cascade reactions with M. Taq I and an engineered variant of mouse DNMT1 both in the absence and presence of competing Met. We then installed two of the engineered variants as MAT2A-DNMT1 cascades in mouse embryonic stem cells by using CRISPR-Cas genome editing. The resulting cell lines maintained normal viability and DNA methylation levels and showed Dnmt1-dependent DNA modification with extended azide tags upon exposure to N 3 -Met in the presence of physiological levels of Met. This for the first time demonstrates a genetically stable system for biosynthetic production of an extended AdoMet analogue, which enables mild metabolic labeling of a DNMT-specific methylome in live mammalian cells.

Published

2024

23. Engineering Biomimetic Protein Camouflage for Delivering Peptide/siRNA Nanocomplexes.

Author

Wang J and Chen P

Subjects

Humans, Protein Engineering, Apolipoprotein A-I chemistry, Apolipoprotein A-I genetics, Apolipoprotein A-I metabolism, Protein Corona chemistry, Biomimetics methods, RNA, Small Interfering chemistry, Peptides chemistry, Biomimetic Materials chemistry, Nanoparticles chemistry, Serum Albumin, Human chemistry

Abstract

For cationic nanoparticles, the spontaneous nanoparticle-protein corona formation and aggregation in biofluids can trigger unexpected biological reactions. Herein, we present a biomimetic strategy for camouflaging the cationic peptide/siRNA nanocomplex (P/Si) with single or dual proteins, which exploits the unique properties of endogenous proteins and stabilizes the cationic P/Si complex for safe and targeted delivery. An in-depth study of the P/Si protein corona (P/Si-PC) formation and protein binding was conducted. The results provided insights into the biochemical and toxicological properties of cationic nanocomplexes and the rationales for engineering biomimetic protein camouflages. Based on this, the human serum albumin (HSA) and apolipoprotein AI (Apo-AI) ranked within the top 20 abundant protein species of P/Si-PC were selected to construct biomimetic HSA-dressed P/Si (P/Si@HSA) and dual protein (HSA and Apo-AI)-dressed P/Si (P/Si@HSA_Apo), given that the dual-protein camouflage plays complementary roles in efficient delivery. A branched cationic peptide (b-HKR) was tailored for siRNA delivery, and their nanocomplexes, including the cationic P/Si and biomimetic protein-dressed P/Si, were produced by a precise microfluidic technology. The biomimetic anionic protein camouflage greatly enhanced P/Si biostability and biocompatibility, which offers a reliable strategy for overcoming the limitation of applying cationic nanoparticles in biofluids and systemic delivery.

Published

2024

24. Design of a photoswitchable cadherin.

Author

Ritterson, Ryan, Kuchenbecker, Kristopher, Michalik, Michael, and Kortemme, Tanja

Subjects

Cadherins, Calcium, Cell Adhesion, Dimerization, Models, Molecular, Molecular Structure, Photochemical Processes, Protein Engineering

Abstract

There is a growing interest in engineering proteins whose function can be controlled with the spatial and temporal precision of light. Here, we present a novel example of a functional light-triggered switch in the Ca-dependent cell-cell adhesion protein E-cadherin, created using a mechanism-based design strategy. We report an 18-fold change in apparent Ca(2+) binding affinity upon illumination. Our results include a detailed examination of functional switching via linked changes in Ca(2+) binding and cadherin dimerization. This design opens avenues toward controllable tools that could be applied to many long-standing questions about cadherins biological function in cell-cell adhesion and downstream signaling.

Published

2013

25. Direct Identification of Complex Glycans via a Highly Sensitive Engineered Nanopore.

Author

Yao G, Tian Y, Ke W, Fang J, Ma S, Li T, Cheng X, Xia B, Wen L, and Gao Z

Subjects

Hemolysin Proteins chemistry, Protein Engineering, Nanopores, Polysaccharides chemistry, Molecular Dynamics Simulation

Abstract

The crucial roles that glycans play in biological systems are determined by their structures. However, the analysis of glycan structures still has numerous bottlenecks due to their inherent complexities. The nanopore technology has emerged as a powerful sensor for DNA sequencing and peptide detection. This has a significant impact on the development of a related research area. Currently, nanopores are beginning to be applied for the detection of simple glycans, but the analysis of complex glycans by this technology is still challenging. Here, we designed an engineered α-hemolysin nanopore M113R/T115A to achieve the sensing of complex glycans at micromolar concentrations and under label-free conditions. By extracting characteristic features to depict a three-dimensional (3D) scatter plot, glycans with different numbers of functional groups, various chain lengths ranging from disaccharide to decasaccharide, and distinct glycosidic linkages could be distinguished. Molecular dynamics (MD) simulations show different behaviors of glycans with β1,3- or β1,4-glycosidic bonds in nanopores. More importantly, the designed nanopore system permitted the discrimination of each glycan isomer with different lengths in a mixture with a separation ratio of over 0.9. This work represents a proof-of-concept demonstration that complex glycans can be analyzed using nanopore sequencing technology.

Published

2024

26. Bioluminescence Imaging of Potassium Ion Using a Sensory Luciferin and an Engineered Luciferase.

Author

Zhao S, Xiong Y, Sunnapu R, Zhang Y, Tian X, and Ai HW

Subjects

Animals, Mice, Humans, Protein Engineering, Luminescent Agents chemistry, Firefly Luciferin chemistry, Firefly Luciferin metabolism, Potassium metabolism, Potassium chemistry, Luminescent Measurements methods, Luciferases chemistry, Luciferases metabolism

Abstract

Bioluminescent indicators are power tools for studying dynamic biological processes. In this study, we present the generation of novel bioluminescent indicators by modifying the luciferin molecule with an analyte-binding moiety. Specifically, we have successfully developed the first bioluminescent indicator for potassium ions (K + ), which are critical electrolytes in biological systems. Our approach involved the design and synthesis of a K + -binding luciferin named potassiorin. Additionally, we engineered a luciferase enzyme called BRIPO (bioluminescent red indicator for potassium) to work synergistically with potassiorin, resulting in optimized K + -dependent bioluminescence responses. Through extensive validation in cell lines, primary neurons, and live mice, we demonstrated the efficacy of this new tool for detecting K + . Our research demonstrates an innovative concept of incorporating sensory moieties into luciferins to modulate luciferase activity. This approach has great potential for developing a wide range of bioluminescent indicators, advancing bioluminescence imaging (BLI), and enabling the study of various analytes in biological systems.

Published

2024

27. The Influence of Protein Dynamics on the Success of Computational Enzyme Design

Author

Ruscio, Jory Z, Kohn, Jonathan E, Ball, K Aurelia, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Bioengineering, Catalysis, Enzymes, Kinetics, Models, Molecular, Molecular Dynamics Simulation, Protein Conformation, Protein Engineering, Protons, Substrate Specificity, General Chemistry, Chemical sciences, Engineering

Abstract

We characterize the molecular dynamics of a previously described computational de novo designed enzyme optimized to perform a multistep retrol-aldol reaction when engineered into a TIM barrel protein scaffold. The molecular dynamics simulations show that the protein dynamics under physiological conditions of temperature and aqueous environment distorts the designed geometric factors of the substrate-enzyme reaction intermediates, such that catalysis is limited by the primary retrol-aldol step of proton abstraction from the covalently bound substrate and its interactions with a histidine-aspartate dyad. These results emphasize that computational enzyme designs will benefit from considerations of dynamical fluctuations when optimizing active site geometries.

Published

2009

28. Data Science-Driven Analysis of Substrate-Permissive Diketopiperazine Reverse Prenyltransferase NotF: Applications in Protein Engineering and Cascade Biocatalytic Synthesis of (−)-Eurotiumin A

Author

Samantha P. Kelly, Vikram V. Shende, Autumn R. Flynn, Qingyun Dan, Ying Ye, Janet L. Smith, Sachiko Tsukamoto, Matthew S. Sigman, and David H. Sherman

Subjects

Biological Products, Data Science, Diketopiperazines, General Chemistry, Dimethylallyltranstransferase, Protein Engineering, Biochemistry, Article, Carbon, Catalysis, Indole Alkaloids, Mixed Function Oxygenases, Substrate Specificity, Colloid and Surface Chemistry, Flavins, Chemical Sciences, Solvents, Animals

Abstract

Prenyltransfer is an early-stage carbon-hydrogen bond (C-H) functionalization prevalent in the biosynthesis of a diverse array of biologically active bacterial, fungal, plant, and metazoan diketopiperazine (DKP) alkaloids. Toward the development of a unified strategy for biocatalytic construction of prenylated DKP indole alkaloids, we sought to identify and characterize a substrate-permissive C2 reverse prenyltransferase (PT). As the first tailoring event within the biosynthesis of cytotoxic notoamide metabolites, PT NotF catalyzes C2 reverse prenyltransfer of brevianamide F. Solving a crystal structure of NotF (in complex with native substrate and prenyl donor mimic dimethylallyl S-thiolodiphosphate (DMSPP)) revealed a large, solvent-exposed active site, intimating NotF may possess a significantly broad substrate scope. To assess the substrate selectivity of NotF, we synthesized a panel of 30 sterically and electronically differentiated tryptophanyl DKPs, the majority of which were selectively prenylated by NotF in synthetically useful conversions (2 to >99%). Quantitative representation of this substrate library and development of a descriptive statistical model provided insight into the molecular origins of NotF's substrate promiscuity. This approach enabled the identification of key substrate descriptors (electrophilicity, size, and flexibility) that govern the rate of NotF-catalyzed prenyltransfer, and the development of an "induced fit docking (IFD)-guided" engineering strategy for improved turnover of our largest substrates. We further demonstrated the utility of NotF in tandem with oxidative cyclization using flavin monooxygenase, BvnB. This one-pot, in vitro biocatalytic cascade enabled the first chemoenzymatic synthesis of the marine fungal natural product, (-)-eurotiumin A, in three steps and 60% overall yield.

Published

2022

29. Free-Energy-Based Protein Design: Re-Engineering Cellular Retinoic Acid Binding Protein II Assisted by the Moveable-Type Approach.

Author

Zhong, Haizhen A., Santos, Elizabeth M., Vasileiou, Chrysoula, Zheng, Zheng, Geiger, James H., Borhan, Babak, and Merz, Jr., Kenneth M.

Subjects

*TRETINOIN, *FREE energy (Thermodynamics), *MOLECULAR structure of carrier proteins, *PROTEIN engineering, *MOLECULAR energy levels (Quantum mechanics)

Abstract

How to fine-tune the binding free energy of a small-molecule to a receptor site by altering the amino acid residue composition is a key question in protein engineering. Indeed, the ultimate solution to this problem, to chemical accuracy (±1 kcal/mol), will result in profound and wide-ranging applications in protein design. Numerous tools have been developed to address this question using knowledge-based models to more computationally intensive molecular dynamics simulations-based free energy calculations, but while some success has been achieved there remains room for improvement in terms of overall accuracy and in the speed of the methodology. Here we report a fast, knowledge-based movable-type (MT)-based approach to estimate the absolute and relative free energy of binding as influenced by mutations in a small-molecule binding site in a protein. We retrospectively validate our approach using mutagenesis data for retinoic acid binding to the Cellular Retinoic Acid Binding Protein II (CRABPII) system and then make prospective predictions that are borne out experimentally. The overall performance of our approach is supported by its success in identifying mutants that show high or even sub-nanomolar binding affinities of retinoic acid to the CRABPII system. [ABSTRACT FROM AUTHOR]

Published

2018

30. Deciphering the Dynamic Interaction Profile of an Intrinsically Disordered Protein by NMR Exchange Spectroscopy.

Author

Delaforge, Elise, Kragelj, Jaka, Tengo, Laura, Palencia, Andrés, Milles, Sigrid, Bouvignies, Guillaume, Salvi, Nicola, Blackledge, Martin, and Ringkjøbing Jensen, Malene

Subjects

*PROTEIN folding, *PROTEIN crystallography, *PROTEIN engineering, *PROTEIN spectra, *CRYSTAL structure research, *NUCLEAR magnetic resonance spectroscopy, *MITOGEN-activated protein kinases

Abstract

Intrinsically disordered proteins (IDPs) display a large number of interaction modes including folding-upon-binding, binding without major structural transitions, or binding through highly dynamic, so-called fuzzy, complexes. The vast majority of experimental information about IDP binding modes have been inferred from crystal structures of proteins in complex with short peptides of IDPs. However, crystal structures provide a mainly static view of the complexes and do not give information about the conformational dynamics experienced by the IDP in the bound state. Knowledge of the dynamics of IDP complexes is of fundamental importance to understand how IDPs engage in highly specific interactions without concomitantly high binding affinity. Here, we combine rotating-frame R1ρ, Carr-Purcell-Meiboom Gill relaxation dispersion as well as chemical exchange saturation transfer to decipher the dynamic interaction profile of an IDP in complex with its partner. We apply the approach to the dynamic signaling complex formed between the mitogen-activated protein kinase (MAPK) p38α and the intrinsically disordered regulatory domain of the MAPK kinase MKK4. Our study demonstrates that MKK4 employs a subtle combination of interaction modes in order to bind to p38α, leading to a complex displaying significantly different dynamics across the bound regions. [ABSTRACT FROM AUTHOR]

Published

2018

31. Site-Specific One-to-One Click Coupling of Single Proteins to Individual Carbon Nanotubes: A Single-Molecule Approach.

Author

Freeley, Mark, Worthy, Harley L., Ahmed, Rochelle, Bowen, Ben, Watkins, Daniel, Macdonald, J. Emyr, Ming Zheng, Jones, D. Dafydd, and Palma, Matteo

Subjects

*CARBON nanotubes, *GREEN fluorescent protein, *PROTEIN engineering, *SINGLE molecules, *ATOMIC force microscopy, *FLUORIMETRY, *BIOENGINEERING

Abstract

We report the site-specific coupling of single proteins to individual carbon nanotubes (CNTs) in solution and with single-molecule control. Using an orthogonal Click reaction, Green Fluorescent Protein (GFP) was engineered to contain a genetically encoded azide group and then bound to CNT ends in different configurations: in close proximity or at longer distances from the GFP's functional center. Atomic force microscopy and fluorescence analysis in solution and on surfaces at the single-protein level confirmed the importance of bioengineering optimal protein attachment sites to achieve direct protein-nanotube communication and bridging. [ABSTRACT FROM AUTHOR]

Published

2017

32. Controlling Association and Separation of Gold Nanoparticles with Computationally Designed Zinc-Coordinating Proteins.

Author

Eibling, Matthew J., MacDermaid, Christopher M., Qian, Zhaoxia, Lanci, Christopher J., Park, So-Jung, and Saven, Jeffery G.

Subjects

*GOLD nanoparticles, *ZINC proteins, *PROTEIN engineering, *PROTEIN structure, *HOMODIMERS, *CYSTEINE

Abstract

Functionalization of nanoparticles with biopolymers has yielded a wide range of structured and responsive hybrid materials. DNA provides the ability to program length and recognition using complementary oligonucleotide sequences. Nature more often leverages the versatility of proteins, however, where structure, assembly, and recognition are more subtle to engineer. Herein, a protein was computationally designed to present multiple Zn2+ coordination sites and cooperatively self-associate to form an antiparallel helical homodimer. Each subunit was unstructured in the absence of Zn2+ or when the cation was sequestered with a chelating agent. When bound to the surface of gold nanoparticles via cysteine, the protein provided a reversible molecular linkage between particles. Nanoparticle association and changes in interparticle separation were monitored by redshifts in the surface plasmon resonance (SPR) band and by transmission electron microscopy (TEM). Titrations with Zn2+ revealed sigmoidal transitions at submicromolar concentrations. The metal-ion concentration required to trigger association varied with the loading of the proteins on the nanoparticles, the solution ionic strength, and the cation employed. Specifying the number of helical (heptad) repeat units conferred control over protein length and nanoparticle separation. Two different length proteins were designed via extension of the helical structure. TEM and extinction measurements revealed distributions of nanoparticle separations consistent with the expected protein structures. Nanoparticle association, interparticle separation, and SPR properties can be tuned using computationally designed proteins, where protein structure, folding, length, and response to molecular species such as Zn2+ can be engineered. [ABSTRACT FROM AUTHOR]

Published

2017

33. Synthesis of Multi-Protein Complexes through Charge-Directed Sequential Activation of Tyrosine Residues

Author

Marco J. Lobba, Jennifer A. Doudna, Jamie M Gleason, Daniel D. Brauer, Casey S. Mogilevsky, Matthew B. Francis, Johnathan C. Maza, and Alan M. Marmelstein

Subjects

biology, Monophenol Monooxygenase, Chemistry, Tyrosinase, Protein design, Chemical biology, Substrate (chemistry), General Chemistry, Protein engineering, biology.organism_classification, Biochemistry, Article, Catalysis, Colloid and Surface Chemistry, Mutagenesis, Bacillus megaterium, Benzoquinones, Mutagenesis, Site-Directed, Tyrosine, Protein Multimerization, Cysteine

Abstract

Site-selective protein–protein coupling has long been a goal of chemical biology research. In recent years, that goal has been realized to varying degrees through a number of techniques, including the use of tyrosinase-based coupling strategies. Early publications utilizing tyrosinase from Agaricus bisporus(abTYR) showed the potential to convert tyrosine residues into ortho-quinone functional groups, but this enzyme is challenging to produce recombinantly and suffers from some limitations in substrate scope. Initial screens of several tyrosinase candidates revealed that the tyrosinase from Bacillus megaterium (megaTYR) is an enzyme that possesses a broad substrate tolerance. We use the expanded substrate preference as a starting point for protein design experiments and show that single point mutants of megaTYR are capable of activating tyrosine residues in various sequence contexts. We leverage this new tool to enable the construction of protein trimers via a charge-directed sequential activation of tyrosine residues (CDSAT).

Published

2021

34. Catalytic Space Engineering as a Strategy to Activate C–H Oxidation on 5-Methylcytosine in Mammalian Genome

Author

Kabirul Islam, Babu Sudhamalla, Debasis Dey, and Sushma Sappa

Subjects

Chromosomal translocation, Biochemistry, Article, Catalysis, Dioxygenases, Enzyme catalysis, law.invention, chemistry.chemical_compound, Colloid and Surface Chemistry, law, Animals, Humans, Gene, chemistry.chemical_classification, biology, Chemistry, Active site, General Chemistry, Protein engineering, Cell biology, 5-Methylcytosine, Enzyme, Mutation, Biocatalysis, biology.protein, Suppressor, Genetic Engineering, Oxidation-Reduction

Abstract

Conditional remodeling of enzyme catalysis is a formidable challenge in protein engineering. Herein, we have undertaken a unique active site engineering tactic to command catalytic outcome. With ten-eleven translocation (TET) enzyme as a paradigm, we show that variants with an expanded active site significantly enhance multi-step C-H oxidation in 5-methylcytosine (5mC) whereas a crowded cavity leads to a single-step catalytic apparatus. We further identify an evolutionarily conserved residue in the TET family with a remarkable catalysis-directing ability. The activating variant demonstrated its prowess to oxidize 5mC in chromosomal DNA for potentiating expression of genes including tumor suppressors silenced in human neoplasia.

Published

2021

35. A Genetically Encoded Fluorosulfonyloxybenzoyl-<scp>l</scp>-lysine for Expansive Covalent Bonding of Proteins via SuFEx Chemistry

Author

Rujin Cheng, Paul C. Klauser, Bingchen Yu, Nanxi Wang, Farid Ghelichkhani, Wei Sun, Jun Liu, Lei Wang, Li Cao, Sharon Rozovsky, and Viktoriya Y. Berdan

Subjects

Models, Molecular, Protein Conformation, 1.1 Normal biological development and functioning, Green Fluorescent Proteins, Lysine, Protein Engineering, Biochemistry, Article, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Bacterial Proteins, Models, Underpinning research, Epidermal growth factor, Escherichia coli, Side chain, Animals, Humans, chemistry.chemical_classification, Chemistry, Aryl, Proteins, Molecular, General Chemistry, Protein engineering, In vitro, Amino acid, ErbB Receptors, Cross-Linking Reagents, Covalent bond, Chemical Sciences, Generic health relevance, Protein Binding

Abstract

Genetically introducing novel chemical bonds into proteins provides innovative avenues for biochemical research, protein engineering, and biotherapeutic applications. Recently, latent bioreactive unnatural amino acids (Uaas) have been incorporated into proteins to covalently target natural residues through proximity-enabled reactivity. Aryl fluorosulfate is particularly attractive due to its exceptional biocompatibility and multitargeting capability via sulfur(VI) fluoride exchange (SuFEx) reaction. Thus far, fluorosulfate-l-tyrosine (FSY) is the only aryl fluorosulfate-containing Uaa that has been genetically encoded. FSY has a relatively rigid and short side chain, which restricts the diversity of proteins targetable and the scope of applications. Here we designed and genetically encoded a new latent bioreactive Uaa, fluorosulfonyloxybenzoyl-l-lysine (FSK), in E. coli and mammalian cells. Due to its long and flexible aryl fluorosulfate-containing side chain, FSK was particularly useful in covalently linking protein sites that are unreachable with FSY, both intra- and intermolecularly, in vitro and in live cells. In addition, we created covalent nanobodies that irreversibly bound to epidermal growth factor receptors (EGFR) on cells, with FSK and FSY targeting distinct positions on EGFR to counter potential mutational resistance. Moreover, we established the use of FSK and FSY for genetically encoded chemical cross-linking to capture elusive enzyme-substrate interactions in live cells, allowing us to target residues aside from Cys and to cross-link at the binding periphery. FSK complements FSY to expand target diversity and versatility. Together, they provide a powerful, genetically encoded, latent bioreactive SuFEx system for creating covalent bonds in diverse proteins in vitro and in vivo, which will be widely useful for biological research and applications.

Published

2021

36. Targeted Protein Degradation through Fast Optogenetic Activation and Its Application to the Control of Cell Signaling

Author

Jihe Liu, Amy Ryan, and Alexander Deiters

Subjects

Cell signaling, Protein Conformation, Green Fluorescent Proteins, MAP Kinase Kinase 1, DUSP6, Protein degradation, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Colloid and Surface Chemistry, Dual Specificity Phosphatase 6, Luciferases, Firefly, Animals, Humans, Luciferase, biology, Chemistry, Fireflies, General Chemistry, Protein engineering, 0104 chemical sciences, Cell biology, Ubiquitin ligase, biology.protein, Target protein, Degron, Peptides

Abstract

Development of methodologies for optically triggered protein degradation enables the study of dynamic protein functions, such as those involved in cell signaling, that are difficult to be probed with traditional genetic techniques. Here, we describe the design and implementation of a novel light-controlled peptide degron conferring N-end pathway degradation to its protein target. The degron comprises a photocaged N-terminal amino acid and a lysine-rich, 13-residue linker. By caging the N-terminal residue, we were able to optically control N-degron recognition by an E3 ligase, consequently controlling ubiquitination and proteasomal degradation of the target protein. We demonstrate broad applicability by applying this approach to a diverse set of target proteins, including EGFP, firefly luciferase, the kinase MEK1, and the phosphatase DUSP6 (also known as MKP3). The caged degron can be used with minimal protein engineering and provides virtually complete, light-triggered protein degradation on a second to minute time scale.

Published

2021

37. Ground-State Electron Transfer as an Initiation Mechanism for Biocatalytic C–C Bond Forming Reactions

Author

Braddock A. Sandoval, Heather Lam, Haigen Fu, Megan A. Emmanuel, Todd K. Hyster, and Ji Hye Kim

Subjects

Reaction mechanism, Alkylation, Dinitrocresols, Stereochemistry, Electrons, Cyclopentanes, Flavin group, Alkenes, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Cofactor, Electron transfer, Colloid and Surface Chemistry, Bacterial Proteins, Saturated mutagenesis, Ene reaction, Zymomonas, biology, Hydrocarbons, Halogenated, Chemistry, Active site, Stereoisomerism, General Chemistry, Ketones, 0104 chemical sciences, Cyclization, Biocatalysis, Mutation, biology.protein, Directed Molecular Evolution, Oxidoreductases

Abstract

The development of non-natural reaction mechanisms is an attractive strategy for expanding the synthetic capabilities of substrate promiscuous enzymes. Here, we report an "ene"-reductase catalyzed asymmetric hydroalkylation of olefins using α-bromoketones as radical precursors. Radical initiation occurs via ground-state electron transfer from the flavin cofactor located within the enzyme active site, an underrepresented mechanism in flavin biocatalysis. Four rounds of site saturation mutagenesis were used to access a variant of the "ene"-reductase nicotinamide-dependent cyclohexanone reductase (NCR) from Zymomonas mobiles capable of catalyzing a cyclization to furnish β-chiral cyclopentanones with high levels of enantioselectivity. Additionally, wild-type NCR can catalyze intermolecular couplings with precise stereochemical control over the radical termination step. This report highlights the utility for ground-state electron transfers to enable non-natural biocatalytic C-C bond forming reactions.

Published

2021

38. Regulation of Proteins to the Cytosol Using Delivery Systems with Engineered Polymer Architecture

Author

Taewon Jeon, Vincent M. Rotello, Yi-Wei Lee, Cameron W. Evans, Marck Norret, William Jerome, Sanjana Gopalakrishnan, K. Swaminathan Iyer, Jessica A. Kretzmann, and David C. Luther

Subjects

Polymers, Endosome, Cell, Polymer architecture, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Cell Line, Mice, Cytosol, Colloid and Surface Chemistry, Organelle, medicine, Animals, Humans, Protein activity, chemistry.chemical_classification, Molecular Structure, Chemistry, Proteins, General Chemistry, Polymer, 0104 chemical sciences, medicine.anatomical_structure, Biophysics, Nucleus

Abstract

Intracellular protein delivery enables selective regulation of cellular metabolism, signaling, and development through introduction of defined protein quantities into the cell. Most applications require that the delivered protein has access to the cytosol, either for protein activity or as a gateway to other organelles such as the nucleus. The vast majority of delivery vehicles employ an endosomal pathway however, and efficient release of entrapped protein cargo from the endosome remains a challenge. Recent research has made significant advances toward efficient cytosolic delivery of proteins using polymers, but the influence of polymer architecture on protein delivery is yet to be investigated. Here, we developed a family of dendronized polymers that enable systematic alterations of charge density and structure. We demonstrate that while modulation of surface functionality has a significant effect on overall delivery efficiency, the endosomal release rate can be highly regulated by manipulating polymer architecture. Notably, we show that large, multivalent structures cause slower sustained release, while rigid spherical structures result in rapid burst release.

Published

2021

39. Acyl Transfer Catalytic Activity in De Novo Designed Protein with N-Terminus of α-Helix As Oxyanion-Binding Site

Author

Catherine Birck, Pierre Poussin-Courmontagne, Elise A. Naudin, Sophia K. Tan, Jean-Louis Schmitt, William F. DeGrado, Alastair G. McEwen, Vladimir Yu. Torbeev, Institut de Science et d'ingénierie supramoléculaires (ISIS), Réseau nanophotonique et optique, Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA), Institut de Génétique et de Biologie Moléculaire et Cellulaire (IGBMC), Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Department of Pharmaceutical Chemistry, University of California [San Francisco] (UCSF), University of California-University of California, Centre for Integrative Biology - CBI (Inserm U964 - CNRS UMR7104 - IGBMC), Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), univOAK, Archive ouverte, Université de Strasbourg (UNISTRA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Matériaux et Nanosciences Grand-Est (MNGE), Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Réseau nanophotonique et optique, Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS), University of California [San Francisco] (UC San Francisco), and University of California (UC)-University of California (UC)

Subjects

Protein Conformation, alpha-Helical, Stereochemistry, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Substrate Specificity, chemistry.chemical_compound, Residue (chemistry), Colloid and Surface Chemistry, Catalytic Domain, [SDV.BBM] Life Sciences [q-bio]/Biochemistry, Molecular Biology, Peptide bond, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Amino Acid Sequence, Cysteine, Peptide Synthases, Binding site, Structural motif, chemistry.chemical_classification, DNA ligase, Hydrolysis, [CHIM.CATA] Chemical Sciences/Catalysis, [CHIM.CATA]Chemical Sciences/Catalysis, General Chemistry, 0104 chemical sciences, Kinetics, chemistry, Biocatalysis, Oxyanion hole, Peptides, Acyltransferases, Acyl group

Abstract

The design of catalytic proteins with functional sites capable of specific chemistry is gaining momentum and a number of artificial enzymes have recently been reported, including hydrolases, oxidoreductases, retro-aldolases, and others. Our goal is to develop a peptide ligase for robust catalysis of amide bond formation that possesses no stringent restrictions to the amino acid composition at the ligation junction. We report here the successful completion of the first step in this long-term project by building a completely de novo protein with predefined acyl transfer catalytic activity. We applied a minimalist approach to rationally design an oxyanion hole within a small cavity that contains an adjacent thiol nucleophile. The N-terminus of the α-helix with unpaired hydrogen-bond donors was exploited as a structural motif to stabilize negatively charged tetrahedral intermediates in nucleophilic addition–elimination reactions at the acyl group. Cysteine acting as a principal catalytic residue was introduced at the second residue position of the α-helix N-terminus in a designed three-α-helix protein based on structural informatics prediction. We showed that this minimal set of functional elements is sufficient for the emergence of catalytic activity in a de novo protein. Using peptide-(α)thioesters as acyl-donors, we demonstrated their catalyzed amidation concomitant with hydrolysis and proved that the environment at the catalytic site critically influences the reaction outcome. These results represent a promising starting point for the development of efficient catalysts for protein labeling, conjugation, and peptide ligation.

Published

2021

40. Ground-State Destabilization by Active-Site Hydrophobicity Controls the Selectivity of a Cofactor-Free Decarboxylase

Author

Michal Biler, Shina Caroline Lynn Kamerlin, Anna Katharina Schweiger, Rory M. Crean, and Robert Kourist

Subjects

Bordetella, Carboxy-Lyases, Stereochemistry, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Turn (biochemistry), chemistry.chemical_compound, Colloid and Surface Chemistry, Bacterial Proteins, Catalytic Domain, Carboxylate, chemistry.chemical_classification, Binding Sites, biology, Biochemistry and Molecular Biology, Metadynamics, Active site, Substrate (chemistry), General Chemistry, Protein engineering, Carbon Dioxide, Arylmalonate decarboxylase, 0104 chemical sciences, Amino acid, chemistry, Biocatalysis, Mutagenesis, Site-Directed, biology.protein, Quantum Theory, Thermodynamics, Hydrophobic and Hydrophilic Interactions, Biokemi och molekylärbiologi

Abstract

Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity, and selectivity of this enzyme are only poorly understood to date, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond and metadynamics simulations were performed on wild-type AMDase and variants thereof to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the nonconverted or poorly converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Finally, our results indicate a switch from preferential cleavage of the pro-(R) to the pro-(S) carboxylate group in the CLG-IPL variant of AMDase for all substrates studied. This appears to be due to the emergence of a new hydrophobic pocket generated by the insertion of the six amino acid substitutions, into which the pro-(S) carboxylate binds. Our results allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering.

Published

2020

41. Transmembrane Epitope Delivery by Passive Protein Threading through the Pores of the OmpF Porin Trimer

Author

Renata Kaminska, Nicholas G. Housden, Matthew Zimmer, Hagan Bayley, Sandra A Ionescu, Colin Kleanthous, and Sejeong Lee

Subjects

Chemistry, Protein subunit, Porins, General Chemistry, Protein engineering, Periplasmic space, biochemical phenomena, metabolism, and nutrition, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Transmembrane protein, 0104 chemical sciences, Epitopes, Colloid and Surface Chemistry, Porin, Biophysics, bacteria, Threading (protein sequence), Lipid bilayer, Bacterial outer membrane

Abstract

Trimeric porins in the outer membrane (OM) of Gram-negative bacteria are the conduits by which nutrients and antibiotics diffuse passively into cells. The narrow gateways that porins form in the OM are also exploited by bacteriocins to translocate into cells by a poorly understood process. Here, using single-channel electrical recording in planar lipid bilayers in conjunction with protein engineering, we explicate the mechanism by which the intrinsically unstructured N-terminal translocation domain (IUTD) of the endonuclease bacteriocin ColE9 is imported passively across the Escherichia coli OM through OmpF. We show that the import is dominated by weak interactions of OmpF pores with binding epitopes within the IUTD that are orientationally biased and result in the threading of over 60 amino acids through 2 subunits of OmpF. Single-molecule kinetic analysis demonstrates that the IUTD enters from the extracellular side of OmpF and translocates to the periplasm where the polypeptide chain does an about turn in order to enter a neighboring subunit, only for some of these molecules to pop out of this second subunit before finally re-entering to form a stable complex. These intimately linked transport/binding processes generate an essentially irreversible, hook-like assembly that constrains an import activating peptide epitope between two subunits of the OmpF trimer.

Published

2020

42. Harnessing Conformational Plasticity to Generate Designer Enzymes

Author

Shina Caroline Lynn Kamerlin, Rory M. Crean, and Jasmine M. Gardner

Subjects

Flexibility (engineering), Enzyme function, Chemistry, Protein Conformation, Biochemistry and Molecular Biology, General Chemistry, Protein engineering, Molecular Dynamics Simulation, 010402 general chemistry, Protein Engineering, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Enzymes, Evolvability, Engineering studies, Colloid and Surface Chemistry, Perspective, Biocatalysis, Computational design, Humans, Biochemical engineering, Engineering design process, Biokemi och molekylärbiologi

Abstract

Recent years have witnessed an explosion of interest in understanding the role of conformational dynamics both in the evolution of new enzymatic activities from existing enzymes and in facilitating the emergence of enzymatic activity de novo on scaffolds that were previously non-catalytic. There are also an increasing number of examples in the literature of targeted engineering of conformational dynamics being successfully used to alter enzyme selectivity and activity. Despite the obvious importance of conformational dynamics to both enzyme function and evolvability, many (although not all) computational design approaches still focus either on pure sequence-based approaches or on using structures with limited flexibility to guide the design. However, there exist a wide variety of computational approaches that can be (re)purposed to introduce conformational dynamics as a key consideration in the design process. Coupled with laboratory evolution and more conventional existing sequence- and structure-based approaches, these techniques provide powerful tools for greatly expanding the protein engineering toolkit. This Perspective provides an overview of evolutionary studies that have dissected the role of conformational dynamics in facilitating the emergence of novel enzymes, as well as advances in computational approaches that allow one to target conformational dynamics as part of enzyme design. Harnessing conformational dynamics in engineering studies is a powerful paradigm with which to engineer the next generation of designer biocatalysts.

Published

2020

43. Chemoinformatic-Guided Engineering of Polyketide Synthases

Author

Aindrila Mukhopadhyay, Yuzhong Liu, Ravi Lal, Rasha Anayah, Pablo Cruz-Morales, Amin Zargar, Mitchell G. Thompson, Jay D. Keasling, Carolina Barcelos, Arthur Loubat, Jessica Wang, Christopher J. Petzold, Andrew R. Wong, Veronica T. Benites, Jesus F. Barajas, Yan Chen, Miranda Werts, Luis E. Valencia, Samantha Chang, Edward E. K. Baidoo, Amanda C. Hernández, Ankita Kothari, Tyler W. H. Backman, Constance B. Bailey, Leonard Katz, and Hector Garcia Martin

Subjects

Stereochemistry, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, 03 medical and health sciences, Polyketide, Colloid and Surface Chemistry, Polyketide synthase, Streptomyces albus, 030304 developmental biology, 0303 health sciences, Molecular Structure, biology, 010405 organic chemistry, Chemistry, Drug discovery, Computational Biology, Substrate (chemistry), Chemical similarity, General Chemistry, biology.organism_classification, 0104 chemical sciences, Cheminformatics, Chemical Sciences, biology.protein, Polyketide Synthases

Abstract

Polyketide synthase (PKS) engineering is an attractive method to generate new molecules such as commodity, fine and specialty chemicals. A significant challenge in PKS design is engineering a partially reductive module to produce a saturated β-carbon through a reductive loop exchange. In this work, we sought to establish that chemoinformatics, a field traditionally used in drug discovery, could provide a viable strategy to reductive loop exchanges. We first introduced a set of donor reductive loops of diverse genetic origin and chemical substrate structures into the first extension module of the lipomycin PKS (LipPKS1). Product titers of these engineered unimodular PKSs correlated with atom pair chemical similarity between the substrate of the donor reductive loops and recipient LipPKS1, reaching a titer of 165 mg/L of short chain fatty acids produced by Streptomyces albus J1074 harboring these engineered PKSs. Expanding this method to larger intermediates requiring bimodular communication, we introduced reductive loops of divergent chemosimilarity into LipPKS2 and determined triketide lactone production. Collectively, we observed a statistically significant correlation between atom pair chemosimilarity and production, establishing a new chemoinformatic method that may aid in the engineering of PKSs to produce desired, unnatural products.

Published

2020

44. Exploring the Post-translational Enzymology of PaaA by mRNA Display

Author

Albert A. Bowers, Steven R Fleming, Yuki Goto, Paul M. Himes, Swapnil V. Ghodge, and Hiroaki Suga

Subjects

Substrate recognition, Peptide, Protein Engineering, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Substrate Specificity, Colloid and Surface Chemistry, Bacterial Proteins, Point Mutation, mRNA display, Carbon-Nitrogen Ligases, Amino Acid Sequence, RNA, Messenger, Enzyme Assays, chemistry.chemical_classification, Pantoea, Substrate (chemistry), General Chemistry, Glutamic acid, 0104 chemical sciences, Enzyme, Post translational, chemistry, Protein Binding

Abstract

PaaA is a RiPP enzyme that catalyzes the transformation of two glutamic acid residues within a substrate peptide into the bicyclic core of Pantocin A. Here, for the first time, we use mRNA display techniques to understand RiPP enzyme-substrate interactions to illuminate PaaA substrate recognition. Additionally, our data revealed insights into the enzymatic timing of glutamic acid modification. The technique developed is quite sensitive and a significant advancement over current RiPP studies and opens the door to enzyme modified mRNA display libraries for natural product-like inhibitor pans.

Published

2020

45. Photoenzymatic Synthesis of α-Tertiary Amines by Engineered Flavin-Dependent 'Ene'-Reductases

Author

Xin Gao, Young Joo Choi, Joshua R Turek-Herman, Ryan D. Cohen, and Todd K. Hyster

Subjects

Flavin group, Protein Engineering, Biochemistry, Catalysis, Cofactor, Article, chemistry.chemical_compound, Colloid and Surface Chemistry, Flavins, Oximes, Amines, Ene reaction, biology, Molecular Structure, Chemistry, Enantioselective synthesis, Stereoisomerism, General Chemistry, Oxime, Combinatorial chemistry, Mutation, biology.protein, Biocatalysis, Stereoselectivity, Organic synthesis, Oxidoreductases, hormones, hormone substitutes, and hormone antagonists

Abstract

α-Tertiary amines are a common motif in pharmaceutically important molecules but are challenging to prepare using asymmetric catalysis. Here, we demonstrate engineered flavin-dependent 'ene'-reductases (EREDs) can catalyze radical additions into oximes to prepare this motif. Two different EREDs were evolved into competent catalysts for this transformation with high levels of stereoselectivity. Mechanistic studies indicate that the oxime contributes to the enzyme templated charge-transfer complex formed between the substrate and cofactor. These products can be further derivatized to prepare a variety of motifs, highlighting the versatility of ERED photoenzymatic catalysis for organic synthesis.

Published

2021

46. Enzymatic C-Terminal Protein Engineering with Amines

Author

Tristan J. Tyler, Thomas Durek, David J. Craik, Simon J. de Veer, Kuok Yap, and Fabian B. H. Rehm

Subjects

chemistry.chemical_classification, Models, Molecular, 0303 health sciences, Peptide modification, Terminal protein, Substrate (chemistry), Peptide, General Chemistry, 010402 general chemistry, Protein Engineering, 01 natural sciences, Biochemistry, Combinatorial chemistry, Catalysis, 0104 chemical sciences, 03 medical and health sciences, Colloid and Surface Chemistry, Enzyme, chemistry, Homogeneous, Peptidyl Transferases, Asparagine, Amines, 030304 developmental biology, Conjugate

Abstract

Chemoenzymatic protein and peptide modification is a powerful means of generating defined, homogeneous conjugates for a range of applications. However, the use of transpeptidases is limited by the need to prepare synthetic peptide conjugates to be ligated, bulky recognition tags remaining in the product, and inefficient substrate turnover. Here, we report a peptide/protein labeling strategy that utilizes a promiscuous, engineered transpeptidase to irreversibly incorporate diverse, commercially available amines at a C-terminal asparagine. To demonstrate the utility of this approach, we prepare a protein-drug conjugate, generate a genetically inaccessible C-to-C protein fusion, and site specifically label both termini of a single protein in sequential steps.

Published

2021

47. Rational Redesign of Enzyme via the Combination of Quantum Mechanics/Molecular Mechanics, Molecular Dynamics, and Structural Biology Study

Author

Ying Ye, Hong-Yan Lin, Chang-Guo Zhan, Guang-Fu Yang, Jin Dong, Lin-Hui Li, Jing-Fang Yang, Wen-Chao Yang, Xi Chen, and Han Xiao

Subjects

Arabidopsis, Molecular Dynamics Simulation, Crystallography, X-Ray, Biochemistry, Molecular mechanics, 4-Hydroxyphenylpyruvate Dioxygenase, Catalysis, Molecular dynamics, Structure-Activity Relationship, Colloid and Surface Chemistry, Dioxygenase, Quantum mechanics, Homogentisate 1,2-dioxygenase, Mechanical Phenomena, chemistry.chemical_classification, Molecular Structure, General Chemistry, Protein engineering, Molecular Docking Simulation, Kinetics, Enzyme, chemistry, Structural biology, Mutation, Thermodynamics, Mutant Proteins

Abstract

Increasing demands for efficient and versatile chemical reactions have prompted innovations in enzyme engineering. A major challenge in engineering α-ketoglutarate-dependent oxygenases is to develop a rational strategy which can be widely used for directly evolving the desired mutant to generate new products. Herein, we report a strategy for rational redesign of a model enzyme, 4-hydroxyphenylpyruvate dioxygenase (HPPD), based on quantum mechanics/molecular mechanics (QM/MM) calculation and molecular dynamic simulations. This strategy enriched our understanding of the HPPD catalytic reaction pathway and led to the discovery of a series of HPPD mutants producing hydroxyphenylacetate (HPA) as the alternative product other than the native product homogentisate. The predicted HPPD-Fe(IV)═O-HPA intermediate was further confirmed by the crystal structure of Arabidopsis thaliana HPPD/S267W complexed with HPA. These findings not only provide a good understanding of the structure-function relationship of HPPD but also demonstrate a generally applicable platform for the development of biocatalysts.

Published

2021

48. Design, Synthesis, and Dynamics of a Green Fluorescent Protein Fluorophore Mimic with an Ultrafast Switching Function.

Author

Paolino, Marco, Gueye, Moussa, Pieri, Elisa, Manathunga, Madushanka, Fusi, Stefania, Cappelli, Andrea, Latterini, Loredana, Pannacc, Danilo, Filatov, Michael, Léonard, Jérémie, and Olivucci, Massimo

Subjects

*GREEN fluorescent protein, *PROTEIN engineering, *PROTEIN synthesis, *MOLECULAR switches, *PICOSECOND pulses

Abstract

While rotary molecular switches based on neutral and cationic organic -systems have been reported, structurally homologous anionic switches providing complementary properties have not been prepared so far. Flere we report the design and preparation of a molecular switch mimicking the anionic p-HBDI chromophore of the green fluorescent protein. The investigation of the mechanism and dynamics of the E/Z switching function is carried out both computationally and experimentally. The data consistently support axial rotary motion occurring on a sub-picosecond time scale. Transient spectroscopy and trajectory simulations show that the nonadiabatic decay process occurs in the vicinity of a conical intersection (CInt) between a charge transfer state and a covalent/diradical state. Comparison of our anionic p-HBDI-like switch with the previously reported cationic N-alkyl indanylidene pyrrolinium switch mimicking visual pigments reveals that these similar systems translocate, upon vertical excitation, a similar net charge in the same axial direction. [ABSTRACT FROM AUTHOR]

Published

2016

49. Butelase 1: A Versatile Ligase for Peptide and Protein Macrocyclization.

Author

Nguyen, Giang K. T., Kam, Antony, Shining Loo, Jansson, Anna E., Pan, Lucy X., and Tam, James P.

Subjects

*MACROCYCLIC compound synthesis, *PROTEIN engineering, *LIGASES, *RING formation (Chemistry), *DRUG design

Abstract

Macrocyclization is a valuable tool for drug design and protein engineering. Although various methods have been developed to prepare macrocycles, a general and efficient strategy is needed. Here we report a highly efficient method using butelase 1 to macrocyclize peptides and proteins ranging in sizes from 26 to >200 residues. We achieved cyclizations that are 20,000 times faster than sortase A, the most widely used ligase for protein cyclization. The reactions completed within minutes with up to 95% yields. [ABSTRACT FROM AUTHOR]

Published

2015

50. Engineering Bioactive Dimeric Transcription Factor Analogs via Palladium Rebound Reagents

Author

Susana Wilson Hawken, Stephen L. Buchwald, Sebastian Pomplun, Ann Boija, Bradley L. Pentelute, Carly K. Schissel, Isaac A. Klein, Muhammad Jbara, and Jacob Rodriguez

Subjects

Models, Molecular, Dimer, 010402 general chemistry, Protein Engineering, 01 natural sciences, Biochemistry, Catalysis, Proto-Oncogene Proteins c-myc, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Transcription (biology), Humans, Transcription factor, 030304 developmental biology, Cell Proliferation, 0303 health sciences, RNA, General Chemistry, DNA, Protein tertiary structure, 0104 chemical sciences, chemistry, Covalent bond, Indicators and Reagents, Small molecule binding, Protein Multimerization, Palladium, HeLa Cells

Abstract

Transcription factors (TF), such as Myc, are proteins implicated in disease pathogenesis, with dysregulation of Myc expression in 50% of all human cancers. Still, targeting Myc remains a challenge due to the lack of small molecule binding pockets in the tertiary structure. Here, we report synthetic covalently linked TF mimetics that inhibit oncogenic Myc-driven transcription by antagonistic binding of the target DNA-binding site. We combined automated flow peptide chemistry with palladium(II) oxidative addition complexes (OACs) to engineer covalent protein dimers derived from the DNA-binding domains of Myc, Max, and Omomyc TF analogs. Palladium-mediated cross-coupling of synthesized protein monomers resulted in milligram quantities of seven different covalent homo- and heterodimers. The covalent helical dimers were found to bind DNA and exhibited improved thermal stability. Cell-based studies revealed the Max-Max covalent dimer is cell-penetrating and interfered with Myc-dependent gene transcription resulting in reduced cancer cell proliferation (EC50 of 6 μM in HeLa). RNA sequencing and gene analysis of extracted RNA from treated cancer cells confirmed that the covalent Max-Max homodimer interferes with Myc-dependent transcription. Flow chemistry, combined with palladium(II) OACs, has enabled a practical strategy to generate new bioactive compounds to inhibit tumor cell proliferation.

Published

2021