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101. Selection of linkers for a catalytic single-chain antibody using phage display technology.

Author

Tang, Y, Jiang, N, Parakh, C, and Hilvert, D

Abstract

Phage display has been evaluated as a means of rapidly selecting tailored linkers for single-chain antibodies (scFvs) from protein linker libraries. Preliminary experiments with a conventional linker failed to yield a functional single-chain version of a catalytic antibody with chorismate mutase activity. A random linker library was therefore constructed in which the genes for the heavy and light chain variable domains were linked by a segment encoding an 18-amino acid polypeptide of variable composition. The scFv repertoire ( approximately 5 x 10(6) different members) was displayed on filamentous phage and subjected to affinity selection with hapten. The population of selected variants exhibited significant increases in binding activity but retained considerable sequence diversity. Screening 1054 individual variants subsequently yielded a catalytically active scFv that was produced efficiently in soluble form. Sequence analysis revealed a conserved proline in the linker two residues after the VH C terminus and an abundance of arginines and prolines at other positions as the only common features of the selected tethers. There are apparently many viable solutions to the problem of linking individual VH and VL domains, but subtle differences in sequence dramatically influence the production, stability, and recognition properties of the scFv. The success of these experiments suggests that phage display will be generally useful for identifying peptide sequences for covalently linking any two protein domains.

Published
1996

102. Evidence for the general base mechanism in carboxypeptidase A-catalyzed reactions: partitioning studies on nucleophiles and H2(18)O kinetic isotope effects.

Author

Breslow, R, Chin, J, Hilvert, D, and Trainor, G

Abstract

Methanol does not detectably compete with water in carboxypeptidase-catalyzed cleavage of any substrate, although it is preferentially reactive in a model for the proposed nucleophilic mechanism for the enzyme that involves an anhydride intermediate. To test for such a common intermediate in the cleavage of related peptide and ester substrates, a method has been developed to examine H2(16)O-H2(18)O kinetic isotope-partitioning effects. The finding that benzoylglycylphenylalanine has an isotope effect of 1.019 +/- 0.002 while benzoylglycyl-beta-L-phenyl-lactate shows a small inverse isotope effect excludes most versions of a nucleophilic mechanism having a common anhydride intermediate. The bulk of the available evidence strongly favors the previously proposed general base mechanism.

Published
1983
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103. Use of directed mutagenesis to probe the role of tyrosine 198 in the catalytic mechanism of carboxypeptidase A.

Author

Gardell, S J, Hilvert, D, Barnett, J, Kaiser, E T, and Rutter, W J

Abstract

Derivatization of Tyr198 in carboxypeptidase A (CPA) results in lowered catalytic activity toward peptide substrates (Cueni, L., and Riordan, J.F. (1978) Biochemistry 17, 1834-1842). We have synthesized via directed mutagenesis a rat CPA variant [Phe198] CPA containing a Tyr198-to-Phe substitution in order to test whether the phenolic hydroxyl plays a critical role in catalysis. A double mutant [Phe193, Phe248]CPA in which both Tyr198 and Tyr248 have been replaced by phenylalanine has also been engineered. Enzymatic characterization of [Phe198]CPA indicates that the Tyr198 hydroxyl is not obligatory for the hydrolysis of peptide and ester substrates. Furthermore, parallel studies with [Phe198, Phe248]CPA show that simultaneous removal of both the Tyr198 and Tyr248 hydroxyls does not abolish catalytic activity. Analysis of the acetylated derivatives of [Phe198]CPA, [Phe248]CPA, and [Phe198, Phe248]CPA establishes that Tyr198 and Tyr248 are the active site tyrosines which are modified by N-acetylimidazole. In addition, the perturbations of enzymatic activity which accompany acetylation of native CPA can be largely assigned to derivatization of Tyr248. The changes in the kinetic constants of substrate hydrolysis due to the Tyr198-to-Phe substitution are manifested as small decreases in the kcat values, but the Km values are essentially unaffected. This exclusive effect on the kcat values suggests that the Tyr198 hydroxyl participates in catalysis by stabilizing the rate-determining transition-state complex.

Published
1987
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104. Thermodynamics of the Conversion of Chorismate to Prephenate:  Experimental Results and Theoretical Predictions

Author

Kast, P., Tewari, Y. B., Wiest, O., Hilvert, D., Houk, K. N., and Goldberg, R. N.

Abstract

A thermodynamic investigation of the Claisen rearrangement of chorismate2-(aq) to prephenate2-(aq) has been performed using microcalorimetry and high-performance liquid chromatography. The study used a well-characterized monofunctional chorismate mutase from Bacillus subtilis that was devoid of prephenate dehydrogenase and prephenate dehydratase activities. The calorimetric measurements led to a standard molar enthalpy change %@mt;sys@%Δ%@sb@%r%@sbx@%%@ital@%H%@rsf@%%@/xs;55;%lnwidth@%°%@/xs;63;(%lnwidth-x55)@%%@mh;-x63@%%@sb@%m%@sbx@%%@mx@% = −(55.4 ± 2.3) kJ mol-1 at 298.15 K for this reaction. An estimated value of the standard molar entropy change %@mt;sys@%Δ%@sb@%r%@sbx@%%@ital@%S%@rsf@%%@/xs;55;%lnwidth@%°%@/xs;63;(%lnwidth-x55)@%%@mh;-x63@%%@sb@%m%@sbx@%%@mx@% = 3 J K-1 mol-1 for the above reaction was used together with the experimental value of %@mt;sys@%Δ%@sb@%r%@sbx@%%@ital@%H%@rsf@%%@/xs;55;%lnwidth@%°%@/xs;63;(%lnwidth-x55)@%%@mh;-x63@%%@sb@%m%@sbx@%%@mx@% to obtain a standard molar Gibbs free energy change %@mt;sys@%Δ%@sb@%r%@sbx@%%@ital@%G%@rsf@%%@/xs;55;%lnwidth@%°%@/xs;63;(%lnwidth-x55)@%%@mh;-x63@%%@sb@%m%@sbx@%%@mx@% ≈ −56 kJ mol-1 and an equilibrium constant K ≈ 7 × 109 for the conversion of chorismate2-(aq) to prephenate2-(aq) at 298.15 K. Thus, for all practical purposes, this reaction can be considered to be “irreversible”. Quantum mechanics (Gaussian 94 with a B3LYP functional and a 6-31G* basis set) was used to calculate values of absolute and relative energies for the chorismic acid and prephenic acid species having charge numbers 0 and −2 both in the gas phase and in aqueous solution. The structures of prephenic acid and its dianion were also obtained along with values of thermodynamic reaction quantities. The effects of water solvation and solvent polarization were accounted for by using a self-consistent isodensity polarized continuum model (SCI-PCM). The calculated value of %@mt;sys@%Δ%@sb@%r%@sbx@%%@ital@%H%@rsf@%%@/xs;55;%lnwidth@%°%@/xs;63;(%lnwidth-x55)@%%@mh;-x63@%%@sb@%m%@sbx@%%@mx@% for the conversion of chorismate2-(aq) to prephenate2-(aq) at 298.l5 K was −46.4 kJ mol-1. This very good agreement between theory and experiment suggests that the energetics of this Claisen rearrangement are well understood and that the SCI-PCM method is capable of adequately describing the increased solvent−solute interaction of prephenate2- relative to chorismate.2-

Published
1997

105. Semisynthetic enzymes: design of flavin-dependent oxidoreductases

Author

Hilvert D and Kaiser Et

Subjects
chemistry.chemical_classification, Chemistry, Stereochemistry, Bioengineering, Flavin group, Kinetics, Enzyme, Biochemistry, Oxidoreductase, Flavins, Coenzyme analog, Oxidoreductases, Molecular Biology, Biotechnology
Published
1987

121. Design of artificial metalloenzymes for C-C cross-coupling reactions

Author

Sharma, M, Armstrong, F, Hilvert, D, and Davis, B

Abstract

Artificial metalloenzymes enable several non-natural chemical transformations by hosting a metal catalyst and providing activating microenvironments to the metal. New strategies to combine the complementary features of enzyme and transition metal catalysis are crucial for exploiting the pre-evolved selectivities of enzymes in chemical synthesis. In order to exploit the inherent selectivity of a serine protease Subtilisin (SBL) for C-C crosscoupling reactions, the interplay of natural substrate binding pockets and the nucleophilic machinery of the enzyme with the metal catalyst was central to our approach. A catalytically potent metal catalyst (palladium) was appropriately positioned to carry out oxidative Heck reaction between an alkene and arylboronic acid substrates in the active site of SBL. Further characterization of SBL-based artificial metalloenzymes and step-wise elucidation of the biotransformation pathway was accomplished through X-ray crystallography and mass-spectrometry studies. Such interlacing of the metal and the enzyme steps for cross-coupling reactions presents an attractive route for performing important organic reactions enzymatically.

Published
2016

122. Analysis of conserved residues of the human dipeptidyl peptidase III

Author

Špoljarić, Jasminka, Salopek-Sondi, Branka, Vukelić, Bojana, Jajčanin Jozić, Nina, Makarević, Janja, Agić, Dejan, Šimaga, Šumski, Vujaklija, Dušica, Abramić, Marija, Pluckthun, A, Aebersold, R, Engel, A, Helenius, A, Hilvert, D, Richmond, T, and Schuler, B

Subjects
peptidase family M49, dipeptidyl peptidase III, hydroxamate inhibitor, protein structure-function, site-directed mutagenesis
Abstract

The dipeptidyl peptidase III (DPP III) is a zinc-exopeptidase and a member of the metallopeptidase family M49 with an implied role in the pain-modulating system and endogenous defense against oxidative stress. The role of the unique fully conserved tyrosine (Tyr318) and tryptophan (Trp300) was investigated in human enzyme by site-directed mutagenesis. The substitution of Tyr318 for Phe decreased kcat by two orders of magnitude without altering the binding affinity of substrate or of a competitive inhibitor. However, replacement of the Trp300 reduced enzyme activity and had a negative effect on the binding of two competitive hydroxamate inhibitors designed to interact with S1 and S2 subsites. The results indicate that the conserved tyrosine could be involved in transition state stabilization during the catalytic action of M49 peptidases, and that conserved tryptophan contributes in maintaining the functional integrity of the enzyme's S2 subsite.

Published
2009

123. Enriching productive mutational paths accelerates enzyme evolution.

Author

Patsch D, Schwander T, Voss M, Schaub D, Hüppi S, Eichenberger M, Stockinger P, Schelbert L, Giger S, Peccati F, Jiménez-Osés G, Mutný M, Krause A, Bornscheuer UT, Hilvert D, and Buller RM

Subjects
Enzymes genetics, Enzymes metabolism, Enzymes chemistry, Directed Molecular Evolution methods, Evolution, Molecular, Biocatalysis, Models, Molecular, Protons, Protein Engineering, Mutation
Abstract

Darwinian evolution has given rise to all the enzymes that enable life on Earth. Mimicking natural selection, scientists have learned to tailor these biocatalysts through recursive cycles of mutation, selection and amplification, often relying on screening large protein libraries to productively modulate the complex interplay between protein structure, dynamics and function. Here we show that by removing destabilizing mutations at the library design stage and taking advantage of recent advances in gene synthesis, we can accelerate the evolution of a computationally designed enzyme. In only five rounds of evolution, we generated a Kemp eliminase-an enzymatic model system for proton transfer from carbon-that accelerates the proton abstraction step >10 8 -fold over the uncatalyzed reaction. Recombining the resulting variant with a previously evolved Kemp eliminase HG3.17, which exhibits similar activity but differs by 29 substitutions, allowed us to chart the topography of the designer enzyme's fitness landscape, highlighting that a given protein scaffold can accommodate several, equally viable solutions to a specific catalytic problem., Competing Interests: Competing interests: All authors declare no competing interests., (© 2024. The Author(s).)

Published
2024
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124. Structure Prediction and Computational Protein Design for Efficient Biocatalysts and Bioactive Proteins.

Author

Buller R, Damborsky J, Hilvert D, and Bornscheuer U

Abstract

The ability to predict and design protein structures has led to numerous applications in medicine, diagnostics and sustainable chemical manufacture. In addition, the wealth of predicted protein structures advances our understanding about how life's molecules function and interact. Honouring the work that has fundamentally changed the way scientists research and engineer proteins, the Nobel Prize in Chemistry in 2024 was awarded to David Baker for computational protein design and jointly to Demis Hassabis and John Jumper, who developed AlphaFold for machine-learning based protein structure prediction. Here, we highlight notable contributions to the development of these computational tools and their importance for the design of functional proteins that are applied in organic synthesis. Importantly, both technologies also have a profound impact on drug discovery as any therapeutic protein target can now be modelled allowing the de novo design of    peptide binders or the identification of small molecule ligands through the in silico docking of large compound libraries. Looking ahead, we highlight future research directions in protein engineering, medicinal chemistry and material design enabled by this transformative shift in protein science., (© 2024 Wiley‐VCH GmbH.)

Published
2024
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125. Artificial, biomimetic and hybrid enzymes: general discussion.

Author

Acevedo-Rocha C, Bakshi A, Bornscheuer UT, Campopiano DJ, Čivić J, Drienovská I, Ehinger FJ, Gomm A, Góra A, Green AP, Hanzevacki M, Harvey JN, Hilvert D, Huang M, Jarvis AG, Kamerlin SCL, Lichtenstein BR, Luk LYP, Lutz S, Marsh ENG, McKenzie A, Moliner V, Mulholland A, Osuna S, Pelletier JN, Raczyńska A, Rao AG, Rhys GG, Roelfes G, Rulíšek L, Stockinger P, Szleper K, Thompson SA, Turner N, Van der Kamp M, Xu G, and Zeymer C

Subjects
Biomimetics, Enzymes chemistry, Enzymes metabolism, Biomimetic Materials chemistry, Biomimetic Materials metabolism
Published
2024
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126. Spiers Memorial Lecture: Engineering biocatalysts.

Author

Hilvert D

Subjects
Biocatalysis, Enzymes metabolism, Enzymes chemistry, Protein Engineering methods
Abstract

Enzymes are being engineered to catalyze chemical reactions for many practical applications in chemistry and biotechnology. The approaches used are surveyed in this short review, emphasizing methods for accessing reactivities not expressed by native protein scaffolds. The successful generation of completely de novo enzymes that rival the rates and selectivities of their natural counterparts highlights the potential role that designer enzymes may play in the coming years in research, industry, and medicine. Some challenges that need to be addressed to realize this ambitious dream are considered together with possible solutions.

Published
2024
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127. Biocatalytic pathways, cascades, cells and systems: general discussion.

Author

Abramiuk M, Acevedo-Rocha C, Alogaidi A, Armstrong F, Bakshi A, Bornscheuer UT, Campopiano DJ, Chaiyen P, Ehinger FJ, Flitsch S, Harvey JN, Hilvert D, Jarvis AG, Jones REH, Lichtenstein BR, Luk LYP, Lurshay TC, Malcomson T, Marsh ENG, McFarlane NR, McKenzie A, Megarity CF, Moliner V, Mulholland AJ, Orton B, Pelletier JN, Raczyńska A, Syrén PO, Thompson SA, Turner N, Valetti F, Wong LS, and Zeymer C

Published
2024
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128. Enzyme evolution, engineering and design: mechanism and dynamics: general discussion.

Author

Acevedo-Rocha C, Berlicki L, Bornscheuer UT, Campopiano DJ, Chaiyen P, Čivić J, Cong Z, Ehinger FJ, Flitsch S, Góra A, Hanzevacki M, Harvey JN, Hilvert D, Hollfelder F, Jarvis AG, Lichtenstein BR, Lutz S, Malcomson T, Marsh ENG, McFarlane NR, McKenzie A, Mulholland A, Osuna S, Pelletier JN, Raczyńska A, Roelfes G, Rulíšek L, Stockinger P, Turner N, Valetti F, Van der Kamp M, Widersten M, and Zeymer C

Published
2024
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129. Biocatalysis for industry, medicine and the circular economy: general discussion.

Author

Alogaidi A, Armstrong F, Bakshi A, Bornscheuer UT, Brown G, Bruton I, Campopiano DJ, Dourado D, Ehinger FJ, Flitsch S, Góra A, Green AP, Hilvert D, Honda S, Huang M, Jones REH, King T, Lichtenstein BR, Lihan M, Luk LYP, Lurshay TC, Lutz S, Marsh ENG, McKenzie A, Orton B, Pelletier JN, Raczyńska A, Rulíšek L, Stockinger P, Syrén PO, Turner N, Valetti F, Van der Kamp M, and Wong LS

Published
2024
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130. High-throughput reprogramming of an NRPS condensation domain.

Author

Folger IB, Frota NF, Pistofidis A, Niquille DL, Hansen DA, Schmeing TM, and Hilvert D

Subjects
Substrate Specificity, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Protein Engineering methods, High-Throughput Screening Assays, Protein Domains, Peptide Synthases metabolism, Peptide Synthases genetics, Peptide Synthases chemistry
Abstract

Engineered biosynthetic assembly lines could revolutionize the sustainable production of bioactive natural product analogs. Although yeast display is a proven, powerful tool for altering the substrate specificity of gatekeeper adenylation domains in nonribosomal peptide synthetases (NRPSs), comparable strategies for other components of these megaenzymes have not been described. Here we report a high-throughput approach for engineering condensation (C) domains responsible for peptide elongation. We show that a 120-kDa NRPS module, displayed in functional form on yeast, can productively interact with an upstream module, provided in solution, to produce amide products tethered to the yeast surface. Using this system to screen a large C-domain library, we reprogrammed a surfactin synthetase module to accept a fatty acid donor, increasing catalytic efficiency for this noncanonical substrate >40-fold. Because C domains can function as selectivity filters in NRPSs, this methodology should facilitate the precision engineering of these molecular assembly lines., (© 2024. The Author(s).)

Published
2024
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131. Stimulus-responsive assembly of nonviral nucleocapsids.

Author

Hori M, Steinauer A, Tetter S, Hälg J, Manz EM, and Hilvert D

Subjects
Virus Assembly, Capsid metabolism, RNA, Viral metabolism, RNA, Viral genetics, Capsid Proteins metabolism, Capsid Proteins genetics, Capsid Proteins chemistry, RNA, Messenger metabolism, RNA, Messenger genetics, Nucleocapsid metabolism, Nucleocapsid ultrastructure, Cryoelectron Microscopy, Maltose-Binding Proteins metabolism, Maltose-Binding Proteins genetics
Abstract

Controlled assembly of a protein shell around a viral genome is a key step in the life cycle of many viruses. Here we report a strategy for regulating the co-assembly of nonviral proteins and nucleic acids into highly ordered nucleocapsids in vitro. By fusing maltose binding protein to the subunits of NC-4, an engineered protein cage that encapsulates its own encoding mRNA, we successfully blocked spontaneous capsid assembly, allowing isolation of the individual monomers in soluble form. To initiate RNA-templated nucleocapsid formation, the steric block can be simply removed by selective proteolysis. Analyses by transmission and cryo-electron microscopy confirmed that the resulting assemblies are structurally identical to their RNA-containing counterparts produced in vivo. Enzymatically triggered cage formation broadens the range of RNA molecules that can be encapsulated by NC-4, provides unique opportunities to study the co-assembly of capsid and cargo, and could be useful for studying other nonviral and viral assemblies., (© 2024. The Author(s).)

Published
2024
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132. Designed modular protein hydrogels for biofabrication.

Author

Dranseike D, Ota Y, Edwardson TGW, Guzzi EA, Hori M, Nakic ZR, Deshmukh DV, Levasseur MD, Mattli K, Tringides CM, Zhou J, Hilvert D, Peters C, and Tibbitt MW

Subjects
Humans, Proteins chemistry, Biocompatible Materials metabolism, Biopolymers, Tissue Engineering, Hydrogels chemistry, Mesenchymal Stem Cells
Abstract

Designing proteins that fold and assemble over different length scales provides a way to tailor the mechanical properties and biological performance of hydrogels. In this study, we designed modular proteins that self-assemble into fibrillar networks and, as a result, form hydrogel materials with novel properties. We incorporated distinct functionalities by connecting separate self-assembling (A block) and cell-binding (B block) domains into single macromolecules. The number of self-assembling domains affects the rigidity of the fibers and the final storage modulus G' of the materials. The mechanical properties of the hydrogels could be tuned over a broad range (G' = 0.1 - 10 kPa), making them suitable for the cultivation and differentiation of multiple cell types, including cortical neurons and human mesenchymal stem cells. Moreover, we confirmed the bioavailability of cell attachment domains in the hydrogels that can be further tailored for specific cell types or other biological applications. Finally, we demonstrate the versatility of the designed proteins for application in biofabrication as 3D scaffolds that support cell growth and guide their function. STATEMENT OF SIGNIFICANCE: Designed proteins that enable the decoupling of biophysical and biochemical properties within the final material could enable modular biomaterial engineering. In this context, we present a designed modular protein platform that integrates self-assembling domains (A blocks) and cell-binding domains (B blocks) within a single biopolymer. The linking of assembly domains and cell-binding domains this way provided independent tuning of mechanical properties and inclusion of biofunctional domains. We demonstrate the use of this platform for biofabrication, including neural cell culture and 3D printing of scaffolds for mesenchymal stem cell culture and differentiation. Overall, this work highlights how informed design of biopolymer sequences can enable the modular design of protein-based hydrogels with independently tunable biophysical and biochemical properties., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: TGWE, YO, MH, DD, EAG, ZRN, CP, MWT, and DH are listed as co-inventors of a provisional patent application on the materials described in this manuscript., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published
2024
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133. Myoglobin-Catalyzed Azide Reduction Proceeds via an Anionic Metal Amide Intermediate.

Author

Tinzl M, Diedrich JV, Mittl PRE, Clémancey M, Reiher M, Proppe J, Latour JM, and Hilvert D

Abstract

Nitrene transfer reactions catalyzed by heme proteins have broad potential for the stereoselective formation of carbon-nitrogen bonds. However, competition between productive nitrene transfer and the undesirable reduction of nitrene precursors limits the broad implementation of such biocatalytic methods. Here, we investigated the reduction of azides by the model heme protein myoglobin to gain mechanistic insights into the factors that control the fate of key reaction intermediates. In this system, the reaction proceeds via a proposed nitrene intermediate that is rapidly reduced and protonated to give a reactive ferrous amide species, which we characterized by UV/vis and Mössbauer spectroscopies, quantum mechanical calculations, and X-ray crystallography. Rate-limiting protonation of the ferrous amide to produce the corresponding amine is the final step in the catalytic cycle. These findings contribute to our understanding of the heme protein-catalyzed reduction of azides and provide a guide for future enzyme engineering campaigns to create more efficient nitrene transferases. Moreover, harnessing the reduction reaction in a chemoenzymatic cascade provided a potentially practical route to substituted pyrroles.

Published
2024
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134. High-Throughput Engineering of Nonribosomal Extension Modules.

Author

Camus A, Gantz M, and Hilvert D

Subjects
Phenylalanine, Peptides chemistry, Yeasts, Peptide Synthases metabolism
Abstract

Nonribosomal peptides constitute an important class of natural products that display a wide range of bioactivities. They are biosynthesized by large assembly lines called nonribosomal peptide synthetases (NRPSs). Engineering NRPS modules represents an attractive strategy for generating customized synthetases for the production of peptide variants with improved properties. Here, we explored the yeast display of NRPS elongation and termination modules as a high-throughput screening platform for assaying adenylation domain activity and altering substrate specificity. Depending on the module, display of A-T bidomains or C-A-T tridomains, which also include an upstream condensation domain, proved to be most effective. Reprograming a tyrocidine synthetase elongation module to accept 4-propargyloxy-phenylalanine, a noncanonical amino acid that is not activated by the native protein, illustrates the utility of this approach for altering NRPS specificity at internal sites.

Published
2023
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135. Albert Eschenmoser (1925-2023): A Giant of Organic Chemistry.

Author

Hilvert D, Pfaltz A, and Wennemers H

Abstract

Albert Eschenmoser, one of the greatest organic chemists of the past hundred years, died on July 14, 2023 at the age of 97. The extraordinary breadth of his scientific contributions ranged from synthetic methodology, structure elucidation, and synthesis of natural products to the chemical etiology of biomolecular structures., (© 2023 Wiley-VCH GmbH.)

Published
2023
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136. Cyanophycin and its biosynthesis: not hot but very cool.

Author

Sharon I, Hilvert D, and Schmeing TM

Subjects
Humans, Peptide Synthases metabolism, Dipeptides chemistry, Bacterial Proteins metabolism, Cyanobacteria metabolism
Abstract

Covering: 1878 to early 2023Cyanophycin is a biopolymer consisting of a poly-aspartate backbone with arginines linked to each Asp sidechain through isopeptide bonds. Cyanophycin is made by cyanophycin synthetase 1 or 2 through ATP-dependent polymerization of Asp and Arg, or β-Asp-Arg, respectively. It is degraded into dipeptides by exo-cyanophycinases, and these dipeptides are hydrolyzed into free amino acids by general or dedicated isodipeptidase enzymes. When synthesized, chains of cyanophycin coalesce into large, inert, membrane-less granules. Although discovered in cyanobacteria, cyanophycin is made by species throughout the bacterial kingdom, and cyanophycin metabolism provides advantages for toxic bloom forming algae and some human pathogens. Some bacteria have developed dedicated schemes for cyanophycin accumulation and use, which include fine temporal and spatial regulation. Cyanophycin has also been heterologously produced in a variety of host organisms to a remarkable level, over 50% of the host's dry mass, and has potential for a variety of green industrial applications. In this review, we summarize the progression of cyanophycin research, with an emphasis on recent structural studies of enzymes in the cyanophycin biosynthetic pathway. These include several unexpected revelations that show cyanophycin synthetase to be a very cool, multi-functional macromolecular machine.

Published
2023
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137. Complementary charge-driven encapsulation of functional protein by engineered protein cages in cellulo .

Author

Zakaszewski D, Koziej L, Pankowski J, Malolan VV, Gämperli N, Heddle JG, Hilvert D, and Azuma Y

Abstract

Charge-driven inclusion complex formation in live cells was examined using a degradation-prone fluorescent protein and a series of protein cages. The results show that sufficiently strong host-guest ionic interaction and an intact shell-like structure are crucial for the protective guest encapsulation.

Published
2023
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138. Structure and function of a hexameric cyanophycin synthetase 2.

Author

Markus LMD, Sharon I, Munro K, Grogg M, Hilvert D, Strauss M, and Schmeing TM

Subjects
Aspartic Acid, Bacterial Proteins chemistry, Peptide Synthases chemistry, Cyanobacteria
Abstract

Cyanophycin is a natural polymer composed of a poly-aspartate backbone with arginine attached to each of the aspartate sidechains. Produced by a wide range of bacteria, which mainly use it as a store of fixed nitrogen, it has many promising industrial applications. Cyanophycin can be synthesized from the amino acids Asp and Arg by the widespread cyanophycin synthetase 1 (CphA1), or from the dipeptide β-Asp-Arg by the cyanobacterial enzyme cyanophycin synthetase 2 (CphA2). CphA2 enzymes display a range of oligomeric states, from dimers to dodecamers. Recently, the crystal structure of a CphA2 dimer was solved but could not be obtained in complex with substrate. Here, we report cryo-EM structures of the hexameric CphA2 from Stanieria sp. at ~2.8 Å resolution, both with and without ATP analog and cyanophycin. The structures show a two-fold symmetrical, trimer-of-dimers hexameric architecture, and substrate-binding interactions that are similar to those of CphA1. Mutagenesis experiments demonstrate the importance of several conserved substrate-binding residues. We also find that a Q416A/R528G double mutation prevents hexamer formation and use this double mutant to show that hexamerization augments the rate of cyanophycin synthesis. Together, these results increase our mechanistic understanding of how an interesting green polymer is biosynthesized., (© 2023 The Authors. Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published
2023
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139. Engineered Nonviral Protein Cages Modified for MR Imaging.

Author

Kaster MA, Levasseur MD, Edwardson TGW, Caldwell MA, Hofmann D, Licciardi G, Parigi G, Luchinat C, Hilvert D, and Meade TJ

Subjects
Contrast Media chemistry, Gadolinium chemistry, Magnetic Resonance Imaging methods, Protons, Nanoparticles
Abstract

Diagnostic medical imaging utilizes magnetic resonance (MR) to provide anatomical, functional, and molecular information in a single scan. Nanoparticles are often labeled with Gd(III) complexes to amplify the MR signal of contrast agents (CAs) with large payloads and high proton relaxation efficiencies (relaxivity, r 1 ). This study examined the MR performance of two structurally unique cages, AaLS-13 and OP, labeled with Gd(III). The cages have characteristics relevant for the development of theranostic platforms, including (i) well-defined structure, symmetry, and size; (ii) the amenability to extensive engineering; (iii) the adjustable loading of therapeutically relevant cargo molecules; (iv) high physical stability; and (v) facile manufacturing by microbial fermentation. The resulting conjugates showed significantly enhanced proton relaxivity ( r 1 = 11-18 mM -1 s -1 at 1.4 T) compared to the Gd(III) complex alone ( r 1 = 4 mM -1 s -1 ). Serum phantom images revealed 107% and 57% contrast enhancements for Gd(III)-labeled AaLS-13 and OP cages, respectively. Moreover, proton nuclear magnetic relaxation dispersion ( 1 H NMRD) profiles showed maximum relaxivity values of 50 mM -1 s -1 . Best-fit analyses of the 1 H NMRD profiles attributed the high relaxivity of the Gd(III)-labeled cages to the slow molecular tumbling of the conjugates and restricted local motion of the conjugated Gd(III) complex.

Published
2023
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140. Design and optimization of enzymatic activity in a de novo β-barrel scaffold.

Author

Kipnis Y, Chaib AO, Vorobieva AA, Cai G, Reggiano G, Basanta B, Kumar E, Mittl PRE, Hilvert D, and Baker D

Subjects
Proteins genetics, Protein Engineering methods
Abstract

While native scaffolds offer a large diversity of shapes and topologies for enzyme engineering, their often unpredictable behavior in response to sequence modification makes de novo generated scaffolds an exciting alternative. Here we explore the customization of the backbone and sequence of a de novo designed eight stranded β-barrel protein to create catalysts for a retro-aldolase model reaction. We show that active and specific catalysts can be designed in this fold and use directed evolution to further optimize activity and stereoselectivity. Our results support previous suggestions that different folds have different inherent amenability to evolution and this property could account, in part, for the distribution of natural enzymes among different folds., (© 2022 The Authors. Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published
2022
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141. The structure of cyanophycinase in complex with a cyanophycin degradation intermediate.

Author

Sharon I, Grogg M, Hilvert D, and Schmeing TM

Subjects
Bacterial Proteins, Polymers, Dipeptides, Peptide Hydrolases
Abstract

Background: Cyanophycinases are serine protease family enzymes which are required for the metabolism of cyanophycin, the natural polymer multi-L-arginyl-poly(L-aspartic acid). Cyanophycinases degrade cyanophycin to β-Asp-Arg dipeptides, which enables use of this important store of fixed nitrogen., Methods: We used genetic code expansion to incorporate diaminopropionic acid into cyanophycinase in place of the active site serine, and determined a high-resolution structure of the covalent acyl-enzyme intermediate resulting from attack of cyanophycinase on a short cyanophycin segment., Results: The structure indicates that cyanophycin dipeptide residues P1 and P1' bind shallow pockets adjacent to the catalytic residues. We observe many cyanophycinase - P1 dipeptide interactions in the co-complex structure. Calorimetry measurements show that at least two cyanophycin dipeptides are needed for high affinity binding to cyanophycinase. We also characterized a putative cyanophycinase which we found to be structurally very similar but that shows no activity and could not be activated by mutation of its active site., General Significance: Despite its peptidic structure, cyanophycin is resistant to degradation by peptidases and other proteases. Our results help show how cyanophycinase can specifically bind and degrade this important polymer., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published
2022
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142. Post-Assembly Modification of Protein Cages by Ubc9-Mediated Lysine Acylation.

Author

Levasseur MD, Hofmann R, Edwardson TGW, Hehn S, Thanaburakorn M, Bode JW, and Hilvert D

Subjects
Recombinant Proteins genetics, Acylation, Anti-Bacterial Agents, Lysine metabolism, Peptides metabolism
Abstract

Although viruses have been successfully repurposed as vaccines, antibiotics, and anticancer therapeutics, they also raise concerns regarding genome integration and immunogenicity. Virus-like particles and non-viral protein cages represent a potentially safer alternative but often lack desired functionality. Here, we investigated the utility of a new enzymatic bioconjugation method, called lysine acylation using conjugating enzymes (LACE), to chemoenzymatically modify protein cages. We equipped two structurally distinct protein capsules with a LACE-reactive peptide tag and demonstrated their modification with diverse ligands. This modular approach combines the advantages of chemical conjugation and genetic fusion and allows for site-specific modification with recombinant proteins as well as synthetic peptides with facile control of the extent of labeling. This strategy has the potential to fine-tune protein containers of different shape and size by providing them with new properties that go beyond their biologically native functions., (© 2022 The Authors. ChemBioChem published by Wiley-VCH GmbH.)

Published
2022
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143. Reprogramming Nonribosomal Peptide Synthetases for Site-Specific Insertion of α-Hydroxy Acids.

Author

Camus A, Truong G, Mittl PRE, Markert G, and Hilvert D

Subjects
Amines, Amino Acids metabolism, Hydroxy Acids, Peptide Synthases metabolism, Substrate Specificity, Biological Products, Depsipeptides
Abstract

High-throughput engineering has the potential to revolutionize the customization of biosynthetic assembly lines for the sustainable production of pharmaceutically relevant natural product analogs. Here, we show that the substrate specificity of gatekeeper adenylation domains of nonribosomal peptide synthetases can be switched from an α-amino acid to an α-hydroxy acid in a single round of combinatorial mutagenesis and selection using yeast cell surface display. In addition to shedding light on how such proteins discriminate between amino and hydroxy groups, the remodeled domains function in a pathway context to produce α-hydroxy acid-containing linear peptides and cyclic depsipeptides with high efficiency. Site-specific replacement of backbone amines with oxygens by an engineered synthetase provides the means to probe and tune the activities of diverse peptide metabolites in a simple and predictable fashion.

Published
2022
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144. A cryptic third active site in cyanophycin synthetase creates primers for polymerization.

Author

Sharon I, Pinus S, Grogg M, Moitessier N, Hilvert D, and Schmeing TM

Subjects
Catalytic Domain, Plant Proteins metabolism, Polymerization, Bacterial Proteins chemistry, Peptide Synthases metabolism
Abstract

Cyanophycin is a nitrogen reserve biopolymer in many bacteria that has promising industrial applications. Made by cyanophycin synthetase 1 (CphA1), it has a poly-L-Asp backbone with L-Arg residues attached to each aspartate sidechain. CphA1s are thought to typically require existing segments of cyanophycin to act as primers for cyanophycin polymerization. In this study, we show that most CphA1s will not require exogenous primers and discover the surprising cause of primer independence: CphA1 can make minute quantities of cyanophycin without primer, and an unexpected, cryptic metallopeptidase-like active site in the N-terminal domain of many CphA1s digests these into primers, solving the problem of primer availability. We present co-complex cryo-EM structures, make mutations that transition CphA1s between primer dependence and independence, and demonstrate that primer dependence can be a limiting factor for cyanophycin production in heterologous hosts. In CphA1, domains with opposite catalytic activities combine into a remarkable, self-sufficient, biosynthetic nanomachine., (© 2022. The Author(s).)

Published
2022
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145. The road to fully programmable protein catalysis.

Author

Lovelock SL, Crawshaw R, Basler S, Levy C, Baker D, Hilvert D, and Green AP

Subjects
Biocatalysis, Biotechnology methods, Biotechnology trends, Protein Engineering methods, Protein Engineering trends, Proteins chemistry, Proteins metabolism
Abstract

The ability to design efficient enzymes from scratch would have a profound effect on chemistry, biotechnology and medicine. Rapid progress in protein engineering over the past decade makes us optimistic that this ambition is within reach. The development of artificial enzymes containing metal cofactors and noncanonical organocatalytic groups shows how protein structure can be optimized to harness the reactivity of nonproteinogenic elements. In parallel, computational methods have been used to design protein catalysts for diverse reactions on the basis of fundamental principles of transition state stabilization. Although the activities of designed catalysts have been quite low, extensive laboratory evolution has been used to generate efficient enzymes. Structural analysis of these systems has revealed the high degree of precision that will be needed to design catalysts with greater activity. To this end, emerging protein design methods, including deep learning, hold particular promise for improving model accuracy. Here we take stock of key developments in the field and highlight new opportunities for innovation that should allow us to transition beyond the current state of the art and enable the robust design of biocatalysts to address societal needs., (© 2022. Springer Nature Limited.)

Published
2022
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146. Protein Cages: From Fundamentals to Advanced Applications.

Author

Edwardson TGW, Levasseur MD, Tetter S, Steinauer A, Hori M, and Hilvert D

Subjects
Capsid Proteins chemistry, Catalysis, Protein Engineering, Capsid chemistry, Materials Science
Abstract

Proteins that self-assemble into polyhedral shell-like structures are useful molecular containers both in nature and in the laboratory. Here we review efforts to repurpose diverse protein cages, including viral capsids, ferritins, bacterial microcompartments, and designed capsules, as vaccines, drug delivery vehicles, targeted imaging agents, nanoreactors, templates for controlled materials synthesis, building blocks for higher-order architectures, and more. A deep understanding of the principles underlying the construction, function, and evolution of natural systems has been key to tailoring selective cargo encapsulation and interactions with both biological systems and synthetic materials through protein engineering and directed evolution. The ability to adapt and design increasingly sophisticated capsid structures and functions stands to benefit the fields of catalysis, materials science, and medicine.

Published
2022
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147. Structure and Function of the β-Asp-Arg Polymerase Cyanophycin Synthetase 2.

Author

Sharon I, Grogg M, Hilvert D, and Schmeing TM

Subjects
Bacterial Proteins metabolism, Nucleotidyltransferases, Plant Proteins metabolism, Cyanobacteria metabolism, Peptide Synthases metabolism
Abstract

Cyanophycin is a biopolymer composed of long chains of β-Asp-Arg. It is widespread in nature, being synthesized by many clades of bacteria, which use it as a cellular reservoir of nitrogen, carbon, and energy. Two enzymes are known to produce cyanophycin: cyanophycin synthetase 1 (CphA1), which builds cyanophycin from the amino acids Asp and Arg by alternating between two separate reactions for backbone extension and side chain modification, and cyanophycin synthetase 2 (CphA2), which polymerizes β-Asp-Arg dipeptides. CphA2 is evolutionarily related to CphA1, but questions about CphA2's altered structure and function remain unresolved. Cyanophycin and related molecules have drawn interest as green biopolymers. Because it only has a single active site, CphA2 could be more useful than CphA1 for biotechnological applications seeking to produce modified cyanophycin. In this study, we report biochemical assays on nine cyanobacterial CphA2 enzymes and report the crystal structure of CphA2 from Gloeothece citriformis at 3.0 Å resolution. The structure reveals a homodimeric, three-domain architecture. One domain harbors the polymerization active site and the two other domains have structural roles. The structure and biochemical assays explain how CphA2 binds and polymerizes β-Asp-Arg and highlights differences in in vitro oligomerization and activity between CphA2 enzymes. Using the structure and distinct activity profile as a guide, we introduced a single point mutation that converted Gloeothece citriformis CphA2 from a primer-dependent enzyme into a primer-independent enzyme.

Published
2022
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148. Whi3 mnemon association with endoplasmic reticulum membranes confines the memory of deceptive courtship to the yeast mother cell.

Author

Lau Y, Oamen HP, Grogg M, Parfenova I, Saarikangas J, Hannay R, Nichols RA, Hilvert D, Barral Y, and Caudron F

Subjects
Courtship, Endoplasmic Reticulum metabolism, RNA-Binding Proteins metabolism, Stem Cells metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism
Abstract

Prion-like proteins are involved in many aspects of cellular physiology, including cellular memory. In response to deceptive courtship, budding yeast escapes pheromone-induced cell-cycle arrest through the coalescence of the G1/S inhibitor Whi3 into a dominant, inactive super-assembly. Whi3 is a mnemon (Whi3 mnem ), a protein that conformational change maintains as a trait in the mother cell but is not inherited by the daughter cells. How the maintenance and asymmetric inheritance of Whi3 mnem are achieved is unknown. Here, we report that Whi3 mnem is closely associated with endoplasmic reticulum (ER) membranes and is retained in the mother cell by the lateral diffusion barriers present at the bud neck. Strikingly, barrier defects made Whi3 mnem propagate in a mitotically stable, prion-like manner. The amyloid-forming glutamine-rich domain of Whi3 was required for both mnemon and prion-like behaviors. Thus, we propose that Whi3 mnem is in a self-templating state, lending temporal maintenance of memory, whereas its association with the compartmentalized membranes of the ER prevents infectious propagation to the daughter cells. These results suggest that confined self-templating super-assembly is a powerful mechanism for the long-term encoding of information in a spatially defined manner. Yeast courtship may provide insights on how individual synapses become potentiated in neuronal memory., Competing Interests: Declaration of interests The authors declare no competing interests., (Crown Copyright © 2022. Published by Elsevier Inc. All rights reserved.)

Published
2022
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149. De novo peptide grafting to a self-assembling nanocapsule yields a hepatocyte growth factor receptor agonist.

Author

Komatsu Y, Terasaka N, Sakai K, Mihara E, Wakabayashi R, Matsumoto K, Hilvert D, Takagi J, and Suga H

Abstract

Lasso-grafting (LG) technology is a method for generating de novo biologics (neobiologics) by genetically implanting macrocyclic peptide pharmacophores, which are selected in vitro against a protein of interest, into loops of arbitrary protein scaffolds. In this study, we have generated a neo-capsid that potently binds the hepatocyte growth factor receptor MET by LG of anti-MET peptide pharmacophores into a circularly permuted variant of Aquifex aeolicus lumazine synthase (AaLS), a self-assembling protein nanocapsule. By virtue of displaying multiple-pharmacophores on its surface, the neo-capsid can induce dimerization (or multimerization) of MET, resulting in phosphorylation and endosomal internalization of the MET-capsid complex. This work demonstrates the potential of the LG technology as a synthetic biology approach for generating capsid-based neobiologics capable of activating signaling receptors., Competing Interests: The authors declare no conflicts of competing financial interest., (© 2021 The Authors.)

Published
2021
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150. Structures and function of the amino acid polymerase cyanophycin synthetase.

Author

Sharon I, Haque AS, Grogg M, Lahiri I, Seebach D, Leschziner AE, Hilvert D, and Schmeing TM

Subjects
Bacteria genetics, Bacteria metabolism, Bacterial Proteins genetics, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Models, Molecular, Peptide Synthases genetics, Protein Conformation, Bacteria enzymology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Peptide Synthases chemistry, Peptide Synthases metabolism
Abstract

Cyanophycin is a natural biopolymer produced by a wide range of bacteria, consisting of a chain of poly-L-Asp residues with L-Arg residues attached to the β-carboxylate sidechains by isopeptide bonds. Cyanophycin is synthesized from ATP, aspartic acid and arginine by a homooligomeric enzyme called cyanophycin synthetase (CphA1). CphA1 has domains that are homologous to glutathione synthetases and muramyl ligases, but no other structural information has been available. Here, we present cryo-electron microscopy and X-ray crystallography structures of cyanophycin synthetases from three different bacteria, including cocomplex structures of CphA1 with ATP and cyanophycin polymer analogs at 2.6 Å resolution. These structures reveal two distinct tetrameric architectures, show the configuration of active sites and polymer-binding regions, indicate dynamic conformational changes and afford insight into catalytic mechanism. Accompanying biochemical interrogation of substrate binding sites, catalytic centers and oligomerization interfaces combine with the structures to provide a holistic understanding of cyanophycin biosynthesis., (© 2021. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published
2021
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