Your search keyword '"Sarel J. Fleishman"' showing total 90 results

1. Allosteric regulation of the 20S proteasome by the Catalytic Core Regulators (CCRs) family

Author

Fanindra Kumar Deshmukh, Gili Ben-Nissan, Maya A. Olshina, Maria G. Füzesi-Levi, Caley Polkinghorn, Galina Arkind, Yegor Leushkin, Irit Fainer, Sarel J. Fleishman, Dan Tawfik, and Michal Sharon

Subjects

Science

Abstract

Abstract Controlled degradation of proteins is necessary for ensuring their abundance and sustaining a healthy and accurately functioning proteome. One of the degradation routes involves the uncapped 20S proteasome, which cleaves proteins with a partially unfolded region, including those that are damaged or contain intrinsically disordered regions. This degradation route is tightly controlled by a recently discovered family of proteins named Catalytic Core Regulators (CCRs). Here, we show that CCRs function through an allosteric mechanism, coupling the physical binding of the PSMB4 β-subunit with attenuation of the complex’s three proteolytic activities. In addition, by dissecting the structural properties that are required for CCR-like function, we could recapitulate this activity using a designed protein that is half the size of natural CCRs. These data uncover an allosteric path that does not involve the proteasome’s enzymatic subunits but rather propagates through the non-catalytic subunit PSMB4. This way of 20S proteasome-specific attenuation opens avenues for decoupling the 20S and 26S proteasome degradation pathways as well as for developing selective 20S proteasome inhibitors.

Published

2023

2. Designed active-site library reveals thousands of functional GFP variants

Author

Jonathan Yaacov Weinstein, Carlos Martí-Gómez, Rosalie Lipsh-Sokolik, Shlomo Yakir Hoch, Demian Liebermann, Reinat Nevo, Haim Weissman, Ekaterina Petrovich-Kopitman, David Margulies, Dmitry Ivankov, David M. McCandlish, and Sarel J. Fleishman

Subjects

Science

Abstract

Abstract Mutations in a protein active site can lead to dramatic and useful changes in protein activity. The active site, however, is sensitive to mutations due to a high density of molecular interactions, substantially reducing the likelihood of obtaining functional multipoint mutants. We introduce an atomistic and machine-learning-based approach, called high-throughput Functional Libraries (htFuncLib), that designs a sequence space in which mutations form low-energy combinations that mitigate the risk of incompatible interactions. We apply htFuncLib to the GFP chromophore-binding pocket, and, using fluorescence readout, recover >16,000 unique designs encoding as many as eight active-site mutations. Many designs exhibit substantial and useful diversity in functional thermostability (up to 96 °C), fluorescence lifetime, and quantum yield. By eliminating incompatible active-site mutations, htFuncLib generates a large diversity of functional sequences. We envision that htFuncLib will be used in one-shot optimization of activity in enzymes, binders, and other proteins.

Published

2023

3. Computational design and molecular dynamics simulations suggest the mode of substrate binding in ceramide synthases

Author

Iris D. Zelnik, Beatriz Mestre, Jonathan J. Weinstein, Tamir Dingjan, Stav Izrailov, Shifra Ben-Dor, Sarel J. Fleishman, and Anthony H. Futerman

Subjects

Science

Abstract

Abstract Until now, membrane-protein stabilization has relied on iterations of mutations and screening. We now validate a one-step algorithm, mPROSS, for stabilizing membrane proteins directly from an AlphaFold2 model structure. Applied to the lipid-generating enzyme, ceramide synthase, 37 designed mutations lead to a more stable form of human CerS2. Together with molecular dynamics simulations, we propose a pathway by which substrates might be delivered to the ceramide synthases.

Published

2023

4. Computationally designed hyperactive Cas9 enzymes

Author

Pascal D. Vos, Giulia Rossetti, Jessica L. Mantegna, Stefan J. Siira, Andrianto P. Gandadireja, Mitchell Bruce, Samuel A. Raven, Olga Khersonsky, Sarel J. Fleishman, Aleksandra Filipovska, and Oliver Rackham

Subjects

Science

Abstract

The ability to alter the genomes of living cells is key to understanding how genes influence the functions of organisms and will be critical to modify living systems for useful purposes. Here, the authors use computational design to discover Cas9 enzymes with increased activity.

Published

2022

5. Computer-aided engineering of staphylokinase toward enhanced affinity and selectivity for plasmin

Author

Dmitri Nikitin, Jan Mican, Martin Toul, David Bednar, Michaela Peskova, Patricia Kittova, Sandra Thalerova, Jan Vitecek, Jiri Damborsky, Robert Mikulik, Sarel J. Fleishman, Zbynek Prokop, and Martin Marek

Subjects

Acute myocardial infarction, Stroke treatments, Thrombolytics, Plasminogen activators, Staphylokinase, Rational design, Biotechnology, TP248.13-248.65

Abstract

Cardio- and cerebrovascular diseases are leading causes of death and disability, resulting in one of the highest socio-economic burdens of any disease type. The discovery of bacterial and human plasminogen activators and their use as thrombolytic drugs have revolutionized treatment of these pathologies. Fibrin-specific agents have an advantage over non-specific factors because of lower rates of deleterious side effects. Specifically, staphylokinase (SAK) is a pharmacologically attractive indirect plasminogen activator protein of bacterial origin that forms stoichiometric noncovalent complexes with plasmin, promoting the conversion of plasminogen into plasmin. Here we report a computer-assisted re-design of the molecular surface of SAK to increase its affinity for plasmin. A set of computationally designed SAK mutants was produced recombinantly and biochemically characterized. Screening revealed a pharmacologically interesting SAK mutant with ∼7-fold enhanced affinity toward plasmin, ∼10-fold improved plasmin selectivity and moderately higher plasmin-generating efficiency in vitro. Collectively, the results obtained provide a framework for SAK engineering using computational affinity-design that could pave the way to next-generation of effective, highly selective, and less toxic thrombolytics.

Published

2022

6. Local Mutations Can Serve as a Game Changer for Global Protein Solvent Interaction

Author

Ellen M. Adams, Simone Pezzotti, Jonas Ahlers, Maximilian Rüttermann, Maxim Levin, Adi Goldenzweig, Yoav Peleg, Sarel J. Fleishman, Irit Sagi, and Martina Havenith

Subjects

Chemistry, QD1-999

Published

2021

7. What Have We Learned from Design of Function in Large Proteins?

Author

Olga Khersonsky and Sarel J. Fleishman

Subjects

Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

The overarching goal of computational protein design is to gain complete control over protein structure and function. The majority of sophisticated binders and enzymes, however, are large and exhibit diverse and complex folds that defy atomistic design calculations. Encouragingly, recent strategies that combine evolutionary constraints from natural homologs with atomistic calculations have significantly improved design accuracy. In these approaches, evolutionary constraints mitigate the risk from misfolding and aggregation, focusing atomistic design calculations on a small but highly enriched sequence subspace. Such methods have dramatically optimized diverse proteins, including vaccine immunogens, enzymes for sustainable chemistry, and proteins with therapeutic potential. The new generation of deep learning-based ab initio structure predictors can be combined with these methods to extend the scope of protein design, in principle, to any natural protein of known sequence. We envision that protein engineering will come to rely on completely computational methods to efficiently discover and optimize biomolecular activities.

Published

2022

8. Computational Enzyme Engineering Pipelines for Optimized Production of Renewable Chemicals

Author

Marc Scherer, Sarel J. Fleishman, Patrik R. Jones, Thomas Dandekar, and Elena Bencurova

Subjects

computational, enzyme, engineering, design, biomanufacturing, biofuel, Biotechnology, TP248.13-248.65

Abstract

To enable a sustainable supply of chemicals, novel biotechnological solutions are required that replace the reliance on fossil resources. One potential solution is to utilize tailored biosynthetic modules for the metabolic conversion of CO2 or organic waste to chemicals and fuel by microorganisms. Currently, it is challenging to commercialize biotechnological processes for renewable chemical biomanufacturing because of a lack of highly active and specific biocatalysts. As experimental methods to engineer biocatalysts are time- and cost-intensive, it is important to establish efficient and reliable computational tools that can speed up the identification or optimization of selective, highly active, and stable enzyme variants for utilization in the biotechnological industry. Here, we review and suggest combinations of effective state-of-the-art software and online tools available for computational enzyme engineering pipelines to optimize metabolic pathways for the biosynthesis of renewable chemicals. Using examples relevant for biotechnology, we explain the underlying principles of enzyme engineering and design and illuminate future directions for automated optimization of biocatalysts for the assembly of synthetic metabolic pathways.

Published

2021

9. Ultrahigh specificity in a network of computationally designed protein-interaction pairs

Author

Ravit Netzer, Dina Listov, Rosalie Lipsh, Orly Dym, Shira Albeck, Orli Knop, Colin Kleanthous, and Sarel J. Fleishman

Subjects

Science

Abstract

The molecular basis of ultrahigh specificity in protein-protein interactions remains obscure. The authors present a computational method to design atomically accurate new pairs exhibiting >100,000-fold specificity switches, generating a large and complex interaction network.

Published

2018

10. Highly Specific Monoclonal Antibody Targeting the Botulinum Neurotoxin Type E Exposed SNAP-25 Neoepitope

Author

Adva Mechaly, Eran Diamant, Ron Alcalay, Alon Ben David, Eyal Dor, Amram Torgeman, Ada Barnea, Meni Girshengorn, Lilach Levin, Eyal Epstein, Ariel Tennenhouse, Sarel J. Fleishman, Ran Zichel, and Ohad Mazor

Subjects

botulinum E, monoclonal antibody, phage-display, SNAP-25, Immunologic diseases. Allergy, RC581-607

Abstract

Botulinum neurotoxin type E (BoNT/E), the fastest acting toxin of all BoNTs, cleaves the 25 kDa synaptosomal-associated protein (SNAP-25) in motor neurons, leading to flaccid paralysis. The specific detection and quantification of the BoNT/E-cleaved SNAP-25 neoepitope can facilitate the development of cell-based assays for the characterization of anti-BoNT/E antibody preparations. In order to isolate highly specific monoclonal antibodies suitable for the in vitro immuno-detection of the exposed neoepitope, mice and rabbits were immunized with an eight amino acid peptide composed of the C-terminus of the cleaved SNAP-25. The immunized rabbits developed a specific and robust polyclonal antibody response, whereas the immunized mice mostly demonstrated a weak antibody response that could not discriminate between the two forms of SNAP-25. An immune scFv phage-display library was constructed from the immunized rabbits and a panel of antibodies was isolated. The sequence alignment of the isolated clones revealed high similarity between both heavy and light chains with exceptionally short HCDR3 sequences. A chimeric scFv-Fc antibody was further expressed and characterized, exhibiting a selective, ultra-high affinity (pM) towards the SNAP-25 neoepitope. Moreover, this antibody enabled the sensitive detection of cleaved SNAP-25 in BoNT/E treated SiMa cells with no cross reactivity with the intact SNAP-25. Thus, by applying an immunization and selection procedure, we have isolated a novel, specific and high-affinity antibody against the BoNT/E-derived SNAP-25 neoepitope. This novel antibody can be applied in in vitro assays that determine the potency of antitoxin preparations and reduce the use of laboratory animals for these purposes.

Published

2022

11. Highly active enzymes by automated combinatorial backbone assembly and sequence design

Author

Gideon Lapidoth, Olga Khersonsky, Rosalie Lipsh, Orly Dym, Shira Albeck, Shelly Rogotner, and Sarel J. Fleishman

Subjects

Science

Abstract

Computationally designed enzymes often show lower activity or stability than their natural counterparts. Here, the authors present an evolution-inspired method for automated enzyme design, creating stable enzymes with accurate active site architectures and wild-type-like activities.

Published

2018

12. De novo-designed transmembrane domains tune engineered receptor functions

Author

Assaf Elazar, Nicholas J Chandler, Ashleigh S Davey, Jonathan Y Weinstein, Julie V Nguyen, Raphael Trenker, Ryan S Cross, Misty R Jenkins, Melissa J Call, Matthew E Call, and Sarel J Fleishman

Subjects

de novo design, membrane protein, transmembrane, chimeric antigen receptor, CAR T cell, immunotherapy, Medicine, Science, Biology (General), QH301-705.5

Abstract

De novo-designed receptor transmembrane domains (TMDs) present opportunities for precise control of cellular receptor functions. We developed a de novo design strategy for generating programmed membrane proteins (proMPs): single-pass α-helical TMDs that self-assemble through computationally defined and crystallographically validated interfaces. We used these proMPs to program specific oligomeric interactions into a chimeric antigen receptor (CAR) that we expressed in mouse primary T cells and found that both in vitro CAR T cell cytokine release and in vivo antitumor activity scaled linearly with the oligomeric state encoded by the receptor TMD, from monomers up to tetramers. All programmed CARs stimulated substantially lower T cell cytokine release relative to the commonly used CD28 TMD, which we show elevated cytokine release through lateral recruitment of the endogenous T cell costimulatory receptor CD28. Precise design using orthogonal and modular TMDs thus provides a new way to program receptor structure and predictably tune activity for basic or applied synthetic biology.

Published

2022

13. Evolutionary paths that link orthogonal pairs of binding proteins

Author

Ziv Avizemer, Carlos Martí‐Gómez, Shlomo Yakir Hoch, David M. McCandlish, and Sarel J. Fleishman

Abstract

Some protein binding pairs exhibit extreme specificities that functionally insulate them from homologs. Such pairs evolve mostly by accumulating single-point mutations, and mutants are selected if their affinity exceeds the threshold required for function1–4. Thus, homologous and high-specificity binding pairs bring to light an evolutionary conundrum: how does a new specificity evolve while maintaining the required affinity in each intermediate5,6? Until now, a fully functional single-mutation path that connects two orthogonal pairs has only been described where the pairs were mutationally close enabling experimental enumeration of all intermediates2. We present an atomistic and graph-theoretical framework for discovering low molecular strain single-mutation paths that connect two extant pairs and apply it to two orthogonal bacterial colicin endonuclease-immunity pairs separated by 17 interface mutations7. We were not able to find a strain-free and functional path in the sequence space defined by the two extant pairs. By including mutations that bridge amino acids that cannot be exchanged through single-nucleotide mutations, we found a strain-free 19-mutation trajectory that is completely functional in vivo. Despite the long mutational trajectory, the specificity switch is remarkably abrupt, resulting from only one radical mutation on each partner. Each of the critical specificity-switch mutations increases fitness, demonstrating that functional divergence could be driven by positive Darwinian selection. These results reveal how even radical functional changes in an epistatic fitness landscape may evolve.

Published

2023

14. Stable mammalian serum albumins designed for bacterial expression

Author

Olga Khersonsky, Moshe Goldsmith, Irina Zaretsky, Shelly Rogotner, Orly Dym, Tamar Unger, Meital Yona, and Sarel J. Fleishman

Abstract

Albumin is the most abundant protein in the blood serum of mammals and has essential carrier and physiological roles. Albumins are also used in a wide variety of molecular and cellular experiments and in the cultured-meat industry. Despite their importance, however, albumins are challenging for heterologous expression in microbial hosts, likely due to 17 conserved intramolecular disulfide bonds. Therefore, albumins used in research and biotechnological applications either derive from animal serum, despite severe ethical and reproducibility concerns, or from recombinant expression in yeast or rice. We used the PROSS algorithm to stabilize human and bovine serum albumins. All the stabilized designs are highly expressed inE. coli. Design accuracy is verified by crystallographic analysis of a human albumin variant with 16 mutations. This albumin variant exhibits ligand binding properties similar to those of the wild type. Remarkably, a design with 73 mutations relative to human albumin exhibits over 40°C improved stability and is stable beyond the boiling point. Our results suggest that proteins with many disulfide bridges have the potential to exhibit extreme stability when subjected to design. The designed albumins may be used to make economical, reproducible, and animal-free reagents for molecular and cell biology. They also open the way to high-throughput screening to study and enhance albumin carrier properties.Graphical abstractHighlights-Computational design was applied to stabilize human and bovine serum albumin-Albumin designs express solubly inE. coliand exhibit up to 40 °C increased thermostability-Some designs exhibit identical ligand binding properties-Crystal structure confirms design accuracy-Designs can be used in cell culture andin vitroapplications

Published

2023

15. Design of a stable human acid‐β‐glucosidase: towards improved Gaucher disease therapy and mutation classification

Author

Sarka Pokorna, Olga Khersonsky, Rosalie Lipsh‐Sokolik, Adi Goldenzweig, Rebekka Nielsen, Yacov Ashani, Yoav Peleg, Tamar Unger, Shira Albeck, Orly Dym, Asa Tirosh, Rana Tarayra, Michaël Hocquemiller, Ralph Laufer, Shifra Ben‐Dor, Israel Silman, Joel L. Sussman, Sarel J. Fleishman, and Anthony H. Futerman

Subjects

Cell Biology, Molecular Biology, Biochemistry

Published

2023

16. Structure and receptor recognition by the Lassa virus spike complex

Author

Michael Katz, Jonathan Weinstein, Maayan Eilon-Ashkenazy, Katrin Gehring, Hadas Cohen-Dvashi, Nadav Elad, Sarel J. Fleishman, and Ron Diskin

Subjects

Lassa Fever, Multidisciplinary, Viral Envelope Proteins, Protein Conformation, Humans, Receptors, Virus, Protein Sorting Signals, Virus Internalization, Dystroglycans, Lassa virus

Abstract

Lassa virus (LASV) is a human pathogen, causing substantial morbidity and mortality

Published

2022

17. Computationally designed dual-color MRI reporters for noninvasive imaging of transgene expression

Author

Hyla Allouche-Arnon, Olga Khersonsky, Nishanth D. Tirukoti, Yoav Peleg, Orly Dym, Shira Albeck, Alexander Brandis, Tevie Mehlman, Liat Avram, Talia Harris, Nirbhay N. Yadav, Sarel J. Fleishman, and Amnon Bar-Shir

Subjects

Genes, Reporter, Biomedical Engineering, Animals, Molecular Medicine, Bioengineering, Transgenes, Magnetic Resonance Imaging, Applied Microbiology and Biotechnology, Biotechnology

Abstract

Imaging of gene-expression patterns in live animals is difficult to achieve with fluorescent proteins because tissues are opaque to visible light. Imaging of transgene expression with magnetic resonance imaging (MRI), which penetrates to deep tissues, has been limited by single reporter visualization capabilities. Moreover, the low-throughput capacity of MRI limits large-scale mutagenesis strategies to improve existing reporters. Here we develop an MRI system, called GeneREFORM, comprising orthogonal reporters for two-color imaging of transgene expression in deep tissues. Starting from two promiscuous deoxyribonucleoside kinases, we computationally designed highly active, orthogonal enzymes ('reporter genes') that specifically phosphorylate two MRI-detectable synthetic deoxyribonucleosides ('reporter probes'). Systemically administered reporter probes exclusively accumulate in cells expressing the designed reporter genes, and their distribution is displayed as pseudo-colored MRI maps based on dynamic proton exchange for noninvasive visualization of transgene expression. We envision that future extensions of GeneREFORM will pave the way to multiplexed deep-tissue mapping of gene expression in live animals.

Published

2022

18. Author response for 'Design of a stable human acid‐β‐glucosidase: towards improved Gaucher disease therapy and mutation classification'

Author

null Sarka Pokorna, null Olga Khersonsky, null Rosalie Lipsh‐Sokolik, null Adi Goldenzweig, null Rebekka Nielsen, null Yacov Ashani, null Yoav Peleg, null Tamar Unger, null Shira Albeck, null Orly Dym, null Asa Tirosh, null Rana Tarayra, null Michaël Hocquemiller, null Ralph Laufer, null Shifra Ben‐Dor, null Israel Silman, null Joel L. Sussman, null Sarel J. Fleishman, and null Anthony H. Futerman

Published

2023

19. A Rationally and Computationally Designed Fluorescent Biosensor for <scp>d</scp>-Serine

Author

Sarel J. Fleishman, Hiromu Monai, Björn Breithausen, Vanessa Vongsouthi, Leon Kremers, Joshua A. Mitchell, Christian Henneberger, Harald Janovjak, Petr Unichenko, Colin J. Jackson, Jason H. Whitfield, Hajime Hirase, and Olga Khersonsky

Subjects

Conformational change, computational design, rational design, Bioengineering, Biosensing Techniques, Ligands, FRET biosensor, 03 medical and health sciences, 0302 clinical medicine, ddc:570, Fluorescence Resonance Energy Transfer, Serine, Animals, Binding site, Instrumentation, 030304 developmental biology, Thermostability, Fluid Flow and Transfer Processes, 0303 health sciences, neuroimaging, Binding Sites, Chemistry, Process Chemistry and Technology, Protein dynamics, Rational design, protein engineering, Protein engineering, Ligand (biochemistry), Rats, d-serine, Biophysics, Biosensor, 030217 neurology & neurosurgery

Abstract

Solute-binding proteins (SBPs) have evolved to balance the demands of ligand affinity, thermostability, and conformational change to accomplish diverse functions in small molecule transport, sensing, and chemotaxis. Although the ligand-induced conformational changes that occur in SBPs make them useful components in biosensors, they are challenging targets for protein engineering and design. Here, we have engineered a d-alanine-specific SBP into a fluorescence biosensor with specificity for the signaling molecule d-serine (D-serFS). This was achieved through binding site and remote mutations that improved affinity (KD = 6.7 ± 0.5 μM), specificity (40-fold increase vs glycine), thermostability (Tm = 79 °C), and dynamic range (∼14%). This sensor allowed measurement of physiologically relevant changes in d-serine concentration using two-photon excitation fluorescence microscopy in rat brain hippocampal slices. This work illustrates the functional trade-offs between protein dynamics, ligand affinity, and thermostability and how these must be balanced to achieve desirable activities in the engineering of complex, dynamic proteins.

Published

2021

20. Computational design of BclxL inhibitors that target transmembrane domain interactions

Author

Gerard Duart, Assaf Elazar, Jonathan Y. Weinstein, Laura Gadea-Salom, Juan Ortiz-Mateu, Sarel J. Fleishman, Ismael Mingarro, and Luis Martinez-Gil

Subjects

Multidisciplinary

Abstract

Several methods have been developed to explore interactions among water-soluble proteins or regions of proteins. However, techniques to target transmembrane domains have not been examined thoroughly. Here we developed a novel computational approach to design transmembrane sequences that specifically modulate protein-protein interactions in the membrane. To illustrate this method we demonstrated that BclxL can interact with other members of the Bcl2 family through the transmembrane domain and that these interactions are necessary for BclxL control of cell death. Next, we designed sequences that specifically recognize and sequester the transmembrane domain of BclxL. Hence, we were able to prevent BclxL intra-membrane interactions and cancel its anti-apoptotic effect. These results advance our understanding of protein-protein interactions in membranes and provide new means to modulate them. Moreover, the success of our approach may trigger the development of a new generation of inhibitors targeting interactions between transmembrane domains.

Published

2022

21. Designed active-site library reveals thousands of functional GFP variants

Author

Jonathan Yaacov Weinstein, Carlos Martí-Gómez, Rosalie Lipsh-Sokolik, Shlomo Yakir Hoch, Demian Liebermann, Reinat Nevo, Haim Weissman, Ekaterina Petrovich-Kopitman, David Margulies, Dmitry Ivankov, David M. McCandlish, and Sarel J. Fleishman

Subjects

Multidisciplinary, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology

Abstract

Mutations in a protein active site can lead to dramatic and useful changes in protein activity. The active site, however, is sensitive to mutations due to a high density of molecular interactions, substantially reducing the likelihood of obtaining functional multipoint mutants. We introduce an atomistic and machine-learning-based approach, called high-throughput Functional Libraries (htFuncLib), that designs a sequence space in which mutations form low-energy combinations that mitigate the risk of incompatible interactions. We apply htFuncLib to the GFP chromophore-binding pocket, and, using fluorescence readout, recover >16,000 unique designs encoding as many as eight active-site mutations. Many designs exhibit substantial and useful diversity in functional thermostability (up to 96 °C), fluorescence lifetime, and quantum yield. By eliminating incompatible active-site mutations, htFuncLib generates a large diversity of functional sequences. We envision that htFuncLib will be used in one-shot optimization of activity in enzymes, binders, and other proteins.

Published

2022

22. Combinatorial assembly and design of enzymes

Author

Rosalie Lipsh-Sokolik, Olga Khersonsky, Sybrin P. Schröder, Casper de Boer, Shlomo-Yakir Hoch, Gideon J. Davies, Hermen S. Overkleeft, and Sarel J. Fleishman

Abstract

Design of structurally diverse enzymes is constrained by long-range interactions that are needed for accurate folding. We introduce an atomistic and machine-learning strategy for Combinatorial Assembly and Design of ENZymes, CADENZ, to design fragments that combine with one another to generate diverse, low-energy structures with stable catalytic constellations. We applied CADENZ to endoxylanases and used activity-based protein profiling to recover thousands of active and structurally diverse enzymes. Functional designs exhibit high active-site preorganization and more stable and compact packing outside the active site. Implementing these lessons into CADENZ led to a tenfold improved hit rate and >10,000 active enzymes. This design-test-learn loop can be applied, in principle, to any modular protein family, yielding huge diversity and general lessons on protein design principles.

Published

2022

23. Local Mutations Can Serve as a Game Changer for Global Protein Solvent Interaction

Author

Yoav Peleg, Simone Pezzotti, Sarel J. Fleishman, Ellen M. Adams, Martina Havenith, Irit Sagi, Maxim Levin, Maximilian Rüttermann, Adi Goldenzweig, and Jonas Ahlers

Subjects

matrix metalloproteinase, Chemistry, Protein design, rational design, Rational design, Orders of magnitude (numbers), Article, molecular dynamics, Solvent, Molecular dynamics, local thermodynamics, THz spectroscopy, Biophysics, Computational design, Molecule, solvation science, Surface protein, QD1-999

Abstract

Although it is well-known that limited local mutations of enzymes, such as matrix metalloproteinases (MMPs), may change enzyme activity by orders of magnitude as well as its stability, the completely rational design of proteins is still challenging. These local changes alter the electrostatic potential and thus local electrostatic fields, which impacts the dynamics of water molecules close the protein surface. Here we show by a combined computational design, experimental, and molecular dynamics (MD) study that local mutations have not only a local but also a global effect on the solvent: In the specific case of the matrix metalloprotease MMP14, we found that the nature of local mutations, coupled with surface morphology, have the ability to influence large patches of the water hydrogen-bonding network at the protein surface, which is correlated with stability. The solvent contribution can be experimentally probed via terahertz (THz) spectroscopy, thus opening the door to the exciting perspective of rational protein design in which a systematic tuning of hydration water properties allows manipulation of protein stability and enzymatic activity.

Published

2021

24. Reliable energy-based antibody humanization and stabilization

Author

Ariel Tennenhouse, Lev Khmelnitsky, Razi Khalaila, Noa Yeshaya, Ashish Noronha, Moshit Lindzen, Emily Makowski, Ira Zaretsky, Yael Fridmann Sirkis, Yael Galon-Wolfenson, Peter M. Tessier, Jakub Abramson, Yosef Yarden, Deborah Fass, and Sarel J. Fleishman

Abstract

Humanization is an essential step in developing animal-derived antibodies into therapeutics, and approximately one third of approved antibodies have been humanized. Conventional humanization approaches graft the complementarity-determining regions (CDRs) of the animal antibody onto several homologous human frameworks. This process, however, often drastically lowers stability and antigen binding, demanding iterative mutational fine-tuning to recover the original antibody properties. Here, we present Computational hUMan AntiBody design (CUMAb), a web-accessible method that starts from an experimental or model antibody structure, systematically grafts the animal CDRs on thousands of human frameworks, and uses Rosetta atomistic simulations to rank the designs by energy and structural integrity (http://CUMAb.weizmann.ac.il). CUMAb designs of five independent antibodies exhibit similar affinities to the parental animal antibody, and some designs show marked improvement in stability. Surprisingly, nonhomologous frameworks are often preferred to the highest-homology ones, and several CUMAb designs that use different human frameworks and differ by dozens of mutations are functionally equivalent. Thus, CUMAb presents a general and streamlined approach to optimizing antibody stability and expressibility while increasing humanness.

Published

2022

25. Editorial overview: Engineering and design

Author

Sarel J. Fleishman and Roy A. Mariuzza

Subjects

Structural Biology, Protein Engineering, Molecular Biology

Published

2022

26. Designed high-redox potential laccases exhibit high functional diversity

Author

Shiran Barber-Zucker, Ivan Mateljak, Moshe Goldsmith, Meital Kupervaser, Miguel Alcalde, and Sarel J. Fleishman

Subjects

General Chemistry, Catalysis

Abstract

White-rot fungi secrete an impressive repertoire of high-redox potential laccases (HRPLs) and peroxidases for efficient oxidation and utilization of lignin. Laccases are attractive enzymes for green-chemistry applications due to their broad substrate range and low environmental impact. Since expression of functional recombinant HRPLs is challenging, however, iterative directed evolution protocols have been applied to improve their expression, activity and stability. We implement a rational, stabilize-and-diversify strategy to two HRPLs that we could not functionally express: first, we use the PROSS stability-design algorithm to allow functional expression in yeast. Second, we use the stabilized enzymes as starting points for FuncLib active-site design to improve their activity and substrate diversity. Four of the FuncLib designed HRPLs and their PROSS progenitor exhibit substantial diversity in reactivity profiles against high-redox potential substrates, including lignin monomers. Combinations of 3-4 subtle mutations that change the polarity, solvation and sterics of the substrate-oxidation site result in orders of magnitude changes in reactivity profiles. These stable and versatile HRPLs are a step towards the generation of an effective lignin-degrading consortium of enzymes that can be secreted from yeast. More broadly, the stabilize-and-diversify strategy can be applied to other challenging enzyme families to study and expand the utility of natural enzymes.

Published

2022

27. Obituary: Dan S Tawfik (1955–2021)

Author

Amir Aharoni and Sarel J. Fleishman

Subjects

Pride, History, media_common.quotation_subject, Climbing, Art history, Passion, Cell Biology, Obituary, Molecular Biology, Biochemistry, Accident (philosophy), Protein evolution, media_common

Abstract

Dan (Danny) Tawfik, a leader in biochemistry and protein evolution, sadly died due to a fatal climbing accident on May 4th, 2021. Apart from science, rock climbing was Danny's passion and a source of pride as only a handful of researchers are active climbers. Danny made unique and long-lasting contributions to our understanding of molecular evolution. He was also incredibly generous with his time and insights, and many researchers around the world are indebted to him, not least the two authors of this obituary.

Published

2021

28. Protein quaternary structures in solution are a mixture of multiple forms

Author

Shir Marciano, Debabrata Dey, Dina Listov, Sarel J Fleishman, Adar Sonn-Segev, Haydyn Mertens, Florian Busch, Yongseok Kim, Sophie R. Harvey, Vicki H. Wysocki, and Gideon Schreiber

Subjects

ddc:540, General Chemistry

Abstract

Chemical science 13(39), 11680 - 11695 (2022). doi:10.1039/D2SC02794A, Over half the proteins in the E. coli cytoplasm form homo or hetero-oligomeric structures. Experimentally determined structures are often considered in determining a protein's oligomeric state, but static structures miss the dynamic equilibrium between different quaternary forms. The problem is exacerbated in homo-oligomers, where the oligomeric states are challenging to characterize. Here, we re-evaluated the oligomeric state of 17 different bacterial proteins across a broad range of protein concentrations and solutions by native mass spectrometry (MS), mass photometry (MP), size exclusion chromatography (SEC), and small-angle X-ray scattering (SAXS), finding that most exhibit several oligomeric states. Surprisingly, some proteins did not show mass-action driven equilibrium between the oligomeric states. For approximately half the proteins, the predicted oligomeric forms described in publicly available databases underestimated the complexity of protein quaternary structures in solution. Conversely, AlphaFold multimer provided an accurate description of the potential multimeric states for most proteins, suggesting that it could help resolve uncertainties on the solution state of many proteins., Published by RSC, Cambridge

Published

2022

29. Author response: De novo-designed transmembrane domains tune engineered receptor functions

Author

Ashleigh S Davey, Nicholas J Chandler, Assaf Elazar, Jonathan Y Weinstein, Julie V Nguyen, Raphael Trenker, Ryan S Cross, Misty R Jenkins, Melissa J Call, Matthew E Call, and Sarel J Fleishman

Published

2022

30. One-step sequence and structure-guided optimization of HIV-1 envelope gp140

Author

Adi Goldenzweig, Ishika Pramanick, Raghavan Varadarajan, Sarel J. Fleishman, Somnath Dutta, Malavika Abhineshababu Sridevi, Sameer Kumar Malladi, and David Schreiber

Subjects

Automated, Antigenicity, Immunogen, Chemistry, Protein design, Mutant, Wild type, Computational biology, Article, Epitope, Virus, lcsh:Biology (General), Structural Biology, Rosetta, Protein stability, Molecular Biology, Linker, Vaccine, lcsh:QH301-705.5, Sequence (medicine)

Abstract

Stabilization of the metastable envelope glycoprotein (Env) of HIV-1 is hypothesized to improve induction of broadly neutralizing antibodies. We improved the expression yield and stability of the HIV-1 envelope glycoprotein BG505SOSIP.664 gp140 by means of a previously described automated sequence and structure-guided computational thermostabilization approach, PROSS. This combines sequence conservation information with computational assessment of mutant stabilization, thus taking advantage of the extensive natural sequence variation present in HIV-1 Env. PROSS is used to design three gp140 variants with 17-45 mutations relative to the parental construct. One of the designs is experimentally observed to have a fourfold improvement in yield and a 4 °C increment in thermostability. In addition, the designed immunogens have similar antigenicity profiles to the native flexible linker version of wild type, BG505SOSIP.664 gp140 (NFL Wt) to major epitopes targeted by broadly neutralizing antibodies. PROSS eliminates the laborious process of screening many variants for stability and functionality, providing a proof of principle of the method for stabilization and improvement of yield without compromising antigenicity for next generation complex, highly glycosylated vaccine candidates.

Published

2020

31. Stable and Functionally Diverse Versatile Peroxidases Designed Directly from Sequences

Author

Shiran Barber-Zucker, Vladimir Mindel, Eva Garcia-Ruiz, Jonathan J. Weinstein, Miguel Alcalde, and Sarel J. Fleishman

Subjects

Colloid and Surface Chemistry, Peroxidases, Basidiomycota, Reproducibility of Results, General Chemistry, Biochemistry, Lignin, Catalysis

Abstract

White-rot fungi secrete a repertoire of high-redox potential oxidoreductases to efficiently decompose lignin. Of these enzymes, versatile peroxidases (VPs) are the most promiscuous biocatalysts. VPs are attractive enzymes for research and industrial use but their recombinant production is extremely challenging. To date, only a single VP has been structurally characterized and optimized for recombinant functional expression, stability, and activity. Computational enzyme optimization methods can be applied to many enzymes in parallel but they require accurate structures. Here, we demonstrate that model structures computed by deep-learning-based

Published

2022

32. De novo-designed transmembrane domains tune engineered receptor functions

Author

Ashleigh S Davey, Nicholas J Chandler, Assaf Elazar, Jonathan Y Weinstein, Julie V Nguyen, Raphael Trenker, Ryan S Cross, Misty R Jenkins, Melissa J Call, Matthew E Call, and Sarel J Fleishman

Subjects

60199 Biochemistry and Cell Biology not elsewhere classified, Receptors, Chimeric Antigen, General Immunology and Microbiology, T-Lymphocytes, General Neuroscience, Receptors, Antigen, T-Cell, General Medicine, Xenograft Model Antitumor Assays, General Biochemistry, Genetics and Molecular Biology, Mice, CD28 Antigens, Protein Domains, FOS: Biological sciences, Animals, Cytokines

Abstract

De novo-designed receptor transmembrane domains (TMDs) present opportunities for precise control of cellular receptor functions. We developed a de novo design strategy for generating programmed membrane proteins (proMPs): single-pass α-helical TMDs that self-assemble through computationally defined and crystallographically validated interfaces. We used these proMPs to program specific oligomeric interactions into a chimeric antigen receptor (CAR) that we expressed in mouse primary T cells and found that both in vitro CAR T cell cytokine release and in vivo antitumor activity scaled linearly with the oligomeric state encoded by the receptor TMD, from monomers up to tetramers. All programmed CARs stimulated substantially lower T cell cytokine release relative to the commonly used CD28 TMD, which we show elevated cytokine release through lateral recruitment of the endogenous T cell costimulatory receptor CD28. Precise design using orthogonal and modular TMDs thus provides a new way to program receptor structure and predictably tune activity for basic or applied synthetic biology.

Published

2022

33. Enhancing the Thermal and Kinetic Stability of Ketol-Acid Reductoisomerase, a Central Catalyst of a Cell-Free Enzyme Cascade for the Manufacture of Platform Chemicals

Author

You Lv, Shan Zheng, Adi Goldenzweig, Fengjiang Liu, Yan Gao, Xiuna Yang, Ajit Kandale, Ross P. McGeary, Simon Williams, Bostjan Kobe, Mark A. Schembri, Michael J. Landsberg, Bin Wu, Thomas B. Brück, Volker Sieber, Mikael Boden, Zihe Rao, Sarel J. Fleishman, Gerhard Schenk, and Luke W. Guddat

Subjects

cell-free enzyme cascades, biomanufacturing, enzyme stability, protein design, PROSS, branched chain amino acid biosynthesis, ketol-acid reductoisomerase, Article, ddc

Abstract

The branched-chain amino acids (BCAAs) leucine, isoleucine and valine are synthesized via a common biosynthetic pathway. Ketol-acid reductoisomerase (KARI) is the second enzyme in this pathway. In addition to its role in BCAA biosynthesis, KARI catalyzes two rate-limiting steps that are key components of a cell-free biofuel biosynthesis route. For industrial applications, reaction temperature and enzyme stability are key factors that affect process robustness and product yield. Here, we have solved the cryo-EM structure (2.94 Å resolution) of a homododecameric Class I KARI (from Campylobacter jejuni) and demonstrated how a triad of amino acid side chains plays a crucial role in promoting the oligomerization of this enzyme. Importantly, both its thermal and solvent stability are greatly enhanced in the dodecameric state when compared to its dimeric counterpart (apparent melting temperatures (Tm) of 83.1 °C and 51.5 °C, respectively). We also employed protein design (PROSS) for a tetrameric Class II KARI (from Escherichia coli) to generate a variant with improved thermal and solvent stabilities. In total, 34 mutations were introduced, which did not affect the oligomeric state of this enzyme but resulted in a fully functional catalyst with a significantly elevated Tm (58.5 °C vs. 47.9 °C for the native version).

Published

2021

34. Stable and functionally diverse versatile peroxidases by computational design directly from sequence

Author

Miguel Alcalde, Sarel J. Fleishman, Eva Garcia-Ruiz, Jonathan Jacob Weinstein, Vladimir Mindel, and Shiran Barber-Zucker

Subjects

chemistry.chemical_classification, biology, Wild type, Sequence (biology), Computational biology, Yeast, law.invention, Enzyme, chemistry, Functional expression, law, Recombinant DNA, biology.protein, Computational design, Peroxidase

Abstract

White-rot fungi secrete a repertoire of high-redox potential oxidoreductases to efficiently decompose lignin. Of these enzymes, versatile peroxidases (VPs) are the most promiscuous biocatalysts. VPs are attractive enzymes for research and industrial use, but their recombinant production is extremely challenging. To date, only a single VP has been structurally characterized and optimized for recombinant functional expression, stability and activity. Computational enzyme optimization methods can be applied to many enzymes in parallel, but they require accurate structures. Here, we demonstrate that model structures computed by deep-learning based ab initio structure prediction methods are reliable starting points for one-shot PROSS stability-design calculations. Four designed VPs encoding as many as 43 mutations relative to the wild type enzymes are functionally expressed in yeast whereas their wild type parents are not. Three of these designs exhibit substantial and useful diversity in reactivity profile and tolerance to environmental conditions. The reliability of the new generation of structure predictors and design methods increases the scale and scope of computational enzyme optimization, enabling efficient discovery and exploitation of the functional diversity in natural enzyme families.

Published

2021

35. Isolation and characterization of a highly specific monoclonal antibody targeting the botulinum neurotoxin type E exposed SNAP-25 neoepitope

Author

Ron Alcalay, Meni Girshengorn, Eyal Epstein, Eran Diamant, Lilach Levin, Amram Torgeman, Ada Barnea, Ran Zichel, Eyal Dor, Alon Ben-David, Ariel Tennenhouse, Ohad Mazor, Sarel J. Fleishman, and Adva Mechaly

Subjects

biology, Toxin, medicine.drug_class, Chemistry, medicine.disease_cause, Immunoglobulin light chain, Monoclonal antibody, Cross-reactivity, Molecular biology, In vitro, Polyclonal antibodies, medicine, biology.protein, Antibody, Antitoxin

Abstract

Botulinum neurotoxin type E (BoNT/E), the fastest acting toxin of all BoNTs, cleaves the 25 kDa synaptosomal associated protein (SNAP-25) in motor neurons, leading to flaccid paralysis. Specific detection and quantification of BoNT/E-cleaved SNAP-25 neoepitope is essential for diagnosis of BoNT/E intoxication as well as for characterization of anti-BoNT/E antibody preparations. In order to isolate highly specific monoclonal antibodies suitable for in vitro immuno-detection of the exposed neoepitope, mice and rabbits were immunized with an eight amino acid peptide composed of the C-terminus of the cleaved SNAP-25. Immunized rabbits developed a specific and robust polyclonal antibody response, whereas immunized mice mostly demonstrated a weak antibody response that could not discriminate between the two forms of SNAP-25. An immune scFv phage-display library was constructed from the immunized rabbits and a panel of antibodies was isolated. Sequence alignment of the isolated clones revealed high similarity between both heavy and light chains, with exceptionally short HCDR3 sequences. A chimeric scFv-Fc antibody was further expressed and characterized, exhibiting a selective, ultra-high affinity (pM) towards the SNAP-25 neoepitope. Moreover, this antibody enabled sensitive detection of the cleaved SNAP-25 in BoNT/E treated SiMa cells with no cross reactivity with the intact SNAP-25. This novel antibody can be further used to develop an in vitro cell-based assay to diagnose BoNT/E intoxication and to characterize antitoxin preparations, thus eliminating the use of animals in the standard mouse bioassay.

Published

2021

36. The neutralization potency of anti-SARS-CoV-2 therapeutic human monoclonal antibodies is retained against novel viral variants

Author

Efi Makdasi, Anat Zvi, Ron Alcalay, Tal Noy-Porat, Eldar Peretz, Adva Mechaly, Yinon Levy, Eyal Epstein, Theodor Chitlaru, Ariel Tennenhouse, Moshe Aftalion, David Gur, Nir Paran, Hadas Tamir, Oren Zimhony, Shay Weiss, Michal Mandelboim, Ella Mendelson, Neta Zuckerman, Ital Nemet, Limor Kliker, Shmuel Yitzhaki, Shmuel C. Shapira, Tomer Israely, Sarel J. Fleishman, Ohad Mazor, and Ronit Rosenfeld

Subjects

chemistry.chemical_classification, medicine.drug_class, Biology, Monoclonal antibody, Virology, Epitope, Virus, Neutralization, In vitro, chemistry, medicine, biology.protein, Potency, Antibody, Glycoprotein

Abstract

SummaryA wide range of SARS-CoV-2 neutralizing monoclonal antibodies (mAbs) were reported to date, most of which target the spike glycoprotein and in particular its receptor binding domain (RBD) and N-terminal domain (NTD) of the S1 subunit. The therapeutic implementation of these antibodies has been recently challenged by emerging SARS-CoV-2 variants that harbor extensively mutated spike versions. Consequently, the re-assessment of mAbs, previously reported to neutralize the original early-version of the virus, is of high priority.Four previously selected mAbs targeting non-overlapping epitopes, were evaluated for their binding potency to RBD versions harboring individual mutations at spike positions 417, 439, 453, 477, 484 and 501. Mutations at these positions represent the prevailing worldwide distributed modifications of the RBD, previously reported to mediate escape from antibody neutralization. Additionally, the in vitro neutralization potencies of the four RBD-specific mAbs, as well as two NTD-specific mAbs, were evaluated against two frequent SARS-CoV-2 variants of concern (VOCs): (i) the B.1.1.7 variant, emerged in the UK and (ii) the B.1.351 variant, emerged in South Africa. Variant B.1.351 was previously suggested to escape many therapeutic mAbs, including those authorized for clinical use. The possible impact of RBD mutations on recognition by mAbs is addressed by comparative structural modelling. Finally, we demonstrate the therapeutic potential of three selected mAbs by treatment of K18-hACE2 transgenic mice two days post infection with each of the virus strains.Our results clearly indicate that despite the accumulation of spike mutations, some neutralizing mAbs preserve their potency against SARS-CoV-2. In particular, the highly potent MD65 and BL6 mAbs are shown to retain their ability to bind the prevalent novel viral mutations and to effectively protect against B.1.1.7 and B.1.351 variants of high clinical concern.

Published

2021

37. Computationally designed pyocyanin demethylase acts synergistically with tobramycin to kill recalcitrant

Author

Chelsey M, VanDrisse, Rosalie, Lipsh-Sokolik, Olga, Khersonsky, Sarel J, Fleishman, and Dianne K, Newman

Subjects

Biofilms, Drug Design, Pseudomonas aeruginosa, Pyocyanine, Tobramycin, Humans, Drug Synergism, Oxidoreductases, N-Demethylating, Biological Sciences, Protein Engineering

Abstract

Pseudomonas aeruginosa is an opportunistic human pathogen that develops difficult-to-treat biofilms in immunocompromised individuals, cystic fibrosis patients, and in chronic wounds. P. aeruginosa has an arsenal of physiological attributes that enable it to evade standard antibiotic treatments, particularly in the context of biofilms where it grows slowly and becomes tolerant to many drugs. One of its survival strategies involves the production of the redox-active phenazine, pyocyanin, which promotes biofilm development. We previously identified an enzyme, PodA, that demethylated pyocyanin and disrupted P. aeruginosa biofilm development in vitro. Here, we asked if this protein could be used as a potential therapeutic for P. aeruginosa infections together with tobramycin, an antibiotic typically used in the clinic. A major roadblock to answering this question was the poor yield and stability of wild-type PodA purified from standard Escherichia coli overexpression systems. We hypothesized that the insufficient yields were due to poor packing within PodA’s obligatory homotrimeric interfaces. We therefore applied the protein design algorithm, AffiLib, to optimize the symmetric core of this interface, resulting in a design that incorporated five mutations leading to a 20-fold increase in protein yield from heterologous expression and purification and a substantial increase in stability to environmental conditions. The addition of the designed PodA with tobramycin led to increased killing of P. aeruginosa cultures under oxic and hypoxic conditions in both the planktonic and biofilm states. This study highlights the potential for targeting extracellular metabolites to assist the control of P. aeruginosa biofilms that tolerate conventional antibiotic treatment.

Published

2021

38. Biomolecular recognition of the glycan neoantigen CA19-9 by distinct antibodies

Author

Nova Tasnima, Hai Yu, Xi Chen, Ron Diskin, Shira Warszawski, Aliza Borenstein-Katz, Ron Amon, Vered Padler-Karavani, and Sarel J. Fleishman

Subjects

chemistry.chemical_classification, Glycan, Glycolipid, biology, Biochemistry, Antigen, Chemistry, biology.protein, Antibody, Antigen binding, Glycoprotein, Carbohydrate antigen

Abstract

Glycans decorate cell surface, secreted glycoproteins and glycolipids. Altered glycans are often found in cancers. Despite their high diagnostic and therapeutic potentials, glycans are polar and flexible molecules that are quite challenging for the development and design of high-affinity binding antibodies. To understand the mechanisms by which glycan neoantigens are specifically recognized by antibodies, we analyze the biomolecular recognition of a single tumor-associated carbohydrate antigen CA19-9 by two distinct antibodies using X-ray crystallography. Despite the plasticity of glycans and the very different antigen-binding surfaces presented by the antibodies, both structures reveal an essentially identical extended CA19-9 conformer, suggesting that this conformer’s stability selects the antibodies. Starting from the bound structure of one of the antibodies, we use the AbLIFT computational method to design a variant with seven core mutations that exhibited tenfold improved affinity for CA19-9. The results reveal strategies used by antibodies to specifically recognize glycan antigens and show how automated antibody-optimization methods may be used to enhance the clinical potential of existing antibodies.

Published

2021

39. Computationally designed pyocyanin demethylase acts synergistically with tobramycin to kill recalcitrant Pseudomonas aeruginosa biofilms

Author

Rosalie Lipsh-Sokolik, Olga Khersonsky, Sarel J. Fleishman, Chelsey M VanDrisse, and Dianne K. Newman

Subjects

0303 health sciences, Multidisciplinary, Multidrug tolerance, 030306 microbiology, Pseudomonas aeruginosa, Chemistry, Biofilm, Context (language use), Human pathogen, medicine.disease_cause, 3. Good health, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Pyocyanin, medicine, Tobramycin, Escherichia coli, 030304 developmental biology, medicine.drug

Abstract

Pseudomonas aeruginosa is an opportunistic human pathogen that develops difficult-to-treat biofilms in immunocompromised individuals, cystic fibrosis patients, and in chronic wounds. P. aeruginosa has an arsenal of physiological attributes that enable it to evade standard antibiotic treatments, particularly in the context of biofilms where it grows slowly and becomes tolerant to many drugs. One of its survival strategies involves the production of the redox-active phenazine, pyocyanin, which promotes biofilm development. We previously identified an enzyme, PodA, that demethylated pyocyanin and disrupted P. aeruginosa biofilm development in vitro. Here, we asked if this protein could be used as a potential therapeutic for P. aeruginosa infections together with tobramycin, an antibiotic typically used in the clinic. A major roadblock to answering this question was the poor yield and stability of wild-type PodA purified from standard Escherichia coli overexpression systems. We hypothesized that the insufficient yields were due to poor packing within PodA’s obligatory homotrimeric interfaces. We therefore applied the protein design algorithm, AffiLib, to optimize the symmetric core of this interface, resulting in a design that incorporated five mutations leading to a 20-fold increase in protein yield from heterologous expression and purification and a substantial increase in stability to environmental conditions. The addition of the designed PodA with tobramycin led to increased killing of P. aeruginosa cultures under oxic and hypoxic conditions in both the planktonic and biofilm states. This study highlights the potential for targeting extracellular metabolites to assist the control of P. aeruginosa biofilms that tolerate conventional antibiotic treatment.

Published

2021

40. Decision letter: Zinc shapes the folding landscape of p53 and establishes a pathway for reactivating structurally diverse cancer mutants

Author

Hua Lu and Sarel J. Fleishman

Subjects

Folding (chemistry), chemistry, Mutant, medicine, Cancer, chemistry.chemical_element, Computational biology, Zinc, medicine.disease

Published

2020

41. Coronacept – a potent immunoadhesin against SARS-CoV-2

Author

Ron Diskin, Sarel J. Fleishman, Maya Shemesh, Jonathan Weinstein, Michael Katz, Hadas Cohen-Dvashi, Maayan Eilon, Romano Strobelt, Yuval Mor, and Amir Shimon

Subjects

chemistry.chemical_classification, biology, viruses, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Cellular receptor, Virology, Enzyme, chemistry, Viral Receptor, biology.protein, Computational analysis, Antibody, hormones, hormone substitutes, and hormone antagonists, Binding domain

Abstract

Angiotensin-converting enzyme 2 (ACE2) is the cellular receptor for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Computational analysis of mammalian ACE2 orthologues suggests various residues at the interface with the viral receptor binding domain that could facilitate tighter interaction compared to the human-ACE2. Introducing several mutations to the human-ACE2 resulted with significantly augmented affinity to the viral spike complex. This modified human-ACE2 fused to an Fc portion of an antibody makes a potent immunoadhesin that effectively targets SARS-CoV-2.

Published

2020

42. De novo designed transmembrane domains tune engineered receptor functions

Author

Ashleigh S Davey, Sarel J. Fleishman, Jonathan Weinstein, Melissa J. Call, Raphael Trenker, Ryan S. Cross, Nicholas J. Chandler, Matthew E. Call, Julie V. Nguyen, Misty R. Jenkins, and Assaf Elazar

Subjects

Transmembrane domain, Synthetic biology, Cytokine, medicine.anatomical_structure, Membrane protein, Chemistry, medicine.medical_treatment, T cell, medicine, CD28, Receptor, Chimeric antigen receptor, Cell biology

Abstract

De novo designed receptor transmembrane domains (TMDs) present opportunities for precise control of cellular receptor functions. We developed a de novo design strategy for generating programmed membrane proteins (proMPs): single-pass α-helical TMDs that self-assemble through computationally defined and crystallographically validated interfaces. We used these proMPs to program specific oligomeric interactions into a chimeric antigen receptor (CAR) and found that both in vitro CAR T cell cytokine release and in vivo antitumor activity scaled linearly with the oligomeric state encoded by the receptor TMD, from monomers up to tetramers. All programmed CARs (proCARs) stimulated substantially lower T cell cytokine release relative to the commonly used CD28 TMD, which we show elevated cytokine release through lateral recruitment of the endogenous T cell costimulatory receptor CD28. Precise design using orthogonal and modular TMDs thus provides a new way to program receptor structure and predictably tune activity for basic or applied synthetic biology.

Published

2020

43. Decision letter: Multiplexed measurement of variant abundance and activity reveals VKOR topology, active site and human variant impact

Author

Weikai Li and Sarel J. Fleishman

Subjects

Physics, biology, Abundance (ecology), biology.protein, Active site, Topology, Multiplexing, Topology (chemistry)

Published

2020

44. Practically useful protein-design methods combining phylogenetic and atomistic calculations

Author

Jonathan Weinstein, Sarel J. Fleishman, and Olga Khersonsky

Subjects

Models, Molecular, Computer science, Protein Conformation, Protein design, Computational biology, Ligands, Protein Engineering, Article, 03 medical and health sciences, Automation, Structure-Activity Relationship, 0302 clinical medicine, Protein stability, Structural Biology, Computational design, Amino Acid Sequence, Molecular Biology, Phylogeny, 030304 developmental biology, 0303 health sciences, Phylogenetic tree, Scope (project management), Computational Biology, Proteins, Mutagenesis, Epistasis, 030217 neurology & neurosurgery, Large size, Protein Binding

Abstract

Our ability to design new or improved biomolecular activities depends on understanding the sequence-function relationships in proteins. The large size and fold complexity of most proteins, however, obscures these relationships, and protein-optimization methods continue to rely on laborious experimental iterations. Recently, a deeper understanding of the roles of stability-threshold effects and biomolecular epistasis in proteins has led to the development of hybrid methods that combine phylogenetic analysis with atomistic design calculations. These methods enable reliable and even single-step optimization of protein stability, expressibility, and activity in proteins that were considered outside the scope of computational design. Furthermore, ancestral-sequence reconstruction produces insights on missing links in the evolution of enzymes and binders that may be used in protein design. Through the combination of phylogenetic and atomistic calculations, the long-standing goal of general computational methods that can be universally applied to study and optimize proteins finally seems within reach.

Published

2020

45. Decision letter: Altered expression of a quality control protease in E. coli reshapes the in vivo mutational landscape of a model enzyme

Author

Sarel J. Fleishman

Subjects

chemistry.chemical_classification, Protease, Enzyme, chemistry, In vivo, medicine.medical_treatment, medicine, Biology, Cell biology

Published

2019

46. Principles of Protein Stability and Their Application in Computational Design

Author

Sarel J. Fleishman and Adi Goldenzweig

Subjects

Models, Molecular, 0301 basic medicine, Protein Folding, Computer science, Protein design, Stability (learning theory), Protein Engineering, Biochemistry, Protein Aggregates, 03 medical and health sciences, Protein stability, Animals, Humans, Computational design, Thermal stability, Design methods, Phylogeny, Protein Stability, Proteins, 030104 developmental biology, Proteostasis, Drug Design, Thermodynamics, Biochemical engineering, Directed Molecular Evolution, Marginal stability

Abstract

Proteins are increasingly used in basic and applied biomedical research. Many proteins, however, are only marginally stable and can be expressed in limited amounts, thus hampering research and applications. Research has revealed the thermodynamic, cellular, and evolutionary principles and mechanisms that underlie marginal stability. With this growing understanding, computational stability design methods have advanced over the past two decades starting from methods that selectively addressed only some aspects of marginal stability. Current methods are more general and, by combining phylogenetic analysis with atomistic design, have shown drastic improvements in solubility, thermal stability, and aggregation resistance while maintaining the protein's primary molecular activity. Stability design is opening the way to rational engineering of improved enzymes, therapeutics, and vaccines and to the application of protein design methodology to large proteins and molecular activities that have proven challenging in the past.

Published

2018

47. Extending the New Generation of Structure Predictors to Account for Dynamics and Allostery

Author

Sarel J. Fleishman and Amnon Horovitz

Subjects

Models, Molecular, Structure (mathematical logic), 0303 health sciences, Protein Conformation, Computer science, Protein dynamics, Proteins, Contact map, Computational biology, Static structure, Homologous Sequences, 03 medical and health sciences, Deep Learning, 0302 clinical medicine, Allosteric Regulation, Sequence Analysis, Protein, Structural Biology, Dynamics (music), Animals, Humans, Protein activity, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Recent progress in structure-prediction methods that rely on deep learning suggests that the atomic structure of almost any protein may soon be predictable directly from its amino acid sequence. This much-awaited revolution was driven by substantial improvements in the reliability of methods for inferring the spatial distances between amino acid pairs from an analysis of homologous sequences. Improved reliability has been accompanied, however, by a reduced ability to detect amino acid relationships that are not due to direct spatial contacts, such as those that arise from protein dynamics or allostery. Given the central importance of dynamics and allostery to protein activity, we argue that an important future advance would extend modeling beyond predicting a single static structure. Here, we briefly review some of the developments that have led to the remarkable recent achievement in structure prediction and speculate what methods and sources of information may be leveraged in the future to develop a modeling framework that addresses protein dynamics and allostery.

Published

2021

48. Direct‐MS analysis of antibody‐antigen complexes

Author

Gili Ben-Nissan, Michal Sharon, Sarel J. Fleishman, Shay Vimer, and Michael T. Marty

Subjects

Chemistry, Quality assessment, Ms analysis, Computational biology, Biochemistry, Antibodies, Mass Spectrometry, Article, Protein stability, Biopharmaceutical industry, Antigen, Antibody antigen, Antigens, Molecular Biology

Abstract

In recent decades, antibodies (Abs) have attracted the attention of academia and the biopharmaceutical industry due to their therapeutic properties and versatility in binding a vast spectrum of antigens. Different engineering strategies have been developed for optimizing Ab specificity, efficacy, affinity, stability and production, enabling systematic screening and analysis procedures for selecting lead candidates. This quality assessment is critical but usually demands time-consuming and labor-intensive purification procedures. Here, we harnessed the direct-mass spectrometry (direct-MS) approach, in which the analysis is carried out directly from the crude growth media, for the rapid, structural characterization of designed Abs. We demonstrate that properties such as stability, specificity and interactions with antigens can be defined, without the need for prior purification. This ty.

Published

2021

49. Biomolecular Recognition of the Glycan Neoantigen CA19-9 by Distinct Antibodies

Author

Ron Amon, Shani Leviatan Ben-Arye, Hai Yu, Sarel J. Fleishman, Nova Tasnima, Maayan Eilon, Shira Warszawski, Aliza Borenstein-Katz, Vered Padler-Karavani, Ron Diskin, Hadas Cohen-Dvashi, and Xi Chen

Subjects

Models, Molecular, Protein Conformation, design, Antibody Affinity, Computational algorithm, Crystallography, X-Ray, Mice, 0302 clinical medicine, Models, Structural Biology, Monoclonal, Cancer, chemistry.chemical_classification, 0303 health sciences, Crystallography, biology, Antibodies, Monoclonal, CA19-9, Antigen binding, 3. Good health, Antibody, Carbohydrate antigen, Algorithms, Biochemistry & Molecular Biology, Glycan, CA-19-9 Antigen, Computational biology, Microbiology, Antibodies, Article, Medicinal and Biomolecular Chemistry, 03 medical and health sciences, Glycolipid, Antigen, Animals, Humans, structure, Molecular Biology, 030304 developmental biology, Prevention, Molecular, Computational Biology, chemistry, Mutation, X-Ray, biology.protein, glycans, Biochemistry and Cell Biology, Glycoprotein, 030217 neurology & neurosurgery

Abstract

Glycans decorate the cell surface, secreted glycoproteins and glycolipids, and altered glycans are often found in cancers. Despite their high diagnostic and therapeutic potential, however, glycans are polar and flexible molecules that are quite challenging for the development and design of high-affinity binding antibodies. To understand the mechanisms by which glycan neoantigens are specifically recognized by antibodies, we analyze the biomolecular recognition of the tumor-associated carbohydrate antigen CA19-9 by two distinct antibodies using X-ray crystallography. Despite the potential plasticity of glycans and the very different antigen-binding surfaces presented by the antibodies, both structures reveal an essentially identical extended CA19-9 conformer, suggesting that this conformer's stability selects the antibodies. Starting from the bound structure of one of the antibodies, we use the AbLIFT computational algorithm to design a variant with seven core mutations in the variable domain's light-heavy chain interface that exhibits tenfold improved affinity for CA19-9. The results reveal strategies used by antibodies to specifically recognize glycan antigens and show how automated antibody-optimization methods may be used to enhance the clinical potential of existing antibodies.

Published

2021

50. Incorporating an allosteric regulatory site in an antibody through backbone design

Author

Sarel J. Fleishman and Olga Khersonsky

Subjects

0301 basic medicine, chemistry.chemical_classification, biology, Chemistry, Stereochemistry, Protein design, Allosteric regulation, Regulatory site, Protein engineering, 010402 general chemistry, Ligand (biochemistry), 01 natural sciences, Biochemistry, DNA-binding protein, 0104 chemical sciences, Divalent, 03 medical and health sciences, 030104 developmental biology, Allosteric enzyme, biology.protein, Molecular Biology

Abstract

Allosteric regulation underlies living cells' ability to sense changes in nutrient and signaling-molecule concentrations, but the ability to computationally design allosteric regulation into non-allosteric proteins has been elusive. Allosteric-site design is complicated by the requirement to encode the relative stabilities of active and inactive conformations of the same protein in the presence and absence of both ligand and effector. To address this challenge, we used Rosetta to design the backbone of the flexible heavy-chain complementarity-determining region 3 (HCDR3), and used geometric matching and sequence optimization to place a Zn2+ -coordination site in a fluorescein-binding antibody. We predicted that due to HCDR3's flexibility, the fluorescein-binding pocket would configure properly only upon Zn2+ application. We found that regulation by Zn2+ was reversible and sensitive to the divalent ion's identity, and came at the cost of reduced antibody stability and fluorescein-binding affinity. Fluorescein bound at an order of magnitude higher affinity in the presence of Zn2+ than in its absence, and the increase in fluorescein affinity was due almost entirely to faster fluorescein on-rate, suggesting that Zn2+ preorganized the antibody for fluorescein binding. Mutation analysis demonstrated the extreme sensitivity of Zn2+ regulation on the atomic details in and around the metal-coordination site. The designed antibody could serve to study how allosteric regulation evolved from non-allosteric binding proteins, and suggests a way to designing molecular sensors for environmental and biomedical targets.

Published

2017