Your search keyword '"Samer Halabiya"' showing total 8 results

1. 1198 Cytokine affinity tuning and antibody discovery/optimization using the AlphaSeq and AlphaBind platforms to generate targeted immuno-oncology therapeutics

Author

Ryan Swanson, John Marken, Davis Goodnight, Kimberly Wellman, Jeff Adamo, Emily Engelhart, Oliver Serang, Aditya Agarwal, Cameron Cordray, Samer Halabiya, Kyle Minch, and Randolph Lopez

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

2. De novo design of luciferases using deep learning

Author

Andy Hsien-Wei Yeh, Christoffer Norn, Yakov Kipnis, Doug Tischer, Samuel J. Pellock, Declan Evans, Pengchen Ma, Gyu Rie Lee, Jason Z. Zhang, Ivan Anishchenko, Brian Coventry, Longxing Cao, Justas Dauparas, Samer Halabiya, Michelle DeWitt, Lauren Carter, K. N. Houk, and David Baker

Subjects

Luminescence, Hot Temperature, Multidisciplinary, General Science & Technology, Substrate Specificity, Deep Learning, Catalytic Domain, Enzyme Stability, Luciferins, Biocatalysis, Generic health relevance, Luciferases, Oxidation-Reduction, Biotechnology

Abstract

De novo enzyme design has sought to introduce active sites and substrate-binding pockets that are predicted to catalyse a reaction of interest into geometrically compatible native scaffolds1,2, but has been limited by a lack of suitable protein structures and the complexity of native protein sequence–structure relationships. Here we describe a deep-learning-based ‘family-wide hallucination’ approach that generates large numbers of idealized protein structures containing diverse pocket shapes and designed sequences that encode them. We use these scaffolds to design artificial luciferases that selectively catalyse the oxidative chemiluminescence of the synthetic luciferin substrates diphenylterazine3 and 2-deoxycoelenterazine. The designed active sites position an arginine guanidinium group adjacent to an anion that develops during the reaction in a binding pocket with high shape complementarity. For both luciferin substrates, we obtain designed luciferases with high selectivity; the most active of these is a small (13.9 kDa) and thermostable (with a melting temperature higher than 95 °C) enzyme that has a catalytic efficiency on diphenylterazine (kcat/Km = 106 M−1 s−1) comparable to that of native luciferases, but a much higher substrate specificity. The creation of highly active and specific biocatalysts from scratch with broad applications in biomedicine is a key milestone for computational enzyme design, and our approach should enable generation of a wide range of luciferases and other enzymes.

Published

2023

3. Design of protein-binding proteins from the target structure alone

Author

Longxing Cao, Brian Coventry, Inna Goreshnik, Buwei Huang, William Sheffler, Joon Sung Park, Kevin M. Jude, Iva Marković, Rameshwar U. Kadam, Koen H. G. Verschueren, Kenneth Verstraete, Scott Thomas Russell Walsh, Nathaniel Bennett, Ashish Phal, Aerin Yang, Lisa Kozodoy, Michelle DeWitt, Lora Picton, Lauren Miller, Eva-Maria Strauch, Nicholas D. DeBouver, Allison Pires, Asim K. Bera, Samer Halabiya, Bradley Hammerson, Wei Yang, Steffen Bernard, Lance Stewart, Ian A. Wilson, Hannele Ruohola-Baker, Joseph Schlessinger, Sangwon Lee, Savvas N. Savvides, K. Christopher Garcia, and David Baker

Subjects

RECEPTOR ECTODOMAIN, COMPLEX, Binding Sites, Multidisciplinary, COMPUTATIONAL DESIGN, HEMAGGLUTININ, NERVE GROWTH-FACTOR, Biology and Life Sciences, Proteins, MODEL, ANTIBODY, DOMAIN, Medicine and Health Sciences, STRUCTURE REFINEMENT, CRYSTAL-STRUCTURE, Amino Acids, Carrier Proteins, Protein Binding

Abstract

The design of proteins that bind to a specific site on the surface of a target protein using no information other than the three-dimensional structure of the target remains a challenge1–5. Here we describe a general solution to this problem that starts with a broad exploration of the vast space of possible binding modes to a selected region of a protein surface, and then intensifies the search in the vicinity of the most promising binding modes. We demonstrate the broad applicability of this approach through the de novo design of binding proteins to 12 diverse protein targets with different shapes and surface properties. Biophysical characterization shows that the binders, which are all smaller than 65 amino acids, are hyperstable and, following experimental optimization, bind their targets with nanomolar to picomolar affinities. We succeeded in solving crystal structures of five of the binder–target complexes, and all five closely match the corresponding computational design models. Experimental data on nearly half a million computational designs and hundreds of thousands of point mutants provide detailed feedback on the strengths and limitations of the method and of our current understanding of protein–protein interactions, and should guide improvements of both. Our approach enables the targeted design of binders to sites of interest on a wide variety of proteins for therapeutic and diagnostic applications.

Published

2022

4. Perturbing the energy landscape for improved packing during computational protein design

Author

David F Thieker, Eric Klavins, Surya V.S.R.K. Pulavarti, Frank DiMaio, Jermel R. Griffin, David Baker, Matthew Cummins, Thomas Szyperski, Hugh K. Haddox, Devin Strickland, Brian Coventry, Brian Kuhlman, Samer Halabiya, and Jack Maguire

Subjects

Protein Folding, Molecular model, Protein Conformation, Computer science, Protein design, Stability (learning theory), Protein Engineering, Energy minimization, Biochemistry, Article, 03 medical and health sciences, Protein structure, Structural Biology, Databases, Protein, Molecular Biology, Protocol (object-oriented programming), 030304 developmental biology, 0303 health sciences, Sequence, Protein Stability, 030302 biochemistry & molecular biology, Computational Biology, Proteins, Energy landscape, Biological system, Hydrophobic and Hydrophilic Interactions

Abstract

The FastDesign protocol in the molecular modeling program Rosetta iterates between sequence optimization and structure refinement to stabilize de novo designed protein structures and complexes. FastDesign has been used previously to design novel protein folds and assemblies with important applications in research and medicine. To promote sampling of alternative conformations and sequences, FastDesign includes stages where the energy landscape is smoothened by reducing repulsive forces. Here, we discover that this process disfavors larger amino acids in the protein core because the protein compresses in the early stages of refinement. By testing alternative ramping strategies for the repulsive weight, we arrive at a scheme that produces lower energy designs with more native-like sequence composition in the protein core. We further validate the protocol by designing and experimentally characterizing over 4000 proteins and show that the new protocol produces higher stability proteins. This article is protected by copyright. All rights reserved.

Published

2020

5. Robust de novo design of protein binding proteins from target structural information alone

Author

Iva Marković, Lisa Kozodoy, Wei Yang, K. Christopher Garcia, Joon Sung Park, K. Verschueren, Samer Halabiya, Lance Stewart, Ashish Phal, Lauren Miller, Rameshwar U. Kadam, Kevin Jude, Nathaniel Bennett, Savvas N. Savvides, Steffen Benard, Brian Coventry, Lora Picton, Aerin Yang, Inna Goreshnik, David Baker, Hannele Ruohola-Baker, Kenneth Verstraete, Joseph Schlessinger, Longxing Cao, Scott T. R. Walsh, Bradley Hammerson, Michelle DeWitt, Buwei Huang, Sangwon Lee, Eva-Maria Strauch, and Ian A. Wilson

Subjects

Computer science, Computational design, Plasma protein binding, Computational biology, Target protein, Affinities, DNA-binding protein

Abstract

The design of proteins that bind to a specific site on the surface of a target protein using no information other than the three-dimensional structure of the target remains an outstanding challenge. We describe a general solution to this problem which starts with a broad exploration of the very large space of possible binding modes and interactions, and then intensifies the search in the most promising regions. We demonstrate its very broad applicability by de novo design of binding proteins to 12 diverse protein targets with very different shapes and surface properties. Biophysical characterization shows that the binders, which are all smaller than 65 amino acids, are hyperstable and bind their targets with nanomolar to picomolar affinities. We succeeded in solving crystal structures of four of the binder-target complexes, and all four are very close to the corresponding computational design models. Experimental data on nearly half a million computational designs and hundreds of thousands of point mutants provide detailed feedback on the strengths and limitations of the method and of our current understanding of protein-protein interactions, and should guide improvement of both. Our approach now enables targeted design of binders to sites of interest on a wide variety of proteins for therapeutic and diagnostic applications.

Published

2021

6. Aquarium: open-source laboratory software for design, execution and data management

Author

Devin Strickland, Garrett Newman, Eriberto Lopez, Michelle Parks, Abraham Miller, Ayesha Saleem, Samer Halabiya, Justin D. Vrana, Yaoyu Yang, Benjamin J. Keller, Orlando de Lange, Eric Klavins, Sarah Goldberg, and Cameron Cordray

Subjects

AcademicSubjects/SCI00010, Computer science, Data management, Automatic identification and data capture, Biomedical Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Bioengineering, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Software, replicability, LIMS, Protocol (object-oriented programming), automation, 030304 developmental biology, 0303 health sciences, software, business.industry, Robotics, Agricultural and Biological Sciences (miscellaneous), Automation, Workflow, Scalability, Artificial intelligence, business, Software engineering, 030217 neurology & neurosurgery, Research Article, Biotechnology

Abstract

Automation has been shown to improve the replicability and scalability of biomedical and bioindustrial research. Although the work performed in many labs is repetitive and can be standardized, few academic labs can afford the time and money required to automate their workflows with robotics. We propose that human-in-the-loop automation can fill this critical gap. To this end, we present Aquarium, an open-source, web-based software application that integrates experimental design, inventory management, protocol execution and data capture. We provide a high-level view of how researchers can install Aquarium and use it in their own labs. We discuss the impacts of the Aquarium on working practices, use in biofoundries and opportunities it affords for collaboration and education in life science laboratory research and manufacture.

Published

2021

7. Author response for 'Perturbing the energy landscape for improved packing during computational protein design'

Author

Jermel R. Griffin, Samer Halabiya, Brian Coventry, Frank DiMaio, Hugh K. Haddox, Devin Strickland, S. Pulavarti, David Baker, Thomas Szyperski, Jack Maguire, Brian Kuhlman, Eric Klavins, Matthew Cummins, and David F Thieker

Subjects

Computer science, Protein design, Energy landscape, Biological system

Published

2020

8. Perturbing the energy landscape for improved packing during computational protein design

Author

Frank DiMaio, Brian Coventry, Samer Halabiya, Matthew Cummins, David Baker, Brian Kuhlman, Jack Maguire, David F Thieker, Devin Strickland, Eric Klavins, and Hugh K. Haddox

Subjects

Sequence, Protein structure, Molecular model, Computer science, Protein design, Sequence optimization, Stability (learning theory), Energy landscape, Biological system, Protocol (object-oriented programming)

Abstract

The FastDesign protocol in the molecular modeling program Rosetta iterates between sequence optimization and structure refinement to stabilize de novo designed protein structures and complexes. FastDesign has been used previously to design novel protein folds and assemblies with important applications in research and medicine. To promote sampling of alternative conformations and sequences, FastDesign includes stages where the energy landscape is smoothened by reducing repulsive forces. Here, we discover that this process disfavors larger amino acids in the protein core because the protein compresses in the early stages of refinement. By testing alternative ramping strategies for the repulsive weight, we arrive at a scheme that produces lower energy designs with more native-like sequence composition in the protein core. We further validate the protocol by designing and experimentally characterizing over 4000 proteins and show that the new protocol produces higher stability proteins.

Published

2020