Advances in protein structure prediction and design
Brian Kuhlman,Philip Bradley +1 more
TL;DR: Improvements in computational algorithms and technological advances have dramatically increased the accuracy and speed of protein structure modelling, providing novel opportunities for controlling protein function, with potential applications in biomedicine, industry and research.
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Abstract: The prediction of protein three-dimensional structure from amino acid sequence has been a grand challenge problem in computational biophysics for decades, owing to its intrinsic scientific interest and also to the many potential applications for robust protein structure prediction algorithms, from genome interpretation to protein function prediction. More recently, the inverse problem - designing an amino acid sequence that will fold into a specified three-dimensional structure - has attracted growing attention as a potential route to the rational engineering of proteins with functions useful in biotechnology and medicine. Methods for the prediction and design of protein structures have advanced dramatically in the past decade. Increases in computing power and the rapid growth in protein sequence and structure databases have fuelled the development of new data-intensive and computationally demanding approaches for structure prediction. New algorithms for designing protein folds and protein-protein interfaces have been used to engineer novel high-order assemblies and to design from scratch fluorescent proteins with novel or enhanced properties, as well as signalling proteins with therapeutic potential. In this Review, we describe current approaches for protein structure prediction and design and highlight a selection of the successful applications they have enabled.
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Citations
Highly accurate protein structure prediction with AlphaFold
John M. Jumper,Richard O. Evans,Alexander Pritzel,Tim Green,Michael Figurnov,Olaf Ronneberger,Kathryn Tunyasuvunakool,Russell Bates,Augustin Žídek,Anna Potapenko,Alex Bridgland,Clemens Meyer,Simon A. A. Kohl,Andrew J. Ballard,Andrew Cowie,Bernardino Romera-Paredes,Stanislav Nikolov,R. D. Jain,Jonas Adler,Trevor Back,Stig Petersen,David Reiman,Ellen Clancy,Michal Zielinski,Martin Steinegger,Michalina Pacholska,Tamas Berghammer,Sebastian Bodenstein,David L. Silver,Oriol Vinyals,Andrew W. Senior,Koray Kavukcuoglu,Pushmeet Kohli,Demis Hassabis +33 more
TL;DR: For example, AlphaFold as mentioned in this paper predicts protein structures with an accuracy competitive with experimental structures in the majority of cases using a novel deep learning architecture. But the accuracy is limited by the fact that no homologous structure is available.
Highly accurate protein structure prediction for the human proteome
Kathryn Tunyasuvunakool,Jonas Adler,Zachary Wu,Tim Green,Michal Zielinski,Augustin Žídek,Alex Bridgland,Andrew Cowie,Clemens Meyer,Agata Laydon,Sameer Velankar,Gerard J. Kleywegt,Alex Bateman,Richard Evans,Alexander Pritzel,Michael Figurnov,Olaf Ronneberger,Russell Bates,Simon A. A. Kohl,Anna Potapenko,Andrew J. Ballard,Bernardino Romera-Paredes,Stanislav Nikolov,R. D. Jain,Ellen Clancy,David Reiman,Stig Petersen,Andrew W. Senior,Koray Kavukcuoglu,Ewan Birney,Pushmeet Kohli,John M. Jumper,Demis Hassabis +32 more
TL;DR: The AlphaFold2 dataset as discussed by the authors is a large-scale and high-accuracy structure prediction dataset for protein structures, which is used to evaluate the structural properties of proteins.
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Funnels, Pathways and the Energy Landscape of Protein Folding: A Synthesis
TL;DR: In this paper, the authors use the energy landscape approach to understand the structure of protein foldings and the mechanism of protein folding, and the success of energy landscape ideas in protein structure prediction.
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Deciphering cell-cell interactions and communication from gene expression.
TL;DR: This Review highlights discoveries enabled by analyses of cell–cell interactions from transcriptomic data and reviews the methods and tools used in this context.
Overcoming cancer therapeutic bottleneck by drug repurposing
TL;DR: This review presents various promising repurposed non-oncology drugs for clinical cancer management and classify these candidates into their proposed administration for either mono- or drug combination therapy.
References
Protein homology model refinement by large-scale energy optimization.
TL;DR: A large-scale energy optimization-based refinement method that incorporates advances in both search and energy function accuracy that can substantially improve the accuracy of low-resolution homology models is described.
PyIgClassify: a database of antibody CDR structural classifications
TL;DR: PyIgClassify is presented, a database and web server that provides access to assignments of all CDR structures in the PDB to the authors' classification system and is downloadable so that users may filter the data as needed for antibody structure analysis, prediction and design.
Structured States of Disordered Proteins from Genomic Sequences
Agnes Toth-Petroczy,Perry Palmedo,John Ingraham,Thomas A. Hopf,Bonnie Berger,Chris Sander,Debora S. Marks +6 more
TL;DR: Assessing the potential for structure of more than 1,000 apparently disordered regions of human proteins reveals a continuum of structural order with at least 50% with clear propensity for three- or two-dimensional states.
Computational Enzyme Design
Abstract: Recent developments in computational chemistry and biology have come together in the "inside-out" approach to enzyme engineering. Proteins have been designed to catalyze reactions not previously accelerated in nature. Some of these proteins fold and act as catalysts, but the success rate is still low. The achievements and limitations of the current technology are highlighted and contrasted to other protein engineering techniques. On its own, computational "inside-out" design can lead to the production of catalytically active and selective proteins, but their kinetic performances fall short of natural enzymes. When combined with directed evolution, molecular dynamics simulations, and crowd-sourced structure-prediction approaches, however, computational designs can be significantly improved in terms of binding, turnover, and thermal stability.
Protein coagulation and its reversal : the preparation of insoluble globin, soluble globin and heme.
M. L. Anson,Alfred E. Mirsky +1 more
TL;DR: The denatured globin may be largely converted into a soluble, apparently native form which can combine with heme to form hemoglobin, and the heme may be obtained in acetone-free, slightly alkaline solution without the use of strong alkali.
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