Your search keyword '"Cofsky, Joshua C."' showing total 14 results

1. CRISPR-Cas12a bends DNA to destabilize base pairs during target interrogation

Author

Soczek, Katarzyna M, Cofsky, Joshua C, Tuck, Owen T, Shi, Honglue, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Genetics, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Generic health relevance, Good Health and Well Being, CRISPR-Cas Systems, DNA, CRISPR-Associated Proteins, Base Pairing, RNA, Guide, CRISPR-Cas Systems, Nucleic Acid Conformation, Gene Editing, Cryoelectron Microscopy, Bacterial Proteins, Endodeoxyribonucleases, Models, Molecular, Nucleic Acid Hybridization, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences

Abstract

RNA-guided endonucleases are involved in processes ranging from adaptive immunity to site-specific transposition and have revolutionized genome editing. CRISPR-Cas9, -Cas12 and related proteins use guide RNAs to recognize ∼20-nucleotide target sites within genomic DNA by mechanisms that are not yet fully understood. We used structural and biochemical methods to assess early steps in DNA recognition by Cas12a protein-guide RNA complexes. We show here that Cas12a initiates DNA target recognition by bending DNA to induce transient nucleotide flipping that exposes nucleobases for DNA-RNA hybridization. Cryo-EM structural analysis of a trapped Cas12a-RNA-DNA surveillance complex and fluorescence-based conformational probing show that Cas12a-induced DNA helix destabilization enables target discovery and engagement. This mechanism of initial DNA interrogation resembles that of CRISPR-Cas9 despite distinct evolutionary origins and different RNA-DNA hybridization directionality of these enzyme families. Our findings support a model in which RNA-mediated DNA interference begins with local helix distortion by transient CRISPR-Cas protein binding.

Published

2025

2. CasPEDIA Database: a functional classification system for class 2 CRISPR-Cas enzymes

Author

Adler, Benjamin A, Trinidad, Marena I, Bellieny-Rabelo, Daniel, Zhang, Elaine, Karp, Hannah M, Skopintsev, Petr, Thornton, Brittney W, Weissman, Rachel F, Yoon, Peter H, Chen, LinXing, Hessler, Tomas, Eggers, Amy R, Colognori, David, Boger, Ron, Doherty, Erin E, Tsuchida, Connor A, Tran, Ryan V, Hofman, Laura, Shi, Honglue, Wasko, Kevin M, Zhou, Zehan, Xia, Chenglong, Al-Shimary, Muntathar J, Patel, Jaymin R, Thomas, Vienna CJX, Pattali, Rithu, Kan, Matthew J, Vardapetyan, Anna, Yang, Alana, Lahiri, Arushi, Maxwell, Micaela F, Murdock, Andrew G, Ramit, Glenn C, Henderson, Hope R, Calvert, Roland W, Bamert, Rebecca S, Knott, Gavin J, Lapinaite, Audrone, Pausch, Patrick, Cofsky, Joshua C, Sontheimer, Erik J, Wiedenheft, Blake, Fineran, Peter C, Brouns, Stan JJ, Sashital, Dipali G, Thomas, Brian C, Brown, Christopher T, Goltsman, Daniela SA, Barrangou, Rodolphe, Siksnys, Virginius, Banfield, Jillian F, Savage, David F, and Doudna, Jennifer A

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Biotechnology, Genetics, Generic health relevance, CRISPR-Cas Systems, Phylogeny, CRISPR-Associated Proteins, Databases, Genetic, Endodeoxyribonucleases, Encyclopedias as Topic, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences

Abstract

CRISPR-Cas enzymes enable RNA-guided bacterial immunity and are widely used for biotechnological applications including genome editing. In particular, the Class 2 CRISPR-associated enzymes (Cas9, Cas12 and Cas13 families), have been deployed for numerous research, clinical and agricultural applications. However, the immense genetic and biochemical diversity of these proteins in the public domain poses a barrier for researchers seeking to leverage their activities. We present CasPEDIA (http://caspedia.org), the Cas Protein Effector Database of Information and Assessment, a curated encyclopedia that integrates enzymatic classification for hundreds of different Cas enzymes across 27 phylogenetic groups spanning the Cas9, Cas12 and Cas13 families, as well as evolutionarily related IscB and TnpB proteins. All enzymes in CasPEDIA were annotated with a standard workflow based on their primary nuclease activity, target requirements and guide-RNA design constraints. Our functional classification scheme, CasID, is described alongside current phylogenetic classification, allowing users to search related orthologs by enzymatic function and sequence similarity. CasPEDIA is a comprehensive data portal that summarizes and contextualizes enzymatic properties of widely used Cas enzymes, equipping users with valuable resources to foster biotechnological development. CasPEDIA complements phylogenetic Cas nomenclature and enables researchers to leverage the multi-faceted nucleic-acid targeting rules of diverse Class 2 Cas enzymes.

Published

2024

3. CRISPR–Cas9 bends and twists DNA to read its sequence

Author

Cofsky, Joshua C, Soczek, Katarzyna M, Knott, Gavin J, Nogales, Eva, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Biotechnology, Genetics, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Generic health relevance, CRISPR-Cas Systems, DNA, Endonucleases, Gene Editing, RNA, Guide, CRISPR-Cas Systems, Chemical Sciences, Medical and Health Sciences, Biophysics, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences

Abstract

In bacterial defense and genome editing applications, the CRISPR-associated protein Cas9 searches millions of DNA base pairs to locate a 20-nucleotide, guide RNA-complementary target sequence that abuts a protospacer-adjacent motif (PAM). Target capture requires Cas9 to unwind DNA at candidate sequences using an unknown ATP-independent mechanism. Here we show that Cas9 sharply bends and undertwists DNA on PAM binding, thereby flipping DNA nucleotides out of the duplex and toward the guide RNA for sequence interrogation. Cryogenic-electron microscopy (cryo-EM) structures of Cas9-RNA-DNA complexes trapped at different states of the interrogation pathway, together with solution conformational probing, reveal that global protein rearrangement accompanies formation of an unstacked DNA hinge. Bend-induced base flipping explains how Cas9 'reads' snippets of DNA to locate target sites within a vast excess of nontarget DNA, a process crucial to both bacterial antiviral immunity and genome editing. This mechanism establishes a physical solution to the problem of complementarity-guided DNA search and shows how interrogation speed and local DNA geometry may influence genome editing efficiency.

Published

2022

4. Crystal structure of an RNA/DNA strand exchange junction

Author

Cofsky, Joshua C, Knott, Gavin J, Gee, Christine L, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Biological Sciences, Genetics, 1.1 Normal biological development and functioning, Generic health relevance, DNA, Nucleic Acid Conformation, Nucleic Acids, Nucleotides, RNA, General Science & Technology

Abstract

Short segments of RNA displace one strand of a DNA duplex during diverse processes including transcription and CRISPR-mediated immunity and genome editing. These strand exchange events involve the intersection of two geometrically distinct helix types-an RNA:DNA hybrid (A-form) and a DNA:DNA homoduplex (B-form). Although previous evidence suggests that these two helices can stack on each other, it is unknown what local geometric adjustments could enable A-on-B stacking. Here we report the X-ray crystal structure of an RNA-5'/DNA-3' strand exchange junction at an anisotropic resolution of 1.6 to 2.2 Å. The structure reveals that the A-to-B helical transition involves a combination of helical axis misalignment, helical axis tilting and compression of the DNA strand within the RNA:DNA helix, where nucleotides exhibit a mixture of A- and B-form geometry. These structural principles explain previous observations of conformational stability in RNA/DNA exchange junctions, enabling a nucleic acid architecture that is repeatedly populated during biological strand exchange events.

Published

2022

5. Cas9 interrogates DNA in discrete steps modulated by mismatches and supercoiling

Author

Ivanov, Ivan E, Wright, Addison V, Cofsky, Joshua C, Aris, Kevin D Palacio, Doudna, Jennifer A, and Bryant, Zev

Subjects

Biochemistry and Cell Biology, Physical Sciences, Biological Sciences, Bioengineering, Genetics, 1.1 Normal biological development and functioning, Generic health relevance, Base Pairing, CRISPR-Associated Proteins, CRISPR-Cas Systems, DNA, DNA Cleavage, Endonucleases, Gene Editing, Genome, R-Loop Structures, RNA, RNA, Guide, CRISPR-Cas Systems, magnetic tweezers, gene editing, torque spectroscopy

Abstract

The CRISPR-Cas9 nuclease has been widely repurposed as a molecular and cell biology tool for its ability to programmably target and cleave DNA. Cas9 recognizes its target site by unwinding the DNA double helix and hybridizing a 20-nucleotide section of its associated guide RNA to one DNA strand, forming an R-loop structure. A dynamic and mechanical description of R-loop formation is needed to understand the biophysics of target searching and develop rational approaches for mitigating off-target activity while accounting for the influence of torsional strain in the genome. Here we investigate the dynamics of Cas9 R-loop formation and collapse using rotor bead tracking (RBT), a single-molecule technique that can simultaneously monitor DNA unwinding with base-pair resolution and binding of fluorescently labeled macromolecules in real time. By measuring changes in torque upon unwinding of the double helix, we find that R-loop formation and collapse proceed via a transient discrete intermediate, consistent with DNA:RNA hybridization within an initial seed region. Using systematic measurements of target and off-target sequences under controlled mechanical perturbations, we characterize position-dependent effects of sequence mismatches and show how DNA supercoiling modulates the energy landscape of R-loop formation and dictates access to states competent for stable binding and cleavage. Consistent with this energy landscape model, in bulk experiments we observe promiscuous cleavage under physiological negative supercoiling. The detailed description of DNA interrogation presented here suggests strategies for improving the specificity and kinetics of Cas9 as a genome engineering tool and may inspire expanded applications that exploit sensitivity to DNA supercoiling.

Published

2020

6. Cas9 interrogates DNA in discrete steps modulated by mismatches and supercoiling

Author

Ivanov, Ivan E, Wright, Addison V, Cofsky, Joshua C, Aris, Kevin D Palacio, Doudna, Jennifer A, and Bryant, Zev

Subjects

Biochemistry and Cell Biology, Physical Sciences, Biological Sciences, Biotechnology, Genetics, Bioengineering, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Base Pairing, CRISPR-Associated Proteins, CRISPR-Cas Systems, DNA, DNA Cleavage, Endonucleases, Gene Editing, Genome, R-Loop Structures, RNA, RNA, Guide, Kinetoplastida, magnetic tweezers, gene editing, torque spectroscopy

Abstract

The CRISPR-Cas9 nuclease has been widely repurposed as a molecular and cell biology tool for its ability to programmably target and cleave DNA. Cas9 recognizes its target site by unwinding the DNA double helix and hybridizing a 20-nucleotide section of its associated guide RNA to one DNA strand, forming an R-loop structure. A dynamic and mechanical description of R-loop formation is needed to understand the biophysics of target searching and develop rational approaches for mitigating off-target activity while accounting for the influence of torsional strain in the genome. Here we investigate the dynamics of Cas9 R-loop formation and collapse using rotor bead tracking (RBT), a single-molecule technique that can simultaneously monitor DNA unwinding with base-pair resolution and binding of fluorescently labeled macromolecules in real time. By measuring changes in torque upon unwinding of the double helix, we find that R-loop formation and collapse proceed via a transient discrete intermediate, consistent with DNA:RNA hybridization within an initial seed region. Using systematic measurements of target and off-target sequences under controlled mechanical perturbations, we characterize position-dependent effects of sequence mismatches and show how DNA supercoiling modulates the energy landscape of R-loop formation and dictates access to states competent for stable binding and cleavage. Consistent with this energy landscape model, in bulk experiments we observe promiscuous cleavage under physiological negative supercoiling. The detailed description of DNA interrogation presented here suggests strategies for improving the specificity and kinetics of Cas9 as a genome engineering tool and may inspire expanded applications that exploit sensitivity to DNA supercoiling.

Published

2020

7. Cas9 interrogates DNA in discrete steps modulated by mismatches and supercoiling.

Author

Ivanov, Ivan E, Wright, Addison V, Cofsky, Joshua C, Aris, Kevin D Palacio, Doudna, Jennifer A, and Bryant, Zev

Subjects

Endonucleases, DNA, RNA, RNA, Guide, Base Pairing, Genome, DNA Cleavage, CRISPR-Cas Systems, CRISPR-Associated Proteins, Gene Editing, R-Loop Structures, gene editing, magnetic tweezers, torque spectroscopy, Guide

Abstract

The CRISPR-Cas9 nuclease has been widely repurposed as a molecular and cell biology tool for its ability to programmably target and cleave DNA. Cas9 recognizes its target site by unwinding the DNA double helix and hybridizing a 20-nucleotide section of its associated guide RNA to one DNA strand, forming an R-loop structure. A dynamic and mechanical description of R-loop formation is needed to understand the biophysics of target searching and develop rational approaches for mitigating off-target activity while accounting for the influence of torsional strain in the genome. Here we investigate the dynamics of Cas9 R-loop formation and collapse using rotor bead tracking (RBT), a single-molecule technique that can simultaneously monitor DNA unwinding with base-pair resolution and binding of fluorescently labeled macromolecules in real time. By measuring changes in torque upon unwinding of the double helix, we find that R-loop formation and collapse proceed via a transient discrete intermediate, consistent with DNA:RNA hybridization within an initial seed region. Using systematic measurements of target and off-target sequences under controlled mechanical perturbations, we characterize position-dependent effects of sequence mismatches and show how DNA supercoiling modulates the energy landscape of R-loop formation and dictates access to states competent for stable binding and cleavage. Consistent with this energy landscape model, in bulk experiments we observe promiscuous cleavage under physiological negative supercoiling. The detailed description of DNA interrogation presented here suggests strategies for improving the specificity and kinetics of Cas9 as a genome engineering tool and may inspire expanded applications that exploit sensitivity to DNA supercoiling.

Published

2020

8. CRISPR-Cas12a exploits R-loop asymmetry to form double-strand breaks

Author

Cofsky, Joshua C, Karandur, Deepti, Huang, Carolyn J, Witte, Isaac P, Kuriyan, John, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Genetics, 1.1 Normal biological development and functioning, Generic health relevance, Bacterial Proteins, CRISPR-Associated Proteins, CRISPR-Cas Systems, DNA, DNA Breaks, Double-Stranded, Endodeoxyribonucleases, Escherichia coli, Gene Editing, R-Loop Structures, RNA, Guide, CRISPR-Cas Systems, CRISPR, E. coli, R-loop, RNA, biochemistry, chemical biology, deoxyribonuclease, genome editing, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Type V CRISPR-Cas interference proteins use a single RuvC active site to make RNA-guided breaks in double-stranded DNA substrates, an activity essential for both bacterial immunity and genome editing. The best-studied of these enzymes, Cas12a, initiates DNA cutting by forming a 20-nucleotide R-loop in which the guide RNA displaces one strand of a double-helical DNA substrate, positioning the DNase active site for first-strand cleavage. However, crystal structures and biochemical data have not explained how the second strand is cut to complete the double-strand break. Here, we detect intrinsic instability in DNA flanking the RNA-3' side of R-loops, which Cas12a can exploit to expose second-strand DNA for cutting. Interestingly, DNA flanking the RNA-5' side of R-loops is not intrinsically unstable. This asymmetry in R-loop structure may explain the uniformity of guide RNA architecture and the single-active-site cleavage mechanism that are fundamental features of all type V CRISPR-Cas systems.

Published

2020

9. CRISPR-Cas12a exploits R-loop asymmetry to form double-strand breaks

Author

Cofsky, Joshua C, Karandur, Deepti, Huang, Carolyn J, Witte, Isaac P, Kuriyan, John, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Genetics, Prevention, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Bacterial Proteins, CRISPR-Associated Proteins, CRISPR-Cas Systems, DNA, DNA Breaks, Double-Stranded, Endodeoxyribonucleases, Escherichia coli, Gene Editing, R-Loop Structures, RNA, Guide, Kinetoplastida, CRISPR, E. coli, R-loop, RNA, biochemistry, chemical biology, deoxyribonuclease, genome editing, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Type V CRISPR-Cas interference proteins use a single RuvC active site to make RNA-guided breaks in double-stranded DNA substrates, an activity essential for both bacterial immunity and genome editing. The best-studied of these enzymes, Cas12a, initiates DNA cutting by forming a 20-nucleotide R-loop in which the guide RNA displaces one strand of a double-helical DNA substrate, positioning the DNase active site for first-strand cleavage. However, crystal structures and biochemical data have not explained how the second strand is cut to complete the double-strand break. Here, we detect intrinsic instability in DNA flanking the RNA-3' side of R-loops, which Cas12a can exploit to expose second-strand DNA for cutting. Interestingly, DNA flanking the RNA-5' side of R-loops is not intrinsically unstable. This asymmetry in R-loop structure may explain the uniformity of guide RNA architecture and the single-active-site cleavage mechanism that are fundamental features of all type V CRISPR-Cas systems.

Published

2020

10. Attachment of a 32P-phosphate to the 3' Terminus of a DNA Oligonucleotide.

Author

Cofsky, Joshua C and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Biological Sciences, Genetics, Radiolabel, P-32-phosphate, 3' DNA end, T4 polynucleotide kinase, T4 RNA ligase 2, DNA oligonucleotide, 2'-O-methylribonucleotide, 2', 3'-cyclic phosphate, 2′-O-methylribonucleotide, 2′, 32P-phosphate, 3′ DNA end, 3′-cyclic phosphate, Biological sciences, Biomedical and clinical sciences

Abstract

Biochemical investigations into DNA-binding and DNA-cutting proteins often benefit from the specific attachment of a radioactive label to one of the two DNA termini. In many cases, it is essential to perform two versions of the same experiment: one with the 5' DNA end labeled and one with the 3' DNA end labeled. While homogeneous 5'-radiolabeling can be accomplished using a single kinase-catalyzed phosphorylation step, existing procedures for 3'-radiolabeling often result in probe heterogeneity, prohibiting precise DNA fragment identification in downstream experiments. We present here a new protocol to efficiently attach a 32P-phosphate to the 3' end of a DNA oligonucleotide of arbitrary sequence, relying on inexpensive DNA oligonucleotide modifications (2'-O-methylribonucleotide and ribonucleotide sugar substitutions), two enzymes (T4 polynucleotide kinase and T4 RNA ligase 2), and the differential susceptibility of DNA and RNA to hydroxide treatment. Radioactive probe molecules produced by this protocol are homogeneous and oxidant-compatible, and they can be used for precise cleavage-site mapping in the context of both DNase enzyme characterization and DNA footprinting assays. Graphic abstract.

Published

2020

11. A Broad-Spectrum Inhibitor of CRISPR-Cas9

Author

Harrington, Lucas B, Doxzen, Kevin W, Ma, Enbo, Liu, Jun-Jie, Knott, Gavin J, Edraki, Alireza, Garcia, Bianca, Amrani, Nadia, Chen, Janice S, Cofsky, Joshua C, Kranzusch, Philip J, Sontheimer, Erik J, Davidson, Alan R, Maxwell, Karen L, and Doudna, Jennifer A

Subjects

Biochemistry and Cell Biology, Biological Sciences, Prevention, Genetics, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Generic health relevance, Amino Acid Sequence, Bacterial Proteins, Bacteriophages, CRISPR-Cas Systems, Endonucleases, Evolution, Molecular, HEK293 Cells, Humans, Protein Domains, Sequence Alignment, Viral Proteins, CRISPR, CRISPR-Cas9, Cas9, anti-CRISPR, gene editing, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

CRISPR-Cas9 proteins function within bacterial immune systems to target and destroy invasive DNA and have been harnessed as a robust technology for genome editing. Small bacteriophage-encoded anti-CRISPR proteins (Acrs) can inactivate Cas9, providing an efficient off switch for Cas9-based applications. Here, we show that two Acrs, AcrIIC1 and AcrIIC3, inhibit Cas9 by distinct strategies. AcrIIC1 is a broad-spectrum Cas9 inhibitor that prevents DNA cutting by multiple divergent Cas9 orthologs through direct binding to the conserved HNH catalytic domain of Cas9. A crystal structure of an AcrIIC1-Cas9 HNH domain complex shows how AcrIIC1 traps Cas9 in a DNA-bound but catalytically inactive state. By contrast, AcrIIC3 blocks activity of a single Cas9 ortholog and induces Cas9 dimerization while preventing binding to the target DNA. These two orthogonal mechanisms allow for separate control of Cas9 target binding and cleavage and suggest applications to allow DNA binding while preventing DNA cutting by Cas9.

Published

2017

12. A Broad-Spectrum Inhibitor of CRISPR-Cas9.

Author

Harrington, Lucas B, Doxzen, Kevin W, Ma, Enbo, Liu, Jun-Jie, Knott, Gavin J, Edraki, Alireza, Garcia, Bianca, Amrani, Nadia, Chen, Janice S, Cofsky, Joshua C, Kranzusch, Philip J, Sontheimer, Erik J, Davidson, Alan R, Maxwell, Karen L, and Doudna, Jennifer A

Subjects

Humans, Bacteriophages, Endonucleases, Bacterial Proteins, Viral Proteins, Sequence Alignment, Evolution, Molecular, Amino Acid Sequence, HEK293 Cells, CRISPR-Cas Systems, Protein Domains, CRISPR, CRISPR-Cas9, Cas9, anti-CRISPR, gene editing, Genetics, Prevention, 1.1 Normal biological development and functioning, Generic health relevance, Developmental Biology, Biological Sciences, Medical and Health Sciences

Abstract

CRISPR-Cas9 proteins function within bacterial immune systems to target and destroy invasive DNA and have been harnessed as a robust technology for genome editing. Small bacteriophage-encoded anti-CRISPR proteins (Acrs) can inactivate Cas9, providing an efficient off switch for Cas9-based applications. Here, we show that two Acrs, AcrIIC1 and AcrIIC3, inhibit Cas9 by distinct strategies. AcrIIC1 is a broad-spectrum Cas9 inhibitor that prevents DNA cutting by multiple divergent Cas9 orthologs through direct binding to the conserved HNH catalytic domain of Cas9. A crystal structure of an AcrIIC1-Cas9 HNH domain complex shows how AcrIIC1 traps Cas9 in a DNA-bound but catalytically inactive state. By contrast, AcrIIC3 blocks activity of a single Cas9 ortholog and induces Cas9 dimerization while preventing binding to the target DNA. These two orthogonal mechanisms allow for separate control of Cas9 target binding and cleavage and suggest applications to allow DNA binding while preventing DNA cutting by Cas9.

Published

2017

13. Deconstruction of the Ras switching cycle through saturation mutagenesis.

Author

Bandaru, Pradeep, Shah, Neel H, Bhattacharyya, Moitrayee, Barton, John P, Kondo, Yasushi, Cofsky, Joshua C, Gee, Christine L, Chakraborty, Arup K, Kortemme, Tanja, Ranganathan, Rama, and Kuriyan, John

Subjects

Humans, ras Proteins, DNA Mutational Analysis, Evolution, Molecular, Mutagenesis, Conserved Sequence, Protein Interaction Maps, E. coli, S. cerevisiae, allostery, biophysics, evolution, protein dynamics, structural biology, systems biology, Evolution, Molecular, Genetics, 1.1 Normal biological development and functioning, Generic Health Relevance, Biochemistry and Cell Biology

Abstract

Ras proteins are highly conserved signaling molecules that exhibit regulated, nucleotide-dependent switching between active and inactive states. The high conservation of Ras requires mechanistic explanation, especially given the general mutational tolerance of proteins. Here, we use deep mutational scanning, biochemical analysis and molecular simulations to understand constraints on Ras sequence. Ras exhibits global sensitivity to mutation when regulated by a GTPase activating protein and a nucleotide exchange factor. Removing the regulators shifts the distribution of mutational effects to be largely neutral, and reveals hotspots of activating mutations in residues that restrain Ras dynamics and promote the inactive state. Evolutionary analysis, combined with structural and mutational data, argue that Ras has co-evolved with its regulators in the vertebrate lineage. Overall, our results show that sequence conservation in Ras depends strongly on the biochemical network in which it operates, providing a framework for understanding the origin of global selection pressures on proteins.

Published

2017

14. Deconstruction of the Ras switching cycle through saturation mutagenesis

Author

Bandaru, Pradeep, Shah, Neel H, Bhattacharyya, Moitrayee, Barton, John P, Kondo, Yasushi, Cofsky, Joshua C, Gee, Christine L, Chakraborty, Arup K, Kortemme, Tanja, Ranganathan, Rama, and Kuriyan, John

Subjects

Biochemistry and Cell Biology, Biological Sciences, Genetics, 1.1 Normal biological development and functioning, Generic health relevance, Conserved Sequence, DNA Mutational Analysis, Evolution, Molecular, Humans, Mutagenesis, Protein Interaction Maps, ras Proteins, E. coli, S. cerevisiae, allostery, biophysics, evolution, protein dynamics, structural biology, systems biology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Ras proteins are highly conserved signaling molecules that exhibit regulated, nucleotide-dependent switching between active and inactive states. The high conservation of Ras requires mechanistic explanation, especially given the general mutational tolerance of proteins. Here, we use deep mutational scanning, biochemical analysis and molecular simulations to understand constraints on Ras sequence. Ras exhibits global sensitivity to mutation when regulated by a GTPase activating protein and a nucleotide exchange factor. Removing the regulators shifts the distribution of mutational effects to be largely neutral, and reveals hotspots of activating mutations in residues that restrain Ras dynamics and promote the inactive state. Evolutionary analysis, combined with structural and mutational data, argue that Ras has co-evolved with its regulators in the vertebrate lineage. Overall, our results show that sequence conservation in Ras depends strongly on the biochemical network in which it operates, providing a framework for understanding the origin of global selection pressures on proteins.

Published

2017