Your search keyword '"I. Can Kazan"' showing total 13 results

1. The Role of Rigid Residues in Modulating TEM-1 β-Lactamase Function and Thermostability

Author

Bethany Kolbaba-Kartchner, I. Can Kazan, Jeremy H. Mills, and S. Banu Ozkan

Subjects

protein dynamics, allostery, molecular dynamics, protein engineering, β-lactamases, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The relationship between protein motions (i.e., dynamics) and enzymatic function has begun to be explored in β-lactamases as a way to advance our understanding of these proteins. In a recent study, we analyzed the dynamic profiles of TEM-1 (a ubiquitous class A β-lactamase) and several ancestrally reconstructed homologues. A chief finding of this work was that rigid residues that were allosterically coupled to the active site appeared to have profound effects on enzyme function, even when separated from the active site by many angstroms. In the present work, our aim was to further explore the implications of protein dynamics on β-lactamase function by altering the dynamic profile of TEM-1 using computational protein design methods. The Rosetta software suite was used to mutate amino acids surrounding either rigid residues that are highly coupled to the active site or to flexible residues with no apparent communication with the active site. Experimental characterization of ten designed proteins indicated that alteration of residues surrounding rigid, highly coupled residues, substantially affected both enzymatic activity and stability; in contrast, native-like activities and stabilities were maintained when flexible, uncoupled residues, were targeted. Our results provide additional insight into the structure-function relationship present in the TEM family of β-lactamases. Furthermore, the integration of computational protein design methods with analyses of protein dynamics represents a general approach that could be used to extend our understanding of the relationship between dynamics and function in other enzyme classes.

Published

2021

2. Some mechanistic underpinnings of molecular adaptations of SARS-COV-2 spike protein by integrating candidate adaptive polymorphisms with protein dynamics

Author

Nicholas James Ose, Paul Campitelli, Tushar Modi, I Can Kazan, Sudhir Kumar, and Sefika Banu Ozkan

Subjects

SARS-CoV-2, spike protein, evolution, dynamics, allostery, epistasis, Medicine, Science, Biology (General), QH301-705.5

Abstract

We integrate evolutionary predictions based on the neutral theory of molecular evolution with protein dynamics to generate mechanistic insight into the molecular adaptations of the SARS-COV-2 spike (S) protein. With this approach, we first identified candidate adaptive polymorphisms (CAPs) of the SARS-CoV-2 S protein and assessed the impact of these CAPs through dynamics analysis. Not only have we found that CAPs frequently overlap with well-known functional sites, but also, using several different dynamics-based metrics, we reveal the critical allosteric interplay between SARS-CoV-2 CAPs and the S protein binding sites with the human ACE2 (hACE2) protein. CAPs interact far differently with the hACE2 binding site residues in the open conformation of the S protein compared to the closed form. In particular, the CAP sites control the dynamics of binding residues in the open state, suggesting an allosteric control of hACE2 binding. We also explored the characteristic mutations of different SARS-CoV-2 strains to find dynamic hallmarks and potential effects of future mutations. Our analyses reveal that Delta strain-specific variants have non-additive (i.e., epistatic) interactions with CAP sites, whereas the less pathogenic Omicron strains have mostly additive mutations. Finally, our dynamics-based analysis suggests that the novel mutations observed in the Omicron strain epistatically interact with the CAP sites to help escape antibody binding.

Published

2024

3. Dynamic coupling of residues within proteins as a mechanistic foundation of many enigmatic pathogenic missense variants.

Author

Nicholas J Ose, Brandon M Butler, Avishek Kumar, I Can Kazan, Maxwell Sanderford, Sudhir Kumar, and S Banu Ozkan

Subjects

Biology (General), QH301-705.5

Abstract

Many pathogenic missense mutations are found in protein positions that are neither well-conserved nor fall in any known functional domains. Consequently, we lack any mechanistic underpinning of dysfunction caused by such mutations. We explored the disruption of allosteric dynamic coupling between these positions and the known functional sites as a possible mechanism for pathogenesis. In this study, we present an analysis of 591 pathogenic missense variants in 144 human enzymes that suggests that allosteric dynamic coupling of mutated positions with known active sites is a plausible biophysical mechanism and evidence of their functional importance. We illustrate this mechanism in a case study of β-Glucocerebrosidase (GCase) in which a vast majority of 94 sites harboring Gaucher disease-associated missense variants are located some distance away from the active site. An analysis of the conformational dynamics of GCase suggests that mutations on these distal sites cause changes in the flexibility of active site residues despite their distance, indicating a dynamic communication network throughout the protein. The disruption of the long-distance dynamic coupling caused by missense mutations may provide a plausible general mechanistic explanation for biological dysfunction and disease.

Published

2022

4. Investigating the allosteric response of the PICK1 PDZ domain to different ligands with all-atom simulations

Author

Amy O. Stevens, I. Can Kazan, Banu Ozkan, and Yi He

Subjects

PDZ Domains, Nuclear Proteins, Ligands, Carrier Proteins, Molecular Biology, Biochemistry, Adaptor Proteins, Signal Transducing, Protein Binding

Abstract

The PDZ family is comprised of small modular domains that play critical roles in the allosteric modulation of many cellular signaling processes by binding to the C-terminal tail of different proteins. As dominant modular proteins that interact with a diverse set of peptides, it is of particular interest to explore how different binding partners induce different allosteric effects on the same PDZ domain. Because the PICK1 PDZ domain can bind different types of ligands, it is an ideal test case to answer this question and explore the network of interactions that give rise to dynamic allostery. Here, we use all-atom molecular dynamics simulations to explore dynamic allostery in the PICK1 PDZ domain by modeling two PICK1 PDZ systems: PICK1 PDZ-DAT and PICK1 PDZ-GluR2. Our results suggest that ligand binding to the PICK1 PDZ domain induces dynamic allostery at the αA helix that is similar to what has been observed in other PDZ domains. We found that the PICK1 PDZ-ligand distance is directly correlated with both dynamic changes of the αA helix and the distance between the αA helix and βB strand. Furthermore, our work identifies a hydrophobic core between DAT/GluR2 and I35 as a key interaction in inducing such dynamic allostery. Finally, the unique interaction patterns between different binding partners and the PICK1 PDZ domain can induce unique dynamic changes to the PICK1 PDZ domain. We suspect that unique allosteric coupling patterns with different ligands may play a critical role in how PICK1 performs its biological functions in various signaling networks.

Published

2022

5. The Role of Rigid Residues in Modulating TEM-1 β-Lactamase Function and Thermostability

Author

I. Can Kazan, S. Banu Ozkan, Bethany Kolbaba-Kartchner, and Jeremy H. Mills

Subjects

0301 basic medicine, Models, Molecular, Protein Conformation, β-lactamases, 01 natural sciences, lcsh:Chemistry, Catalytic Domain, Enzyme Stability, Amino Acids, lcsh:QH301-705.5, Spectroscopy, Thermostability, chemistry.chemical_classification, allostery, 010304 chemical physics, biology, Chemistry, Protein dynamics, General Medicine, Computer Science Applications, Amino acid, protein dynamics, Allosteric regulation, Protein design, Molecular Dynamics Simulation, Catalysis, beta-Lactamases, Article, Inorganic Chemistry, 03 medical and health sciences, Structure-Activity Relationship, 0103 physical sciences, Escherichia coli, Physical and Theoretical Chemistry, Molecular Biology, Binding Sites, Bacteria, Sequence Homology, Amino Acid, Organic Chemistry, Active site, Computational Biology, protein engineering, Protein engineering, molecular dynamics, 030104 developmental biology, lcsh:Biology (General), lcsh:QD1-999, Biophysics, biology.protein, Mutant Proteins, Function (biology)

Abstract

The relationship between protein motions (i.e., dynamics) and enzymatic function has begun to be explored in β-lactamases as a way to advance our understanding of these proteins. In a recent study, we analyzed the dynamic profiles of TEM-1 (a ubiquitous class A β-lactamase) and several ancestrally reconstructed homologues. A chief finding of this work was that rigid residues that were allosterically coupled to the active site appeared to have profound effects on enzyme function, even when separated from the active site by many angstroms. In the present work, our aim was to further explore the implications of protein dynamics on β-lactamase function by altering the dynamic profile of TEM-1 using computational protein design methods. The Rosetta software suite was used to mutate amino acids surrounding either rigid residues that are highly coupled to the active site or to flexible residues with no apparent communication with the active site. Experimental characterization of ten designed proteins indicated that alteration of residues surrounding rigid, highly coupled residues, substantially affected both enzymatic activity and stability, in contrast, native-like activities and stabilities were maintained when flexible, uncoupled residues, were targeted. Our results provide additional insight into the structure-function relationship present in the TEM family of β-lactamases. Furthermore, the integration of computational protein design methods with analyses of protein dynamics represents a general approach that could be used to extend our understanding of the relationship between dynamics and function in other enzyme classes.

Published

2021

6. Design of novel cyanovirin-N variants by modulation of binding dynamics through distal mutations

Author

I. Can Kazan, Prerna Sharma, Mohammad Imtiazur Rahman, Andrey Bobkov, Raimund Fromme, Giovanna Ghirlanda, and S. Banu Ozkan

Subjects

General Immunology and Microbiology, biology, Chemistry, General Neuroscience, Allosteric regulation, Mutant, Lectin, General Medicine, General Biochemistry, Genetics and Molecular Biology, Dynamic coupling, Docking (molecular), biology.protein, Biophysics, Statistical analysis, Binding site

Abstract

We develop a computational approach to identify distal residues that allosterically modulate the dynamics of binding sites by combining dynamic coupling with statistical analysis of co-evolution. Putative mutants of these predicted allosteric sites are subjected to Adaptive BP-Dock docking tool for binding analysis. Here, we apply this method to a small lectin, Cyanovirin-N (CV-N), that selectively binds to dimannose. Our computational method points out mutations on I34, that is 16A away from binding site can modulate binding. Experimental characterization of I34 mutants confirms that I34Y increases affinity towards dimannose, while I34K completely abolish binding. The increased affinity is not due to changes in the binding region, which are conserved in the crystal structure. However, ITC analysis reveals an opposite contribution of TDS (negative in WT, and positive in I34Y) and suggests that modulation of dynamics (i.e., dynamic allostery) is responsible for the change in binding affinity. Our results point to a novel approach to identify and substitute distal sites, guiding the mutational landscape in glycan-binding proteins to improve binding affinity.

Published

2021

7. Author Correction: Plant-expressed cocaine hydrolase variants of butyrylcholinesterase exhibit altered allosteric effects of cholinesterase activity and increased inhibitor sensitivity

Author

Matthew Barcus, Tsafrir Leket-Mor, Stephen Brimijoin, I. Can Kazan, Ashini Bolia, Chang-Guo Zhan, Latha Kannan, R. Player Kendle, Katherine E. Larrimore, Sefika Banu Ozkan, and Tameem Jamal

Subjects

0301 basic medicine, Allosteric regulation, lcsh:Medicine, 03 medical and health sciences, 0302 clinical medicine, Allosteric Regulation, Cocaine, Catalytic Domain, Hydrolase, lcsh:Science, Author Correction, Butyrylcholinesterase, Cholinesterase, Plant Proteins, Multidisciplinary, Binding Sites, biology, Chemistry, Hydrolysis, lcsh:R, Genetic Variation, Stereoisomerism, Recombinant Proteins, 030104 developmental biology, Biochemistry, 030220 oncology & carcinogenesis, Mutation, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, biology.protein, lcsh:Q, Cholinesterase Inhibitors, Protein Binding

Abstract

Butyrylcholinesterase (BChE) is an enzyme with broad substrate and ligand specificities and may function as a generalized bioscavenger by binding and/or hydrolyzing various xenobiotic agents and toxicants, many of which target the central and peripheral nervous systems. Variants of BChE were rationally designed to increase the enzyme's ability to hydrolyze the psychoactive enantiomer of cocaine. These variants were cloned, and then expressed using the magnICON transient expression system in plants and their enzymatic properties were investigated. In particular, we explored the effects that these site-directed mutations have over the enzyme kinetics with various substrates of BChE. We further compared the affinity of various anticholinesterases including organophosphorous nerve agents and pesticides toward these BChE variants relative to the wild type enzyme. In addition to serving as a therapy for cocaine addiction-related diseases, enhanced bioscavenging against other harmful agents could add to the practicality and versatility of the plant-derived recombinant enzyme as a multivalent therapeutic.

Published

2018

8. Design of Novel Lectins by Computer‐Guided Directed Evolution

Author

Giovanna Ghirlanda, Prerna Sharma, I. Can Kazan, and Sefika Banu Ozkan

Subjects

Computer science, Genetics, Computational biology, Directed evolution, Molecular Biology, Biochemistry, Biotechnology

Published

2018

9. Plant-expressed cocaine hydrolase variants of butyrylcholinesterase exhibit altered allosteric effects of cholinesterase activity and increased inhibitor sensitivity

Author

Stephen Brimijoin, Katherine E. Larrimore, Chang-Guo Zhan, Ashini Bolia, Latha Kannan, R. Player Kendle, Tsafrir S. Mor, I. Can Kazan, Tameem Jamal, Matthew Barcus, and S. Banu Ozkan

Subjects

0301 basic medicine, chemistry.chemical_classification, Multidisciplinary, biology, lcsh:R, Allosteric regulation, lcsh:Medicine, Ligand (biochemistry), Article, 3. Good health, 03 medical and health sciences, 030104 developmental biology, Enzyme, chemistry, Biochemistry, Hydrolase, biology.protein, lcsh:Q, Enzyme kinetics, Binding site, lcsh:Science, Butyrylcholinesterase, Cholinesterase

Abstract

Butyrylcholinesterase (BChE) is an enzyme with broad substrate and ligand specificities and may function as a generalized bioscavenger by binding and/or hydrolyzing various xenobiotic agents and toxicants, many of which target the central and peripheral nervous systems. Variants of BChE were rationally designed to increase the enzyme’s ability to hydrolyze the psychoactive enantiomer of cocaine. These variants were cloned, and then expressed using the magnICON transient expression system in plants and their enzymatic properties were investigated. In particular, we explored the effects that these site-directed mutations have over the enzyme kinetics with various substrates of BChE. We further compared the affinity of various anticholinesterases including organophosphorous nerve agents and pesticides toward these BChE variants relative to the wild type enzyme. In addition to serving as a therapy for cocaine addiction-related diseases, enhanced bioscavenging against other harmful agents could add to the practicality and versatility of the plant-derived recombinant enzyme as a multivalent therapeutic.

Published

2017

10. Coevolving residues inform protein dynamics profiles and disease susceptibility of nSNVs

Author

S. Banu Ozkan, Brandon M. Butler, I. Can Kazan, and Avishek Kumar

Subjects

Protein Structure Comparison, 0301 basic medicine, Protein Conformation, Computer science, Molecular Conformation, Normal Distribution, Protein Structure Prediction, Biochemistry, Acyl-CoA Dehydrogenase, Database and Informatics Methods, Protein structure, Macromolecular Structure Analysis, Protein Isoforms, Biology (General), Neurons, Crystallography, Multiple sequence alignment, Ecology, Physics, Protein dynamics, Genomics, Protein structure prediction, Condensed Matter Physics, Phenotype, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Crystal Structure, symbols, Disease Susceptibility, Protein Structure Determination, Sequence Analysis, Gaussian network model, Research Article, Protein Structure, Multiple Alignment Calculation, QH301-705.5, Bioinformatics, Computational biology, Research and Analysis Methods, Structural genomics, 03 medical and health sciences, Cellular and Molecular Neuroscience, symbols.namesake, Imaging, Three-Dimensional, Computational Techniques, Genetics, Solid State Physics, Animals, Humans, Computer Simulation, Molecular Biology, Cytochrome Reductases, Ecology, Evolution, Behavior and Systematics, Sequence (medicine), Biology and Life Sciences, Proteins, Computational Biology, Split-Decomposition Method, Rats, 030104 developmental biology, ROC Curve, Structural Genomics, Muramidase, Sequence Alignment

Abstract

The conformational dynamics of proteins is rarely used in methodologies used to predict the impact of genetic mutations due to the paucity of three-dimensional protein structures as compared to the vast number of available sequences. Until now a three-dimensional (3D) structure has been required to predict the conformational dynamics of a protein. We introduce an approach that estimates the conformational dynamics of a protein, without relying on structural information. This de novo approach utilizes coevolving residues identified from a multiple sequence alignment (MSA) using Potts models. These coevolving residues are used as contacts in a Gaussian network model (GNM) to obtain protein dynamics. B-factors calculated using sequence-based GNM (Seq-GNM) are in agreement with crystallographic B-factors as well as theoretical B-factors from the original GNM that utilizes the 3D structure. Moreover, we demonstrate the ability of the calculated B-factors from the Seq-GNM approach to discriminate genomic variants according to their phenotypes for a wide range of proteins. These results suggest that protein dynamics can be approximated based on sequence information alone, making it possible to assess the phenotypes of nSNVs in cases where a 3D structure is unknown. We hope this work will promote the use of dynamics information in genetic disease prediction at scale by circumventing the need for 3D structures., Author summary Proteins are dynamic machines that undergo atomic fluctuations, side chain rotations, and collective domain movements that are required for biological function. There is, therefore, a need for quantitative metrics that capture the dynamic fluctuations per position to understand the critical role of protein dynamics in shaping biological functions. A limiting factor in incorporating structural dynamics information in the classification of non-synonymous single nucleotide variants (nSNVs) is the limited number of known 3D structures compared to the vast number of available sequences. We have developed a new sequence-based GNM method, termed Seq-GNM, which uses co-evolving amino acid positions based on the multiple sequence alignment of a given query sequence to estimate the thermal motions of C-alpha atoms. In this paper, we have demonstrated that the predicted thermal motions using Seq-GNM are in reasonable agreement with experimental B-factors as well as B-factors computed using 3D crystal structures. We also provide evidence that B-factors predicted by Seq-GNM are capable of distinguishing between disease-associated and neutral nSNVs.

Published

2018

11. Design of novel cyanovirin-N variants by modulation of binding dynamics through distal mutations

Author

I Can Kazan, Prerna Sharma, Mohammad Imtiazur Rahman, Andrey Bobkov, Raimund Fromme, Giovanna Ghirlanda, and S Banu Ozkan

Subjects

protein dynamics, allostery, lectin, glycan, enzyme, molecular mechanism, Medicine, Science, Biology (General), QH301-705.5

Abstract

We develop integrated co-evolution and dynamic coupling (ICDC) approach to identify, mutate, and assess distal sites to modulate function. We validate the approach first by analyzing the existing mutational fitness data of TEM-1 β-lactamase and show that allosteric positions co-evolved and dynamically coupled with the active site significantly modulate function. We further apply ICDC approach to identify positions and their mutations that can modulate binding affinity in a lectin, cyanovirin-N (CV-N), that selectively binds to dimannose, and predict binding energies of its variants through Adaptive BP-Dock. Computational and experimental analyses reveal that binding enhancing mutants identified by ICDC impact the dynamics of the binding pocket, and show that rigidification of the binding residues compensates for the entropic cost of binding. This work suggests a mechanism by which distal mutations modulate function through dynamic allostery and provides a blueprint to identify candidates for mutagenesis in order to optimize protein function.

Published

2022

12. Coevolving residues inform protein dynamics profiles and disease susceptibility of nSNVs.

Author

Brandon M Butler, I Can Kazan, Avishek Kumar, and S Banu Ozkan

Subjects

Biology (General), QH301-705.5

Abstract

The conformational dynamics of proteins is rarely used in methodologies used to predict the impact of genetic mutations due to the paucity of three-dimensional protein structures as compared to the vast number of available sequences. Until now a three-dimensional (3D) structure has been required to predict the conformational dynamics of a protein. We introduce an approach that estimates the conformational dynamics of a protein, without relying on structural information. This de novo approach utilizes coevolving residues identified from a multiple sequence alignment (MSA) using Potts models. These coevolving residues are used as contacts in a Gaussian network model (GNM) to obtain protein dynamics. B-factors calculated using sequence-based GNM (Seq-GNM) are in agreement with crystallographic B-factors as well as theoretical B-factors from the original GNM that utilizes the 3D structure. Moreover, we demonstrate the ability of the calculated B-factors from the Seq-GNM approach to discriminate genomic variants according to their phenotypes for a wide range of proteins. These results suggest that protein dynamics can be approximated based on sequence information alone, making it possible to assess the phenotypes of nSNVs in cases where a 3D structure is unknown. We hope this work will promote the use of dynamics information in genetic disease prediction at scale by circumventing the need for 3D structures.

Published

2018

13. Some mechanistic underpinnings of molecular adaptations of SARS-COV-2 spike protein by integrating candidate adaptive polymorphisms with protein dynamics.

Author

Ose NJ, Campitelli P, Modi T, Can Kazan I, Kumar S, and Banu Ozkan S

Abstract

We integrate evolutionary predictions based on the neutral theory of molecular evolution with protein dynamics to generate mechanistic insight into the molecular adaptations of the SARS-COV-2 Spike (S) protein. With this approach, we first identified Candidate Adaptive Polymorphisms (CAPs) of the SARS-CoV-2 Spike protein and assessed the impact of these CAPs through dynamics analysis. Not only have we found that CAPs frequently overlap with well-known functional sites, but also, using several different dynamics-based metrics, we reveal the critical allosteric interplay between SARS-CoV-2 CAPs and the S protein binding sites with the human ACE2 (hACE2) protein. CAPs interact far differently with the hACE2 binding site residues in the open conformation of the S protein compared to the closed form. In particular, the CAP sites control the dynamics of binding residues in the open state, suggesting an allosteric control of hACE2 binding. We also explored the characteristic mutations of different SARS-CoV-2 strains to find dynamic hallmarks and potential effects of future mutations. Our analyses reveal that Delta strain-specific variants have non-additive (i.e., epistatic) interactions with CAP sites, whereas the less pathogenic Omicron strains have mostly additive mutations. Finally, our dynamics-based analysis suggests that the novel mutations observed in the Omicron strain epistatically interact with the CAP sites to help escape antibody binding.

Published

2024