Your search keyword '"I. Can Kazan"' showing total 3 results

1. 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

2. 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

3. 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