Iyanar VETRIVEL
Doctorant Université de Nantes
janvier 2014 - octobre 2017
| Équipe : |
Thèmes de recherche
Bioinformatique structurale
Parcours universitaire
Feb 2020 – present: Clinical Scientist, BuddhiMed Technologies Pvt. Ltd. Bengaluru, India
Aug 2018 – Dec 2019: Post-doctoral researcher, University of Nantes, Nantes, France
Nov 2017 – Apr 2018: Teaching and research assistant, University of Nantes, Nantes, France
Jan 2014 – Oct 2017: Ph.D., Structural Bioinformatics, University of Nantes, Nantes, France
Sep 2011 – Jun 2013: M.Sc., Computational Biology, Anna University, Chennai, India
Sep 2007 – Jun 2011: B.E., Biotechnology, PES Institute of Technology, Bangalore, India
Publications
3 publications
Tripathi, Neha; Vetrivel, Iyanar; Téletchéa, Stéphane; Jean, Mickaël; Legembre, Patrick; Laurent, Adèle D
Investigation of phospholipase Cγ1 interaction with SLP76 using molecular modeling methods for identifying novel inhibitors Article de journal
Dans: International Journal of Molecular Sciences, vol. 20, no. 19, 2019, ISSN: 14220067.
@article{Tripathi2019,
title = {Investigation of phospholipase Cγ1 interaction with SLP76 using molecular modeling methods for identifying novel inhibitors},
author = {Neha Tripathi and Iyanar Vetrivel and Stéphane Téletchéa and Mickaël Jean and Patrick Legembre and Adèle D Laurent},
doi = {10.3390/ijms20194721},
issn = {14220067},
year = {2019},
date = {2019-10-01},
journal = {International Journal of Molecular Sciences},
volume = {20},
number = {19},
publisher = {MDPI AG},
abstract = {The enzyme phospholipase C gamma 1 (PLCγ1) has been identified as a potential drug target of interest for various pathological conditions such as immune disorders, systemic lupus erythematosus, and cancers. Targeting its SH3 domain has been recognized as an efficient pharmacological approach for drug discovery against PLCγ1. Therefore, for the first time, a combination of various biophysical methods has been employed to shed light on the atomistic interactions between PLCγ1 and its known binding partners. Indeed, molecular modeling of PLCγ1 with SLP76 peptide and with previously reported inhibitors (ritonavir, anethole, daunorubicin, diflunisal, and rosiglitazone) facilitated the identification of the common critical residues (Gln805, Arg806, Asp808, Glu809, Asp825, Gly827, and Trp828) as well as the quantification of their interaction through binding energies calculations. These features are in agreement with previous experimental data. Such an in depth biophysical analysis of each complex provides an opportunity to identify new inhibitors through pharmacophore mapping, molecular docking and MD simulations. From such a systematic procedure, a total of seven compounds emerged as promising inhibitors, all characterized by a strong binding with PLCγ1 and a comparable or higher binding affinity to ritonavir (ΔGbind < -25 kcal/mol), one of the most potent inhibitor reported till now.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
The enzyme phospholipase C gamma 1 (PLCγ1) has been identified as a potential drug target of interest for various pathological conditions such as immune disorders, systemic lupus erythematosus, and cancers. Targeting its SH3 domain has been recognized as an efficient pharmacological approach for drug discovery against PLCγ1. Therefore, for the first time, a combination of various biophysical methods has been employed to shed light on the atomistic interactions between PLCγ1 and its known binding partners. Indeed, molecular modeling of PLCγ1 with SLP76 peptide and with previously reported inhibitors (ritonavir, anethole, daunorubicin, diflunisal, and rosiglitazone) facilitated the identification of the common critical residues (Gln805, Arg806, Asp808, Glu809, Asp825, Gly827, and Trp828) as well as the quantification of their interaction through binding energies calculations. These features are in agreement with previous experimental data. Such an in depth biophysical analysis of each complex provides an opportunity to identify new inhibitors through pharmacophore mapping, molecular docking and MD simulations. From such a systematic procedure, a total of seven compounds emerged as promising inhibitors, all characterized by a strong binding with PLCγ1 and a comparable or higher binding affinity to ritonavir (ΔGbind < -25 kcal/mol), one of the most potent inhibitor reported till now.
Vetrivel, Iyanar; Hoffmann, Lionel; Guegan, Sean; Offmann, Bernard; Laurent, Adele D
PBmapclust: Mapping and Clustering the Protein Conformational Space Using a Structural Alphabet Proceedings Article
Dans: Byska, Jan; Krone, Michael; Sommer, Björn (Ed.): Workshop on Molecular Graphics and Visual Analysis of Molecular Data, The Eurographics Association, 2019, ISBN: 978-3-03868-085-7.
@inproceedings{lva.20191097b,
title = {PBmapclust: Mapping and Clustering the Protein Conformational Space Using a Structural Alphabet},
author = {Iyanar Vetrivel and Lionel Hoffmann and Sean Guegan and Bernard Offmann and Adele D Laurent},
editor = {Jan Byska and Michael Krone and Björn Sommer},
doi = {10.2312/molva.20191097},
isbn = {978-3-03868-085-7},
year = {2019},
date = {2019-01-01},
booktitle = {Workshop on Molecular Graphics and Visual Analysis of Molecular Data},
publisher = {The Eurographics Association},
abstract = {Analyzing the data from molecular dynamics simulation of biological macromolecules like proteins is challenging. We propose a simple tool called PBmapclust that is based on a well established structural alphabet called Protein blocks (PB). PBs help in tracing the trajectory of the protein backbone by categorizing it into 16 distinct structural states. PBmapclust provides a time vs. amino acid residue plot that is color coded to match each of the PBs. Color changes correspond to structural changes, giving a visual overview of the simulation. Further, PBmapclust enables the user to "map" the conformational space sampled by the protein during the MD simulation by clustering the conformations. The ability to generate sub-maps for specific residues and specific time intervals allows the user to focus on residues of interest like for active sites or disordered regions. We have included an illustrative case study to demonstrate the utility of the tool. It describes the effect of the disordered domain of a HSP90 co-chaperone on the conformation of its active site residues. The scripts required to perform PBmapclust are made freely available under the GNU general public license.},
keywords = {},
pubstate = {published},
tppubtype = {inproceedings}
}
Analyzing the data from molecular dynamics simulation of biological macromolecules like proteins is challenging. We propose a simple tool called PBmapclust that is based on a well established structural alphabet called Protein blocks (PB). PBs help in tracing the trajectory of the protein backbone by categorizing it into 16 distinct structural states. PBmapclust provides a time vs. amino acid residue plot that is color coded to match each of the PBs. Color changes correspond to structural changes, giving a visual overview of the simulation. Further, PBmapclust enables the user to "map" the conformational space sampled by the protein during the MD simulation by clustering the conformations. The ability to generate sub-maps for specific residues and specific time intervals allows the user to focus on residues of interest like for active sites or disordered regions. We have included an illustrative case study to demonstrate the utility of the tool. It describes the effect of the disordered domain of a HSP90 co-chaperone on the conformation of its active site residues. The scripts required to perform PBmapclust are made freely available under the GNU general public license.
Vetrivel, Iyanar; de Brevern, Alexandre G; Cadet, Frédéric; Srinivasan, Narayanaswamy; Offmann, Bernard
Structural variations within proteins can be as large as variations observed across their homologues Article de journal
Dans: Biochimie, vol. 167, p. 162–170, 2019, ISSN: 61831638.
@article{Vetrivel2019,
title = {Structural variations within proteins can be as large as variations observed across their homologues},
author = {Iyanar Vetrivel and Alexandre G de Brevern and Frédéric Cadet and Narayanaswamy Srinivasan and Bernard Offmann},
doi = {10.1016/j.biochi.2019.09.013},
issn = {61831638},
year = {2019},
date = {2019-01-01},
journal = {Biochimie},
volume = {167},
pages = {162--170},
abstract = {Understanding the structural plasticity of proteins is key to understanding the intricacies of their functions and mechanistic basis. In the current study, we analyzed the available multiple crystal structures of the same protein for the structural differences. For this purpose we used an abstraction of protein structures referred as Protein Blocks (PBs) that was previously established. We also characterized the nature of the structural variations for a few proteins using molecular dynamics simulations. In both the cases, the structural variations were summarized in the form of substitution matrices of PBs. We show that certain conformational states are preferably replaced by other specific conformational states. Interestingly, these structural variations are highly similar to those previously observed across structures of homologous proteins (r2 = 0.923) or across the ensemble of conformations from NMR data (r2 = 0.919). Thus our study quantitatively shows that overall trends of structural changes in a given protein are nearly identical to the trends of structural differences that occur in the topologically equivalent positions in homologous proteins. Specific case studies are used to illustrate the nature of these structural variations.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Understanding the structural plasticity of proteins is key to understanding the intricacies of their functions and mechanistic basis. In the current study, we analyzed the available multiple crystal structures of the same protein for the structural differences. For this purpose we used an abstraction of protein structures referred as Protein Blocks (PBs) that was previously established. We also characterized the nature of the structural variations for a few proteins using molecular dynamics simulations. In both the cases, the structural variations were summarized in the form of substitution matrices of PBs. We show that certain conformational states are preferably replaced by other specific conformational states. Interestingly, these structural variations are highly similar to those previously observed across structures of homologous proteins (r2 = 0.923) or across the ensemble of conformations from NMR data (r2 = 0.919). Thus our study quantitatively shows that overall trends of structural changes in a given protein are nearly identical to the trends of structural differences that occur in the topologically equivalent positions in homologous proteins. Specific case studies are used to illustrate the nature of these structural variations.
1 publication
Cadet, Frédéric; Fontaine, Nicolas; Li, Guangyue; Sanchis, Joaquin; Chong, Matthieu Ng Fuk; Pandjaitan, Rudy; Vetrivel, Iyanar; Offmann, Bernard; Reetz, Manfred T
A machine learning approach for reliable prediction of amino acid interactions and its application in the directed evolution of enantioselective enzymes Article de journal
Dans: Scientific Reports, vol. 8, no. 1, p. 1–15, 2018, ISSN: 20452322.
@article{Cadet2018,
title = {A machine learning approach for reliable prediction of amino acid interactions and its application in the directed evolution of enantioselective enzymes},
author = {Frédéric Cadet and Nicolas Fontaine and Guangyue Li and Joaquin Sanchis and Matthieu {Ng Fuk Chong} and Rudy Pandjaitan and Iyanar Vetrivel and Bernard Offmann and Manfred T Reetz},
doi = {10.1038/s41598-018-35033-y},
issn = {20452322},
year = {2018},
date = {2018-01-01},
journal = {Scientific Reports},
volume = {8},
number = {1},
pages = {1--15},
abstract = {Directed evolution is an important research activity in synthetic biology and biotechnology. Numerous reports describe the application of tedious mutation/screening cycles for the improvement of proteins. Recently, knowledge-based approaches have facilitated the prediction of protein properties and the identification of improved mutants. However, epistatic phenomena constitute an obstacle which can impair the predictions in protein engineering. We present an innovative sequence-activity relationship (innov'SAR) methodology based on digital signal processing combining wet-lab experimentation and computational protein design. In our machine learning approach, a predictive model is developed to find the resulting property of the protein when the n single point mutations are permuted (2n combinations). The originality of our approach is that only sequence information and the fitness of mutants measured in the wet-lab are needed to build models. We illustrate the application of the approach in the case of improving the enantioselectivity of an epoxide hydrolase from Aspergillus niger. n = 9 single point mutants of the enzyme were experimentally assessed for their enantioselectivity and used as a learning dataset to build a model. Based on combinations of the 9 single point mutations (29), the enantioselectivity of these 512 variants were predicted, and candidates were experimentally checked: better mutants with higher enantioselectivity were indeed found.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Directed evolution is an important research activity in synthetic biology and biotechnology. Numerous reports describe the application of tedious mutation/screening cycles for the improvement of proteins. Recently, knowledge-based approaches have facilitated the prediction of protein properties and the identification of improved mutants. However, epistatic phenomena constitute an obstacle which can impair the predictions in protein engineering. We present an innovative sequence-activity relationship (innov'SAR) methodology based on digital signal processing combining wet-lab experimentation and computational protein design. In our machine learning approach, a predictive model is developed to find the resulting property of the protein when the n single point mutations are permuted (2n combinations). The originality of our approach is that only sequence information and the fitness of mutants measured in the wet-lab are needed to build models. We illustrate the application of the approach in the case of improving the enantioselectivity of an epoxide hydrolase from Aspergillus niger. n = 9 single point mutants of the enzyme were experimentally assessed for their enantioselectivity and used as a learning dataset to build a model. Based on combinations of the 9 single point mutations (29), the enantioselectivity of these 512 variants were predicted, and candidates were experimentally checked: better mutants with higher enantioselectivity were indeed found.
1 publication
Vetrivel, Iyanar; Mahajan, Swapnil; Tyagi, Manoj; Hoffmann, Lionel; Sanejouand, Yves-Henri; Srinivasan, Narayanaswamy; Brevern, Alexandre G De; Cadet, Frédéric; Offmann, Bernard
Knowledge-based prediction of protein backbone conformation using a structural alphabet Article de journal
Dans: PLoS ONE, vol. 12, no. 11, 2017, ISSN: 19326203.
@article{Vetrivel2017,
title = {Knowledge-based prediction of protein backbone conformation using a structural alphabet},
author = {Iyanar Vetrivel and Swapnil Mahajan and Manoj Tyagi and Lionel Hoffmann and Yves-Henri Sanejouand and Narayanaswamy Srinivasan and Alexandre G {De Brevern} and Frédéric Cadet and Bernard Offmann},
doi = {10.1371/journal.pone.0186215},
issn = {19326203},
year = {2017},
date = {2017-11-01},
journal = {PLoS ONE},
volume = {12},
number = {11},
publisher = {Public Library of Science},
abstract = {Libraries of structural prototypes that abstract protein local structures are known as structural alphabets and have proven to be very useful in various aspects of protein structure analyses and predictions. One such library, Protein Blocks, is composed of 16 standard 5-residues long structural prototypes. This form of analyzing proteins involves drafting its structure as a string of Protein Blocks. Predicting the local structure of a protein in terms of protein blocks is the general objective of this work. A new approach, PB-kPRED is proposed towards this aim. It involves (i) organizing the structural knowledge in the form of a database of pentapeptide fragments extracted from all protein structures in the PDB and (ii) applying a knowledge-based algorithm that does not rely on any secondary structure predictions and/ or sequence alignment profiles, to scan this database and predict most probable backbone conformations for the protein local structures. Though PB-kPRED uses the structural information from homologues in preference, if available. The predictions were evaluated rigorously on 15,544 query proteins representing a non-redundant subset of the PDB filtered at 30% sequence identity cut-off. We have shown that the kPRED method was able to achieve mean accuracies ranging from 40.8% to 66.3% depending on the availability of homologues. The impact of the different strategies for scanning the database on the prediction was evaluated and is discussed. Our results highlight the usefulness of the method in the context of proteins without any known structural homologues. A scoring function that gives a good estimate of the accuracy of prediction was further developed. This score estimates very well the accuracy of the algorithm (R2 of 0.82). An online version of the tool is provided freely for non-commercial usage at http://www.bo-protscience.fr/kpred/.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Libraries of structural prototypes that abstract protein local structures are known as structural alphabets and have proven to be very useful in various aspects of protein structure analyses and predictions. One such library, Protein Blocks, is composed of 16 standard 5-residues long structural prototypes. This form of analyzing proteins involves drafting its structure as a string of Protein Blocks. Predicting the local structure of a protein in terms of protein blocks is the general objective of this work. A new approach, PB-kPRED is proposed towards this aim. It involves (i) organizing the structural knowledge in the form of a database of pentapeptide fragments extracted from all protein structures in the PDB and (ii) applying a knowledge-based algorithm that does not rely on any secondary structure predictions and/ or sequence alignment profiles, to scan this database and predict most probable backbone conformations for the protein local structures. Though PB-kPRED uses the structural information from homologues in preference, if available. The predictions were evaluated rigorously on 15,544 query proteins representing a non-redundant subset of the PDB filtered at 30% sequence identity cut-off. We have shown that the kPRED method was able to achieve mean accuracies ranging from 40.8% to 66.3% depending on the availability of homologues. The impact of the different strategies for scanning the database on the prediction was evaluated and is discussed. Our results highlight the usefulness of the method in the context of proteins without any known structural homologues. A scoring function that gives a good estimate of the accuracy of prediction was further developed. This score estimates very well the accuracy of the algorithm (R2 of 0.82). An online version of the tool is provided freely for non-commercial usage at http://www.bo-protscience.fr/kpred/.
2019
Fontaine, Nicolas T; Cadet, Xavier F; Vetrivel, Iyanar
Novel Descriptors and Digital Signal Processing-Based Method for Protein Sequence Activity Relationship Study Article de journal
Dans: International Journal of Molecular Sciences, vol. 20, no. 22, 2019, ISSN: 1422-0067.
@article{ijms20225640,
title = {Novel Descriptors and Digital Signal Processing-Based Method for Protein Sequence Activity Relationship Study},
author = {Nicolas T Fontaine and Xavier F Cadet and Iyanar Vetrivel},
url = {https://www.mdpi.com/1422-0067/20/22/5640},
doi = {10.3390/ijms20225640},
issn = {1422-0067},
year = {2019},
date = {2019-01-01},
journal = {International Journal of Molecular Sciences},
volume = {20},
number = {22},
abstract = {The work aiming to unravel the correlation between protein sequence and function in the absence of structural information can be highly rewarding. We present a new way of considering descriptors from the amino acids index database for modeling and predicting the fitness value of a polypeptide chain. This approach includes the following steps: (i) Calculating Q elementary numerical sequences (Ele_SEQ) depending on the encoding of the amino acid residues, (ii) determining an extended numerical sequence (Ext_SEQ) by concatenating the Q elementary numerical sequences, wherein at least one elementary numerical sequence is a protein spectrum obtained by applying fast Fourier transformation (FFT), and (iii) predicting a value of fitness for polypeptide variants (train and/or validation set). These new descriptors were tested on four sets of proteins of different lengths (GLP-2, TNF alpha, cytochrome P450, and epoxide hydrolase) and activities (cAMP activation, binding affinity, thermostability and enantioselectivity). We show that the use of multiple physicochemical descriptors coupled with the implementation of the FFT, taking into account the interactions between residues of amino acids within the protein sequence, could lead to very significant improvement in the quality of models and predictions. The choice of the descriptor or of the combination of descriptors and/or FFT is dependent on the couple protein/fitness. This approach can provide potential users with value added to existing mutant libraries where screening efforts have so far been unsuccessful in finding improved polypeptide mutants for useful applications.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
The work aiming to unravel the correlation between protein sequence and function in the absence of structural information can be highly rewarding. We present a new way of considering descriptors from the amino acids index database for modeling and predicting the fitness value of a polypeptide chain. This approach includes the following steps: (i) Calculating Q elementary numerical sequences (Ele_SEQ) depending on the encoding of the amino acid residues, (ii) determining an extended numerical sequence (Ext_SEQ) by concatenating the Q elementary numerical sequences, wherein at least one elementary numerical sequence is a protein spectrum obtained by applying fast Fourier transformation (FFT), and (iii) predicting a value of fitness for polypeptide variants (train and/or validation set). These new descriptors were tested on four sets of proteins of different lengths (GLP-2, TNF alpha, cytochrome P450, and epoxide hydrolase) and activities (cAMP activation, binding affinity, thermostability and enantioselectivity). We show that the use of multiple physicochemical descriptors coupled with the implementation of the FFT, taking into account the interactions between residues of amino acids within the protein sequence, could lead to very significant improvement in the quality of models and predictions. The choice of the descriptor or of the combination of descriptors and/or FFT is dependent on the couple protein/fitness. This approach can provide potential users with value added to existing mutant libraries where screening efforts have so far been unsuccessful in finding improved polypeptide mutants for useful applications.
2018
Cadet, Frédéric; Fontaine, Nicolas; Vetrivel, Iyanar; Chong, Matthieu Ng Fuk; Savriama, Olivier; Cadet, Xavier; Charton, Philippe
Application of fourier transform and proteochemometrics principles to protein engineering Article de journal
Dans: BMC bioinformatics, vol. 19, no. 1, p. 1–11, 2018.
@article{cadet2018application,
title = {Application of fourier transform and proteochemometrics principles to protein engineering},
author = {Frédéric Cadet and Nicolas Fontaine and Iyanar Vetrivel and Matthieu Ng Fuk Chong and Olivier Savriama and Xavier Cadet and Philippe Charton},
doi = {10.1186/s12859-018-2407-8},
year = {2018},
date = {2018-01-01},
journal = {BMC bioinformatics},
volume = {19},
number = {1},
pages = {1--11},
publisher = {BioMed Central},
abstract = {Connecting the dots between the protein sequence and its function is of fundamental interest for protein engineers. In-silico methods are useful in this quest especially when structural information is not available. In this study we propose a mutant library screening tool called iSAR (innovative Sequence Activity Relationship) that relies on the physicochemical properties of the amino acids, digital signal processing and partial least squares regression to uncover these sequence-function correlations.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Connecting the dots between the protein sequence and its function is of fundamental interest for protein engineers. In-silico methods are useful in this quest especially when structural information is not available. In this study we propose a mutant library screening tool called iSAR (innovative Sequence Activity Relationship) that relies on the physicochemical properties of the amino acids, digital signal processing and partial least squares regression to uncover these sequence-function correlations.
2012
Pavitra, BV; Shanbhogue, Ashish K; Vetrivel, Iyanar; Earanna, N
Genetic diversity of Bradyrhizobia isolated from vegetable soybean (Glycine max L.) genotypes. Article de journal
Dans: Environment and Ecology, vol. 30, no. 3A, p. 726–730, 2012.
@article{pavitra2012genetic,
title = {Genetic diversity of Bradyrhizobia isolated from vegetable soybean (Glycine max L.) genotypes.},
author = {BV Pavitra and Ashish K Shanbhogue and Iyanar Vetrivel and N Earanna},
url = {https://www.researchgate.net/profile/Iyanar_Vetrivel/publication/332275822_Genetic_Diversity_of_Bradyrhizobia_Isolated_from_Vegetable_Soybean_Glycine_max_L_Genotypes/links/5cab6e59299bf118c4bae7a0/Genetic-Diversity-of-Bradyrhizobia-Isolated-from-Vegetable-Soybean-Glycine-max-L-Genotypes.pdf},
year = {2012},
date = {2012-01-01},
journal = {Environment and Ecology},
volume = {30},
number = {3A},
pages = {726--730},
publisher = {MKK Publication},
abstract = {Bradyrhizobia associated with 12 different vegetable soybean genotypes were isolated and characterized. Genetic diversity of these isolates were analyzed using randomly amplified plymorhic DNA (RAPD) primers in PCR. The 10 random primers produced total of 89 amplified products of which 59 were found polymorphic. The 12 strains formed 2 major clusters and three sub clusters. The strains VSBR-1, 2 and 3 formed one cluster. The strains VSBR-4, 6, and 12 formed the second cluster and the third cluster was with the strains VSBR-5, 7, 8, 10, 9, and 11. This indicated the diversity between the bradyrhizobial strains isolated from 12 different soybean genotypes.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Bradyrhizobia associated with 12 different vegetable soybean genotypes were isolated and characterized. Genetic diversity of these isolates were analyzed using randomly amplified plymorhic DNA (RAPD) primers in PCR. The 10 random primers produced total of 89 amplified products of which 59 were found polymorphic. The 12 strains formed 2 major clusters and three sub clusters. The strains VSBR-1, 2 and 3 formed one cluster. The strains VSBR-4, 6, and 12 formed the second cluster and the third cluster was with the strains VSBR-5, 7, 8, 10, 9, and 11. This indicated the diversity between the bradyrhizobial strains isolated from 12 different soybean genotypes.