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Your search keyword '"Prates, Érica T."' showing total 15 results
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15 results on '"Prates, Érica T."'

1. Spatial Graph Attention and Curiosity-driven Policy for Antiviral Drug Discovery

Author

Wu, Yulun, Cashman, Mikaela, Choma, Nicholas, Prates, Érica T., Vergara, Verónica G. Melesse, Shah, Manesh, Chen, Andrew, Clyde, Austin, Brettin, Thomas S., de Jong, Wibe A., Kumar, Neeraj, Head, Martha S., Stevens, Rick L., Nugent, Peter, Jacobson, Daniel A., and Brown, James B.

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Quantitative Biology - Biomolecules
Abstract

We developed Distilled Graph Attention Policy Network (DGAPN), a reinforcement learning model to generate novel graph-structured chemical representations that optimize user-defined objectives by efficiently navigating a physically constrained domain. The framework is examined on the task of generating molecules that are designed to bind, noncovalently, to functional sites of SARS-CoV-2 proteins. We present a spatial Graph Attention (sGAT) mechanism that leverages self-attention over both node and edge attributes as well as encoding the spatial structure -- this capability is of considerable interest in synthetic biology and drug discovery. An attentional policy network is introduced to learn the decision rules for a dynamic, fragment-based chemical environment, and state-of-the-art policy gradient techniques are employed to train the network with stability. Exploration is driven by the stochasticity of the action space design and the innovation reward bonuses learned and proposed by random network distillation. In experiments, our framework achieved outstanding results compared to state-of-the-art algorithms, while reducing the complexity of paths to chemical synthesis.

Published
2021

2. Initiation of fatty acid biosynthesis in Pseudomonas putida KT2440

Author

McNaught, Kevin J., Kuatsjah, Eugene, Zahn, Michael, Prates, Érica T., Shao, Huiling, Bentley, Gayle J., Pickford, Andrew R., Gruber, Josephine N., Hestmark, Kelley V., Jacobson, Daniel A., Poirier, Brenton C., Ling, Chen, San Marchi, Myrsini, Michener, William E., Nicora, Carrie D., Sanders, Jacob N., Szostkiewicz, Caralyn J., Veličković, Dušan, Zhou, Mowei, Munoz, Nathalie, Kim, Young-Mo, Magnuson, Jon K., Burnum-Johnson, Kristin E., Houk, K.N., McGeehan, John E., Johnson, Christopher W., and Beckham, Gregg T.

Published
2023
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6. Structural insights into β-1,3-glucan cleavage by a glycoside hydrolase family

Author

Santos, Camila R., Costa, Pedro A. C. R., Vieira, Plínio S., Gonzalez, Sinkler E. T., Correa, Thamy L. R., Lima, Evandro A., Mandelli, Fernanda, Pirolla, Renan A. S., Domingues, Mariane N., Cabral, Lucelia, Martins, Marcele P., Cordeiro, Rosa L., Junior, Atílio T., Souza, Beatriz P., Prates, Érica T., Gozzo, Fabio C., Persinoti, Gabriela F., Skaf, Munir S., and Murakami, Mario T.

Published
2020
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7. Publisher Correction: Structural insights into β-1,3-glucan cleavage by a glycoside hydrolase family

Author

Santos, Camila R., primary, Costa, Pedro A. C. R., additional, Vieira, Plínio S., additional, Gonzalez, Sinkler E. T., additional, Correa, Thamy L. R., additional, Lima, Evandro A., additional, Mandelli, Fernanda, additional, Pirolla, Renan A. S., additional, Domingues, Mariane N., additional, Cabral, Lucelia, additional, Martins, Marcele P., additional, Cordeiro, Rosa L., additional, Junior, Atílio T., additional, Souza, Beatriz P., additional, Prates, Érica T., additional, Gozzo, Fabio C., additional, Persinoti, Gabriela F., additional, Skaf, Munir S., additional, and Murakami, Mario T., additional

Published
2020
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8. Correction: Corrigendum: Molecular characterization of a family 5 glycoside hydrolase suggests an induced-fit enzymatic mechanism

Author

Liberato, Marcelo V., primary, Silveira, Rodrigo L., additional, Prates, Érica T., additional, de Araujo, Evandro A., additional, Pellegrini, Vanessa O. A., additional, Camilo, Cesar M., additional, Kadowaki, Marco A., additional, Neto, Mario de O., additional, Popov, Alexander, additional, Skaf, Munir S., additional, and Polikarpov, Igor, additional

Published
2016
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9. Molecular characterization of a family 5 glycoside hydrolase suggests an induced-fit enzymatic mechanism

Author

Liberato, Marcelo V., primary, Silveira, Rodrigo L., additional, Prates, Érica T., additional, de Araujo, Evandro A., additional, Pellegrini, Vanessa O. A., additional, Camilo, Cesar M., additional, Kadowaki, Marco A., additional, Neto, Mario de O., additional, Popov, Alexander, additional, Skaf, Munir S., additional, and Polikarpov, Igor, additional

Published
2016
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10. X-ray Structure and Molecular Dynamics Simulations of Endoglucanase 3 from Trichoderma harzianum: Structural Organization and Substrate Recognition by Endoglucanases That Lack Cellulose Binding Module

Author

Prates, Érica T., Stanković, Ivana, Silveira, Rodrigo L., Liberato, Marcelo V., Henrique-Silva, Flávio, Pereira, Nei Jr., Polikarpov, Igor, Skaf, Munir S., Prates, Érica T., Stanković, Ivana, Silveira, Rodrigo L., Liberato, Marcelo V., Henrique-Silva, Flávio, Pereira, Nei Jr., Polikarpov, Igor, and Skaf, Munir S.

Abstract

Plant biomass holds a promise for the production of second-generation ethanol via enzymatic hydrolysis, but its utilization as a biofuel resource is currently limited to a large extent by the cost and low efficiency of the cellulolytic enzymes. Considerable efforts have been dedicated to elucidate the mechanisms of the enzymatic process. It is well known that most cellulases possess a catalytic core domain and a carbohydrate binding module (CBM), without which the enzymatic activity can be drastically reduced. However, Cel12A members of the glycosyl hydrolases family 12 (GHF12) do not bear a CBM and yet are able to hydrolyze amorphous cellulose quite efficiently. Here, we use X-ray crystallography and molecular dynamics simulations to unravel the molecular basis underlying the catalytic capability of endoglucanase 3 from Trichoderma harzianum (ThEG3), a member of the GHF12 enzymes that lacks a CBM. A comparative analysis with the Cellulomonas fimi CBM identifies important residues mediating interactions of EG3s with amorphous regions of the cellulose. For instance, three aromatic residues constitute a harboring wall of hydrophobic contacts with the substrate in both ThEG3 and CfCBM structures. Moreover, residues at the entrance of the active site cleft of ThEG3 are identified, which might hydrogen bond to the substrate. We advocate that the ThEG3 residues Asn152 and Glu201 interact with the substrate similarly to the corresponding CfCBM residues Asn81 and Arg75. Altogether, these results show that CBM motifs are incorporated within the ThEG3 catalytic domain and suggest that the enzymatic efficiency is associated with the length and position of the substrate chain, being higher when the substrate interact with the aromatic residues at the entrance of the cleft and the catalytic triad. Our results provide guidelines for rational protein engineering aiming to improve interactions of GHF12 enzymes with cellulosic substrates.

Published
2013

11. X-ray Structure and Molecular Dynamics Simulations of Endoglucanase 3 from Trichoderma harzianum: Structural Organization and Substrate Recognition by Endoglucanases That Lack Cellulose Binding Module

Author

Prates, Érica T., primary, Stankovic, Ivana, additional, Silveira, Rodrigo L., additional, Liberato, Marcelo V., additional, Henrique-Silva, Flávio, additional, Pereira, Nei, additional, Polikarpov, Igor, additional, and Skaf, Munir S., additional

Published
2013
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13. X-ray Structure and Molecular Dynamics Simulations of Endoglucanase 3 from Trichoderma harzianum: Structural Organization and Substrate Recognition by Endoglucanases That Lack Cellulose Binding Module.

Author

Prates, Érica T., Stankovic, Ivana, Silveira, Rodrigo L., Liberato, Marcelo V., Henrique-Silva, Flávio, Pereira Jr, Nei, Polikarpov, Igor, and Skaf, Munir S.

Subjects
*MOLECULAR dynamics, *MOLECULAR structure, *HYDROLASES, *TRICHODERMA harzianum, *MOLECULAR recognition, *CELLULOSE, *PLANT biomass, *X-ray crystallography
Abstract

Plant biomass holds a promise for the production of second-generation ethanol via enzymatic hydrolysis, but its utilization as a biofuel resource is currently limited to a large extent by the cost and low efficiency of the cellulolytic enzymes. Considerable efforts have been dedicated to elucidate the mechanisms of the enzymatic process. It is well known that most cellulases possess a catalytic core domain and a carbohydrate binding module (CBM), without which the enzymatic activity can be drastically reduced. However, Cel12A members of the glycosyl hydrolases family 12 (GHF12) do not bear a CBM and yet are able to hydrolyze amorphous cellulose quite efficiently. Here, we use X-ray crystallography and molecular dynamics simulations to unravel the molecular basis underlying the catalytic capability of endoglucanase 3 from Trichoderma harzianum (ThEG3), a member of the GHF12 enzymes that lacks a CBM. A comparative analysis with the Cellulomonas fimi CBM identifies important residues mediating interactions of EG3s with amorphous regions of the cellulose. For instance, three aromatic residues constitute a harboring wall of hydrophobic contacts with the substrate in both ThEG3 and CfCBM structures. Moreover, residues at the entrance of the active site cleft of ThEG3 are identified, which might hydrogen bond to the substrate. We advocate that the ThEG3 residues Asn152 and Glu201 interact with the substrate similarly to the corresponding CfCBM residues Asn81 and Arg75. Altogether, these results show that CBM motifs are incorporated within the ThEG3 catalytic domain and suggest that the enzymatic efficiency is associated with the length and position of the substrate chain, being higher when the substrate interact with the aromatic residues at the entrance of the cleft and the catalytic triad. Our results provide guidelines for rational protein engineering aiming to improve interactions of GHF12 enzymes with cellulosic substrates. [ABSTRACT FROM AUTHOR]

Published
2013
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14. CHARMM-based parameterization of neutral articaine-A widely used local anesthetic.

Author

Prates, Érica T., Souza, Paulo C. T., Pickholz, Mónica, and Skaf, Munir S.

Subjects
*LOCAL anesthetics, *DENTAL anesthesia, *COMPUTER simulation, *CHEMICAL bonds, *BILAYER lipid membranes, *QUANTUM chemistry, *MOLECULAR dynamics
Abstract

We present a set of CHARMM-based parameters of molecular mechanics force field for neutral articaine (ATC), a potent and widely used local anesthetic in medical and dental applications. Partial atomic charges and effective torsion potentials around four chemical bonds, not available in CHARMM for this molecule, were obtained from quantum chemical calculations. The newly parameterized model was evaluated by examining the behavior of ATC in water and in a phospholipid bilayer using molecular dynamics simulations. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem, 2010 [ABSTRACT FROM AUTHOR]

Published
2011
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