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40 results on '"Goswami, Debanjan"'

1. Active Learning for Video Classification with Frame Level Queries

Author

Goswami, Debanjan and Chakraborty, Shayok

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Deep learning algorithms have pushed the boundaries of computer vision research and have depicted commendable performance in a variety of applications. However, training a robust deep neural network necessitates a large amount of labeled training data, acquiring which involves significant time and human effort. This problem is even more serious for an application like video classification, where a human annotator has to watch an entire video end-to-end to furnish a label. Active learning algorithms automatically identify the most informative samples from large amounts of unlabeled data; this tremendously reduces the human annotation effort in inducing a machine learning model, as only the few samples that are identified by the algorithm, need to be labeled manually. In this paper, we propose a novel active learning framework for video classification, with the goal of further reducing the labeling onus on the human annotators. Our framework identifies a batch of exemplar videos, together with a set of informative frames for each video; the human annotator needs to merely review the frames and provide a label for each video. This involves much less manual work than watching the complete video to come up with a label. We formulate a criterion based on uncertainty and diversity to identify the informative videos and exploit representative sampling techniques to extract a set of exemplar frames from each video. To the best of our knowledge, this is the first research effort to develop an active learning framework for video classification, where the annotators need to inspect only a few frames to produce a label, rather than watching the end-to-end video.

Published
2023

2. Machine learning–driven multiscale modeling reveals lipid-dependent dynamics of RAS signaling proteins

Author

Ingólfsson, Helgi I, Neale, Chris, Carpenter, Timothy S, Shrestha, Rebika, López, Cesar A, Tran, Timothy H, Oppelstrup, Tomas, Bhatia, Harsh, Stanton, Liam G, Zhang, Xiaohua, Sundram, Shiv, Di Natale, Francesco, Agarwal, Animesh, Dharuman, Gautham, Kokkila Schumacher, Sara IL, Turbyville, Thomas, Gulten, Gulcin, Van, Que N, Goswami, Debanjan, Jean-Francois, Frantz, Agamasu, Constance, Chen, De, Hettige, Jeevapani J, Travers, Timothy, Sarkar, Sumantra, Surh, Michael P, Yang, Yue, Moody, Adam, Liu, Shusen, Van Essen, Brian C, Voter, Arthur F, Ramanathan, Arvind, Hengartner, Nicolas W, Simanshu, Dhirendra K, Stephen, Andrew G, Bremer, Peer-Timo, Gnanakaran, S, Glosli, James N, Lightstone, Felice C, McCormick, Frank, Nissley, Dwight V, and Streitz, Frederick H

Subjects
Networking and Information Technology R&D (NITRD), Generic health relevance, Cell Membrane, Humans, Lipids, Machine Learning, Molecular Dynamics Simulation, Protein Multimerization, Proto-Oncogene Proteins p21(ras), Signal Transduction, RAS dynamics, RAS-membrane biology, multiscale modeling, massive parallel simulations, multiscale infrastructure
Abstract

RAS is a signaling protein associated with the cell membrane that is mutated in up to 30% of human cancers. RAS signaling has been proposed to be regulated by dynamic heterogeneity of the cell membrane. Investigating such a mechanism requires near-atomistic detail at macroscopic temporal and spatial scales, which is not possible with conventional computational or experimental techniques. We demonstrate here a multiscale simulation infrastructure that uses machine learning to create a scale-bridging ensemble of over 100,000 simulations of active wild-type KRAS on a complex, asymmetric membrane. Initialized and validated with experimental data (including a new structure of active wild-type KRAS), these simulations represent a substantial advance in the ability to characterize RAS-membrane biology. We report distinctive patterns of local lipid composition that correlate with interfacially promiscuous RAS multimerization. These lipid fingerprints are coupled to RAS dynamics, predicted to influence effector binding, and therefore may be a mechanism for regulating cell signaling cascades.

Published
2022

3. Undermining Glutaminolysis Bolsters Chemotherapy While NRF2 Promotes Chemoresistance in KRAS-Driven Pancreatic Cancers

Author

Mukhopadhyay, Suman, Goswami, Debanjan, Adiseshaiah, Pavan P, Burgan, William, Yi, Ming, Guerin, Theresa M, Kozlov, Serguei V, Nissley, Dwight V, and McCormick, Frank

Subjects
Pancreatic Cancer, Digestive Diseases, Cancer, Rare Diseases, Orphan Drug, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, 2.1 Biological and endogenous factors, Aetiology, Animals, Antimetabolites, Antineoplastic, Carcinoma, Pancreatic Ductal, Cell Line, Tumor, Deoxycytidine, Drug Resistance, Neoplasm, Glutaminase, Glutamine, Heterografts, Humans, Mice, Mice, Nude, Mutation, NF-E2-Related Factor 2, Neoplasm Proteins, Pancreatic Neoplasms, Prognosis, Proto-Oncogene Proteins p21(ras), Random Allocation, Tissue Array Analysis, Up-Regulation, Gemcitabine, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

Pancreatic cancer is a disease with limited therapeutic options. Resistance to chemotherapies poses a significant clinical challenge for patients with pancreatic cancer and contributes to a high rate of recurrence. Oncogenic KRAS, a critical driver of pancreatic cancer, promotes metabolic reprogramming and upregulates NRF2, a master regulator of the antioxidant network. Here, we show that NRF2 contributed to chemoresistance and was associated with a poor prognosis in patients with pancreatic cancer. NRF2 activation metabolically rewired and elevated pathways involved in glutamine metabolism. This curbed chemoresistance in KRAS-mutant pancreatic cancers. In addition, manipulating glutamine metabolism restrained the assembly of stress granules, an indicator of chemoresistance. Glutaminase inhibitors sensitized chemoresistant pancreatic cancer cells to gemcitabine, thereby improving the effectiveness of chemotherapy. This therapeutic approach holds promise as a novel therapy for patients with pancreatic cancer harboring KRAS mutation. SIGNIFICANCE: These findings illuminate the mechanistic features of KRAS-mediated chemoresistance and provide a rationale for exploiting metabolic reprogramming in pancreatic cancer cells to confer therapeutic opportunities that could be translated into clinical trials. GRAPHICAL ABSTRACT: http://cancerres.aacrjournals.org/content/canres/80/8/1630/F1.large.jpg.

Published
2020

4. Membrane interactions of the globular domain and the hypervariable region of KRAS4b define its unique diffusion behavior.

Author

Goswami, Debanjan, Chen, De, Yang, Yue, Gudla, Prabhakar R, Columbus, John, Worthy, Karen, Rigby, Megan, Wheeler, Madeline, Mukhopadhyay, Suman, Powell, Katie, Burgan, William, Wall, Vanessa, Esposito, Dominic, Simanshu, Dhirendra K, Lightstone, Felice C, Nissley, Dwight V, McCormick, Frank, and Turbyville, Thomas

Subjects
RAS diffusion, atomistic simulation, cancer, cancer biology, human, mouse, physics of living systems, single molecule tracking, Biochemistry and Cell Biology
Abstract

The RAS proteins are GTP-dependent switches that regulate signaling pathways and are frequently mutated in cancer. RAS proteins concentrate in the plasma membrane via lipid-tethers and hypervariable region side-chain interactions in distinct nano-domains. However, little is known about RAS membrane dynamics and the details of RAS activation of downstream signaling. Here, we characterize RAS in live human and mouse cells using single-molecule-tracking methods and estimate RAS mobility parameters. KRAS4b exhibits confined mobility with three diffusive states distinct from the other RAS isoforms (KRAS4a, NRAS, and HRAS); and although most of the amino acid differences between RAS isoforms lie within the hypervariable region, the additional confinement of KRAS4b is largely determined by the protein's globular domain. To understand the altered mobility of an oncogenic KRAS4b, we used complementary experimental and molecular dynamics simulation approaches to reveal a detailed mechanism.

Published
2020

8. Machine Learning-Driven Multiscale Modeling: Bridging the Scales with a Next-Generation Simulation Infrastructure

Author

Ingólfsson, Helgi I., primary, Bhatia, Harsh, additional, Aydin, Fikret, additional, Oppelstrup, Tomas, additional, López, Cesar A., additional, Stanton, Liam G., additional, Carpenter, Timothy S., additional, Wong, Sergio, additional, Di Natale, Francesco, additional, Zhang, Xiaohua, additional, Moon, Joseph Y., additional, Stanley, Christopher B., additional, Chavez, Joseph R., additional, Nguyen, Kien, additional, Dharuman, Gautham, additional, Burns, Violetta, additional, Shrestha, Rebika, additional, Goswami, Debanjan, additional, Gulten, Gulcin, additional, Van, Que N., additional, Ramanathan, Arvind, additional, Van Essen, Brian, additional, Hengartner, Nicolas W., additional, Stephen, Andrew G., additional, Turbyville, Thomas, additional, Bremer, Peer-Timo, additional, Gnanakaran, S., additional, Glosli, James N., additional, Lightstone, Felice C., additional, Nissley, Dwight V., additional, and Streitz, Frederick H., additional

Published
2023
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16. Machine Learning-driven Multiscale Modeling Reveals Lipid-Dependent Dynamics of RAS Signaling Proteins

Author

Ingolfsson, Helgi, primary, Neale, Chris, additional, Carpenter, Timothy, additional, Shrestha, Rebika, additional, Lopez, Cesar, additional, Tran, Timothy, additional, Oppelstrup, Tomas, additional, Bhatia, Harsh, additional, Stanton, Liam, additional, Zhang, Xiaohua, additional, Sundram, Shiv, additional, Natale, Francesco Di, additional, Agarwal, Animesh, additional, Dharuman, Gautham, additional, Schumacher, Sara Kokkila, additional, Turbyville, Thomas, additional, Gulten, Gulcin, additional, Van, Que, additional, Goswami, Debanjan, additional, Jean-Francios, Frantz, additional, Agamasu, Constance, additional, Chen, De, additional, Hettige, Jeevapani, additional, Travers, Timothy, additional, Sarkar, Sumantra, additional, Surh, Michael, additional, Yang, Yue, additional, Moody, Adam, additional, Liu, Shusen, additional, Essen, Brian Van, additional, Voter, Arthur, additional, Ramanathan, Arvind, additional, Hengartner, Nicolas, additional, Simanshu, Dhirendra, additional, Stephen, Andrew, additional, Bremer, Peer-Timo, additional, Gnanakaran, S, additional, Glosli, James, additional, Lightstone, Felice, additional, McCormick, Frank, additional, Nissley, Dwight, additional, and Streitz, Frederick, additional

Published
2020
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21. Membrane interactions of the globular domain and the hypervariable region of KRAS4b define its unique diffusion behavior

Author

Goswami, Debanjan, primary, Chen, De, additional, Yang, Yue, additional, Gudla, Prabhakar R, additional, Columbus, John, additional, Worthy, Karen, additional, Rigby, Megan, additional, Wheeler, Madeline, additional, Mukhopadhyay, Suman, additional, Powell, Katie, additional, Burgan, William, additional, Wall, Vanessa, additional, Esposito, Dominic, additional, Simanshu, Dhirendra K, additional, Lightstone, Felice C, additional, Nissley, Dwight V, additional, McCormick, Frank, additional, and Turbyville, Thomas, additional

Published
2020
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22. Author response: Membrane interactions of the globular domain and the hypervariable region of KRAS4b define its unique diffusion behavior

Author

Goswami, Debanjan, primary, Chen, De, additional, Yang, Yue, additional, Gudla, Prabhakar R, additional, Columbus, John, additional, Worthy, Karen, additional, Rigby, Megan, additional, Wheeler, Madeline, additional, Mukhopadhyay, Suman, additional, Powell, Katie, additional, Burgan, William, additional, Wall, Vanessa, additional, Esposito, Dominic, additional, Simanshu, Dhirendra K, additional, Lightstone, Felice C, additional, Nissley, Dwight V, additional, McCormick, Frank, additional, and Turbyville, Thomas, additional

Published
2020
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23. Abstract 3373: Identification of KRAS membrane bound states using an integrated computational and experimental approach

Author

Stephen, Andrew G., primary, Agarwal, Animesh, additional, Garcia, Angel E., additional, Gnanakaran, Gnana S., additional, Hettige, Jeevapani, additional, Neale, Christopher, additional, Travers, Timothy, additional, Bhatia, Harsh, additional, Bremer, Peer-Timo, additional, Carpenter, Tim, additional, Glosli, Jim, additional, Ingolfsson, Helgi, additional, Karande, Piyush, additional, Lightstone, Felice, additional, Oppelstrup, Tomas, additional, Stanton, Liam, additional, Sundram, Shiv, additional, Zhang, Xiaohua, additional, Bhowmik, Debsindhu, additional, Ramanathan, Arvind, additional, Stanley, Christopher, additional, Goswami, Debanjan, additional, Gulten, Gulcin, additional, Jean-Francios, Frantz, additional, Simanshu, Dhirendra, additional, Turbyville, Tommy, additional, Shrestha, Rebika, additional, Van, Que, additional, McCormick, Frank, additional, Nissley, Dwight, additional, Streitz, Fred, additional, and Agamasu, Constance, additional

Published
2019
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29. LTP requires a unique postsynaptic SNARE fusion machinery

Author

National Institutes of Health (US), Ministerio de Educación (España), Jurado, Sandra, Goswami, Debanjan, Zhang, Yingsha, Miñano Molina, Alfredo J., Südhof, Thomas C., Malenka, Robert C., National Institutes of Health (US), Ministerio de Educación (España), Jurado, Sandra, Goswami, Debanjan, Zhang, Yingsha, Miñano Molina, Alfredo J., Südhof, Thomas C., and Malenka, Robert C.

Abstract

Membrane fusion during exocytosis is mediated by assemblies of SNARE (soluble NSF-attachment protein receptor) and SM (Sec1/Munc18-like) proteins. The SNARE/SM proteins involved in vesicle fusion during neurotransmitter release are well understood, whereas little is known about the protein machinery that mediates activity-dependent AMPA receptor (AMPAR) exocytosis during long-term potentiation (LTP). Using direct measurements of LTP in acute hippocampal slices and an in vitro LTP model of stimulated AMPAR exocytosis, we demonstrate that the Q-SNARE proteins syntaxin-3 and SNAP-47 are required for regulated AMPAR exocytosis during LTP but not for constitutive basal AMPAR exocytosis. In contrast, the R-SNARE protein synaptobrevin-2/VAMP2 contributes to both regulated and constitutive AMPAR exocytosis. Both the central complexin-binding and the N-terminal Munc18-binding sites of syntaxin-3 are essential for its postsynaptic role in LTP. Thus, postsynaptic exocytosis of AMPARs during LTP is mediated by a unique fusion machinery that is distinct from that used during presynaptic neurotransmitter release.

Published
2013

38. Lifetime of actin-dependent protein nanoclusters

Author

Sarkar, Sumantra and Goswami, Debanjan

Abstract

Protein nanoclusters (PNCs) are dynamic collections of a few proteins that spatially organize in nanometer-length clusters. PNCs are one of the principal forms of spatial organization of membrane proteins, and they have been shown or hypothesized to be important in various cellular processes, including cell signaling. PNCs show remarkable diversity in size, shape, and lifetime. In particular, the lifetime of PNCs can vary over a wide range of timescales. The diversity in size and shape can be explained by the interaction of the clustering proteins with the actin cytoskeleton or the lipid membrane, but very little is known about the processes that determine the lifetime of the nanoclusters. In this paper, using mathematical modeling of the cluster dynamics, we model the biophysical processes that determine the lifetime of actin-dependent PNCs. In particular, we investigated the role of actin aster fragmentation, which had been suggested to be a key determinant of the PNC lifetime, and we found that it is important only for a small class of PNCs. A simple extension of our model allowed us to investigate the kinetics of protein-ligand interaction near PNCs. We found an anomalous increase in the lifetime of ligands near PNCs, which agrees remarkably well with experimental data on RAS-RAF kinetics. In particular, analysis of the RAS-RAF data through our model provides falsifiable predictions and novel hypotheses that will not only shed light on the role of RAS-RAF kinetics in various cancers, but also will be useful in studying membrane protein clustering in general.

Published
2022
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40. Dynamic imaging of homo-FRET in live cells by fluorescence anisotropy microscopy.

Author

Ghosh S, Saha S, Goswami D, Bilgrami S, and Mayor S

Subjects
Animals, Cell Membrane metabolism, Drosophila cytology, Fluorescence Polarization instrumentation, Fluorescence Polarization methods, Image Processing, Computer-Assisted, Lipid Metabolism, Microscopy, Confocal instrumentation, Cell Tracking methods, Fluorescence Resonance Energy Transfer methods, Green Fluorescent Proteins, Microscopy, Confocal methods, Microscopy, Fluorescence methods
Abstract

Multiple lipid and protein components of the plasma membrane of a living cell are organized, both compositionally and functionally, at different spatial and temporal scales. For instance, Rab protein domains in membranes the clathrin-coated pit, or the immunological synapse are exquisite examples of functional compartmentalization in cell membranes. These assemblies consist in part of nanoscale complexes of lipids and proteins and are necessary to facilitate some specific sorting and signaling functions. It is evident that cellular functions require a regulated spatiotemporal organization of components at the nanoscale, often comprising of countable number of molecular species. Here, we describe multiple homo-FRET-based imaging methods that provide information about nanoscale interactions between fluorescently tagged molecules in live cells, at optically resolved spatial resolution., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published
2012
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