Your search keyword '"Shrinivas, Krishna"' showing total 40 results

1. A model for organization and regulation of nuclear condensates by gene activity

Author

Schede, Halima H., Natarajan, Pradeep, Chakraborty, Arup K., and Shrinivas, Krishna

Published

2023

2. The phosphatidylinositol-transfer protein Nir3 promotes PI(4,5)P2 replenishment in response to TCR signaling during T cell development and survival

Author

Lu, Wen, Helou, Ynes A., Shrinivas, Krishna, Liou, Jen, Au-Yeung, Byron B., and Weiss, Arthur

Published

2023

3. A model for cis-regulation of transcriptional condensates and gene expression by proximal lncRNAs

Author

Natarajan, Pradeep, Shrinivas, Krishna, and Chakraborty, Arup K.

Published

2023

4. Phase separation in fluids with many interacting components

Author

Shrinivas, Krishna and Brenner, Michael P.

Published

2021

5. Heterocyclic system containing bridgehead nitrogen atom: Substituted 1,2,3-triazolo [3,4-b]-1,3,4-thiadiazole derivative useful for the treatment of breast cancer and other diseases

Author

Sonawane, Rushikesh Kishor, Nere, Karishma Ravindra, and Mohite, Shrinivas Krishna

Published

2022

6. A stochastic chemical dynamic approach to correlate autoimmunity and optimal vitamin-D range

Author

Roy, Susmita, Shrinivas, Krishna, and Bagchi, Biman

Subjects

Quantitative Biology - Molecular Networks

Abstract

Motivated by several recent experimental observations that vitamin-D could interact with antigen presenting cells (APCs) and T-lymphocyte cells (T-cells) to promote and to regulate different stages of immune response, we developed a coarse grained kinetic model in an attempt to quantify the role of vitamin-D in immunomodulatory responses. Our kinetic model, developed using the ideas of chemical network theory, leads to a system of nine coupled equations that we solve both by direct and by stochastic (Gillespie) methods. Both the analyses consistently provide detail information on the dependence of immune response to the variation of critical rate parameters. We find that although vitamin-D plays a negligible role in the initial immune response, it exerts a profound influence in the long term, especially in helping the system to achieve a new, stable steady state. The study explores the role of vitamin-D in preserving an observed bistability in the phase diagram (spanned by system parameters) of immune regulation, thus allowing the response to tolerate a wide range of pathogenic stimulation which could help in resisting autoimmune diseases. We also study how vitamin-D affects the time dependent population of dendritic cells that connect between innate and adaptive immune responses. Variations in dose dependent response in anti-inflammatory and pro-inflammatory T-cell populations to vitamin-D correlate well with recent experimental results. Our kinetic model allows for an estimation of the range of optimum level of vitamin-D required for smooth functioning of the immune system and for control of both hyper-regulation and inflammation. Most importantly, the present study reveals that an overdose or toxic level of vitamin-D or any steroid analogue could give rise to too large a tolerant response, leading to an inefficacy in adaptive immune function., Comment: arXiv admin note: substantial text overlap with arXiv:1304.7193

Published

2014

7. Vitamin D sensitivity to the immune responses and autoimmunity: A chemical network model study

Author

Roy, Susmita, Shrinivas, Krishna, and Bagchi, Biman

Subjects

Quantitative Biology - Molecular Networks, Quantitative Biology - Cell Behavior

Abstract

Although Vitamin D is believed to be involved in a large number of immune responses our understanding of these processes at cellular level remained at infancy. We develop and solve a coarse grained kinetic network model to quantify the effects of variation of vitamin D on human immunity. The system of equations accounts for known inter-relation between active and inactive vitamin D, antigen presenting cells, effector T cells, regulatory T cells and pathogen. Both time dependent and steady state solutions are obtained. The time dependent solution of the system of equations reveals that the immune response is rather strongly regulated in presence of vitamin D. We found quantitatively that lower than optimum levels of concentration of active vitamin D correspond to weak regulation where, once a pathogen/antigen enters the body, the nature of the immune response would be less regulatory and hence more aggressive, or inflammatory. The steady state solution of our model shows that vitamin D enhances the tolerance level of immune system, thereby increasing resistance to autoimmune diseases. Our model and accompanied numerical analyses reveal another important aspect of immunity: While extremely low levels of vitamin D could lead to increased risk of autoimmune responses, an overdose (toxic) level would give rise to too large a tolerant response, leading to the increased risk of tumors and cancerous cell growth., Comment: 44 pages, 9 figures

Published

2013

8. Evolution of weak cooperative interactions for biological specificity

Author

Gao, Ang, Shrinivas, Krishna, Lepeudry, Paul, Suzuki, Hiroshi I., Sharp, Phillip A., and Chakraborty, Arup K.

Published

2018

9. Coactivator condensation at super-enhancers links phase separation and gene control

Author

Sabari, Benjamin R., Dall’Agnese, Alessandra, Boija, Ann, Klein, Isaac A., Coffey, Eliot L., Shrinivas, Krishna, Abraham, Brian J., Hannett, Nancy M., Zamudio, Alicia V., Manteiga, John C., Li, Charles H., Guo, Yang E., Day, Daniel S., Schuijers, Jurian, Vasile, Eliza, Malik, Sohail, Hnisz, Denes, Lee, Tong Ihn, Cisse, Ibrahim I., Roeder, Robert G., Sharp, Phillip A., Chakraborty, Arup K., and Young, Richard A.

Published

2018

10. Pol II phosphorylation regulates a switch between transcriptional and splicing condensates

Author

Guo, Yang Eric, Manteiga, John C., Henninger, Jonathan E., Sabari, Benjamin R., Dall’Agnese, Alessandra, Hannett, Nancy M., Spille, Jan-Hendrik, Afeyan, Lena K., Zamudio, Alicia V., Shrinivas, Krishna, Abraham, Brian J., Boija, Ann, Decker, Tim-Michael, Rimel, Jenna K., Fant, Charli B., Lee, Tong Ihn, Cisse, Ibrahim I., Sharp, Phillip A., Taatjes, Dylan J., and Young, Richard A.

Published

2019

11. Heterocyclic system containing bridgehead nitrogen atom: Substituted 1,2,3-Triazolo [3,4-b]-1,3,4-Thiadiazole derivative useful for the treatment of breast cancer and other diseases

Author

Rushikesh Kishor Sonawane, Karishma Ravindra Nere, and Shrinivas Krishna Mohite

Abstract

There has been considerable interest in the development of novel compounds with anticonvulsant, analgesic, anti-inflammatory, antimicrobial, antimycobecterial, antitumour, and antitubercular activities. 1,3,4-thiadiazole constitute an important class of compound for new drug development. They have interesting pharmacophore that display a broad spectrum of Pharmacological activity. The 1,3,4-thiadiazole compound is an interesting heterocycling group that has been used to synthesize a variety of useful bioactive compounds. The stability of thiadiazole nucleus has inspired medicinal chemist to carry out various structural variation in the ring. The marketed drugs such as acetazolamide and methazolamide etc showed their therapeutic potential Therefore; many researchers have synthesized these compounds as target structures and evaluated their biological activities. This review highlights the various Pharmacological activities associated with 1,3,4-thiadiazole ring system.

Published

2022

12. The phosphatidylinositol-transfer protein Nir3 promotes PI(4,5)P2 replenishment in response to TCR signaling during T cell development and survival

Author

Lu, Wen, primary, Helou, Ynes A., additional, Shrinivas, Krishna, additional, Liou, Jen, additional, Au-Yeung, Byron B., additional, and Weiss, Arthur, additional

Published

2022

13. Multiphase coexistence capacity in complex fluids

Author

Shrinivas, Krishna, primary and Brenner, Michael P., additional

Published

2022

14. Organization and regulation of nuclear condensates by gene activity

Author

Schede, Halima H., primary, Natarajan, Pradeep, additional, Chakraborty, Arup K., additional, and Shrinivas, Krishna, additional

Published

2022

15. RNA-Mediated Feedback Control of Transcriptional Condensates

Author

Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Koch Institute for Integrative Cancer Research at MIT, Ragon Institute of MGH, MIT and Harvard, Henninger, Jonathan E, Oksuz, Ozgur, Shrinivas, Krishna, Sagi, Ido, LeRoy, Gary, Zheng, Ming M, Andrews, J Owen, Zamudio, Alicia V, Lazaris, Charalampos, Hannett, Nancy M, Lee, Tong Ihn, Sharp, Phillip A, Cissé, Ibrahim I, Chakraborty, Arup K, Young, Richard A, Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Koch Institute for Integrative Cancer Research at MIT, Ragon Institute of MGH, MIT and Harvard, Henninger, Jonathan E, Oksuz, Ozgur, Shrinivas, Krishna, Sagi, Ido, LeRoy, Gary, Zheng, Ming M, Andrews, J Owen, Zamudio, Alicia V, Lazaris, Charalampos, Hannett, Nancy M, Lee, Tong Ihn, Sharp, Phillip A, Cissé, Ibrahim I, Chakraborty, Arup K, and Young, Richard A

Abstract

© 2020 Elsevier Inc. During the early steps of transcription initiation, nascent RNAs stimulate transcriptional condensate formation, whereas the burst of RNAs produced during elongation stimulates condensate dissolution.

Published

2022

16. Evolution of weak cooperative interactions for biological specificity

Author

Gao, Ang, Shrinivas, Krishna, Lepeudry, Paul, Suzuki, Hiroshi I., Sharp, Phillip A., Chakraborty, Arup K., Gao, Ang, Shrinivas, Krishna, Lepeudry, Paul, Suzuki, Hiroshi I., Sharp, Phillip A., and Chakraborty, Arup K.

Abstract

© 2018 National Academy of Sciences. All rights reserved. A hallmark of biological systems is that particular functions and outcomes are realized in specific contexts, such as when particular signals are received. One mechanism for mediating specificity is described by Fisher’s “lock and key” metaphor, exemplified by enzymes that bind selectively to a particular substrate via specific finely tuned interactions. Another mechanism, more prevalent in multicellular organisms, relies on multivalent weak cooperative interactions. Its importance has recently been illustrated by the recognition that liquid-liquid phase transitions underlie the formation of mem-braneless condensates that perform specific cellular functions. Based on computer simulations of an evolutionary model, we report that the latter mechanism likely became evolutionarily prominent when a large number of tasks had to be performed specifically for organisms to function properly. We find that the emergence of weak cooperative interactions for mediating specificity results in organisms that can evolve to accomplish new tasks with fewer, and likely less lethal, mutations. We argue that this makes the system more capable of undergoing evolutionary changes robustly, and thus this mechanism has been repeatedly positively selected in increasingly complex organisms. Specificity mediated by weak cooperative interactions results in some useful cross-reactivity for related tasks, but at the same time increases susceptibility to misregulation that might lead to pathologies.

Published

2022

17. Partitioning of cancer therapeutics in nuclear condensates

Author

Klein, Isaac A., Boija, Ann, Afeyan, Lena K., Hawken, Susana Wilson, Fan, Mengyang, Dall'Agnese, Alessandra, Oksuz, Ozgur, Henninger, Jonathan E., Shrinivas, Krishna, Sabari, Benjamin R., Sagi, Ido, Clark, Victoria E., Platt, Jesse M., Kar, Mrityunjoy, McCall, Patrick M., Zamudio, Alicia V., Manteiga, John C., Coffey, Eliot L., Li, Charles H., Hannett, Nancy M., Guo, Yang Eric, Decker, Tim-Michael, Lee, Tong Ihn, Zhang, Tinghu, Weng, Jing-Ke, Taatjes, Dylan J., Chakraborty, Arup, Sharp, Phillip A., Chang, Young Tae, Hyman, Anthony A., Gray, Nathanael S., Young, Richard A., Klein, Isaac A., Boija, Ann, Afeyan, Lena K., Hawken, Susana Wilson, Fan, Mengyang, Dall'Agnese, Alessandra, Oksuz, Ozgur, Henninger, Jonathan E., Shrinivas, Krishna, Sabari, Benjamin R., Sagi, Ido, Clark, Victoria E., Platt, Jesse M., Kar, Mrityunjoy, McCall, Patrick M., Zamudio, Alicia V., Manteiga, John C., Coffey, Eliot L., Li, Charles H., Hannett, Nancy M., Guo, Yang Eric, Decker, Tim-Michael, Lee, Tong Ihn, Zhang, Tinghu, Weng, Jing-Ke, Taatjes, Dylan J., Chakraborty, Arup, Sharp, Phillip A., Chang, Young Tae, Hyman, Anthony A., Gray, Nathanael S., and Young, Richard A.

Abstract

© 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works The nucleus contains diverse phase-separated condensates that compartmentalize and concentrate biomolecules with distinct physicochemical properties. Here, we investigated whether condensates concentrate small-molecule cancer therapeutics such that their pharmacodynamic properties are altered. We found that antineoplastic drugs become concentrated in specific protein condensates in vitro and that this occurs through physicochemical properties independent of the drug target. This behavior was also observed in tumor cells, where drug partitioning influenced drug activity. Altering the properties of the condensate was found to affect the concentration and activity of drugs. These results suggest that selective partitioning and concentration of small molecules within condensates contributes to drug pharmacodynamics and that further understanding of this phenomenon may facilitate advances in disease therapy.

Published

2022

18. The phosphatidylinositol-transfer protein Nir3 modulates T cell development and function

Author

Lu, Wen, primary, Helou, Ynes A, additional, Au-Yeung, Byron B, additional, Shrinivas, Krishna, additional, Liou, Jen, additional, and Weiss, Arthur, additional

Published

2022

19. Evolution of weak cooperative interactions for biological specificity

Author

Gao, Ang, Shrinivas, Krishna, Lepeudry, Paul, Suzuki, Hiroshi I, Sharp, Phillip A, Chakraborty, Arup K, Gao, Ang, Shrinivas, Krishna, Lepeudry, Paul, Suzuki, Hiroshi I, Sharp, Phillip A, and Chakraborty, Arup K

Abstract

© 2018 National Academy of Sciences. All rights reserved. A hallmark of biological systems is that particular functions and outcomes are realized in specific contexts, such as when particular signals are received. One mechanism for mediating specificity is described by Fisher’s “lock and key” metaphor, exemplified by enzymes that bind selectively to a particular substrate via specific finely tuned interactions. Another mechanism, more prevalent in multicellular organisms, relies on multivalent weak cooperative interactions. Its importance has recently been illustrated by the recognition that liquid-liquid phase transitions underlie the formation of mem-braneless condensates that perform specific cellular functions. Based on computer simulations of an evolutionary model, we report that the latter mechanism likely became evolutionarily prominent when a large number of tasks had to be performed specifically for organisms to function properly. We find that the emergence of weak cooperative interactions for mediating specificity results in organisms that can evolve to accomplish new tasks with fewer, and likely less lethal, mutations. We argue that this makes the system more capable of undergoing evolutionary changes robustly, and thus this mechanism has been repeatedly positively selected in increasingly complex organisms. Specificity mediated by weak cooperative interactions results in some useful cross-reactivity for related tasks, but at the same time increases susceptibility to misregulation that might lead to pathologies.

Published

2021

20. Enhancer Features that Drive Formation of Transcriptional Condensates

Author

Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Physics, Ragon Institute of MGH, MIT and Harvard, Massachusetts Institute of Technology. Department of Chemistry, Shrinivas, Krishna, Sabari, Benjamin R, Coffey, Eliot L, Klein, Isaac A, Boija, Ann, Zamudio, Alicia V, Schuijers, Jurian, Hannett, Nancy M, Sharp, Phillip A, Young, Richard A, Chakraborty, Arup K, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Massachusetts Institute of Technology. Department of Physics, Ragon Institute of MGH, MIT and Harvard, Massachusetts Institute of Technology. Department of Chemistry, Shrinivas, Krishna, Sabari, Benjamin R, Coffey, Eliot L, Klein, Isaac A, Boija, Ann, Zamudio, Alicia V, Schuijers, Jurian, Hannett, Nancy M, Sharp, Phillip A, Young, Richard A, and Chakraborty, Arup K

Abstract

© 2019 Elsevier Inc. Enhancers are DNA elements that are bound by transcription factors (TFs), which recruit coactivators and the transcriptional machinery to genes. Phase-separated condensates of TFs and coactivators have been implicated in assembling the transcription machinery at particular enhancers, yet the role of DNA sequence in this process has not been explored. We show that DNA sequences encoding TF binding site number, density, and affinity above sharply defined thresholds drive condensation of TFs and coactivators. A combination of specific structured (TF-DNA) and weak multivalent (TF-coactivator) interactions allows for condensates to form at particular genomic loci determined by the DNA sequence and the complement of expressed TFs. DNA features found to drive condensation promote enhancer activity and transcription in cells. Our study provides a framework to understand how the genome can scaffold transcriptional condensates at specific loci and how the universal phenomenon of phase separation might regulate this process. Shrinivas et al. demonstrate that specific types of motif compositions encoded in DNA drive localized formation of transcriptional condensates. These findings explain how phase separation can occur at specific genomic locations and shed light on why only some genomic loci become highly active enhancers.

Published

2021

21. Phase separation in fluids with many interacting components

Author

Shrinivas, Krishna, primary and Brenner, Michael P., additional

Published

2021

22. A Phase Separation Model for Transcriptional Control

Author

Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Shrinivas, Krishna, Young, Richard A., Chakraborty, Arup K., Sharp, Phillip A., Hnisz, Denes, Shrinivas, Krishna,Ph. D.Massachusetts Institute of Technology., Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Shrinivas, Krishna, Young, Richard A., Chakraborty, Arup K., Sharp, Phillip A., Hnisz, Denes, and Shrinivas, Krishna,Ph. D.Massachusetts Institute of Technology.

Abstract

Phase-separated multi-molecular assemblies provide a general regulatory mechanism to compartmentalize biochemical reactions within cells. We propose that a phase separation model explains established and recently described features of transcriptional control. These features include the formation of super-enhancers, the sensitivity of super-enhancers to perturbation, the transcriptional bursting patterns of enhancers, and the ability of an enhancer to produce simultaneous activation at multiple genes. This model provides a conceptual framework to further explore principles of gene control in mammals. Keywords: super-enhancer; enhancer; phase separation; transcription; nuclear body; gene control; bursting; transcriptional burst; co-operativity, National Institutes of Health (U.S.) (Grant HG002668), National Institutes of Health (U.S.) (Grant P01-CA042063), National Cancer Institute (U.S.) (Grant P30-CA14051)

Published

2018

23. Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Author

Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Klein, Isaac A., Sabari, Benjamin R., Dall’Agnese, Alessandra, Coffey, Eliot L., Zamudio, Alicia V., Manteiga, John C., Hannett, Nancy M., Abraham, Brian J., Afeyan, Lena K., Guo, Yang E., Schuijers, Jurian, Lee, Tong Ihn, Taatjes, Dylan J., Young, Richard A., Shrinivas, Krishna,Ph. D.Massachusetts Institute of Technology., Li, Charles H., Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Klein, Isaac A., Sabari, Benjamin R., Dall’Agnese, Alessandra, Coffey, Eliot L., Zamudio, Alicia V., Manteiga, John C., Hannett, Nancy M., Abraham, Brian J., Afeyan, Lena K., Guo, Yang E., Schuijers, Jurian, Lee, Tong Ihn, Taatjes, Dylan J., Young, Richard A., Shrinivas, Krishna,Ph. D.Massachusetts Institute of Technology., and Li, Charles H.

Abstract

Gene expression is controlled by transcription factors (TFs) that consist of DNA-binding domains (DBDs) and activation domains (ADs). The DBDs have been well characterized, but little is known about the mechanisms by which ADs effect gene activation. Here, we report that diverse ADs form phase-separated condensates with the Mediator coactivator. For the OCT4 and GCN4 TFs, we show that the ability to form phase-separated droplets with Mediator in vitro and the ability to activate genes in vivo are dependent on the same amino acid residues. For the estrogen receptor (ER), a ligand-dependent activator, we show that estrogen enhances phase separation with Mediator, again linking phase separation with gene activation. These results suggest that diverse TFs can interact with Mediator through the phase-separating capacity of their ADs and that formation of condensates with Mediator is involved in gene activation., National Institutes of Health (U.S.) (Grant GM123511), National Institutes of Health (U.S.) (Grant GM117370), Swedish Research Council (Postdoctoral Fellowship VR 2017-00372), Damon Runyon Cancer Research Foundation ( Fellowship 2309-17)

Published

2020

24. Pol II phosphorylation regulates a switch between transcriptional and splicing condensates

Author

Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Manteiga, John Colonnese, Spille, Jan Hendrik, Afeyan, Lena K., Zamudio Montes de Oca, Alicia, Shrinivas, Krishna, Cisse, Ibrahim I, Sharp, Phillip A., Young, Richard A., Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Manteiga, John Colonnese, Spille, Jan Hendrik, Afeyan, Lena K., Zamudio Montes de Oca, Alicia, Shrinivas, Krishna, Cisse, Ibrahim I, Sharp, Phillip A., and Young, Richard A.

Abstract

The synthesis of pre-mRNA by RNA polymerase II (Pol II) involves the formation of a transcription initiation complex, and a transition to an elongation complex1–4. The large subunit of Pol II contains an intrinsically disordered C-terminal domain that is phosphorylated by cyclin-dependent kinases during the transition from initiation to elongation, thus influencing the interaction of the C-terminal domain with different components of the initiation or the RNA-splicing apparatus5,6. Recent observations suggest that this model provides only a partial picture of the effects of phosphorylation of the C-terminal domain7–12. Both the transcription-initiation machinery and the splicing machinery can form phase-separated condensates that contain large numbers of component molecules: hundreds of molecules of Pol II and mediator are concentrated in condensates at super-enhancers7,8, and large numbers of splicing factors are concentrated in nuclear speckles, some of which occur at highly active transcription sites9–12. Here we investigate whether the phosphorylation of the Pol II C-terminal domain regulates the incorporation of Pol II into phase-separated condensates that are associated with transcription initiation and splicing. We find that the hypophosphorylated C-terminal domain of Pol II is incorporated into mediator condensates and that phosphorylation by regulatory cyclin-dependent kinases reduces this incorporation. We also find that the hyperphosphorylated C-terminal domain is preferentially incorporated into condensates that are formed by splicing factors. These results suggest that phosphorylation of the Pol II C-terminal domain drives an exchange from condensates that are involved in transcription initiation to those that are involved in RNA processing, and implicates phosphorylation as a mechanism that regulates condensate preference., National Institutes of Health (U.S.) (grant GM123511), National Science Foundation (U.S.) (grant PHY1743900), National Institutes of Health (U.S.) (grant grant R01-GM034277), German Research Foundation (Postdoctoral Fellowship SP 1680/1-1)

Published

2020

25. Abstract GS3-10: Partitioning of cancer therapeutics in nuclear condensates

Author

Klein, Isaac, primary, Boija, Ann, additional, Afeyan, Lena, additional, Hawken, Susana Wilson, additional, Fan, Mengyang, additional, Dall'Agnese, Alessandra, additional, Oksuz, Ozgur, additional, Henninger, Jonathan, additional, Shrinivas, Krishna, additional, Sabari, Benjamin, additional, Sagi, Ido, additional, Clark, Victoria, additional, Platt, Jesse, additional, Kar, Mrityunjoy, additional, McCall, Patrick, additional, Zamudio, Alicia, additional, Mantiega, John, additional, Coffey, Eliot, additional, Li, Charles, additional, Hannett, Nancy, additional, Guo, Yang, additional, Decker, Tim-Michael, additional, Lee, Tong, additional, Zhang, Tinghu, additional, Weng, Jing-Ke, additional, Taatjes, Dylan, additional, Chakraborty, Arup, additional, Sharp, Phillip, additional, Chang, Young Tae, additional, Hyman, Anthony, additional, Gray, Nathanael, additional, and Young, Richard, additional

Published

2021

26. RNA-Mediated Feedback Control of Transcriptional Condensates

Author

Henninger, Jonathan E., primary, Oksuz, Ozgur, additional, Shrinivas, Krishna, additional, Sagi, Ido, additional, LeRoy, Gary, additional, Zheng, Ming M., additional, Andrews, J. Owen, additional, Zamudio, Alicia V., additional, Lazaris, Charalampos, additional, Hannett, Nancy M., additional, Lee, Tong Ihn, additional, Sharp, Phillip A., additional, Cissé, Ibrahim I., additional, Chakraborty, Arup K., additional, and Young, Richard A., additional

Published

2021

27. Partitioning of cancer therapeutics in nuclear condensates

Author

Klein, Isaac A., primary, Boija, Ann, additional, Afeyan, Lena K., additional, Hawken, Susana Wilson, additional, Fan, Mengyang, additional, Dall'Agnese, Alessandra, additional, Oksuz, Ozgur, additional, Henninger, Jonathan E., additional, Shrinivas, Krishna, additional, Sabari, Benjamin R., additional, Sagi, Ido, additional, Clark, Victoria E., additional, Platt, Jesse M., additional, Kar, Mrityunjoy, additional, McCall, Patrick M., additional, Zamudio, Alicia V., additional, Manteiga, John C., additional, Coffey, Eliot L., additional, Li, Charles H., additional, Hannett, Nancy M., additional, Guo, Yang Eric, additional, Decker, Tim-Michael, additional, Lee, Tong Ihn, additional, Zhang, Tinghu, additional, Weng, Jing-Ke, additional, Taatjes, Dylan J., additional, Chakraborty, Arup, additional, Sharp, Phillip A., additional, Chang, Young Tae, additional, Hyman, Anthony A., additional, Gray, Nathanael S., additional, and Young, Richard A., additional

Published

2020

28. DETECTION OF IMIDACLOPRID RESIDUES IN SPINACH BY HPLC AND ITS EFFECT ON ANTIOXIDANT ACTIVITY

Author

Thorat, Swapnali Ashok, primary, Dharanguttikar, Vyankatesh Ravindra, additional, Adnaik, Rahul Shivaji, additional, and Mohite, Shrinivas Krishna, additional

Published

2020

29. Coactivator condensation at super-enhancers links phase separation and gene control

Author

Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Coffey, Eliot Leo, Shrinivas, Krishna, Zamudio Montes de Oca, Alicia, Manteiga, John Colonnese, Li, Charles Han, Vasile, Eliza, Cisse, Ibrahim I, Sharp, Phillip A, Chakraborty, Arup K, Young, Richard A, Sabari, Benjamin R., Dall’Agnese, Alessandra, Boija, Ann, Klein, Isaac A., Abraham, Brian J., Hannett, Nancy M., Guo, Yang E., Day, Daniel S., Schuijers, Jurian, Hnisz, Denes, Lee, Tong Ihn, Sharp, Phillip A., Young, Richard A., Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Coffey, Eliot Leo, Shrinivas, Krishna, Zamudio Montes de Oca, Alicia, Manteiga, John Colonnese, Li, Charles Han, Vasile, Eliza, Cisse, Ibrahim I, Sharp, Phillip A, Chakraborty, Arup K, Young, Richard A, Sabari, Benjamin R., Dall’Agnese, Alessandra, Boija, Ann, Klein, Isaac A., Abraham, Brian J., Hannett, Nancy M., Guo, Yang E., Day, Daniel S., Schuijers, Jurian, Hnisz, Denes, Lee, Tong Ihn, Sharp, Phillip A., and Young, Richard A.

Abstract

Super-enhancers (SEs) are clusters of enhancers that cooperatively assemble a high density of the transcriptional apparatus to drive robust expression of genes with prominent roles in cell identity. Here we demonstrate that the SE-enriched transcriptional coactivators BRD4 and MED1 form nuclear puncta at SEs that exhibit properties of liquid-like condensates and are disrupted by chemicals that perturb condensates. The intrinsically disordered regions (IDRs) of BRD4 and MED1 can form phase-separated droplets, and MED1-IDR droplets can compartmentalize and concentrate the transcription apparatus from nuclear extracts. These results support the idea that coactivators form phase-separated condensates at SEs that compartmentalize and concentrate the transcription apparatus, suggest a role for coactivator IDRs in this process, and offer insights into mechanisms involved in the control of key cell-identity genes., National Institutes of Health (U.S.) (Grant GM123511), National Institutes of Health (U.S.) (Grant P01-CA042063), National Science Foundation (U.S.) (Grant PHY-1743900), National Cancer Institute (U.S.) (Grant P30-CA14051)

Published

2019

30. Enhancer Features that Drive Formation of Transcriptional Condensates

Author

Shrinivas, Krishna, primary, Sabari, Benjamin R., additional, Coffey, Eliot L., additional, Klein, Isaac A., additional, Boija, Ann, additional, Zamudio, Alicia V., additional, Schuijers, Jurian, additional, Hannett, Nancy M., additional, Sharp, Phillip A., additional, Young, Richard A., additional, and Chakraborty, Arup K., additional

Published

2019

31. The phosphatidylinositol-transfer protein Nir3 promotes PI(4,5)P2replenishment in response to TCR signaling during T cell development and survival

Author

Lu, Wen, Helou, Ynes A., Shrinivas, Krishna, Liou, Jen, Au-Yeung, Byron B., and Weiss, Arthur

Abstract

Hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) by phospholipase C-γ (PLCγ1) represents a critical step in T cell antigen receptor (TCR) signaling and subsequent thymocyte and T cell responses. PIP2replenishment following its depletion in the plasma membrane (PM) is dependent on delivery of its precursor phosphatidylinositol (PI) from the endoplasmic reticulum (ER) to the PM. We show that a PI transfer protein (PITP), Nir3 (Pitpnm2), promotes PIP2replenishment following TCR stimulation and is important for T cell development. In Nir3–/–T lineage cells, the PIP2replenishment following TCR stimulation is slower. Nir3deficiency attenuates calcium mobilization in double-positive (DP) thymocytes in response to weak TCR stimulation. This impaired TCR signaling leads to attenuated thymocyte development at TCRβ selection and positive selection as well as diminished mature T cell fitness in Nir3–/–mice. This study highlights the importance of PIP2replenishment mediated by PITPs at ER-PM junctions during TCR signaling.

Published

2022

32. Enhancer features that drive formation of transcriptional condensates

Author

Shrinivas, Krishna, primary, Sabari, Benjamin R., additional, Coffey, Eliot L., additional, Klein, Isaac A., additional, Boija, Ann, additional, Zamudio, Alicia V., additional, Schuijers, Jurian, additional, Hannett, Nancy M., additional, Sharp, Phillip A., additional, Young, Richard A., additional, and Chakraborty, Arup K., additional

Published

2018

33. Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Author

Boija, Ann, primary, Klein, Isaac A., additional, Sabari, Benjamin R., additional, Dall’Agnese, Alessandra, additional, Coffey, Eliot L., additional, Zamudio, Alicia V., additional, Li, Charles H., additional, Shrinivas, Krishna, additional, Manteiga, John C., additional, Hannett, Nancy M., additional, Abraham, Brian J., additional, Afeyan, Lena K., additional, Guo, Yang E., additional, Rimel, Jenna K., additional, Fant, Charli B., additional, Schuijers, Jurian, additional, Lee, Tong Ihn, additional, Taatjes, Dylan J., additional, and Young, Richard A., additional

Published

2018

34. A phase separation model predicts key features of transcriptional control

Author

Hnisz, Denes, Shrinivas, Krishna, Young, Richard A., Chakraborty, Arup K., and Sharp, Phillip A.

Subjects

Transcriptional Activation, Enhancer Elements, Genetic, Eukaryotic Cells, Gene Expression Regulation, Transcription, Genetic, parasitic diseases, Animals, Humans, Models, Biological, Article, Transcription Factors

Abstract

Super-enhancers are large clusters of enhancers that control transcription of genes with prominent roles in cell-type specific processes in healthy and diseased states. A model that explains the spectrum of observations regarding super-enhancer formation, function and dissolution is lacking. Phase-separated multi-molecular assemblies provide an essential regulatory mechanism to compartmentalize biochemical reactions within cells. We propose that a phase separation model explains features of transcriptional control, including the formation of super-enhancers, the sensitivity of super-enhancers to perturbation, and their transcriptional bursting patterns. This model provides a conceptual framework to further explore principles of gene control in mammals.

Published

2017

35. A Self-Consistent Lattice Formulation for Thermodynamic Properties of Multi-Component Polymer Mixtures Adsorbed at Solid Interfaces

Author

Shrinivas, Krishna, primary and Natarajan, Upendra, additional

Published

2018

36. A Phase Separation Model for Transcriptional Control

Author

Hnisz, Denes, primary, Shrinivas, Krishna, additional, Young, Richard A., additional, Chakraborty, Arup K., additional, and Sharp, Phillip A., additional

Published

2017

37. A Stochastic Chemical Dynamic Approach to Correlate Autoimmunity and Optimal Vitamin-D Range

Author

Roy, Susmita, primary, Shrinivas, Krishna, additional, and Bagchi, Biman, additional

Published

2014

38. RNA structure controls assembly of multi-layered paraspeckles

Author

Snead, Wilton T., Shrinivas, Krishna, Babaki, Danial, Weeks, Kevin M., and Gladfelter, Amy S.

Published

2023

39. Coactivator condensation at super-enhancers links phase separation and gene control

Author

Krishna Shrinivas, Ibrahim I Cisse, Robert G. Roeder, Eliot L. Coffey, Daniel S. Day, Arup K. Chakraborty, Phillip A. Sharp, Isaac A. Klein, Benjamin R. Sabari, Yang Eric Guo, Richard A. Young, Brian J. Abraham, Jurian Schuijers, Sohail Malik, John C. Manteiga, Alessandra Dall’Agnese, Tong Ihn Lee, Eliza Vasile, Charles H. Li, Denes Hnisz, Alicia V. Zamudio, Nancy M. Hannett, Ann Boija, Institute for Medical Engineering and Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Coffey, Eliot Leo, Shrinivas, Krishna, Zamudio Montes de Oca, Alicia, Manteiga, John Colonnese, Li, Charles Han, Vasile, Eliza, Cisse, Ibrahim I, Sharp, Phillip A, Chakraborty, Arup K, and Young, Richard A

Subjects

0301 basic medicine, Multidisciplinary, Chemistry, Immunoprecipitation, HEK 293 cells, Fluorescence recovery after photobleaching, Article, MED1, Cell biology, 03 medical and health sciences, 030104 developmental biology, Super-enhancer, Transcription (biology), Coactivator, Enhancer

Abstract

Super-enhancers (SEs) are clusters of enhancers that cooperatively assemble a high density of the transcriptional apparatus to drive robust expression of genes with prominent roles in cell identity. Here we demonstrate that the SE-enriched transcriptional coactivators BRD4 and MED1 form nuclear puncta at SEs that exhibit properties of liquid-like condensates and are disrupted by chemicals that perturb condensates. The intrinsically disordered regions (IDRs) of BRD4 and MED1 can form phase-separated droplets, and MED1-IDR droplets can compartmentalize and concentrate the transcription apparatus from nuclear extracts. These results support the idea that coactivators form phase-separated condensates at SEs that compartmentalize and concentrate the transcription apparatus, suggest a role for coactivator IDRs in this process, and offer insights into mechanisms involved in the control of key cell-identity genes., National Institutes of Health (U.S.) (Grant GM123511), National Institutes of Health (U.S.) (Grant P01-CA042063), National Science Foundation (U.S.) (Grant PHY-1743900), National Cancer Institute (U.S.) (Grant P30-CA14051)

Published

2018

40. A Phase Separation Model for Transcriptional Control

Author

Richard A. Young, Krishna Shrinivas, Denes Hnisz, Phillip A. Sharp, Arup K. Chakraborty, Institute for Medical Engineering and Science, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Chemistry, Massachusetts Institute of Technology. Department of Physics, Koch Institute for Integrative Cancer Research at MIT, Shrinivas, Krishna, Young, Richard A., Chakraborty, Arup K., and Sharp, Phillip A.

Subjects

0301 basic medicine, Genetics, Transcriptional bursting, Regulation of gene expression, Enhancer RNAs, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Bursting, 030104 developmental biology, Super-enhancer, parasitic diseases, Transcriptional regulation, Enhancer, Transcription factor

Abstract

Phase-separated multi-molecular assemblies provide a general regulatory mechanism to compartmentalize biochemical reactions within cells. We propose that a phase separation model explains established and recently described features of transcriptional control. These features include the formation of super-enhancers, the sensitivity of super-enhancers to perturbation, the transcriptional bursting patterns of enhancers, and the ability of an enhancer to produce simultaneous activation at multiple genes. This model provides a conceptual framework to further explore principles of gene control in mammals. Keywords: super-enhancer; enhancer; phase separation; transcription; nuclear body; gene control; bursting; transcriptional burst; co-operativity, National Institutes of Health (U.S.) (Grant HG002668), National Institutes of Health (U.S.) (Grant P01-CA042063), National Cancer Institute (U.S.) (Grant P30-CA14051)

Published

2017