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In genetics and molecular biology, a corepressor is a molecule that represses the expression of genes. [1] In prokaryotes, corepressors are small molecules whereas in eukaryotes, corepressors are proteins. A corepressor does not directly bind to DNA, but instead indirectly regulates gene expression by binding to repressors.

A corepressor downregulates (or represses) the expression of genes by binding to and activating a repressor transcription factor. The repressor in turn binds to a gene's operator sequence (segment of DNA to which a transcription factor binds to regulate gene expression), thereby blocking transcription of that gene.

Corepressor Transcription Factor Complex on Regulatory Element

Function

Prokaryotes

In prokaryotes, the term corepressor is used to denote the activating ligand of a repressor protein. For example, the E. coli tryptophan repressor (TrpR) is only able to bind to DNA and repress transcription of the trp operon when its corepressor tryptophan is bound to it. TrpR in the absence of tryptophan is known as an aporepressor and is inactive in repressing gene transcription. [2] Trp operon encodes enzymes responsible for the synthesis of tryptophan. Hence TrpR provides a negative feedback mechanism that regulates the biosynthesis of tryptophan.

In short tryptophan acts as a corepressor for its own biosynthesis. [3]

Eukaryotes

In eukaryotes, a corepressor is a protein that binds to transcription factors. [4] In the absence of corepressors and in the presence of coactivators, transcription factors upregulate gene expression. Coactivators and corepressors compete for the same binding sites on transcription factors. A second mechanism by which corepressors may repress transcriptional initiation when bound to transcription factor/DNA complexes is by recruiting histone deacetylases which catalyze the removal of acetyl groups from lysine residues. This increases the positive charge on histones which strengthens the electrostatic attraction between the positively charged histones and negatively charged DNA, making the DNA less accessible for transcription. [5] [6]

In humans several dozen to several hundred corepressors are known, depending on the level of confidence with which the characterisation of a protein as a corepressors can be made. [7]

Examples of corepressors

NCoR

NCoR (nuclear receptor co-repressor) directly binds to the D and E domains of nuclear receptors and represses their transcriptional activity. [8] [9] [10] Class I histone deacetylases are recruited by NCoR through SIN3, and NCoR directly binds to class II histone deacetylases. [8] [10] [11]

Silencing mediator for retinoid and thyroid-hormone receptor

SMRT (silencing mediator of retinoic acid and thyroid hormone receptor), also known as NCoR2, is an alternatively spliced SRC-1(steroid receptor coactivator-1). [8] [9] It is negatively and positively affected by MAPKKK (mitogen activated protein kinase kinase kinase) and casein kinase 2 phosphorylation, respectively. [8] SMRT has two major mechanisms: first, similar to NCoR, SMRT also recruits class I histone deacetylases through SIN3 and directly binds to class II histone deacetylases. [8] Second, it binds and sequesters components of the general transcriptional machinery, such as transcription factor II B. [8] [10]

Role in biological processes

Corepressors are known to regulate transcription through different activation and inactivation states. [12] [13]

NCoR and SMRT act as a corepressor complex to regulate transcription by becoming activated once the ligand is bound. [12] [13] [14] [15] Knockouts of NCoR resulted in embryo death, indicating its importance in erythrocytic, thymic, and neural system development. [15] [16]

Mutations in certain corepressors can result in deregulation of signals. [13] SMRT contributes to cardiac muscle development, with knockouts of the complex resulting in less developed muscle and improper development. [13]

NCoR has also been found to be an important checkpoint in processes such as inflammation and macrophage activation. [15]

Recent evidence also suggests the role of corepressor RIP140 in metabolic regulation of energy homeostasis. [14]

Clinical significance

Diseases

Since corepressors participate and regulate a vast range of gene expression, it is not surprising that aberrant corepressor activities can cause diseases. [17]

Acute myeloid leukemia (AML) is a highly lethal blood cancer characterized by uncontrolled myeloid cell growth. [18] Two homologous corepressor genes, BCOR (BCL6 corepressor) and BCORL1, are recurrently mutated in AML patients. [19] [20] BCOR works with multiple transcription factors and is known to play vital regulatory roles in embryonic development. [18] [19] Clinical results detected BCOR somatic mutations in ~4% of an unselected group of AML patients, and ~17% in a subset of patients who lack known AML-causing mutations. [18] [19] Similarly, BCORL1 is a corepressor that regulates cellular processes, [21] and was found to be mutated in ~6% of tested AML patients. [18] [20] These studies point out a strong association between corepressor mutations and AML. Further corepressor research may reveal potential therapeutic targets for AML and other diseases.

Therapeutic Potential

Corepressors present many potential avenues for drugs to target a vast range of diseases. [22]

BCL6 upregulation is observed in cancers such as diffuse large B-cell lymphomas (DLBCLs), [23] [24] [25] [26] colorectal cancer, [27] [28] and lung cancer. [29] [30] BCL-6 corepressor, SMRT, NCoR, and other corepressors are able to interact with and transcriptionally repress BCL6. [23] [24] [25] [26] Small-molecule compounds, such as synthetic peptides that target BCL6 and corepressor interactions, [23] [24] as well as other protein-protein interaction inhibitors, [26] have been shown to effectively kill cancer cells.

Activated liver X receptor (LXR) forms a complex with corepressors to suppress the inflammatory response in rheumatoid arthritis, making LXR agonists like GW3965 a potential therapeutic strategy. [31] [32] Ursodeoxycholic acid (UDCA), by upregulating the corepressor small heterodimer partner interacting leucine zipper protein (SMILE), inhibits the expression of IL-17, an inflammatory cytokine, and suppresses Th17 cells, both implicated in rheumatoid arthritis. [33] [34] This effect is dose-dependent in humans, and UCDA is thought to be another prospective agent of rheumatoid arthritis therapy. [33]

See also

References

  1. ^ Privalsky, Martin L., ed. (2001). Transcriptional Corepressors: Mediators of Eukaryotic Gene Repression. Current Topics in Microbiology and Immunology. Vol. 254. Berlin, Heidelberg: Springer Berlin Heidelberg. doi: 10.1007/978-3-662-10595-5. ISBN  978-3-642-08709-7. S2CID  8922796.
  2. ^ Evans PD, Jaseja M, Jeeves M, Hyde EI (December 1996). "NMR studies of the Escherichia coli Trp repressor.trpRs operator complex". Eur. J. Biochem. 242 (3): 567–75. doi: 10.1111/j.1432-1033.1996.0567r.x. PMID  9022683.
  3. ^ Foster JB, Slonczewski J (2010). Microbiology: An Evolving Science (Second ed.). New York: W. W. Norton & Company. ISBN  978-0-393-93447-2.
  4. ^ Jenster G (August 1998). "Coactivators and corepressors as mediators of nuclear receptor function: an update". Mol. Cell. Endocrinol. 143 (1–2): 1–7. doi: 10.1016/S0303-7207(98)00145-2. PMID  9806345. S2CID  26244186.
  5. ^ Lazar MA (2003). "Nuclear receptor corepressors". Nucl Recept Signal. 1: e001. doi: 10.1621/nrs.01001. PMC  1402229. PMID  16604174.
  6. ^ Goodson M, Jonas BA, Privalsky MA (2005). "Corepressors: custom tailoring and alterations while you wait". Nucl Recept Signal. 3 (Oct 21): e003. doi: 10.1621/nrs.03003. PMC  1402215. PMID  16604171.
  7. ^ Schaefer U, Schmeier S, Bajic VB (January 2011). "TcoF-DB: dragon database for human transcription co-factors and transcription factor interacting proteins". Nucleic Acids Res. 39 (Database issue): D106–10. doi: 10.1093/nar/gkq945. PMC  3013796. PMID  20965969.
  8. ^ a b c d e f Bolander, Franklyn F. (2004), "Hormonally Regulated Transcription Factors", Molecular Endocrinology, Elsevier, pp. 387–443, doi: 10.1016/b978-012111232-5/50013-0, ISBN  978-0-12-111232-5, retrieved 2020-10-25
  9. ^ a b Chinnadurai, G (February 2002). "CtBP, an Unconventional Transcriptional Corepressor in Development and Oncogenesis". Molecular Cell. 9 (2): 213–224. doi: 10.1016/S1097-2765(02)00443-4. PMID  11864595.
  10. ^ a b c Kammer, Gary M. (2004), "Estrogen, Signal Transduction, and Systemic Lupus Erythematosus: Molecular Mechanisms", Principles of Gender-Specific Medicine, Elsevier, pp. 1082–1092, doi: 10.1016/b978-012440905-7/50375-3, ISBN  978-0-12-440905-7, retrieved 2020-10-25
  11. ^ Kadamb, Rama; Mittal, Shilpi; Bansal, Nidhi; Batra, Harish; Saluja, Daman (August 2013). "Sin3: Insight into its transcription regulatory functions". European Journal of Cell Biology. 92 (8–9): 237–246. doi: 10.1016/j.ejcb.2013.09.001. PMID  24189169.
  12. ^ a b Rosenfeld, M. G. (2006-06-01). "Sensors and signals: a coactivator/corepressor/epigenetic code for integrating signal-dependent programs of transcriptional response". Genes & Development. 20 (11): 1405–1428. doi: 10.1101/gad.1424806. ISSN  0890-9369. PMID  16751179.
  13. ^ a b c d Battaglia, Sebastiano; Maguire, Orla; Campbell, Moray J. (2010). "Transcription factor co-repressors in cancer biology: roles and targeting". International Journal of Cancer. 126 (11): 2511–9. doi: 10.1002/ijc.25181. PMC  2847647. PMID  20091860.
  14. ^ a b Christian, Mark; White, Roger; Parker, Malcolm G. (August 2006). "Metabolic regulation by the nuclear receptor corepressor RIP140". Trends in Endocrinology & Metabolism. 17 (6): 243–250. doi: 10.1016/j.tem.2006.06.008. PMID  16815031. S2CID  45870845.
  15. ^ a b c Ogawa, S.; Lozach, J.; Jepsen, K.; Sawka-Verhelle, D.; Perissi, V.; Sasik, R.; Rose, D. W.; Johnson, R. S.; Rosenfeld, M. G.; Glass, C. K. (2004-10-05). "A nuclear receptor corepressor transcriptional checkpoint controlling activator protein 1-dependent gene networks required for macrophage activation". Proceedings of the National Academy of Sciences. 101 (40): 14461–14466. Bibcode: 2004PNAS..10114461O. doi: 10.1073/pnas.0405786101. ISSN  0027-8424. PMC  521940. PMID  15452344.
  16. ^ Jepsen, Kristen; Hermanson, Ola; Onami, Thandi M; Gleiberman, Anatoli S; Lunyak, Victoria; McEvilly, Robert J; Kurokawa, Riki; Kumar, Vivek; Liu, Forrest; Seto, Edward; Hedrick, Stephen M (September 2000). "Combinatorial Roles of the Nuclear Receptor Corepressor in Transcription and Development". Cell. 102 (6): 753–763. doi: 10.1016/S0092-8674(00)00064-7. PMID  11030619. S2CID  15645977.
  17. ^ Privalsky, Martin L. (March 2004). "The Role of Corepressors in Transcriptional Regulation by Nuclear Hormone Receptors". Annual Review of Physiology. 66 (1): 315–360. doi: 10.1146/annurev.physiol.66.032802.155556. ISSN  0066-4278. PMID  14977406.
  18. ^ a b c d Tiacci, E.; Grossmann, V.; Martelli, M. P.; Kohlmann, A.; Haferlach, T.; Falini, B. (2011-12-30). "The corepressors BCOR and BCORL1: two novel players in acute myeloid leukemia". Haematologica. 97 (1): 3–5. doi: 10.3324/haematol.2011.057901. ISSN  0390-6078. PMC  3248923. PMID  22210327.
  19. ^ a b c Grossmann, Vera; Tiacci, Enrico; Holmes, Antony B.; Kohlmann, Alexander; Martelli, Maria Paola; Kern, Wolfgang; Spanhol-Rosseto, Ariele; Klein, Hans-Ulrich; Dugas, Martin; Schindela, Sonja; Trifonov, Vladimir (2011-12-01). "Whole-exome sequencing identifies somatic mutations of BCOR in acute myeloid leukemia with normal karyotype". Blood. 118 (23): 6153–6163. doi: 10.1182/blood-2011-07-365320. ISSN  0006-4971. PMID  22012066.
  20. ^ a b Li, Meng; Collins, Roxane; Jiao, Yuchen; Ouillette, Peter; Bixby, Dale; Erba, Harry; Vogelstein, Bert; Kinzler, Kenneth W.; Papadopoulos, Nickolas; Malek, Sami N. (2011-11-24). "Somatic mutations in the transcriptional corepressor gene BCORL1 in adult acute myelogenous leukemia". Blood. 118 (22): 5914–5917. doi: 10.1182/blood-2011-05-356204. ISSN  0006-4971. PMC  3228503. PMID  21989985.
  21. ^ Pagan, Julia K.; Arnold, Jeremy; Hanchard, Kim J.; Kumar, Raman; Bruno, Tiziana; Jones, Mathew J. K.; Richard, Derek J.; Forrest, Alistair; Spurdle, Amanda; Verdin, Eric; Crossley, Merlin (2007-03-22). "A Novel Corepressor, BCoR-L1, Represses Transcription through an Interaction with CtBP". Journal of Biological Chemistry. 282 (20): 15248–15257. doi: 10.1074/jbc.m700246200. ISSN  0021-9258. PMID  17379597.
  22. ^ Vaiopoulos, Aristeidis G.; Kostakis, Ioannis D.; Athanasoula, Kalliopi Ch.; Papavassiliou, Athanasios G. (June 2012). "Targeting transcription factor corepressors in tumor cells". Cellular and Molecular Life Sciences. 69 (11): 1745–1753. doi: 10.1007/s00018-012-0986-5. ISSN  1420-682X. PMC  11114811. PMID  22527719. S2CID  16407925.
  23. ^ a b c Cerchietti, Leandro C.; Ghetu, Alexandru F.; Zhu, Xiao; Da Silva, Gustavo F.; Zhong, Shijun; Matthews, Marilyn; Bunting, Karen L.; Polo, Jose M.; Farès, Christophe; Arrowsmith, Cheryl H.; Yang, Shao Ning (April 2010). "A Small-Molecule Inhibitor of BCL6 Kills DLBCL Cells In Vitro and In Vivo". Cancer Cell. 17 (4): 400–411. doi: 10.1016/j.ccr.2009.12.050. PMC  2858395. PMID  20385364.
  24. ^ a b c Cerchietti, Leandro C.; Yang, Shao Ning; Shaknovich, Rita; Hatzi, Katerina; Polo, Jose M.; Chadburn, Amy; Dowdy, Steven F.; Melnick, Ari (2009-04-09). "A peptomimetic inhibitor of BCL6 with potent antilymphoma effects in vitro and in vivo". Blood. 113 (15): 3397–3405. doi: 10.1182/blood-2008-07-168773. ISSN  0006-4971. PMC  2668844. PMID  18927431.
  25. ^ a b Parekh, Samir; Privé, Gilbert; Melnick, Ari (January 2008). "Therapeutic targeting of the BCL6 oncogene for diffuse large B-cell lymphomas". Leukemia & Lymphoma. 49 (5): 874–882. doi: 10.1080/10428190801895345. ISSN  1042-8194. PMC  2748726. PMID  18452090.
  26. ^ a b c Yasui, Takeshi; Yamamoto, Takeshi; Sakai, Nozomu; Asano, Kouhei; Takai, Takafumi; Yoshitomi, Yayoi; Davis, Melinda; Takagi, Terufumi; Sakamoto, Kotaro; Sogabe, Satoshi; Kamada, Yusuke (September 2017). "Discovery of a novel B-cell lymphoma 6 (BCL6)–corepressor interaction inhibitor by utilizing structure-based drug design". Bioorganic & Medicinal Chemistry. 25 (17): 4876–4886. doi: 10.1016/j.bmc.2017.07.037. PMID  28760529.
  27. ^ Sena, Paola; Mariani, Francesco; Benincasa, Marta; De Leon, Maurizio Ponz; Di Gregorio, Carmela; Mancini, Stefano; Cavani, Francesco; Smargiassi, Alberto; Palumbo, Carla; Roncucci, Luca (January 2014). "Morphological and quantitative analysis of BCL6 expression in human colorectal carcinogenesis". Oncology Reports. 31 (1): 103–110. doi: 10.3892/or.2013.2846. hdl: 11380/1011113. ISSN  1021-335X. PMID  24220798.
  28. ^ Sun, Naihui; Zhang, Liang; Zhang, Chongguang; Yuan, Yuan (December 2020). "miR-144-3p inhibits cell proliferation of colorectal cancer cells by targeting BCL6 via inhibition of Wnt/β-catenin signaling". Cellular & Molecular Biology Letters. 25 (1): 19. doi: 10.1186/s11658-020-00210-3. ISSN  1425-8153. PMC  7079415. PMID  32206063.
  29. ^ Deb, Dhruba; Rajaram, Satwik; Larsen, Jill E.; Dospoy, Patrick D.; Marullo, Rossella; Li, Long Shan; Avila, Kimberley; Xue, Fengtian; Cerchietti, Leandro; Minna, John D.; Altschuler, Steven J. (2017-06-01). "Combination Therapy Targeting BCL6 and Phospho-STAT3 Defeats Intratumor Heterogeneity in a Subset of Non–Small Cell Lung Cancers". Cancer Research. 77 (11): 3070–3081. doi: 10.1158/0008-5472.CAN-15-3052. ISSN  0008-5472. PMC  5489259. PMID  28377453.
  30. ^ Sun, Chengcao; Li, Shujun; Yang, Cuili; Xi, Yongyong; Wang, Liang; Zhang, Feng; Li, Dejia (February 2016). "MicroRNA-187-3p mitigates non-small cell lung cancer (NSCLC) development through down-regulation of BCL6". Biochemical and Biophysical Research Communications. 471 (1): 82–88. doi: 10.1016/j.bbrc.2016.01.175. PMID  26845350.
  31. ^ Venteclef, N.; Jakobsson, T.; Ehrlund, A.; Damdimopoulos, A.; Mikkonen, L.; Ellis, E.; Nilsson, L.-M.; Parini, P.; Janne, O. A.; Gustafsson, J.-A.; Steffensen, K. R. (2010-02-15). "GPS2-dependent corepressor/SUMO pathways govern anti-inflammatory actions of LRH-1 and LXR in the hepatic acute phase response". Genes & Development. 24 (4): 381–395. doi: 10.1101/gad.545110. ISSN  0890-9369. PMC  2816737. PMID  20159957.
  32. ^ Yoon, Chong-Hyeon; Kwon, Yong-Jin; Lee, Sang-Won; Park, Yong-Beom; Lee, Soo-Kon; Park, Min-Chan (January 2013). "Activation of Liver X Receptors Suppresses Inflammatory Gene Expressions and Transcriptional Corepressor Clearance in Rheumatoid Arthritis Fibroblast Like Synoviocytes". Journal of Clinical Immunology. 33 (1): 190–199. doi: 10.1007/s10875-012-9799-4. ISSN  0271-9142. PMID  22990668. S2CID  15965750.
  33. ^ a b Lee, Eun-Jung; Kwon, Jeong-Eun; Park, Min-Jung; Jung, Kyung-Ah; Kim, Da-Som; Kim, Eun-Kyung; Lee, Seung Hoon; Choi, Jong Young; Park, Sung-Hwan; Cho, Mi-La (August 2017). "Ursodeoxycholic acid attenuates experimental autoimmune arthritis by targeting Th17 and inducing pAMPK and transcriptional corepressor SMILE". Immunology Letters. 188: 1–8. doi: 10.1016/j.imlet.2017.05.011. PMID  28539269.
  34. ^ Sarkar, Sujata; Fox, David A. (May 2010). "Targeting IL-17 and Th17 Cells in Rheumatoid Arthritis". Rheumatic Disease Clinics of North America. 36 (2): 345–366. doi: 10.1016/j.rdc.2010.02.006. PMID  20510238.

External links

Retrieved from " https://en.wikipedia.org/?title=Corepressor&oldid=1225865823"
From Wikipedia, the free encyclopedia
(Redirected from Corepressor (genetics))

In genetics and molecular biology, a corepressor is a molecule that represses the expression of genes. [1] In prokaryotes, corepressors are small molecules whereas in eukaryotes, corepressors are proteins. A corepressor does not directly bind to DNA, but instead indirectly regulates gene expression by binding to repressors.

A corepressor downregulates (or represses) the expression of genes by binding to and activating a repressor transcription factor. The repressor in turn binds to a gene's operator sequence (segment of DNA to which a transcription factor binds to regulate gene expression), thereby blocking transcription of that gene.

Corepressor Transcription Factor Complex on Regulatory Element

Function

Prokaryotes

In prokaryotes, the term corepressor is used to denote the activating ligand of a repressor protein. For example, the E. coli tryptophan repressor (TrpR) is only able to bind to DNA and repress transcription of the trp operon when its corepressor tryptophan is bound to it. TrpR in the absence of tryptophan is known as an aporepressor and is inactive in repressing gene transcription. [2] Trp operon encodes enzymes responsible for the synthesis of tryptophan. Hence TrpR provides a negative feedback mechanism that regulates the biosynthesis of tryptophan.

In short tryptophan acts as a corepressor for its own biosynthesis. [3]

Eukaryotes

In eukaryotes, a corepressor is a protein that binds to transcription factors. [4] In the absence of corepressors and in the presence of coactivators, transcription factors upregulate gene expression. Coactivators and corepressors compete for the same binding sites on transcription factors. A second mechanism by which corepressors may repress transcriptional initiation when bound to transcription factor/DNA complexes is by recruiting histone deacetylases which catalyze the removal of acetyl groups from lysine residues. This increases the positive charge on histones which strengthens the electrostatic attraction between the positively charged histones and negatively charged DNA, making the DNA less accessible for transcription. [5] [6]

In humans several dozen to several hundred corepressors are known, depending on the level of confidence with which the characterisation of a protein as a corepressors can be made. [7]

Examples of corepressors

NCoR

NCoR (nuclear receptor co-repressor) directly binds to the D and E domains of nuclear receptors and represses their transcriptional activity. [8] [9] [10] Class I histone deacetylases are recruited by NCoR through SIN3, and NCoR directly binds to class II histone deacetylases. [8] [10] [11]

Silencing mediator for retinoid and thyroid-hormone receptor

SMRT (silencing mediator of retinoic acid and thyroid hormone receptor), also known as NCoR2, is an alternatively spliced SRC-1(steroid receptor coactivator-1). [8] [9] It is negatively and positively affected by MAPKKK (mitogen activated protein kinase kinase kinase) and casein kinase 2 phosphorylation, respectively. [8] SMRT has two major mechanisms: first, similar to NCoR, SMRT also recruits class I histone deacetylases through SIN3 and directly binds to class II histone deacetylases. [8] Second, it binds and sequesters components of the general transcriptional machinery, such as transcription factor II B. [8] [10]

Role in biological processes

Corepressors are known to regulate transcription through different activation and inactivation states. [12] [13]

NCoR and SMRT act as a corepressor complex to regulate transcription by becoming activated once the ligand is bound. [12] [13] [14] [15] Knockouts of NCoR resulted in embryo death, indicating its importance in erythrocytic, thymic, and neural system development. [15] [16]

Mutations in certain corepressors can result in deregulation of signals. [13] SMRT contributes to cardiac muscle development, with knockouts of the complex resulting in less developed muscle and improper development. [13]

NCoR has also been found to be an important checkpoint in processes such as inflammation and macrophage activation. [15]

Recent evidence also suggests the role of corepressor RIP140 in metabolic regulation of energy homeostasis. [14]

Clinical significance

Diseases

Since corepressors participate and regulate a vast range of gene expression, it is not surprising that aberrant corepressor activities can cause diseases. [17]

Acute myeloid leukemia (AML) is a highly lethal blood cancer characterized by uncontrolled myeloid cell growth. [18] Two homologous corepressor genes, BCOR (BCL6 corepressor) and BCORL1, are recurrently mutated in AML patients. [19] [20] BCOR works with multiple transcription factors and is known to play vital regulatory roles in embryonic development. [18] [19] Clinical results detected BCOR somatic mutations in ~4% of an unselected group of AML patients, and ~17% in a subset of patients who lack known AML-causing mutations. [18] [19] Similarly, BCORL1 is a corepressor that regulates cellular processes, [21] and was found to be mutated in ~6% of tested AML patients. [18] [20] These studies point out a strong association between corepressor mutations and AML. Further corepressor research may reveal potential therapeutic targets for AML and other diseases.

Therapeutic Potential

Corepressors present many potential avenues for drugs to target a vast range of diseases. [22]

BCL6 upregulation is observed in cancers such as diffuse large B-cell lymphomas (DLBCLs), [23] [24] [25] [26] colorectal cancer, [27] [28] and lung cancer. [29] [30] BCL-6 corepressor, SMRT, NCoR, and other corepressors are able to interact with and transcriptionally repress BCL6. [23] [24] [25] [26] Small-molecule compounds, such as synthetic peptides that target BCL6 and corepressor interactions, [23] [24] as well as other protein-protein interaction inhibitors, [26] have been shown to effectively kill cancer cells.

Activated liver X receptor (LXR) forms a complex with corepressors to suppress the inflammatory response in rheumatoid arthritis, making LXR agonists like GW3965 a potential therapeutic strategy. [31] [32] Ursodeoxycholic acid (UDCA), by upregulating the corepressor small heterodimer partner interacting leucine zipper protein (SMILE), inhibits the expression of IL-17, an inflammatory cytokine, and suppresses Th17 cells, both implicated in rheumatoid arthritis. [33] [34] This effect is dose-dependent in humans, and UCDA is thought to be another prospective agent of rheumatoid arthritis therapy. [33]

See also

References

  1. ^ Privalsky, Martin L., ed. (2001). Transcriptional Corepressors: Mediators of Eukaryotic Gene Repression. Current Topics in Microbiology and Immunology. Vol. 254. Berlin, Heidelberg: Springer Berlin Heidelberg. doi: 10.1007/978-3-662-10595-5. ISBN  978-3-642-08709-7. S2CID  8922796.
  2. ^ Evans PD, Jaseja M, Jeeves M, Hyde EI (December 1996). "NMR studies of the Escherichia coli Trp repressor.trpRs operator complex". Eur. J. Biochem. 242 (3): 567–75. doi: 10.1111/j.1432-1033.1996.0567r.x. PMID  9022683.
  3. ^ Foster JB, Slonczewski J (2010). Microbiology: An Evolving Science (Second ed.). New York: W. W. Norton & Company. ISBN  978-0-393-93447-2.
  4. ^ Jenster G (August 1998). "Coactivators and corepressors as mediators of nuclear receptor function: an update". Mol. Cell. Endocrinol. 143 (1–2): 1–7. doi: 10.1016/S0303-7207(98)00145-2. PMID  9806345. S2CID  26244186.
  5. ^ Lazar MA (2003). "Nuclear receptor corepressors". Nucl Recept Signal. 1: e001. doi: 10.1621/nrs.01001. PMC  1402229. PMID  16604174.
  6. ^ Goodson M, Jonas BA, Privalsky MA (2005). "Corepressors: custom tailoring and alterations while you wait". Nucl Recept Signal. 3 (Oct 21): e003. doi: 10.1621/nrs.03003. PMC  1402215. PMID  16604171.
  7. ^ Schaefer U, Schmeier S, Bajic VB (January 2011). "TcoF-DB: dragon database for human transcription co-factors and transcription factor interacting proteins". Nucleic Acids Res. 39 (Database issue): D106–10. doi: 10.1093/nar/gkq945. PMC  3013796. PMID  20965969.
  8. ^ a b c d e f Bolander, Franklyn F. (2004), "Hormonally Regulated Transcription Factors", Molecular Endocrinology, Elsevier, pp. 387–443, doi: 10.1016/b978-012111232-5/50013-0, ISBN  978-0-12-111232-5, retrieved 2020-10-25
  9. ^ a b Chinnadurai, G (February 2002). "CtBP, an Unconventional Transcriptional Corepressor in Development and Oncogenesis". Molecular Cell. 9 (2): 213–224. doi: 10.1016/S1097-2765(02)00443-4. PMID  11864595.
  10. ^ a b c Kammer, Gary M. (2004), "Estrogen, Signal Transduction, and Systemic Lupus Erythematosus: Molecular Mechanisms", Principles of Gender-Specific Medicine, Elsevier, pp. 1082–1092, doi: 10.1016/b978-012440905-7/50375-3, ISBN  978-0-12-440905-7, retrieved 2020-10-25
  11. ^ Kadamb, Rama; Mittal, Shilpi; Bansal, Nidhi; Batra, Harish; Saluja, Daman (August 2013). "Sin3: Insight into its transcription regulatory functions". European Journal of Cell Biology. 92 (8–9): 237–246. doi: 10.1016/j.ejcb.2013.09.001. PMID  24189169.
  12. ^ a b Rosenfeld, M. G. (2006-06-01). "Sensors and signals: a coactivator/corepressor/epigenetic code for integrating signal-dependent programs of transcriptional response". Genes & Development. 20 (11): 1405–1428. doi: 10.1101/gad.1424806. ISSN  0890-9369. PMID  16751179.
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