Your search keyword '"Coull, Barry J."' showing total 13 results

1. The tumor suppressor folliculin regulates AMPK-dependent metabolic transformation

Author

Yan, Ming, Gingras, Marie-Claude, Dunlop, Elaine A., Nouet, Yann, Dupuy, Fanny, Jalali, Zahra, Possik, Elite, Coull, Barry J., Kharitidi, Dmitri, Dydensborg, Anders Bondo, Faubert, Brandon, Kamps, Miriam, Sabourin, Sylvie, Preston, Rachael S., Davies, David Mark, Roughead, Taren, Chotard, Laetitia, van Steensel, Maurice A.M., Jones, Russell, Tee, Andrew R., and Pause, Arnim

Subjects

Drug metabolism -- Genetic aspects, Estrone -- Physiological aspects, Tumor suppressor genes -- Properties, Mitochondria -- Properties, Cancer cells -- Genetic aspects, Health care industry

Abstract

The Warburg effect is a tumorigenic metabolic adaptation process characterized by augmented aerobic glycolysis, which enhances cellular bioenergetics. In normal cells, energy homeostasis is controlled by AMPK; however, its role in cancer is not understood, as both AMPK-dependent tumor-promoting and -inhibiting functions were reported. Upon stress, energy levels are maintained by increased mitochondrial biogenesis and glycolysis, controlled by transcriptional coactivator PGC-1α and HIF, respectively. In normoxia, AMPK induces PGC-1α, but how HIF is activated is unclear. Germline mutations in the gene encoding the tumor suppressor folliculin (FLCN) lead to Birt-Hogg-Dube (BHD) syndrome, which is associated with an increased cancer risk. FLCN was identified as an AMPK binding partner, and we evaluated its role with respect to AMPK-dependent energy functions. We revealed that loss of FLCN constitutively activates AMPK, resulting in PGC-1α-mediated mitochondrial biogenesis and increased ROS production. ROS induced HIF transcriptional activity and drove Warburg metabolic reprogramming, coupling AMPK-dependent mitochondrial biogenesis to HIF-dependent metabolic changes. This reprogramming stimulated cellular bioenergetics and conferred a HIF-dependent tumorigenic advantage in FLCN-negative cancer cells. Moreover, this pathway is conserved in a BHD-derived tumor. These results indicate that FLCN inhibits tumorigenesis by preventing AMPK-dependent HIF activation and the subsequent Warburg metabolic transformation., Introduction Kidney cancer is a metabolic disease, because renal cancer genes, including VHL, MET, TSC1, TSC2, FH, and SDH, are involved in metabolic sensing and adaptation to fluctuations in oxygen, [...]

Published

2014

2. Birt–Hogg–Dubé syndrome and the skin

Author

Vernooij, Marigje, Claessens, Tijs, Luijten, Monique, van Steensel, Maurice A. M., and Coull, Barry J.

Published

2013

3. A de novo FLCN mutation in a patient with spontaneous pneumothorax and renal cancer; a clinical and molecular evaluation

Author

Menko, Fred H., Johannesma, Paul C., van Moorselaar, R. Jeroen A., Reinhard, Rinze, van Waesberghe, Jan Hein, Thunnissen, Erik, Houweling, Arjan C., Leter, Edward M., Waisfisz, Quinten, van Doorn, Martijn B., Starink, Theo M., Postmus, Pieter E., Coull, Barry J., van Steensel, Maurice A. M., and Gille, Johan J. P.

Published

2013

4. Birt–Hogg–Dubé syndrome is a novel ciliopathy

Author

Luijten, Monique N.H., Basten, Sander G., Claessens, Tijs, Vernooij, Marigje, Scott, Claire L., Janssen, Renske, Easton, Jennifer A., Kamps, Miriam A.F., Vreeburg, Maaike, Broers, Jos L.V., van Geel, Michel, Menko, Fred H., Harbottle, Richard P., Nookala, Ravi K., Tee, Andrew R., Land, Stephen C., Giles, Rachel H., Coull, Barry J., and van Steensel, Maurice A.M.

Published

2013

5. Whatʼs new in Birt–Hogg–Dubé syndrome?

Author

Claessens, Tijs, Vernooij, Marigje, Luijten, Monique, Coull, Barry J, and van Steensel, Maurice AM

Published

2012

6. A rare missense mutation in GJB3 (Cx31G45E) is associated with a unique cellular phenotype resulting in necrotic cell death.

Author

Easton, Jennifer A., Albuloushi, Ahmad K., Kamps, Miriam A. F., Brouns, Gladys H. M. R., Broers, Jos L. V., Coull, Barry J., Oji, Vincent, van Geel, Michel, van Steensel, Maurice A. M., and Martin, Patricia E.

Subjects

CELL death, MISSENSE mutation, HELA cells, MUTANT proteins, CELL membranes, GAIN-of-function mutations, NECROSIS

Abstract

Erythrokeratodermia variabilis et progressiva (EKV‐P) is caused by mutations in either the GJB3 (Cx31) or GJB4 genes (Cx30.3). We identified a rare GJB3 missense mutation, c.134G>A (p.G45E), in two unrelated patients and investigated its cellular characteristics. Expression of Cx31G45E‐GFP caused previously undescribed changes within HeLa cells and HaCaT cells, a model human keratinocyte cell line. Cx31WT‐GFP localised to the plasma membrane, but expression of Cx31G45E‐GFP caused vacuolar expansion of the endoplasmic reticulum (ER), the mutant protein accumulated within the ER membrane and disassembly of the microtubular network occurred. No ER stress responses were evoked. Cx31WT‐myc‐myc‐6xHis and Cx31G45E‐GFP co‐immunoprecipitated, indicative of heteromeric interaction, but co‐expression with Cx31WT‐mCherry, Cx26 or Cx30.3 did not mitigate the phenotype. Cx31 and Cx31G45E both co‐immunoprecipitated with Cx43, indicating the ability to form heteromeric connexons. WT‐Cx31 and Cx43 assembled into large gap junction plaques at points of cell‐to‐cell contact; Cx31G45E restricted the ability of Cx43 to reach the plasma membrane in both HaCaT cells and HeLa cells stably expressing Cx43 where the proteins strongly co‐localised with the vacolourised ER. Cell viability assays identified an increase in cell death in cells expressing Cx31G45E‐GFP, which FACS analysis determined was necrotic. Blocking connexin channel function with 18α‐glycyrrhetinic acid did not completely rescue necrosis or prevent propidium iodide uptake, suggesting that expression of Cx31G45E‐GFP damages the cellular membrane independent of its channel function. Our data suggest that entrapment of Cx43 and necrotic cell death in the epidermis could underlie the EKV skin phenotype. [ABSTRACT FROM AUTHOR]

Published

2019

7. Multicentric osteolytic syndromes represent a phenotypic spectrum defined by defective collagen remodeling.

Author

Vos, Ivo J. H. M., Wong, Arnette Shi Wei, Welting, Tim J. M., Coull, Barry J., and Steensel, Maurice A. M.

Abstract

Frank‐Ter Haar syndrome (FTHS), Winchester syndrome (WS), and multicentric osteolysis, nodulosis, and arthropathy (MONA) are ultra‐rare multisystem disorders characterized by craniofacial malformations, reduced bone density, skeletal and cardiac anomalies, and dermal fibrosis. These autosomal recessive syndromes are caused by homozygous mutation or deletion of respectively SH3PXD2B (SH3 and PX Domains 2B), MMP14 (matrix metalloproteinase 14), or MMP2. Here, we give an overview of the clinical features of 63 previously reported patients with an SH3PXD2B, MMP14, or MMP2 mutation, demonstrating considerable clinical overlap between FTHS, WS, and MONA. Interestingly, the protein products of SH3PXD2B, MMP14, and MMP2 directly cooperate in collagen remodeling. We review animal models for these three disorders that accurately reflect the major clinical features and likewise show significant phenotypical similarity with each other. Furthermore, they demonstrate that defective collagen remodeling is central in the underlying pathology. As such, we propose a nosological revision, placing these SH3PXD2B, MMP14, and MMP2 related syndromes in a novel "defective collagen‐remodelling spectrum (DECORS)". In our opinion, this revised nosology better reflects the central role for impaired collagen remodeling, a potential target for pharmaceutical intervention. [ABSTRACT FROM AUTHOR]

Published

2019

8. FLCN, a novel autophagy component, interacts with GABARAP and is regulated by ULK1 phosphorylation.

Author

Dunlop, Elaine A., Seifan, Sara, Claessens, Tijs, Behrends, Christian, Kamps, Miriam A. F., Rozycka, Ewelina, Kemp, Alain J., Nookala, Ravi K., Blenis, John, Coull, Barry J., Murray, James T., van Steensel, Maurice A. M., Wilkinson, Simon, and Tee, Andrew R.

Published

2014

9. Multifaceted transforming growth factor-beta (TGFβ) signalling in glioblastoma.

Author

Birch, Joanna L., Coull, Barry J., Spender, Lindsay C., Watt, Courtney, Willison, Alice, Syed, Nelofer, Chalmers, Anthony J., Hossain-Ibrahim, M. Kismet, and Inman, Gareth J.

Subjects

*TRANSFORMING growth factors-beta, *BRAIN tumors, *GLIOBLASTOMA multiforme

Abstract

Glioblastoma (GBM) is an aggressive and devastating primary brain cancer which responds very poorly to treatment. The average survival time of patients is only 14–15 months from diagnosis so there is a clear and unmet need for the development of novel targeted therapies to improve patient outcomes. The multifunctional cytokine TGFβ plays fundamental roles in development, adult tissue homeostasis, tissue wound repair and immune responses. Dysfunction of TGFβ signalling has been implicated in both the development and progression of many tumour types including GBM, thereby potentially providing an actionable target for its treatment. This review will examine TGFβ signalling mechanisms and their role in the development and progression of GBM. The targeting of TGFβ signalling using a variety of approaches including the TGFβ binding protein Decorin will be highlighted as attractive therapeutic strategies. • TGFβ can act as a context dependent tumour suppressor and tumour promoter in GBM. • TGFβ can modulate GBM tumour cell proliferation, migration, invasion and stemness. • TGFβ can modulate the tumour microenvironment in GBM. • TGFβ signalling is a promising target for therapeutic intervention for some GBM. • DCN may have therapeutic potential in GBM. [ABSTRACT FROM AUTHOR]

Published

2020

10. The tumor suppressor folliculin regulates AMPK-dependent metabolic transformation.

Author

Ming Yan, Gingras, Marie-Claude, Dunlop, Elaine A., Nouët, Yann, Dupuy, Fanny, Jalali, Zahra, Possik, Elite, Coull, Barry J., Kharitidi, Dmitri, Bondo Dydensborg, Anders, Faubert, Brandon, Kamps, Miriam, Sabourin, Sylvie, Preston, Rachael S., Davies, David Mark, Roughead, Taren, Chotard, Laëtitia, van Steensel, Maurice A. M., Jones, Russell, and Tee, Andrew R.

Subjects

*GLYCOLYSIS, *CELLULAR bioenergetics, *HOMEOSTASIS, *MITOCHONDRIA formation, *GENETIC mutation, *CANCER risk factors

Abstract

The Warburg effect is a tumorigenic metabolic adaptation process characterized by augmented aerobic glycolysis, which enhances cellular bioenergetics. In normal cells, energy homeostasis is controlled by AMPK; however, its role in cancer is not understood, as both AMPK-dependent tumor-promoting and -inhibiting functions were reported. Upon stress, energy levels are maintained by increased mitochondrial biogenesis and glycolysis, controlled by transcriptional coactivator PGC-1α and HIF, respectively. In normoxia, AMPK induces PGC-1α, but how HIF is activated is unclear. Germline mutations in the gene encoding the tumor suppressor folliculin (FLCN) lead to Birt-Hogg-Dubé (BHD) syndrome, which is associated with an increased cancer risk. FLCN was identified as an AMPK binding partner, and we evaluated its role with respect to AMPK-dependent energy functions. We revealed that loss of FLCN constitutively activates AMPK, resulting in PGC-1α--mediated mitochondrial biogenesis and increased ROS production. ROS induced HIF transcriptional activity and drove Warburg metabolic reprogramming, coupling AMPK-dependent mitochondrial biogenesis to HIF-dependent metabolic changes. This reprogramming stimulated cellular bioenergetics and conferred a HIF-dependent tumorigenic advantage in FLCN-negative cancer cells. Moreover, this pathway is conserved in a BHD-derived tumor. These results indicate that FLCN inhibits tumorigenesis by preventing AMPK-dependent HIF activation and the subsequent Warburg metabolic transformation. [ABSTRACT FROM AUTHOR]

Published

2014

11. A zebrafish model for Winchester syndrome.

Author

De Vos, Ivo Johannes Hendrikus Marie, Ong, Sheena Li Ming, Lim, John, Goggi, Julian, Ong, Chee Bing, Coull, Barry J., Dunn, Norris Ray, Carney, Thomas J., and Van Steensel, Maurice A.M.

Subjects

*CONNECTIVE tissue diseases, *GENETIC mutation, *MATRIX metalloproteinases, *PHENOTYPES, *LABORATORY zebrafish

Published

2017

12. Multicentric osteolytic syndromes represent a phenotypic spectrum defined by defective collagen remodeling.

Author

de Vos IJHM, Wong ASW, Welting TJM, Coull BJ, and van Steensel MAM

Subjects

Alleles, Animals, Collagen chemistry, Gene Knockdown Techniques, Genetic Association Studies, Genetic Predisposition to Disease, Humans, Matrix Metalloproteinase 14 genetics, Matrix Metalloproteinase 14 metabolism, Matrix Metalloproteinase 2 genetics, Matrix Metalloproteinase 2 metabolism, Collagen genetics, Hajdu-Cheney Syndrome diagnosis, Hajdu-Cheney Syndrome genetics, Mutation, Phenotype

Abstract

Frank-Ter Haar syndrome (FTHS), Winchester syndrome (WS), and multicentric osteolysis, nodulosis, and arthropathy (MONA) are ultra-rare multisystem disorders characterized by craniofacial malformations, reduced bone density, skeletal and cardiac anomalies, and dermal fibrosis. These autosomal recessive syndromes are caused by homozygous mutation or deletion of respectively SH3PXD2B (SH3 and PX Domains 2B), MMP14 (matrix metalloproteinase 14), or MMP2. Here, we give an overview of the clinical features of 63 previously reported patients with an SH3PXD2B, MMP14, or MMP2 mutation, demonstrating considerable clinical overlap between FTHS, WS, and MONA. Interestingly, the protein products of SH3PXD2B, MMP14, and MMP2 directly cooperate in collagen remodeling. We review animal models for these three disorders that accurately reflect the major clinical features and likewise show significant phenotypical similarity with each other. Furthermore, they demonstrate that defective collagen remodeling is central in the underlying pathology. As such, we propose a nosological revision, placing these SH3PXD2B, MMP14, and MMP2 related syndromes in a novel "defective collagen-remodelling spectrum (DECORS)". In our opinion, this revised nosology better reflects the central role for impaired collagen remodeling, a potential target for pharmaceutical intervention., (© 2019 Wiley Periodicals, Inc.)

Published

2019

13. Functional analysis of a hypomorphic allele shows that MMP14 catalytic activity is the prime determinant of the Winchester syndrome phenotype.

Author

de Vos IJHM, Tao EY, Ong SLM, Goggi JL, Scerri T, Wilson GR, Low CGM, Wong ASW, Grussu D, Stegmann APA, van Geel M, Janssen R, Amor DJ, Bahlo M, Dunn NR, Carney TJ, Lockhart PJ, Coull BJ, and van Steensel MAM

Subjects

Abnormalities, Multiple physiopathology, Alleles, Animals, Catalytic Domain genetics, Contracture physiopathology, Corneal Opacity physiopathology, Craniofacial Abnormalities physiopathology, Gene Knockout Techniques, Growth Disorders physiopathology, Humans, Mice, Osteolysis physiopathology, Osteoporosis physiopathology, Phenotype, Zebrafish, Abnormalities, Multiple genetics, Contracture genetics, Corneal Opacity genetics, Craniofacial Abnormalities genetics, Growth Disorders genetics, Matrix Metalloproteinase 14 genetics, Osteolysis genetics, Osteoporosis genetics

Abstract

Winchester syndrome (WS, MIM #277950) is an extremely rare autosomal recessive skeletal dysplasia characterized by progressive joint destruction and osteolysis. To date, only one missense mutation in MMP14, encoding the membrane-bound matrix metalloprotease 14, has been reported in WS patients. Here, we report a novel hypomorphic MMP14 p.Arg111His (R111H) allele, associated with a mitigated form of WS. Functional analysis demonstrated that this mutation, in contrast to previously reported human and murine MMP14 mutations, does not affect MMP14's transport to the cell membrane. Instead, it partially impairs MMP14's proteolytic activity. This residual activity likely accounts for the mitigated phenotype observed in our patients. Based on our observations as well as previously published data, we hypothesize that MMP14's catalytic activity is the prime determinant of disease severity. Given the limitations of our in vitro assays in addressing the consequences of MMP14 dysfunction, we generated a novel mmp14a/b knockout zebrafish model. The fish accurately reflected key aspects of the WS phenotype including craniofacial malformations, kyphosis, short-stature and reduced bone density owing to defective collagen remodeling. Notably, the zebrafish model will be a valuable tool for developing novel therapeutic approaches to a devastating bone disorder.

Published

2018