Your search keyword '"Elmiligy, Sarah"' showing total 7 results

1. Aspartate is an endogenous metabolic limitation for tumour growth

Author

Sullivan, Lucas B., Luengo, Alba, Danai, Laura V., Bush, Lauren N., Diehl, Frances F., Hosios, Aaron M., Lau, Allison N., Elmiligy, Sarah, Malstrom, Scott, Lewis, Caroline A., and Vander Heiden, Matthew G.

Published

2018

2. Assessment of ABT-263 activity across a cancer cell line collection leads to a potent combination therapy for small-cell lung cancer

Author

Faber, Anthony C., Farago, Anna F., Costa, Carlotta, Dastur, Anahita, Gomez-Caraballo, Maria, Robbins, Rebecca, Wagner, Bethany L., Rideout, William M., Jakubik, Charles T., Ham, Jungoh, Edelman, Elena J., Ebi, Hiromichi, Yeo, Alan T., Hata, Aaron N., Song, Youngchul, Patel, Neha U., March, Ryan J., Tam, Ah Ting, Milano, Randy J., Boisvert, Jessica L., Hicks, Mark A., Elmiligy, Sarah, Malstrom, Scott E., Rivera, Miguel N., Harada, Hisashi, Windle, Brad E., Ramaswamy, Sridhar, Benes, Cyril H., Jacks, Tyler, and Engelman, Jeffrey A.

Published

2015

3. Abnormalities in Mitochondrial Structure in Cells from Patients with Bipolar Disorder

Author

Cataldo, Anne M., McPhie, Donna L., Lange, Nicholas T., Punzell, Steven, Elmiligy, Sarah, Ye, Nancy Z., Froimowitz, Michael P., Hassinger, Linda C., Menesale, Emily B., Sargent, Laura W., Logan, David J., Carpenter, Anne E., and Cohen, Bruce M.

Published

2010

4. Stabilization of the Max Homodimer with a Small Molecule Attenuates Myc-Driven Transcription

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Struntz, Nicholas B., Chen, Andrew I, Deutzmann, Anja, Wilson, Robert M., Stefan, Eric, Evans, Helen L, Ramirez, Maricela A., Liang, Tong, Caballero, Francisco, Wildschut, Mattheus H.E., Neel, Dylan V, Freeman, David B., Pop, Marius S, McConkey, Marie, Muller, Sandrine, Curtin, Brice Harrison, Tseng, Hanna, Frombach, Kristen R., Butty, Vincent L G, Levine, Stuart S., Feau, Clementine, Elmiligy, Sarah, Hong, Jiyoung A., Lewis, Timothy A., Vetere, Amedeo, Clemons, Paul A., Malstrom, Scott E., Ebert, Benjamin L., Lin, Charles Y., Felsher, Dean W., Koehler, Angela Nicole, Massachusetts Institute of Technology. Department of Biological Engineering, Koch Institute for Integrative Cancer Research at MIT, Struntz, Nicholas B., Chen, Andrew I, Deutzmann, Anja, Wilson, Robert M., Stefan, Eric, Evans, Helen L, Ramirez, Maricela A., Liang, Tong, Caballero, Francisco, Wildschut, Mattheus H.E., Neel, Dylan V, Freeman, David B., Pop, Marius S, McConkey, Marie, Muller, Sandrine, Curtin, Brice Harrison, Tseng, Hanna, Frombach, Kristen R., Butty, Vincent L G, Levine, Stuart S., Feau, Clementine, Elmiligy, Sarah, Hong, Jiyoung A., Lewis, Timothy A., Vetere, Amedeo, Clemons, Paul A., Malstrom, Scott E., Ebert, Benjamin L., Lin, Charles Y., Felsher, Dean W., and Koehler, Angela Nicole

Abstract

The transcription factor Max is a basic-helix-loop-helix leucine zipper (bHLHLZ) protein that forms homodimers or interacts with other bHLHLZ proteins, including Myc and Mxd proteins. Among this dynamic network of interactions, the Myc/Max heterodimer has crucial roles in regulating normal cellular processes, but its transcriptional activity is deregulated in a majority of human cancers. Despite this significance, the arsenal of high-quality chemical probes to interrogate these proteins remains limited. We used small molecule microarrays to identify compounds that bind Max in a mechanistically unbiased manner. We discovered the asymmetric polycyclic lactam, KI-MS2-008, which stabilizes the Max homodimer while reducing Myc protein and Myc-regulated transcript levels. KI-MS2-008 also decreases viable cancer cell growth in a Myc-dependent manner and suppresses tumor growth in vivo. This approach demonstrates the feasibility of modulating Max with small molecules and supports altering Max dimerization as an alternative approach to targeting Myc., National Cancer Institute (Grant R01-CA160860), National Cancer Institute (Grant P30-CA14051), National Cancer Institute (Grant U01-CA176152), National Cancer Institute (Grant CA170378PQ2), National Institutes of Health (Grant CA170378PQ2)

Published

2020

5. Aspartate is an endogenous metabolic limitation for tumour growth

Author

Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Sullivan, Lucas B., Luengo, Alba, Danai, Laura V., Bush, Lauren N., Diehl, Frances F., Hosios, Aaron M., Lau, Allison N., Elmiligy, Sarah, Lewis, Caroline A., Vander Heiden, Matthew G., Whitehead Institute for Biomedical Research, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Sullivan, Lucas B., Luengo, Alba, Danai, Laura V., Bush, Lauren N., Diehl, Frances F., Hosios, Aaron M., Lau, Allison N., Elmiligy, Sarah, Lewis, Caroline A., and Vander Heiden, Matthew G.

Abstract

Defining the metabolic limitations of tumour growth will help to develop cancer therapies 1 . Cancer cells proliferate slower in tumours than in standard culture conditions, indicating that a metabolic limitation may restrict cell proliferation in vivo. Aspartate synthesis can limit cancer cell proliferation when respiration is impaired 2-4 ; however, whether acquiring aspartate is endogenously limiting for tumour growth is unknown. We confirm that aspartate has poor cell permeability, which prevents environmental acquisition, whereas the related amino acid asparagine is available to cells in tumours, but cancer cells lack asparaginase activity to convert asparagine to aspartate. Heterologous expression of guinea pig asparaginase 1 (gpASNase1), an enzyme that produces aspartate from asparagine 5 , confers the ability to use asparagine to supply intracellular aspartate to cancer cells in vivo. Tumours expressing gpASNase1 grow at a faster rate, indicating that aspartate acquisition is an endogenous metabolic limitation for the growth of some tumours. Tumours expressing gpASNase1 are also refractory to the growth suppressive effects of metformin, suggesting that metformin inhibits tumour growth by depleting aspartate. These findings suggest that therapeutic aspartate suppression could be effective to treat cancer., American Cancer Society. Post-Doctoral Fellowship (PF-15-096-01-TBE), National Institutes of Health (U.S.). Pathway to Independence Award (K99CA218679), Nation al Science Foundation (U.S.) (Grant GRFP DGE-1122374), National Institutes of Health (U.S.). Ruth Kirschstein Fellowship (F32CA210421), Damon Runyon Cancer Research Foundation. Robert Black Fellow ( DRG-2241-15), National Institutes of Health (U.S.) (Grant R01CA201276), National Institutes of Health (U.S.) (Grant R01CA168653), National Institutes of Health (U.S.) (Grant P30CA14051)

Published

2020

6. Stabilization of the Max Homodimer with a Small Molecule Attenuates Myc-Driven Transcription

Author

Struntz, Nicholas B., primary, Chen, Andrew, additional, Deutzmann, Anja, additional, Wilson, Robert M., additional, Stefan, Eric, additional, Evans, Helen L., additional, Ramirez, Maricela A., additional, Liang, Tong, additional, Caballero, Francisco, additional, Wildschut, Mattheus H.E., additional, Neel, Dylan V., additional, Freeman, David B., additional, Pop, Marius S., additional, McConkey, Marie, additional, Muller, Sandrine, additional, Curtin, Brice H., additional, Tseng, Hanna, additional, Frombach, Kristen R., additional, Butty, Vincent L., additional, Levine, Stuart S., additional, Feau, Clementine, additional, Elmiligy, Sarah, additional, Hong, Jiyoung A., additional, Lewis, Timothy A., additional, Vetere, Amedeo, additional, Clemons, Paul A., additional, Malstrom, Scott E., additional, Ebert, Benjamin L., additional, Lin, Charles Y., additional, Felsher, Dean W., additional, and Koehler, Angela N., additional

Published

2019

7. Assessment of ABT-263 activity across a cancer cell line collection leads to a potent combination therapy for small-cell lung cancer

Author

Koch Institute for Integrative Cancer Research at MIT, Farago, Anna, Robbins, Rebecca, Wagner, Bethany L., Rideout, William M., Elmiligy, Sarah, Malstrom, Scott E., Jacks, Tyler E., Faber, Anthony C., Costa, Carlotta, Dastur, Anahita, Gomez-Caraballo, Maria, Jakubik, Charles T., Ham, Jungoh, Edelman, Elena J., Ebi, Hiromichi, Yeo, Alan T., Hata, Aaron N., Song, Youngchul, Patel, Neha U., March, Ryan J., Tam, Ah Ting, Milano, Randy J., Boisvert, Jessica L., Hicks, Mark A., Rivera, Miguel N., Harada, Hisashi, Windle, Brad E., Ramaswamy, Sridhar, Benes, Cyril H., Engelman, Jeffrey A., Jacks, Tyler E, Koch Institute for Integrative Cancer Research at MIT, Farago, Anna, Robbins, Rebecca, Wagner, Bethany L., Rideout, William M., Elmiligy, Sarah, Malstrom, Scott E., Jacks, Tyler E., Faber, Anthony C., Costa, Carlotta, Dastur, Anahita, Gomez-Caraballo, Maria, Jakubik, Charles T., Ham, Jungoh, Edelman, Elena J., Ebi, Hiromichi, Yeo, Alan T., Hata, Aaron N., Song, Youngchul, Patel, Neha U., March, Ryan J., Tam, Ah Ting, Milano, Randy J., Boisvert, Jessica L., Hicks, Mark A., Rivera, Miguel N., Harada, Hisashi, Windle, Brad E., Ramaswamy, Sridhar, Benes, Cyril H., Engelman, Jeffrey A., and Jacks, Tyler E

Abstract

BH3 mimetics such as ABT-263 induce apoptosis in a subset of cancer models. However, these drugs have shown limited clinical efficacy as single agents in small-cell lung cancer (SCLC) and other solid tumor malignancies, and rational combination strategies remain underexplored. To develop a novel therapeutic approach, we examined the efficacy of ABT-263 across >500 cancer cell lines, including 311 for which we had matched expression data for select genes. We found that high expression of the proapoptotic gene Bcl2-interacting mediator of cell death (BIM) predicts sensitivity to ABT-263. In particular, SCLC cell lines possessed greater BIM transcript levels than most other solid tumors and are among the most sensitive to ABT-263. However, a subset of relatively resistant SCLC cell lines has concomitant high expression of the antiapoptotic myeloid cell leukemia 1 (MCL-1). Whereas ABT-263 released BIM from complexes with BCL-2 and BCL-XL, high expression of MCL-1 sequestered BIM released from BCL-2 and BCL-XL, thereby abrogating apoptosis. We found that SCLCs were sensitized to ABT-263 via TORC1/2 inhibition, which led to reduced MCL-1 protein levels, thereby facilitating BIM-mediated apoptosis. AZD8055 and ABT-263 together induced marked apoptosis in vitro, as well as tumor regressions in multiple SCLC xenograft models. In a Tp53; Rb1 deletion genetically engineered mouse model of SCLC, the combination of ABT-263 and AZD8055 significantly repressed tumor growth and induced tumor regressions compared with either drug alone. Furthermore, in a SCLC patient-derived xenograft model that was resistant to ABT-263 alone, the addition of AZD8055 induced potent tumor regression. Therefore, addition of a TORC1/2 inhibitor offers a therapeutic strategy to markedly improve ABT-263 activity in SCLC., United States. Dept. of Defense (Grant W81-XWH-13-1-0323), National Cancer Institute (U.S.) (Cancer Center Support Grant P30-CA14051)

Published

2015