Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer

Meifang Yu; Nicholas D. Nguyen; Yanqing Huang; Daniel Lin; Tara N. Fujimoto; Jessica M. Molkentine; Amit Deorukhkar; Yaan Kang; F. Anthony San Lucas; Conrad J. Fernandes; Eugene J. Koay; Sonal Gupta; Haoqiang Ying; Albert C. Koong; Joseph M. Herman; Jason B. Fleming; Anirban Maitra; Cullen M. Taniguchi

doi:10.1172/jci.insight.126915

Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer

Meifang Yu, Nicholas D. Nguyen, Yanqing Huang, Daniel Lin, Tara N. Fujimoto, Jessica M. Molkentine, Amit Deorukhkar, Yaan Kang, F. Anthony San Lucas, Conrad J. Fernandes, Eugene J. Koay, Sonal Gupta, Haoqiang Ying, Albert C. Koong, Joseph M. Herman, Jason B. Fleming, Anirban Maitra, Cullen M. Taniguchi

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106 Scopus citations

Abstract

Pancreatic ductal adenocarcinoma (PDAC) requires mitochondrial oxidative phosphorylation (OXPHOS) to fuel its growth; however, broadly inhibiting this pathway might also disrupt essential mitochondrial functions in normal tissues. PDAC cells exhibit abnormally fragmented mitochondria that are essential to the oncogenicity of PDAC, but it was unclear if this mitochondrial feature was a valid therapeutic target. Here, we present evidence that normalizing the fragmented mitochondria of pancreatic cancer via the process of mitochondrial fusion reduces OXPHOS, which correlates with suppressed tumor growth and improved survival in preclinical models. Mitochondrial fusion was achieved by genetic or pharmacologic inhibition of dynamin-related protein-1 (Drp1) or through overexpression of mitofusin-2 (Mfn2). Notably, we found that oral leflunomide, an FDA-approved arthritis drug, promoted a 2-fold increase in Mfn2 expression in tumors and was repurposed as a chemotherapeutic agent, improving the median survival of mice with spontaneous tumors by 50% compared with vehicle. We found that the chief tumor-suppressive mechanism of mitochondrial fusion was enhanced mitophagy, which proportionally reduced mitochondrial mass and ATP production. These data suggest that mitochondrial fusion is a specific and druggable regulator of pancreatic cancer growth that could be rapidly translated to the clinic.

Original language	English (US)
Article number	e126915
Journal	JCI Insight
Volume	4
Issue number	16
DOIs	https://doi.org/10.1172/jci.insight.126915
State	Published - Aug 22 2019

ASJC Scopus subject areas

General Medicine

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Yu, M., Nguyen, N. D., Huang, Y., Lin, D., Fujimoto, T. N., Molkentine, J. M., Deorukhkar, A., Kang, Y., Anthony San Lucas, F., Fernandes, C. J., Koay, E. J., Gupta, S., Ying, H., Koong, A. C., Herman, J. M., Fleming, J. B., Maitra, A., & Taniguchi, C. M. (2019). Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer. JCI Insight, 4(16), Article e126915. https://doi.org/10.1172/jci.insight.126915

Yu, M, Nguyen, ND, Huang, Y, Lin, D, Fujimoto, TN, Molkentine, JM, Deorukhkar, A, Kang, Y , Anthony San Lucas, F, Fernandes, CJ, Koay, EJ, Gupta, S, Ying, H , Koong, AC, Herman, JM, Fleming, JB, Maitra, A & Taniguchi, CM 2019, 'Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer', JCI Insight, vol. 4, no. 16, e126915. https://doi.org/10.1172/jci.insight.126915

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title = "Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer",

abstract = "Pancreatic ductal adenocarcinoma (PDAC) requires mitochondrial oxidative phosphorylation (OXPHOS) to fuel its growth; however, broadly inhibiting this pathway might also disrupt essential mitochondrial functions in normal tissues. PDAC cells exhibit abnormally fragmented mitochondria that are essential to the oncogenicity of PDAC, but it was unclear if this mitochondrial feature was a valid therapeutic target. Here, we present evidence that normalizing the fragmented mitochondria of pancreatic cancer via the process of mitochondrial fusion reduces OXPHOS, which correlates with suppressed tumor growth and improved survival in preclinical models. Mitochondrial fusion was achieved by genetic or pharmacologic inhibition of dynamin-related protein-1 (Drp1) or through overexpression of mitofusin-2 (Mfn2). Notably, we found that oral leflunomide, an FDA-approved arthritis drug, promoted a 2-fold increase in Mfn2 expression in tumors and was repurposed as a chemotherapeutic agent, improving the median survival of mice with spontaneous tumors by 50% compared with vehicle. We found that the chief tumor-suppressive mechanism of mitochondrial fusion was enhanced mitophagy, which proportionally reduced mitochondrial mass and ATP production. These data suggest that mitochondrial fusion is a specific and druggable regulator of pancreatic cancer growth that could be rapidly translated to the clinic.",

author = "Meifang Yu and Nguyen, {Nicholas D.} and Yanqing Huang and Daniel Lin and Fujimoto, {Tara N.} and Molkentine, {Jessica M.} and Amit Deorukhkar and Yaan Kang and {Anthony San Lucas}, F. and Fernandes, {Conrad J.} and Koay, {Eugene J.} and Sonal Gupta and Haoqiang Ying and Koong, {Albert C.} and Herman, {Joseph M.} and Fleming, {Jason B.} and Anirban Maitra and Taniguchi, {Cullen M.}",

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doi = "10.1172/jci.insight.126915",

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AU - Yu, Meifang

AU - Nguyen, Nicholas D.

AU - Huang, Yanqing

AU - Lin, Daniel

AU - Fujimoto, Tara N.

AU - Molkentine, Jessica M.

AU - Deorukhkar, Amit

AU - Kang, Yaan

AU - Anthony San Lucas, F.

AU - Fernandes, Conrad J.

AU - Koay, Eugene J.

AU - Gupta, Sonal

AU - Ying, Haoqiang

AU - Koong, Albert C.

AU - Herman, Joseph M.

AU - Fleming, Jason B.

AU - Maitra, Anirban

AU - Taniguchi, Cullen M.

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Y1 - 2019/8/22

N2 - Pancreatic ductal adenocarcinoma (PDAC) requires mitochondrial oxidative phosphorylation (OXPHOS) to fuel its growth; however, broadly inhibiting this pathway might also disrupt essential mitochondrial functions in normal tissues. PDAC cells exhibit abnormally fragmented mitochondria that are essential to the oncogenicity of PDAC, but it was unclear if this mitochondrial feature was a valid therapeutic target. Here, we present evidence that normalizing the fragmented mitochondria of pancreatic cancer via the process of mitochondrial fusion reduces OXPHOS, which correlates with suppressed tumor growth and improved survival in preclinical models. Mitochondrial fusion was achieved by genetic or pharmacologic inhibition of dynamin-related protein-1 (Drp1) or through overexpression of mitofusin-2 (Mfn2). Notably, we found that oral leflunomide, an FDA-approved arthritis drug, promoted a 2-fold increase in Mfn2 expression in tumors and was repurposed as a chemotherapeutic agent, improving the median survival of mice with spontaneous tumors by 50% compared with vehicle. We found that the chief tumor-suppressive mechanism of mitochondrial fusion was enhanced mitophagy, which proportionally reduced mitochondrial mass and ATP production. These data suggest that mitochondrial fusion is a specific and druggable regulator of pancreatic cancer growth that could be rapidly translated to the clinic.

AB - Pancreatic ductal adenocarcinoma (PDAC) requires mitochondrial oxidative phosphorylation (OXPHOS) to fuel its growth; however, broadly inhibiting this pathway might also disrupt essential mitochondrial functions in normal tissues. PDAC cells exhibit abnormally fragmented mitochondria that are essential to the oncogenicity of PDAC, but it was unclear if this mitochondrial feature was a valid therapeutic target. Here, we present evidence that normalizing the fragmented mitochondria of pancreatic cancer via the process of mitochondrial fusion reduces OXPHOS, which correlates with suppressed tumor growth and improved survival in preclinical models. Mitochondrial fusion was achieved by genetic or pharmacologic inhibition of dynamin-related protein-1 (Drp1) or through overexpression of mitofusin-2 (Mfn2). Notably, we found that oral leflunomide, an FDA-approved arthritis drug, promoted a 2-fold increase in Mfn2 expression in tumors and was repurposed as a chemotherapeutic agent, improving the median survival of mice with spontaneous tumors by 50% compared with vehicle. We found that the chief tumor-suppressive mechanism of mitochondrial fusion was enhanced mitophagy, which proportionally reduced mitochondrial mass and ATP production. These data suggest that mitochondrial fusion is a specific and druggable regulator of pancreatic cancer growth that could be rapidly translated to the clinic.

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Mitochondrial fusion exploits a therapeutic vulnerability of pancreatic cancer

Abstract

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MD Anderson CCSG core facilities

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