Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis

Alessandro Carrer; Sophie Trefely; Steven Zhao; Sydney L. Campbell; Robert J. Norgard; Kollin C. Schultz; Simone Sidoli; Joshua L.D. Parris; Hayley C. Affronti; Sharanya Sivanand; Shaun Egolf; Yogev Sela; Marco Trizzino; Alessandro Gardini; Benjamin A. Garcia; Nathaniel W. Snyder; Ben Z. Stanger; Kathryn E. Wellen

doi:10.1158/2159-8290.CD-18-0567

Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis

Alessandro Carrer, Sophie Trefely, Steven Zhao, Sydney L. Campbell, Robert J. Norgard, Kollin C. Schultz, Simone Sidoli, Joshua L.D. Parris, Hayley C. Affronti, Sharanya Sivanand, Shaun Egolf, Yogev Sela, Marco Trizzino, Alessandro Gardini, Benjamin A. Garcia, Nathaniel W. Snyder, Ben Z. Stanger, Kathryn E. Wellen

Research output: Contribution to journal › Article › peer-review

145 Scopus citations

Abstract

Pancreatic ductal adenocarcinoma (PDA) has a poor prognosis, and new strategies for prevention and treatment are urgently needed. We previously reported that histone H4 acetylation is elevated in pancreatic acinar cells harboring Kras mutations prior to the appearance of premalignant lesions. Because acetyl-CoA abundance regulates global histone acetylation, we hypothesized that altered acetyl-CoA metabolism might contribute to metabolic or epigenetic alterations that promote tumorigenesis. We found that acetyl-CoA abundance is elevated in KRAS-mutant acinar cells and that its use in the mevalonate pathway supports acinar-to-ductal metaplasia (ADM). Pancreas-specific loss of the acetyl-CoA–producing enzyme ATP-citrate lyase (ACLY) accordingly suppresses ADM and tumor formation. In PDA cells, growth factors promote AKT–ACLY signaling and histone acetylation, and both cell proliferation and tumor growth can be suppressed by concurrent BET inhibition and statin treatment. Thus, KRAS-driven metabolic alterations promote acinar cell plasticity and tumor development, and targeting acetyl-CoA–dependent processes exerts anticancer effects. SIGNIFICANCE : Pancreatic cancer is among the deadliest of human malignancies. We identify a key role for the metabolic enzyme ACLY, which produces acetyl-CoA, in pancreatic carcinogenesis. The data suggest that acetyl-CoA use for histone acetylation and in the mevalonate pathway facilitates cell plasticity and proliferation, suggesting potential to target these pathways.

Original language	English (US)
Pages (from-to)	416-435
Number of pages	20
Journal	Cancer discovery
Volume	9
Issue number	3
DOIs	https://doi.org/10.1158/2159-8290.CD-18-0567
State	Published - Mar 1 2019
Externally published	Yes

ASJC Scopus subject areas

Oncology

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10.1158/2159-8290.CD-18-0567

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Carrer, A., Trefely, S., Zhao, S., Campbell, S. L., Norgard, R. J., Schultz, K. C., Sidoli, S., Parris, J. L. D., Affronti, H. C., Sivanand, S., Egolf, S., Sela, Y., Trizzino, M., Gardini, A., Garcia, B. A., Snyder, N. W., Stanger, B. Z., & Wellen, K. E. (2019). Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis. Cancer discovery, 9(3), 416-435. https://doi.org/10.1158/2159-8290.CD-18-0567

Carrer, A, Trefely, S, Zhao, S, Campbell, SL, Norgard, RJ, Schultz, KC, Sidoli, S, Parris, JLD, Affronti, HC, Sivanand, S, Egolf, S, Sela, Y, Trizzino, M, Gardini, A, Garcia, BA, Snyder, NW, Stanger, BZ & Wellen, KE 2019, 'Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis', Cancer discovery, vol. 9, no. 3, pp. 416-435. https://doi.org/10.1158/2159-8290.CD-18-0567

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title = "Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis",

abstract = "Pancreatic ductal adenocarcinoma (PDA) has a poor prognosis, and new strategies for prevention and treatment are urgently needed. We previously reported that histone H4 acetylation is elevated in pancreatic acinar cells harboring Kras mutations prior to the appearance of premalignant lesions. Because acetyl-CoA abundance regulates global histone acetylation, we hypothesized that altered acetyl-CoA metabolism might contribute to metabolic or epigenetic alterations that promote tumorigenesis. We found that acetyl-CoA abundance is elevated in KRAS-mutant acinar cells and that its use in the mevalonate pathway supports acinar-to-ductal metaplasia (ADM). Pancreas-specific loss of the acetyl-CoA–producing enzyme ATP-citrate lyase (ACLY) accordingly suppresses ADM and tumor formation. In PDA cells, growth factors promote AKT–ACLY signaling and histone acetylation, and both cell proliferation and tumor growth can be suppressed by concurrent BET inhibition and statin treatment. Thus, KRAS-driven metabolic alterations promote acinar cell plasticity and tumor development, and targeting acetyl-CoA–dependent processes exerts anticancer effects. SIGNIFICANCE : Pancreatic cancer is among the deadliest of human malignancies. We identify a key role for the metabolic enzyme ACLY, which produces acetyl-CoA, in pancreatic carcinogenesis. The data suggest that acetyl-CoA use for histone acetylation and in the mevalonate pathway facilitates cell plasticity and proliferation, suggesting potential to target these pathways.",

author = "Alessandro Carrer and Sophie Trefely and Steven Zhao and Campbell, {Sydney L.} and Norgard, {Robert J.} and Schultz, {Kollin C.} and Simone Sidoli and Parris, {Joshua L.D.} and Affronti, {Hayley C.} and Sharanya Sivanand and Shaun Egolf and Yogev Sela and Marco Trizzino and Alessandro Gardini and Garcia, {Benjamin A.} and Snyder, {Nathaniel W.} and Stanger, {Ben Z.} and Wellen, {Kathryn E.}",

note = "Funding Information: The authors acknowledge Cynthia Clendenin and the staff at the Pancreatic Cancer Mouse Hospital for their support for the in vivo drug-treatment experiments. The authors thank Jinyang Li (Stanger Lab) for providing C57BL/6 KPCY PDA cell lines. The authors also thank the PennVet Core (Elizabeth Buza) for histologic evaluation of murine pancreatic tumor samples. A. Carrer thanks Kyoung Lee for her help in establishing acinar cell culture. This work was supported by the 2014 Pancreatic Cancer Action Network–AACR Career Development Award, grant number 14-20-25-WELL, and the NIH grants R01CA174761 and R01CA228339 to K.E. Wellen. This project was also funded in part under a grant with the Pennsylvania Department of Health to K.E. Wellen and B.Z. Stanger. The Department specifically disclaims responsibility for any analyses, interpretations, or conclusions. N.W. Snyder is supported by the NIH grant R03HD092630. B.A. Garcia acknowledges NIH funding GM110174, AI118891, and CA196539. S.L. Campbell is supported by NIH predoctoral fellowship 1F31CA217070-01. S. Trefely is supported by the American Diabetes Association through postdoctoral fellowship #1-18-PDF-144. S. Zhao received funding from the NIH transition award F99CA222741. J.L.D. Parris was supported by the UPenn Baccalaureate Research Education fellowship R25-GM071745. H.C. Affronti is supported by NIH transition award 4K00CA212455-03. Funding Information: The authors acknowledge Cynthia Clendenin and the staff at the Pancreatic Cancer Mouse Hospital for their support for the in vivo drug-treatment experiments. The authors thank Jinyang Li (Stanger Lab) for providing C57BL/6 KPCY PDA cell lines. The authors also thank the PennVet Core (Elizabeth Buza) for histologic evaluation of murine pancreatic tumor samples. A. Carrer thanks Kyoung Lee for her help in establishing acinar cell culture. This work was supported by the 2014 Publisher Copyright: {\textcopyright} 2019 American Association for Cancer Research.",

year = "2019",

month = mar,

day = "1",

doi = "10.1158/2159-8290.CD-18-0567",

language = "English (US)",

volume = "9",

pages = "416--435",

journal = "Cancer discovery",

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TY - JOUR

T1 - Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis

AU - Carrer, Alessandro

AU - Trefely, Sophie

AU - Zhao, Steven

AU - Campbell, Sydney L.

AU - Norgard, Robert J.

AU - Schultz, Kollin C.

AU - Sidoli, Simone

AU - Parris, Joshua L.D.

AU - Affronti, Hayley C.

AU - Sivanand, Sharanya

AU - Egolf, Shaun

AU - Sela, Yogev

AU - Trizzino, Marco

AU - Gardini, Alessandro

AU - Garcia, Benjamin A.

AU - Snyder, Nathaniel W.

AU - Stanger, Ben Z.

AU - Wellen, Kathryn E.

N1 - Funding Information: The authors acknowledge Cynthia Clendenin and the staff at the Pancreatic Cancer Mouse Hospital for their support for the in vivo drug-treatment experiments. The authors thank Jinyang Li (Stanger Lab) for providing C57BL/6 KPCY PDA cell lines. The authors also thank the PennVet Core (Elizabeth Buza) for histologic evaluation of murine pancreatic tumor samples. A. Carrer thanks Kyoung Lee for her help in establishing acinar cell culture. This work was supported by the 2014 Pancreatic Cancer Action Network–AACR Career Development Award, grant number 14-20-25-WELL, and the NIH grants R01CA174761 and R01CA228339 to K.E. Wellen. This project was also funded in part under a grant with the Pennsylvania Department of Health to K.E. Wellen and B.Z. Stanger. The Department specifically disclaims responsibility for any analyses, interpretations, or conclusions. N.W. Snyder is supported by the NIH grant R03HD092630. B.A. Garcia acknowledges NIH funding GM110174, AI118891, and CA196539. S.L. Campbell is supported by NIH predoctoral fellowship 1F31CA217070-01. S. Trefely is supported by the American Diabetes Association through postdoctoral fellowship #1-18-PDF-144. S. Zhao received funding from the NIH transition award F99CA222741. J.L.D. Parris was supported by the UPenn Baccalaureate Research Education fellowship R25-GM071745. H.C. Affronti is supported by NIH transition award 4K00CA212455-03. Funding Information: The authors acknowledge Cynthia Clendenin and the staff at the Pancreatic Cancer Mouse Hospital for their support for the in vivo drug-treatment experiments. The authors thank Jinyang Li (Stanger Lab) for providing C57BL/6 KPCY PDA cell lines. The authors also thank the PennVet Core (Elizabeth Buza) for histologic evaluation of murine pancreatic tumor samples. A. Carrer thanks Kyoung Lee for her help in establishing acinar cell culture. This work was supported by the 2014 Publisher Copyright: © 2019 American Association for Cancer Research.

PY - 2019/3/1

Y1 - 2019/3/1

N2 - Pancreatic ductal adenocarcinoma (PDA) has a poor prognosis, and new strategies for prevention and treatment are urgently needed. We previously reported that histone H4 acetylation is elevated in pancreatic acinar cells harboring Kras mutations prior to the appearance of premalignant lesions. Because acetyl-CoA abundance regulates global histone acetylation, we hypothesized that altered acetyl-CoA metabolism might contribute to metabolic or epigenetic alterations that promote tumorigenesis. We found that acetyl-CoA abundance is elevated in KRAS-mutant acinar cells and that its use in the mevalonate pathway supports acinar-to-ductal metaplasia (ADM). Pancreas-specific loss of the acetyl-CoA–producing enzyme ATP-citrate lyase (ACLY) accordingly suppresses ADM and tumor formation. In PDA cells, growth factors promote AKT–ACLY signaling and histone acetylation, and both cell proliferation and tumor growth can be suppressed by concurrent BET inhibition and statin treatment. Thus, KRAS-driven metabolic alterations promote acinar cell plasticity and tumor development, and targeting acetyl-CoA–dependent processes exerts anticancer effects. SIGNIFICANCE : Pancreatic cancer is among the deadliest of human malignancies. We identify a key role for the metabolic enzyme ACLY, which produces acetyl-CoA, in pancreatic carcinogenesis. The data suggest that acetyl-CoA use for histone acetylation and in the mevalonate pathway facilitates cell plasticity and proliferation, suggesting potential to target these pathways.

AB - Pancreatic ductal adenocarcinoma (PDA) has a poor prognosis, and new strategies for prevention and treatment are urgently needed. We previously reported that histone H4 acetylation is elevated in pancreatic acinar cells harboring Kras mutations prior to the appearance of premalignant lesions. Because acetyl-CoA abundance regulates global histone acetylation, we hypothesized that altered acetyl-CoA metabolism might contribute to metabolic or epigenetic alterations that promote tumorigenesis. We found that acetyl-CoA abundance is elevated in KRAS-mutant acinar cells and that its use in the mevalonate pathway supports acinar-to-ductal metaplasia (ADM). Pancreas-specific loss of the acetyl-CoA–producing enzyme ATP-citrate lyase (ACLY) accordingly suppresses ADM and tumor formation. In PDA cells, growth factors promote AKT–ACLY signaling and histone acetylation, and both cell proliferation and tumor growth can be suppressed by concurrent BET inhibition and statin treatment. Thus, KRAS-driven metabolic alterations promote acinar cell plasticity and tumor development, and targeting acetyl-CoA–dependent processes exerts anticancer effects. SIGNIFICANCE : Pancreatic cancer is among the deadliest of human malignancies. We identify a key role for the metabolic enzyme ACLY, which produces acetyl-CoA, in pancreatic carcinogenesis. The data suggest that acetyl-CoA use for histone acetylation and in the mevalonate pathway facilitates cell plasticity and proliferation, suggesting potential to target these pathways.

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Acetyl-CoA metabolism supports multistep pancreatic tumorigenesis

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