Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer

Christopher J. Halbrook; Corbin Pontious; Ilya Kovalenko; Laura Lapienyte; Stephan Dreyer; Ho Joon Lee; Galloway Thurston; Yaqing Zhang; Jenny Lazarus; Peter Sajjakulnukit; Hanna S. Hong; Daniel M. Kremer; Barbara S. Nelson; Samantha Kemp; Li Zhang; David Chang; Andrew Biankin; Jiaqi Shi; Timothy L. Frankel; Howard C. Crawford; Jennifer P. Morton; Marina Pasca di Magliano; Costas A. Lyssiotis

doi:10.1016/j.cmet.2019.02.001

Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer

Christopher J. Halbrook, Corbin Pontious, Ilya Kovalenko, Laura Lapienyte, Stephan Dreyer, Ho Joon Lee, Galloway Thurston, Yaqing Zhang, Jenny Lazarus, Peter Sajjakulnukit, Hanna S. Hong, Daniel M. Kremer, Barbara S. Nelson, Samantha Kemp, Li Zhang, David Chang, Andrew Biankin, Jiaqi Shi, Timothy L. Frankel, Howard C. CrawfordJennifer P. Morton, Marina Pasca di Magliano, Costas A. Lyssiotis

Mechanical Engineering

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

186 Scopus citations

Abstract

Pancreatic ductal adenocarcinoma (PDA) is characterized by abundant infiltration of tumor-associated macrophages (TAMs). TAMs have been reported to drive resistance to gemcitabine, a frontline chemotherapy in PDA, though the mechanism of this resistance remains unclear. Profiling metabolite exchange, we demonstrate that macrophages programmed by PDA cells release a spectrum of pyrimidine species. These include deoxycytidine, which inhibits gemcitabine through molecular competition at the level of drug uptake and metabolism. Accordingly, genetic or pharmacological depletion of TAMs in murine models of PDA sensitizes these tumors to gemcitabine. Consistent with this, patients with low macrophage burden demonstrate superior response to gemcitabine treatment. Together, these findings provide insights into the role of macrophages in pancreatic cancer therapy and have potential to inform the design of future treatments. Additionally, we report that pyrimidine release is a general function of alternatively activated macrophage cells, suggesting an unknown physiological role of pyrimidine exchange by immune cells. Macrophages are present in high abundance in pancreatic ductal adenocarcinoma. Halbrook et al. identify that alternatively activated macrophages release a spectrum of pyrimidine nucleosides that are consumed by pancreatic cancer cells. Among these, deoxycytidine can directly compete with gemcitabine, hindering its efficiency as a chemotherapy.

Original language	English (US)
Pages (from-to)	1390-1399.e6
Journal	Cell Metabolism
Volume	29
Issue number	6
DOIs	https://doi.org/10.1016/j.cmet.2019.02.001
State	Published - Jun 4 2019

All Science Journal Classification (ASJC) codes

Physiology
Molecular Biology
Cell Biology

Access to Document

10.1016/j.cmet.2019.02.001

Cite this

Halbrook, C. J., Pontious, C., Kovalenko, I., Lapienyte, L., Dreyer, S., Lee, H. J., Thurston, G., Zhang, Y., Lazarus, J., Sajjakulnukit, P., Hong, H. S., Kremer, D. M., Nelson, B. S., Kemp, S., Zhang, L., Chang, D., Biankin, A., Shi, J., Frankel, T. L., ... Lyssiotis, C. A. (2019). Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer. Cell Metabolism, 29(6), 1390-1399.e6. https://doi.org/10.1016/j.cmet.2019.02.001

@article{857d22c51c424027ab0700f365ee56d7,

title = "Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer",

abstract = "Pancreatic ductal adenocarcinoma (PDA) is characterized by abundant infiltration of tumor-associated macrophages (TAMs). TAMs have been reported to drive resistance to gemcitabine, a frontline chemotherapy in PDA, though the mechanism of this resistance remains unclear. Profiling metabolite exchange, we demonstrate that macrophages programmed by PDA cells release a spectrum of pyrimidine species. These include deoxycytidine, which inhibits gemcitabine through molecular competition at the level of drug uptake and metabolism. Accordingly, genetic or pharmacological depletion of TAMs in murine models of PDA sensitizes these tumors to gemcitabine. Consistent with this, patients with low macrophage burden demonstrate superior response to gemcitabine treatment. Together, these findings provide insights into the role of macrophages in pancreatic cancer therapy and have potential to inform the design of future treatments. Additionally, we report that pyrimidine release is a general function of alternatively activated macrophage cells, suggesting an unknown physiological role of pyrimidine exchange by immune cells. Macrophages are present in high abundance in pancreatic ductal adenocarcinoma. Halbrook et al. identify that alternatively activated macrophages release a spectrum of pyrimidine nucleosides that are consumed by pancreatic cancer cells. Among these, deoxycytidine can directly compete with gemcitabine, hindering its efficiency as a chemotherapy.",

author = "Halbrook, {Christopher J.} and Corbin Pontious and Ilya Kovalenko and Laura Lapienyte and Stephan Dreyer and Lee, {Ho Joon} and Galloway Thurston and Yaqing Zhang and Jenny Lazarus and Peter Sajjakulnukit and Hong, {Hanna S.} and Kremer, {Daniel M.} and Nelson, {Barbara S.} and Samantha Kemp and Li Zhang and David Chang and Andrew Biankin and Jiaqi Shi and Frankel, {Timothy L.} and Crawford, {Howard C.} and Morton, {Jennifer P.} and {Pasca di Magliano}, Marina and Lyssiotis, {Costas A.}",

note = "Funding Information: The authors would like to thank Devon Pendlebury, Drs. Luigi Franchi, Filip Bednar, Andrea Viale, Vinee Purohit, and the Lyssiotis lab for scientific feedback and Daniel Long for histology support. C.J.H. was supported by UL1TR000433 , T32CA009676 , and F32CA228328 ; L.L. by Pancreatic Cancer UK ; S.K. by T32GM113900 ; B.S.N. by T32CA009676 and T32DK094775 ; J.S. by NCI 1K08CA234222 ; H.C.C. by the Sky Foundation ; J.P.M. by Cancer Research UK ; H.S.H. by T32AI007413 ; C.A.L., H.C.C., and M.P.d.M. by a Cancer Center Support Grant ( P30CA046592 ) and U01 CA224145 ; M.P.d.M. by the American Cancer Society ; C.A.L. by the Pancreatic Cancer Action Network /AACR ( 13-70-25-LYSS ), Damon Runyon Cancer Research Foundation ( DFS-09-14 ), V Foundation for Cancer Research ( V2016-009 ), Sidney Kimmel Foundation for Cancer Research ( SKF-16-005 ), and the AACR ( 17-20-01-LYSS ). Metabolomics studies were supported by DK097153 , an Agilent ACT-UR grant mechanism, the Charles Woodson Research Fund , and the UM Pediatric Brain Tumor Initiative . Funding Information: The authors would like to thank Devon Pendlebury, Drs. Luigi Franchi, Filip Bednar, Andrea Viale, Vinee Purohit, and the Lyssiotis lab for scientific feedback and Daniel Long for histology support. C.J.H. was supported by UL1TR000433, T32CA009676, and F32CA228328; L.L. by Pancreatic Cancer UK; S.K. by T32GM113900; B.S.N. by T32CA009676 and T32DK094775; J.S. by NCI 1K08CA234222; H.C.C. by the Sky Foundation; J.P.M. by Cancer Research UK; H.S.H. by T32AI007413; C.A.L. H.C.C. and M.P.d.M. by a Cancer Center Support Grant (P30CA046592) and U01 CA224145; M.P.d.M. by the American Cancer Society; C.A.L. by the Pancreatic Cancer Action Network/AACR (13-70-25-LYSS), Damon Runyon Cancer Research Foundation (DFS-09-14), V Foundation for Cancer Research (V2016-009), Sidney Kimmel Foundation for Cancer Research (SKF-16-005), and the AACR (17-20-01-LYSS). Metabolomics studies were supported by DK097153, an Agilent ACT-UR grant mechanism, the Charles Woodson Research Fund, and the UM Pediatric Brain Tumor Initiative. C.J.H. M.P.d.M. and C.A.L. conceived and designed this study. C.J.H. and C.A.L. planned and guided the research and wrote the manuscript. C.J.H. C.P. H.-J.L. I.K. L.L. S.D. D.M.K. P.S. L.Z. B.S.N. H.S.H. J.L. J.S. T.L.F. Y.Z. G.T. and S.K. performed experiments, analyzed, and interpreted data. D.C. A.B. H.C.C. J.P.M. M.P.d.M. and C.A.L. supervised the work carried out in this study. C.A.L. is an inventor on patents pertaining to Kras-regulated metabolic pathways, redox control pathways in pancreatic cancer, and targeting GOT1 as a therapeutic approach. Publisher Copyright: {\textcopyright} 2019 Elsevier Inc.",

year = "2019",

month = jun,

day = "4",

doi = "10.1016/j.cmet.2019.02.001",

language = "English (US)",

volume = "29",

pages = "1390--1399.e6",

journal = "Cell Metabolism",

issn = "1550-4131",

publisher = "Cell Press",

number = "6",

}

Halbrook, CJ, Pontious, C, Kovalenko, I, Lapienyte, L, Dreyer, S, Lee, HJ, Thurston, G, Zhang, Y, Lazarus, J, Sajjakulnukit, P, Hong, HS, Kremer, DM, Nelson, BS, Kemp, S, Zhang, L, Chang, D, Biankin, A, Shi, J, Frankel, TL, Crawford, HC, Morton, JP, Pasca di Magliano, M & Lyssiotis, CA 2019, 'Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer', Cell Metabolism, vol. 29, no. 6, pp. 1390-1399.e6. https://doi.org/10.1016/j.cmet.2019.02.001

TY - JOUR

T1 - Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer

AU - Halbrook, Christopher J.

AU - Pontious, Corbin

AU - Kovalenko, Ilya

AU - Lapienyte, Laura

AU - Dreyer, Stephan

AU - Lee, Ho Joon

AU - Thurston, Galloway

AU - Zhang, Yaqing

AU - Lazarus, Jenny

AU - Sajjakulnukit, Peter

AU - Hong, Hanna S.

AU - Kremer, Daniel M.

AU - Nelson, Barbara S.

AU - Kemp, Samantha

AU - Zhang, Li

AU - Chang, David

AU - Biankin, Andrew

AU - Shi, Jiaqi

AU - Frankel, Timothy L.

AU - Crawford, Howard C.

AU - Morton, Jennifer P.

AU - Pasca di Magliano, Marina

AU - Lyssiotis, Costas A.

N1 - Funding Information: The authors would like to thank Devon Pendlebury, Drs. Luigi Franchi, Filip Bednar, Andrea Viale, Vinee Purohit, and the Lyssiotis lab for scientific feedback and Daniel Long for histology support. C.J.H. was supported by UL1TR000433 , T32CA009676 , and F32CA228328 ; L.L. by Pancreatic Cancer UK ; S.K. by T32GM113900 ; B.S.N. by T32CA009676 and T32DK094775 ; J.S. by NCI 1K08CA234222 ; H.C.C. by the Sky Foundation ; J.P.M. by Cancer Research UK ; H.S.H. by T32AI007413 ; C.A.L., H.C.C., and M.P.d.M. by a Cancer Center Support Grant ( P30CA046592 ) and U01 CA224145 ; M.P.d.M. by the American Cancer Society ; C.A.L. by the Pancreatic Cancer Action Network /AACR ( 13-70-25-LYSS ), Damon Runyon Cancer Research Foundation ( DFS-09-14 ), V Foundation for Cancer Research ( V2016-009 ), Sidney Kimmel Foundation for Cancer Research ( SKF-16-005 ), and the AACR ( 17-20-01-LYSS ). Metabolomics studies were supported by DK097153 , an Agilent ACT-UR grant mechanism, the Charles Woodson Research Fund , and the UM Pediatric Brain Tumor Initiative . Funding Information: The authors would like to thank Devon Pendlebury, Drs. Luigi Franchi, Filip Bednar, Andrea Viale, Vinee Purohit, and the Lyssiotis lab for scientific feedback and Daniel Long for histology support. C.J.H. was supported by UL1TR000433, T32CA009676, and F32CA228328; L.L. by Pancreatic Cancer UK; S.K. by T32GM113900; B.S.N. by T32CA009676 and T32DK094775; J.S. by NCI 1K08CA234222; H.C.C. by the Sky Foundation; J.P.M. by Cancer Research UK; H.S.H. by T32AI007413; C.A.L. H.C.C. and M.P.d.M. by a Cancer Center Support Grant (P30CA046592) and U01 CA224145; M.P.d.M. by the American Cancer Society; C.A.L. by the Pancreatic Cancer Action Network/AACR (13-70-25-LYSS), Damon Runyon Cancer Research Foundation (DFS-09-14), V Foundation for Cancer Research (V2016-009), Sidney Kimmel Foundation for Cancer Research (SKF-16-005), and the AACR (17-20-01-LYSS). Metabolomics studies were supported by DK097153, an Agilent ACT-UR grant mechanism, the Charles Woodson Research Fund, and the UM Pediatric Brain Tumor Initiative. C.J.H. M.P.d.M. and C.A.L. conceived and designed this study. C.J.H. and C.A.L. planned and guided the research and wrote the manuscript. C.J.H. C.P. H.-J.L. I.K. L.L. S.D. D.M.K. P.S. L.Z. B.S.N. H.S.H. J.L. J.S. T.L.F. Y.Z. G.T. and S.K. performed experiments, analyzed, and interpreted data. D.C. A.B. H.C.C. J.P.M. M.P.d.M. and C.A.L. supervised the work carried out in this study. C.A.L. is an inventor on patents pertaining to Kras-regulated metabolic pathways, redox control pathways in pancreatic cancer, and targeting GOT1 as a therapeutic approach. Publisher Copyright: © 2019 Elsevier Inc.

PY - 2019/6/4

Y1 - 2019/6/4

N2 - Pancreatic ductal adenocarcinoma (PDA) is characterized by abundant infiltration of tumor-associated macrophages (TAMs). TAMs have been reported to drive resistance to gemcitabine, a frontline chemotherapy in PDA, though the mechanism of this resistance remains unclear. Profiling metabolite exchange, we demonstrate that macrophages programmed by PDA cells release a spectrum of pyrimidine species. These include deoxycytidine, which inhibits gemcitabine through molecular competition at the level of drug uptake and metabolism. Accordingly, genetic or pharmacological depletion of TAMs in murine models of PDA sensitizes these tumors to gemcitabine. Consistent with this, patients with low macrophage burden demonstrate superior response to gemcitabine treatment. Together, these findings provide insights into the role of macrophages in pancreatic cancer therapy and have potential to inform the design of future treatments. Additionally, we report that pyrimidine release is a general function of alternatively activated macrophage cells, suggesting an unknown physiological role of pyrimidine exchange by immune cells. Macrophages are present in high abundance in pancreatic ductal adenocarcinoma. Halbrook et al. identify that alternatively activated macrophages release a spectrum of pyrimidine nucleosides that are consumed by pancreatic cancer cells. Among these, deoxycytidine can directly compete with gemcitabine, hindering its efficiency as a chemotherapy.

AB - Pancreatic ductal adenocarcinoma (PDA) is characterized by abundant infiltration of tumor-associated macrophages (TAMs). TAMs have been reported to drive resistance to gemcitabine, a frontline chemotherapy in PDA, though the mechanism of this resistance remains unclear. Profiling metabolite exchange, we demonstrate that macrophages programmed by PDA cells release a spectrum of pyrimidine species. These include deoxycytidine, which inhibits gemcitabine through molecular competition at the level of drug uptake and metabolism. Accordingly, genetic or pharmacological depletion of TAMs in murine models of PDA sensitizes these tumors to gemcitabine. Consistent with this, patients with low macrophage burden demonstrate superior response to gemcitabine treatment. Together, these findings provide insights into the role of macrophages in pancreatic cancer therapy and have potential to inform the design of future treatments. Additionally, we report that pyrimidine release is a general function of alternatively activated macrophage cells, suggesting an unknown physiological role of pyrimidine exchange by immune cells. Macrophages are present in high abundance in pancreatic ductal adenocarcinoma. Halbrook et al. identify that alternatively activated macrophages release a spectrum of pyrimidine nucleosides that are consumed by pancreatic cancer cells. Among these, deoxycytidine can directly compete with gemcitabine, hindering its efficiency as a chemotherapy.

UR - http://www.scopus.com/inward/record.url?scp=85062590895&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85062590895&partnerID=8YFLogxK

U2 - 10.1016/j.cmet.2019.02.001

DO - 10.1016/j.cmet.2019.02.001

M3 - Article

C2 - 30827862

AN - SCOPUS:85062590895

SN - 1550-4131

VL - 29

SP - 1390-1399.e6

JO - Cell Metabolism

JF - Cell Metabolism

IS - 6

ER -

Macrophage-Released Pyrimidines Inhibit Gemcitabine Therapy in Pancreatic Cancer

Abstract

All Science Journal Classification (ASJC) codes

Access to Document

Other files and links

Fingerprint

Cite this