Gain of glucose-independent growth upon metastasis of breast cancer cells to the brain

Jinyu Chen; Ho Jeong Lee; Xuefeng Wu; Lei Huo; Sun Jin Kim; Lei Xu; Yan Wang; Junqing He; Lakshmi R. Bollu; Guang Gao; Fei Su; James Briggs; Xiaojing Liu; Tamar Melman; John M. Asara; Isaiah J. Fidler; Lewis C. Cantley; Jason W. Locasale; Zhang Weihua

doi:10.1158/0008-5472.CAN-14-2268

Gain of glucose-independent growth upon metastasis of breast cancer cells to the brain

Jinyu Chen, Ho Jeong Lee, Xuefeng Wu, Lei Huo, Sun Jin Kim, Lei Xu, Yan Wang, Junqing He, Lakshmi R. Bollu, Guang Gao, Fei Su, James Briggs, Xiaojing Liu, Tamar Melman, John M. Asara, Isaiah J. Fidler, Lewis C. Cantley, Jason W. Locasale, Zhang Weihua

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

123 Scopus citations

Abstract

Breast cancer brain metastasis is resistant to therapy and a particularly poor prognostic feature in patient survival. Altered metabolism is a common feature of cancer cells, but little is known as to what metabolic changes benefit breast cancer brain metastases. We found that brain metastatic breast cancer cells evolved the ability to survive and proliferate independent of glucose due to enhanced gluconeogenesis and oxidations of glutamine and branched chain amino acids, which together sustain the nonoxidative pentose pathway for purine synthesis. Silencing expression of fructose-1,6-bisphosphatases (FBP) in brain metastatic cells reduced their viability and improved the survival of metastasisbearing immunocompetent hosts. Clinically, we showed that brain metastases from human breast cancer patients expressed higher levels of FBP and glycogen than the corresponding primary tumors. Together, our findings identify a critical metabolic condition required to sustain brain metastasis and suggest that targeting gluconeogenesismay help eradicate this deadly feature in advanced breast cancer patients.

Original language	English (US)
Pages (from-to)	554-565
Number of pages	12
Journal	Cancer Research
Volume	75
Issue number	3
DOIs	https://doi.org/10.1158/0008-5472.CAN-14-2268
State	Published - Feb 1 2015

ASJC Scopus subject areas

Oncology
Cancer Research

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Chen, J., Lee, H. J., Wu, X., Huo, L., Kim, S. J., Xu, L., Wang, Y., He, J., Bollu, L. R., Gao, G., Su, F., Briggs, J., Liu, X., Melman, T., Asara, J. M., Fidler, I. J., Cantley, L. C., Locasale, J. W., & Weihua, Z. (2015). Gain of glucose-independent growth upon metastasis of breast cancer cells to the brain. Cancer Research, 75(3), 554-565. https://doi.org/10.1158/0008-5472.CAN-14-2268

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abstract = "Breast cancer brain metastasis is resistant to therapy and a particularly poor prognostic feature in patient survival. Altered metabolism is a common feature of cancer cells, but little is known as to what metabolic changes benefit breast cancer brain metastases. We found that brain metastatic breast cancer cells evolved the ability to survive and proliferate independent of glucose due to enhanced gluconeogenesis and oxidations of glutamine and branched chain amino acids, which together sustain the nonoxidative pentose pathway for purine synthesis. Silencing expression of fructose-1,6-bisphosphatases (FBP) in brain metastatic cells reduced their viability and improved the survival of metastasisbearing immunocompetent hosts. Clinically, we showed that brain metastases from human breast cancer patients expressed higher levels of FBP and glycogen than the corresponding primary tumors. Together, our findings identify a critical metabolic condition required to sustain brain metastasis and suggest that targeting gluconeogenesismay help eradicate this deadly feature in advanced breast cancer patients.",

author = "Jinyu Chen and Lee, {Ho Jeong} and Xuefeng Wu and Lei Huo and Kim, {Sun Jin} and Lei Xu and Yan Wang and Junqing He and Bollu, {Lakshmi R.} and Guang Gao and Fei Su and James Briggs and Xiaojing Liu and Tamar Melman and Asara, {John M.} and Fidler, {Isaiah J.} and Cantley, {Lewis C.} and Locasale, {Jason W.} and Zhang Weihua",

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doi = "10.1158/0008-5472.CAN-14-2268",

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AU - Lee, Ho Jeong

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AU - Xu, Lei

AU - Wang, Yan

AU - He, Junqing

AU - Bollu, Lakshmi R.

AU - Gao, Guang

AU - Su, Fei

AU - Briggs, James

AU - Liu, Xiaojing

AU - Melman, Tamar

AU - Asara, John M.

AU - Fidler, Isaiah J.

AU - Cantley, Lewis C.

AU - Locasale, Jason W.

AU - Weihua, Zhang

PY - 2015/2/1

Y1 - 2015/2/1

N2 - Breast cancer brain metastasis is resistant to therapy and a particularly poor prognostic feature in patient survival. Altered metabolism is a common feature of cancer cells, but little is known as to what metabolic changes benefit breast cancer brain metastases. We found that brain metastatic breast cancer cells evolved the ability to survive and proliferate independent of glucose due to enhanced gluconeogenesis and oxidations of glutamine and branched chain amino acids, which together sustain the nonoxidative pentose pathway for purine synthesis. Silencing expression of fructose-1,6-bisphosphatases (FBP) in brain metastatic cells reduced their viability and improved the survival of metastasisbearing immunocompetent hosts. Clinically, we showed that brain metastases from human breast cancer patients expressed higher levels of FBP and glycogen than the corresponding primary tumors. Together, our findings identify a critical metabolic condition required to sustain brain metastasis and suggest that targeting gluconeogenesismay help eradicate this deadly feature in advanced breast cancer patients.

AB - Breast cancer brain metastasis is resistant to therapy and a particularly poor prognostic feature in patient survival. Altered metabolism is a common feature of cancer cells, but little is known as to what metabolic changes benefit breast cancer brain metastases. We found that brain metastatic breast cancer cells evolved the ability to survive and proliferate independent of glucose due to enhanced gluconeogenesis and oxidations of glutamine and branched chain amino acids, which together sustain the nonoxidative pentose pathway for purine synthesis. Silencing expression of fructose-1,6-bisphosphatases (FBP) in brain metastatic cells reduced their viability and improved the survival of metastasisbearing immunocompetent hosts. Clinically, we showed that brain metastases from human breast cancer patients expressed higher levels of FBP and glycogen than the corresponding primary tumors. Together, our findings identify a critical metabolic condition required to sustain brain metastasis and suggest that targeting gluconeogenesismay help eradicate this deadly feature in advanced breast cancer patients.

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Gain of glucose-independent growth upon metastasis of breast cancer cells to the brain

Abstract

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