Role of Increased n-acetylaspartate Levels in Cancer

Behrouz Zand; Rebecca A. Previs; Niki M. Zacharias; Rajesha Rupaimoole; Takashi Mitamura; Archana Sidalaghatta Nagaraja; Michele Guindani; Heather J. Dalton; Lifeng Yang; Joelle Baddour; Abhinav Achreja; Wei Hu; Chad V. Pecot; Cristina Ivan; Sherry Y. Wu; Christopher R. McCullough; Kshipra M. Gharpure; Einav Shoshan; Sunila Pradeep; Lingegowda S. Mangala; Cristian Rodriguez-Aguayo; Ying Wang; Alpa M. Nick; Michael A. Davies; Guillermo Armaiz-Pena; Jinsong Liu; Susan K. Lutgendorf; Keith A. Baggerly; Menashe Bar Eli; Gabriel Lopez-Berestein; Deepak Nagrath; Pratip K. Bhattacharya; Anil K. Sood

doi:10.1093/jnci/djv426

Role of Increased n-acetylaspartate Levels in Cancer

Behrouz Zand, Rebecca A. Previs, Niki M. Zacharias, Rajesha Rupaimoole, Takashi Mitamura, Archana Sidalaghatta Nagaraja, Michele Guindani, Heather J. Dalton, Lifeng Yang, Joelle Baddour, Abhinav Achreja, Wei Hu, Chad V. Pecot, Cristina Ivan, Sherry Y. Wu, Christopher R. McCullough, Kshipra M. Gharpure, Einav Shoshan, Sunila Pradeep, Lingegowda S. MangalaCristian Rodriguez-Aguayo, Ying Wang, Alpa M. Nick, Michael A. Davies, Guillermo Armaiz-Pena, Jinsong Liu, Susan K. Lutgendorf, Keith A. Baggerly, Menashe Bar Eli, Gabriel Lopez-Berestein, Deepak Nagrath, Pratip K. Bhattacharya, Anil K. Sood

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

46 Scopus citations

Abstract

Background: The clinical and biological effects of metabolic alterations in cancer are not fully understood. Methods: In high-grade serous ovarian cancer (HGSOC) samples (n = 101), over 170 metabolites were profiled and compared with normal ovarian tissues (n = 15). To determine NAT8L gene expression across different cancer types, we analyzed the RNA expression of cancer types using RNASeqV2 data available from the open access The Cancer Genome Atlas (TCGA) website (http://www.cbioportal.org/public-portal/). Using NAT8L siRNA, molecular techniques and histological analysis, we determined cancer cell viability, proliferation, apoptosis, and tumor growth in in vitro and in vivo (n = 6-10 mice/group) settings. Data were analyzed with the Student's t test and Kaplan-Meier analysis. Statistical tests were two-sided. Results: Patients with high levels of tumoral NAA and its biosynthetic enzyme, aspartate N-acetyltransferase (NAT8L), had worse overall survival than patients with low levels of NAA and NAT8L. The overall survival duration of patients with higher-than-median NAA levels (3.6 years) was lower than that of patients with lower-than-median NAA levels (5.1 years, P =. 03). High NAT8L gene expression in other cancers (melanoma, renal cell, breast, colon, and uterine cancers) was associated with worse overall survival. NAT8L silencing reduced cancer cell viability (HEYA8: control siRNA 90.61%±2.53, NAT8L siRNA 39.43%±3.00, P <. 001; A2780: control siRNA 90.59%±2.53, NAT8L siRNA 7.44%±1.71, P <. 001) and proliferation (HEYA8: control siRNA 74.83%±0.92, NAT8L siRNA 55.70%±1.54, P <. 001; A2780: control siRNA 50.17%±4.13, NAT8L siRNA 26.52%±3.70, P <. 001), which was rescued by addition of NAA. In orthotopic mouse models (ovarian cancer and melanoma), NAT8L silencing reduced tumor growth statistically significantly (A2780: control siRNA 0.52 g±0.15, NAT8L siRNA 0.08 g±0.17, P <. 001; HEYA8: control siRNA 0.79 g±0.42, NAT8L siRNA 0.24 g±0.18, P =. 008, A375-SM: control siRNA 0.55 g±0.22, NAT8L siRNA 0.21 g±0.17g, P =. 001). NAT8L silencing downregulated the anti-apoptotic pathway, which was mediated through FOXM1. Conclusion: These findings indicate that the NAA pathway has a prominent role in promoting tumor growth and represents a valuable target for anticancer therapy. Altered energy metabolism is a hallmark of cancer (1). Proliferating cancer cells have much greater metabolic requirements than nonproliferating differentiated cells (2,3). Moreover, altered cancer metabolism elevates unique metabolic intermediates, which can promote cancer survival and progression (4,5). Furthermore, emerging evidence suggests that proliferating cancer cells exploit alternative metabolic pathways to meet their high demand for energy and to accumulate biomass (6-8).

Original language	English (US)
Article number	djv426
Journal	Journal of the National Cancer Institute
Volume	108
Issue number	6
DOIs	https://doi.org/10.1093/jnci/djv426
State	Published - Jun 1 2016

ASJC Scopus subject areas

Oncology
Cancer Research

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10.1093/jnci/djv426

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Zand, B., Previs, R. A., Zacharias, N. M., Rupaimoole, R., Mitamura, T., Nagaraja, A. S., Guindani, M., Dalton, H. J., Yang, L., Baddour, J., Achreja, A., Hu, W., Pecot, C. V., Ivan, C., Wu, S. Y., McCullough, C. R., Gharpure, K. M., Shoshan, E., Pradeep, S., ... Sood, A. K. (2016). Role of Increased n-acetylaspartate Levels in Cancer. Journal of the National Cancer Institute, 108(6), Article djv426. https://doi.org/10.1093/jnci/djv426

Zand, B, Previs, RA, Zacharias, NM, Rupaimoole, R, Mitamura, T, Nagaraja, AS, Guindani, M, Dalton, HJ, Yang, L, Baddour, J, Achreja, A, Hu, W, Pecot, CV, Ivan, C, Wu, SY, McCullough, CR, Gharpure, KM, Shoshan, E, Pradeep, S, Mangala, LS , Rodriguez-Aguayo, C, Wang, Y, Nick, AM, Davies, MA, Armaiz-Pena, G, Liu, J, Lutgendorf, SK, Baggerly, KA, Eli, MB, Lopez-Berestein, G, Nagrath, D, Bhattacharya, PK & Sood, AK 2016, 'Role of Increased n-acetylaspartate Levels in Cancer', Journal of the National Cancer Institute, vol. 108, no. 6, djv426. https://doi.org/10.1093/jnci/djv426

@article{7a7e075af1874999a423fa3dee14adfa,

title = "Role of Increased n-acetylaspartate Levels in Cancer",

abstract = "Background: The clinical and biological effects of metabolic alterations in cancer are not fully understood. Methods: In high-grade serous ovarian cancer (HGSOC) samples (n = 101), over 170 metabolites were profiled and compared with normal ovarian tissues (n = 15). To determine NAT8L gene expression across different cancer types, we analyzed the RNA expression of cancer types using RNASeqV2 data available from the open access The Cancer Genome Atlas (TCGA) website (http://www.cbioportal.org/public-portal/). Using NAT8L siRNA, molecular techniques and histological analysis, we determined cancer cell viability, proliferation, apoptosis, and tumor growth in in vitro and in vivo (n = 6-10 mice/group) settings. Data were analyzed with the Student's t test and Kaplan-Meier analysis. Statistical tests were two-sided. Results: Patients with high levels of tumoral NAA and its biosynthetic enzyme, aspartate N-acetyltransferase (NAT8L), had worse overall survival than patients with low levels of NAA and NAT8L. The overall survival duration of patients with higher-than-median NAA levels (3.6 years) was lower than that of patients with lower-than-median NAA levels (5.1 years, P =. 03). High NAT8L gene expression in other cancers (melanoma, renal cell, breast, colon, and uterine cancers) was associated with worse overall survival. NAT8L silencing reduced cancer cell viability (HEYA8: control siRNA 90.61%±2.53, NAT8L siRNA 39.43%±3.00, P <. 001; A2780: control siRNA 90.59%±2.53, NAT8L siRNA 7.44%±1.71, P <. 001) and proliferation (HEYA8: control siRNA 74.83%±0.92, NAT8L siRNA 55.70%±1.54, P <. 001; A2780: control siRNA 50.17%±4.13, NAT8L siRNA 26.52%±3.70, P <. 001), which was rescued by addition of NAA. In orthotopic mouse models (ovarian cancer and melanoma), NAT8L silencing reduced tumor growth statistically significantly (A2780: control siRNA 0.52 g±0.15, NAT8L siRNA 0.08 g±0.17, P <. 001; HEYA8: control siRNA 0.79 g±0.42, NAT8L siRNA 0.24 g±0.18, P =. 008, A375-SM: control siRNA 0.55 g±0.22, NAT8L siRNA 0.21 g±0.17g, P =. 001). NAT8L silencing downregulated the anti-apoptotic pathway, which was mediated through FOXM1. Conclusion: These findings indicate that the NAA pathway has a prominent role in promoting tumor growth and represents a valuable target for anticancer therapy. Altered energy metabolism is a hallmark of cancer (1). Proliferating cancer cells have much greater metabolic requirements than nonproliferating differentiated cells (2,3). Moreover, altered cancer metabolism elevates unique metabolic intermediates, which can promote cancer survival and progression (4,5). Furthermore, emerging evidence suggests that proliferating cancer cells exploit alternative metabolic pathways to meet their high demand for energy and to accumulate biomass (6-8).",

author = "Behrouz Zand and Previs, {Rebecca A.} and Zacharias, {Niki M.} and Rajesha Rupaimoole and Takashi Mitamura and Nagaraja, {Archana Sidalaghatta} and Michele Guindani and Dalton, {Heather J.} and Lifeng Yang and Joelle Baddour and Abhinav Achreja and Wei Hu and Pecot, {Chad V.} and Cristina Ivan and Wu, {Sherry Y.} and McCullough, {Christopher R.} and Gharpure, {Kshipra M.} and Einav Shoshan and Sunila Pradeep and Mangala, {Lingegowda S.} and Cristian Rodriguez-Aguayo and Ying Wang and Nick, {Alpa M.} and Davies, {Michael A.} and Guillermo Armaiz-Pena and Jinsong Liu and Lutgendorf, {Susan K.} and Baggerly, {Keith A.} and Eli, {Menashe Bar} and Gabriel Lopez-Berestein and Deepak Nagrath and Bhattacharya, {Pratip K.} and Sood, {Anil K.}",

year = "2016",

month = jun,

day = "1",

doi = "10.1093/jnci/djv426",

language = "English (US)",

volume = "108",

journal = "Journal of the National Cancer Institute",

issn = "0027-8874",

publisher = "Oxford University Press",

number = "6",

}

TY - JOUR

T1 - Role of Increased n-acetylaspartate Levels in Cancer

AU - Zand, Behrouz

AU - Previs, Rebecca A.

AU - Zacharias, Niki M.

AU - Rupaimoole, Rajesha

AU - Mitamura, Takashi

AU - Nagaraja, Archana Sidalaghatta

AU - Guindani, Michele

AU - Dalton, Heather J.

AU - Yang, Lifeng

AU - Baddour, Joelle

AU - Achreja, Abhinav

AU - Hu, Wei

AU - Pecot, Chad V.

AU - Ivan, Cristina

AU - Wu, Sherry Y.

AU - McCullough, Christopher R.

AU - Gharpure, Kshipra M.

AU - Shoshan, Einav

AU - Pradeep, Sunila

AU - Mangala, Lingegowda S.

AU - Rodriguez-Aguayo, Cristian

AU - Wang, Ying

AU - Nick, Alpa M.

AU - Davies, Michael A.

AU - Armaiz-Pena, Guillermo

AU - Liu, Jinsong

AU - Lutgendorf, Susan K.

AU - Baggerly, Keith A.

AU - Eli, Menashe Bar

AU - Lopez-Berestein, Gabriel

AU - Nagrath, Deepak

AU - Bhattacharya, Pratip K.

AU - Sood, Anil K.

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Background: The clinical and biological effects of metabolic alterations in cancer are not fully understood. Methods: In high-grade serous ovarian cancer (HGSOC) samples (n = 101), over 170 metabolites were profiled and compared with normal ovarian tissues (n = 15). To determine NAT8L gene expression across different cancer types, we analyzed the RNA expression of cancer types using RNASeqV2 data available from the open access The Cancer Genome Atlas (TCGA) website (http://www.cbioportal.org/public-portal/). Using NAT8L siRNA, molecular techniques and histological analysis, we determined cancer cell viability, proliferation, apoptosis, and tumor growth in in vitro and in vivo (n = 6-10 mice/group) settings. Data were analyzed with the Student's t test and Kaplan-Meier analysis. Statistical tests were two-sided. Results: Patients with high levels of tumoral NAA and its biosynthetic enzyme, aspartate N-acetyltransferase (NAT8L), had worse overall survival than patients with low levels of NAA and NAT8L. The overall survival duration of patients with higher-than-median NAA levels (3.6 years) was lower than that of patients with lower-than-median NAA levels (5.1 years, P =. 03). High NAT8L gene expression in other cancers (melanoma, renal cell, breast, colon, and uterine cancers) was associated with worse overall survival. NAT8L silencing reduced cancer cell viability (HEYA8: control siRNA 90.61%±2.53, NAT8L siRNA 39.43%±3.00, P <. 001; A2780: control siRNA 90.59%±2.53, NAT8L siRNA 7.44%±1.71, P <. 001) and proliferation (HEYA8: control siRNA 74.83%±0.92, NAT8L siRNA 55.70%±1.54, P <. 001; A2780: control siRNA 50.17%±4.13, NAT8L siRNA 26.52%±3.70, P <. 001), which was rescued by addition of NAA. In orthotopic mouse models (ovarian cancer and melanoma), NAT8L silencing reduced tumor growth statistically significantly (A2780: control siRNA 0.52 g±0.15, NAT8L siRNA 0.08 g±0.17, P <. 001; HEYA8: control siRNA 0.79 g±0.42, NAT8L siRNA 0.24 g±0.18, P =. 008, A375-SM: control siRNA 0.55 g±0.22, NAT8L siRNA 0.21 g±0.17g, P =. 001). NAT8L silencing downregulated the anti-apoptotic pathway, which was mediated through FOXM1. Conclusion: These findings indicate that the NAA pathway has a prominent role in promoting tumor growth and represents a valuable target for anticancer therapy. Altered energy metabolism is a hallmark of cancer (1). Proliferating cancer cells have much greater metabolic requirements than nonproliferating differentiated cells (2,3). Moreover, altered cancer metabolism elevates unique metabolic intermediates, which can promote cancer survival and progression (4,5). Furthermore, emerging evidence suggests that proliferating cancer cells exploit alternative metabolic pathways to meet their high demand for energy and to accumulate biomass (6-8).

AB - Background: The clinical and biological effects of metabolic alterations in cancer are not fully understood. Methods: In high-grade serous ovarian cancer (HGSOC) samples (n = 101), over 170 metabolites were profiled and compared with normal ovarian tissues (n = 15). To determine NAT8L gene expression across different cancer types, we analyzed the RNA expression of cancer types using RNASeqV2 data available from the open access The Cancer Genome Atlas (TCGA) website (http://www.cbioportal.org/public-portal/). Using NAT8L siRNA, molecular techniques and histological analysis, we determined cancer cell viability, proliferation, apoptosis, and tumor growth in in vitro and in vivo (n = 6-10 mice/group) settings. Data were analyzed with the Student's t test and Kaplan-Meier analysis. Statistical tests were two-sided. Results: Patients with high levels of tumoral NAA and its biosynthetic enzyme, aspartate N-acetyltransferase (NAT8L), had worse overall survival than patients with low levels of NAA and NAT8L. The overall survival duration of patients with higher-than-median NAA levels (3.6 years) was lower than that of patients with lower-than-median NAA levels (5.1 years, P =. 03). High NAT8L gene expression in other cancers (melanoma, renal cell, breast, colon, and uterine cancers) was associated with worse overall survival. NAT8L silencing reduced cancer cell viability (HEYA8: control siRNA 90.61%±2.53, NAT8L siRNA 39.43%±3.00, P <. 001; A2780: control siRNA 90.59%±2.53, NAT8L siRNA 7.44%±1.71, P <. 001) and proliferation (HEYA8: control siRNA 74.83%±0.92, NAT8L siRNA 55.70%±1.54, P <. 001; A2780: control siRNA 50.17%±4.13, NAT8L siRNA 26.52%±3.70, P <. 001), which was rescued by addition of NAA. In orthotopic mouse models (ovarian cancer and melanoma), NAT8L silencing reduced tumor growth statistically significantly (A2780: control siRNA 0.52 g±0.15, NAT8L siRNA 0.08 g±0.17, P <. 001; HEYA8: control siRNA 0.79 g±0.42, NAT8L siRNA 0.24 g±0.18, P =. 008, A375-SM: control siRNA 0.55 g±0.22, NAT8L siRNA 0.21 g±0.17g, P =. 001). NAT8L silencing downregulated the anti-apoptotic pathway, which was mediated through FOXM1. Conclusion: These findings indicate that the NAA pathway has a prominent role in promoting tumor growth and represents a valuable target for anticancer therapy. Altered energy metabolism is a hallmark of cancer (1). Proliferating cancer cells have much greater metabolic requirements than nonproliferating differentiated cells (2,3). Moreover, altered cancer metabolism elevates unique metabolic intermediates, which can promote cancer survival and progression (4,5). Furthermore, emerging evidence suggests that proliferating cancer cells exploit alternative metabolic pathways to meet their high demand for energy and to accumulate biomass (6-8).

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JF - Journal of the National Cancer Institute

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ER -

Role of Increased n-acetylaspartate Levels in Cancer

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