Stable isotope resolved metabolomics analysis of ribonucleotide and RNA metabolism in human lung cancer cells

Teresa W.M. Fan, Jinlian Tan, Martin M. McKinney, Andrew N. Lane

Research output: Contribution to journalArticlepeer-review

40 Scopus citations

Abstract

We have developed a simple NMR-based method to determine the turnover of nucleotides and incorporation into RNA by stable isotope resolved metabolomics (SIRM) in A549 lung cancer cells. This method requires no chemical degradation of the nucleotides or chromatography. During cell growth, the free ribonucleotide pool is rapidly replaced by de novo synthesized nucleotides. Using [U- 13C]-glucose and [U- 13C, 15N]-glutamine as tracers, we showed that virtually all of the carbons in the nucleotide riboses were derived from glucose, whereas glutamine was preferentially utilized over glucose for pyrimidine ring biosynthesis, via the synthesis of Asp through the Krebs cycle. Incorporation of the glutamine amido nitrogen into the N3 and N9 positions of the purine rings was also demonstrated by proton-detected 15N NMR. The incorporation of 13C from glucose into total RNA was measured and shown to be a major sink for the nucleotides during cell proliferation. This method was applied to determine the metabolic action of an anti-cancer selenium agent (methylseleninic acid or MSA) on A549 cells. We found that MSA inhibited nucleotide turnover and incorporation into RNA, implicating an important role of nucleotide metabolism in the toxic action of MSA on cancer cells.

Original languageEnglish
Pages (from-to)517-527
Number of pages11
JournalMetabolomics
Volume8
Issue number3
DOIs
StatePublished - Jun 2012

Bibliographical note

Funding Information:
Acknowledgments The authors thank Dr. S. Arumugam for assistance in the NMR measurements. This study was supported in part by National Science Foundation EPSCoR grant # EPS-0447479; NIH NCRR Grant 5P20RR018733, 1R01CA118434-01A2 (to TWMF), 1RO1 CA101199 (to TWMF), R21CA133668-01 (to ANL) from the National Cancer Institute; the Kentucky Challenge for Excellence, and the Brown Foundation.

Funding

Acknowledgments The authors thank Dr. S. Arumugam for assistance in the NMR measurements. This study was supported in part by National Science Foundation EPSCoR grant # EPS-0447479; NIH NCRR Grant 5P20RR018733, 1R01CA118434-01A2 (to TWMF), 1RO1 CA101199 (to TWMF), R21CA133668-01 (to ANL) from the National Cancer Institute; the Kentucky Challenge for Excellence, and the Brown Foundation.

FundersFunder number
Kentucky Challenge for Excellence
NIH/NCRRR21CA133668-01, 5P20RR018733, 1R01CA118434-01A2, 1RO1 CA101199
National Science Foundation/EPSCoREPS-0447479
National Childhood Cancer Registry – National Cancer Institute
Brown Foundation

    Keywords

    • Nucleotide pools
    • RNA biosynthesis
    • SIRM
    • Selenium

    ASJC Scopus subject areas

    • Endocrinology, Diabetes and Metabolism
    • Biochemistry
    • Clinical Biochemistry

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