Plasma Metabolome Signature Indicative of BRCA1 Germline Status Independent of Cancer Incidence

Plasma Metabolome Signature Indicative of BRCA1 Germline Status Independent of Cancer Incidence

Individuals carrying a pathogenic germline variant in the breast cancer predisposition gene (g +) are prone to developing breast cancer. Apart from its well-known role in DNA repair, BRCA1 has been shown to powerfully impact cellular metabolism. While, in general, metabolic reprogramming was named a...

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Published in:Frontiers in oncology Vol. 11; p. 627217
Main Authors: Penkert, Judith, Märtens, Andre, Seifert, Martin, Auber, Bernd, Derlin, Katja, Hille-Betz, Ursula, Hörmann, Philipp, Klopp, Norman, Prokein, Jana, Schlicker, Lisa, Wacker, Frank, Wallaschek, Hannah, Schlegelberger, Brigitte, Hiller, Karsten, Ripperger, Tim, Illig, Thomas
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 07-04-2021
Subjects:
BRCA1 germline mutation
breast cancer
energy metabolism
HIF1 alpha
NAD+ balance
Oncology
plasma metabolome
BRCA1 germline mutation
NAD+ balance
HIF1 alpha
breast cancer
plasma metabolome
lactate
aerobic glycolysis
energy metabolism
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Summary:Individuals carrying a pathogenic germline variant in the breast cancer predisposition gene (g +) are prone to developing breast cancer. Apart from its well-known role in DNA repair, BRCA1 has been shown to powerfully impact cellular metabolism. While, in general, metabolic reprogramming was named a hallmark of cancer, disrupted metabolism has also been suggested to drive cancer cell evolution and malignant transformation by critically altering microenvironmental tissue integrity. Systemic metabolic effects induced by germline variants in cancer predisposition genes have been demonstrated before. Whether or not systemic metabolic alterations exist in g + individuals independent of cancer incidence has not been investigated yet. We therefore profiled the plasma metabolome of 72 g + women and 72 age-matched female controls, none of whom (carriers and non-carriers) had a prior cancer diagnosis and all of whom were cancer-free during the follow-up period. We detected one single metabolite, pyruvate, and two metabolite ratios involving pyruvate, lactate, and a metabolite of yet unknown structure, significantly altered between the two cohorts. A machine learning signature of metabolite ratios was able to correctly distinguish between g + and controls in ~82%. The results of this study point to innate systemic metabolic differences in g + women independent of cancer incidence and raise the question as to whether or not constitutional alterations in energy metabolism may be involved in the etiology of -associated breast cancer.
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These authors share senior authorship
Edited by: Federica Sotgia, University of Salford, United Kingdom
This article was submitted to Cancer Metabolism, a section of the journal Frontiers in Oncology
Reviewed by: Maria Adelaide Caligo, Pisana University Hospital, Italy; Steven Narod, University of Toronto, Canada
These authors share first authorship
ISSN:2234-943X
2234-943X
DOI:10.3389/fonc.2021.627217