Human Serum Metabolic Profiles Are Age Dependent

Overview

Journal Aging Cell

Specialties Cell Biology
Geriatrics

Date 2012 Jul 28

PMID 22834969

Citations 169

Authors

Zhonghao Yu

Guangju Zhai

Paula Singmann

Ying He

Tao Xu

Cornelia Prehn

Werner Romisch-Margl

Eva Lattka

Christian Gieger

Nicole Soranzo

Joachim Heinrich

Marie Standl

Elisabeth Thiering

Kirstin Mittelstrass

Heinz-Erich Wichmann

Annette Peters

Karsten Suhre

Yixue Li

Jerzy Adamski

Tim D Spector

Thomas Illig

Rui Wang-Sattler

Affiliations

Soon will be listed here.

Abstract

Understanding the complexity of aging is of utmost importance. This can now be addressed by the novel and powerful approach of metabolomics. However, to date, only a few metabolic studies based on large samples are available. Here, we provide novel and specific information on age-related metabolite concentration changes in human homeostasis. We report results from two population-based studies: the KORA F4 study from Germany as a discovery cohort, with 1038 female and 1124 male participants (32-81 years), and the TwinsUK study as replication, with 724 female participants. Targeted metabolomics of fasting serum samples quantified 131 metabolites by FIA-MS/MS. Among these, 71/34 metabolites were significantly associated with age in women/men (BMI adjusted). We further identified a set of 13 independent metabolites in women (with P values ranging from 4.6 × 10(-04) to 7.8 × 10(-42) , α(corr) = 0.004). Eleven of these 13 metabolites were replicated in the TwinsUK study, including seven metabolite concentrations that increased with age (C0, C10:1, C12:1, C18:1, SM C16:1, SM C18:1, and PC aa C28:1), while histidine decreased. These results indicate that metabolic profiles are age dependent and might reflect different aging processes, such as incomplete mitochondrial fatty acid oxidation. The use of metabolomics will increase our understanding of aging networks and may lead to discoveries that help enhance healthy aging.

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