posted on 2018-04-19, 00:00authored byDan Wang, Deying Chen, Jiong Yu, Jingqi Liu, Xiaowei Shi, Yanni Sun, Qiaoling Pan, Xian Luo, Jinfeng Yang, Yang Li, Hongcui Cao, Liang Li, Lanjuan Li
The
placenta resides in a physiologically low oxygen microenvironment
of the body. Hypoxia induces a wide range of stem cell cellular activities.
Here, we report a workflow for exploring the role of physiological
(hypoxic, 5% oxygen) and original cell culture (normoxic, 21% oxygen)
oxygen concentrations in regulating the metabolic status of human
placenta-derived mesenchymal stem cells (hPMSCs). The general biological
characteristics of hPMSCs were assessed via a variety of approaches
such as cell counts, flow cytometry and differentiation study. A sensitive 13C/12C-dansyl labeling liquid chromatography–mass
spectrometry (LC–MS) method targeting the amine/phenol submetabolome
was used for metabolic profiling of the cell and corresponding culture
supernatant. Multivariate and univariate statistical analyses were
used to analyze the metabolomics data. hPMSCs cultured in hypoxia
display smaller size, higher proliferation, greater differentiation
ability and no difference in immunophenotype. Overall, 2987 and 2860
peak pairs or metabolites were detected and quantified in hPMSCs and
culture supernatant, respectively. Approximately 86.0% of cellular
metabolites and 84.3% of culture supernatant peak pairs were identified
using a dansyl standard library or matched to metabolite structures
using accurate mass search against human metabolome libraries. The
orthogonal partial least-squares discriminant analysis (OPLS-DA) showed
a clear separation between the hypoxic group and the normoxic group.
Ten metabolites from cells and six metabolites from culture supernatant
were identified as potential biomarkers of hypoxia. This study demonstrated
that chemical isotope labeling LC–MS can be used to reveal
the role of oxygen in the regulation of hPMSC metabolism, whereby
physiological oxygen concentrations may promote arginine and proline
metabolism, pantothenate and coenzyme A (CoA) biosynthesis, and alanine,
aspartate and glutamate metabolism.