posted on 2021-11-11, 16:37authored byGaurav Sharma, Xiaodong Wen, Nesmine R. Maptue, Thomas Hever, Craig R. Malloy, A. Dean Sherry, Chalermchai Khemtong
Cellular redox is intricately linked
to energy production and normal
cell function. Although the redox states of mitochondria and cytosol
are connected by shuttle mechanisms, the redox state of mitochondria
may differ from redox in the cytosol in response to stress. However,
detecting these differences in functioning tissues is difficult. Here,
we employed 13C magnetic resonance spectroscopy (MRS) and
co-polarized [1-13C]pyruvate and [1,3-13C2]acetoacetate ([1,3-13C2]AcAc) to monitor
production of hyperpolarized (HP) lactate and β-hydroxybutyrate
as indicators of cytosolic and mitochondrial redox, respectively.
Isolated rat hearts were examined under normoxic conditions, during
low-flow ischemia, and after pretreatment with either aminooxyacetate
(AOA) or rotenone. All interventions were associated with an increase
in [Pi]/[ATP] measured by 31P NMR. In well-oxygenated
untreated hearts, rapid conversion of HP [1-13C]pyruvate
to [1-13C]lactate and [1,3-13C2]AcAc
to [1,3-13C2]β-hydroxybutyrate ([1,3-13C2]β-HB) was readily detected. A significant
increase in HP [1,3-13C2]β-HB but not
[1-13C]lactate was observed in rotenone-treated and ischemic
hearts, consistent with an increase in mitochondrial NADH but not
cytosolic NADH. AOA treatments did not alter the productions of HP
[1-13C]lactate or [1,3-13C2]β-HB.
This study demonstrates that biomarkers of mitochondrial and cytosolic
redox may be detected simultaneously in functioning tissues using
co-polarized [1-13C]pyruvate and [1,3-13C2]AcAc and 13C MRS and that changes in mitochondrial
redox may precede changes in cytosolic redox.