Quantitative proteomics reveals oxygen-dependent changes in neuronal mitochondria affecting function and sensitivity to rotenone.

Mitochondria are implicated in a variety of degenerative disorders and aging. Mitochondria are responsive to the oxygen in their environment, yet tissue culture is performed at atmospheric (21%) oxygen and not at physiological (1-11%) oxygen levels found in tissues. We employed imaging of mitochondrial probes, mass spectrometry, Western blots, and ATP assays of the human neuroblastoma cell-line SH-SY5Y and imaging of mitochondrial probes in human primary neurons under standard nonphysiological oxygen conditions (atmospheric) and under physiological oxygen levels in the nervous system to assess the impact of oxygen on mitochondrial function. SH-SY5Y cells cultured in physiological 5% oxygen exhibited the lowest reactive oxygen species (ROS) production, indicating that culture at 5% oxygen is favored; these results were mimicked in primary human cells. Mass spectrometric analysis revealed extensive mitochondrial proteomic alterations in SH-SY5Y cells based on oxygen culture condition. Among these, the rotenone-sensitive subunit of complex I NDUFV3 was increased in cells cultured at 5% oxygen. Rotenone is a Parkinson's disease-linked toxin, and correspondingly SH-SY5Y cells cultured at 5% oxygen also exhibited over 10 times greater sensitivity to rotenone than those cultured in atmospheric, 21%, oxygen. Our results indicate that neuronal mitochondria are responsive to oxygen levels and produce differential responses under different oxygen levels.

Determination of hair cell metabolic state in isolated cochlear preparations by two-photon microscopy.

Currently there is no accepted method to measure the metabolic status of the organ of Corti. Since metabolism and mitochondrial dysfunction are expected to play a role in many different hearing disorders, here for the first time we employ two-photon metabolic imaging to assess the metabolic status of the cochlea. When excited with ultrashort pulses of 740-nm light, both inner and outer hair cells in isolated murine cochlear preparations exhibited intrinsic fluorescence. This fluorescence is characterized and shown to be consistent with a mixture of oxidized flavoproteins (Fp) and reduced nicotinamide adenine dinucleotide (NADH). The location of the fluorescence within hair cells is also consistent with the different mitochondrial distributions in these cell types. Treatments with cyanide and mitochondrial uncouplers show that hair cells are metabolically active. Both NADH and Fp in inner hair cells gradually become completely oxidized within 50 min from the time of death of the animal. Outer hair cells show similar trends but are found to have greater variability. We show that it is possible to use two-photon metabolic imaging to assess metabolism in the mouse organ of Corti.

Photobleaching of reduced nicotinamide adenine dinucleotide and the development of highly fluorescent lesions in rat basophilic leukemia cells during multiphoton microscopy.

Endogenous reduced nicotinamide adenine dinucleotide (NADH) fluorescence provides an intrinsic indicator of the cellular metabolic state, but prolonged monitoring is limited by photobleaching and/or phototoxicity. Multiphoton excitation of NADH by ultrashort, 740-nm laser pulses provides a significant improvement over UV excitation by eliminating peripheral photobleaching; however, molecules within the subfemtoliter excitation volume remain susceptible. We have investigated the photophysical mechanisms responsible for multiphoton photobleaching of NADH in living cells to permit the imaging technique to be optimized. The loss of fluorescence because of multiphoton photobleaching was measured by repetitively imaging individual planes within rat basophilic leukemia cells. The photobleaching rate was proportional to the fourth power of the laser intensity. Based on these measurements, we propose a double-biphotonic, four-photon photobleaching mechanism and estimate the quantum yield of photobleaching of intracellular NADH to be 0.0073 +/- 0.0002 by this mechanism. In addition to photobleaching, the development of bright, punctate fluorescent lesions can also be observed. The frequency of lesion formation also increased approximately as the fourth power of the laser intensity after an intensity-dependent threshold number of images had been exceeded. The consequences for two-photon metabolic imaging are discussed.