Abstract
Photoreceptors are specialized neurons that rely on Ca2+ to regulate phototransduction and neurotransmission. Photoreceptor dysfunction and degeneration occur when intracellular Ca2+ homeostasis is disrupted. Ca2+ homeostasis is maintained partly by mitochondrial Ca2+ uptake through the mitochondrial Ca2+ uniporter (MCU), which can influence cytosolic Ca2+ signals, stimulate energy production, and trigger apoptosis. Here we discovered that zebrafish cone photoreceptors express unusually low levels of MCU. We expected that this would be important to prevent mitochondrial Ca2+ overload and consequent cone degeneration. To test this hypothesis, we generated a cone-specific model of MCU overexpression. Surprisingly, we found that cones tolerate MCU overexpression, surviving elevated mitochondrial Ca2+ and disruptions to mitochondrial ultrastructure until late adulthood. We exploited the survival of MCU overexpressing cones to additionally demonstrate that mitochondrial Ca2+ uptake alters the distributions of citric acid cycle intermediates and accelerates recovery kinetics of the cone response to light. Cones adapt to mitochondrial Ca2+ stress by decreasing MICU3, an enhancer of MCU-mediated Ca2+ uptake, and selectively transporting damaged mitochondria away from the ellipsoid toward the synapse. Our findings demonstrate how mitochondrial Ca2+ can influence physiological and metabolic processes in cones and highlight the remarkable ability of cone photoreceptors to adapt to mitochondrial stress.
Highlights
Photoreceptors are highly specialized sensory neurons responsible for vision
To quantify mitochondrial Ca2+ uniporter (MCU) expression in zebrafish cone photoreceptors, we took advantage of a zebrafish cone degeneration model caused by a mutation in the cone phosphodiesterase; in this model, cones selectively degenerate while rods and other retinal neurons are preserved (Stearns et al, 2007)
We analyzed MCU and mitochondrial membrane protein expression in the pde6c-/- mutants compared to their wild-type fish (WT) siblings and found that without cones there is a loss in mitochondrial membrane protein expression that is not reflected in a loss of MCU signal (Figure 1D,E)
Summary
In addition to having unique and vulnerable structural features, photoreceptors reside in the retina, a hostile cellular environment The copyright holder for this preprint It is made available under than most cells in the body Despite these chronic stressors, most people retain vision throughout their lives, highlighting the extraordinary ability of photoreceptors to regulate cellular homeostasis and maintain viability. Photoreceptors rely on Ca2+ as a second messenger to recover from light signals and adapt to constant illumination (Nakatani and Yau, 1988) In darkness they continuously release synaptic vesicles, which requires precise regulation of synaptic Ca2+ by L-type voltage-gated channels (Barnes and Kelly, 2002). Sustained light exposure or deficiencies of rhodopsin kinase and arrestin that cause sustained low intracellular Ca2+ cause degeneration of photoreceptors (Chen et al, 1999a, 1999b; LaVail et al, 1987)
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