Systemic isradipine treatment diminishes calcium-dependent mitochondrial oxidant stress
Jaime N. Guzman, … , Paul T. Schumacker, D. James Surmeier
Jaime N. Guzman, … , Paul T. Schumacker, D. James Surmeier
Published April 30, 2018
Citation Information: J Clin Invest. 2018;128(6):2266-2280. https://doi.org/10.1172/JCI95898.
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Research Article Neuroscience

Systemic isradipine treatment diminishes calcium-dependent mitochondrial oxidant stress

Abstract

The ability of the Cav1 channel inhibitor isradipine to slow the loss of substantia nigra pars compacta (SNc) dopaminergic (DA) neurons and the progression of Parkinson’s disease (PD) is being tested in a phase 3 human clinical trial. But it is unclear whether and how chronic isradipine treatment will benefit SNc DA neurons in vivo. To pursue this question, isradipine was given systemically to mice at doses that achieved low nanomolar concentrations in plasma, near those achieved in patients. This treatment diminished cytosolic Ca2+ oscillations in SNc DA neurons without altering autonomous spiking or expression of Ca2+ channels, an effect mimicked by selectively knocking down expression of Cav1.3 channel subunits. Treatment also lowered mitochondrial oxidant stress, reduced a high basal rate of mitophagy, and normalized mitochondrial mass — demonstrating that Cav1 channels drive mitochondrial oxidant stress and turnover in vivo. Thus, chronic isradipine treatment remodeled SNc DA neurons in a way that should not only diminish their vulnerability to mitochondrial challenges, but to autophagic stress as well.

Authors

Jaime N. Guzman, Ema Ilijic, Ben Yang, Javier Sanchez-Padilla, David Wokosin, Dan Galtieri, Jyothisri Kondapalli, Paul T. Schumacker, D. James Surmeier

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Figure 4

Chronic administration of isradipine reduced dendritic Ca2+ oscillations without inducing compensations in channel expression.

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Chronic administration of isradipine reduced dendritic Ca2+ oscillations...
(A) qPCR revealed no significant change in the mRNA expression of Cav1.3, Cav1.2, Cav3.1, and Cav3.2 Ca2+ channels after chronic isradipine treatment (n = 6 tissues from each group os 3 mice for Cav1.2 and Cav1.3; n = 7 tissues from each group of 3 mice for Cav3.1 and Cav3.2). (B) Perforated-patched recordings from vehicle-treated (black) and isradipine-treated (green) neurons. (C) Pacemaking rates in SNc DA neurons from control and isradipine-treated mice were unchanged (vehicle, 9 neurons from 4 mice; isradipine, 11 neurons from 4 mice). (D) Whole-cell somatic recording (left) and distal dendritic Ca2+ transients; chronic isradipine treatment (green trace, upper middle) reduced dendritic Ca2+ oscillations. Removal of the pumps (washout) led to restoration of the oscillation (lower right, black traces). (E) Peak and average proximal dendritic Ca2+ measurements under control (from Figure 2, B and C), isradipine-treated, and isradipine-washout conditions (control, 28 neurons from 23 mice; chronic isradipine, 5 neurons from 5 mice; washout, 5 neurons from 5 mice). (F) Summary of data from distal dendrites (control, 31 neurons from 22 mice; chronic isradipine, 8 neurons from 8 mice; acute 10 nM isradipine, 14 neurons from 6 mice; washout, 5 neurons from 5 mice). (G) Average Ca2+ transients in control (black trace) and isradipine-treated (green trace) distal dendrite of an SNc DA neuron. (H) Box plots summarizing the ramp [Ca2+] in control (n = 8 neurons from 6 mice, from Figure 3G), Cav1.3 shRNA–injected (n = 5 neurons from 5 mice, from historical Cav1.3 shRNA in Figure 3G), and chronic isradipine (n = 9 neurons from 8 mice) SNc DA neurons. Data were analyzed using 1-tailed Mann-Whitney U test with Dunn’s correction for multiple comparisons. *P < 0.05.