Role of defective calcium regulation in cardiorespiratory dysfunction in Huntington’s disease
Haikel Dridi, Xiaoping Liu, Qi Yuan, Steve Reiken, Mohamad Yehya, Leah Sittenfeld, Panagiota Apostolou, Julie Buron, Pierre Sicard, Stefan Matecki, Jérome Thireau, Clement Menuet, Alain Lacampagne, Andrew R. Marks
Haikel Dridi, Xiaoping Liu, Qi Yuan, Steve Reiken, Mohamad Yehya, Leah Sittenfeld, Panagiota Apostolou, Julie Buron, Pierre Sicard, Stefan Matecki, Jérome Thireau, Clement Menuet, Alain Lacampagne, Andrew R. Marks
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Research Article Cell biology Therapeutics

Role of defective calcium regulation in cardiorespiratory dysfunction in Huntington’s disease

Abstract

Huntington’s disease (HD) is a progressive, autosomal dominant neurodegenerative disorder affecting striatal neurons beginning in young adults with loss of muscle coordination and cognitive decline. Less appreciated is the fact that patients with HD also exhibit cardiac and respiratory dysfunction, including pulmonary insufficiency and cardiac arrhythmias. The underlying mechanism for these symptoms is poorly understood. In the present study we provide insight into the cause of cardiorespiratory dysfunction in HD and identify a potentially novel therapeutic target. We now show that intracellular calcium (Ca2+) leak via posttranslationally modified ryanodine receptor/intracellular calcium release (RyR) channels plays an important role in HD pathology. RyR channels were oxidized, PKA phosphorylated, and leaky in brain, heart, and diaphragm both in patients with HD and in a murine model of HD (Q175). HD mice (Q175) with endoplasmic reticulum Ca2+ leak exhibited cognitive dysfunction, decreased parasympathetic tone associated with cardiac arrhythmias, and reduced diaphragmatic contractile function resulting in impaired respiratory function. Defects in cognitive, motor, and respiratory functions were ameliorated by treatment with a novel Rycal small-molecule drug (S107) that fixes leaky RyR. Thus, leaky RyRs likely play a role in neuronal, cardiac, and diaphragmatic pathophysiology in HD, and RyRs are a potential novel therapeutic target.

Authors

Haikel Dridi, Xiaoping Liu, Qi Yuan, Steve Reiken, Mohamad Yehya, Leah Sittenfeld, Panagiota Apostolou, Julie Buron, Pierre Sicard, Stefan Matecki, Jérome Thireau, Clement Menuet, Alain Lacampagne, Andrew R. Marks

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Figure 6

Sympathovagal imbalance and arrhythmias in HD during rest period.

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Sympathovagal imbalance and arrhythmias in HD during rest period. (A) Re...
(A) Representative ECG trace in freely moving conscious animals allowing HR (bpm) measurement in WT and Q175 mice treated or not with S107 or ARM036 during light (rest period) and dark (awake period) cycles. (B) HR (bpm) average during awake and rest periods in WT (n = 5), Q175 (n = 8), and Q175 mice treated or not with S107 (n = 6) or ARM036 (n = 6). (C) HR average record. Hexamethonium injection (20 mg/kg) had moderate effects on HR related to suppression of cardiac autonomic control of HR, that is, lowering HR during the daylight period in Q175 (n = 6) and Q175 mice treated or not with S107 (n = 6) or ARM036 (n = 6). Data (mean ± SD) analysis was performed by 1-way ANOVA. Bonferroni’s posttest revealed *P < 0.05 vs. WT, #P < 0.05 vs. Q175 at rest period. Student’s t test, $P < 0.05 rest vs. awake period and baseline vs. hexamethonium. (D and E) Low-frequency (LFr) spectral power density measured by HRV analysis using fast Fourier transformation (LFr: 0.15–1.5 Hz) in WT, Q175, Q175+ARM036, and Q175+S107 during rest and awake periods (n = 5–8 mouse/group). (F and G) High-frequency (HFr) spectral power measured by HRV analysis using fast Fourier transformation (HFr: 1.5–5 Hz) during rest and awake periods in WT, Q175, Q175+ARM036, and Q175+S107 (n = 5–8 mouse/group). (H and I) LFr/HFr ratio (n = 5–8 mouse/group). (J and K) Number of isolated and triplet (3 consecutive) ventricular extrasystoles (VESs) during 10 hours in WT, Q175, Q175+ARM036, and Q175+S107 during rest and awake periods (n = 5–8 mouse/group). Comparison of HRV (standard deviation of NN intervals) and VESs at rest versus awake is shown in Supplemental Figure 5, D–F. Representative example of VESs in Q175 mice is shown in Supplemental Figure 5G. Data (mean ± SD) analysis was performed by 1-way ANOVA. Bonferroni’s posttest revealed *P < 0.05 vs. WT, #P < 0.05 vs. Q175. Scale bar: 110 ms.