Mitochondrial Dysfunction and Insulin Resistance: Topic of High Interest in Research

Introduction: Obesity and diabetes are associated with progressive cardiac fibrosis that, sequentially, results in diastolic dysfunction, reduced contractility, and ultimately heart failure. Contributing factors include hyperglycemia, insulin resistance, mitochondrial dysfunction, and a reduction in AMPK signaling. PGC-1α activates mitochondrial biogenesis and oxidative phosphorylation and is decreased in patients with diabetes mellitus (DM). We hypothesize that an epoxyeicosatrienoic acids (EETs) agonist (EET-A) will increase PGC-1α levels in a db mouse model of DM attenuate cardiomyopathy, and prevent heart failure. Methods: Db mice (4-wks), were allowed to acclimatize for 16-wks and were then divided into 3 treatment groups for an additional 16 wks: A) control, B) EET-A 1.5mg/100g BW 2 weeks and C) EET-A-Ln-PGC-1α shRNA. Ln-PGC-1α shRNA suppressed PGC-1α protein in heart tissue by 40-50%. Oxygen consumption (VO 2 ), and blood glucose was determined. Heart tissues were harvested to measure PGC-1α, HO-1, pAMPK, PGC-1α, echocardiographic fractional shortening, mitochondrial oxidative phosphorylation (OXPHOS) and mitofusion protein markers. Results: All mice developed heart failure by the end of 16 weeks and were characterized by a decrease in myocardial contractility, an increase in insulin resistance and blood pressure, decreased VO 2 , the appearance of mitochondria dysfunction and a decrease in AMPK and downstream PGC-1α signaling. Mice treated with EET-A demonstrated an increase in PGC-1α levels, improved mitochondrial function and oxidative phosphorylation (p<0.01 vs control), increased NO bioavailability (p<0.05 vs control), and normalization of glucose metabolism, insulin levels, VO 2 and LV systolic function (p<0.05 vs control). All of these findings were suppressed by PGC-1α inhibition which was accompanied by the onset of even more severe LV dysfunction than in the control group. Conclusion: Increased EET levels result in activation of PGC-1α-HO-1 which reverses diabetes induced insulin resistance, mitochondrial dysfunction, and cardiomyopathy. EET may have potential as a powerful agent for therapeutic application in the treatment of diabetic cardiomyopathy.

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Insulin Resistance Promotes Parkinson’s Disease through Aberrant Expression of α-Synuclein, Mitochondrial Dysfunction, and Deregulation of the Polo-Like Kinase 2 Signaling

Cells ◽

10.3390/cells9030740 ◽

2020 ◽

Vol 9 (3) ◽

pp. 740 ◽

Cited By ~ 5

Author(s):

Chien-Tai Hong ◽

Kai-Yun Chen ◽

Weu Wang ◽

Jing-Yuan Chiu ◽

Dean Wu ◽

...

Keyword(s):

Insulin Resistance ◽

Parkinson’S Disease ◽

Parkinson's Disease ◽

Mitochondrial Dysfunction ◽

Ex Vivo ◽

Proteinase K ◽

Ros Production ◽

Aberrant Expression ◽

In Vivo Models

Background: Insulin resistance (IR), considered a hallmark of diabetes at the cellular level, is implicated in pre-diabetes, results in type 2 diabetes, and negatively affects mitochondrial function. Diabetes is increasingly associated with enhanced risk of developing Parkinson’s disease (PD); however, the underlying mechanism remains unclear. This study investigated the probable culpability of IR in the pathogenesis of PD. Methods: Using MitoPark mice in vivo models, diabetes was induced by a high-fat diet in the in vivo models, and IR was induced by protracted pulse-stimulation with 100 nM insulin treatment of neuronal cells, in vitro to determine the molecular mechanism(s) underlying altered cellular functions in PD, including mitochondrial dysfunction and α-synuclein (SNCA) aberrant expression. Findings: We observed increased SNCA expression in the dopaminergic (DA) neurons of both the wild-type and diabetic MitoPark mice, coupled with enhanced degeneration of DA neurons in the diabetic MitoPark mice. Ex vivo, in differentiated human DA neurons, IR was associated with increased SNCA and reactive oxygen species (ROS) levels, as well as mitochondrial depolarization. Moreover, we demonstrated concomitant hyperactivation of polo-like kinase-2 (PLK2), and upregulated p-SNCA (Ser129) and proteinase K-resistant SNCA proteins level in IR SH-SY5Y cells, however the inhibition of PLK2 reversed IR-related increases in phosphorylated and total SNCA. Similarly, the overexpression of peroxisome proliferator-activated receptor-γ coactivator 1-alpha (PGC)-1α suppressed ROS production, repressed PLK2 hyperactivity, and resulted in downregulation of total and Ser129-phosphorylated SNCA in the IR SH-SY5Y cells. Conclusions: These findings demonstrate that IR-associated diabetes promotes the development and progression of PD through PLK2-mediated mitochondrial dysfunction, upregulated ROS production, and enhanced SNCA signaling, suggesting the therapeutic targetability of PLK2 and/or SNCA as potential novel disease-modifying strategies in patients with PD.

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