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Early disruption of nerve mitochondrial and myelin lipid homeostasis in obesity-induced diabetes
Juan P. Palavicini, Juan Chen, Chunyan Wang, Jianing Wang, Chao Qin, Eric Baeuerle, Xinming Wang, Jung A. Woo, David E. Kang, Nicolas Musi, Jeffrey L. Dupree, Xianlin Han
Juan P. Palavicini, Juan Chen, Chunyan Wang, Jianing Wang, Chao Qin, Eric Baeuerle, Xinming Wang, Jung A. Woo, David E. Kang, Nicolas Musi, Jeffrey L. Dupree, Xianlin Han
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Research Article Metabolism Neuroscience

Early disruption of nerve mitochondrial and myelin lipid homeostasis in obesity-induced diabetes

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Abstract

Diabetic neuropathy is a major complication of diabetes. Current treatment options alleviate pain but do not stop the progression of the disease. At present, there are no approved disease-modifying therapies. Thus, developing more effective therapies remains a major unmet medical need. Seeking to better understand the molecular mechanisms driving peripheral neuropathy, as well as other neurological complications associated with diabetes, we performed spatiotemporal lipidomics, biochemical, ultrastructural, and physiological studies on PNS and CNS tissue from multiple diabetic preclinical models. We unraveled potentially novel molecular fingerprints underlying nerve damage in obesity-induced diabetes, including an early loss of nerve mitochondrial (cardiolipin) and myelin signature (galactosylceramide, sulfatide, and plasmalogen phosphatidylethanolamine) lipids that preceded mitochondrial, myelin, and axonal structural/functional defects; started in the PNS; and progressed to the CNS at advanced diabetic stages. Mechanistically, we provided substantial evidence indicating that these nerve mitochondrial/myelin lipid abnormalities are (surprisingly) not driven by hyperglycemia, dysinsulinemia, or insulin resistance, but rather associate with obesity/hyperlipidemia. Importantly, our findings have major clinical implications as they open the door to novel lipid-based biomarkers to diagnose and distinguish different subtypes of diabetic neuropathy (obese vs. nonobese diabetics), as well as to lipid-lowering therapeutic strategies for treatment of obesity/diabetes-associated neurological complications and for glycemic control.

Authors

Juan P. Palavicini, Juan Chen, Chunyan Wang, Jianing Wang, Chao Qin, Eric Baeuerle, Xinming Wang, Jung A. Woo, David E. Kang, Nicolas Musi, Jeffrey L. Dupree, Xianlin Han

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Figure 6

Reduced cellular respiration in sciatic nerve tissue of obese diabetic mice.

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Reduced cellular respiration in sciatic nerve tissue of obese diabetic m...
Sciatic nerves (left and right) were permeabilized with collagenase, desheathed, and defluffed, while spinal cords were homogenized on a Kontes glass homogenizer in MiR06-Creatine respiration medium. High-resolution respirometry was conducted on Oxygraph-2K (Oroboros). Representative respirometric traces from sciatic nerve (A and B) and spinal cord (D and E) tissues using a substrate-uncoupler-inhibition titration (SUIT) protocol to measure oxygen consumption in WT (open circles/bars) and db/db (filled circles/bars) mice. Traces represent the oxygen concentration of the chamber (left y axis) and the oxygen flux per sciatic nerve unit or spinal cord mass (right y axis). Respiration analyses for sciatic nerve (C) and spinal cord tissue (F) are graphically represented as dot plots with bars; each dot represents 1 animal; data are displayed as the mean ± SEM of n = 6–7 male mice/genotype/tissue. Respiration parameters were compared between genotypes using 2-way ANOVA and Holm-Šidák multiple-comparisons tests on GraphPad Prism 7. *P < 0.05, ***P < 0.001. “Genotype effect” describes the global 2-way ANOVA results (considering all the measurements). The P value markers shown above brackets are from the multiple comparisons done between genotypes for each individual measure. ETFL (fatty acid oxidation in the absence of ADP [state 2]); ETFP (fatty acid oxidation coupled to ATP production); CIP (complex I-linked respiration coupled [state 3]); CI + CIIP (complex I and complex II-linked respiration coupled [state 3]); CI + CIIE (complex I and complex II-linked respiration uncoupled [maximum respiration]); and CIIE (complex II activity uncoupled). Experimental mice were 2–2.5 months old. MAL, malate; OCT, octanoylcarnitine; GLUT, glutamate; SUCC, succinate; CYTOC, cytochrome c; FCCP, carbonylcyanide p-trifluoromethoxyphenylhydrazone; ROT, rotenone; MNA, malonic acid; AA, antimycin A.

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