Augmenting Vacuolar H+-ATPase Function Prevents Cardiomyocytes from Lipid-Overload Induced Dysfunction.
Shujin WangLi-Yen WongDietbert NeumannYilin LiuAomin SunGudrun AntoonsAgnieszka StrzeleckaJan F C GlatzMiranda NabbenJoost J F P LuikenPublished in: International journal of molecular sciences (2020)
The diabetic heart is characterized by a shift in substrate utilization from glucose to lipids, which may ultimately lead to contractile dysfunction. This substrate shift is facilitated by increased translocation of lipid transporter CD36 (SR-B2) from endosomes to the sarcolemma resulting in increased lipid uptake. We previously showed that endosomal retention of CD36 is dependent on the proper functioning of vacuolar H+-ATPase (v-ATPase). Excess lipids trigger CD36 translocation through inhibition of v-ATPase function. Conversely, in yeast, glucose availability is known to enhance v-ATPase function, allowing us to hypothesize that glucose availability, via v-ATPase, may internalize CD36 and restore contractile function in lipid-overloaded cardiomyocytes. Increased glucose availability was achieved through (a) high glucose (25 mM) addition to the culture medium or (b) adenoviral overexpression of protein kinase-D1 (a kinase mediating GLUT4 translocation). In HL-1 cardiomyocytes, adult rat and human cardiomyocytes cultured under high-lipid conditions, each treatment stimulated v-ATPase re-assembly, endosomal acidification, endosomal CD36 retention and prevented myocellular lipid accumulation. Additionally, these treatments preserved insulin-stimulated GLUT4 translocation and glucose uptake as well as contractile force. The present findings reveal v-ATPase functions as a key regulator of cardiomyocyte substrate preference and as a novel potential treatment approach for the diabetic heart.
Keyphrases
- high glucose
- endothelial cells
- endoplasmic reticulum
- fatty acid
- blood glucose
- type diabetes
- oxidative stress
- protein kinase
- heart failure
- nk cells
- transcription factor
- cell proliferation
- blood pressure
- atrial fibrillation
- smooth muscle
- metabolic syndrome
- risk assessment
- climate change
- single molecule
- gene expression
- young adults
- wound healing
- single cell
- structural basis
- tyrosine kinase