To prove the hypothesis that proximal tubular CB1Rs are critically involved in the pathogenesis of obesity- or diabetes-induced CKD, we have utilized our novel mouse strain that lacks CB1R in the RPTCs (RPTC-CB1R-/-), and subjected the KO mice and their littermate controls to either obesity or diabetes. In both cases, the null mice develop the same degree of obesity or diabetes as their littermate controls, BUT their kidney was completely protected from the development of dysfunction, inflammation and fibrosis.
Next, we elucidated the downstream cellular pathways involved in CB1R-induced CKD during obesity or diabetes. Our findings show that during obese conditions CB1R governs intracellular lipid accumulation in the RPTCs by modulating the PKA/LKB1/AMPK/ACC signaling pathway. During diabetes conditions, CB1R regulates Ca2+-dependent PKC-β1 activation, which, in turn, modulates the expression and translocation of the facilitative glucose transporter 2 (GLUT2) in RPTCs. We also revealed the existence of a CB1R/mTORC1 signaling axis in RPTCs and its importance in regulating kidney function in health and disease.
We also reported a novel kidney-to-bone axis modulated via RPTC-CB1R. Specifically, we showed that nullification of CB1R from the RPTCs preserved bone mass under hyperglycemic conditions via affecting both osteoclastogenesis and bone formation mediated by erythropoietin (EPO).
In addition, we have found that stimulating CB1R results in mitochondrial fragmentation in RPTCs, and this effect is associated with the progression of obesity-induced CKD, and most likely related to the increased phosphorylation of dynamin-related protein 1 (DRP-1) that regulates mitochondrial fission. CB1R-induced mitochondrial fission was found to be associated with mitochondrial dysfunction, as documented by reduced oxygen consumption and ATP production, increased reactive oxygen species and cellular lactate levels, as well as a decline in mitochondrial biogenesis.
Moreover, we show that pharmacological activation/blockade and genetic overexpression/deletion of hepatic CB1R modulates soluble leptin receptor (sOb-R) levels and hepatic leptin resistance. Interestingly, peripheral CB1R blockade failed to reverse diet-induced reduction of sOb-R levels, increased fat mass and dyslipidemia, and hepatic steatosis in mice lacking C/EBP homologous protein (CHOP), whereas direct activation of CB1R in wild-type hepatocytes reduced sOb-R levels in a CHOP-dependent manner.
Taken together, we have established the first complete view of the involvement of proximal tubular CB1R in the development of CKD, and delineated the cascade of events underlying the activation of CB1R in RPTCs that lead to diabetic renal dysfunction. In addition, we have uncovered a new role for CB1R as a direct modulator of mitochondrial function in RPTCs by regulating mitochondrial shape, biogenesis integrity and membrane physiology as well as identified its role in regulating bone remodeling during diabetes. Additionally, we highlight a novel molecular aspect by which the hepatic eCB/CB1R system is involved in the development of hepatic leptin resistance and in the regulation of sOb-R levels via CHOP.