Key Points aPC protects from myocardial and renal IRIs by restricting mTORC1-mediated activation of the Nlrp3 inflammasome. Nlrp3 inflammasome suppression by aPC is independent of its anticoagulant effect, depends on PAR-1, and can be mimicked by parmodulin-2.
Established therapies for diabetic nephropathy (dNP) delay but do not prevent its progression. The shortage of established therapies may reflect the inability to target the tubular compartment. The chemical chaperone tauroursodeoxycholic acid (TUDCA) ameliorates maladaptive endoplasmic reticulum (ER) stress signaling and experimental dNP. Additionally, TUDCA activates the farnesoid X receptor (FXR), which is highly expressed in tubular cells. We hypothesized that TUDCA ameliorates maladaptive ER signaling FXR agonism specifically in tubular cells. Indeed, TUDCA induced expression of FXR-dependent genes ( and ) in tubular cells but not in other renal cells., TUDCA reduced glomerular and tubular injury in db/db and diabetic endothelial nitric oxide synthase-deficient mice. FXR inhibition with Z-guggulsterone or vivo-morpholino targeting of FXR diminished the ER-stabilizing and renoprotective effects of TUDCA. Notably, these approaches abolished tubular but not glomerular protection by TUDCA. Combined intervention with TUDCA and the angiotensin-converting enzyme inhibitor enalapril in 16-week-old db/db mice reduced albuminuria more efficiently than did either treatment alone. Although both therapies reduced glomerular damage, only TUDCA ameliorated tubular damage. Thus, interventions that specifically protect the tubular compartment in dNP, such as FXR agonism, may provide renoprotective effects on top of those achieved by inhibiting angiotensin-converting enzyme.
Coagulation proteases have increasingly recognized functions beyond hemostasis and thrombosis. Disruption of activated protein C (aPC) or insulin signaling both impair function of podocytes and ultimately cause dysfunction of the glomerular filtration barrier and diabetic kidney disease (DKD). We here show that insulin and aPC converge on a common spliced-X-box binding protein-1 (sXBP1) signaling pathway to maintain endoplasmic reticulum (ER)-homeostasis. Analogous to insulin, physiological levels of aPC maintain endoplasmic reticulum (ER) proteostasis in DKD. Accordingly, genetically impaired protein C activation exacerbates maladaptive ER-response, while genetic or pharmacological restoration of aPC maintains ER-proteostasis in DKD models. Importantly, in mice with podocyte specific deficiency of insulin receptor (INSR), aPC selectively restores the activity of the cytoprotective ER-transcription factor sXBP1 by temporally targeting INSR downstream signaling intermediates, the regulatory subunits of PI3Kinase, p85α and p85β. Genome-wide mapping of condition-specific XBP1-transcriptional regulatory patterns confirmed that concordant UPR target genes are involved in maintenance of ER-proteostasis by both insulin and aPC. Thus, aPC efficiently employs disengaged insulin signaling components to re-configure ER-signaling and restore proteostasis. These results identify ER-reprogramming as a novel hormone-like function of coagulation proteases and demonstrate that targeting insulin signaling intermediates may be a feasible therapeutic approach ameliorating defective insulin signaling.
A major obstacle in diabetes is the metabolic or hyperglycemic memory, which lacks specific therapies. Here we show that glucose-mediated changes in gene expression largely persist in diabetic kidney disease (DKD) despite reversing hyperglycemia. The senescence-associated cyclin-dependent kinase inhibitor p21 (Cdkn1a) was the top hit among genes persistently induced by hyperglycemia and was associated with induction of the p53-p21 pathway. Persistent p21 induction was confirmed in various animal models, human samples and in vitro models. Tubular and urinary p21-levels were associated with DKD severity and remained elevated despite improved blood glucose levels in humans. Mechanistically, sustained tubular p21 expression in DKD is linked to demethylation of its promoter and reduced DNMT1 expression. Two disease resolving agents, protease activated protein C (3K3A-aPC) and parmodulin-2, reversed sustained tubular p21 expression, tubular senescence, and DKD. Thus, p21-dependent tubular senescence is a pathway contributing to the hyperglycemic memory, which can be therapeutically targeted.
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