TY - JOUR
T1 - Signal integration at the PI3K-p85-XBP1 hub endows coagulation protease activated protein C with insulin-like function
AU - Madhusudhan, Thati
AU - Wang, Hongjie
AU - Ghosh, Sanchita
AU - Dong, Wei
AU - Kumar, Varun
AU - Al-Dabet, Moh’d Mohanad
AU - Manoharan, Jayakumar
AU - Nazir, Sumra
AU - Elwakiel, Ahmed
AU - Bock, Fabian
AU - Kohli, Shrey
AU - Marquardt, Andi
AU - Sögüt, Ibrahim
AU - Shahzad, Khurrum
AU - Müller, Andreas J.
AU - Esmon, Charles T.
AU - Nawroth, Peter P.
AU - Reiser, Jochen
AU - Chavakis, Triantafyllos
AU - Ruf, Wolfram
AU - Isermann, Berend
N1 - Publisher Copyright:
© 2017 by The American Society of Hematology.
PY - 2017/9/21
Y1 - 2017/9/21
N2 - Coagulation proteases have increasingly recognized functions beyond hemostasis and thrombosis. Disruption of activated protein C (aPC) or insulin signaling 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 ER proteostasis in DKD. Accordingly, genetically impaired protein C activation exacerbates maladaptive ER response, whereas 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, p85a and p85b. Genome-wide mapping of condition-specific XBP1-transcriptional regulatory patterns confirmed that concordant unfolded protein response target genes are involved in maintenance of ER proteostasis by both insulin and aPC. Thus, aPC efficiently employs disengaged insulin signaling components to reconfigure ER signaling and restore proteostasis. These results identify ER reprogramming as a novel hormonelike function of coagulation proteases and demonstrate that targeting insulin signaling intermediates may be a feasible therapeutic approach ameliorating defective insulin signaling.
AB - Coagulation proteases have increasingly recognized functions beyond hemostasis and thrombosis. Disruption of activated protein C (aPC) or insulin signaling 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 ER proteostasis in DKD. Accordingly, genetically impaired protein C activation exacerbates maladaptive ER response, whereas 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, p85a and p85b. Genome-wide mapping of condition-specific XBP1-transcriptional regulatory patterns confirmed that concordant unfolded protein response target genes are involved in maintenance of ER proteostasis by both insulin and aPC. Thus, aPC efficiently employs disengaged insulin signaling components to reconfigure ER signaling and restore proteostasis. These results identify ER reprogramming as a novel hormonelike function of coagulation proteases and demonstrate that targeting insulin signaling intermediates may be a feasible therapeutic approach ameliorating defective insulin signaling.
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U2 - 10.1182/blood-2017-02-767921
DO - 10.1182/blood-2017-02-767921
M3 - Article
C2 - 28687614
AN - SCOPUS:85027712509
SN - 0006-4971
VL - 130
SP - 1445
EP - 1455
JO - Blood
JF - Blood
IS - 12
ER -