cotransfection of HEK293 cells with GLP-1R and Lrp5 increased GLP1 agonist induced TCF luciferase activity to a similar level as observed for cotransfection of HEK293 cells with GCGR and Lrp5. This is consistent with the hypothesis that there is a common mechanism 12098599” for activation of the SKI II b-catenin signaling pathway through both GCGR and GLP1R receptors. Glucagon agonist induced b-catenin signaling in GCGRexpressing cells Glucagon Induced b-Catenin Signaling Pathway 3 Glucagon Induced b-Catenin Signaling Pathway Glucagon-induced TCF reporter activity was PKAdependent To understand the mechanism of glucagon-induced b-catenin signaling, we first asked whether glucagon-induced cAMP/PKA activity is required for activating the b-catenin pathway. HEK293 cells were transfected with GCGR and treated with GCG1-29 and H89, a PKA inhibitor. Inhibition of PKA activity completely blocked the activation of the b-catenin pathway induced by GCG1-29. In another experiment, HEK293 cells were cotransfected with GCGR and Lrp5 and then treated with GCG129 in the presence or absence of H89 inhibitor. Treatment with H89 also completely abolished glucagon-induced b-catenin transcription activity. In these two experiments, we demonstrated that the glucagon-induced b-catenin signaling required PKA activity, consistent with previous reports on GLP1R or PTH1R. Inhibition of Lrp5/6 blocked glucagon-induced TCF reporter activity We next asked whether inhibition of Lrp5/6 would reduce glucagon-induced b-catenin signaling, and we used two approaches. First, we used a dominant negative inhibitor of Lrp5/6, the Lrp5 extracellular domain . Lrp5ECD inhibited glucagon-induced TCF luciferase activity when HEK293 cells were transfected with GCGR alone 23505071” or GCGR+Lrp5. In the other approach, we used Dickkopf-1, a known inhibitor of Lrp5/6, to block Lrp5/6 activity. In this experiment, DKK1 completely blocked glucagon-induced TCF luciferase activity when HEK293 cells were transfected with either GCGR alone or GCGR+Lrp5. These two experiments demonstrated that inhibiting Lrp5/6 activity blocked the glucagon-induced b-catenin signaling, suggesting that Lrp5/6 is required for glucagon-induced b-catenin dependent transcription. Lrp5 physically interacts with GCGR Because cotransfection with GCGR and Lrp5 increases glucagon-induced b-catenin stabilization and TCF luciferase activity, we examined whether GCGR and Lrp5 physically interact with each other by immunoprecipitation. HEK293 cells Glucagon Induced b-Catenin Signaling Pathway immunoprecipitated. Consistent with this, using v5 antibody to pull down v5-tagged Lrp5, we also pulled down GCGR protein. We also saw a diffused band above the band with expected molecular weight for GCGR in the immunoprecipitated samples, which may be a nonspecific band picked up by the HA antibody. We found that the association of GCGR and Lrp5 was independent of GCG1-29 treatment. As controls, immunoprecipitation with normal mouse IgG did not pull down either protein; further, anti-HA antibody did not pull down v5tagged Lrp5 and anti-v5 antibody did not pull down HA-tagged GCGR. Similarly, GCGR was co-immunoprecipitated with Lrp6 in a glucagon-independent manner. To further confirm the immunoprecipitation results, we used bioluminescence resonance energy transfer assay to examine GCGR and Lrp5 interaction by tagging GCGR with YFP and Lrp5 with Rlu, respectively. In the static BRET assay, we found that GCGR interacts with Lrp5 with a BRET ratio of 0.28, wh
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