PDI Cleavage of Disulfide Bonds within the TP Receptor Inhibits Signaling through Gα 13

G-protein coupled receptors (GPCRs) are the most abundant superfamily of cell surface receptors. Approximately 35% of approved drugs target GPCRs and class A GPCRs account for ~85% of this superfamily. Class A GPCRs are characterized in part by two highly conserved disulfides in their extracellular domains that are thought to stabilize protein structure. Whether these disulfides can be enzymatically modified to influence G-protein signaling is not known. We and others have previously shown that disulfide bond modification by thiol isomerases such as protein disulfide isomerase (PDI) represent a previously unrecognized level of control of thrombus formation. We therefore evaluated the ability of recombinant PDI (rPDI) to modulate signaling through modification of the canonical disulfides within platelet GPCRs. Exposure of platelets to rPDI had no effect on stimulation through PAR1, PAR4, or the α 2A-adrenergic receptor. In contrast, rPDI exposure dramatically decreased platelet activation induced by the TP receptor agonists U46619 or arachidonic acid, implicating rPDI-mediated modulation of TP receptor signaling. Consistent with this finding, rPDI blocked U46619-mediated activation of α IIbβ 3, α-granule release, and dense granule release. Conversely, inhibition of endogenous PDI using either inhibitory antibodies or PDI-targeted small molecules enhanced TP receptor-mediated platelet aggregation and granule release, indicating that endogenous platelet PDI influences TP receptor signaling. Inhibition of TP receptor-mediated signaling required PDI active site cysteines since rPDI mutants lacking these cysteines lost inhibitory activity. Evaluation of the inhibitory activity of different PDI fragments showed that the PDI substrate binding domain is also critical for inhibitory activity. The ability to inhibit signaling through the TP receptor was specific for rPDI since incubation with other recombinant thiol isomerases including ERp57, ERp5, and ERp72 had no effect. To determine the specific modifications to TP receptor canonical disulfides induced by PDI, HEK cells were transfected with TP receptor and exposed to rPDI. TP receptor was subsequently immunopreciptated and disulfide-linked peptide analysis was performed using mass spectrometry. Compared to untreated controls, TP receptor exposed to rPDI demonstrated cleavage of Cys11-Cys102 and Cys105-Cys183 bonds and the generation of a new Cys102-Cys183 bond. To determine how modification of the disulfide bonding pattern affected signaling through the TP receptor, we evaluated signaling through specific Gα subunits in platelets. The platelet TP receptor signals through Gα q (which couples to phospholipase and increases calcium flux) and Gα 13 (which couples to RhoA and myosin light chain kinase). PDI-mediated cleavage of the platelet TP receptor resulted in biased signaling, with substantial inhibition of G α13-mediated RhoA-GTP activation and myosin light chain phosphorylation and little effect on Gα q-mediated calcium flux. These results show how PDI can modify platelet signaling and represent the first demonstration that a thiol isomerase can modulate the function of a GPCR via rearrangement of canonical disulfide bonds. Disclosures No relevant conflicts of interest to declare.

Molecular Pathomechanisms of Impaired Flow-Induced Constriction of Cerebral Arteries Following Traumatic Brain Injury: A Potential Impact on Cerebral Autoregulation

(1) Background: Traumatic brain injury (TBI) frequently occurs worldwide, resulting in high morbidity and mortality. Here, we hypothesized that TBI impairs an autoregulatory mechanism, namely the flow-induced constriction of isolated rat middle cerebral arteries (MCAs). (2) Methods: TBI was induced in anaesthetized rats by weight drop model, and then MCAs were isolated and transferred into a pressure-flow chamber. The internal diameter was measured by a video-microscopy. (3) Results: In MCAs from intact rats, increases in flow and pressure + flow elicited constrictions (−26 ± 1.9 µm and −52 ± 2.8 µm, p < 0.05), which were significantly reduced after TBI or in the presence of thromboxane-prostanoid (TP receptor) antagonist SQ 29,548. Flow-induced constrictions were significantly reduced by HET0016, inhibitor of cytochrome P450 4A (CYP450 4A). Arachidonic acid, (AA, 10−7 M), and CYP-450 4A metabolite 20-hydroxyeicosatetraenoic acid (20-HETE) elicited constrictions of intact MCA (−26 ± 2.3% and −31 ± 3.6%), which were significantly reduced after TBI (to 11 ± 1.3% and −16 ±2.5%). The TP receptor agonist U46619 (10−7 M) elicited substantial constrictions of MCA from intact rats (−21 ± 3.3%), which were also significantly reduced, after TBI (to −16 ± 2.4%). (4) Conclusions: Flow-induced constrictor response of MCA is impaired by traumatic brain injury, likely due to the reduced ability of cytochrome P450 4A to convert arachidonic acid to constrictor prostaglandins and the mitigated sensitivity of thromboxane-prostanoid receptors.

Isoprostanes evoke contraction of the murine and human detrusor muscle via activation of the thromboxane prostanoid TP receptor and Rho-kinase

Local or systemic inflammation can severely impair urinary bladder functions and contribute to the development of voiding disorders in millions of people worldwide. Isoprostanes are inflammatory lipid mediators that are upregulated in the blood and urine by oxidative stress and may potentially induce detrusor overactivity. The aim of the study was to investigate the effects and signal transduction of isoprostanes in human and murine urinary bladders to provide potential pharmacological targets in detrusor overactivity. Contraction force was measured with myograph in murine and human urinary bladder smooth muscle (UBSM) ex vivo. Isoprostane 8-iso-PGE2 and 8-iso-PGF2α evoked dose-dependent contraction in murine UBSM, which was abolished in mice deficient for the thromboxane prostanoid receptor (TP-KO). The responses remained unaltered after removal of the mucosa or incubation with tetrodotoxin. Smooth muscle specific deletion of Gα12/13-protein or inhibition of Rho-kinase (ROCK) by Y-27632 decreased the contractions. In Gαq/11‐KO mice, responses were reduced and in the presence of Y‐27632 abolished completely. In human UBSM the TP agonist U-46619 evoked dose‐dependent contractions. Neither atropine, nor the purinergic receptor antagonist pyridoxalphosphate‐6‐azophenyl‐2',4'‐disulfonic acid (PPADS) decreased the effect, indicating that TP receptors directly mediate detrusor muscle contraction. 8-iso-PGE2 and 8-iso-PGF2α evoked dose-dependent contraction in human UBSM, and these responses were abolished by the TP antagonist SQ-29548 and were decreased by Y-27632. Our results indicate that isoprostanes evoke contraction in murine and human UBs, an effect mediated by the TP receptor. The G12/13-Rho-ROCK pathway plays a significant role in mediating the contraction and therefore may be a potential therapeutic target.

P737Endothelial ERK2/thromboxane receptor pathway induces endothelial dysfunction, insulin resistance and steatohepatosis through superoxide with high fat high sucrose diet

Introduction Metabolic syndrome (MetS) is well known as the risk of cardiovascular diseases associated with endothelial dysfunction and induces steatohepatosis. Insulin resistance is a major character of MetS, which affects intracellular signaling pathways and endothelial function. Extracellular signal-regulated kinase (ERK) is a major component of insulin signal and many of vasoactive peptides, which were released in MetS, can activate it in endothelium. However, the role of endothelial ERK in nitric oxide (NO) bioactivity in MetS in in vivo has been unknown. Purpose The aim of this study is to clarify the role of endothelial ERK2 on NO bioactivity in mice model of MetS. Methods and results We created endothelial specific ERK2 knock out mice (EE2KO) crossing Tie2-Cre mice and ERK2 flox mice and fed them with normal or high-fat/high-sucrose diet (HFHSD) for 24 weeks. Serum glucose and insulin levels and HOMA-IR were lowered in EE2KO with HFHSD without changing body weight. In wild type mice (WT) with HFHSD, nonalcoholic fatty liver disease (NAFLD) activity score, fibrosis score and serum ALT level were increased, all of which were blunted in EE2KO. EE2KO with HFHSD lowered systolic blood pressure (WT: 123.7±5.83 mmHg, EE2KO: 101.4±3.66 mmHg, P<0.01, N=8) without changing heart rate, which was increased to the same levels with L-NAME, an endothelial NO synthase inhibitor, in both groups. Serum NO levels measured with serum nitrite/nitrate concentrations were increased in EE2KO with HFHSD (WT: 23.10±3.74 μmol/l, EE2KO: 41.71±6.73 μmol/l, P<0.05, N=12). Endothelial function was assessed with the isometric tension measurement of aortic rings with acetylcholine (ACh). ACh-induced relaxation was improved in EE2KO with HFHSD. Superoxide production of aorta from EE2KO was lowered than WT with HFHSD in dihydroethidium (DHE) staining. S18886, an antagonist of the thromboxane A2-prostanoid (TP) receptor, decreased superoxide production of aorta in DHE staining resulting in improving endothelial function in the isometric tension measurement of aortic rings. Oral administrations of S18886 decreased systolic blood pressure, serum fasting glucose and insulin levels, and surprisingly improved steatohepatosis by decreasing NAFLD activity score and fibrosis score. Relaxation of aortic rings with ACh Conclusions Endothelial ERK2/TP receptor pathway increases superoxide production and decreased NO bioactivity, resulting in deteriorating endothelial function, insulin resistance and steatohepatosis, which were improved by antagonist of the TP receptor in mice model of MetS. The present study indicates that ERK2/TP pathway could be a therapeutic target for complications of MetS.