Dopamine D2L receptor density influences the recruitment of ß-arrestin2 and Gi1 induced by antiparkinsonian drugs.

INTRODUCTION: Brain imaging studies have highlighted that the density of dopamine D2 receptors markedly fluctuates across the stages of Parkinson's disease and in response to pharmacological treatment. Moreover, receptor density constitutes a molecular determinant for the signaling profile of D2 receptor ligands. We therefore hypothesized that variations in receptor expression could influence D2 receptor response to antiparkinsonian drugs, most notably with respect to the recruitment bias between Gi1 and ß-arrestin2. METHODS: The recruitment bias of dopamine, pramipexole, ropinirole, and rotigotine was examined using a nanoluciferase-based biosensor for probing the interactions of the D2L receptor with either Gi1 or ß-arrestin2. The characterization of the functional selectivity of these D2 receptor agonists was performed at two distinct D2L receptor densities by taking advantage of a cell model carrying an inducible system that enables the overexpression of the D2L receptor when exposed to doxycycline. RESULTS: A high receptor density oriented the balanced signaling profile of dopamine towards a preferential recruitment of Gi1. It also moderated the marked Gi1 and ß-arrestin2 biases of pramipexole and rotigotine, respectively. At variance, the Gi1 bias of ropinirole appeared as not being influenced by D2L receptor density. CONCLUSIONS: Taken together, these observations highlight receptor density as a key driver of the signaling transducer recruitment triggered by antiparkinsonian agents. Moreover, given the putative beneficial properties of ß-arrestin2 in promoting locomotion, this study provides molecular insights that position the arrestin-biased ligand rotigotine as a putatively more beneficial D2 receptor agonist for the treatment of early and late Parkinson's disease.

Propranolol and low-dose isoproterenol ameliorate insulin resistance, enhance ß-arrestin2 signaling, and reduce cardiac remodeling in high-fructose, high-fat diet-fed mice: Comparative study with metformin.

AIMS: ß-Arrestin2 signaling has emerged as a promising therapeutic target for the management of insulin resistance and related complications. Moreover, recent studies have shown that certain G protein-coupled receptor (GPCR) ligands can modulate ß-arrestin2 signaling. The current study examined the effects of the ß-blocker propranolol and a low dose of the agonist isoproterenol (L-D-ISOPROT) on ß-arrestin2 signaling, insulin resistance, and cardiac remodeling in high-fructose, high-fat diet (HFrHFD)-fed mice. In addition, the effects of these agents were compared to those of the clinical antidiabetic agent, metformin. MATERIALS AND METHODS: Insulin resistance was induced by HFrHFD feeding for 16 weeks. Mice were then randomly allocated to groups receiving propranolol, L-D-ISOPROT, metformin, or vehicle (control) for 4 weeks starting on week 13 of HFrHFD feeding. Survival rate, body weight, visceral fat weight, blood glucose, serum insulin, insulin resistance index, hepatic ß-arrestin2 signaling, heart weight, left and right ventricular thicknesses, cardiac fibrosis severity, serum endothelin-1, cardiac cardiotrophin-1, and cardiac ß-arrestin2 signaling were then compared among groups. KEY FINDINGS: HFrHFD for 16 weeks significantly increased insulin resistance index, cardiac fibrosis area, and serum endothelin-1, and reduced hepatic ß-arrestin2 signaling, cardiac cardiotrophin-1, and cardiac ß-arrestin2 signaling without significant changes in survival rate, body weight, visceral fat weight, heart weight, or left and right ventricular thicknesses. All three drugs reduced insulin resistance and cardiac remodeling parameters and enhanced ß-arrestin2 signaling with variable efficacies. SIGNIFICANCE: Propranolol and L-D-ISOPROT, like metformin, can reduce insulin-resistance and cardiac remodeling in HFrHFD-fed mice, possibly by upregulating ß-arrestin2 signaling activity. Therefore, ß-arrestin2-signaling modulation might be a promising strategy for insulin-resistance treatment.

Lactate enhances Arc/arg3.1 expression through hydroxycarboxylic acid receptor 1-ß-arrestin2 pathway in astrocytes.

In recent years, with the discovery and research of lactate-specific receptor HCAR1(hydroxycarboxylic acid receptor 1), lactate is not only as a product of Glycolysis in astrocytes, but also as a signaling molecule which has gradually received attention. Studies have found that lactate can be used as an intercellular signaling molecule involved in synaptic plasticity, and so that peripheral administration of lactate can produce antidepressant effects. Here, we focus on HCAR1 on the most widely distributed astrocytes in the brain, found and verified that lactate could cause Arc/arg3.1 protein overexpression in astrocytes through HCAR1. However, the expression of Arc/arg3.1 does not depend on the Gi protein pathway of HCAR1, and we found that lactate enhanced the expression of Arc/arg3.1 protein through the HCAR1-ß-arrestin2 pathway. In summary, lactate acts on HCAR1 of astrocytes. It enhances the expression of MAPK-dependent Arc through ß-arrestin2, thereby reducing the influx of calcium ions when astrocytes are exposed to glutamate damage, achieving the role of protecting astrocytes and indirectly enhancing the absorption of glutamate by astrocytes. These results also demonstrate that HCAR1 in the brain is a potential therapeutic target in an experimental in vitro model of glutamate damage, which is strongly associated with many neurodegenerative diseases.

Beta-sitosterol attenuates insulin resistance in adipose tissue via IRS-1/Akt mediated insulin signaling in high fat diet and sucrose induced type-2 diabetic rats.

In our previous study, we have shown that ß-sitosterol (SIT) enhances glycemic control by increasing the activation of insulin receptor (IR) and glucose transporter 4 (GLUT4) proteins in adipose tissue. However, the possible role of SIT on the regulation of post-receptor insulin signal transduction is not known. Hence, the study was aimed to assess the effects of SIT on IRS-1/Akt mediated insulin signaling molecules in high-fat diet and sucrose induced type-2 diabetic rats. An oral effective dose of SIT (20 mg/kg b.wt) was given for 30 days to high fat-fed type-2 diabetic rats to find out whether SIT regulates IRS-1/Akt pathway of insulin signaling. The results showed that SIT attenuated the insulin receptor substrate-1 serine phosphorylation (p-IRS-1Ser636) (P = 0.0003). However, it up-regulated the mRNA expression of IR (P = 0.0036) and post-receptor insulin signaling molecules such as IRS-1 (P < 0.0001), ß-arrestin-2 (P < 0.0058), Akt (P = 0.0008), AS160 (P = 0.0030) and GLUT4 (P < 0.0001) with a concomitant increase in the levels of IRS-1(P < 0.0001), p-IRS1-1Tyr632 (P = 0.0014), Akt (P < 0.0001), p-AktSer473/Thr308 (P = 0.0006; P < 0.0001), AS160 and p-AS160Thr642 (P < 0.0001) compared with type-2 diabetic rats. In Silico analysis was also performed and it showed that SIT possesses the greater binding affinity with ß-arrestin-2, c-Src, and IRS-1 as well as Akt proteins and proved to attenuate insulin resistance as this study coincides with in vivo findings. Our present study clearly shows that SIT attenuates high fat diet-induced detrimental changes in adipose tissue. Therefore, it is concluded from the present findings that, SIT could be used as potential therapeutic phytomedicine for the management of type-2 diabetes.

Tardive dyskinesia is associated with altered putamen Akt/GSK-3ß signaling in nonhuman primates.

BACKGROUND: Tardive dyskinesia is a delayed and potentially irreversible motor complication arising from chronic exposure to antipsychotic drugs. Interaction of antipsychotic drugs with G protein-coupled receptors triggers multiple intracellular events. Nevertheless, signaling pathways that might be associated with chronic unwanted effects of antipsychotic drugs remain elusive. In this study, we aimed to better understand kinase signaling associated with the expression of tardive dyskinesia in nonhuman primates. METHODS: We exposed capuchin monkeys to prolonged haloperidol (n = 10) or clozapine (n = 6) treatments. Untreated animals were used as controls (n = 6). Half of haloperidol-treated animals (5) developed mild tardive dyskinesia similar to that found in humans. Using Western blots and immunochemistry, we measured putamen total and phosphorylated protein kinase levels associated with canonical and noncanonical signaling cascades of G protein-coupled receptors. RESULTS: Antipsychotic drugs enhanced pDARPP-32 and pERK1/2, but no difference ws observed in phosphoprotein kinase levels between dyskinetic and nondyskinetic monkeys. On the other hand, comparison of kinase levels between haloperidol-treated dyskinetic and nondyskinetic monkeys indicated that dyskinetic animals had lower GRK6 and ß-arrestin2 levels. Levels of pAkt and pGSK-3ß were also reduced, but only haloperidol-treated monkeys that developed tardive dyskinesia had reduced pGSK-3ß levels, whereas pAkt levels in dyskinetic animals positively correlated with dyskinetic scores. Interestingly, double immunofluorescence labeling showed that putamen dopamine D3 receptor levels were upregulated and that D3/pAkt colocalization was enriched in haloperidol-treated animals displaying tardive dyskinesia. CONCLUSIONS: Our results suggest that upregulation of putamen dopamine D3 receptor and alterations along the noncanonical GRK6/ß-arrestin2/Akt/GSK-3ß molecular cascade are associated with the development of tardive dyskinesia in nonhuman primates. © 2019 International Parkinson and Movement Disorder Society.