Salvinorin A regulates dopamine transporter function via a kappa opioid receptor and ERK1/2-dependent mechanism
Salvinorin A (SalA), a selective κ-opioid receptor (KOR) agonist, produces dysphoria and pro-depressant like effects. These actions have been attributed to inhibition of striatal dopamine release. The dopamine transporter (DAT) regulates dopamine transmission via uptake of released neurotransmitter. KORs are apposed to DAT in dopamine nerve terminals suggesting an additional target by which SalA modulates dopamine transmission. SalA produced a concentration-dependent, nor-binaltorphimine (BNI)- and pertussis toxin-sensitive increase of ASP+ accumulation in EM4 cells coexpressing myc-KOR and YFP-DAT, using live cell imaging and the fluorescent monoamine transporter substrate, trans 4-(4-(dimethylamino)-styryl)-N-methylpyridinium) (ASP+). Other KOR agonists also increased DAT activity that was abolished by BNI pretreatment. While SalA increased DAT activity, SalA treatment decreased serotonin transporter (SERT) activity and had no effect on norepinephrine transporter (NET) activity. In striatum, SalA increased the Vmax for DAT mediated DA transport and DAT surface expression. SalA up-regulation of DAT function is mediated by KOR activation and the KOR-linked extracellular signal regulated kinase-½ (ERK1/2) pathway. Co-immunoprecipitation and BRET studies revealed that DAT and KOR exist in a complex. In live cells, DAT and KOR exhibited robust FRET signals under basal conditions. SalA exposure caused a rapid and significant increase of the FRET signal. This suggests that the formation of KOR and DAT complexes is promoted in response to KOR activation. Together, these data suggest that enhanced DA transport and decreased DA release resulting in decreased dopamine signaling may contribute to the dysphoric and pro-depressant like effects of SalA and other KOR agonists.
Here we tested an hypothesis that PKC-mediated phosphorylation of NET is required for transporter internalization. Phosphoamino acid analysis of 32 Plabeled native NETs from rat placental trophoblasts and heterologously expressed wild type human NET (WT-hNET) from human placental trophoblast cells revealed that the phorbol ester (-PMA)-induced phosphorylation of NET occurs on serine and threonine residues. -PMA treatment inhibited NE transport, reduced plasma membrane hNET levels, and stimulated hNET phosphorylation in human placental trophoblast cells expressing the WT-hNET. Substance P-mediated activation of the G␣ q -coupled human neurokinin 1 (hNK-1) receptor coexpressed with the WT-hNET produced effects similar to -PMA via PKC stimulation. In striking contrast, an hNET double mutant harboring T258A and S259A failed to show NE uptake inhibition and plasma membrane redistribution by -PMA or SP. Most interestingly, the plasma membrane insertion of the WT-hNET and hNET double mutant were not affected by -PMA. Although the WT-hNET showed increased endocytosis and redistribution from caveolin-rich plasma membrane domains following -PMA treatment, the hNET double mutant was completely resistant to these PKC-mediated effects. In addition, the PKC-induced phosphorylation of hNET double mutant was significantly reduced. In the absence of T258A and S259A mutations, alanine substitution of all other potential phosphosites within the hNET did not block PKC-induced phosphorylation and down-regulation. These results suggest that Thr-258 and Ser-259 serve as a PKC-specific phospho-acceptor site and that phosphorylation of this motif is linked to PKC-induced NET internalization. The norepinephrine (NE)2 transporter (NET) regulates noradrenergic signaling by mediating the clearance of NE and is an important target for antidepressants and psychostimulants (2-5). NE signaling is linked to behavioral arousal (6) and is affected in stress-related paradigms linked to depression (7,8). NE acutely inhibits nociceptive transmission, including that mediated by SP (NK1), potentiates opioid analgesia, and underlies part of antinociceptive effects of tricyclic antidepressants (9). Various biologic stimuli regulate NE signaling, and alterations in NE signaling, including NE clearance and NET density, are observed in cardiovascular diseases and brain disorders (10 -13). Recent studies provided evidence for protein kinase C (PKC)-mediated regulation of NET function attributed to alterations in NET surface redistribution (1, 14, 15). Signals mediated through G-protein-coupled receptors are a likely trigger for PKC-mediated regulation of NET, and such receptors are abundant on neuronal and non-neuronal cells.Human placenta expresses both SERT and NET (16 -18), and we have developed trophoblast cultures from the rat placenta that robustly express endogenous NET (19). Placenta also expresses several receptors, including receptors for peptides such as insulin, SP, and NKB, neurotransmitters,. Our recent study using rat placental trophobla...
Chronic cerebral hypoperfusion (CCH), featuring in most of the Alzheimer's disease spectrum, plays a detrimental role in brain amyloid-β (Aβ) homeostasis, cerebrovascular morbidity, and cognitive decline; therefore, early management of cerebrovascular pathology is considered to be important for intervention in the impending cognitive decline. S-nitrosoglutathione (GSNO) is an endogenous nitric oxide carrier modulating endothelial function, inflammation, and neurotransmission. Therefore, the effect of GSNO treatment on CCH-associated neurocognitive pathologies was determined in vivo by using rats with permanent bilateral common carotid artery occlusion (BCCAO), a rat model of chronic cerebral hypoperfusion. We observed that rats subjected to permanent BCCAO showed a significant decrease in learning/memory performance and increases in brain levels of Aβ and vascular inflammatory markers. GSNO treatment (50 μg/kg/day for 2 months) significantly improved learning and memory performance of BCCAO rats and reduced the Aβ levels and ICAM-1/VCAM-1 expression in the brain. Further, in in vitro cell culture studies, GSNO treatment also decreased the cytokine-induced proinflammatory responses, such as activations of NFκB and STAT3 and expression of ICAM-1 and VCAM-1 in endothelial cells. In addition, GSNO treatment increased the endothelial and microglial Aβ uptake. Additionally, GSNO treatment inhibited the β-secretase activity in primary rat neuron cell culture, thus reducing secretion of Aβ, suggesting GSNO mediated mechanisms in anti-inflammatory and anti-amyloidogenic activities. Taken together, these data document that systemic GSNO treatment is beneficial for improvement of cognitive decline under the conditions of chronic cerebral hypoperfusion and suggests a potential therapeutic use of GSNO for cerebral hypoperfusion associated mild cognitive impairment in Alzheimer's disease.
Tyrosine Phosphorylation of the Human Serotonin Transporter: A Role in the Transporter Stability and Function
The serotonin (5-HT) transporter (SERT) regulates serotoninergic neurotransmission by clearing 5-HT released into the synaptic space. Phosphorylation of SERT on serine and threonine mediates SERT regulation. Whether tyrosine phosphorylation regulates SERT is unknown. Here, we tested the hypothesis that tyrosine-phosphorylation of SERT regulates 5-HT transport. In support of this, alkali-resistant 32 P-labeled SERT was found in rat platelets, and Src-tyrosine kinase inhibitor 4-amino-5-(4-chlorophenyl)-7-(t-butyl)pyrazolo [3,4,d]pyrimidine (PP2) decreased platelet SERT function and expression. In human placental trophoblast cells expressing SERT, PP2 reduced transporter function, expression, and stability. Although siRNA silencing of Src expression decreased SERT function and expression, coexpression of Src resulted in PP2-sensitive increases in SERT function and expression. PP2 treatment markedly decreased SERT protein stability. Compared with WT-SERT, SERT tyrosine mutants Y47F and Y142F exhibited reduced 5-HT transport despite their higher total and cell surface expression levels. Moreover, Src-coexpression increased total and cell surface expression of Y47F and Y142F SERT mutants without affecting their 5-HT transport capacity. It is noteworthy that Y47F and Y142F mutants exhibited higher protein stability compared with WT-SERT. However, similar to WT-SERT, PP2 treatment decreased the stability of Y47F and Y142F mutants. Furthermore, compared with WT-SERT, Y47F and Y142F mutants exhibited lower basal tyrosine phosphorylation and no further enhancement of tyrosine phosphorylation in response to Src coexpression. These results provide the first evidence that SERT tyrosine phosphorylation supports transporter protein stability and 5HT transport.
A subset of Eph receptors and their corresponding ligands are commonly expressed in tumor cells, where they mediate biological processes such as cell migration and adhesion, while their expression in endothelial cells promotes angiogenesis. In particular, the tumor-specific upregulation of EphA2 confers properties of increased cellular motility, invasiveness, tumor angiogenesis, and tumor progression, and its overexpression correlates with poor prognosis in several cancer types. The cellular chaperone Hsp90 also plays a significant role in regulating cell migration and angiogenesis, although the full repertoire of motility driving proteins dependent upon Hsp90 function remain poorly defined. We explored the hypothesis that Hsp90 may regulate the activity of EphA2 and examined the potential relationship between EphA2 receptor signaling and chaperone function. We demonstrate that geldanamycin (GA), an Hsp90 antagonist, dramatically destabilizes newly synthesized EphA2 protein and diminishes receptor levels in a proteasome-dependent pathway. In addition, GA treatment impairs EphA2 signaling, as evidenced by a decrease in ligand-dependent receptor phosphorylation and subsequent cell rounding. Therefore, Hsp90 exerts a dual role in regulating the stability of nascent EphA2 protein, and maintaining the signaling capacity of the mature receptor. Our findings also suggest that the GA-dependent mitigation of EphA2 signaling in receptor-overexpressing cancer cells may be sufficient to recapitulate the anti-motility effects of this drug. Finally, the identification of a pharmacologic approach to suppress EphA2 expression and signaling highlights the attractive possibility that Hsp90 inhibitors may have clinical utility in antagonizing EphA2-dependent tumorigenic progression.
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