Xiaohan Zhang

Selectivity of commonly used inhibitors of clathrin-mediated and caveolae-dependent endocytosis of G protein-coupled receptors.

Among the multiple G protein-coupled receptor (GPCR) endocytic pathways, clathrin-mediated endocytosis (CME) and caveolar endocytosis are more extensively characterized than other endocytic pathways. A number of endocytic inhibitors have been used to block CME; however, systemic studies to determine the selectivity of these inhibitors are needed. Clathrin heavy chain or caveolin1-knockdown cells have been employed to determine the specificity of various chemical and molecular biological tools for CME and caveolar endocytosis. Sucrose, concanavalin A, and dominant negative mutants of dynamin blocked other endocytic pathways, in addition to CME. In particular, concanavalin A nonspecifically interfered with the signaling of several GPCRs tested in the study. Decreased pH, monodansylcadaverine, and dominant negative mutants of epsin were more specific for CME than other treatments were. A recently introduced CME inhibitor, Pitstop2™, showed only marginal selectivity for CME and interfered with receptor expression on the cell surface. Blockade of receptor endocytosis by epsin mutants and knockdown of the clathrin heavy chain enhanced the β2AR-mediated ERK activation. Overall, our studies show that previous experimental results should be interpreted with discretion if they included the use of endocytic inhibitors that were previously thought to be CME-selective. In addition, our study shows that endocytosis of β2 adrenoceptor through clathrin-mediated pathway has negative effects on ERK activation.

Novel roles for β‐arrestins in the regulation of pharmacological sequestration to predict agonist‐induced desensitization of dopamine D3 receptors

In addition to typical GPCR kinase (GRK)‐/β‐arrestin‐dependent internalization, dopamine D3 receptor employed an additional GRK‐independent sequestration pathway. In this study, we investigated the molecular mechanism of this novel sequestration pathway.

Multifactorial Regulation of G Protein-Coupled Receptor Endocytosis.

Endocytosis is a process by which cells absorb extracellular materials via the inward budding of vesicles formed from the plasma membrane. Receptor-mediated endocytosis is a highly selective process where receptors with specific binding sites for extracellular molecules internalize via vesicles. G protein-coupled receptors (GPCRs) are the largest single family of plasma-membrane receptors with more than 1000 family members. But the molecular mechanisms involved in the regulation of GPCRs are believed to be highly conserved. For example, receptor phosphorylation in collaboration with β-arrestins plays major roles in desensitization and endocytosis of most GPCRs. Nevertheless, a number of subsequent studies showed that GPCR regulation, such as that by endocytosis, occurs through various pathways with a multitude of cellular components and processes. This review focused on i) functional interactions between homologous and heterologous pathways, ii) methodologies applied for determining receptor endocytosis, iii) experimental tools to determine specific endocytic routes, iv) roles of small guanosine triphosphate-binding proteins in GPCR endocytosis, and v) role of post-translational modification of the receptors in endocytosis.

Agonist-induced changes in RalA activities allows the prediction of the endocytosis of G protein-coupled receptors.

GTP binding proteins are classified into two families: heterotrimeric large G proteins which are composed of three subunits, and one subunit of small G proteins. Roles of small G proteins in the intracellular trafficking of G protein-coupled receptors (GPCRs) were studied. Among various small G proteins tested, GTP-bound form (G23V) of RalA inhibited the internalization of dopamine D2 receptor independently of the previously reported downstream effectors of RalA, such as Ral-binding protein 1 and PLD. With high affinity for GRK2, active RalA inhibited the GPCR endocytosis by sequestering the GRK2 from receptors. When it was tested for several GPCRs including an endogenous GPCR, lysophosphatidic acid receptor 1, agonist-induced conversion of GTP-bound to GDP-bound RalA, which presumably releases the sequestered GRK2, was observed selectively with the GPCRs which have tendency to undergo endocytosis. Conversion of RalA from active to inactive state occurred by translocation of RGL, a guanine nucleotide exchange factor, from the plasma membrane to cytosol as a complex with Gβγ. These results suggest that agonist-induced Gβγ-mediated conversion of RalA from the GTP-bound form to the GDP-bound form could be a mechanism to facilitate agonist-induced internalization of GPCRs.

N-linked Glycosylation on the N-terminus of the dopamine D2 and D3 receptors determines receptor association with specific microdomains in the plasma membrane.

Numerous G protein-coupled receptors (GPCRs) are glycosylated at extracellular regions. The regulatory roles of glycosylation on receptor function vary across receptor types. In this study, we used the dopamine D₂and D₃receptors as an experimental model to understand the underlying principles governing the functional roles of glycosylation. We used the pharmacological inhibitor, tunicamycin, to inhibit glycosylation, generated chimeric D₂and D₃receptors by swapping their respective N-termini, and produced the glycosylation site mutant D₂and D₃receptors to study the roles of glycosylation on receptor functions, including cell surface expression, signaling, and internalization through specific microdomains. Our results demonstrate that glycosylation on the N-terminus of the D₃ receptor is involved in the development of desensitization and proper cell surface expression. In addition, glycosylation on the N-terminus mediates the internalization of D₂and D₃receptors within the caveolae and clathrin-coated pit microdomains of the plasma membrane, respectively, by regulating receptor interactions with caveolin-1 and clathrin. In conclusion, this study shows for the first time that glycosylation on the N-terminus of GPCRs is involved in endocytic pathway selection through specific microdomains. These data suggest that changes in the cellular environment that influence posttranslational modification could be an important determinant of intracellular GPCR trafficking.

Clathrin-mediated endocytosis is responsible for the lysosomal degradation of dopamine D3 receptor

GRK2-/β-Arrestin- and PKA-/PKC-mediated desensitization, internalization, and degradation are three representative pathways for regulating G protein-coupled receptors (GPCRs). Compared with GRK2/β-arrestin-mediated ones, functional relationship among the aforementioned three regulatory processes mediated by PKA/PKC is less clear. Dopamine D3 receptor (D3R), a major target of currently available antipsychotic drugs, is a typical GPCR that selectively undergoes PKC-mediated regulation. In the present study, we examined PKC-mediated internalization of D3R in correlation with its roles in desensitization and degradation. Our results showed that the kinase activity of PKCβII and the 229th and 257th serine residues of D3R were required for PKC-mediated desensitization, internalization, and degradation of D3R. PMA treatment ubiquitinated D3R and induced its degradation through lysosomal pathway. Blockade of clathrin-mediated internalization inhibited PKC-mediated lysosomal degradation of D3R but did not affect its desensitization. These results suggested that PKC-mediated phosphorylation of D3R involved clathrin-mediated internalization, which was important for the lysosomal degradation of D3R.

PKCβII inhibits the ubiquitination of β-arrestin2 in an autophosphorylation-dependent manner

GPCR kinase 2 (GRK2)/β‐arrestins and protein kinase A (PKA)/protein kinase C (PKC) mediate homologous and heterologous regulations of GPCRs, respectively. Conventional protein kinase C enzymes (PKCs), as exemplified by PKCβII, selectively inhibit internalization of dopamine D2 receptor and β2 adrenoceptor in a β‐arrestin‐ but not GRK2‐dependent manner. PKCβII interacts with β‐arrestin2 upon autophosphorylation at T250, and inhibits the receptor internalization by decreasing the ubiquitination of β‐arrestin2. PKCβII interferes with the interaction between β‐arrestin2 and MDM2 in the cytosol, resulting in the redistribution of MDM2 to the nucleus. Subsequently, deubiquitination of β‐arrestin2 and inhibition of agonist‐induced receptor internalization follow. Thus, our study suggests that the extent of β‐arrestin ubiquitination and the autophosphorylation status of PKCs determine PKCβII‐mediated inhibition of homologous regulatory processes of GPCRs.

RalA employs GRK2 and β-arrestins for the filamin A-mediated regulation of trafficking and signaling of dopamine D2 and D3 receptor

Filamin A (FLNA) is known to act as platform for the signaling and intracellular trafficking of various GPCRs including dopamine D2 and D3 receptors (D2R, D3R). To understand molecular mechanisms involved in the FLNA-mediated regulation of D2R and D3R, comparative studies were conducted on the signaling and intracellular trafficking of the D2R and D3R in FLNA-knockdown cells, with a specific focus on the roles of the proteins that interact with FLNA and the D2R and D3R. Lowering the level of cellular FLNA caused an elevation in RalA activity and resulted in selective interference with the normal intracellular trafficking and signaling of the D2R and D3R, through GRK2 and β-arrestins, respectively. Knockdown of FLNA or coexpression of active RalA interfered with the recycling of the internalized D2R and resulted in the development of receptor tolerance. Active RalA was found to interact with GRK2 to sequester it from D2R. Knockdown of FLNA or coexpression of active RalA prevented D3R from coupling with G protein. The selective involvement of GRK2- and β-arrestins in the RalA-mediated cellular processes of the D2R and D3R was achieved via their different modes of interactions with the receptor and their distinct functional roles in receptor regulation. Our results show that FLNA is a multi-functional protein that acts as a platform on which D2R and D3R can interact with various proteins, through which selective regulation of these receptors occurs in combination with GRK2 and β-arrestins.

Palmitoylation on the carboxyl terminus tail is required for the selective regulation of dopamine D2 versus D3 receptors.

Dopamine D2 receptor (D2R) and D3 receptor (D3R) possess highly conserved amino acid sequences but this study showed that D3R was more extensively palmitoylated than D2R. Based on this finding, the molecular basis of this selective palmitoylation of D3R was determined and the roles of palmitoylation in the regulation of D3R functions were investigated. D3R was palmitoylated on the cysteine residue on its carboxyl terminus tail, the last amino acid residue of D3R, and an exchange of the carboxyl terminus tail between D2R and D3R (D2R-D3C and D3R-D2C) resulted in the switching of the palmitoylation phenotype. When the consensus site for palmitoylation was mutated or the palmitoylation of D3R was inhibited by treatment with 2-bromopalmitate (2BP), a palmitoylation blocker, cell-surface expression, PKC-mediated endocytosis, agonist affinity, and agonist-induced tolerance of D3R were all inhibited. However, these changes were not observed when D3R palmitoylation was inhibited by replacing its carboxyl tail with that of D2R (D3R-D2C) or when the palmitoylation of D2R-D3C was inhibited by treatment with 2BP. Overall, this study shows that D3R is palmitoylated more extensively than D2R even though the carboxyl terminus tails of D2R and D3R are highly homologous, and thus provides a new clue regarding the consensus sequence for palmitoylation. This study also shows that palmitoylation controls various functionalities of D3R only when the receptor is in the intact D3R configuration.

Roles of Dopamine D 2 Receptor Subregions in Interactions with β-Arrestin2

β-Arrestins are one of the protein families that interact with G protein-coupled receptors (GPCRs). The roles of β-arrestins are multifaceted, as they mediate different processes including receptor desensitization, endocytosis, and G protein-independent signaling. Thus, determining the GPCR regions involved in the interactions with β-arrestins would be a preliminary step in understanding the molecular mechanisms involved in the selective direction of each function. In the current study, we determined the roles of the N-terminus, intracellular loops, and C-terminal tail of a representative GPCR in the interaction with β-arrestin2. For this, we employed dopamine D2 and D3 receptors (D2R and D3R, respectively), since they display distinct agonist-induced interactions with β-arrestins. Our results showed that the second and third intracellular loops of D2R are involved in the agonist-induced translocation of β-arrestins toward plasma membranes. In contrast, the N- and C-termini of D2R exerted negative effects on the basal interaction with β-arrestins.