PDZ Protein Regulation of G Protein–Coupled Receptor Trafficking and Signaling Pathways

Henry A. Dunn; Stephen S. G. Ferguson

doi:10.1124/mol.115.098509

Abstract

G protein–coupled receptors (GPCRs) contribute to the regulation of every aspect of human physiology and are therapeutic targets for the treatment of numerous diseases. As a consequence, understanding the myriad of mechanisms controlling GPCR signaling and trafficking is essential for the development of new pharmacological strategies for the treatment of human pathologies. Of the many GPCR-interacting proteins, postsynaptic density protein of 95 kilodaltons, disc large, zona occludens-1 (PDZ) domain–containing proteins appear most abundant and have similarly been implicated in disease mechanisms. PDZ proteins play an important role in regulating receptor and channel protein localization within synapses and tight junctions and function to scaffold intracellular signaling protein complexes. In the current study, we review the known functional interactions between PDZ domain–containing proteins and GPCRs and provide insight into the potential mechanisms of action. These PDZ domain–containing proteins include the membrane-associated guanylate-like kinases [postsynaptic density protein of 95 kilodaltons; synapse-associated protein of 97 kilodaltons; postsynaptic density protein of 93 kilodaltons; synapse-associated protein of 102 kilodaltons; discs, large homolog 5; caspase activation and recruitment domain and membrane-associated guanylate-like kinase domain-containing protein 3; membrane protein, palmitoylated 3; calcium/calmodulin-dependent serine protein kinase; membrane-associated guanylate kinase protein (MAGI)-1, MAGI-2, and MAGI-3], Na⁺/H⁺ exchanger regulatory factor proteins (NHERFs) (NHERF1, NHERF2, PDZ domain–containing kidney protein 1, and PDZ domain–containing kidney protein 2), Golgi-associated PDZ proteins (Gα-binding protein interacting protein, C-terminus and CFTR-associated ligand), PDZ domain–containing guanine nucleotide exchange factors (GEFs) 1 and 2, regulator of G protein signaling (RGS)–homology-RhoGEFs (PDZ domain–containing RhoGEF and leukemia-associated RhoGEF), RGS3 and RGS12, spinophilin and neurabin-1, SRC homology 3 domain and multiple ankyrin repeat domain (Shank) proteins (Shank1, Shank2, and Shank3), partitioning defective proteins 3 and 6, multiple PDZ protein 1, Tamalin, neuronal nitric oxide synthase, syntrophins, protein interacting with protein kinase C α 1, syntenin-1, and sorting nexin 27.

Introduction

In the central nervous system, G protein–coupled receptors (GPCRs) and ion channels are targeted to the membrane of dendritic postsynaptic terminals in and around a region termed the postsynaptic density (PSD) (Neubig and Siderovski, 2002; Feng and Zhang, 2009; Magalhaes et al., 2012). Each postsynaptic density is specifically organized, such that dozens to hundreds of receptors are targeted to this specialized membrane domain via the interaction of scaffolding proteins with the receptors. These scaffold proteins contain multiple protein-protein interaction domains that allow them to interact with a multitude of structural and signaling proteins and hold them in close proximity with one another (Feng and Zhang, 2009). Of these scaffolding proteins, it is believed that postsynaptic density protein of 95 kilodaltons (PSD-95), disc large, zona occludens-1 (PDZ) domain–containing proteins are the most abundant and often provide direct contact with both GPCRs and ion channels at the postsynaptic density (Cheng et al., 2006; Feng and Zhang, 2009). PDZ proteins are not only important for targeting GPCRs to synapses, but they have an important role in regulating tight junctions and signaling protein complexes. In the current review, we will provide an overview of the growing understanding of the role of PDZ domain–containing proteins in the regulation of GPCR subcellular localization, endocytosis, trafficking, and signal transduction.

PDZ Domains

PDZ domains are approximately 80–90 amino acid residues in size and represent the most common protein-protein interaction domain (Doyle et al., 1996; Feng and Zhang, 2009; Magalhaes et al., 2012). Although there are hundreds of unique PDZ domain sequences, they all contain a conserved glycine-leucine-glycine-phenylalanine sequence that provides the domain’s folded, globular, cup-like structure that is capable of recognizing short, finger-like peptides (Harris and Lim, 2001). Because of this structure, PDZ domains appear best suited for binding the distal regions of receptor carboxyl-terminal tails, which are labeled the PDZ-binding motif (Kornau et al., 1995; Niethammer et al., 1996; Harris and Lim, 2001; Magalhaes et al., 2012). Interestingly, additional studies have identified internal PDZ ligands that, like a carboxyl-terminal tail, project outwardly from the protein (Xu et al., 1998; Christopherson et al., 1999; Hillier et al., 1999; Fouassier et al., 2000; Harris and Lim, 2001; Paasche et al., 2005; Trejo, 2005). In this case, the internal PDZ-binding motif manifests as a sharply folded, finger-like projection.

PDZ-Binding Motifs

Although seemingly imperfect and likely biased against internal PDZ ligands (reviewed by Trejo, 2005), a simple classification system has evolved to identify potential PDZ-binding motifs and helps to predict potential PDZ domain–containing protein interactions (Songyang et al., 1997; Bezprozvanny and Maximov, 2001; Sheng and Sala, 2001; Vaccaro and Dente, 2002). Although there is some deliberation over how many classes of PDZ-binding motifs there are, it is most commonly limited to three classes (Sheng and Sala, 2001; Tonikian et al., 2008; Magalhaes et al., 2012). Class I PDZ-binding motifs are the most described class within the literature and are classified by their final three–amino acid sequence of S/T-x-ϕ, where x indicates any amino acid and ϕ indicates any hydrophobic amino acid (Songyang et al., 1997; Bezprozvanny and Maximov, 2001; Sheng and Sala, 2001; Vaccaro and Dente, 2002). However, valine, isoleucine, or leucine appear to be the most common of the hydrophobic amino acids that contribute to the formation of a class I PDZ-binding motif (Songyang et al., 1997; Bezprozvanny and Maximov, 2001; Sheng and Sala, 2001; Vaccaro and Dente, 2002). Class II and III PDZ-binding motifs are not as well characterized and show slightly more ambiguous sequences, with class II having its final three amino acids as ϕ-x-ϕ, and class III having Ψ-x-Ψ, where Ψ represents any acidic amino acid residue (Sheng and Sala, 2001).

GPCR-Interacting PSD-95 Family PDZ Domain–Containing Membrane-Associated Guanylate Kinase Proteins

PSD-95 (DLG4).

PSD-95 contains three PDZ domains, an SRC homology 3 (SH3) domain, and a guanylate kinase–like (GK) domain (Fig. 1), and is prototypically localized within the postsynaptic density (Sampedro et al., 1981; Cho et al., 1992). PSD-95 has been demonstrated to modulate both α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-d-aspartate (NMDA) receptor function as well as a number of GPCRs. With regards to AMPA and NMDA receptors, it appears that PSD-95 is important for enhancing and/or maintaining these receptors at the synaptic membrane, thereby potentiating receptor activation, channel opening, receptor-mediated currents, and receptor trafficking (Elias et al., 2006; Elias and Nicoll, 2007). PSD-95 is able to indirectly bind and regulate AMPA receptors via a shared association with transmembrane AMPA receptor–regulating proteins, such as stargazin (Chen et al., 2000). The β₁-adrenergic receptor (β₁AR) is the first GPCR to be reported as a PSD-95–interacting GPCR, and PSD-95 is responsible for antagonizing β₁AR endocytosis in response to agonist activation, thereby stabilizing the receptor at the cell surface (Hu et al., 2000) (Table 1). Despite the potentiation of β₁AR membrane expression, this interaction appears to have no functional consequence on Gα_s-coupled signaling, as measured by cAMP accumulation (Hu et al., 2000). In contrast, PSD-95 interactions with the serotonin 2A receptor (5-HT_2AR) facilitate Gα_q-coupled signaling by the receptor (Xia et al., 2003) (Table 2). PSD-95 has similarly been shown to antagonize the agonist-induced endocytosis of 5-HT_2AR (Xia et al., 2003). G protein–coupled receptor kinase 5 phosphorylation also disrupts PSD-95 interactions with β₁AR, which is consistent with a PSD-95/β-arrestin competition model (Hu et al., 2002). Moreover, the recruitment of β-arrestin2 to 5-HT_2AR corresponds with the dissociation of PSD-95, suggesting competitive binding for 5-HT_2AR, with mechanistic implications for the regulation of endocytosis of PSD-95–associated GPCRs (Schmid and Bohn, 2010). Notably, PSD-95 is documented to have an opposing role in 5-HT_2CR trafficking, where PSD-95 overexpression is suggested to suppress cell surface receptor expression and promote receptor endocytosis (Gavarini et al., 2006). This decrease in receptor expression at the cell surface is correlated with enhanced desensitization of 5-HT_2CR–mediated Ca²⁺ accumulation (Gavarini et al., 2006). In PSD-95 null mice, serotonin 2C receptor (5-HT_2CR)–mediated cfos induction is impaired (Abbas et al., 2009). Despite significant sequence homology, PSD-95 appears to have opposing roles in regulating its trafficking and signaling pathways of 5-HT_2AR and 5-HT_2CR (Xia et al., 2003; Gavarini et al., 2006). PSD-95 was recently suggested to form a complex with G protein–coupled receptor 30, protein kinase A (PKA)–anchoring protein 5, and the PKA RIIβ regulatory subunit, thereby promoting G protein–coupled receptor 30 membrane localization and facilitating the constitutive inhibition of cAMP (Akama et al., 2013; Broselid et al., 2014). PSD-95 has also been reported to positively regulate dopamine 1 receptor (D₁R) endocytosis and inhibit D₁R-mediated cAMP formation (Zhang et al., 2007b). A more recent study suggests that PSD-95 contributes to D₁R recycling and resensitization without influencing D₁R-mediated Gα_s activation (Sun et al., 2009). However, the methods and cellular contexts used to arrive at these conclusions in these various studies are not directly comparable. Nevertheless, this highlights the importance of considering the specific GPCR in question when determining the regulatory role of a PDZ domain–containing protein as well as the endogenous trafficking and signaling machineries available within each specific cellular context.

Fig. 1.

Molecular topology of protein-protein interaction domains found in MAGUK family PDZ proteins. CaMKII, Ca²⁺/calmodulin-dependent kinase domain; CARD, caspase activation and recruitment domain; CC, coiled-coiled domain; L27, L27 domain.

View this table:

TABLE 1

Effect of PDZ proteins on GPCR trafficking

View this table:

TABLE 2

Effect of PDZ proteins on GPCR signaling

Synapse-Associated Protein of 97 kDa (DLG1).

Although synapse-associated protein of 97 kDa (SAP97) shares ∼60% sequence homology with PSD-95 (including three PDZ domains, an SH3 domain, a GK domain, and an additional L27 domain on the amino terminal), less is known about the role of SAP97 in regulating GPCR activity (Fig. 1). Nevertheless, SAP97 has been demonstrated to promote β₁AR phosphorylation via cyclic AMP–dependent protein kinase (PKA), despite having no effect on β₁AR-stimulated adenylyl cyclase activation and cAMP accumulation (Gardner et al., 2007). Additionally, SAP97 promotes recycling of β₁AR by a mechanism that involves the formation of a complex among β₁AR, PKA-anchoring protein 79, and PKA (Gardner et al., 2007; Nooh, et al., 2013, 2014). In contrast, SAP97 promotes membrane stabilization of the corticotropin-releasing factor (CRF) receptor 1 by suppressing CRFR1 endocytosis (Dunn et al., 2013). Although SAP97 does not contribute to the regulation of CRFR1-mediated cAMP accumulation via Gα_s, endogenous SAP97 is essential for CRF-mediated extracellular signal regulated kinase (ERK) 1/2 phosphorylation via the ERK1/2 signaling pathway (Dunn et al., 2013). In contrast, similar to what is observed for PSD-95–mediated enhancement of 5-HT_2AR–stimulated inositol phosphate formation, the loss of endogenous SAP97 expression results in a reduction in 5-HT_2AR–activated inositol accumulation via Gα_q (Xia et al., 2003; Dunn et al., 2014). However, SAP97 also suppresses 5-HT_2AR endocytosis and facilitates 5-HT–mediated ERK1/2 phosphorylation. The role of endogenous SAP97 in facilitating CRFR1- and 5-HT_2AR–stimulated ERK1/2 phosphorylation does not require interactions with the PDZ-binding motifs of these receptors, and knockdown of endogenous SAP97 also reduces corticotropin-releasing factor receptor 2–mediated ERK1/2 phosphorylation (Dunn et al., 2013, 2014). Since corticotropin-releasing factor receptor 2 does not encode a class I PDZ-binding motif, it is possible that SAP97 may play a global role in regulating GPCR-mediated ERK1/2 activity that is independent of receptor interactions.

PSD Protein of 93 kDa (DLG2) and SAP of 102 kDa (DLG3).

Postsynaptic density protein of 93 kDa (PSD-93) contains three PDZ domains, an SH3 domain, and a GK domain (Fig. 1). Not a great deal is known about the role of PSD-93 in regulating GPCRs, but PSD-95 and PSD-93 have been previously demonstrated to compensate for one another (Sun and Turrigiano, 2011). Therefore, it is likely that both PSD-93 and PSD-95 may play similar roles with respect to GPCR regulation. PSD-95 and PSD-93 have been identified to interact with the somatostatin receptor (SSTR) 1 and SSTR4 (Christenn et al., 2007), and both have been shown to inhibit NMDA receptor (NMDAR) endocytosis (Lavezzari et al., 2003). Future studies are needed to examine the role of PSD-93 in the regulation of GPCR trafficking to determine whether its function overlaps with both PSD-95 and SAP97. Synapse-associated protein of 102 kDA (SAP102) contains three PDZ domains, an SH3 domain, and a GK domain (Fig. 1). SAP102 has been demonstrated to regulate adenosine A_2A receptor mobility and promote A_2A receptor–mediated ERK signaling (Thurner et al., 2014). SAP102 has additionally been identified to regulate the trafficking of AMPA and NMDA receptors. Thus, it is of interest in the future to determine whether SAP102 plays a role similar to that of other membrane-associated guanylate kinase (MAGUK) proteins in the regulation of GPCR activity.

Discs, Large Homolog 5.

Discs, large homolog 5 (DLG5) differs from the common topology of the PSD-95 subfamily of MAGUKs, with the inclusion of an amino-terminal caspase activation and recruitment domain, which is similar to the caspase activation and recruitment domain and membrane-associated guanylate-like kinase domain-containing proteins, and a fourth PDZ domain (de Mendoza et al., 2010) (Fig. 1). CARMA3 has been implicated in facilitating GPCR-induced activation of NFκB via lysophosphatidic acid, endothelin-1, and angiotensin II (Scudiero et al., 2014). Although there does not appear to be any examples of DLG5 in the direct regulation of GPCRs, DLG5 has been implicated in regulating synaptogenesis by enhancing the membrane localization of the transmembrane protein N-cadherin (Wang et al., 2014). DLG5 has also been demonstrated to scaffold atypical protein kinase C (PKC) isoforms, and this provides a mechanism by which DLG5 contributes to the regulation of GPCR-mediated signaling (Nechiporuk et al., 2013).

Other GPCR-Interacting PDZ Domain–Containing MAGUK Proteins

Membrane Palmitoylated Proteins and Calmodulin-Activated Serine/Threonine Kinase (PALS3, LIN-2).

Membrane palmitoylated proteins (MPPs) (MPP1/p55, MPP2, MPP3, MPP4, MPP5/PALS1, MPP6/PALS2, and MPP7) are unified by the inclusion of a PDZ domain, an SH3 domain, and a GK domain (Fig. 1). Additionally, all but MPP1 have two amino-terminal L27 domains, with MPP5 also including an amino-terminal coiled-coil domain. MPP1 and MPP2 and MPP5–MPP7 also include a HOOK domain between their SH3 and GK domains. Although MPP proteins are a relatively abundant group of MAGUK proteins, very little is known about their regulation of GPCR function. MPP3 has been demonstrated to promote the membrane stability of 5-HT_2CR and prevent receptor desensitization (Gavarini et al., 2006). MPP1 has additionally been implicated in membrane organization, raft formation, and receptor tyrosine kinase–mediated ERK signaling (Łach et al., 2012; Biernatowska et al., 2013). Thus, it is plausible that MPPs may generally promote the membrane organization of integral proteins, including GPCRs.

Ca²⁺/calcium/calmodulin-dependent serine protein kinase (CASK) is very similar in topology to the MPPs, with protein domains that include a catalytically active Ca²⁺/calmodulin-dependent kinase domain at the amino-terminus followed by two L27 domains, a PDZ domain, an SH3 domain, and a GK domain (te Velthuis et al., 2007; Mukherjee et al., 2008) (Fig. 1). CASK forms a tripartite complex with the PDZ domain containing Mint1 and Veli proteins, but the role of Mint1 and Veli proteins in the regulation of GPCRs remains undetermined (Butz et al., 1998). Like MPP3, CASK has been shown to interact with 5-HT_2CR (Bécamel et al., 2002, 2004; Gavarini et al., 2006). Although the functional consequence of this interaction on 5-HT_2CR trafficking and signaling remains to be tested, CASK has been implicated in regulating the trafficking of NMDAR and AMPA receptor (AMPAR), partly via its regulation of SAP97 conformation and receptor interactions (Jeyifous et al., 2009; Lin et al., 2013). Interestingly, CASK has been demonstrated to interact with PKA, PKCε, and the regulator of G protein signaling (RGS) 4, which may suggest a role for CASK in regulating GPCR-mediated signaling (Hong and Hsueh, 2006).

Membrane-Associated Guanylate Kinase with Inverted Orientation PDZ Protein Family

Membrane-associated guanylate kinase with inverted orientation proteins (MAGIs) include three proteins with an amino terminal PDZ domain followed by a GK domain, two tryptophan-tryptophan (WW) domains, and five more PDZ domains (Fig. 1). MAGI proteins differ from other MAGUK proteins in the exclusion of an SH3 domain (Dobrosotskaya et al., 1997). MAGI-1 colocalizes with the brain angiogenesis inhibitor 1 receptor (BAI-1R) at the cell membrane via an interaction with the receptor carboxyl-terminal tail, and MAGI-3 interacts with BAI-1R to promote ERK phosphorylation (Shiratsuchi et al., 1998; Stephenson et al., 2013). MAGI-3 promotes ERK and RhoA signaling, which is mediated by lysophosphatidic acid receptor 2 (LPA₂R), but antagonizes ERK1/2 activation in response to the activation of either β₁AR or β₂AR (He et al., 2006; Zhang et al., 2007a; Yang et al., 2010). MAGI-2 interacts with β₁AR via its first PDZ domain and functions to promote β₁AR endocytosis without affecting β₁AR-mediated cAMP signaling (Xu et al., 2001). In contrast, MAGI-2 interacts with the vasoactive intestinal peptide receptor 1 (VPAC1) and functions to both inhibit VPAC1 endocytosis and suppress VPAC1-mediated cAMP signaling (Gee et al., 2009). MAGI-2 also promotes the cell surface expression of metabotropic glutamate receptor (mGluR) 1a via its association with the PDZ domain–containing protein tamalin (Sugi et al., 2007). Thus, similar to what has been reported for PSD-95 family PDZ proteins, the MAGI family of PDZ proteins contributes to the regulation of the endocytosis and cell signaling of a number of GPCRs, but the functional effects of these protein interactions have differential effects, depending on the GPCR studied.

Na⁺/H⁺ Exchanger Regulatory Factor Family of PDZ Proteins

Na⁺/H⁺ Exchanger Regulatory Factor 1.

Na⁺/H⁺ exchanger regulatory factor (NHERF) 1 (ezrin/radixin/moesin–binding protein 50) is a relatively small PDZ domain–containing protein characterized by two PDZ domains and a carboxyl-terminal ezrin-binding domain (Fig. 2). NHERF1 represents one of the earliest PDZ proteins to be shown to interact with a GPCR (Hall et al., 1998). NHERF1 regulates Na⁺/H⁺ exchange via its interaction with β₂AR without altering cAMP signaling, and has since been demonstrated to regulate a number of GPCRs. NHERF1 regulates the recycling of β₂AR, and its binding to the receptor is disrupted by G protein–coupled receptor kinase phosphorylation of β₂AR at serine residue 411 (Cao et al., 1999). However, NHERF1 is reported to inhibit recycling of the parathyroid 1 receptor (PTH1R) (Wang et al., 2007). NHERF1 also inhibits PTH1R desensitization and endocytosis, a function that appears to involve NHERF1-dependent inhibition of β-arrestin2 recruitment to PTH1R (Wang et al., 2007, 2009). NHERF1 expression also enhances PTH1R-mediated cAMP signaling and couples PTHR1 to the activation of Gα_q (Wang et al., 2007, 2010; Wheeler et al., 2008). NHERF1 expression enhances cell surface expression of the κ opioid receptor, inhibiting downregulation and promoting receptor recycling (Li et al., 2002). In contrast, NHERF1 increases thromboxane receptor β cell surface expression by blocking the internalization of the receptor (Rochdi and Parent, 2003). An additional mechanism by which NHERF1 may increase GPCR membrane targeting is via its competition with the cystic fibrosis transmembrane conductance regulator–associated ligand (CAL) to antagonize CAL-mediated retention of GPCRs in the Golgi (Bauch et al., 2014).

Fig. 2.

Molecular topology of other PDZ domain–containing proteins that interact with GPCRs. ABD, actin binding domain; AH, arfaptin homology domain; ANK, ankyrin repeat domain; C2, C2 domain; CC, coiled-coiled domain; cNBD, cyclic nucleotide binding domain; EBD, ezin-binding domain; FAD, flavin adenine dinucleotide–binding domain; FDX, flavodoxin-like domain; G, Golocco motif; GEF-CD, Ras GEF catalytic domain; GEF-N, Ras-like GEF, N-terminal domain; L27, L27 domain; PB1, Phox/Bem1 domain; PH_A/B, interrupted pleckstrin homology domain; PP1, protein phosphatase 1–binding domain; PTB, phosphtyrosine-binding domain; PX, Phox-homology domain; RA, Ras association domain; RB, Ras-binding domain; RGSL, RGS-like domain; RhoGEF, RhoGEF domain; SAM, sterile alpha motif; SU, syntrophin unique domain.

In contrast to the role of NHERF1 in antagonizing the endocytosis of PTHR1 and thromboxane receptor β, NHERF1 is reported to facilitate the endocytosis of a number of GPCRs. NHERF1 enhances chemokine (C-C motif) receptor 5 (CCR5) endocytosis and β-arrestin1 recruitment, thereby promoting the activation of ERK, Rho, and focal adhesion kinase signaling pathways, as well as potentially contributes to CCR5-mediated HIV-1 entry (Hammad et al., 2010; Kuang et al., 2012). NHERF1 overexpression also rescues the endocytosis of an internalization-defective platelet-activating factor receptor and antagonizes platelet-activating factor receptor–mediated inositol phosphate formation (Dupré et al., 2012). Agonist activation of the purinergic P2Y₁₂ receptor results in the β-arrestin–dependent recruitment of NHERF1 to the receptor and promotes the formation of a P2Y₁₂ receptor/NHERF1 complex that does not require PDZ-binding motif interactions (Nisar et al., 2012). NHERF1 also regulated frizzled family receptor activity (Wheeler et al., 2011). Thus, NHERF1 appears to play an integral, but complex, role in regulating the endocytosis and recycling of a variety of different GPCRs.

Na⁺/H⁺ Exchanger Regulatory Factor 2.

The topology of Na⁺/H⁺ exchanger regulatory factor 2 (NHERF2) is quite similar to NHERF1 as it shares a 44% sequence homology with NHERF1 and contains two PDZ domains and a carboxyl-terminal ezrin-binding domain (Ardura and Friedman, 2011) (Fig. 2). Similar to NHERF1, NHERF2 contributes to the regulation of PTH1R (Mahon et al., 2002; Wang et al., 2010). NHERF2 functions to antagonize PTHR1 coupling to Gα_s-coupling, while concomitantly promoting the coupling of PTH1R to both the activation of Gα_q and Gα_i (Mahon et al., 2002; Wang et al., 2010). NHERF2 also interacts directly with phospholipase C (PLC) β to enhance P2Y₁ receptor–mediated Ca²⁺ signaling (Fam et al., 2005). Similarly, NHERF2 interacts with PLCβ3 and the LPA₂R, allowing for the formation of a protein complex that directly links the receptor to PLCβ3-mediated inositol phosphate signaling (Oh et al., 2004; Choi et al., 2010). NHERF2 and mGluR5 show overlapping expression in a mouse brain at postsynaptic neuronal sites and astrocytic processes, and NHERF2 prolongs the mGluR5-mediated Ca²⁺ response (Paquet et al., 2006).

PDZ Domain–Containing Kidney Protein 1 (Na⁺/H⁺ Exchanger Regulatory Factor 3) and 2 (Na⁺/H⁺ Exchanger Regulatory Factor 4).

PDZ domain–containing kidney protein 1 (PDZK1), formerly known as Na⁺/H⁺ exchanger regulatory factor 3, differs from NHERF1 and NHERF2 in structural topology by having four PDZ domains and no carboxyl-terminal ezrin-binding domain (Fig. 2). Nevertheless, PDZK1 has been implicated in regulating a subset of GPCRs. PDZK1 promotes the formation of a complex between SSTRs and PLCβ3, similar to what is observed for LPA₂R (Oh et al., 2004; Choi et al., 2010), thereby facilitating somatostatin-stimulated PLC activation, Ca²⁺ mobilization, and ERK1/2 phosphorylation (Kim et al., 2012). PDZK1 also functions to enhance human prostacyclin receptor (hIPR) cell surface localization and cAMP signaling and contributes to endothelial cell migration and angiogenesis (Turner et al., 2011). PDZK1 inhibits 5-HT_2AR endocytosis, and siRNA knockdown of PDZK1 results in reduced 5-HT_2AR–mediated inositol phosphate accumulation, but is not involved in 5-HT_2AR–stimulated ERK1/2 phosphorylation (Walther et al., 2015). However, PDZK1 interactions with 5-HT_2AR do not appear to be required for its regulation of 5-HT_2AR activity. In contrast, although PDZK1 does not regulate CRFR1-mediated cAMP accumulation, unlike what is observed for 5-HT_2AR, PDZK1 facilitates CRFR1-mediated ERK1/2 phosphorylation. Similar to PDZK1, PDZ domain–containing kidney protein 2 (PDZK2) also has four PDZ domains and has been shown to regulate hIPR (Reid et al., 2012). Agonist activation of hIPR increases PDZK2 association and results in PKA- and PKC-mediated phosphorylation of PDZK2 (Reid et al., 2012). Like PDZK1, PDZK2 also enhances hIPR cell surface expression and cAMP accumulation (Reid et al., 2012). Taken together, PDZK1 and PDZK2 appear to be important for regulating the trafficking of an increasing subset of GPCRs and may be biased toward increased Gα_q signaling, similar to what is observed for both NHERF1 and NHERF2.

PDZ Proteins that Regulate Golgi Trafficking

Gα-Binding Protein Interacting Protein Carboxyl-Terminus (TIP-2, Synectin).

RGS Gα-binding protein–interacting protein carboxyl-terminus (GIPC) is a PDZ domain–containing protein, with one PDZ domain that is implicated in the sorting of nascent proteins from the Golgi network (Liu et al., 2001) (Fig. 2). With regards to GPCRs, GIPC has been shown to target D₂R to endosomes and the Golgi apparatus (Jeanneteau et al., 2004). Furthermore, GIPC expression suppresses dopamine 3 receptor Gα_i-coupling and prevents dopamine 3 receptor degradation (Jeanneteau et al., 2004). GIPC also plays a role in regulating both the human luteinizing hormone receptor and LPA₁R trafficking (Hirakawa et al., 2003; Varsano et al., 2012). The interaction of GIPC with LPA₁R is essential for LPA₁R trafficking from APPL-positive signaling endosomes to early endosome antigen 1–positive early endosomes (Varsano et al., 2012). Additionally, GIPC links LPA₁R to the protein kinase B signaling pathway, cell proliferation, and cell motility (Varsano et al., 2012). GIPC also contributes to the suppression of β₁AR-mediated ERK activation, but does affect β₁AR-stimulated cAMP accumulation (Hu et al., 2003).

CAL (Golgi-Associated Coiled-Coil and PDZ Domain–Containing Protein, PIST).

CAL is also named Golgi-associated coiled-coil and PDZ domain–containing protein due to its common subcellular localization within the trans-Golgi network and a structural topology consisting of two coiled-coil domains and one PDZ domain (Fig. 2). CAL is selectively localized to the trans-Golgi network in neurons as well as other cell types and interacts with Rab6a, a small GTPase implicated in Golgi-related trafficking pathways (Bergbrede et al., 2009; Valente et al., 2010; Chen et al., 2012). CAL reduces plasma membrane expression and recycling of β₁AR, and interferes with both β₁AR-mediated ERK signaling and postendocytotic receptor degradation via the lysosome (He et al., 2004; Koliwer et al., 2015). CAL overexpression retains SSTR5 in the Golgi apparatus, thereby reducing SSTR5 cell surface expression (Wente et al., 2005; Bauch et al., 2014). Additionally, CAL colocalizes with mGluR1a following agonist activation, and its overexpression decreases mGluR1a-stimulated ERK signaling (Zhang et al., 2008b). CAL is suggested to regulate mGluR5a function by increasing the expression of the receptor by a mechanism that involves the inhibition of mGluR5a ubiquitination (Cheng et al., 2010). Taken together, it appears CAL could have a regulatory role over the subcellular localization of a subset of GPCRs, perhaps by contributing to the post-translational modification of nascent and mature proteins that ultimately influence the sorting and trafficking fate.

Additional GPCR-Interacting PDZ Proteins

Spinophilin (Neurabin-2) and Neurabin-1.

Both spinophilin/neurabin-2 and neurabin-1 contain an amino-terminal actin-binding domain, a protein phosphatase 1γ-binding domain, a single PDZ domain, and a coiled-coil domain, with neurabin-1 also containing a carboxyl-terminal sterile alpha motif domain (Kelker et al., 2007) (Fig. 2). Spinophilin has been shown to interact with both D2R and α₂-adrenergic receptor (α₂AR) (Smith et al., 1999; Richman et al., 2001; Wang and Limbird, 2002; Brady et al., 2003; Wang et al., 2004). However, these interactions appear to be mediated by the third intracellular loop domains of these GPCRs, as opposed to interactions with PDZ-binding motifs. Spinophilin functions to promote membrane localization and inhibit the endocytosis and desensitization of α₂ARs by competing for β-arrestin2 binding (Wang et al., 2004b). The interaction between spinophilin and α₂AR is prevented by PKA-mediated phosphorylation of spinophilin, which results in increased agonist-stimulated α_2AAR endocytosis (Xu et al., 2008). β₂AR activation also stimulates PKA-mediated spinophilin phosphorylation to increase α_2AAR endocytosis (Cottingham et al., 2013). Conversely, spinophilin appears to promote RGS2-mediated inhibition of α₂AR-evoked Ca²⁺ signaling and RGS2-mediated modulation of α₁-adrenergic receptor–NMDAR crosstalk (Wang et al., 2005; Liu et al., 2006). In spinophilin knockout mice, the α_2A-adrenergic receptor (α_2AAR) exhibits increased G protein coupling and sensitized responses to α_2AAR agonists (Lu et al., 2010; Cottingham et al., 2012). Both spinophilin and neurabin-1 are implicated in the D₁R-dependent regulation of AMPAR as well as long-term depression and potentiation, respectively (Allen et al., 2006). Spinophilin promotes prostacyclin receptor signaling via Gα_s and influences both M1 muscarinic acetylcholine receptor and M3 muscarinic acetylcholine receptor (m3AChR) activity by enhancing RGS8-mediated inhibition of the Gα_q-coupled signaling (Fujii et al., 2008; Kurogi et al., 2009; Ma et al., 2012). Similarly, spinophilin recruits RGS4 to m3AChR, and like RGS8, RGS4 antagonizes m3AChR inositol phosphate signaling (Ruiz de Azua et al., 2012). Spinophilin also promotes μ-opioid receptor (μOR)–mediated signaling via Gα_i, but inhibits μOR-mediated ERK activation, while facilitating μOR endocytosis (Charlton et al., 2008; Fourla et al., 2012).

The interaction between spinophilin and opioid receptors appears to occur via the opioid receptor third intracellular loop and a conserved region of the carboxyl-termini, which is proximal to the seventh transmembrane domain (Fourla et al., 2012). Interestingly, this region appears to correlate with a small helical region identified in many class A rhodopsin-like GPCRs as helix 8 (Huynh et al., 2009). This domain is suggested to run perpendicular to the other seven helical transmembrane domains and is initiated by an N-P-x-x-Y motif (Huynh et al., 2009). In examining the amino acid sequences of class A rhodopsin-like GPCRs with this motif, a possible internal class I PDZ-binding motif, as characterized by an S/T-x-ϕ motif, may be present near this region (Trejo, 2005). Furthermore, homologous regions are found within α₂ARs and D₂R, which also interact with spinophilin via the third intracellular loop domain. Notably, a recent study has identified helix 8 of D₂R to associate with the PDZ domain of GIPC (Sensoy and Weinstein, 2015). Future studies could look to investigate whether secondary interactions with spinophilin may occur within the α₂ARs and D₂R carboxyl-terminal/helix 8, and whether these interactions require spinophilin’s PDZ domain.

SH3 and Multiple Ankyrin Repeat Domain Proteins.

SH3 and multiple ankyrin repeat domain (Shank) proteins are unified by the inclusion of multiple ankyrin repeat domains, an SH3 domain, a PDZ domain, and a sterile alpha motif domain; however, Shank2 lacks the ankyrin repeats (Fig. 2). Shank1B enhances mGluR1/5-mediated ERK1/2 and Ca²⁺-dependent signaling, and Shank3 is important for mGluR5-mediated ERK1/2 and cAMP response element-binding protein phosphorylation and subsequent mGluR5-mediated long-term depression (Sala et al., 2005; Verpelli et al., 2011). Furthermore, Shank3 prevents mGluR1-mediated inhibition of NMDAR via its association with Homer1A (Guo et al., 2004; Bertaso et al., 2010). Similarly, Shank1/3 modulates muscarinic acetylcholine receptor 1– and D₂R-mediated inhibition of L-type Ca²⁺ channels via Homer proteins (Olson et al., 2005). With regards to GPCR trafficking, Shank influences the clustering and subcellular localization of mGluR5 and calcium-independent α-latrotoxin receptor CIRL/latrophilin 1 (Tu et al., 1999; Tobaben et al., 2000). Interestingly, a Shank/Homer1A complex can suppress NMDAR and AMPAR clustering and surface expression (Sala et al., 2003). Shank1 directly interacts with dynamin-2, which may provide insight into a mechanism of action in preventing GPCR-mediated crosstalk mechanisms and receptor surface expression (Okamoto et al., 2001). Future studies could look to investigate the role of Shank proteins in regulating GPCR trafficking and the crosstalk between GPCRs and ion channels.

Partitioning Defective Proteins 3 and 6.

Partitioning defective (Par) proteins have been implicated in cellular polarization, and Par3 and Par6 are PDZ domain–containing members of the Par family (Fig. 2) (Macara, 2004). Par3 is implicated as having a role in synaptogenesis as a consequence of its interaction with BAI-1R (Duman et al., 2013). Additionally, Par3 has been shown to increase bradykinin receptor interactions with PLCβ1 (Choi et al., 2010). Interestingly, both Par3 and Par6 interact and catalyze the activation of PLCβ downstream of heterotrimeric G proteins and form a complex with atypical PKCs (Joberty et al., 2000; Cai et al., 2005). Taken together, these observations suggest that Par3 and Par6 may contribute to the regulation of GPCR-mediated Gα_q signaling as well as feedback receptor desensitization by atypical PKCs.

Multiple PDZ Protein 1.

Multiple PDZ protein 1 (MUPP1) is one of the largest PDZ domain–containing proteins and is comprised of an amino terminal L27 domain followed by 13 PDZ domains (Fig. 2). The interaction of MUPP1 with the melatonin 1 receptor facilitates melatonin 1 receptor Gα_i-coupling, resulting in the inhibition of adenylyl cyclase activity (Guillaume et al., 2008). MUPP1 has also been shown to promote γ-aminobutyric acid B receptor–mediated Ca²⁺ signaling, although MUPP1 knockdown prolongs the decay of the odorant receptor olfactory receptor 2AG1–mediated Ca²⁺ response (Balasubramanian et al., 2007; Dooley et al., 2009). With regards to GPCR trafficking, MUPP1 increases the cell surface expression of 5-HT_2AR (Jones et al., 2009). Additionally, MUPP1 promotes the targeting of SSTR3 to tight junctions, thereby influencing transepithelial permeability (Liew et al., 2009; Vockel et al., 2010). Given that MUPP1 influences NMDA-dependent AMPA trafficking and clustering, it is likely that MUPP1 also regulates the trafficking of GPCRs that encode PDZ-binding motifs, thereby contributing to GPCR-dependent regulation of synaptic activity (Krapivinsky et al., 2004).

Tamalin (General Receptor for Phosphoinositides-Associated Scaffold Protein).

Tamalin or general receptor for phosphoinositides-associated scaffold protein encodes a PDZ domain, leucine zipper, and class I PDZ-binding motif on the distal carboxyl-terminal (Kitano et al., 2002, 2003) (Fig. 2). Tamalin promotes the plasma membrane localization of mGluR1a as well as the neuritic targeting of mGluR5 in hippocampal neurons (Kitano et al., 2002). Tamalin also interacts with mGluR2, mGluR3, and the γ-aminobutyric acid B2 receptor, but the functional consequence of these interactions remains to be determined (Kitano et al., 2002). In the absence of mGluRs or other potential GPCR binding partners, tamalin displays an autoinhibitory confirmation that is caused by the interaction between the tamalin PDZ domain and tamalin PDZ-binding motif (Sugi et al., 2007). Upon mGluR1a binding to the tamalin PDZ domain, the tamalin PDZ-binding motif is free to associate with MAGI-2 to further enhance the membrane localization of mGluR1a (Sugi et al., 2007). PDZ–guanine nucleotide exchange factor (GEF) 1/2 also contains PDZ-binding motifs, and future studies could look to determine whether they similarly exhibit autoregulation (Kuiperij et al., 2003, 2006; Ogawa et al., 2007).

Neuronal Nitric Oxide Synthase.

Neuronal nitric oxide synthase (nNOS) contains an amino-terminal PDZ domain, a flavodoxin-like domain, and a flavin adenine dinucleotide–binding domain (Fig. 2). nNOS, in conjunction with RGS17, has been demonstrated to complex with multiple GPCRs, including μOR, δ opioid receptor, serotonin 1A receptor, 5-HT_2AR, α₂AR, D₁R, D₂R, M2 muscarinic acetylcholine receptor, M4 muscarinic acetylcholine receptor, mGluR2, mGluR5, and cannabinoid receptor 1 (Sánchez-Blázquez et al., 2012). Activation of these receptors leads to the nNOS/NO-dependent recruitment of PKCγ and Raf-1 to many of these GPCRs. nNOS also facilitates crosstalk between μOR and NMDAR (Rodríguez-Muñoz et al., 2008; Sánchez-Blázquez et al., 2010; Garzón et al., 2011). Interestingly, nNOS interacts with both PSD-95 and PSD-93, and is targeted to the neuromuscular junction via its interaction with PDZ protein α-syntrophin (Brenman et al., 1996; Adams et al., 2010). Although this nNOS interaction with PSD-95 is suggested to regulate NMDAR activity (Christopherson et al., 1999), it is yet to be determined whether these PDZ/PDZ protein interactions regulate GPCR function.

Syntrophins.

α-syntrophin, β₁-syntrophin, and β₂-syntrophin all have an amino-terminal pleckstrin-homology (PH) domain interrupted by a PDZ domain, followed by another PH domain and a syntrophin unique calmodulin-binding domain (Fig. 2) (Adams et al., 1995; Ahn et al., 1996; Chen et al., 2006). These syntrophins interact with α_1DAR and collectively facilitate the functional expression of the receptor at the membrane, promoting α_1DAR-mediated phosphatidylinositol hydrolysis, ERK1/2 phosphorylation, and Ca²⁺ mobilization (Chen et al., 2006; Lyssand et al., 2008, 2010, 2011). Neither γ₁-syntrophin nor γ₂-syntrophin comparably bind α_1DAR, despite containing one PDZ domain and a PH domain, and their potential role in GPCR regulation remains uncertain (Chen et al., 2006). α-syntrophin can additionally scaffold the PDZ protein nNOS and notably binds Gβγ subunits via its PDZ domain (Brenman et al., 1996; Adams et al., 2010; Zhou et al., 2005).

Protein Interacting with Protein Kinase C α 1.

The protein interacting with protein kinase C α 1 (PICK1) encodes one PDZ domain and an arfaptin homology domain/bin/amphiphysin/Rvs domain involved in cell membrane interactions (Katsushima et al., 2013) (Fig. 2). PICK1 promotes the intracellular clustering of the prolactin-releasing peptide receptor, influences plasma membrane expression of the growth hormone–releasing hormone receptor, and antagonizes growth hormone–releasing hormone receptor–mediated cAMP signaling (Lin et al., 2001; Katsushima et al., 2013). PICK1 regulates PKC phosphorylation of mGluR7a, regulates the presynaptic clustering of mGluR7, and mediates stable mGluR7 cell surface expression (Boudin et al., 2000; Dev et al., 2000; Suh et al., 2008). mGluR7a knock-in mice lacking a PDZ-binding motif exhibit deficits in hippocampal-dependent spatial memory and are highly susceptible to the convulsant drugs, and the disruption of the mGluR7a-PICK1 complex induces epilepsy-like seizures (Bertaso et al., 2008; Zhang et al., 2008a). Taken together, it appears PICK1 may be important for regulating the trafficking of a subset of GPCRs and may prove important in regulating GPCR-mediated signaling pathways. Notably, PICK1 can both homodimerize and heterodimerize with another PDZ domain–containing protein, syntenin-1 (Staudinger et al., 1997; Koroll et al., 2001).

Syntenin-1.

Syntenin-1 contains two PDZ domains (Fig. 2) and has been found to self-associate as well as heterodimerize with PICK1 and form a complex with mGluR7 (Koroll et al., 2001; Hirbec et al., 2002; Enz and Croci, 2003). Although PICK1 regulates mGluR7 phosphorylation, clustering, and membrane expression, it is not yet clear what role syntenin-1 may play in this regulation (Boudin et al., 2000; Dev et al., 2000; Suh et al., 2008). Nonetheless, syntenin-1 has been demonstrated to enhance the membrane expression of G protein–coupled receptor 37 (endothelin receptor type B–like) (Dunham et al., 2009). In regards to signaling, syntenin-1 interacts with frizzled-7 and promotes c-Jun phosphorylation, CDC42 activation, and PKCα recruitment to the membrane (Luyten et al., 2008). Syntenin-1 can also heterodimerize with syntenin-2, although little is known about the role of syntenin-2 in GPCR regulation (Koroll et al., 2001).

Sorting Nexin-27.

Sorting nexin-27 (SNX27) differs from other sorting nexins through the inclusion of an amino-terminal PDZ domain, followed by a Phox homology domain and a Ras-associating domain (Fig. 2). SNX27 interacts with both serotonin 4A receptor and β₂AR in early endosome antigen 1–positive early endosomes (Joubert et al., 2004; Lauffer et al., 2010). Moreover, SNX27 is involved in regulating the recycling of β₂AR, β₁AR, and SSTR5, thereby preventing receptor degradation (Lauffer et al., 2010; Temkin et al., 2011; Nakagawa and Asahi, 2013; Bauch et al., 2014). The regulation of β₂AR recycling by SNX27 is dependent upon Phox homology domain–mediated associations with the endosomal membrane (Lauffer et al., 2010). Furthermore, SNX27 interacts with the endosomal WASH complex to target β₂AR to the retromer tubule for efficient recycling (Temkin et al., 2011). Taken together, it appears SNX27 is capable of promoting the endosomal sorting and recycling of a subset of GPCRs, a role that may be generalizable to several other PDZ motif-encoding GPCRs.

PDZ-GEFs (RAPGEFs, CNrasGEF, RA-GEF).

PDZ domain–containing GEFs (PDZ-GEF1 and PDZ-GEF2) share an approximately 56% sequence homology and include one or two cyclic nucleotide-binding domains, respectively, an N-terminal Ras GEF domain, a PDZ domain, a Ras-associating domain, and a Ras GEF catalytic domain within their molecular structure (Kuiperij et al., 2003, 2006) (Fig. 2). Similar to the PDZ domain–containing protein tamalin, PDZ-GEF1/2 have also been reported to contain a class I PDZ-binding motif at their carboxyl-termini, suggesting a capability for homo/hetero-oligomerization with PDZ domain–containing proteins or perhaps even autoregulatory capability via self-association (Kuiperij et al., 2003, 2006; Ogawa et al., 2007). Our current understanding of PDZ-GEF2 regulation of GPCRs is poor, but PDZ-GEF1 couples β₁AR to the activation of Ras (Pak et al., 2002). Furthermore, PDZ-GEF1 is essential for coupling the pituitary adenylate cyclase–activating polypeptide type I receptor to the ERK1/2 signaling pathway and the subsequent activation of neuritogenesis, with no effect on cAMP accumulation (Emery et al., 2013).

RGS Proteins with PDZ Domains (PDZ Domain–Containing RhoGEF, Leukemia-Associated RhoGEF, RGS3, and RGS12).

PDZ domain–containing RhoGEF (PDZ-RhoGEF) and leukemia-associated RhoGEF (LARG) are members of the RGS homology domain–containing RhoGEF subfamily and include an amino-terminal PDZ domain, an RGS-homology domain, a RhoGEF domain, and a PH domain (Fig. 2). LARG transduces Gα_q/12/13 activation into Rho activation via GPCRs, such as the Mas receptor, G2 accumulation receptor, muscarinic acetylcholine receptor 1, angiotensin II receptor 1, sphingosine-1 phosphate receptor 2, histamine H1 receptor, thromboxane A2 receptor, and endothelin 1 receptor (Booden et al., 2002; Ying et al., 2006; Medlin et al., 2010; Chiu et al., 2012; Pfreimer et al., 2012; Artamonov et al., 2013; Del Galdo et al., 2013). Similarly, PDZ-RhoGEF is proposed to contribute to gastrin-releasing peptide receptor–mediated activation of the Rho/ROCK pathway via Gα₁₃ (Patel et al., 2014). Finally, both PDZ-RhoGEF and LARG have been implicated in sustaining Rho activation following thrombin and lysophosphatidic acid receptor activation (Chikumi et al., 2002; Wang et al., 2004a; Yamada et al., 2005). Interestingly, both proteins appear capable of homo- and hetero-dimerization (Chikumi et al., 2004).

RGS12 contains one PDZ domain, a phosphotyrosine-binding domain, an RGS domain, two Ras-binding domains, and a GoLoco motif (Fig. 2). The RGS12 PDZ domain binds to the interleukin-8 receptor B PDZ-binding motif, but the functional consequence of this interaction is not well defined (Snow et al., 1998). Notably, RGS12 has been suggested to couple D₂R to inward rectifier potassium channels Kir3.1/3.2 (Oxford and Webb, 2004). Regulator of G protein signaling 3 (RGS3) contains a membrane-targeting C2 domain, one PDZ domain, and an RGS domain (Fig. 2). RGS3 has been identified to inhibit Gα_q- and Gα_i-mediated signaling by acting as a GTPase-activating protein (Scheschonka et al., 2000). RGS3 antagonizes Gα_q/11 signaling via pheromone P factor receptor and muscarinic acetylcholine receptor 3 activation, and RGS3 promotes Ca²⁺ oscillatory behavior during submaximal muscarinic acetylcholine receptor 3 activation (Wang et al., 2002; Anger et al., 2004, 2007; Tovey and Willars, 2004; Ladds et al., 2007; Karakoula et al., 2008). RGS3 also antagonizes follicle-stimulating hormone receptor– and luteinizing hormone receptor–mediated inositol phosphate and cAMP accumulation (Castro-Fernandez et al., 2004). Furthermore, RGS3 has been demonstrated to suppress Gα_i-mediated signaling pathways via μOR, muscarinic acetylcholine receptor 1, complement C5a receptor, and β₂AR, and even promote a Gα_s bias for β₂AR (Potenza et al., 1999; Anger et al., 2007; Nishiura et al., 2009; Chakir et al., 2011). In contrast, RGS3 was shown to inhibit gonadotropin-releasing hormone receptor–stimulated inositol phosphate signaling via Gα_q, but had no effect on cAMP signaling (Neill et al., 1997, 2001; Castro-Fernandez and Conn, 2002; Castro-Fernandez et al., 2002; Karakoula et al., 2008). Interestingly, RGS3 palmitoylation is increased following gonadotropin-releasing hormone receptor activation (Castro-Fernandez et al., 2002). Curiously, truncated RGS3 isoforms that have been reported to lack the amino-terminal and PDZ domain have also demonstrated a role in influencing GPCR activity, including sphingosine-1-phosphate receptors 1–3, angiotensin II receptor 1, endothelin 1 receptor, gonadotropin-releasing hormone receptor, serotonin 1A receptor, and muscarinic acetylcholine receptor 2/3 (Druey et al., 1996; Castro-Fernandez et al., 2003; Cho et al., 2003; Anger et al., 2004, 2007; Jaén and Doupnik, 2005). Distinguishing the role of LARG, PDZ-RhoGEF, RGS3, and RGS12 PDZ domain interactions, as opposed to RGS domain interactions with heterotrimeric G proteins, in the regulation of GPCR signaling remains a challenge.

Role of PDZ Proteins in GPCR-Regulated Physiology

PSD-95 Family of MAGUK PDZ Proteins.

The PDZ domain–containing MAGUK proteins play an essential role in human neurophysiology and development. This is demonstrated in mouse knockout studies, where PSD-95 and PSD-93 double-knockout mice exhibit severe deficiencies in AMPA currents, and SAP97 knockout mice show neonatal lethality (Caruana and Bernstein, 2001; Howard et al., 2010). Of particular interest is the observation that PSD-95 is essential for hallucinogenic and atypical antipsychotic actions of 5-HT_2AR and 5-HT_2CR (Abbas et al., 2009). In addition to being involved in atypical antipsychotic actions (Abbas et al., 2009), PDZ protein interactions with GPCRs also appear to be important in regulating stress and anxiety responses (Magalhaes et al., 2010). Preactivation of the CRFR1 receptor sensitizes 5-HT_2AR–stimulated inositol phosphate formation, which is dependent upon intact PDZ-binding motifs in both receptors, receptor endocytosis, and recycling (Magalhaes et al., 2010). Furthermore, the phenomenon can be blocked by a Tat-tagged fusion protein corresponding to the last 15 amino acids of the CRFR1 tail. In addition, pretreatment of mice with subthreshold doses of CRF into the prefrontal cortex sensitizes mouse anxiety responses to 2,5-dimethoxy-4-iodoamphetamine treatment (Magalhaes et al., 2010). Thus, it is possible that PDZ protein interactions may serve as a good pharmaceutical target for the treatment of disease.

SAP102 is important during early synaptic development, and SAP97 appears to be important in SSTR1-mediated growth cone dynamics, as evidenced by colocalization within the growth cone (Kim and Sheng, 2004; Elias et al., 2006; Cai et al., 2008). However, this role may not be limited to SAP97 and may include additional PDZ domain–containing proteins (Cai et al., 2008). PSD-95 plays a functional role in synaptic plasticity and contributes to GPCR-mediated regulation of both long-term potentiation and long-term depression (Xu, 2011). Notably, SAP97 also modulates the ability to regulate AMPA and NMDA receptors by promoting synaptic trafficking of these receptors (Howard et al., 2010). Acute overexpression of SAP97 in hippocampal slice cultures restored synaptic transmission in PSD-95/PSD-93 double knockout mice, and long-term overexpression of SAP97 throughout development led to enhancements in synaptic transmission in vivo (Howard et al., 2010). This regulation of NMDAR- and AMPAR-mediated synaptic transmission is likely to also involve a role of GPCRs. PSD-95 is reported to have an important role in regulating the trafficking dynamics of D₁R in striatal neurons, and this regulatory role may contribute to l-adenosine triphosphate–induced dyskinesia (Porras et al., 2012). Thus, the role of PSD-95 in regulating D₁R dynamics may be complicated by its ability to disrupt the formation of D1R/NMDAR complexes, a function that may be potentially directly associated with its role in the regulation of synaptic activity (Zhang et al., 2009). The association of PSD-95 with β₁AR allows it to form a complex with NMDAR, and this may contribute to the regulation of synaptic activity by adrenergic ligands (Hu et al., 2000).

Other PDZ Proteins.

There are a number of other examples of PDZ proteins regulating GPCR-mediated regulation of physiologic functions. In the immune system, it has been found that the interaction of NHERF1 with the complement component C3a receptor is required for C3a-mediated mast cell degranulation, NFκB-activation, and chemokine production (Subramanian et al., 2012). CCR5 functions as a coreceptor for HIV-1 viral entry into mammalian cells by functioning as a cofactor for the entry of the virus (Henrich and Kuritzkes, 2013). NHERF1 interactions with CCR5 function to enhance actin filament rearrangement of host cells, a function that is essential to allow postcell entry HIV-1 replication (Hammad et al., 2010; Kuang et al., 2012). PDZK1 interactions with hIPR selectively facilitate hIPR-dependent activation of endothelial migration and vascular angiogenesis in vitro (Turner et al., 2011). MUPP1, the largest of the PDZ domain–containing adaptor proteins, promotes the targeting of SSTR3 to tight junctions and consequently influences transepithelial permeability of skin cells (Liew et al., 2009; Vockel et al., 2010). Tamalin plays an important role in regulating mGluR signaling, and tamalin knockout mice exhibit differences in their acute and adaptive responses to morphine administration (Ogawa et al., 2007). Similarly, nNOS mediates a mechanism of crosstalk between μOR and NMDA receptors to regulate opioid tolerance and analgesia (Rodríguez-Muñoz et al., 2008; Sánchez-Blázquez et al., 2010; Garzón et al., 2011). PICK1 interactions with mGluR7a have been shown to be important for presynaptic mGluR7a clustering. mGluR7a knock-in mice lacking a PDZ-binding motif exhibit deficits in hippocampal-dependent spatial memory, and the disruption of the mGluR7a-PICK1 complex induces epileptic-like seizures (Boudin et al., 2000; Bertaso et al., 2008; Zhang et al., 2008a). α-Syntrophin and β₂-syntrophin knockout mice display normal systolic blood pressure and resting heart rate; however, a double knockout prevents α_1DAR-mediated blood pressure responses and exhibits a distinct hypotonic phenotype at rest, thereby demonstrating the capability for PDZ protein compensation in vivo (Lyssand et al., 2008).

Concluding Remarks

GPCRs are influential in the regulation of every aspect of human physiology. Therefore, any advancement in the understanding of how they can be regulated could contribute to the design and development of new pharmacological treatment and prevention strategies for a multitude of human diseases (Bockaert et al., 2010; Heng et al., 2013). Accordingly, it is becoming clear that PDZ proteins play an important role in the regulation of GPCR signaling and trafficking. Considering it is estimated that 20% of GPCRs have PDZ-binding motifs and over 800 GPCRs have been identified in the human genome, it is safe to assume that this field is still in its infancy (Fredriksson et al., 2003; Lee and Zheng, 2010). Nevertheless, our growing understanding of the functional specificities and redundancies in PDZ regulation of GPCRs may lead to the development of new pharmacological compounds for precise modulation of GPCR activity. Such a strategy could be pertinent in the pharmacological treatment of a multitude of human pathologies, including, but not limited to, mental illnesses, cystic fibrosis, and osteoporosis (Abbas et al., 2009; Magalhaes et al., 2010; Mahon, 2012; Holcomb et al., 2014).

Authorship Contributions

Wrote or contributed to the writing of the manuscript: Dunn, Ferguson.

Footnotes

Received February 18, 2015.
Accepted March 25, 2015.

This work is supported by a Canadian Institutes of Health Research grant [MOP-62738] to S.S.G.F. S.S.G.F. holds a Tier I Canada Research Chair in Molecular Neurobiology and is a Career Investigator of the Heart and Stroke Foundation of Ontario, Canada.
dx.doi.org/10.1124/mol.115.098509.

Abbreviations

AMPA: α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid
AMPAR: AMPA receptor
CAL: conductance regulator–associated ligand
CRF: corticotropin-releasing factor
ERK: extracellular signal-related kinase
GEF: guanine nucleotide exchange factor
GIPC: Gα-binding protein interacting protein carboxyl-terminus
GK: guanylate kinase–like domain
GPCR: G protein–coupled receptor
hIPR: human prostacyclin receptor
MAGI: membrane-associated guanylate kinase protein
MAGUK: membrane-associated guanylate kinase
mGluR: metabotropic glutamate receptor
MPP: membrane palmitoylated protein
NHERF: Na⁺/H⁺ exchanger regulatory factor
NMDA: N-methyl-d-aspartate
NMDAR: NMDA receptor
nNOS: neuronal nitric oxide synthase
μOR: μ opioid receptor
Par: partitioning defective protein
PDZ: PSD-95, disc large, zona occludens-1
PH: pleckstrin-homology
PKA: protein kinase A
PKC: protein kinase C
PLC: phospholipase C
PSD: postsynaptic density
RGS: regulator of G protein signaling
SH3: SRC homology 3
Shank: SRC homology 3 domain and multiple ankyrin repeat domain
SSTR: somatostatin receptor

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PDZ Protein Regulation of G Protein–Coupled Receptor Trafficking and Signaling Pathways

Abstract

Introduction

PDZ Domains

PDZ-Binding Motifs

GPCR-Interacting PSD-95 Family PDZ Domain–Containing Membrane-Associated Guanylate Kinase Proteins

PSD-95 (DLG4).

Synapse-Associated Protein of 97 kDa (DLG1).

PSD Protein of 93 kDa (DLG2) and SAP of 102 kDa (DLG3).

Discs, Large Homolog 5.

Other GPCR-Interacting PDZ Domain–Containing MAGUK Proteins

Membrane Palmitoylated Proteins and Calmodulin-Activated Serine/Threonine Kinase (PALS3, LIN-2).

Membrane-Associated Guanylate Kinase with Inverted Orientation PDZ Protein Family

Na+/H+ Exchanger Regulatory Factor Family of PDZ Proteins

Na+/H+ Exchanger Regulatory Factor 1.

Na+/H+ Exchanger Regulatory Factor 2.

PDZ Domain–Containing Kidney Protein 1 (Na+/H+ Exchanger Regulatory Factor 3) and 2 (Na+/H+ Exchanger Regulatory Factor 4).

PDZ Proteins that Regulate Golgi Trafficking

Gα-Binding Protein Interacting Protein Carboxyl-Terminus (TIP-2, Synectin).

CAL (Golgi-Associated Coiled-Coil and PDZ Domain–Containing Protein, PIST).

Additional GPCR-Interacting PDZ Proteins

Spinophilin (Neurabin-2) and Neurabin-1.

SH3 and Multiple Ankyrin Repeat Domain Proteins.

Partitioning Defective Proteins 3 and 6.

Multiple PDZ Protein 1.

Tamalin (General Receptor for Phosphoinositides-Associated Scaffold Protein).

Neuronal Nitric Oxide Synthase.

Syntrophins.

Protein Interacting with Protein Kinase C α 1.

Syntenin-1.

Sorting Nexin-27.

PDZ-GEFs (RAPGEFs, CNrasGEF, RA-GEF).

RGS Proteins with PDZ Domains (PDZ Domain–Containing RhoGEF, Leukemia-Associated RhoGEF, RGS3, and RGS12).

Role of PDZ Proteins in GPCR-Regulated Physiology

PSD-95 Family of MAGUK PDZ Proteins.

Other PDZ Proteins.

Concluding Remarks

Authorship Contributions

Footnotes

Abbreviations

References

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GPCR Regulation by PDZ Proteins

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Na⁺/H⁺ Exchanger Regulatory Factor Family of PDZ Proteins

Na⁺/H⁺ Exchanger Regulatory Factor 1.

Na⁺/H⁺ Exchanger Regulatory Factor 2.

PDZ Domain–Containing Kidney Protein 1 (Na⁺/H⁺ Exchanger Regulatory Factor 3) and 2 (Na⁺/H⁺ Exchanger Regulatory Factor 4).