Investigation of a functional requirement for isoprenylation by the human prostacyclin receptor

A Review of Prostanoid Receptors: Expression, Characterization, Regulation, and Mechanism of Action

Prostaglandin signaling controls a wide range of biological processes from blood pressure homeostasis to inflammation and resolution thereof to the perception of pain to cell survival. Disruption of normal prostanoid signaling is implicated in numerous disease states. Prostaglandin signaling is facilitated by G-protein-coupled, prostanoid-specific receptors and the array of associated G-proteins. This review focuses on the expression, characterization, regulation, and mechanism of action of prostanoid receptors with particular emphasis on human isoforms.

Molecular analysis of the prostacyclin receptor's interaction with the PDZ1 domain of its adaptor protein PDZK1

The prostanoid prostacyclin, or prostaglandin I2, plays an essential role in many aspects of cardiovascular disease. The actions of prostacyclin are mainly mediated through its activation of the prostacyclin receptor or, in short, the IP. In recent studies, the cytoplasmic carboxy-terminal domain of the IP was shown to bind several PDZ domains of the multi-PDZ adaptor PDZK1. The interaction between the two proteins was found to enhance cell surface expression of the IP and to be functionally important in promoting prostacyclin-induced endothelial cell migration and angiogenesis. To investigate the interaction of the IP with the first PDZ domain (PDZ1) of PDZK1, we generated a nine residue peptide (KK(411)IAACSLC(417)) containing the seven carboxy-terminal amino acids of the IP and measured its binding affinity to a recombinant protein corresponding to PDZ1 by isothermal titration calorimetry. We determined that the IP interacts with PDZ1 with a binding affinity of 8.2 µM. Using the same technique, we also determined that the farnesylated form of carboxy-terminus of the IP does not bind to PDZ1. To understand the molecular basis of these findings, we solved the high resolution crystal structure of PDZ1 bound to a 7-residue peptide derived from the carboxy-terminus of the non-farnesylated form of IP ((411)IAACSLC(417)). Analysis of the structure demonstrates a critical role for the three carboxy-terminal amino acids in establishing a strong interaction with PDZ1 and explains the inability of the farnesylated form of IP to interact with the PDZ1 domain of PDZK1 at least in vitro.

Interaction of the human prostacyclin receptor with the PDZ adapter protein PDZK1: role in endothelial cell migration and angiogenesis

Prostacyclin is widely implicated in re-endothelialization and angiogenesis but through unknown mechanisms. Herein the HDL scavenger receptor class B, type 1 adapter PDZK1 was identified as a direct, functional interactant of the human prostacyclin receptor and was found to influence prostacyclin-mediated endothelial migration and in vitro angiogenesis.

Prostacyclin is increasingly implicated in re-endothelialization and angiogenesis but through largely unknown mechanisms. Herein the high-density lipoprotein (HDL) scavenger receptor class B, type 1 (SR-B1) adapter protein PDZ domain-containing protein 1 (PDZK1) was identified as an interactant of the human prostacyclin receptor (hIP) involving a Class I PDZ ligand at its carboxyl terminus and PDZ domains 1, 3, and 4 of PDZK1. Although the interaction is constitutive, it may be dynamically regulated following cicaprost activation of the hIP through a mechanism involving cAMP-dependent protein kinase (PK)A-phosphorylation of PDZK1 at Ser-505. Although PDZK1 did not increase overall levels of the hIP, it increased its functional expression at the cell surface, enhancing ligand binding and cicaprost-induced cAMP generation. Consistent with its role in re-endothelialization and angiogenesis, cicaprost activation of the hIP increased endothelial cell migration and tube formation/in vitro angiogenesis, effects completely abrogated by the specific IP antagonist RO1138452. Furthermore, similar to HDL/SR-B1, small interfering RNA (siRNA)-targeted disruption of PDZK1 abolished cicaprost-mediated endothelial responses but did not affect VEGF responses. Considering the essential role played by prostacyclin throughout the cardiovascular system, identification of PDZK1 as a functional interactant of the hIP sheds significant mechanistic insights into the protective roles of these key players, and potentially HDL/SR-B1, within the vascular endothelium.

Identification of a novel endoplasmic reticulum export motif within the eighth α-helical domain (α-H8) of the human prostacyclin receptor

The human prostacyclin receptor (hIP) undergoes agonist-dependent trafficking involving a direct interaction with Rab11a GTPase. The region of interaction was localised to a 14 residue Rab11a binding domain (RBD) within the proximal carboxyl-terminal (C)-tail domain of the hIP, consisting of Val(299)-Val(307) within the eighth helical domain (α-H8) adjacent to the palmitoylated residues at Cys(308)-Cys(311). However, the factors determining the anterograde transport of the newly synthesised hIP from the endoplasmic reticulum (ER) to the plasma membrane (PM) have not been identified. The aim of the current study was to identify the major ER export motif(s) within the hIP initially by investigating the role of Lys residues in its maturation and processing. Through site-directed and Ala-scanning mutational studies in combination with analyses of protein expression and maturation, functional analyses of ligand binding, agonist-induced intracellular signalling and confocal image analyses, it was determined that Lys(297), Arg(302) and Lys(304) located within α-H8 represent the critical determinants of a novel ER export motif of the hIP. Furthermore, while substitution of those critical residues significantly impaired maturation and processing of the hIP, replacement of the positively charged Lys with Arg residues, and vice versa, was functionally permissible. Hence, this study has identified a novel 8 residue ER export motif within the functionally important α-H8 of the hIP. This ER export motif, defined by "K/R(X)(4)K/R(X)K/R," has a strict requirement for positively charged, basic Lys/Arg residues at the 1st, 6th and 8th positions and appears to be evolutionarily conserved within IP sequences from mouse to man.

Interaction of the human prostacyclin receptor with Rab11: characterization of a novel Rab11 binding domain within alpha-helix 8 that is regulated by palmitoylation

The human prostacyclin receptor (hIP) undergoes agonist-induced internalization and subsequent recyclization in slowly recycling endosomes involving its direct physical interaction with Rab11a. Moreover, interaction with Rab11a localizes to a 22-residue putative Rab11 binding domain (RBD) within the carboxyl-terminal tail of the hIP, proximal to the transmembrane 7 (TM7) domain. Because the proposed RBD contains Cys(308) and Cys(311), in addition to Cys(309), that are known to undergo palmitoylation, we sought to identify the structure/function determinants of the RBD, including the influence of palmitoylation, on agonist-induced trafficking of the hIP. Through complementary approaches in yeast and mammalian cells along with computational structural studies, the RBD was localized to a 14-residue domain, between Val(299) and Leu(312), and proposed to be organized into an eighth alpha-helical domain (alpha-helix 8), comprising Val(299)-Val(307), adjacent to the palmitoylated residues at Cys(308)-Cys(311). From mutational and [(3)H]palmitate metabolic labeling studies, it is proposed that palmitoylation at Cys(311) in addition to agonist-regulated deacylation at Cys(309) > Cys(308) may dynamically position alpha-helix 8 in proximity to Rab11a, to regulate agonist-induced intracellular trafficking of the hIP. Moreover, Ala-scanning mutagenesis identified several hydrophobic residues within alpha-helix 8 as necessary for the interaction with Rab11a. Given the diverse membership of the G protein-coupled receptor superfamily, of which many members are also predicted to contain an alpha-helical 8 domain proximal to TM7 and, often, adjacent to palmitoylable cysteine(s), the identification of a functional role for alpha-helix 8, as exemplified as an RBD for the hIP, is likely to have broader significance for certain members of the superfamily.

Immature and mature species of the human Prostacyclin Receptor are ubiquitinated and targeted to the 26S proteasomal or lysosomal degradation pathways, respectively

Background

The human prostacyclin receptor (hIP) undergoes agonist-induced phosphorylation, desensitisation and internalisation and may be recycled to the plasma membrane or targeted for degradation by, as yet, unknown mechanism(s).

Results

Herein it was sought to investigate the turnover of the hIP under basal conditions and in response to cicaprost stimulation. It was established that the hIP is subject to low-level basal degradation but, following agonist stimulation, degradation is substantially enhanced. Inhibition of the lysosomal pathway prevented basal and agonist-induced degradation of the mature species of the hIP (46-66 kDa). Conversely, inhibition of the proteasomal pathway had no effect on levels of the mature hIP but led to time-dependent accumulation of four newly synthesised immature species (38-44 kDa). It was established that both the mature and immature species of the hIP may be polyubiquitinated and this modification may be required for lysosomal sorting of the mature, internalised receptors and for degradation of the immature receptors by the 26S proteasomes through the ER-associated degradation (ERAD) process, respectively. Moreover, these data substantially advance knowledge of the factors regulating processing and maturation of the hIP, a complex receptor subject to multiple post-translational modifications including N-glycosylation, phosphorylation, isoprenylation, palmitoylation, in addition to polyubiquitination, as determined herein.

Conclusion

These findings indicate that the hIP is post-translationally modified by ubiquitination, which targets the immature species to the 26S proteasomal degradation pathway and the mature species to the lysosomal degradation pathway.

Recycling of the human prostacyclin receptor is regulated through a direct interaction with Rab11a GTPase

The human prostacyclin receptor (hIP) undergoes agonist-induced internalization but the mechanisms regulating its intracellular trafficking and/or recycling to the plasma membrane are poorly understood. Herein, we conducted a yeast-two-hybrid screen to identify proteins interacting with the carboxyl-terminal (C)-tail domain of the hIP and discovered a novel interaction with Rab11a. This interaction was confirmed by co-immunoprecipitations in mammalian HEK293 and was augmented by cicaprost stimulation. The hIP co-localized to Rab11-containing recycling endosomes in both HEK293 and endothelial EA.hy 926 cells in a time-dependent manner following cicaprost stimulation. Moreover, over-expression of Rab11a significantly increased recycling of the hIP, while the dominant negative Rab11(S25N) impaired that recycling. Conversely, while the hIP co-localized to Rab4-positive endosomes in response to cicaprost, ectopic expression of Rab4a did not substantially affect overall recycling nor did Rab4a directly interact with the hIP. The specific interaction between the hIP and Rab11a was dependent on a 22 amino acid (Val(299)-Gln(320)) sequence within its C-tail domain and was independent of isoprenylation of the hIP. This study elucidates a critical role for Rab11a in regulating trafficking of the hIP and has identified a novel Rab11 binding domain (RBD) within its C-tail domain that is both necessary and sufficient to mediate interaction with Rab11a.

Agonist-dependent internalization and trafficking of the human prostacyclin receptor: a direct role for Rab5a GTPase

The human prostacyclin receptor (hIP) undergoes rapid agonist-induced internalization by largely unknown mechanism(s). Herein the involvement of Rab5 in regulating cicaprost-induced internalization of the hIP expressed in human embryonic kidney 293 cells was investigated. Over-expression of Rab5a significantly increased agonist-induced hIP internalization. Additionally, the hIP co-localized to Rab5a-containing endocytic vesicles in response to cicaprost stimulation and there was a coincident net translocation of Rab5 from the cytosol/soluble fraction of the cell. Co-immunoprecipitation studies confirmed a direct physical interaction between the hIP and Rab5a that was augmented by cicaprost. Whilst the dominant negative Rab5a(S34N) did not show decreased interaction with the hIP or fully impair internalization, it prevented hIP sorting to endocytic vesicles. Moreover, the GTPase deficient Rab5a(Q79L) significantly increased internalization and co-localized with the hIP in enlarged endocytic vesicles. While deletion of the carboxyl terminal (C)-tail domain of the hIP did not inhibit agonist-induced internalization, co-localization or co-immunoprecipitation with Rab5a per se, receptor trafficking was altered suggesting that it contains structural determinant(s) for hIP sorting post Rab5-mediated endocytosis. Taken together, data herein and in endothelial EA.hy 926 cells demonstrate a direct role for Rab5a in agonist-internalization and trafficking of the hIP and increases knowledge of the factors regulating prostacyclin signaling.

Lipid–protein interactions in GPCR-associated signaling

Signal transduction via G-protein-coupled receptors (GPCRs) is a fundamental pathway through which the functions of an individual cell can be integrated within the demands of a multicellular organism. Since this family of receptors first discovered, the proteins that constitute this signaling cascade and their interactions with one another have been studied intensely. In parallel, the pivotal role of lipids in the correct and efficient propagation of extracellular signals has attracted ever increasing attention. This is not surprising given that most of the signal transduction machinery is membrane-associated and therefore lipid-related. Hence, lipid-protein interactions exert a considerable influence on the activity of these proteins. This review focuses on the post-translational lipid modifications of GPCRs and G proteins (palmitoylation, myristoylation, and isoprenylation) and their significance for membrane binding, trafficking and signaling. Moreover, we address how the particular biophysical properties of different membrane structures may regulate the localization of these proteins and the potential functional consequences of this phenomenon in signal transduction. Finally, the interactions that occur between membrane lipids and GPCR effector enzymes such as PLC and PKC are also considered.

C-Terminal Prenylation of the CLN3 Membrane Glycoprotein Is Required for Efficient Endosomal Sorting to Lysosomes

Mutations in the polytopic lysosomal membrane glycoprotein CLN3 result in a severe neurodegenerative disorder. Previous studies identified two cytosolic signal structures contributing to lysosomal targeting. We now examined the role of glycosylation and the C-terminal CAAX motif in lysosomal transport of CLN3 in non-neuronal and neuronal cells. Mutational analysis revealed that in COS7 cells, CLN3 is glycosylated at asparagine residues 71 and 85. Both partially and non-glycosylated CLN3 were transported correctly to lysosomes. Mevalonate incorporation and farnesyltransferase inhibitor studies indicate that CLN3 is prenylated most likely at cysteine 435. Substitution of cysteine 435 reduced the steady-state level of CLN3 in lysosomes most likely because of impaired sorting in early endosomal structures, particularly in neuronal cells. Additionally, the cell surface expression of CLN3 was increased in the presence of farnesyltransferase inhibitors. Alteration of the spacing between the transmembrane domain and the CAAX motif or the substitution of the entire C-terminal domain of CLN3 with cytoplasmic tails of mannose 6-phosphate receptors have demonstrated the importance of the C-terminal domain of proper length and composition for exit of the endoplasmic reticulum. The data suggest that co-operative signal structures in different cytoplasmic domains of CLN3 are required for efficient sorting and for transport to the lysosome.

Human prostacyclin receptor structure and function from naturally-occurring and synthetic mutations

Prostacyclin (PGI2) is released by vascular endothelial cells and serves as a potent vasodilator, inhibitor of platelet aggregation (anti-thrombotic), and moderator of vascular smooth muscle cell proliferation-migration-differentiation (anti-atherosclerotic). These actions are mediated via a seven transmembrane-spanning G-protein coupled receptor (GPCR), known as the human prostacyclin receptor or hIP. Animal studies using prostacyclin receptor knock-out (IP-/-) mice have revealed increased propensities towards thrombosis, intimal hyperplasia, atherosclerosis, restenosis, as well as reperfusion injury. Of further importance has been the world-wide withdrawal of selective COX-2 inhibitors, due to their discriminating suppression of COX-2-derived PGI2 and its cardioprotective effects, leading to increased cardiovascular events, including myocardial infarction and thrombotic stroke. Over the last decade, mutagenesis studies of the IP receptor, in conjunction with in vitro functional assays and molecular modeling, have provided critical insights into the molecular mechanisms of both agonist binding and receptor activation. Most recently, the discovery of naturally-occurring and dysfunctional mutations within the hIP has provided additional insights into the proposed cardioprotective role of prostacyclin. The aim of this review is to summarize the most recent findings regarding hIP receptor structure-function that have developed through the study of both synthetic and naturally-occurring mutations.

Palmitoylation of the TPbeta isoform of the human thromboxane A2 receptor. Modulation of G protein: effector coupling and modes of receptor internalization

Palmitoylation is a prevalent feature amongst G protein-coupled receptors. In this study we sought to establish whether the TPα and TPβ isoforms of the human prostanoid thromboxane (TX) A₂ receptor (TP) are palmitoylated and to assess the functional consequences thereof. Consistent with the presence of three cysteines within its unique carboxyl-terminal domain, metabolic labelling and site-directed mutagenesis confirmed that TPβ is palmitoylated at Cys³⁴⁷ and, to a lesser extent, at Cys^373,377 whereas TPα is not palmitoylated. Impairment of palmitoylation did not affect TPβ expression or its ligand affinity. Conversely, agonist-induced [Ca²⁺]_i mobilization by TPβ^C347S and the non-palmitoylated TPβ^{C347,373,377S}, but not by TPβ^C373S or TPβ^C373,377S, was significantly reduced relative to the wild type TPβ suggesting that palmitoylation at Cys³⁴⁷ is specifically required for efficient Gq/phospholipase Cβ effector coupling. Furthermore, palmitoylation at Cys^373,377 is critical for TPβ internalization with TPβ^C373S, TPβ^C373,377S and TPβ^{C347,373,377S} failing to undergo either agonist-induced or temperature-dependent tonic internalization. On the other hand, whilst TPβ^C347S underwent reduced agonist-induced internalization, it underwent tonic internalization to a similar extent as TPβ. The deficiency in agonist-induced internalization by TPβ^C347S, but not by TPβ^C373,377 nor TPβ^{C347,373,377S}, was overcome by over-expression of either β-arrestin1 or β-arrestin2. Taken together, data herein suggest that whilst palmitoylation of TPβ at Cys^373,377 is critical for both agonist- and tonic-induced internalization, palmitoylation at Cys³⁴⁷ has a role in determining which pathway is followed, be it by the β-arrestin-dependent agonist-induced pathway or by the β-arrestin-independent tonic internalization pathway.

Versatility and differential roles of cysteine residues in human prostacyclin receptor structure and function

Prostacyclin plays important roles in vascular homeostasis, promoting vasodilatation and inhibiting platelet thrombus formation. Previous studies have shown that three of six cytoplasmic cysteines, particularly those within the C-terminal tail, serve as important lipidation sites and are differentially conjugated to palmitoyl and isoprenyl groups (Miggin, S. M., Lawler, O. A., and Kinsella, B. T. (2003) J. Biol. Chem. 278, 6947-6958). Here we report distinctive roles for extracellular- and transmembrane-located cysteine residues in human prostacyclin receptor structure-function. Within the extracellular domain, all cysteines (4 of 4) appear to be involved in disulfide bonding interactions (i.e. a highly conserved Cys-92-Cys-170 bond and a putative non-conserved Cys-5-Cys-165 bond), and within the transmembrane (TM) region there are several cysteines (3 of 8) that maintain critical hydrogen bonding interactions (Cys-118 (TMIII), Cys-251 (TMVI), and Cys-202 (TMV)). This study highlights the necessity of sulfhydryl (SH) groups in maintaining the structural integrity of the human prostacyclin receptor, as 7 of 12 extracellular and transmembrane cysteines studied were found to be differentially indispensable for receptor binding, activation, and/or trafficking. Moreover, these results also demonstrate the versatility and reactivity of these cysteine residues within different receptor environments, that is, extracellular (disulfide bonds), transmembrane (H-bonds), and cytoplasmic (lipid conjugation).

Homologous desensitization of signalling by the beta (β) isoform of the human thromboxane A2 receptor

Thromboxane (TX) A(2) is a potent stimulator of platelet activation/aggregation and smooth muscle contraction and contributes to a variety of pathologies within the vasculature. In this study, we investigated the mechanism whereby the cellular responses to TXA(2) mediated through the TPbeta isoform of the human TXA(2) receptor (TP) are dynamically regulated by examining the mechanism of agonist-induced desensitization of intracellular signalling and second messenger generation by TPbeta. It was established that TPbeta is subject to profound agonist-induced homologous desensitization of signalling (intracellular calcium mobilization and inositol 1,3,5 trisphosphate generation) in response to stimulation with the TXA(2) mimetic U46619 and this occurs through two key mechanisms: TPbeta undergoes partial agonist-induced desensitization that occurs through a GF 109203X-sensitive, protein kinase (PK)C mechanism whereby Ser(145) within intracellular domain (IC)(2) has been identified as the key phospho-target. In addition, TPbeta also undergoes more profound and sustained agonist-induced desensitization involving G protein-coupled receptor kinase (GRK)2/3-phosphorylation of both Ser(239) and Ser(357) within its IC(3) and carboxyl-terminal C-tail domains, respectively. Inhibition of phosphorylation of either Ser(239) or Ser(357), through site directed mutagenesis, impaired desensitization while mutation of both Ser(239) and Ser(357) almost completely abolished desensitization of signalling, GRK phosphorylation and beta-arrestin association, thereby blocking TPbeta internalization. These data suggest a model whereby agonist-induced PKC phosphorylation of Ser(145) partially impairs. TPbeta signalling while GRK2/3 phosphorylation at both Ser(239) and Ser(357) within its IC(3) and C-tail domains, respectively, sterically inhibits G-protein coupling, profoundly desensitizing signalling, and promotes beta-arrestin association and, in turn, facilitates TPbeta internalization. Thromboxane (TX) A(2) is a potent stimulator of platelet aggregation and smooth muscle contraction and contributes to a variety of vascular pathologies. Herein the mechanism whereby the cellular responses to TXA(2) mediated through the TPbeta isoform of the human TXA(2) receptor (TP) are dynamically regulated was investigated by examining the mechanism of its agonist-induced desensitization of intracellular signalling and second messenger generation. TPbeta is subject to profound agonist-induced homologous desensitization of signalling (intracellular calcium mobilization and inositol 1,3,5 trisphosphate generation) in response to stimulation with the TXA(2) mimetic U46619 and this occurs through two key mechanisms: TPbeta undergoes partial agonist-induced desensitization that occurs through a GF 109203X-sensitive, protein kinase (PK)C mechanism whereby Ser(145) within intracellular domain (IC)(2) was identified as the key phospho-target. In addition, TPbeta also undergoes more profound and sustained agonist-induced desensitization involving G protein-coupled receptor kinase (GRK)2/3-phosphorylation of both Ser(239) and Ser(357) within its IC(3) and carboxyl-terminal C-tail domains, respectively. Inhibition of phosphorylation of either Ser(239) or Ser(357), through site directed mutagenesis, impaired desensitization while mutation of both Ser(239) and Ser(357) almost completely abolished desensitization of signalling, GRK phosphorylation and beta-arrestin association, thereby blocking TPbeta internalization. These data suggest a model whereby agonist-induced PKC phosphorylation of Ser(145) partially impairs TPbeta signalling while GRK2/3 phosphorylation at both Ser(239) and Ser(357) within its IC(3) and C-tail domains, respectively, sterically inhibits G-protein coupling, profoundly desensitizing signalling, and promotes beta-arrestin association and, in turn, facilitates TPbeta internalization.

Internalization and recycling of the human prostacyclin receptor is modulated through its isoprenylation-dependent interaction with the delta subunit of cGMP phosphodiesterase 6

Prostacyclin, the major cyclooxygenase-derived product of arachidonic acid formed in the vasculature, mediates its potent anti-thrombotic and anti-proliferative effects through its G protein-coupled receptor (GPCR) termed the IP. Unlike many GPCRs, agonist-induced internalization of the IP occurs in an arrestin/GPCR kinase-independent manner. However, deletion of the IP COOH-terminal region prevented internalization suggesting that protein interactions at this region are involved in IP regulation. Using the COOH-terminal region of IP as bait we identified the delta subunit of cGMP phosphodiesterase 6 (PDE6delta) as a novel hIP-interacting protein in two independent yeast two-hybrid screens. Interaction of IP and PDE6delta was confirmed by co-immunoprecipitation in HEK293 cells, and in HEPG2 cells, which endogenously express neither IP nor PDE6delta. IP isoprenylation was critical for this interaction, as PDE6delta was unable to associate with an isoprenylation-deficient mutant IP (IPSSLC). PDE6delta overexpression altered the temporal pattern of agonist-induced internalization of IP, but not IPSSLC, in HEPG2 cells, increasing initial internalization but facilitating the return of IP to the cell surface despite the continued presence of agonist. Depletion of PDE6delta using short interfering RNA abolished cicaprost-induced IP internalization in human aortic smooth muscle cells. Recycling of IP, but not IPSSLC, upon agonist removal was facilitated by overexpression of PDE6delta. Thus PDE6delta interacts specifically with IP to modulate receptor trafficking.

The effect of the farnesyl protein transferase inhibitor SCH66336 on isoprenylation and signalling by the prostacyclin receptor

Like Ras, farnesylation of the IP (prostacyclin receptor) is required for its efficient intracellular signalling, and hence the IP represents a potential target for inhibition by FTIs [FTase (farnesyl protein transferase) inhibitors]. Herein, the effect of SCH66336 on the isoprenylation and function of the human and mouse IPs overexpressed in human embryonic kidney 293 cells, and by the IP endogenously expressed in human erythroleukaemia cells, was investigated. SCH66336 yielded concentration-dependent decreases in IP-mediated cAMP generation (IC50 0.27-0.62 nM), [Ca2+]i mobilization (IC50 26.6-48.3 nM) and IP internalization, but had no effect on signalling by the non-isoprenylated beta2 adrenergic receptor or b isoform of the TP (prostanoid thromboxane A2 receptor). Additionally, SCH66336 impaired IP-mediated crossdesensitization of TPa signalling (IC50 56.1 nM) and reduced farnesylation of the molecular chaperone protein HDJ-2 (IC50 3.1 nM). To establish whether farnesylation of the IP is inhibited and/or whether its 'CaaX motif' might undergo alternative geranylgeranylation in the presence of SCH66336, a series of chimaeric Ha (Harvey)-Ras fusions were generated by replacing its CaaX motif (-CVLS) with that of the IP (-CSLC) or, as controls, of Ki (Kirsten)-Ras 4B (-CVIM) or Rac 1 (-CVLL). Whereas SCH66336 had no effect on Ha-RasCVLL isoprenylation in vitro or in whole cells, it supported alternative geranylgeranylation of Ha-RasCVIM, but completely impaired isoprenylation of both Ha-RasCVLS and Ha-RasCSLC. These data confirm that the -CSLC motif of the IP is a direct target for inhibition by the FTI SCH66336, and in the presence of strong FTase inhibition, the IP does not undergo compensatory geranylgeranylation

Pharmacology and signaling of prostaglandin receptors: multiple roles in inflammation and immune modulation

Prostaglandins are lipid-derived autacoids that modulate many physiological systems including the CNS, cardiovascular, gastrointestinal, genitourinary, endocrine, respiratory, and immune systems. In addition, prostaglandins have been implicated in a broad array of diseases including cancer, inflammation, cardiovascular disease, and hypertension. Prostaglandins exert their effects by activating rhodopsin-like seven transmembrane spanning G protein-coupled receptors (GPCRs). The prostanoid receptor subfamily is comprised of eight members (DP, EP1-4, FP, IP, and TP), and recently, a ninth prostaglandin receptor was identified-the chemoattractant receptor homologous molecule expressed on Th2 cells (CRTH2). The precise roles prostaglandin receptors play in physiologic and pathologic settings are determined by multiple factors including cellular context, receptor expression profile, ligand affinity, and differential coupling to signal transduction pathways. This complexity is highlighted by the diverse and often opposing effects of prostaglandins within the immune system. In certain settings, prostaglandins function as pro-inflammatory mediators, but in others, they appear to have anti-inflammatory properties. In this review, we will discuss the pharmacology and signaling of the nine known prostaglandin GPCRs and highlight the specific roles that these receptors play in inflammation and immune modulation.

Investigation of the effect of the farnesyl protein transferase inhibitor R115777 on isoprenylation and intracellular signalling by the prostacyclin receptor

The human (h) and mouse (m) prostacyclin receptors (IPs) undergo isoprenylation through attachment of a C-15 farnesyl moiety within their conserved carboxyl terminal -CSLC sequences. Herein, the effects of a novel farnesyl transferase inhibitor R115777 on signalling by the hIP and mIP, overexpressed in human embryonic kidney 293 cells, and by the hIP endogenously expressed in human erythroleukaemia cells were investigated. R115777 significantly impaired IP-mediated cyclic AMP generation (IC(50) 0.37-0.60 nm) and intracellular calcium ([Ca(2+)](i)) mobilization (IC(50) 37-65 nm), but had no effect on signalling by the control nonisoprenylated beta(2) adrenergic receptor or the alpha or beta isoforms of the human thromboxane A(2) receptor (TP). Additionally, R115777 significantly reduced IP-mediated cross-desensitization of signalling by the TP alpha, but not by the TP beta, isoform of the human TP and impaired the farnesylation-dependent processing of the chaperone HDJ-2 protein (IC(50) 4.5 nm). Furthermore, R115777 fully impaired isoprenylation of both the Ha-Ras(WT) and Ha-Ras(CSLC) in vitro and in whole cells confirming that, unlike N-Ras and Ki-Ras, the -CSLC motif associated with the IP cannot support alternative geranylgeranylation in the presence of R115777 and does not act as a substrate for geranylgeranyl transferase 1 in vitro or in whole cells. In conclusion, these data confirm that R115777 potently impairs IP isoprenylation and signalling, and suggest that clinically it may not only target Ras proteins but may also disrupt IP isoprenylation, events which could impact on physiologic processes in which prostacyclin and its receptor are implicated.

Effect of the statin atorvastatin on intracellular signalling by the prostacyclin receptor in vitro and in vivo

Prostacyclin plays a central role within the vasculature. We have previously established that the prostacyclin receptor (IP) undergoes isoprenylation, a lipid modification obligate for its function. The aim of the current study was to investigate the effect of the hydroxy methyl glutaryl co-enzyme A reductase inhibitor atorvastatin on signalling and function of the IP expressed in mammalian whole cells and in platelets isolated from patients undergoing therapeutic intervention with atorvastatin. Initially, the effect of atorvastatin on signalling by the human (h) and mouse (m) IP overexpressed in human embryonic kidney 293 cells and the hIP endogenously expressed in human erythroleukaemic 92.1.7 cells was investigated. Atorvastatin significantly reduced IP-mediated cAMP generation (IC(50) 6.6-11.1 microm) and [Ca(2+)](i) mobilization (IC(50) 7.2-16.4 microm) in a concentration-dependent manner, but had no effect on signalling by the nonisoprenylated beta(2) adrenergic receptor or the alpha or beta isoforms of the human thromboxane A(2) receptor (TP). Moreover, atorvastatin significantly reduced IP-mediated crossdesensitization of signalling by TP alpha (IC(50) 10.4 microm), but not by TP beta. In contrast to the whole-cell data, atorvastatin therapy did not interfere with IP-mediated cAMP generation or IP-induced inhibition of TP-mediated aggregation of platelets isolated from human volunteers undergoing therapeutic intervention with atorvastatin (10-80 mg per daily dose). In conclusion, while data generated in whole cells indicated that atorvastatin significantly impairs signalling by both the hIP and mP, the in vivo clinical data indicated that, at the administered therapeutic dose, atorvastatin does not significantly compromise IP signalling and function in humans.

Palmitoylation of the human prostacyclin receptor. Functional implications of palmitoylation and isoprenylation

We have previously established that isoprenylation of the prostacyclin receptor (IP) is required for its efficient G protein coupling and effector signaling (Hayes, J. S., Lawler, O. A., Walsh, M. T., and Kinsella, B. T. (1999) J. Biol. Chem. 274, 23707-23718). In the present study, we sought to investigate whether the IP may actually be subject to palmitoylation in addition to isoprenylation and to establish the functional significance thereof. The human (h) IP was efficiently palmitoylated at Cys(308) and Cys(311), proximal to transmembrane domain 7 within its carboxyl-terminal (C)-tail domain, whereas Cys(309) was not palmitoylated. The isoprenylation-defective hIP(SSLC) underwent palmitoylation but did not efficiently couple to G(s) or G(q), confirming that isoprenylation is required for G protein coupling. Deletion of C-tail sequences distal to Val(307) generated hIP(Delta307) that was neither palmitoylated nor isoprenylated and did not efficiently couple to G(s) or to G(q), whereas hIP(Delta312) was palmitoylated and ably coupled to both effector systems. Conversion of Cys(308), Cys(309), Cys(311), Cys(308,309), or Cys(309,311) to corresponding Ser residues, while leaving the isoprenylation CAAX motif intact, did not affect hIP coupling to G(s) signaling, whereas mutation of Cys(308,311) and Cys(308,309,311) abolished signaling, indicating that palmitoylation of either Cys(308) or Cys(311) is sufficient to maintain functional G(s) coupling. Although mutation of Cys(309) and Cys(311) did not affect hIP-mediated G(q) coupling, mutation of Cys(308) abolished signaling, indicating a specific requirement for palmitoylation of Cys(308) for G(q) coupling. Consistent with this, neither hIP(C308S,C309S), hIP(C308S,C311S), nor hIP(C308S,C309S,C311S) coupled to G(q). Taken together, these data confirm that the hIP is isoprenylated and palmitoylated, and collectively these modifications modulate its G protein coupling and effector signaling. We propose that through lipid modification followed by membrane insertion, the C-tail domain of the IP may contain a double loop structure anchored by the dynamically regulated palmitoyl groups proximal to transmembrane domain 7 and by a distal farnesyl isoprenoid permanently attached to its carboxyl terminus.

Investigation of the mechanisms of G protein: effector coupling by the human and mouse prostacyclin receptors. Identification of critical species-dependent differences

We recently identified a novel mechanism explaining how the mouse (m) prostacyclin receptor (IP) couples to Galpha(s), Galpha(i), and Galpha(q) (Lawler, O. A., Miggin, S. M., and Kinsella, B. T. (2001) J. Biol. Chem. 276, 33596-33607) whereby mIP coupling to Galpha(i) and Galpha(q) is dependent on its initial coupling to Galpha(s) and subsequent phosphorylation by cAMP-dependent protein kinase A (PKA) on Ser(357). In the current study, the generality of that mechanism was investigated by examining the G protein coupling specificity of the human (h) IP. The hIP efficiently coupled to Galpha(s)/adenylyl cyclase and to Galpha(q)/phospholipase C activation but failed to couple to Galpha(i). Coupling of the hIP to Galpha(q), or indeed to Galpha(s) or Galpha(i), was unaffected by the PKA or protein kinase C (PKC) inhibitors H-89 and GF 109203X, respectively. Thus, mIP and hIP exhibit essential differences in their coupling to Galpha(i) and in their dependence on PKA in regulating their coupling to Galpha(q). Analysis of their primary sequences revealed that the critical PKA phosphorylation site within the mIP, at Ser(357), is replaced by a PKC site within the hIP, at Ser(328). Conversion of the PKC site of the hIP to a PKA site generated hIP(QL325,326RP) that efficiently coupled to Galpha(s) and to Galpha(i) and Galpha(q); coupling of hIP(QL325,326RP) to Galpha(i) but not to Galpha(s) or Galpha(q) was inhibited by H-89. Abolition of the PKC site of the hIP generated hIP(S328A) that efficiently coupled to Galpha(s) and Galpha(q) but failed to couple to Galpha(i). Finally, conversion of the PKA site at Ser(357) within the mIP to a PKC site generated mIP(RP354,355QL) that efficiently coupled to Galpha(s) but not to Galpha(i) or Galpha(q). Collectively, our data highlight critical differences in signaling by the mIP and hIP that are regulated by their differential phosphorylation by PKA and PKC together with contextual sequence differences surrounding those sites.