Functional selectivity of adenosine A1 receptor ligands?

The concept of functional selectivity offers great potential for the development of drugs that selectively activate a specific intracellular signaling pathway. During the last few years, it has become possible to systematically analyse compound libraries on G protein-coupled receptors (GPCRs) for this ‘biased’ form of signaling. We screened over 800 compounds targeting the class of adenosine A₁ receptors using a β-arrestin-mediated signaling assay in U2OS cells as a G protein-independent readout for GPCR activation. A selection of compounds was further analysed in a G protein-mediated GTPγS assay. Additionally, receptor affinity of these compounds was determined in a radioligand binding assay with the agonist [³H]CCPA. Of all compounds tested, only LUF5589 9 might be considered as functionally selective for the G protein-dependent pathway, particularly in view of a likely overestimation of β-arrestin signaling in the U2OS cells. Altogether, our study shows that functionally selective ligands for the adenosine A₁ receptor are rare, if existing at all. A thorough analysis of biased signaling on other GPCRs also reveals that only very few compounds can be considered functionally selective. This might indicate that the concept of functional selectivity is less common than speculated.     

Dynamic phospholipid signaling by G protein-coupled receptors

G protein-coupled receptors (GPCRs) control a variety of fundamental cellular processes by regulating phospholipid signaling pathways. Essential for signaling by a large number of receptors is the hydrolysis of the membrane phosphoinositide PIP₂ by phospholipase C (PLC) into the second messengers IP₃ and DAG. Many receptors also stimulate phospholipase D (PLD), leading to the generation of the versatile lipid, phosphatidic acid. Particular PLC and PLD isoforms take differential positions in receptor signaling and are additionally regulated by small GTPases of the Ras, Rho and ARF families. It is now recognized that the PLC substrate, PIP₂, has signaling capacity by itself and can, by direct interaction, affect the activity and subcellular localization of PLD and several other proteins. As expected, the synthesis of PIP₂ by phosphoinositide 5-kinases is tightly regulated as well. In this review, we present an overview of how these signaling pathways are governed by GPCRs, explain the molecular basis for the spatially and temporally organized, highly dynamic quality of phospholipid signaling, and point to the functional connection of the pathways.     

Complementary roles of the DRY motif and C-terminus tail of GPCRS for G protein coupling and beta-arrestin interaction

β-arrestin mediates the desensitization of GPCRs and acts as an adaptor molecule to recruit the receptor complex to clathrin-rich regions. Class-A GPCRs subsequently dissociate from β-arrestin but class-B GPCRs internalize with β-arrestin in the endocytic vesicles. Here the dopamine D₂ and D₃ receptors, which have similar structural features but different intracellular trafficking properties, were used in an attempt to better understand the structural requirements for the classification of GPCRs. The C-terminus tail of the vasopressin type-2 receptor was added to the ends of D₂R and D₃R to increase their affinity to β-arrestin. A point mutation was introduced into the DRY motif to change their basal activation levels. Among a battery of constructs in which the C-terminus tail and/or DRY motif was altered, class-B behavior was observed with the constructs whose affinities for β-arrestin were increased complementarily and their signaling was either maintained or regained. In conclusion, the DRY motif and C-terminal tail of the GPCRs determine complementarily their intracellular trafficking behavior by regulating the affinity to β-arrestin and G protein coupling.     

A Conserved Protonation-Induced Switch can Trigger “Ionic-Lock” Formation in Adrenergic Receptors

The mechanism of signal transduction in G-protein-coupled receptors (GPCRs) is a crucial step in cell signaling. However, the molecular details of this process are still largely undetermined. Carrying out submicrosecond molecular dynamics simulations of β-adrenergic receptors, we found that cooperation between a number of highly conserved residues is crucial to alter the equilibrium between the active state and the inactive state of diffusible ligand GPCRs. In particular, “ionic-lock” formation in β-adrenergic receptors is directly correlated with the protonation state of a highly conserved aspartic acid residue [Asp(2.50)] even though the two sites are located more than 20 Å away from each other. Internal polar residues, acting as local microswitches, cooperate to propagate the signal from Asp(2.50) to the G-protein interaction site at the helix III-helix VI interface. Evolutionarily conserved differences between opsin and non-opsin GPCRs in the surrounding of Asp(2.50) influence the acidity of this residue and can thus help in rationalizing the differences in constitutive activity of class A GPCRs.     

A yeast screening method to decipher the interaction between the adenosine A2B receptor and the C-terminus of different G protein α-subunits

The expression of human G protein-coupled receptors (GPCRs) in Saccharomyces cerevisiae containing chimeric yeast/mammalian G_α subunits provides a useful tool for the study of GPCR activation. In this study, we used a one-GPCR-one-G protein yeast screening method in combination with molecular modeling and mutagenesis studies to decipher the interaction between GPCRs and the C-terminus of different α-subunits of G proteins. We chose the human adenosine A_2B receptor (hA_2BR) as a paradigm, a typical class A GPCR that shows promiscuous behavior in G protein coupling in this yeast system. The wild-type hA_2BR and five mutant receptors were expressed in 8 yeast strains with different humanized G proteins, covering the four major classes: G_αi, G_αs, G_αq, and G_α12. Our experiments showed that a tyrosine residue (Y) at the C-terminus of the G_α subunit plays an important role in controlling the activation of GPCRs. Receptor residues R103^3.50 and I107^3.54 are vital too in G protein-coupling and the activation of the hA_2BR, whereas L213^IL3 is more important in G protein inactivation. Substitution of S235^6.36 to alanine provided the most divergent G protein-coupling profile. Finally, L236^6.37 substitution decreased receptor activation in all G protein pathways, although to a different extent. In conclusion, our findings shed light on the selectivity of receptor/G protein coupling, which may help in further understanding GPCR signaling.     

The G protein Gαs acts as a tumor suppressor in sonic hedgehog signaling-driven tumorigenesis

G protein-coupled receptors (GPCRs) are critical players in tumor growth and progression. The redundant roles of GPCRs in tumor development confound effective treatment; therefore, targeting a single common signaling component downstream of these receptors may be efficacious. GPCRs transmit signals through heterotrimeric G proteins composed of Gα and Gβγ subunits. Hyperactive Gα_s signaling can mediate tumor progression in some tissues; however, recent work in medulloblastoma and basal cell carcinoma revealed that Gα_s can also function as a tumor suppressor in neoplasms derived from ectoderm cells including neural and epidermal stem/progenitor cells. In these stem-cell compartments, signaling through Gα_s suppresses self-renewal by inhibiting the Sonic Hedgehog (SHH) and Hippo pathways. The loss of GNAS, which encodes Gα_s, leads to activation of these pathways, over-proliferation of progenitor cells, and tumor formation. Gα_s activates the cAMP-dependent protein kinase A (PKA) signaling pathway and inhibits activation of SHH effectors Smoothened-Gli. In addition, Gα_s-cAMP-PKA activation negatively regulates the Hippo pathway by blocking the NF2-LATS1/2-Yap signaling. In this review, we will address the novel function of the signaling network regulated by Gα_s in suppression of SHH-driven tumorigenesis and the therapeutic approaches that can be envisioned to harness this pathway to inhibit tumor growth and progression.     

Functional studies with membrane-bound and detergent-solubilized α2-adrenergic receptors expressed in Sf9 cells

A chip-based biosensor technology using surface plasmon resonance (SPR) was developed for studying the interaction of ligands and G protein-coupled receptors (GPCRs). GPCRs, the fourth largest superfamily in the human genome, are the largest class of targets for drug discovery.We have expressed the three subtypes of α₂-adrenergic receptor (α₂-AR), a prototypical GPCR as functional fusion proteins in baculovirus-infected insect cells. The localization of the expressed receptor was observed in intracellular organelles, as detected by eGFP fluorescence. In addition, the deletion mutants of α_2B-AR, with a deletion in the 3rd intracellular loop, exhibited unaltered K_d values and enhanced stability, thus making them more promising candidates for crystallization. SPR demonstrated that small molecule ligands can bind the detergent-solubilized receptor, thus proving that α₂-AR is active even in a lipid-free environment. The K_d values obtained from the biosensor analysis and traditional ligand binding studies correlate well with each other. This is the first demonstration of the binding of a small molecule to the detergent-solubilized state of α₂-ARs and interaction of low-molecular mass-ligands in real time in a label-free environment. This technology will also allow the development of high throughput platform for screening a large number of compounds for generation of leads.     

METHIONINE PROXIMITY ASSAY,A NOVEL METHOD FOR EXPLORING PEPTIDE LIGAND–RECEPTOR INTERACTION

ABSTRACT

Probing G-protein coupled receptor (GPCR) structures is a priority in the functional and structural understanding of GPCRs. In the past, we have used several approaches around photoaffinity labeling in order to establish contact points between peptide ligands and their cognate receptors. Such contact points are helpful to build reality based molecular models of GPCRs and to elucidate their activation mechanisms. Most studies of peptidergic GPCRs have been done with photolabeling peptides containing the benzophenone moiety as a reputedly non-selective probe. However our recent results are now showing that p-benzoylphenylalanine (Bpa) has some selectivity for Met residues in the receptor protein, reducing the accuracy of this method. Turning a problem into an asset, modified analogues of Bpa, e.g. p,?p″-nitrobenzoylphenylalanine (NO₂Bpa), display increased selectivity for such Met residues. It means a photoprobe containing such modified benzophenone-moieties does not label a receptor protein unless a Met residue is in the immediate vicinity. This unique property allows us to propose and show the feasibility and utility of a new method for scanning the contact areas of peptidergic GPCRs, the Methionine Proximity Assay (MPA). Putative contact residues of the receptor are exchanged to Met residues by site-directed mutagenesis and are subjected to photoaffinity labeling with such modified benzophenone-containing peptides. Successful incorporation indicates physical proximity of those residues. This principle is established and explored with benzophenone-containing analogues of angiotensin II and the two known human angiotensin II receptors AT₁ and AT₂, determining contact points in both receptors. This approach has several important advantages over other scanning approaches, e.g., the SCAM procedure, since the MPA-method can be used in the hydrophobic core of receptors.     

Extracellular-derived calcium does not initiate in vivo neurotransmission involving docosahexaenoic acid

In vitro studies show that docosahexaenoic acid (DHA) can be released from membrane phospholipid by Ca²⁺-independent phospholipase A₂ (iPLA₂), Ca²⁺-independent plasmalogen PLA₂ or secretory PLA_{2 (sPLA2)}, but not by Ca²⁺-dependent cytosolic PLA₂ (cPLA2), which selectively releases arachidonic acid (AA). Since glutamatergic NMDA (N-methyl-D-aspartate) receptor activation allows extracellular Ca²⁺ into cells, we hypothesized that brain DHA signaling would not be altered in rats given NMDA, to the extent that in vivo signaling was mediated by Ca²⁺-independent mechanisms. Isotonic saline, a subconvulsive dose of NMDA (25 mg/kg), MK-801, or MK-801 followed by NMDA was administered i.p. to unanesthetized rats. Radiolabeled DHA or AA was infused intravenously and their brain incorporation coefficients k*, measures of signaling, were imaged with quantitative autoradiography. NMDA or MK-801 compared with saline did not alter k* for DHA in any of 81 brain regions examined, whereas NMDA produced widespread and significant increments in k* for AA. In conclusion, in vivo brain DHA but not AA signaling via NMDA receptors is independent of extracellular Ca²⁺ and of cPLA₂. DHA signaling may be mediated by iPLA₂, plasmalogen PLA₂, or other enzymes insensitive to low concentrations of Ca²⁺. Greater AA than DHA release during glutamate-induced excitotoxicity could cause brain cell damage.     

Use of Enzymatic Biosensors to Quantify Endogenous ATP or H2O2 in the Kidney

Enzymatic microelectrode biosensors have been widely used to measure extracellular signaling in real-time. Most of their use has been limited to brain slices and neuronal cell cultures. Recently, this technology has been applied to the whole organs. Advances in sensor design have made  possible the measuring of cell signaling in blood-perfused in vivo kidneys. The present protocols list the steps needed to measure ATP and H₂O₂ signaling in the rat kidney interstitium. Two separate sensor designs are used for the ex vivo and in vivo protocols. Both types of sensor are coated with a thin enzymatic biolayer on top of a permselectivity layer to give fast responding, sensitive and selective biosensors. The permselectivity layer protects the signal from the interferents in biological tissue, and the enzymatic layer utilizes the sequential catalytic reaction of glycerol kinase and glycerol-3-phosphate oxidase in the presence of ATP to produce H₂O₂. The set of sensors used for the ex vivo studies further detected analyte by oxidation of H₂O₂ on a platinum/iridium (Pt-Ir) wire electrode. The sensors for the in vivo studies are instead based on the reduction of H₂O₂ on a mediator coated gold electrode designed for blood-perfused tissue. Final concentration changes are detected by real-time amperometry followed by calibration to known concentrations of analyte. Additionally, the specificity of the amperometric signal can be confirmed by the addition of enzymes such as catalase and apyrase that break down H₂O₂ and ATP correspondingly. These sensors also rely heavily on accurate calibrations before and after each experiment. The following two protocols establish the study of real-time detection of ATP and H₂O₂ in kidney tissues, and can be further modified to extend the described method for use in other biological preparations or whole organs.     

Hydrogen peroxide primes heart regeneration with a derepression mechanism

While the adult human heart has very limited regenerative potential, the adult zebrafish heart can fully regenerate after 20% ventricular resection. Although previous reports suggest that developmental signaling pathways such as FGF and PDGF are reused in adult heart regeneration, the underlying intracellular mechanisms remain largely unknown. Here we show that H₂O₂ acts as a novel epicardial and myocardial signal to prime the heart for regeneration in adult zebrafish. Live imaging of intact hearts revealed highly localized H₂O₂ (∼30 μM) production in the epicardium and adjacent compact myocardium at the resection site. Decreasing H₂O₂ formation with the Duox inhibitors diphenyleneiodonium (DPI) or apocynin, or scavenging H₂O₂ by catalase overexpression markedly impaired cardiac regeneration while exogenous H₂O₂ rescued the inhibitory effects of DPI on cardiac regeneration, indicating that H₂O₂ is an essential and sufficient signal in this process. Mechanistically, elevated H₂O₂ destabilized the redox-sensitive phosphatase Dusp6 and hence increased the phosphorylation of Erk1/2. The Dusp6 inhibitor BCI achieved similar pro-regenerative effects while transgenic overexpression of dusp6 impaired cardiac regeneration. H₂O₂ plays a dual role in recruiting immune cells and promoting heart regeneration through two relatively independent pathways. We conclude that H₂O₂ potentially generated from Duox/Nox2 promotes heart regeneration in zebrafish by unleashing MAP kinase signaling through a derepression mechanism involving Dusp6.     

A ménage à trois made in heaven: G-protein-coupled receptors, lipids and TRP channels

Recent technical and conceptual advances in lipid analysis have given us a glimpse into the true versatility of the lipidome and the complexity of lipid signaling species. Progress alike in protein chemistry and genetics has presented us with new signal pathways and molecular mechanisms for the lipid actions. G-protein-coupled receptors (GPCR) appear to play a central role in the regulation of many lipid signals and are also themselves targets for some of these. TRP channels have recently been acknowledged as one of the most important GPCR effectors; in many cases the signals from GPCRs to TRPs are mediated via lipid signals. This review aims at presenting a view into the complex lipid signaling networks, their possible regulation by GPCRs and the signals transmitted to the TRP channels. Critical views and possible shortcomings in the composition of the studies are also presented.     

Microbial 2-Cys Peroxiredoxins: Insights into Their Complex Physiological Roles

The peroxiredoxins (Prxs) constitute a very large and highly conserved family of thiol-based peroxidases that has been discovered only very recently. We consider here these enzymes through the angle of their discovery, and of some features of their molecular and physiological functions, focusing on complex phenotypes of the gene mutations of the 2-Cys Prxs subtype in yeast. As scavengers of the low levels of H₂O₂ and as H₂O₂ receptors and transducers, 2-Cys Prxs have been highly instrumental to understand the biological impact of H₂O₂, and in particular its signaling function. 2-Cys Prxs can also become potent chaperone holdases, and unveiling the in vivo relevance of this function, which is still not established, should further increase our knowledge of the biological impact and toxicity of H₂O₂. The diverse molecular functions of 2-Cys Prx explain the often-hard task of relating them to peroxiredoxin genes phenotypes, which underscores the pleiotropic physiological role of these enzymes and complex biologic impact of H₂O₂.     

Agonist-induced conformational changes in bovine rhodopsin: insight into activation of G-protein-coupled receptors

Activation of G-protein-coupled receptors (GPCRs) is initiated by conformational changes in the transmembrane (TM) helices and the intra- and extracellular loops induced by ligand binding. Understanding the conformational changes in GPCRs leading to activation is imperative in deciphering the role of these receptors in the pathology of diseases. Since the crystal structures of activated GPCRs are not yet available, computational methods and biophysical techniques have been used to predict the structures of GPCR active states. We have recently applied the computational method LITiCon to understand the ligand-induced conformational changes in β₂-adrenergic receptor by ligands of varied efficacies. Here we report a study of the conformational changes associated with the activation of bovine rhodopsin for which the crystal structure of the inactive state is known. Starting from the inactive (dark) state, we have predicted the TM conformational changes that are induced by the isomerization of 11-cis retinal to all-trans retinal leading to the fully activated state, metarhodopsin II. The predicted active state of rhodopsin satisfies all of the 30 known experimental distance constraints. The predicted model also correlates well with the experimentally observed conformational switches in rhodopsin and other class A GPCRs, namely, the breaking of the ionic lock between R135^3.50 at the intracellular end of TM3 (part of the DRY motif) and E247^6.30 on TM6, and the rotamer toggle switch on W265^6.48 on TM6. We observe that the toggling of the W265^6.48 rotamer modulates the bend angle of TM6 around the conserved proline. The rotamer toggling is facilitated by the formation of a water wire connecting S298^7.45, W265^6.48 and H211^5.46. As a result, the intracellular ends of TMs 5 and 6 move outward from the protein core, causing large conformational changes at the cytoplasmic interface. The predicted outward movements of TM5 and TM6 are in agreement with the recently published crystal structure of opsin, which is proposed to be close to the active-state structure. In the predicted active state, several residues in the intracellular loops, such as R69, V139^3.54, T229, Q237, Q239, S240, T243 and V250^6.33, become more water exposed compared to the inactive state. These residues may be involved in mediating the conformational signal from the receptor to the G protein. From mutagenesis studies, some of these residues, such as V139^3.54, T229 and V250^6.33, are already implicated in G-protein activation. The predicted active state also leads to the formation of new stabilizing interhelical hydrogen-bond contacts, such as those between W265^6.48 and H211^5.46 and E122^3.37 and C167^4.56. These hydrogen-bond contacts serve as potential conformational switches offering new opportunities for future experimental investigations. The calculated retinal binding energy surface shows that binding of an agonist makes the receptor dynamic and flexible and accessible to many conformations, while binding of an inverse agonist traps the receptor in the inactive state and makes the other conformations inaccessible.     

Involvement of vasodilator-stimulated phosphoprotein in UDP-induced microglial actin aggregation via PKC- and Rho-dependent pathways

Microglia are major immunocompetent cells in the central nervous system and retain highly dynamic motility. The processes which allow these cells to move, such as chemotaxis and phagocytosis, are considered part of their functions and are closely related to purinergic signaling. Previously, we reported that the activation of the P2Y₆ receptor by UDP stimulation in microglia evoked dynamic cell motility which enhanced their phagocytic capacity, as reported by Koizumi et al. (Nature 446(7139):1091–1095, 2007). These responses require actin cytoskeletal rearrangement, which is seen after UDP stimulation. However, the intracellular signaling pathway has not been defined. In this study, we found that UDP in rat primary microglia rapidly induced the transient phosphorylation at Ser157 of vasodilator-stimulated phosphoprotein (VASP). VASP, one of actin binding protein, accumulated at the plasma membrane where filamentous (F)-actin aggregated in a time-dependent manner. The phosphorylation of VASP was suppressed by inhibition of PKC. UDP-induced local actin aggregations were also abrogated by PKC inhibitors. The Rho inhibitor CT04 and the expression of p115-RGS, which suppresses G_12/13 signaling, attenuated UDP-induced phosphorylation of VASP and actin aggregation. These results indicate that PKC- and Rho-dependent phosphorylation of VASP is involved in UDP-induced actin aggregation of microglia.     

Arbuscular mycorrhizal fungal inoculation increases phenolic synthesis in clover roots via hydrogen peroxide,salicylic acid and nitric oxide signaling pathways

Arbuscular mycorrhizal fungi can increase the host resistance to pathogens via promoted phenolic synthesis, however, the signaling pathway responsible for it still remains unclear. In this study, in order to reveal the signaling molecules involved in this process, we inoculated Trifolium repense L. with an arbuscular mycorrhizal fungus (AMF), Glomus mosseae, and monitored the contents of phenolics and signaling molecules (hydrogen peroxide (H₂O₂), salicylic acid (SA), and nitric oxide (NO)) in roots, measured the activities of l-phenylalanine ammonia-lyase (PAL) and nitric oxide synthase (NOS), and the expression of pal and chs genes. Results demonstrated that AMF colonization promoted the phenolic synthesis, in parallel with the increase in related enzyme activity and gene expression. Meanwhile, the accumulation of all three signaling molecules was also up-regulated by AMF. This study suggested that AMF increased the phenolic synthesis in roots probably via signaling pathways of H₂O₂, SA and NO in a signaling cascade.     

A Lys49-PLA2 myotoxin of Bothrops asper triggers a rapid death of macrophages that involves autocrine purinergic receptor signaling

Lys49-PLA₂ myotoxins, an important component of various viperid snake venoms, are a class of PLA₂-homolog proteins deprived of catalytic activity. Similar to enzymatically active PLA₂ (Asp49) and to other classes of myotoxins, they cause severe myonecrosis. Moreover, these toxins are used as tools to study skeletal muscle repair and regeneration, a process that can be very limited after snakebites. In this work, the cytotoxic effect of different myotoxins, Bothrops asper Lys49 and Asp49-PLA₂, Notechis scutatus notexin and Naja mossambica cardiotoxin, was evaluated on macrophages, cells that have a key role in muscle regeneration. Only the Lys49-myotoxin was found to trigger a rapid asynchronous death of mouse peritoneal macrophages and macrophagic cell lines through a process that involves ATP release, ATP-induced ATP release and that is inhibited by various purinergic receptor antagonists. ATP leakage is induced also at sublytical doses of the Lys49-myotoxin, it involves Ca²⁺ release from intracellular stores, and is reduced by inhibitors of VSOR and the maxi-anion channel. The toxin-induced cell death is different from that caused by high concentration of ATP and appears to be linked to localized purinergic signaling. Based on present findings, a mechanism of cell death is proposed that can be extended to other cytolytic proteins and peptides.     

NO serves as a signaling intermediate downstream of H2O2 to modulate dynamic microtubule cytoskeleton during responses to VD-toxins in Arabidopsis

Although hydrogen peroxide (H₂O₂) and nitric oxide (NO) can act as an upstream signaling molecule to modulate the dynamic microtubule cytoskeleton during the defense responses to Verticillium dahliae (VD) toxins in Arabidopsis, it is not known the relationship between these two signaling molecules. Here, we show that VD-toxin-induced NO accumulation was dependent on prior H₂O₂ production, NO is downstream of H₂O₂ in the signaling process, and that H₂O₂ acted synergistically with NO to modulate the dynamic microtubule cytoskeleton responses to VD-toxins in Arabidopsis.     

Simultaneous activation of p38 and JNK by arachidonic acid stimulates the cytosolic phospholipase A2-dependent synthesis of lipid droplets in human monocytes

Exposure of human peripheral blood monocytes to free arachidonic acid (AA) results in the rapid induction of lipid droplet (LD) formation by these cells. This effect appears specific for AA in that it is not mimicked by other fatty acids, whether saturated or unsaturated. LDs are formed by two different routes: (i) the direct entry of AA into triacylglycerol and (ii) activation of intracellular signaling, leading to increased triacylglycerol and cholesteryl ester formation utilizing fatty acids coming from the de novo biosynthetic route. Both routes can be dissociated by the arachidonyl-CoA synthetase inhibitor triacsin C, which prevents the former but not the latter. LD formation by AA-induced signaling predominates, accounting for 60–70% of total LD formation, and can be completely inhibited by selective inhibition of the group IVA cytosolic phospholipase A₂α (cPLA₂α), pointing out this enzyme as a key regulator of AA-induced signaling. LD formation in AA-treated monocytes can also be blocked by the combined inhibition of the mitogen-activated protein kinase family members p38 and JNK, which correlates with inhibition of cPLA₂α activation by phosphorylation. Collectively, these results suggest that concomitant activation of p38 and JNK by AA cooperate to activate cPLA₂α, which is in turn required for LD formation possibly by facilitating biogenesis of this organelle, not by regulating neutral lipid synthesis.