Role of clathrin-mediated endocytosis in agonist-induced down-regulation of the beta2-adrenergic receptor

Previous studies have demonstrated that non-visual arrestins function as adaptors in clathrin-mediated endocytosis to promote agonist-induced internalization of the beta2-adrenergic receptor (beta2AR). Here, we characterized the effects of arrestins and other modulators of clathrin-mediated endocytosis on down-regulation of the beta2AR. In COS-1 and HeLa cells, non-visual arrestins promote agonist-induced internalization and down-regulation of the beta2AR, whereas dynamin-K44A, a dominant-negative mutant of dynamin that inhibits clathrin-mediated endocytosis, attenuates beta2AR internalization and down-regulation. In HEK293 cells, dynamin-K44A profoundly inhibits agonist-induced internalization and down-regulation of the beta2AR, suggesting that receptor internalization is critical for down-regulation in these cells. Moreover, a dominant-negative mutant of beta-arrestin, beta-arrestin-(319-418), also inhibits both agonist-induced receptor internalization and down-regulation. Immunofluorescence microscopy analysis reveals that the beta2AR is trafficked to lysosomes in HEK293 cells, where presumably degradation of the receptor occurs. These studies demonstrate that down-regulation of the beta2AR is in part due to trafficking of the beta2AR via the clathrin-coated pit endosomal pathway to lysosomes.     

Mutation of tyrosine-350 impairs the coupling of the beta 2-adrenergic receptor to the stimulatory guanine nucleotide binding protein without interfering with receptor down-regulation

Long-term stimulation of the beta 2-adrenergic receptor (beta 2AR) leads to an internalization and degradation of the receptor. This down-regulation of the beta 2AR number contributes to the desensitization of the adenylyl cyclase activity induced by chronic exposure to agonists. It was proposed that two tyrosine residues (Tyr-350 and Tyr-354) located in the cytoplasmic tail of the beta 2AR play a crucial role in agonist-induced down-regulation. In addition to perturbation of the down-regulation, the substitution of these tyrosines for alanines also led to a functional uncoupling of the receptor from Gs [Valiquette et al. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 5089-5093]. To further characterize the relative contribution of Tyr-350 and Tyr-354 to the receptor interaction with Gs and agonist-promoted down-regulation, both tyrosines were individually replaced by alanines and mutant receptors expressed in CHW cells. We show here that mutation of Tyr-350 but not that of Tyr-354 significantly decreased the ability of the beta 2AR to be functionally coupled to Gs and thereby to stimulate the adenylyl cyclase. Moreover, in contrast to the double tyrosine mutation, neither of the single-point mutations affected the agonist-induced down-regulation pattern. These data suggest that the presence of either Tyr-350 or Tyr-354 is sufficient to maintain normal agonist-induced down-regulation whereas the integrity of Tyr-350 is required for an appropriate coupling to Gs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of endothelial permeability by beta-adrenoceptor agonists: contribution of beta 1- and beta 2-adrenoceptors

The barrier function of cultured, macrovascular endothelial cells derived from bovine aorta was analyzed using confluent monolayers of cells and measuring the exchange of fluorescein dextrans of different molecular masses. The effects of beta-adrenoceptor agonists with different selectivity for beta 1- and beta 2-adrenoceptors (AR) were investigated. Formoterol, a novel high-affinity agonist for beta 2-AR recently introduced in the treatment of bronchial asthma, showed a significant reduction of cell permeability with subnanomolar concentrations, whereas the catecholamines (-)-isoproterenol and (-)-norepinephrine only showed significant effects with micromolar concentrations. In order to elucidate if this difference in potential to regulate cell permeability is related to appropriate changes in the selectivity and affinity of the agonists for beta 2 AR, we investigated the beta AR-coupled adenylate cyclase (AC) in membranes from endothelial cells and compared AC stimulation with the binding of agonists to the receptors using [125I](-)-iodopindolol as radioligand. beta-Adrenoceptors revealed to be closely coupled to AC as assessed by a similar magnitude of effects by receptor agonists in comparison to GTP analogues and direct stimulants of AC activity. AC activity was increased by formoterol in parallel to its receptor occupancy of beta 2AR with nanomolar concentrations which were 50-fold higher than those used for the regulation of cell permeability indicating the existence of spare receptors. In contrast to formoterol, the catecholamines (-)-isoproterenol and (-)-norepinephrine stimulated AC activity through both beta 1AR and beta 2AR. From the overproportional high contribution of beta 1AR to AC stimulation (42%) in comparison to its low fraction (13%) in receptor binding we calculated that beta 1AR is 3-4-fold more effectively coupled to AC than beta 2 AR.     

Dimer/monomer equilibrium and domain separations of Escherichia coli ribosomal protein L7/L12

The dimer to monomer equilibrium and interdomain separations of cysteine variants of L7/L12 have been investigated using fluorescence spectroscopy. Steady-state polarization measurements on cysteine containing variants of L7/L12, labeled with 5-(iodoacetamido)fluorescein, demonstrated dimer to monomer dissociation constants near 30 nM for variants labeled at position 33, in the N-terminal domain, and positions 63 and 89, in the C-terminal domain. A dissociation constant near 300 nM was determined for a variant labeled at position 12, in the N-terminal domain. The polarization of a labeled C-terminal fragment did not change over the range of 200 microM to 1 nM, indicating that this construct remains monomeric at these concentrations, whereas a dimer to monomer dissociation constant near 300 nM was observed for an FITC labeled N-terminal fragment. Intersubunit fluorescence resonance energy self-transfer was observed when appropriate probes were attached to cysteines at residues 12 or 33, located in the N-terminal domain. Probes attached to cysteines at positions 63 or 89 in the C-terminal domain, however, did not exhibit intersubunit self-transfer. These results indicate that these residues in the C-terminal domains are, on average, separated by greater than 85 A. Intersubunit self-transfer does occur in a C-89 double mutation variant lacking 11 residues in the putative hinge region, indicating that the loss of the hinge region brings the two C-terminal domains closer together. Rapid subunit exchange between unlabeled wild-type L7/L12 and L7/L12 variants labeled in the N-terminal domain was also demonstrated by the loss of self-transfer upon mixing of the two proteins.     

Palmitoylated cysteine 341 modulates phosphorylation of the beta2-adrenergic receptor by the cAMP-dependent protein kinase

We previously showed that substitution of a glycine residue for the palmitoylated cysteine 341 of the human beta2-adrenergic receptor (Gly341beta2AR), increases the basal level of the receptor phosphorylation and reduces its ability to functionally interact with Gs. In the present study, we show that additional mutation of serines 345 and 346 (Ala345,346Gly341beta2AR) restored normal phosphorylation and receptor-Gs coupling, thus suggesting that the increased phosphorylation of this site, rather than the lack of palmitoylation per se, is responsible for the poor coupling of the unpalmitoylated receptor. This is supported by the observation that chemical depalmitoylation of purified beta2AR did not affect the ability of the receptor to stimulate adenylyl cyclase in reconstitution assays. Furthermore, mutation of Ser345,346 in a wild type receptor background (Ala345,346beta2AR) significantly decreased the rate of agonist-promoted desensitization of the receptor-stimulated adenylyl cyclase activity, supporting a role for this phosphorylation site in regulating the functional coupling of the receptor. Since serines 345 and 346 are located in a putative cyclic AMP-dependent protein kinase (PKA) phosphorylation site immediately downstream of the palmitoylated cysteine 341, the hypothesis that the accessibility of this site may be regulated by the receptor palmitoylation state was further assessed in vitro. In membrane phosphorylation assays, Gly341beta2AR was found to be a better substrate for PKA than the wild type receptor, thus supporting the notion that palmitoylation restrains access of the phosphorylation site to the enzyme. Taken together, the data demonstrate that palmitoylation of cysteine 341 controls the phosphorylation state of the PKA site located in the carboxyl tail of the beta2AR and by doing so modulates the responsiveness of the receptor.     

Quinacrine noncompetitive inhibitor binding site localized on the Torpedo acetylcholine receptor in the open state

Open-channel blockers of the nicotinic acetylcholine receptor (nAcChR) are widely thought to act sterically by entering and "plugging" the open channel of the nAcChR. However, quinacrine, a fluorescent open-channel blocker, has been recently shown to bind to the nAcChR at a site near the lipid bilayer while the receptor is in a closed, desensitized state, suggesting that at least one open-channel blocker might act allosterically outside the channel [Valenzuela et al. (1992) J. Biol. Chem. 267, 8238]. To determine whether or not quinacrine also binds near the lipid bilayer when the receptor is in an open state, a short-range lipophilic quencher (5-doxylstearate, 5-SA) was used to assess the proximity of the nAcChR-bound quinacrine to the lipid bilayer while the receptor was transiently open by an agonist. Initial experiments using a stopped-flow instrument established the conditions required to monitor a portion of the changes in quinacrine fluorescence associated with its binding to the receptor in the open state. 5-SA (80 microM) reduced the amplitude of the rapid agonist-induced change in quinacrine emission to 44% +/- 12% of the control value, indicating that the quinacrine was binding to a site proximal to the membrane-partitioned 5-SA. Control experiments established that 5-SA had no effect on the ability of the receptor to undergo agonist-induced conformational changes, suggesting that little, if any, 5-SA distributed into the channel lumen and perturbed the functional activity of the receptor. Together, the results indicate that quinacrine binds to a site on the open receptor that is in contact with the lipid bilayer and not in the channel lumen.     

Inhibition of smooth muscle actomyosin ATPase by caldesmon is associated with caldesmon-induced conformational changes in tropomyosin bound to actin

The smooth muscle tropomyosin isoforms beta and gamma were isolated in pure form and labeled with N-(1-pyrenyl)iodoacetamide (PIA) on the cysteine residues at either the N- or the C-terminal region (Cys-36 and Cys-190 of beta- and gamma-isoforms, respectively). The effect of caldesmon (CaD) on local conformational changes in different regions of the tropomyosin molecule was determined on the basis of changes in the excimer fluorescence (excited dimer of pyrene) formed in homodimers of tropomyosin isoforms. In the absence of actin, excimer fluorescence from the pyrene at Cys-190 of gamma-tropomyosin homodimer decreased in a simple manner on the addition of CaD, whereas the excimer from the Cys-36 of beta-tropomyosin homodimer exhibited a biphasic change, suggesting that additional weak binding sites exist near Cys-36. In the presence of actin, CaD-induced changes in the excimer fluorescence of pyrene-tropomyosin were observed only with Cys-36, and this change was associated with an inhibition of actin-activated myosin ATPase. A competition study with unlabeled tropomyosin isoforms indicated that the different excimer changes exhibited by beta- and gamma-tropomyosin in the presence of CaD were due to conformational changes in different regions of the tropomyosin molecule and not to differences in their affinities for CaD. Experiments with recombinant CaD mutants derived using the baculovirus expression system showed that the inhibition of tropomyosin potentiation of actomyosin ATPase by CaD requires the regions between residues 728-756 and 718-727 on the CaD molecule, although the latter region was sufficient for direct interaction with tropomyosin.     

Visualization of agonist-induced sequestration and down-regulation of a green fluorescent protein-tagged beta2-adrenergic receptor

To date, the visualization of beta2-adrenergic receptor (beta2AR) trafficking has been largely limited to immunocytochemical analyses of acute internalization events of epitope-tagged receptors in various transfection systems. The development of a beta2AR conjugated with green fluorescent protein (beta2AR-GFP) provides the opportunity for a more extensive optical analysis of beta2AR sequestration, down-regulation, and recycling in cells. Here we demonstrate that stable expression of beta2AR-GFP in HeLa cells enables a detailed temporal and spatial analysis of these events. Time-dependent colocalization of beta2AR-GFP with rhodamine-labeled transferrin and rhodamine-labeled dextran following agonist exposure demonstrates receptor distribution to early endosomes (sequestration) and lysosomes (down-regulation), respectively. The observed temporal distribution of beta2AR-GFP was consistent with measures of receptor sequestration and down-regulation generated by radioligand-receptor binding assays. Cells stimulated with different beta-agonists revealed time courses of beta2AR-GFP redistribution reflective of the intrinsic activity of each agonist.     

Photoacoustic analysis of proteins: volumetric signals and fluorescence quantum yields

A series of proteins has been examined using time-resolved, pulsed-laser volumetric photoacoustic spectroscopy. Photoacoustic waveforms were collected to measure heat release for calculation of fluorescence quantum yields, and to explore the possibility of photoinduced nonthermal volume changes occurring in these protein samples. The proteins studied were the green fluorescent protein (GFP); intestinal fatty acid binding protein (IFABP), and adipocyte lipid-binding protein (ALBP), each labeled noncovalently with 1-anilinonaphthalene-8-sulfonate (1,8-ANS) and covalently with 6-acryloyl-2-(dimethylamino)naphthalene (acrylodan); and acrylodan-labeled IFABP and ALBP with added oleic acid. Of this group of proteins, only the ALBP labeled with 1,8-ANS showed significant nonthermal volume changes at the beta = 0 temperature (approximately 3.8 degrees C) for the buffer used (10 mM Tris-HCI, pH 7.5) (beta is the thermal cubic volumetric expansion coefficient). For all of the proteins except for acrylodan-labeled IFABP, the fluorescence quantum yields calculated assuming simple energy conservation were anomalously high, i.e., the apparent heat signals were lower than those predicted from independent fluorescence measurements. The consistent anomalies suggest that the low photoacoustic signals may be characteristic of fluorophores buried in proteins, and that photoacoustic signals derive in part from the microenvironment of the absorbing chromophore.     

Specificity of the high-mannose recognition site between Enterobacter cloacae pili adhesin and HT-29 cell membranes

Dopamine D2 receptor agonists are commonly used in the control of PRL-secreting adenomas, and the sensitivity of dopamine agonists during long term therapy is exquisite. However, the molecular mechanisms responsible for the maintenance of this cellular sensitivity to dopamine agonists remain poorly understood. In the present study, we examined the agonist-induced regulation of the human D2L receptor expressed to a specific activity of approximately 1 pmol receptor/mg protein in Sf9 insect cells. Treatment of D2L receptor-expressing cells with dopamine for up to 3 h resulted in no detectable change in the ligand-binding properties of the receptor and a approximately 120-fold reduction in the potency, but not the efficacy, of D2L receptors to mediate dopamine inhibition of forskolin-stimulated adenylyl cyclase activity. This resistance of the D2L receptor to agonist-induced desensitization was accompanied by a approximately 28% translocation of intracellular D2L receptors to the cell surface, as quantified by cellular fractionation and radioligand binding and visualized by whole cell immunocytochemical staining and confocal microscopy. Immunoblot analysis of the P2 membrane fraction revealed that surface D2L receptors comprised monomers and dimers. Treatment of D2L receptor-expressing cells with the protein synthesis inhibitor cycloheximide significantly reduced the basal expression level of receptors, but did not block the agonist-induced up-regulation of receptors. Longer periods of dopamine exposure for 24 h brought about a small increase in surface receptor density. However, when these studies were conducted in the presence of cycloheximide, receptor density was marginally reduced, suggesting that receptor synthesis accounts for the maintenance of cellular receptor density under these conditions. We conclude that the resistance of the D2L receptor-coupled adenylyl cyclase system to agonist-induced desensitization is attributed to the up-regulation of surface receptors after the translocation of existing intracellular receptors and de novo receptor synthesis.     

Agonist-receptor-arrestin, an alternative ternary complex with high agonist affinity

The rapid decrease of a response to a persistent stimulus, often termed desensitization, is a widespread biological phenomenon. Signal transduction by numerous G protein-coupled receptors appears to be terminated by a strikingly uniform two-step mechanism, most extensively characterized for the beta2-adrenergic receptor (beta2AR), m2 muscarinic cholinergic receptor (m2 mAChR), and rhodopsin. The model predicts that activated receptor is initially phosphorylated and then tightly binds an arrestin protein that effectively blocks further G protein interaction. Here we report that complexes of beta2AR-arrestin and m2 mAChR-arrestin have a higher affinity for agonists (but not antagonists) than do receptors not complexed with arrestin. The percentage of phosphorylated beta2AR in this high affinity state in the presence of full agonists varied with different arrestins and was enhanced by selective mutations in arrestins. The percentage of high affinity sites also was proportional to the intrinsic activity of an agonist, and the coefficient of proportionality varies for different arrestin proteins. Certain mutant arrestins can form these high affinity complexes with unphosphorylated receptors. Mutations that enhance formation of the agonist-receptor-arrestin complexes should provide useful tools for manipulating both the efficiency of signaling and rate and specificity of receptor internalization.     

Mu opioid receptor phosphorylation, desensitization, and ligand efficacy

Mu opioid receptors are subject to phosphorylation and desensitization through actions of at least two distinct biochemical pathways: agonist-dependent mu receptor phosphorylation and desensitization induced by a biochemically distinct second pathway dependent on protein kinase C activation (1). To better understand the nature of the agonist-induced mu receptor phosphorylation events, we have investigated the effects of a variety of opiate ligands of varying potencies and intrinsic activities on mu receptor phosphorylation and desensitization. Exposure to the potent full agonists sufentanil, dihydroetorphine, etorphine, etonitazine, and [D-Ala2, MePhe4, Glyol5]enkephalin (DAMGO) led to strong receptor phosphorylation, while methadone, l-alpha-acetylmethadone (LAAM), morphine, meperidine, DADL, beta-endorphin(1-31), enkephalins, and dynorphin A(1-17) produced intermediate effects. The partial agonist buprenorphine minimally enhanced receptor phosphorylation while antagonists failed to alter phosphorylation. Buprenorphine and full antagonists each antagonized the enhanced mu receptor phosphorylation induced by morphine or DAMGO. The rank order of opiate ligand efficacies in producing mu receptor-mediated functional desensitization generally paralleled their rank order of efficacies in producing receptor phosphorylation. Interestingly, the desensitization and phosphorylation mediated by methadone and LAAM were disproportionate to their efficacies in two distinct test systems. This generally good fit between the efficacies of opiates in mu receptor activation, phosphorylation, and desensitization supports the idea that activated receptor/agonist/G-protein complexes and/or receptor conformational changes induced by agonists are required for agonist-induced mu receptor phosphorylation. Data for methadone and LAAM suggest possible contribution from their enhanced desensitizing abilities to their therapeutic efficacies.     

The contribution of classical (beta1/2-) and atypical beta-adrenoceptors to the stimulation of human white adipocyte lipolysis and right atrial appendage contraction by novel beta3-adrenoceptor agonists of differing selectivities

The role of beta3- and other putative atypical beta-adrenoceptors in human white adipocytes and right atrial appendage has been investigated using CGP 12177 and novel phenylethanolamine and aryloxypropanolamine beta3-adrenoceptor (beta3AR) agonists with varying intrinsic activities and selectivities for human cloned betaAR subtypes. The ability to demonstrate beta1/2AR antagonist-insensitive (beta3 or other atypical betaAR-mediated) responses to CGP 12177 was critically dependent on the albumin batch used to prepare and incubate the adipocytes. Four aryloxypropanolamine selective beta3AR agonists (SB-226552, SB-229432, SB-236923, SB-246982) consistently elicited beta1/2AR antagonist-insensitive lipolysis. However, a phenylethanolamine (SB-220646) that was a selective full beta3AR agonist elicited full lipolytic and inotropic responses that were sensitive to beta1/2AR antagonism, despite it having very low efficacies at cloned beta1- and beta2ARs. A component of the response to another phenylethanolamine selective beta3AR agonist (SB-215691) was insensitive to beta1/2AR antagonism in some experiments. Because no [corrected] novel aryloxypropanolamine had a beta1/2AR antagonist-insensitive inotropic effect, these results establish more firmly that beta3ARs mediate lipolysis in human white adipocytes, and suggest that putative 'beta4ARs' mediate inotropic responses to CGP 12177. The results also illustrate the difficulty of predicting from studies on cloned betaARs which betaARs will mediate responses to agonists in tissues that have a high number of beta1- and beta2ARs or a low number of beta3ARs.     

Molecular mechanisms of G protein-coupled receptor desensitization and resensitization

Beta-arrestin proteins play a dual role in regulating G protein-coupled receptor (GPCR) responsiveness by contributing to both receptor desensitization and internalization. Recently, beta-arrestins were also shown to be critical determinants for beta2-adrenergic receptor (beta2AR) resensitization. This was demonstrated by overexpressing wild-type beta-arrestins to rescue the resensitization-defect of a beta2AR (Y326A) mutant (gain of function) and overexpressing a dominant-negative beta-arrestin inhibitor of beta2AR sequestration to impair beta2AR dephosphorylation and resensitization (loss of function). Moreover, the ability of the beta2AR to resensitize in different cell types was shown to be dependent upon beta-arrestin expression levels. To further study the mechanisms underlying beta-arrestin function, green fluorescent protein was coupled to beta-arrestin2 (beta arr2GFP), thus allowing the real-time visualization of the agonist-dependent trafficking of beta-arrestin in living cells. Beta arr2GFP translocation from the cytoplasm to the plasma membrane proceeded with a time course, sensitivity and specificity that was indistinguishable from the most sensitive second messenger readout systems. Beta arr2GFP translocation was GRK-dependent and was demonstrated for 16 different ligand-activated GPCRs. Because beta-arrestin binding is a common divergent step in GPCR signalling, this assay represents a universal methodology for screening orphan receptors, GRK inhibitors and novel GPCR ligands. Moreover, beta arr2GFP provides a valuable new tool to dissect the biological function and regulation of beta-arrestin proteins.     

A subunit interaction in chloroplast ATP synthase determined by genetic complementation between chloroplast and bacterial ATP synthase genes

F1F0-ATP synthases utilize protein conformational changes induced by a transmembrane proton gradient to synthesize ATP. The allosteric cooperativity of these multisubunit enzymes presumably requires numerous protein-protein interactions within the enzyme complex. To correlate known in vitro changes in subunit structure with in vivo allosteric interactions, we introduced the beta subunit of spinach chloroplast coupling factor 1 ATP into a bacterial F1 ATP synthase. A cloned atpB gene, encoding the complete chloroplast beta subunit, complemented a chromosomal deletion of the cognate uncD gene in Escherichia coli and was incorporated into a functional hybrid F1 ATP synthase. The cysteine residue at position 63 in chloroplast beta is known to be located at the interface between alpha and beta subunits and to be conformationally coupled, in vitro, to the nucleotide binding site > 40 A away. Enlarging the side chain of chloroplast coupling factor 1 beta residue 63 from Cys to Trp blocked ATP synthesis in vivo without significantly impairing ATPase activity or ADP binding in vitro. The in vivo coupling of nucleotide binding at catalytic sites to transmembrane proton movement may thus involve an interaction, via conformational changes, between the amino-terminal domains of the alpha and beta subunits.     

Effects of thyroid hormone on cardiac beta-adrenergic responsiveness in conscious baboons

BACKGROUND: Many of the cardiovascular manifestations of thyroid hormone excess resemble those produced by sympathoadrenal stimulation. The objective of this study was to determine the effects of thyroid hormone excess on myocardial beta-adrenergic expression and responsiveness to infused agonists in the primate heart. METHODS AND RESULTS: The responses of left ventricular isovolumic contraction (dP/dt(max)) and relaxation (tau) during graded dobutamine infusion were studied both before and after 4 weeks of thyroid hormone administration in 8 chronically instrumented baboons. At matched (atrially paced) heart rates, thyroid hormone significantly increased resting dP/dt(max) (3073+/-1034 versus 2318+/-829 mm Hg/s, P<.05) and decreased tau (24.0+/-5.5 versus 28.2+/-5.4 ms, P<.05). The change from baseline for dP/dt(max) and tau in response to beta1-adrenergic stimulation was significant at each dobutamine dose (2.5 to 10 microg x kg(-1) x min(-1)), but when expressed as a percent change, it was similar before versus after thyroid hormone. Similar changes were found when beta2-adrenergic stimulation was produced by terbutaline infusion in three additional baboons. beta-Adrenergic receptor (betaAR) expression was higher in five thyroxine-treated than in five control baboons (37.4+/-1.2 versus 15.7+/-3.2 fmol/mg, P<.001), and this was due to a greater increase in the beta2AR (5.9+/-1.5 to 20.6+/-1.2 fmol/mg, P<.001) than the beta1AR (9.7+/-1.7 to 16.8+/-0.1 fmol/mg, P<.01) subtype. CONCLUSIONS: In the primate heart, thyroid hormone produces positive inotropic and lusitropic effects in the resting state and upregulates both beta1AR and beta2AR, with the beta2AR increase predominating. At equivalent rates, however, thyroid hormone excess does not appear to enhance the sensitivity of left ventricular contractility and relaxation to either beta1- or beta2-adrenergic stimulation.     

A fluorescent probe study of plasminogen activator inhibitor-1. Evidence for reactive center loop insertion and its role in the inhibitory mechanism

A mutant recombinant plasminogen activator inhibitor 1 (PAI-1) was created (Ser-338-->Cys) in which cysteine was placed at the P9 position of the reactive center loop. Labeling this mutant with N,N'-dimethyl-N-(acetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl) ethylene diamine (NBD) provided a molecule with a fluorescent probe at that position. The NBD-labeled mutant was almost as reactive as wild type but was considerably more stable. Complex formation with tissue or urokinase type plasminogen activator (tPA or uPA), and cleavage between P3 and P4 with a catalytic concentration of elastase, all resulted in identical 13-nm blue shifts of the peak fluorescence emission wavelength and 6.2-fold fluorescence enhancements. Formation of latent PAI showed the same 13-nm spectral shift with a 6.7-fold fluorescence emission increase, indicating that the NBD probe is in a slightly more hydrophobic milieu. These changes can be attributed to insertion of the reactive center loop into the beta sheet A of the inhibitor in a manner that exposes the NBD probe to a more hydrophobic milieu. The rate of loop insertion due to tPA complexation was followed using stopped flow fluorimetry. This rate showed a hyperbolic dependence on tPA concentration, with a half-saturation concentration of 0.96 microM and a maximum rate constant of 3.4 s-1. These results demonstrate experimentally that complexation with proteases is presumably associated with loop insertion. The identical fluorescence changes obtained with tPa.PAI-1 and uPA.PAI-1 complexes and elastase-cleaved PAI-1 strongly suggest that in the stable protease-PAI-1 complex the reactive center loop is cleaved and inserted into beta sheet A and that this process is central to the inhibition mechanism.     

Identification of a cysteine residue essential for activity of protein farnesyltransferase. Cys299 is exposed only upon removal of zinc from the enzyme

Protein farnesyltransferase (FTase) is a zinc metalloenzyme that performs a post-translational modification on many proteins that is critical for their function. The importance of cysteine residues in FTase activity was investigated using cysteine-specific reagents. Zinc-depleted FTase (apo-FTase), but not the holoenzyme, was completely inactivated by treatment with N-ethylmaleimide (NEM). Similar effects were detected after treatment of the enzyme with iodoacetamide. The addition of zinc to apo-FTase protects it from inactivation by NEM. These findings indicated the presence of specific cysteine residue(s), potentially located at the zinc binding site, that are required for FTase activity. We performed a selective labeling strategy whereby the cysteine residues exposed upon removal of zinc from the enzyme were modified with [3H]NEM. The enzyme so modified was digested with trypsin, and four labeled peptides were identified and sequenced, one peptide being the major site of labeling and the remaining three labeled to lesser extents. The major labeled peptide contained a radiolabeled cysteine residue, Cys299, that is in the beta subunit of FTase and is conserved in all known protein prenyltransferases. This cysteine residue was changed to both alanine and serine by site-directed mutagenesis, and the mutant proteins were produced in Escherichia coli and purified. While both mutant proteins retained the ability to bind farnesyl diphosphate, they were found to have lost essentially all catalytic activity and ability to bind zinc. These results indicate that the Cys299 in the beta subunit of FTase plays a critical role in catalysis by the enzyme and is likely to be one of the residues that directly coordinate the zinc atom in this enzyme.