Platelet stimulation releases a cAMP-dependent protein kinase that specifically phosphorylates a plasma protein

Proteomic database mining opens up avenues utilizing extracellular protein phosphorylation for novel therapeutic applications

Recent advances in extracellular signaling suggest that extracellular protein phosphorylation is a regulatory mechanism outside the cell. The list of reported active extracellular protein kinases and phosphatases is growing, and phosphorylation of an increasing number of extracellular matrix molecules and extracellular domains of trans-membrane proteins is being documented. Here, we use public proteomic databases, collagens – the major components of the extracellular matrix, extracellular signaling molecules and proteolytic enzymes as examples to assess what the roles of extracellular protein phosphorylation may be in health and disease. We propose that novel tools be developed to help assess the role of extracellular protein phosphorylation and translate the findings for biomedical applications. Furthermore, we suggest that the phosphorylation state of extracellular matrix components as well as the presence of extracellular kinases be taken into account when designing translational medical applications.

Ecto-protein kinases and phosphatases: an emerging field for translational medicine

Progress in translational research has led to effective new treatments of a large number of diseases. Despite this progress, diseases including cancer and cardiovascular disorders still are at the top in death statistics and disorders such as osteoporosis and osteoarthritis represent an increasing disease burden in the aging population. Novel strategies in research are needed more than ever to overcome such diseases. The growing field of extracellular protein phosphorylation provides excellent opportunities to make major discoveries of disease mechanisms that can lead to novel therapies. Reversible phosphorylation/dephosphorylation of sites in the extracellular domains of matrix, cell-surface and trans-membrane proteins is emerging as a critical regulatory mechanism in health and disease. Moreover, a new concept is emerging from studies of extracellular protein phosphorylation: in cells where ATP is stored within secretory vesicles and released by exocytosis upon cell-stimulation, phosphorylation of extracellular proteins can operate as a messenger operating uniquely in signaling pathways responsible for long-term cellular adaptation. Here, we highlight new concepts that arise from this research, and discuss translation of the findings into clinical applications such as development of diagnostic disease markers and next-generation drugs.

Extracellular phosphorylation and phosphorylated proteins: not just curiosities but physiologically important

Mining of the literature and high-throughput mass spectrometry data from both healthy and diseased tissues and from body fluids reveals evidence that various extracellular proteins can exist in phosphorylated states. Extracellular kinases and phosphatases (ectokinases and ectophosphatases) are active in extracellular spaces during times of sufficiently high concentrations of adenosine triphosphate. There is evidence for a role of extracellular phosphorylation in various physiological functions, including blood coagulation, immune cell activation, and the formation of neuronal networks. Ectokinase activity is increased in some diseases, including cancer, Alzheimer's disease, and some microbial infections. We summarize the literature supporting the physiological and pathological roles of extracellularly localized protein kinases, protein phosphatases, and phosphorylated proteins and provide an analysis of the available mass spectrometry data to annotate potential extracellular phosphorylated proteins.

Proteomics analysis of plasma for potential biomarkers in the diagnosis of Alzheimer's disease

The objective of this study was to search for biological markers associated with Alzheimer's disease (AD). Plasma specimens obtained from ten pathologically diagnosed AD patients and ten non-demented (ND) control subjects were analyzed by a combination of 2-DE and MS. This strategy allowed us to identify six plasma proteins (alpha-1-antitrypsin, vitamin D-binding protein, inter-alpha-trypsin inhibitor family heavy chain-related protein, apolipoprotein J precursor, cAMP-dependent protein kinase catalytic subunit alpha 1, and an orf) whose 2-DE spot densities were different between the AD and ND groups. Due to their involvements in AD amyloid plaque formation, the plasma concentrations of alpha-1-antitrypsin and apolipoprotein J were further validated using either ELISA or Western blot. The results revealed that the plasma levels of alpha-1-antitrypsin in AD were higher than those of controls, confirming the 2-DE findings. However, no difference in total apolipoprotein J concentration was observed between the AD and ND groups. Considering the difference in resolving power to differentially quantitate protein isoforms provided by 2-DE and Western blot, 2-DE analysis combined with MS protein identification offers distinctive advantages when a disease-related protein isoform-specific variance is investigated.

Variable phosphorylation states of pigment-epithelium-derived factor differentially regulate its function

The pigment epithelium-derived factor (PEDF) belongs to the family of noninhibitory serpins. Although originally identified in the eye, PEDF is widely expressed in other body regions including the plasma. This factor can act either as a neurotrophic or as an antiangiogenic factor, and we previously showed that the 2 effects of PEDF are regulated through phosphorylation by PKA and CK2. Here, we studied the interplay between the PKA and CK2 phosphorylation of PEDF, and found that a PEDF mutant mimicking the CK2-phosphorylated PEDF cannot be phosphorylated by PKA, while the mutant mimicking the PKA-phosphorylated PEDF is a good CK2 substrate. Using triple mutants that mimic the PKA- and CK2-phosphorylated and nonphosphorylated PEDF, we found that PEDF can induce several distinct cellular activities dependent on its phosphorylation. The mutant mimicking the accumulative PKA plus CK2 phosphorylation exhibited the strongest antiangiogenic and neurotrophic activities, while the mutants mimicking the individual phosphorylation site mutants had either a reduced activity or only one of these activities. Thus, differential phosphorylation induces variable effects of PEDF, and therefore contributes to the complexity of PEDF action. It is likely that the triple phosphomimetic mutant can be used to generate effective antiangiogenic or neurotrophic drugs.

Extracellular phosphorylation converts pigment epithelium-derived factor from a neurotrophic to an antiangiogenic factor

The pigment epithelium-derived factor (PEDF) belongs to the superfamily of serine protease inhibitors (serpin). There have been 2 distinct functions attributed to this factor, which can act either as a neurotrophic or as an antiangiogenic factor. Besides its localization in the eye, PEDF was recently reported to be present also in human plasma. We found that PEDF purified from plasma is a phosphoprotein, which is extracellularly phosphorylated by protein kinase CK2 (CK2) and to a lesser degree, intracellularly, by protein kinase A (PKA). CK2 phosphorylates PEDF on 2 main residues, Ser24 and Ser114, and PKA phosphorylates PEDF on one residue only, Ser227. The physiologic relevance of these phosphorylations was determined using phosphorylation site mutants. We found that both CK2 and PKA phosphorylations of PEDF markedly affect its physiologic function. The fully CK2 phosphorylation site mutant S24, 114E abolished PEDF neurotrophic activity but enhanced its antiangiogenic activity, while the PKA phosphorylation site mutant S227E reduced PEDF antiangiogenic activity. This is a novel role of extracellular phosphorylation that is shown here to completely change the nature of PEDF from a neutrophic to an antiangiogenic factor.

Reinventing the wheel of cyclic AMP: novel mechanisms of cAMP signaling

Mechanisms of cAMP signal transduction have been thoroughly investigated for more than 40 years. From the binding of hormonal ligands to their receptors on the outer surface of the plasma membrane to the cytoplasmic activation of effectors, the ensuing cAMP signaling cascades and the nuclear gene regulatory functions, coupled with the structural elucidation of the cAMP-dependent protein kinase (PKA) and in vivo functional characterizations of each of the components of PKA by homologous recombination gene targeting, our understanding of cAMP-mediated signal transduction has reached its pinnacle. Despite this trove of knowledge, some recent findings have emerged that suggest hitherto novel and alternative mechanisms of cAMP action that could increase the signaling bandwidth of cAMP and PKA in cell growth and transcriptional regulation. This article attempts to review some of these novel and unconventional mechanisms of cAMP and PKA signaling, and to generate further enthusiasm in investigating and validating these new frontiers of the cAMP signal transduction pathway.

The PKA phosphorylation of vitronectin: effect on conformation and function

Vitronectin (Vn) stabilizes the inhibitory form of plasminogen activator inhibitor-1 (PAI-1), an important modulator of fibrinolysis. We have previously reported that Vn is specifically phosphorylated by PKA (at Ser378), a kinase we have shown to be released from platelets upon their physiological activation. Here we describe the molecular consequences of this phosphorylation and show (by circular dichroism, and by phosphorylation with casein kinase II) that it acts by modulating the conformation of Vn. The PKA phosphorylation of Vn is enhanced in the presence of either PAI-1, or heparin, or both. This enhanced phosphorylation occurs exclusively on Ser378 as shown with the Vn mutants Ser378Ala and Ser378Glu. The binding of PKA phosphorylated Vn to immobilized PAI-1 and to immobilized plasminogen is shown to be lower than that of Vn. The evidence compiled here suggests that this phosphorylation of Vn can modulate plasminogen activation and consequently control fibrinolysis.

The CK2 phosphorylation of vitronectin. Promotion of cell adhesion via the alpha(v)beta 3-phosphatidylinositol 3-kinase pathway

Phosphorylation of vitronectin (Vn) by casein kinase II was previously shown to occur at Thr50 and Thr57 and to augment a major physiological function of vitronectin-cell adhesion and spreading. Here we show that this phosphorylation increases cell adhesion via the alpha(v)beta3 (not via the alpha(v)beta5 integrin), suggesting that alpha(v)beta3 differs from alpha(v)beta5 in its biorecognition profile. Although both the phospho (CK2-PVn) and non-phospho (Vn) analogs of vitronectin (simulated by mutants Vn(T50E,T57E), and Vn(T50A,T57A), respectively) trigger the alpha(v)beta3 as well as the alpha(v)beta5 integrins, and equally activate the ERK pathway, these two forms are different in their activation of the focal adhesion kinase/phosphatidylinositol 3-kinase (PI3K)/protein kinase B (PKB) pathway. Specifically, we show (i) that, upon exposure of cells to Vn/CK2-PVn, their PKB activation depends on the availability of the alpha(v)beta3 integrin on their surface; (ii) that upon adhesion of the beta3-transfected cells onto the CK2-PVn, the extent of PKB activation coincides with the enhanced adhesion of these cells, and (iii) that both the PKB activation and the elevation in the adhesion of these cells is PI3K-dependent. The occurrence of a cell surface receptor that specifically distinguishes between a phosphorylated and a non-phosphorylated analog of Vn, together with the fact that it preferentially activates a distinct intra-cellular signaling pathway, suggest that extra-cellular CK2 phosphorylation may play an important role in the regulation of cell adhesion and migration.

Localization of protein kinase A and vitronectin in resting platelets and their translocation onto fibrin fibers during clot formation

Physiological stimulation of platelets with thrombin brings about the release of protein kinase A (PKA) into the plasma. In human blood, this kinase singles out and phosphorylates vitronectin (Vn), a multifunctional regulatory protein, which was proposed to play an important role in the control of fibrinolysis. Here we present immuno-cytochemical evidence to show: (i) that intact platelets possess on their surface an ecto-PKA which can preferentially phosphorylate Vn; (ii) that in the resting platelet, both the catalytic and the regulatory subunits of PKA are present on the platelet surface, in the surface-connected canalicular system, and within the alpha-granules of the platelets; (iii) that the process initiated upon platelet activation, which leads to the formation of fibrin fibers and consequently forms the fibrin net, is accompanied by a translocation of PKA, of Vn, and of PAI-1 onto the fibrin fibers. We propose that the localization and the translocation of these proteins in the fibrin net, together with our finding that PKA phosphorylation of Vn reduces its grip of PAI-1, can unleash PAI-1 in its free form. The free PAI-1 can then assume its latent (non inhibitory) conformation, allow plasminogen activators to trigger the formation of active plasmin, and to initiate fibrinolysis.

Phosphorylation of vitronectin by casein kinase II. Identification of the sites and their promotion of cell adhesion and spreading

The cell adhesion protein vitronectin (Vn) was previously shown to be the major target in human blood for an extracellular protein kinase A, which is released from platelets upon their physiological stimulation with thrombin and also prevails as an ectoenzyme in several other types of blood cells. Because plasma Vn was shown to have only one protein kinase A phosphorylation site (Ser378) but to contain approximately 3 mol of covalently bound phosphate, and because human serum and blood cells were shown to contain also a casein kinase II (CKII) on their surface, we studied the phosphorylation of Vn by CKII attempting to find out whether such phosphorylation modulates Vn function, an acid test for its having a physiological relevance. Here we show (i) that the CKII phosphorylation of Vn has a Km of 0.5-2 microM (lower than the Vn concentration in blood, 3-6 microM), (ii) that it is targeted to Thr50 and Thr57, which are vicinal to the RGD site of Vn, and (iii) that the phosphorylation of Thr57 facilitates the phosphorylation of Thr50. The maximal stoichiometry of the CKII phosphorylation of plasma Vn was found to be low, which, in principle, could be due to its partial prephosphorylation in vivo. However, for the detection of a functional modulation, we needed a comparison between a fully phosphorylated Vn (at Thr57 and Thr50) and a nonphosphorylated Vn. Therefore, we expressed Vn in a baculovirus system and show (i) that the CKII phosphorylation of wt-Vn enhances the adhesion of bovine aorta endothelial cells; (ii) that the double mutant T50E/T57E (in which the neutral Thr residues are replaced by the negatively charged Glu residues considered analogs of Thr-P) has a significantly enhanced capacity to promote cell adhesion and to accelerate cell spreading when compared with either wild-type Vn or to the neutral T50A/T57A mutant; and (iii) that, at least in the case of bovine aorta endothelial cells, the T50E/T57E mutant exhibits an enhanced adhesion, which seems to be due to an increased affinity toward the alphav beta3 Vn receptors.

Identification and partial characterization of factor Va heavy chain kinase from human platelets

Factor Va, the essential cofactor for prothrombinase, is phosphorylated on the acidic COOH terminus of the heavy chain of the cofactor, at Ser692, by a platelet membrane-associated casein kinase II (CKII). Consistent with this observation, phosphorylation of the factor Va heavy chain by the platelet kinase was inhibited by heparin. The membrane-associated platelet CKII kinase was partially purified using heparin-agarose, phosphocellulose, and ion exchange chromatography. CKII antigen was monitored using a polyclonal antibody to the alpha-subunit, and kinase activity in the various fractions was confirmed using human factor Va as a substrate. Immunoblotting experiments using polyclonal antibodies raised against synthetic peptides mimicking a portion of the deduced amino acid sequence of the alpha-, alpha'-, and beta-subunits of human CKII demonstrated the coexistence of both alpha- and alpha'-subunits in platelets and suggested that the platelet CKII kinase may exist in part as an alpha alpha'beta2 complex. It is also possible that there are two distinct populations of CKII in platelets, one that is alphaalpha/betabeta and one that is alpha'alpha'/betabeta. In the presence of the purified platelet-derived CKII, human factor Va incorporates between 0.8 and 1.3 mol of phosphate/mol of factor Va depending on the concentration of the beta-subunit in the kinase preparation. A peptide mimicking the sequence 687-705 of the human factor V molecule incorporates radioactivity in the presence of purified CKII and inhibits factor Va heavy chain phosphorylation by the platelet CKII. In contrast, a peptide with an alanine instead of a serine at position 692 neither incorporates phosphate nor inhibits factor Va phosphorylation by the platelet CKII. Human factor Va is inactivated by activated protein C following three cleavages of the heavy chain at Arg506, Arg306, and Arg679. Cleavage at Arg506 is necessary for efficient exposure of the inactivating cleavage site at Arg306. The phosphorylated cofactor has increased susceptibility to inactivation by activated protein C, since phosphorylated factor Va was found to be inactivated approximately 3-fold faster than its native counterpart. Acceleration of the inactivation process of the phosphorylated cofactor occurs because of acceleration of the rate of cleavage at Arg506. These data suggest a critical role for factor Va phosphorylation on the surface of platelets in regulating cofactor activity.

The cluster of basic amino acids in vitronectin contributes to its binding of plasminogen activator inhibitor-1: evidence from thrombin-, elastase- and plasmin-cleaved vitronectins and anti-peptide antibodies

Derivatives of vitronectin obtained by specific cleavage at its cluster of basic amino acids with thrombin, elastase and plasmin are shown to have a decreased ability to bind plasminogen activator inhibitor-1 (PAI-1). The identification and localization of the segment involved in the binding of PAI-1 (Lys348-Arg379) were carried out by purification of these cleaved vitronectins and their subsequent structural characterization (sequence analysis, phosphorylation of Ser378 with cAMP-dependent protein kinase and immunostaining with peptide-specific antibodies), then measurement of the vitronectin-PAI-1 interaction by (a) a two-phase system (ELISA); (b) co-precipitation of the vitronectin-PAI-1 complex out of solution, and (c) analysis of the stereospecific interaction between the active conformation of PAI-1 and a peptide derived from the above-mentioned cluster; this interaction occurs when the peptide is composed of all-l-amino acids but not when it is composed of all-d-amino acids. Our results explain why workers who have used immobilized vitronectin to study this interaction could not have observed the involvement of the cluster of basic amino acids in PAI-1 binding, since the immobilization of vitronectin is shown to render this cluster inaccessible for interaction. We propose that vitronectin binds active PAI-1 by interaction via amino acid residues that originate from distal locations in the N- and C-termini of vitronectin.

Phosphorylation of vitronectin on Ser362 by protein kinase C attenuates its cleavage by plasmin

Vitronectin, found in the extracellular matrix and in circulating blood, has an important role in the control of plasminogen activation. It was shown to be the major protein substrate in human blood fluid for a protein kinase A (PKA) released from platelets upon their physiological stimulation with thrombin. Since vitronectin was shown to have only one PKA phosphorylation site, but to contain 2-3 mol covalently bound phosphate, it was reasonable to assume that other protein kinases might phosphorylate vitronectin at other sites in the protein. We have reported earlier that human serum contains at least three protein kinases, one of which was found to be cAMP independent and to phosphorylate a repertoire of plasma proteins that was very similar to that obtained upon phosphorylation of human plasma with protein kinase C (PKC). Since there are now several examples of proteins with extracellular functions that are phosphorylated by PKC, we undertook to study the phosphorylation of vitronectin by PKC. Here, we show that vitronectin is a substrate for PKC, and characterize the kinetic parameters of this phosphorylation (Km approximately tenfold lower than the concentration of vitronectin in blood), indicating that, from the biochemical point of view, this phosphorylation can occur at the locus of a hemostatic event. We also identify Ser362 as the major PKC phosphorylation site in vitronectin, and confirm this localization by means of synthetic peptides derived from the cluster of basic amino acids in vitronectin surrounding Ser362. We show that the PKC phosphorylation at Ser362 alters the functional properties of vitronectin, attenuating its cleavage by plasmin at Arg361-Ser362. This phosphorylation has the potential to regulate plasmin production from plasminogen by a feedback mechanism involving the above-mentioned plasmin cleavage, a loosening of the vitronectin grip on inhibitor 1 of plasminogen activators, and a subsequent latency of this regulatory inhibitor.

The cleavage of protein kinase A by the kinase-splitting membranal proteinase is reproduced by meprin beta

The Kinase-Splitting Membranal Proteinase (KSMP) is a metallo-endoproteinase that clips off the carboxyl terminus tail of the catalytic (C) subunit of protein kinase A to yield a truncated, catalytically inactive protein (C'). Here we report (a) a new procedure for the purification of KSMP, yielding a major protein band in SDS-polyacrylamide gel electrophoresis that correlates with the characteristic KSMP activity; (b) the sequence of tryptic peptides obtained from this band, suggesting an identity between this protein and meprin beta; (c) the immuno-detection by specific anti-peptide antibodies of both the alpha and the beta subunits of meprin in KSMP preparations; (d) the stable expression of meprin beta in a mammalian cell line (293) to establish a clone that constitutively expresses the full-length precursor of meprin beta; and (e) the optimalization of the proteolytic activation of this precursor to obtain an enzyme exhibiting the specific KSMP cleavage, suggesting that KSMP is either derived from, or identical with, the meprin beta gene product. It is hoped that these results will shed light on the possible physiological role of KSMP and the way it may affect protein kinase A-mediated processes.

Evidence for cAMP-dependent platelet ectoprotein kinase activity that phosphorylates platelet glycoprotein IV (CD36)

The dephosphorylating enzyme alkaline phosphatase, by removing phosphate groups from the external platelet membrane proteins, modulates platelet activation (Hatmi, M., Haye, B., Gavaret, J. M., Vargaftig, B. B., and Jacquemin, C. (1991) Br. J. Pharmacol. 104, 554-558). This observation, together with findings reported by others (Ehrlich, Y. H., Davis, T. B., Bock, E., Kornecki, E., and Lenox, R. H. (1986) Nature 320, 67-70; Dusenbery, K. E., Mendiola, J. R., and Skubitz, K. M. (1988) Biochem. Biophys. Res. Commun. 153, 7-13), indicate the existence of ectoprotein kinase activity on the blood platelet surface. In this study, we demonstrate that washed human platelets phosphorylate the synthetic heptapeptide kemptide in a cAMP-dependent mode. The intensity of the phosphorylation was concentration-dependent for kemptide. In addition, incubation of platelets with [gamma-32P]ATP resulted in a rapid incorporation of [32P] phosphate into proteins at the outer membrane surface that was sensitive to alkaline phosphatase treatment. When cAMP was added to the medium, major phosphorylation of an 88-kDa ectoprotein occurred. Its isoelectric point determined by isoelectric focusing SDS-polyacrylamide gel electrophoresis was around pH 6.2. Phosphorylations of this 88-kDa polypeptide and of the exogenous kemptide substrate were both prevented by the specific protein kinase A inhibitor peptide. When platelets were preincubated with [32P]inorganic phosphate to label intracellular proteins, the protein phosphorylation pattern was different from that obtained with [gamma-32P]ATP, indicating that the latter occurred at the outer surface of the cells. Prostacyclin, which induces the increase of intracellular cAMP levels and, consequently, its liberation into the extracellular medium, increased phosphorylation of both kemptide and platelet 88-kDa polypeptide. The major protein of 88-kDa, which was phosphorylated in the presence of cAMP and external [gamma-32P]ATP, was identified by immunoprecipitation to GPIV (CD36), one of thrombospondin and collagen binding sites on platelets. The phosphorylation of CD36 also occurred in platelet-rich plasma, suggesting a physiological role for this ectoenzyme. In the present study, we clearly demonstrate the presence of an ectoprotein kinase A activity at the surface of intact human platelets, and we revealed its principal endogenous substrate as being CD36.

Evidence for an extra-cellular function for protein kinase A

In addition to its intra-cellular functions, cAMP-dependent protein kinase (PKA) may well have an extra-cellular regulatory role in blood. This suggestion is based on the following experimental findings: (a) Physiological stimulation of blood platelets brings about a specific release of PKA, together with its co-substrates ATP and Mg++; (b) In human serum, an endogenous phosphorylation of one protein (p75, M(r) 75 kDa) occurs; this phosphorylation is enhanced by addition of cAMP and blocked by the Walsh-Krebs specific PKA inhibitor; (c) No endogenous phosphorylation of p75 occurs in human plasma devoid of platelets, but the selective labeling of p75 can be reproduced by adding to plasma the pure catalytic subunit of PKA; (d) p75 was shown to be vitronectin (V), a multifunctional protein implicated in processes associated with platelet activation, and thus a protein whose function may require modulation for control; (e) The phosphorylation of vitronectin occurs at one site (Ser378) which, at physiological pH, is buried in its two-chain form (V65 + 10) but it becomes 'exposed' in the presence of glycosaminoglycans (GAGs) e.g. heparin or heparan sulfate. Such a transconformation may be used for targeting the PKA phosphorylation to vitronectin molecules bound to GAGs, for example in the extracellular matrix or on cell surfaces; (f) From the biochemical point of view (Km values and physiological concentrations) the phosphorylation of vitronectin can take place at the locus of a hemostatic event; (g) The phosphorylation of Ser378 in vitronectin alters its function, since it significantly reduces its ability to bind the inhibitor-1 of plasminogen activator(s) (PAI-1).(ABSTRACT TRUNCATED AT 250 WORDS)

Synthetic peptides derived from the sequence around the plasmin cleavage site in vitronectin. Use in mapping the PAI-1 binding site

A series of 8 peptides derived from the amino acid sequence accommodating the plasmin cleavage site in vitronectin were synthesized and used to map its binding site for the type I plasminogen activator inhibitor (PAI-1). This mapping assigned the inhibitor binding site to the K348-R370 region with high affinity recognition elements within the K348-R357 sequence. These results account for our previous finding that cleavage of the R361-S362 bond by plasmin significantly reduces the affinity between PAI-1 and vitronectin, since it splits the PAI-1 binding site in two. Furthermore, in the case of the two-chain form of vitronectin, this cleavage detaches the S362-R379 peptide which provides some of the affinity elements for the binding of PAI-1.

Ecto-phosphorylation on aortic endothelial cells. Exquisite sensitivity to staurosporine

One- and two-dimensional gel electrophoresis of proteins from bovine aortic endothelial cells (BAEC) incubated with [gamma-32P]ATP revealed the preferential labelling of a cell-associated 21 kDa substrate. The labelling of this band was detectable within 30 s, increased up to 30 min and was stable for at least 3 h following the wash-out of the ATP. This protein was also labelled after incubation of the cells with [gamma-35S]ATP. Incorporation of radioactivity into the 21 kDa band did not occur if the endothelial cells were treated with low concentrations of trypsin (0.01%) before or after the labelling period. The pattern of BAEC protein phosphorylation by [gamma-32P]ATP was completely different from that of the fetal calf serum used for the cell culture. The presence of serum during the incubation of BAEC with [gamma-32P]ATP did not modify qualitatively the labelling pattern and, in particular, did not enhance the phosphorylation of the 21 kDa substrate; this suggests that neither the kinase nor the 21 kDa substrate are adsorbed serum proteins. Staurosporine, a protein kinase inhibitor with low specificity, decreased the labelling of the 21 kDa protein with an IC50 of 2 nM. In contrast, at 100 nM, staurosporine did not decrease the accumulation of inositol phosphates induced by ATP via the activation of P2y receptors. These data indicate the presence of aortic endothelial cells of an ecto-kinase which uses extracellular ATP to produce the selective and long-lived phosphorylation of a 21 kDa endothelial substrate. Ecto-phosphorylation of this protein might play a role in the modulation of endothelial cell functions by ATP, in addition to the P2y receptors [Boeynaems & Pearson (1990) Trends Pharmacol. Sci. 11, 34-37]. The exquisite sensitivity of ecto-phosphorylation to inhibition by staurosporine and its specific inhibition by some isoquinolinesulphonamide compounds provide potential pharmacological tools to investigate this hypothesis.

A cAMP-binding ectoprotein in the yeast Saccharomyces cerevisiae

Purified plasma membranes from the yeast Saccharomyces cerevisiae bind about 1.2 pmol of cAMP/mg of protein with high affinity (Kd = 6 nM). By using photoaffinity labeling with 8-N3-[32P]cAMP, we have identified in plasma membrane vesicles a cAMP-binding protein (Mr = 54,000) that is present also in bcy1 disruption mutants, lacking the cytoplasmic R subunit of protein kinase A (PKA). This argues that it is genetically unrelated to PKA. Neither high salt, nor alkaline carbonate, nor cAMP extract the protein from the membrane, suggesting that it is not peripherally bound. The observation that (glycosyl)phosphatidylinositol-specific phospholipases (or nitrous acid) release the amphiphilic protein from the membrane, thereby converting it to a hydrophilic form, indicates anchorage by a glycolipidic membrane anchor. Treatment with N-glycanase reduces the Mr to 44,000-46,000 indicative of a modification by N-linked carbohydrate side chain(s). In addition to the action of a phospholipase, the efficient release from the membrane requires the removal of the carbohydrate side chain(s) or the presence of high salt or methyl alpha-mannopyranoside, suggesting complex interactions with the membrane involving not only the glycolipidic anchor but also the glycan side chain(s). Topological studies show that the protein is exposed to the periplasmic space, raising intriguing questions for the function of this protein.

Plasmin cleavage of vitronectin. Identification of the site and consequent attenuation in binding plasminogen activator inhibitor-1

Plasmin is shown to specifically cleave vitronectin at the Arg361-Ser362 bond, 18 amino acid residues upstream from the site of the endogenous cleavage which gives rise to the two-chain form of vitronectin in plasma. The cleavage site is established using the exclusive phosphorylation of Ser378 with protein kinase A. As a result of the plasmin cleavage, the affinity between vitronectin and the type-1 inhibitor of plasminogen activator (PAI-1) is significantly reduced. This cleavage is stimulated by glycosaminoglycans, which are known to anchor vitronectin to the extracellular matrix. A mechanism is proposed through which plasmin can arrest its own production by feedback signalling, unleashing PAI-1 from the immobilized vitronectin found in the vascular subendothelium, which becomes exposed at the locus of a hemostatic event.

Endogenous cleavage of the Arg-379-Ala-380 bond in vitronectin results in a distinct conformational change which 'buries' Ser-378, its site of phosphorylation by protein kinase A

Activation of blood platelets by thrombin was previously shown to specifically release protein kinase A, which in human plasma singles out and phosphorylates one protein, identified as vitronectin. This protein is known to be involved in processes that follow platelet stimulation, specifically, in the binding of heparin (interfering with the heparin-mediated inhibition of thrombin and Factor Xa by antithrombin III), in the growth of endothelial cells and in fibrinolysis. This paper shows that phosphorylation of vitronectin by protein kinase A is stoichiometric (approx. 1 mol/mol), that it is targeted to one site (Ser-378) at the C-terminal edge of the heparin-binding domain, and that it distinguishes between the two physiologically occurring forms of vitronectin: the one-chain (75 kDa) form, and the nicked two-chain (65 + 10 kDa) form, held together by an interchain disulphide bridge. Protein kinase A phosphorylates the one-chain form but not the two-chain form, although Ser-378 and the complete recognition sequence of the kinase are still present in the clipped 65 kDa chain. Cleavage of the Arg-379-Ala-380 bond results therefore in a conformationally distinct form of vitronectin in which Ser-378 is 'buried'. This is demonstrated by our finding that Ser-378 is present in the 65 kDa chain of clipped vitronectin but inaccessible to phosphorylation at physiological pH. Upon binding heparin, the phosphorylation site becomes exposed and able to undergo a stoichiometric phosphorylation at physiological pH.

The phosphorylation of the two-chain form of vitronectin by protein kinase A is heparin dependent

In circulating blood, vitronectin occurs in two forms: a single-chain (75 kDa) and an endogenously clipped two-chain form (65 kDa and 10 kDa) held together by a disulfide bridge. The 75 kDa form was previously shown to be phosphorylated at Ser378 by protein kinase A, released by physiologically stimulated platelets. By contrast, at pH 7.5 the two-chain form is not phosphorylated at all. Heparin or heparan sulfate are shown here to modulate the conformation of clipped vitronectin at physiological pH, exposing Ser378 and allowing its stoichiometric phosphorylation by the kinase. At this pH the two-chain form of vitronectin in plasma exhibits a higher affinity for heparin, and behaves as a flexible molecule, which can conformationally respond to heparin and heparan sulfate, effectors involved in vitronectin function.

Phosphorylation of complement factor C3 in vivo

Complement factor C3, the central protein of the complement system, was found to be phosphorylated both in EDTA- and heparin-anticoagulated whole blood and in coagulating blood. Complement S protein (vitronectin) was also found to be phosphorylated under these conditions. Further, purified C3 was found to be a phosphoprotein in vivo, containing 0.15 mol of alkali-labile phosphate/mol of protein. The ATP concentration in plasma was measured and found to be about 2 microM.

A cAMP-triggered release of a hormone-like peptide

Preparations of the catalytic subunit of cAMP-dependent protein kinase from rabbit skeletal muscle, which appear to be homogeneous by SDS-polyacrylamide gel electrophoresis, were often found to contain a hormone-like factor (HLF) which causes an immediate rise, then a decline of intracellular cAMP in a B-lymphoma cell line. Active HLF is released when the fractions that contain it in an inactive form are incubated with cAMP prior to chromatography, or passed through an immobilized cAMP column. HLF seems to be a peptide: it loses its cell-stimulating capability after proteolysis and has an apparent molecular mass of 2.2-2.5 kDa.