Acylation of the lymphoma transmembrane glycoprotein, GP85, may be required for GP85-ankyrin interaction.

The lymphoma plasma membrane glycoprotein, GP85, is a transmembrane glycoprotein that binds directly to ankyrin, a molecule known to link the plasma membrane with the underlying cytoskeleton. In this study, we have demonstrated that palmitic acid is incorporated into GP85 in vivo and that the amount of palmitic acid incorporated is greatly stimulated during lymphoma cap formation. The majority of the incorporated palmitic acid appears to be strongly linked to GP85 since it is not dissociated by strong detergents (e.g. sodium dodecyl sulfate) or by chloroform/methanol extraction, but is labile to alkaline or acid hydrolysis. Furthermore, we have established that deacylation of GP85 (i.e. removal of the palmitic acid moiety from GP85 by 1 M hydroxylamine treatment) significantly reduces the binding affinity between GP85 and ankyrin, and reacylation of GP85 restores the binding affinity. These findings suggest that fatty acid acylation of GP85 by palmitic acid may be required for the stable attachment of the cytoskeleton to the lymphoma plasma membrane.     

Mouse T lymphoma cells contain a transmembrane glycoprotein (GP85) that binds ankyrin

In this study we have used complementary biochemical and immunological techniques to establish that the lymphoma GP85 membrane glycoprotein is a transmembrane protein with a cytoplasmic domain that binds directly to ankyrin, a molecule known to link the membrane to the cytoskeleton. The evidence supporting our conclusion that the GP85 is a transmembrane glycoprotein is as follows: (a) GP85 can be surface-labeled with Na 125I and contains wheat germ agglutinin-binding sites, indicating that it has an extracellular domain; (b) GP85 can be phosphorylated by intracellular kinases, indicating that it has an intracellular domain; and (c) GP85 can be successfully incorporated into phospholipid vesicles, indicating the existence of a hydrophobic domain in the molecule. Further studies show that GP85 displays immunological cross-reactivity with the lymphocyte Pgp-1 (differentiation-specific) membrane glycoprotein, and with the erythrocyte anion transport membrane protein, band 3. Immunocytochemical studies indicate that an ankyrin-like protein accumulates underneath the lymphoma GP85 cap structure, suggesting an association of the ankyrin-like protein and GP85. This relationship has been further confirmed by the following results of binding and reconstitution experiments: (a) purified GP85 binds directly to an ankyrin-Sepharose column; (b) purified GP85 inserts into phospholipid vesicles in both the normal (right side out) and reversed (inside out) orientation (and with only the reversed configuration permits binding of ankyrin to GP85); and (c) cleavage of GP85 with trypsin yields a 40-kD peptide fragment that is part of the cytoplasmic domain and contains the ankyrin binding site(s). Based on these findings, we suggest that the lymphoma GP85 transmembrane glycoprotein contains a cytoplasmic domain that is directly involved in linking ankyrin to the cytoskeleton. This transmembrane linkage may play a pivotal role in receptor capping and cell activation in lymphocytes.     

A CD44-like endothelial cell transmembrane glycoprotein (GP116) interacts with extracellular matrix and ankyrin.

We used complementary biochemical and immunological techniques to establish that an endothelial cell transmembrane glycoprotein, GP116, is a CD44-like molecule and binds directly both to extracellular matrix components (e.g., hyaluronic acid) and to ankyrin. The specific characteristics of GP116 are as follows: (i) GP116 can be surface labeled with Na 125I and contains a wheat germ agglutinin-binding site(s), indicating that it has an extracellular domain; (ii) GP116 displays immunological cross-reactivity with a panel of CD44 antibodies, shares some peptide similarity with CD44, and has a similar 52-kDa precursor molecule, indicating that it is a CD44-like molecule; (iii) GP116 displays specific hyaluronic acid-binding properties, indicating that it is a hyaluronic acid receptor; (iv) GP116 can be phosphorylated by endogenous protein kinase C activated by 12-O-tetradecanoylphorbol-13-acetate and by exogenously added protein kinase C; and (v) GP116 and a 20-kDa tryptic polypeptide fragment of GP116 from the intracellular domain are capable of binding the membrane-cytoskeleton linker molecule, ankyrin. Furthermore, phosphorylation of GP116 by protein kinase C significantly enhances GP116 binding to ankyrin. Together, these findings strongly suggest that phosphorylation of the transmembrane glycoprotein GP116 (a CD44-like molecule) by protein kinase C is required for effective GP116-ankyrin interaction during endothelial cell adhesion events.     

The lymphoma transmembrane glycoprotein GP85 (CD44) is a novel guanine nucleotide-binding protein which regulates GP85 (CD44)-ankyrin interaction.

In this study, we have used photoaffinity labeling by [32P]azido-GTP as well as [32P]ADP-ribosylation by pertussis toxin (PT) and cholera toxin (CT) to identify GTP-binding proteins associated with mouse T-lymphoma plasma membranes. Our results indicate that GP85 (CD44) can be photoaffinity labeled by [32P] azido-GTP and [32P]ADP-ribosylated by both PT and CT. Using purified GP85 (CD44) obtained by Triton X-100 extraction, wheat germ agglutinin-Sepharose, and anti-GP85 (CD44) antibody affinity chromatographies, we have further characterized GP85 (CD44) as a GTP-binding protein. GP85 (CD44) is found to bind guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) in a time- and dose-dependent manner with a dissociation constant of 0.83 nM. Importantly, GP85 (CD44) appears to display a GTPase activity which hydrolyzes [gamma-32P]GTP at a rate of 0.011 mol of Pi released/mol of GP85 (CD44)/min. This GTPase activity can be readily inhibited by PT- or CT-mediated ribosylation of GP85 (CD44). Most interestingly, GTP binding significantly enhances the interaction of purified GP85 (CD44) with ankyrin, whereas ADP-ribosylation of GP85 (CD44) by PT or CT inhibits the GTP-induced increase in ankyrin binding to GP85 (CD44). In addition to GP85 (CD44) being the first reported transmembrane GTP-binding protein, these results suggest that GTP plays an important role in promoting the interaction between GP85 (CD44) and its underlying membrane cytoskeleton through ankyrin.     

Post-translational protein modification and expression of ankyrin-binding site(s) in GP85 (Pgp-1/CD44) and its biosynthetic precursors during T-lymphoma membrane biosynthesis.

In this study, we have investigated the biosynthesis and processing of GP85 (Pgp-1/CD44), a lymphoma transmembrane glycoprotein known to contain ankyrin-binding site(s). Using a standard pulse-chase protocol, we have detected a 52-kDa polypeptide precursor (p52) within the first 5 min of pulse labeling which contains a high mannose-type N-linked oligosaccharide chains. The conversion of p52 to GP85 requires further glycosylation (both complex type N-linked and O-linked) which takes place in the Golgi complex within 10-20 min after p52 is synthesized. GP85 is then incorporated into the plasma membrane where its turnover rate is relatively slow, a t1/2 of approximately 8 h. Following tunicamycin treatment, we have detected two other precursor proteins: p42 which is unglycosylated and p58 which is O-glycosylated. p42 appears to be an immediate precursor of p52 because p52 is converted to p42 upon deglycosylation. Therefore, the biosynthesis of GP85 appears to occur in the following sequence: p42 in equilibrium to p52 in equilibrium to GP85. Further analysis reveals that all of the GP85 precursors (i.e. p42, p52, and p58) contain ankyrin-binding site(s). Chemical composition analysis of GP85 indicates that this molecule contains approximately 3 N-linked and 4-5 O-linked oligosaccharide chains. Although neither N-glycosylation nor O-glycosylation appears to play an important role in the formation of ankyrin-binding site(s), O-glycosylation (and to a lesser extent N-glycosylation) of GP85 is required for T-lymphoma cell surface interaction with both collagen and hyaluronic acid. These findings suggest that GP85 (Pgp-1/CD44) and its biosynthetic precursors play a pivotal role in regulating adhesion functions such as lymphocyte homing and binding to the extracellular matrix.     

Importance of protein kinase C targeting for the phosphorylation of its substrate, myristoylated alanine-rich C-kinase substrate

We visualized the translocation of myristoylated alanine-rich protein kinase C substrate (MARCKS) in living Chinese hamster ovary-K1 cells using MARCKS tagged to green fluorescent protein (MARCKS-GFP). MARCKS-GFP was rapidly translocated from the plasma membrane to the cytoplasm after the treatment with phorbol ester, which translocates protein kinase C (PKC) to the plasma membrane. In contrast, PKC activation by hydrogen peroxide, which was not accompanied by PKC translocation, did not alter the intracellular localization of MARCKS-GFP. Non-myristoylated mutant of MARCKS-GFP was distributed throughout the cytoplasm, including the nucleoplasm, and was not translocated by phorbol ester or by hydrogen peroxide. Phosphorylation of wild-type MARCKS-GFP was observed in cells treated with phorbol ester but not with hydrogen peroxide, whereas non-myristoylated mutant of MARCKS-GFP was phosphorylated in cells treated with hydrogen peroxide but not with phorbol ester. Phosphorylation of both MARCKS-GFPs reduced the amount of F-actin. These findings revealed that PKC targeting to the plasma membrane is required for the phosphorylation of membrane-associated MARCKS and that a mutant MARCKS existing in the cytoplasm can be phosphorylated by PKC activated in the cytoplasm without translocation but not by PKC targeted to the membrane.     

Protein kinase C regulates MARCKS cycling between the plasma membrane and lysosomes in fibroblasts.

MARCKS is a protein kinase C (PKC) substrate that is phosphorylated during neurosecretion, phagocyte activation and growth factor-dependent mitogenesis. MARCKS binds calcium/calmodulin and crosslinks F-actin, and both these activities are regulated by PKC-dependent phosphorylation. We present evidence here that PKC-dependent phosphorylation also regulates the cycling of MARCKS between the plasma membrane and Lamp-1-positive lysosomes. Immuno-fluorescence and immunoelectron microscopy, and subcellular fractionation, demonstrated that MARCKS was predominantly associated with the plasma membrane of resting fibroblasts. Activation of PKC resulted in MARCKS phosphorylation and its displacement from the plasma membrane to Lamp-1-positive lysosomes. MARCKS phosphorylation is required for its translocation to lysosomes since mutating either the serine residues phosphorylated by PKC (phos-) or the PKC inhibitor staurosporine, prevented MARCKS phosphorylation, its release from the plasma membrane, and its subsequent association with lysosomes. In the presence of lysosomotropic agents or nocodazole, MARCKS accumulated on lysosomes and returned to the plasma membrane upon drug removal, further suggesting that the protein cycles between the plasma membrane and lysosomes. In contrast to wild-type MARCKS, the phos- mutant did not accumulate on lysosomes in cells treated with NH4Cl, suggesting that basal phosphorylation of MARCKS promotes its constitutive cycling between these two compartments.     

Phorbol ester-induced phosphorylation of a transmembrane glycoprotein (GP 180) in human blood platelets

In this study we have used (phorbol-12-O-tetradecanoylphorbol 13-acetate) and its biologically inactive analogue, 4 alpha-phorbol 12,13-didecanoate), to investigate platelet protein phosphorylation with special emphasis on the properties of a membrane protein-cytoskeleton (transmembrane) complex during platelet activation. Our data indicate that phorbol-12-O-tetradecanoylphorbol 13-acetate (but not 4 alpha-phorbol 12,13-didecanoate) induces both a specific platelet shape change and the preferential phosphorylation of a 180-kDa protein (presumably due to the activation of protein kinase C on the cytoplasmic side of the membrane). Further analysis reveals that the 180-kDa protein can be iodinated by lactoperoxidase and is sensitive to trypsin treatment, indicating exposure of this protein on the outer cell surface. The 180-kDa protein has also been found to contain wheat germ agglutinin-binding sites. All evidence indicates that the 180-kDa polypeptide is a transmembrane glycoprotein and, most importantly, that this protein is found to be preferentially accumulated into a specific membrane-cytoskeleton complex during activation via phorbol-12-O-tetradecanoylphorbol 13-acetate treatment. We believe that the observed phosphorylation of this protein may be closely related to the formation of a complex between several membrane proteins and the cytoskeleton during the initial stages of platelet activation.     

Activation of Protein Kinase C-α and Translocation of the Myristoylated Alanine-Rich C-Kinase Substrate Correlate with Phorbol Ester-Enhanced Noradrenaline Release from SH-SY5Y Human Neuroblastoma Cells

Abstract: The aim of this study was to investigate the mechanism by which short-term pretreatment with the phorbol ester 12- O -tetradecanoylphorbol 13-acetate (TPA; 100 n M ) enhances noradrenaline (NA) release from the human neuroblastoma cell line SH-SY5Y. Subcellular fractionation and immunocytochemical studies demonstrated that an 8-min TPA treatment caused translocation of the α-subtype of protein kinase C (PKC) from the cytosol to the plasma membrane. In contrast, TPA altered the distribution of PKC-ε from cytosolic and membrane-associated to cytoskeleton- and membrane-associated TPA had no effect on the cytosolic location of PKC-ζ. Subcellular fractionation studies also showed that the myristoylated alanine-rich C-kinase substrate (MARCKS), a major neuronal PKC substrate that has been implicated in the mechanism of neurotransmitter release, translocated from membranes to cytosol in response to an 8-min TPA treatment. Under these conditions the level of phosphorylation of MARCKS increased threefold. The ability of TPA to enhance NA release and to cause the translocation and phosphorylation of MARCKS was inhibited by the PKC inhibitor Ro 31-8220 (10 µ M ). Selective down-regulation of PKC subtypes by prolonged exposure to phorbol 12,13-dibutyrate (100 n M ) attenuated the TPA-induced enhancement of NA release and the translocation of MARCKS over an interval similar to that of down-regulation of PKC-α (but not -ε or -ζ). Thus, we have demonstrated a strong correlation between the translocation of MARCKS and the enhancement of NA release from SH-SY5Y cells due to the TPA-induced activation of PKC-α.     

Atrial natriuretic factor inhibits autophosphorylation of protein kinase C and A 240-kDa protein in plasma membranes of bovine adrenal glomerulose cells: Involvement of cGMP-dependent and independent signal transduction mechanisms

To clarify the intracellular signalling mechanisms of atrial natriuretic factor (ANF), we studied its effect on protein phosphorylation in plasma membranes of bovine adrenal cortical cells. ANF (1×10^–7 M) inhibited phosphorylation of the 78-kDa protein kinase C (PKC) and a 240-kDa protein in specific manner. In parallel experiments, cGMP (0.5 mM) inhibited phosphorylation of only the 78-kDa PKC but it did not affect phosphorylation of the 240-kDa protein. Phosphorylation of the 78-kDa PKC was enhanced in a Ca²⁺-/phospholipid-dependent manner. However, after prolonged preincubation of plasma membranes with Ca²⁺ (0.5 mM), the incorporation of³²P-radioactivity rapidly decreased in the 78-kDa PKC and subsequently increased in the 45- and 48-kDa protein bands due to Ca²⁺-dependent proteolytic degradation of 78-kDa PKC. Polyclonal antibodies against brain PCK were used to immunoblot and immunoprecipitate the 78-kDa PKC. Preincubation of plasma membranes with Ca²⁺ for varying times, followed by immunoblotting revealed a gradual loss of the immunoreactive 78-kDa PKC band in a time-dependent manner. Immunoprecipitation of phosphorylated 78-kDa PKC in plasma membranes showed that its phosphorylation was significantly inhibited in the presence of ANF as compared to control membranes, phosphorylated in the absence of ANF. The results in this present study document a new signal transduction mechanism of ANF at molecular level which possibly involves dephosphorylation of the 78-kDa PKC and a 240-kDa protein in a cGMP-dependent and-independent manner in bovine adrenal glomerulosa cell membranes. (Mol Cell Biochem141: 103–111, 1994)     

Induction of plasminogen activator activity by phorbol ester in transformed fetal bovine aortic endothelial cells. Possible independence from protein kinase C

12-O-tetradecanoyl phorbol 13-acetate (TPA) and 1,2-dioctanoyl-sn-glycerol (diC8) activate protein kinase C (PKC) in transformed fetal bovine aortic endothelial GM 7373 cells. Both molecules cause a similar increase in membrane-associated PKC activity and in the phosphorylation of a PKC-specific endogenous 87-kDa substrate in intact cells. Even though both TPA and diC8 exert a mitogenic activity in GM 7373 cells, only TPA induces also an increase in cell-associated plasminogen activator (PA) activity. Down-regulation of PKC which follows TPA-pretreatment completely abolishes the mitogenic activity of diC8 and the mitogenic and PA-inducing activity of TPA. However, both the PKC inhibitor H-7 and the down-regulation of PKC which follows a prolonged stimulation with diC8 do not abolish the PA-inducing activity of TPA. The PA-inducing activity of TPA is instead inhibited in cultures incubated in the presence of 1 mM EGTA or in a calcium-free medium. The data indicate that TPA and diC8 induce a different pattern of cellular activation in GM 7373 cells and that the PA-inducing activity of TPA might not be mediated by PKC.     

Endothelin, vasopressin, and angiotensin II enhance tyrosine phosphorylation by protein kinase C-dependent and -independent pathways in glomerular mesangial cells.

Protein tyrosine phosphorylation has not been considered to be important for cellular activation by phospholipase C-linked vasoactive peptides. We found that endothelin, angiotensin II, and vasopressin (AVP), peptides that signal via phospholipase C activation, rapidly enhanced tyrosine phosphorylation of proteins of approximate molecular mass 225, 190, 135, 120, and 70 kDa in rat renal mesangial cells. The phosphorylated proteins were cytosolic or membrane-associated, and none were integral to the membrane, suggesting that the peptide receptors are not phosphorylated on tyrosine. Epidermal growth factor (EGF), which does not activate phospholipase C in these cells, induced the tyrosine phosphorylation of its own 175-kDa receptor, in addition to five proteins of identical molecular mass to those phosphorylated in response to endothelin, AVP, and angiotensin II. This suggests that in mesangial cells there is a common signaling pathway for phospholipase C-coupled agonists and agonists classically assumed to signal via receptor tyrosine kinase pathways, such as EGF. The phorbol ester, phorbol 12-myristate 13-acetate, and the synthetic diacylglycerol, oleoyl acetylglycerol, stimulated the tyrosine phosphorylation of proteins identical to those phosphorylated by the phospholipase C-linked peptides, suggesting that protein kinase C (PKC) activation is sufficient to active tyrosine phosphorylation. However, the PKC inhibitor, staurosporine, and down-regulation of PKC activity by prolonged exposure to phorbol esters completely inhibited tyrosine phosphorylation in response to PMA but not to endothelin, AVP, or EGF. In conclusion, endothelin, angiotensin II, and AVP enhances protein tyrosine phosphorylation via at least two pathways, PKC-dependent and PKC-independent. Although activation of PKC may be sufficient to enhance protein tyrosine phosphorylation, PKC is not necessary and may not be the primary route by which these agents act. At least one of these pathways is shared with the growth factor EGF, suggesting not only common intermediates in the signaling pathways for growth factors and vasoactive peptides but also perhaps common cellular tyrosine kinases which phosphorylate these intermediates.     

Involvement of desmoplakin phosphorylation in the regulation of desmosomes by protein kinase C, in HeLa cells.

In the present study, we have examined how modulation of protein kinase C (PKC) activity affected desmosome organization in HeLa cells. Immunofluorescence and electron microscopy showed that PKC activation upon short exposure to 12-O-tetradecanoylphorbol 13-acetate (TPA) resulted in a reduction of intercellular contacts, splitting of desmosomes and dislocation of desmosomal components from the cell periphery towards the cytoplasm. As determined by immunoblot analysis of Triton X-100-soluble and -insoluble pools of proteins, these morphological changes were not correlated with modifications in the extractability of both desmoglein and plakoglobin, but involved almost complete solubilization of the desmosomal plaque protein, desmoplakin. Immunoprecipitation experiments and immunoblotting with anti-phosphoserine, antiphosphothreonine and anti-phosphotyrosine antibodies revealed that desmoplakin was mainly phosphorylated on serine and tyrosine residues in both treated and untreated cells. While phosphotyrosine content was not affected by PKC activation, phosphorylation on serine residues was increased by about two-fold. This enhanced serine phosphorylation coincided with the increase in the protein solubility, suggesting that phosphorylation of desmoplakin may be a mechanism by which PKC mediates desmosome disassembly. Consistent with the loss of PKC activity, we also showed that down-modulation of the kinase (in response to prolonged TPA treatment) or its specific inhibition (by GF 109203X) had opposite effects and increased desmosome formation. Taken together, these results clearly demonstrate an important role for PKC in the regulation ofdesmosomal junctions in HeLa cells, and identify serine phosphorylation of desmoplakin as a crucial event in this pathway.     

Phosphorylation of Na,K-ATPase alpha-subunits in microsomes and in homogenates of Xenopus oocytes resulting from the stimulation of protein kinase A and protein kinase C.

The phosphorylation of the alpha-subunit of Na+/K(+)-transporting ATPase (Na,K-ATPase) by cAMP-dependent protein kinase (PKA) and protein kinase C (PKC) was characterized in purified enzyme preparations of Bufo marinus kidney and duck salt gland and in microsomes of Xenopus oocytes. In addition, we have examined cAMP and phorbol esters, which are stimulators of PKA and PKC, respectively, for their ability to provoke the phosphorylation of alpha-subunits of Na,K-ATPase in homogenates of Xenopus oocytes. In the enzyme from the duct salt gland, phosphorylation by PKA and PKC occurs on serine and threonine residues, whereas in the enzyme from B. marinus kidney and Xenopus oocytes, phosphorylation by PKA occurs only on serine residues. Phosphopeptide analysis indicates that a site phosphorylated by PKA resides in a 12-kDa fragment comprising the C terminus of the polypeptide. Studies of phosphorylation performed on homogenates of Xenopus oocytes show that not only endogenous oocyte Na,K-ATPase but also exogenous Xenopus Na,K-ATPase expressed in the oocyte by microinjection of cRNA can be phosphorylated in response to stimulation of oocyte PKA and PKC. In conclusion, these data are consistent with the possibility that the alpha-subunit of Na,K-ATPase can serve as a substrate for PKA and PKC in vivo.     

Involvement of Desmoplakin Phosphorylation in the Regulation of Desmosomes by Protein Kinase C,in HeLa Cells

In the present study, we have examined how modulation of protein kinase C (PKC) activity affected desmosome organization in HeLa cells. Immunofluorescence and electron microscopy showed that PKC activation upon short exposure to 12-O-tetradecanoylphorbol 13-acetate (TPA) resulted in a reduction of intercellular contacts, splitting of desmosomes and dislocation of desmosomal components from the cell periphery towards the cytoplasm. As determined by immunoblot analysis of Triton X-100-soluble and -insoluble pools of proteins, these morphological changes were not correlated with modifications in the extractability of both desmoglein and plakoglobin, but involved almost complete solubilization of the desmosomal plaque protein, desmoplakin. Immunoprecipitation experiments and immunoblotting with anti-phosphoserine, anti-phosphothreonine and anti-phosphotyrosine antibodies revealed that desmoplakin was mainly phosphorylated on serine and tyrosine residues in both treated and untreated cells. While phosphotyrosine content was not affected by PKC activation, phosphorylation on serine residues was increased by about two-fold. This enhanced serine phosphorylation coincided with the increase in the protein solubility, suggesting that phosphorylation of desmoplakin may be a mechanism by which PKC mediates desmosome disassembly. Consistent with the loss of PKC activity, we also showed that down-modulation of the kinase (in response to prolonged TPA treatment) or its specific inhibition (by GF109203X) had opposite effects and increased desmosome formation. Taken together, these results clearly demonstrate an important role for PKC in the regulation of desmosomal junctions in HeLa cells, and identify serine phosphorylation of desmoplakin as a crucial event in this pathway.     

Bacterial lipopolysaccharide modulates protein kinase C signalling in Lymnaea stagnalis haemocytes

Our knowledge of cell signalling pathways in the molluscan immune system and their response to immunological challenge is currently poor. The present study focused on the Protein Kinase C (PKC) pathway in the immune cells (haemocytes) of Lymnaea stagnalis and its response following exposure to bacterial lipopolysaccharide (LPS). Western blotting of haemocyte proteins with either anti-PKC (pan) or anti-phospho-PKC (Ser 660) antibodies revealed the presence of two PKC-like immuno-reactive proteins of approximately 76 and 85 kDa. Challenge of haemocytes with LPS transiently increased the phosphorylation of the 85 kDa isoform, with a 2.2-fold increase in phosphorylation levels at 5 min and a return to basal levels after 20 min. This LPS-mediated response was blocked following treatment of haemocytes with GF109203X. PKC activities measured in anti-phospho-PKC immunocomplexes following haemocyte treatment with LPS and GF109203X correlated well with the observed PKC phosphorylation levels. These data show for the first time that the activity of the PKC pathway in molluscan immune cells is modulated by LPS, as it is in mammals, and suggest that cell signalling in the innate immune response may have been conserved through evolution.     

Membrane-targeting sequences on AKAP79 bind phosphatidylinositol-4, 5-bisphosphate.

Protein kinases and phosphatases are targeted through association with anchoring proteins that tether the enzymes to subcellular structures and organelles. Through in situ fluorescent techniques using a Green Fluorescent Protein tag, we have mapped membrane-targeting domains on AKAP79, a multivalent anchoring protein that binds the cAMP-dependent protein kinase (PKA), protein kinase C (PKC) and protein phosphatase 2B, calcineurin (CaN). Three linear sequences termed region A (residues 31-52), region B (residues 76-101) and region C (residues 116-145) mediate targeting of AKAP79 in HEK-293 cells and cortical neurons. Analysis of these targeting sequences suggests that they contain putative phosphorylation sites for PKA and PKC and are rich in basic and hydrophobic amino acids similar to a class of membrane-targeting domains which bind acidic phospholipids and calmodulin. Accordingly, the AKAP79 basic regions mediate binding to membrane vesicles containing acidic phospholipids including phosphatidylinositol-4, 5-bisphosphate [PtdIns(4,5)P2] and this binding is regulated by phosphorylation and calcium-calmodulin. Finally, AKAP79 was shown to be phosphorylated in HEK-293 cells following stimulation of PKA and PKC, and activation of PKC or calmodulin was shown to release AKAP79 from membrane particulate fractions. These findings suggest that AKAP79 might function in cells not only as an anchoring protein but also as a substrate and effector for the anchored kinases and phosphatases.     

Multiple phosphorylation sites in the 165-kilodalton peptide associated with dihydropyridine-sensitive calcium channels

Evidence from electrophysiological and ion flux studies has established that dihydropyridine-sensitive calcium channels are subject to regulation by neurotransmitter-mediated phosphorylation and dephosphorylation reactions. In the present study, we have further characterized the phosphorylation by cAMP-dependent protein kinase and a multifunctional Ca/calmodulin-dependent protein kinase of the membrane-associated form of the 165-kDa polypeptide identified as the skeletal muscle dihydropyridine receptor. The initial rates of phosphorylation of the 165-kDa peptide by both protein kinases were found to be relatively good compared to the rates of phosphorylation of established substrates of the enzymes. Phosphorylation of the 165-kDa peptide by both protein kinases was additive. Prior phosphorylation by either one of the kinases alone did not preclude phosphorylation by the second kinase. The cAMP-dependent protein kinase phosphorylated the 165-kDa peptide preferentially at serine residues, although a small amount of phosphothreonine was also formed. In contrast, after phosphorylation of the 165-kDa peptide by the Ca/calmodulin-dependent protein kinase, slightly more phosphothreonine than phosphoserine was recovered. Phosphopeptide mapping indicated that the two kinases phosphorylated the peptide at distinct as well as similar sites. Notably, one major site phosphorylated by the cAMP-dependent protein kinase was not phosphorylated by the Ca/calmodulin-dependent protein kinase, while other sites were phosphorylated to a high degree by the Ca/calmodulin-dependent protein kinase, but to a much lesser degree by the cAMP-dependent protein kinase. The results show that the 165-kDa dihydropyridine receptor from skeletal muscle can be multiply phosphorylated at distinct sites by the cAMP- and Ca/calmodulin-dependent protein kinases. As the 165-kDa peptide may be the major functional unit of the dihydropyridine-sensitive Ca channel, the results suggest that the phosphorylation-dependent modulation of Ca channel activity by neurotransmitters may involve phosphorylation of the 165-kDa peptide at multiple sites.     

Zinc causes tyrosine phosphorylation of hippocampal p60c-src.

Zinc cations at concentrations of 0.2 mM and greater catalyzed specific phosphorylation, by ATP, of two membrane-associated proteins from rat hippocampus. These proteins, corresponding to molecular weights of 60 and 49 kDa, were phosphorylated primarily at tyrosine residues. The 60-kDa protein was identified as p60c-src by immunoprecipitation using two different p60src-specific monoclonal antibodies. The 49-kDa protein co-immunoprecipitated with p60c-src. Cyanogen bromide cleavage of p60c-src and the 49-kDa protein phosphorylated in the presence of Zn2+ gave different patterns of phosphopeptides. It is suggested that tyrosine phosphorylation of p60c-src and the p60c-src-associated 49-kDa protein may be a way of zinc participation in hippocampal neurotransmission.     

Arachidonic Acid, but Not Sodium Nitroprusside, Stimulates Presynaptic Protein Kinase C and Phosphorylation of GAP-43 in Rat Hippocampal Slices and Synaptosomes

Abstract: Activation of protein kinase C (PKC) and phosphorylation of its presynaptic substrate, the 43-kDa growth-associated protein GAP-43, may contribute to the maintenance of hippocampal long-term potentiation (LTP) by enhancing the probability of neurotransmitter release and/or modifying synaptic morphology. Induction of LTP in rat hippocampal slices by high-frequency stimulation of Schaffer collateral-CA1 synapses significantly increased the PKC-dependent phosphorylation of GAP-43, as assessed by quantitative immunoblotting with a monoclonal antibody that recognizes an epitope that is specifically phosphorylated by PKC. The stimulatory effect of high-frequency stimulation on levels of immunoreactive phosphorylated GAP-43 was not observed when 4-amino-5-phosphonovalerate (50 µM), an N-methyl-d -aspartate (NMDA) receptor antagonist, was bath-applied during the high-frequency stimulus. This observation supports the hypothesis that a retrograde messenger is produced postsynaptically following NMDA receptor activation and diffuses to the presynaptic terminal to activate PKC. Two retrograde messenger candidates—arachidonic acid and nitric oxide (sodium nitroprusside was used to generate nitric oxide)—were examined for their effects in hippocampal slices on PKC redistribution from cytosol to membrane as an indirect measure of enzyme activation and PKC-specific GAP-43 phosphorylation. Bath application of arachidonic acid, but not sodium nitroprusside, at concentrations that produce synaptic potentiation (100 µM and 1 mM, respectively) significantly increased translocation of PKC immunoreactivity from cytosol to membrane as well as levels of immunoreactive, phosphorylated GAP-43. The stimulatory effect of arachidonic acid on GAP-43 phosphorylation was also observed in hippocampal synaptosomes. These results indicate that arachidonic acid may contribute to LTP maintenance by activation of presynaptic PKC and phosphorylation of GAP-43 substrate. The data also suggest that nitric oxide does not activate this signal transduction system and, by inference, activates a distinct biochemical pathway.