Phosphorylation of the carotenoid droplet protein p57 by the catalytic subunit of cyclic adenosine monophosphate-dependent protein kinase and the effect of fluoride

We have previously shown that the dispersion and aggregation of carotenoid droplets in goldfish xanthophores are regulated, respectively, by phosphorylation and dephosphorylation of a carotenoid droplet protein p57. There is a basal level of p57 phosphorylation of p57 in unstimulated cells, which is greatly stimulated by adrenocorticotropic hormone (ACTH) or cyclic adenosine monophosphate (cAMP) acting via cAMP-dependent protein kinase. We have also observed that, in permeabilized xanthophores, pigment dispersion can be induced when cAMP is replaced by fluoride. Since p57 has multiple phosphorylation sites, there is the question of whether all p57 phosphorylation is by cAMP-dependent protein kinase or whether phosphorylation by cAMP-independent protein kinase coupled with inhibition of phosphatase activity by fluoride can replace cAMP-dependent protein kinase and that the ability of fluoride to replace cAMP for pigment dispersion in permeabilized cells is probably due to activation of adenylcyclase. We also show that ACTH causes an approximately threefold increase in the level of cAMP in these cells.     

Regulation of pigment organelle translocation. II. Participation of a cAMP-dependent protein kinase

In intact goldfish xanthophores, the phosphorylation of a pigment organelle (carotenoid droplet) protein, p57, appears to play an important role in adrenocorticotropin (ACTH)- or cAMP-induced pigment organelle dispersion while the dephosphorylation of this protein upon withdrawal of ACTH or cAMP is implicated in pigment aggregation. In this paper, we report the cAMP-dependent phosphorylation of this protein in cell-free extracts of xanthophores as determined by the incorporation of 32P from [gamma-32P]ATP. As is the case in intact cells, p57 is the predominant protein phosphorylated in the presence of cAMP. The cAMP-dependent protein kinase which phosphorylates p57 is not bound to the isolated organelles but is found in the soluble portion of the cell extracts. Hence, the phosphorylation of p57 requires the carotenoid droplets bearing the substrate, soluble extract containing the kinase, cAMP (half-maximal activation at 0.5 microM), and Mg2+ (optimal at 5 mM or higher). The presence of protein phosphatase(s) in these extracts was shown indirectly by the stimulation of phosphorylation by fluoride. The phosphorylation of p57 does not appear to require a cell-specific kinase as soluble extracts of goldfish dermal nonpigment cells also phosphorylate p57 associated with isolated carotenoid droplets. Furthermore, using a constant amount of carotenoid droplets, a linear relationship was demonstrated between the rate of p57 phosphorylation and the amount of extract present in the assays. These results suggest that p57 is phosphorylated directly by a cAMP-dependent protein kinase and that the activity of this enzyme is important in regulating the intracellular movement of the pigment organelles of the xanthophore.     

Immunofluorescence evidence for cytoskeletal rearrangement accompanying pigment redistribution in goldfish xanthophores

Immunofluorescence and phase-contrast microscopic studies of goldfish xanthophores with aggregated or dispersed pigment show two unusual features. First, immunofluorescence studies with anti-actin show punctate structures instead of filaments. These punctate structures are unique for the xanthophores and are absent from both goldfish dermal non-pigment cells and a dedifferentiated cell line (GEM-81) derived from a goldfish xanthophore tumor. Comparison of immunofluorescence and phase-contrast microscopic images with electron microscopic images of thin sections and of Triton-insoluble cytoskeletons show that these punctate structures represent pterinosomes with radiating F-actin. The high local concentration of actin around the pterinosomes results in strong localized fluorescence such that, when the images have proper brightness for these structures, individual actin filaments elsewhere in the cell are too weak in their fluorescence to be visible in the micrographs. Second, whereas immunofluorescence images with anti-tubulin show typical patterns in xanthophores with either aggregated or dispersed pigment, namely, filaments radiating out from the microtubule organizing center, immunofluorescence images with anti-actin or with anti-intermediate filament proteins show different patterns in xanthophores with aggregated versus dispersed pigment. In cells with dispersed pigment, the punctate structures seen with anti-actin are relatively evenly distributed in the cytoplasm, and intermediate filaments appear usually as a dense perinuclear band and long filaments elsewhere in the cytoplasm. In cells with aggregated pigment, both intermediate filaments and pterinosomes with associated actin are largely excluded from the space occupied by the pigment aggregate, and the band of intermediate filaments surrounds not only the nucleus but also the pigment aggregate. The patterns of distribution of the different cytoskeleton components, together with previous results from this laboratory, indicate that formation of the pigment aggregate depends at least in part on the interaction between pigment organelles and microtubules. The possibility that intermediate filaments may play a role in the formation/stabilization of the pigment aggregate is discussed.     

Regulation of pigment organelle translocation. I. Phosphorylation of the organelle-associated protein p57

Treatment of goldfish xanthophores with adrenocorticotropin (ACTH) or cyclic AMP (cAMP) induces the centrifugal movement of their pigment organelles from the center of the cells. Using purified xanthophores pulse labeled with 32Pi, we have shown that the dispersion of the organelles is accompanied by the phosphorylation of a pair of polypeptides, termed p57. After fractionation on sucrose gradients, nearly all of the p57 is found associated with the pigment organelles. The phosphorylation induced by ACTH or cAMP apparently occurs at multiple sites on p57. The minimal effective doses of ACTH or cAMP required to induce full pigment dispersion also fully stimulate the phosphorylation of p57. Increased phosphorylation of p57 is detectable within a minute after stimulating the cells and appears to be near completion during the early phases of pigment dispersion. Upon withdrawal of ACTH, these events are reversed; the pigment organelles reaggregate toward the center of the cells and p57 is dephosphorylated. Again, dephosphorylation commences soon after ACTH is withdrawn and is complete before the organelles have completely reaggregated. These results suggest a novel mechanism for governing the movement of these organelles which acts on the organelles themselves through the phosphorylation and dephosphorylation of p57.     

Regulation of the distribution of carotenoid droplets in goldfish xanthophores and possible implication to secretory processes

In goldfish xanthophores, the formation of pigment aggregate requires: 1) that a pigment organelle (carotenoid droplet) protein p57 be in the unphosphorylated state; 2) that self-association of pigment organelles occur in a microtubule-independent manner; and 3) that pigment organelles via p57 associate with microtubules. In the fully aggregated state, the pigment organelles are completely stationary. Pigment dispersion is initiated by activation of a cAMP-dependent protein kinase, which phosphorylates p57 and allows pigment dispersion via an active process dependent on F-actin and a cytosolic factor. This factor is not an ATPase, and its function is unknown. However, its abundance in different tissues parallels secretory activity of the tissues, suggesting a similarity between secretion and pigment dispersion in xanthophores. The identity of the motor for pigment dispersion is unclear. Experimental results show that pigment organelles isolated from cells with dispersed pigment have associated actin and ATPase activity comparable to myosin ATPase. This ATPase is probably an organelle protein of relative molecular mass approximately 72,000, and unlikely to be an ion pump. Isolated pigment organelles without associated actin have 5x lower ATPase activity. Whether this organelle ATPase is the motor for pigment dispersion is under investigation. The process of pigment aggregation is poorly understood, with conflicting results for and against the involvement of intermediate filaments.     

Protein phosphorylation and the two stages of pigment organelle dispersion in permeabilized xanthophores: organelle protein phosphorylation alone supports only the first stage

We reported previously that, in cultured goldfish xanthophores, dispersion of aggregated carotenoid droplets (CDs) requires the specific phosphorylation of the CD protein p57 by a cAMP-dependent protein kinase and the presence of cytosol. We report here that, in permeabilized cells, the addition of the catalytic subunit of cAMP-dependent protein kinase and ATP phosphorylates p57 and converts the CDs from an immobile to a mobile state (first stage of CD dispersion). However, the CDs are restricted to the vicinity of the original site of the CD aggregate and do not actually disperse (second stage of CD dispersion) unless cytosol is also added. We propose that this process may be related to aspects of secretory processes.     

Intermediate filaments with novel protein composition from certain goldfish cells

Using the conditions for vimentin filament recycling, intermediate filaments (approximately 10 nm) were prepared from the cytoskeleton of a goldfish tumor cell line (erythrophoroma or xanthophoroma). 2-D analysis showed unusual protein composition, with four proteins of molecular weights of 60, 45, 56 and 51 kilodaltons in ratios of approximately 4:4:1:1. These correspond to four of the major cytoskeletal proteins of both the tumor cells and normal xanthophores.     

Isolation and characterization of two forms of a cytoskeleton

Isolated petaloid coelomocytes from the sea urchin Strongylocentrotus droebachiensis transform to a filopodial morphology in hypotonic media. Electron micrographs of negatively stained Triton-insoluble cytoskeletons show that the petaloid form consists of a loose net of microfilaments while the filopodial form consists of paracrystalline bundles of microfilaments. Actin is the major protein of both forms of the cytoskeleton. Additional polypeptides have molecular weights of approximately 220,000, 64,000, 57,000, and 27,000 daltons. Relative to actin the filopodial cytoskeletons have an average of 2.5 times as much 57k polypeptide as the petaloid cytoskeletons. Treatment with 0.25 M NaCl dissociates the filament bundles into individual actin filaments free of the actin-associated polypeptides. Thus, one or more of these actin-associated polypeptides may be responsible for crosslinking the actin filaments into bundles and maintaining the three-dimensional nature of the cytoskeletons.     

Association of fibrin with the platelet cytoskeleton

We have previously postulated that surface membrane proteins become specifically associated with the internal platelet cytoskeleton upon platelet activation (Tuszynski, G.P., Walsh, P.N., Piperno, J., and Koshy, A. (1982) J. Biol. Chem. 257, 4557-4563). Four lines of evidence are in support of this general hypothesis since we now show that platelet surface receptors for fibrin become specifically associated with the platelet Triton-insoluble cytoskeleton. 1) Fibrin was detected immunologically in the washed Triton-insoluble cytoskeletons of thrombin-activated platelets under conditions where fibrin polymerization and resultant precipitation was blocked with Gly-Pro-Arg-Pro, a synthetic peptide that inhibits polymerization of fibrin monomer. 2) Radiolabeled fibrin bound to thrombin-activated platelets and became associated with the cytoskeleton. 3) The amount of radiolabeled fibrin bound to thrombin-activated thrombasthenic platelets and their cytoskeletons amounted to about 20% of the fibrin bound to thrombin-activated control platelets and their cytoskeletons. 4) The association of fibrin with cytoskeletons and with the platelet surface was nearly quantitatively blocked by an antibody prepared against cytoskeletons (anti-C), an antibody against isolated membranes of Pronase-treated platelets (anti-M1), and a monoclonal antibody to the platelet surface glycoprotein complex, GPIIb-GPIII (anti-GPIII). These antibodies blocked ADP and thrombin-induced platelet aggregation as well as thrombin-induced clot retraction. Analysis of the immunoprecipitates obtained with anti-C, anti-M1, and anti-GPIII from detergent extracts of 125I-surface labeled platelets revealed that these antibodies recognized GPIIb-GPIII. These data suggest that thrombin activation of platelets results in the specific association of fibrin with the platelet cytoskeleton, that this association may be mediated by the GPIIb-GPIII complex, and that these mechanisms may play an important role in platelet aggregation and clot retraction induced by thrombin.     

Association of fibronectin with the platelet cytoskeleton

Triton-insoluble cytoskeletons prepared from either normal or thrombasthenic platelets were found to contain approximately 1.3 micrograms of fibronectin/10(9) platelets as measured by a radioimmunoassay. Total endogenous platelet fibronectin was quantitatively retained on the platelet cytoskeleton, whereas 70% of exogenously added fibronectin that bound the surface of thrombin-activated platelets was recovered with the Triton-insoluble cytoskeleton. The exogenously added fibronectin specifically bound platelets and cytoskeletons with the same affinity giving an apparent binding constant of 1.47 X 10(-7) M. The possibility that fibrin associated with the platelet cytoskeleton could serve as the fibronectin receptor was investigated by measuring the binding constant of fibronectin for polymerizing fibrin and by measuring the amount of fibronectin associated with cytoskeletons of thrombasthenic platelets which contain 4-fold less fibrin than controls. The binding constant of fibronectin for polymerizing fibrin was 14-fold lower than that for cytoskeletons and cytoskeletons prepared from thrombasthenic platelets contained approximately the same amount of fibronectin as controls. Therefore, it is unlikely that fibrin is the platelet fibronectin receptor. These results support the hypothesis that platelet fibronectin is released from platelet alpha granules upon thrombin stimulation and becomes bound to the platelet surface and cytoskeleton either directly or through some intermediate protein that spans the membrane and interacts both with fibronectin and the internal cell cytoskeleton.     

Rearrangements of pterinosomes and cytoskeleton accompanying pigment dispersion in goldfish xanthophores

The cytoskeleton of goldfish xanthophores contains an abundance of unique dense structures (400 nm in diameter) that are absent in goldfish nonpigment cells and are probably remnants of pterinosomes. No major difference in protein composition between xanthophores and nonpigment cells (without these structures) was found that could account for these structures. In xanthophores, these structures are foci of radiating filaments. The addition or withdrawal of ACTH causes a radical rearrangement of the xanthophore cytoskeleton accompanying redistribution of carotenoid droplets, namely, the virtual exclusion of these dense bodies with associated filaments from the space occupied by the carotenoid droplet aggregate vs. a relatively even cytoplasmic distribution of these structures when the carotenoid droplets are dispersed. These changes in cytoskeletal morphology are not accompanied by any major changes in the protein or phosphoprotein composition of the cytoskeleton.     

Enhanced tyrosine phosphorylation in B lymphocytes upon complexing of membrane immunoglobulin

Activation of normal human peripheral blood B-enriched lymphocytes with antiserum reacting with membrane immunoglobulin was associated with increased phosphorylation of cellular proteins, particularly in the Triton-insoluble cytoskeletal fraction. At least two proteins (56K and 60K) were labeled predominantly at tyrosine residues. These findings may indicate another specialized membrane structure which upon specific ligand binding stimulates tyrosine phosphorylation in association with cellular proliferation.     

Activity of pp60c-src and association of pp60c-src, pp54/58lyn, pp60fyn, and pp72syk with the cytoskeleton in platelets activated by collagen

Collagen stimulation of platelets induced an increase in the specific activity of pp60c-src immunoprecipitated from the Triton-soluble fraction. The earliest time after collagen stimulation that an increase in pp60c-src activity was observed was 30 s. However, the maximum activity of pp60c-src in the Triton-soluble fraction was observed 60 s after collagen stimulation. At this time an approximately twofold increase of pp60c-src activity towards phosphorylation of KVEKIGEGTYGVVKK specific peptide and enolase and a 4.5-fold increase towards phosphorylation of pp60c-src itself was measured. Furthermore, the majority of pp60c-src as well as pp54/58lyn, pp60fyn, and pp72syk were found in the Triton-soluble fraction in resting platelets. Collagen induced, to different extents and velocities, translocation of all of these proteins from the Triton-soluble fraction to the Triton-insoluble, cytoskeleton-rich, platelets fraction. These results provide direct evidence that collagen stimulation of platelets increases the tyrosine kinase activity of pp60c-src and suggest that the platelet cytoskeleton plays an important role in collagen-induced signal transduction by localizing signaling molecules.     

Insulin and insulin-like growth factor I (IGF I) stimulate phosphorylation of a Mr 175,000 cytoskeleton-associated protein in intact FRTL5 cells

FRTL5 rat thyroid cells possess separate high affinity receptors for insulin and insulin-like growth factor I (IGF I) that undergo beta-subunit phosphorylation upon interaction with the specific ligand. Phosphorylation is rapid and dose-dependent and occurs primarily on tyrosine residues. Within 2 min, both insulin and IGF I also give rise to a Mr 175,000 phosphoprotein (pp175) that can be immunoprecipitated by anti-phosphotyrosine antibody (alpha-Tyr(P]. Phosphorylation of pp175 occurs on serine and threonine as well as tyrosine residues. When FRTL5 cells are solubilized with 1% Triton X-100, alpha-Tyr(P) immunoprecipitates phosphorylated insulin and IGF I receptors but little pp175 from the Triton-soluble fraction. After treatment of the Triton-insoluble portion with 1% sodium dodecyl sulfate at 100 degrees C, pp175 can be identified by immunoprecipitation with alpha-Tyr(P). The fraction of FRTL5 cells that remains after extraction of an attached monolayer with 1% Triton for 5 min at 22 degrees C contains most of the cytoskeleton and also nuclei. Extraction of this 32P-labeled cytoskeleton preparation with sodium dodecyl sulfate followed by alpha-Tyr(P) immunoprecipitation results in almost complete recovery of the pp175 content of the cells. When a nuclear fraction was prepared from FRTL5 cells by differential centrifugation, pp175 was not found in the nuclear pellet from labeled cells, but greater than 80% of pp175 was recovered in the supernatant. We conclude that pp175 is a common substrate for insulin and IGF I receptor kinases which, in FRTL5 cells, is associated with the cytoskeleton. It is suggested that phosphorylation of proteins associated with cytoskeletal elements could be involved in insulin and IGF I action in cells.     

Ultrastructural Immunogold Localization of Some Organelle-Transport Relevant Proteins in Wholemounted Permeabilized Nonextracted Goldfish Xanthophores

By whole-cell transmission electron microscopy (WCTEM), we recently demonstrated that carotenoid droplets are transported by elongating or retracting endoplasmic reticular cisternae in goldfish xanthophores. Here we report that permeabilized xanthophores demonstrate immunogold reactivity against several proteins involved in organelle translocation. The gold labeling against β-tubulin and the intermediate filament protein p45a were found on microtubules and intermediate filaments. Labeling with antiactin was found on nonidentifiable structures, on vesicles of unknown origin, occasional labeling on carotenoid droplets, and on occasional microfilaments. Immunoreactivity was demonstrated with anti-p57 on the carotenoid droplet surface, confirming previous results (Lynch et al., 1986a,b). Labeling with anti-PCD6 subunit (of the inositol trisphosphate/ryanodine receptor) was demonstrated on carotenoid droplets suggesting they possess calcium channels. Anti-MAP 1C (dynein) immunolabeling was generally seen on club-shaped structures in the cytomatrix and on carotenoid droplets. Finally, immunogold labeling with anti-MAP 2a + 2b was seen on a meshwork of microfilaments and intermediate filaments. Finally, this is the first report of a WCTEM technique for permeabilized cells that reveals immunoreactive elements, organelles, and cytomatrix components without the additional requirements of extraction or fracturing.     

Dermal and epidermal chromatophores of the Antarctic teleost Trematomus bernacchii

The physiological response and ultrastructure of the pigment cells of Trematomus bernacchii, an Antarctic teleost that lives under the sea ice north of the Ross Ice Shelf, were studied. In the integument, two types of epidermal chromatophores, melanophores and xanthophores, were found; in the dermis, typically three types of chromatophores--melanophores, xanthophores, and iridophores--were observed. The occurrence of epidermal xanthophore is reported for the first time in fish. Dermal melanophores and xanthophores have well-developed arrays of cytoplasmic microtubules. They responded rapidly to epinephrine and teleost melanin-concentrating hormone (MCH) with pigment aggregation and to theophylline with pigment dispersion. Total darkness elicited pigment aggregation in the majority of dermal xanthophores of isolated scales, whereas melanophores remained dispersed under both light and dark conditions. Pigment organelles of epidermal and dermal xanthophores that translocate during the pigmentary responses are carotenoid droplets of relatively large size. Dermal iridophores containing large reflecting platelets appeared to be immobile.     

Presence of calmodulin in human platelet cytoskeletons and its concentration change upon activation of platelets

We found that a small, reproducible amount of calmodulin is present in the cytoskeleton of human platelets. Triton-insoluble materials (cytoskeletons), which were prepared by cetrifugation at 1000 × g for 10 min of platelets after lysis by Triton X-100, stimulated cyclic AMP phosphodiesterase activity in the presence of Ca²⁺ but not in the presence of the calcium chelator, EGTA, or the calmodulin antagonist, trifluoperazine. The activation of the enzyme was also obtained after heating Triton-insoluble materials. An alkaline glycerol polyacrylamide gel electrophoresis of fractions obtained after gel fitration of solubilized Triton residues showed a protein band which had a faster electrophoretic mobility in the absence than in the presence of Ca²⁺. Upon thrombin activation of platelets, calmodulin in the Triton-insoluble cytoskeletons increased rapidly parallel to actin, actin-binding protein and myosin. With other stimulants such as collagen, epinephrine and ADP, similar results were obtained but with slower association of these proteins with cytoskeletons. However, after treatment with the Ca²⁺-inophore A23187, calmodulin, actin and actin-binding protein in Triton residues decreased rapidly, whereas the association of myosin increased. Thus, calmodulin seems to be associated with actin filaments rather than myosin filaments, and may be involved in the generation of contractile force in the cell.     

Protonic and cationic changes during cyclical cation transport driven by electron transfer

A method is described for the subcellular fractionation of goldfish xanthophores. The procedure produces relatively pure fractions of caroteniod droplets, pterinosomes, cytosol and what appears to be plasma membrane. The presence of a distinct pattern of proteins is shown to be associated with the carotenoid droplets. Treatment of the xanthophores with ACTH affects the buoyant density of some carotenoid droplets and stimulates the phosphorylation of a polypeptide associated with the carotenoid droplets.     

Interaction of pp60c-src, phospholipase C, inositol-lipid, and diacyglycerol kinases with the cytoskeletons of thrombin-stimulated platelets.

Phosphatidylinositol (PtdIns)-4- and -3-kinases, PtdIns(4)P-5-kinase, diacylglycerol (DAG) kinase, and PtdIns-phospholipase C were all detected in cytoskeletons of resting human platelets. The total cytoskeletal enzyme activities were greatly increased upon thrombin stimulation of the intact cells. Those reached a maximum after a 60-s stimulation for PtdIns(4)P-5-kinase and phospholipase C, while the other kinases appeared to be slightly delayed. Specific activities were stimulated from about 4-fold (PtdIns-3-kinase) to about 6-fold (PtdIns-4-kinase). Thrombin treatment also promoted a co-extraction of pp60c-src with the cytoskeletons and its disappearance from the Triton X-100 soluble fraction. These results suggest that stimulation of platelets by thrombin causes the association of enzymes responsible for lipid phosphorylation and hydrolysis with the cytoskeletons. This could occur at cytoskeleton anchoring points to the membranes.     

Actin-dependent carotenoid droplet dispersion in permeabilized cultured goldfish xanthophores

Organelle translocations are essential cellular processes. Although much progress has been made with regards to microtubule-dependent organelle translocations, little is known about actin-dependent organelle translocation(s) except cytoplasmic streaming in Nitella. On the other hand, there is indirect evidence that actin-dependent organelle translocation may be involved in secretion. We now present evidence that the dispersion of the pigment organelles carotenoid droplets in goldfish xanthophores is apparently actin dependent and that this process may be related to secretory processes. We show that, in digitonin-permeabilized goldfish xanthophores, the pigment organelles can be induced to disperse by a combination of cAMP, ATP, and xanthophore cytosol. This induced dispersion is inhibited by DNase I, phalloidin, or anti-actin, but not by anti-tubulin or anti-intermediate filament proteins, suggesting a dependence on F-actin. Since the dispersion of carotenoid droplets and secretion both involve outward translocation of organelles, we tested the possibility that cytosols of secretory tissues have similar activity. Such activity was indeed found in different tissues, apparently in parallel with the secretory activity of the tissues, suggesting that pigment dispersion in xanthophores and some secretory processes may share a common component.