Mechanism of direct cell interactions. Self-organization of protein synthesis rhythm

Primary 24-hour cultures of hepatocytes on slides in a serum-free medium were studied. Circahoralian rhythm of protein synthesis served as a marker of cell cooperation. Stimulation of protein kinase activities by phorbol 12-myristate 13-acetate at 0.5 or 1.0 microM or forskolin at 10 microM led to visualization of the protein synthesis rhythm in sparse cultures, which were asynchronous in the control and with linear kinetics of protein synthesis. Inhibitors of protein kinase activities H7 (1-(5-isoquinolinylsulfonyl)-5-methylpiperasine dihydrochloride) at 40 microM or H8 (N-(2-[methylamino]ethyl)-5-isoquinolinesulfonamide hydrochloride) at 25 microM eliminated the protein synthesis rhythm in dense cultures, which are normally synchronous with oscillatory kinetics of protein synthesis. After inhibition of the protein kinase activities, gangliosides or phenylephrine did not synchronize the protein synthesis rhythm. Phorbol 12-myristate 13-acetate modulated the protein synthesis rhythm, shifted the rhythm phase, i.e., stimulation of the protein kinase activities, and, correspondingly, protein phosphorylation may be a factor of synchronization of synthesis oscillations in individual cells and of population rhythm formation. Thus, a cascade of processes leading to self-organization of hepatocytes during formation of summarized protein synthesis was revealed in a series of studies: signal of gangliosides or other calcium agonists-->changes in the level of calcium ions in cytoplasm-->increased protein kinase activities-->protein phosphorylation-->modulation of individual oscillations in the intensity of protein synthesis and their coordination in a summarized rhythm. cAMP-dependent protein kinases also affect the protein synthesis rhythm. Protein phosphorylation is a key process. The mechanisms of cell self-organization are similar in vitro and in vivo, specifically in the liver in situ.     

Involvement of protein kinases in self-organization of the rhythm of protein synthesis by direct cell-cell communication

Primary cultures of rat hepatocytes grown on slides were studied in serum-free medium. Ultradian protein synthesis rhythm was used as a marker of synchronization of individual oscillations, resulting in the formation of a common rhythm of the cell population, i.e. cell-cell self-organization. Dense synchronous and sparse non-synchronous cultures were used to estimate effect of protein kinase activity on the kinetics of protein synthesis. Treatment of dense cultures with the inhibitors H7 (40 microM) or H8 (25 microM) resulted in a loss of the protein synthesis rhythm, a suppression of the cell-cell self-organization. Stimulation of protein kinase activity with either 0.5 or 1.0 microM phorbol 12-miristate-13-acetate (PMA) or 10 microM forskolin caused the appearance of the synthetic rhythm in non-synchronous sparse cultures under otherwise normal conditions. Inhibition of protein kinase activity with H7 resulted in signal factors, such as gangliosides and phenylephrine, failing to initiate this rhythm in sparse cultures. Activation of protein kinase activity with PMA shifted the phase pattern of the protein synthesis rhythm. Thus, according to our previous and the new data, protein kinase activity and consequently protein phosphorylation is the crucial step of sequence of processes resulting in synchronization during self-organization of cells in producing a common rhythm in the population. The general pathway can be presented as follows: signaling of gangliosides or other calcium agonists-->efflux of calcium ion from intracellular stores, with elevation of calcium concentration in the cytoplasm-->activation of protein kinases-->protein phosphorylation-->synchronization of individual oscillations in protein synthesis rates-->induction of a common rhythm throughout this population. The data have been discussed concerning similarity of the direct cell-cell communication and the cell self-organization in cultures and in organism.     

Signaling factors of self-organization of protein synthesis rhythm in hepatocyte cultures—gangliosides and catecholamines function independently

Considering the data on the low level of self-organization (self-synchronization) of protein synthesis rhythm in aging, we studied the possible interference of the signaling factors of self-organization, gangliosides and catecholamines, as well as catecholamine reception. Experiments were carried out on primary cultures of rat hepatocytes on slides. Inhibited ganglioside synthesis did not prevent the organization of protein synthesis rhythm by the α-adrenomimetic agent phenylephrine. Upon the blockade of α-receptors by prazosin, the protein synthesis rhythm was observed after the exposure to gangliosides. α-Adrenolytic agents prazosin and benoxathian abolished the synchronizing effect of the β-adrenomimetic isoproterenol. A mixture of α-and β-adrenomimetic agents inhibited the protein synthesis rhythm-organizing effect of noradrenaline. Thus, the signaling molecules of self-organization of protein synthesis function independently via specific receptors.     

Single short-term signal that enhances cooperative activity of old rat hepatocytes acts for several days

Primary cultures of rat hepatocytes were studied in serum-free medium. Ultradian protein synthesis rhythm was used as a marker of overall cell synchronization and cooperation amongst the population. The level of synchronization was determined by amplitudes of the rhythm. Low synchronization of old rat hepatocytes can be enhanced by addition of either gangliosides or phenylephrine to the medium. Incubation of cultures with gangliosides lasted for 2.5 h, while action of phenylephrine was only for 2 min. The amplitude of protein synthesis rhythm was increased 1.5-2 times. In cultures transferred to a fresh normal medium, this increased amplitude was observed for at least 2-3 days. Thus, both gangliosides and phenyleprine are triggers, which, as shown earlier, initiated calcium-dependent processes in the cytoplasm. The results are discussed in the light of concept of the cell self-organization by a direct cell-cell communication.     

Melatonin synchronizes protein synthesis rhythm in hepatocyte cultures as an agonist of intercellular calcium and protein kinases

Melatonin in nanomolar concentrations synchronizes protein synthesis in primary cultures of hepatocytes through calcium-dependent activation of protein kinases. The synchronizing effect of melatonin is blocked by the cytoplasmic calcium chelating agent BAPTA-AM (20 μM) as well as by the inhibitor of protein kinases 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine dihydrochloride (40 μM). Thus, protein phosphorylation is the key event in hepatocyte synchronization by melatonin, as we have demonstrated previously for gangliosides and biogenic amines. The antagonist of melatonin receptors luzindole (20 nM) blocks the synchronizing function of melatonin.     

Changes in Concentration of Calcium Ions and the Rhythm of Protein Synthesis in the Culture of Hepatocytes

We studied the effects of the chelating agents of extra- and intracellular calcium ions, EGTA and BAPTA-AM, and of the inhibitor of Ca²⁺release from the reticulum, TMB-8, in the kinetics of protein synthesis in hepatocyte cultures. We also studied dense cultures capable of self-synchronization of protein synthesis oscillations and diluted cultures, in which synchronization is induced by phenylephrine or gangliosides (standard preparation of total gangliosides from the bovine brain). Preincubation of the diluted or dense cultures in the presence of 2 mM EGTA for 1–2 h with subsequent protein assay in a medium with EGTA did not affect the kinetics of protein synthesis: no rhythm was found in the diluted cultures, while it was preserved in the dense cultures. When the diluted cultures preincubated in the presence of EGTA were placed in a medium with EGTA and 2 M phenylephrine for 2 min, the rhythm was visualized. The treatment of diluted cultures with 100 M TMB-8 for 5 or 10 min with subsequent washing and incubation in a medium with 3 M gangliosides led to visualization of the protein synthesis rhythm, i.e., to the synchronization of oscillations, while no rhythm was found in the standard cultures. Preincubation of the diluted cultures in a medium with 10, 15, or 20 M BAPTA-AM for 1 h did not affect the kinetics of protein synthesis. When, after such preincubation, the diluted cultures were placed in the medium with gangliosides, the rhythm was visualized. In the dense cultures, normally capable of self-synchronization, no rhythm of protein synthesis was found after their treatment with 10–20 M BAPTA-AM for 1 h. The transfer of such cultures in the medium with gangliosides led to visualization of the rhythm. Thus, calcium affects the kinetics of protein synthesis: after the rise of Ca²⁺in the cytoplasm was blocked, the rhythm of protein synthesis was not visualized due, supposedly, to disturbed mechanisms of medium conditioning. However, exogenous gangliosides in the dense or diluted cultures preincubated in the presence of BAPTA-AM ore TMB-8 allowed the rhythm visualization, i.e., synchronization may not depend on changes in the intracellular calcium concentration.     

Signaling factors of self-organization of protein synthesis rhythm in hepatocyte cultures--gangliosides and catecholamines function independently

Considering the data on the low level of self-organization (self-synchronization) of protein synthesis rhythm in aging, we studied the possible interference of the signaling factors of self-organization, gangliosides and catecholamines, as well as catecholamine reception. Experiments were carried out on primary cultures of rat hepatocytes on slides. Inhibited ganglioside synthesis did not prevent the organization of protein synthesis rhythm by the alpha-adrenomimetic agent phenylephrine. Upon the blockade of alpha-receptors by prazosin, the protein synthesis rhythm was observed after the exposure to gangliosides. Alpha-adrenolytic agents prazosin and benoxathian abolished the synchronizing effect of the beta-adrenomimetic isoproterenol. A mixture of alpha- and beta-adrenomimetic agents inhibited the protein synthesis rhythm-organizing effect of noradrenaline. Thus, the signaling molecules of self-organization of protein synthesis function independently via specific receptors.     

Glutamic acid as enhancer of protein synthesis kinetics in hepatocytes from old rats

Dense cultures of hepatocytes from old rats (~2 years old, body weight 530-610 g) are different from similar cultures of hepatocytes from young rats by the low amplitude of protein synthesis rhythm. Addition of glutamic acid (0.2, 0.4, or 0.6 mg/ml) into the culture medium with hepatocytes of old rats resulted in increase in the oscillation amplitudes of the protein synthesis rhythm to the level of young rats. A similar action of glutamic acid on the protein synthesis kinetics was observed in vivo after feeding old rats with glutamic acid. Inhibition of metabotropic receptors of glutamic acid with α-methyl-4-carboxyphenylglycine (0.01 mg/ml) abolished the effect of glutamic acid. The amplitude of oscillation of the protein synthesis rhythm in a cell population characterizes synchronization of individual oscillations caused by direct cell–cell communications. Hence, glutamic acid, acting as a receptor-dependent transmitter, enhanced direct cell–cell communications of hepatocytes that were decreased with aging. As differentiated from other known membrane signaling factors (gangliosides, norepinephrine, serotonin, dopamine), glutamic acid can penetrate into the brain and thus influence the communications and protein synthesis kinetics that are disturbed with aging not only in hepatocytes, but also in neurons.     

Age-related features of protein synthesis rhythm in hepatocytes. Effects of extracellular medium

Cell interactions have been studied in cultures pf hepatocytes from young and old rats. The rhythm of protein synthesis is an index of cell interaction and synchronization in culture, while the amplitude of oscillations characterized cell cooperation in an aggregate rhythm. The mean rhythm amplitude in the culture of hepatocytes from old rats is twice lower than that from young rats. Gangliosides (mixture, bovine brain gangliosides) and alpha1-adrenomimetic phenylephrine enhanced synchronization of cultures of the cells from old rats and increased the amplitude of oscillations to the level of young animals. Addition of rat blood serum (10%) to the medium revealed the rhythm of protein synthesis in the culture, asynchronous in the control, i.e., led to their synchronization. In media with young and old rat blood sera, oscillations were intense, with high amplitudes, and low, respectively. Addition of bovine brain gangliosides to a medium with old rat blood serum increased the amplitudes of oscillations to a level of the rhythm stimulated by the young rat serum. Thus, the cells of old animals can fully perceive synchronizing factors and, in the case of their increased concentration, the rhythm of protein synthesis in old animals did not differ from that in young rats. Current data on biochemical mechanisms underlying intercellular cooperation in the formation of population rhythm of protein synthesis have been discussed.     

Age-related features of protein synthesis rhythm. Effects of extracellular medium

Cell interactions have been studied in cultures pf hepatocytes from young and old rats. The rhythm of protein synthesis is an index of cell interaction and synchronization in culture, while the amplitude of oscillations characterized cell cooperation in an aggregate rhythm. The mean rhythm amplitude in the culture of hepatocytes from old rats is twice lower than that from young rats. Gangliosides (mixture, bovine brain gangliosides) and ₁-adrenomimetic phenylephrine enhanced synchronization of cultures of the cells from old rats and increased the amplitude of oscillations to the level of young animals. Addition of rat blood serum (10%) to the medium revealed the rhythm of protein synthesis in the culture, asynchronous in the control, i.e., led to their synchronization. In media with young and old rat blood sera, oscillations were intense, with high amplitudes, and low, respectively. Addition of bovine brain gangliosides to a medium with old rat blood serum increased the amplitudes of oscillations to a level of the rhythm stimulated by the young rat serum. Thus, the cells of old animals can fully perceive synchronizing factors and, in the case of their increased concentration, the rhythm of protein synthesis in old animals did not differ from that in young rats. Current data on biochemical mechanisms underlying intercellular cooperation in the formation of population rhythm of protein synthesis have been discussed.Translated from Ontogenez, Vol. 36, No. 1, 2005, pp. 9–17.Original Russian Text Copyright © 2005 by Brodsky, Nechaeva, Zvezdina, Novikova, Gvazava, Fateeva, Malchenko.     

Effects of phorbol esters on insulin receptor function and insulin action in hepatocytes: evidence for heterogeneity

We investigated the effect of phorbol 12-myristate 13-acetate (PMA), a protein kinase C (PKC) activator on insulin receptors and insulin action in freshly isolated and primary cultures of rat hepatocytes. PMA (1 x 10^–7 M) did not alter insulin receptor numbers or affinity either acutely or chronically but within 60 minute inactivated insulin stimulated tyrosine kinase of the insulin receptor. PKC activation inhibitied insulin (1 x 10^–7M) stimulation of glycogen and lipid synthesis with a decrease or no change in basal glycogenesis and lipogenesis respectively. However, PKC activation did not alter insulin stimulated or basal amino acid transport even though PCK activation inhibited insulin stimulation of the insulin. receptor tyrosine kinase. Thus, within one tissue, PKC activation has differential effect on insulin action depending on which pathway is examined. Furthermore, insulin stimulation of the insulin receptor tyrosine kinase may not be a necessary step for all insulin signaling pathways.     

The Blocker of Prazosine Adrenoreceptors Does Not Prevent the Synchronization of Protein Synthesis Rhythm by Exogenous Gangliosides in the Culture of Hepatocytes

We studied the effect of the ₁-adrenolytic prazosine on both dense cultures of hepatocytes, which are normally characterized by the protein synthesis rhythm, and diluted cultures, in which such a rhythm is revealed after external synchronization. Exogenous gangliosides (a fraction of the total gangliosides of the bovine brain) then synchronize the rhythm in diluted cultures; this effect is also displayed in the presence of 10^–7 M prazosine. The synchronizing effect of the medium conditioned by dense cultures was also preserved in the presence of prazosine. In the dense cultures that don't normally require external synchronization, prazosine intensified the rhythmic pattern of changes in the protein synthesis. After a total of 0.3 M gangliosides were introduced in the medium with prazosine-pretreated dense cultures, the protein synthesis rhythm was visualized. We propose that, while blocking adrenoreceptors, prazosine does not prevent the action of exogenous synchronizing factors on the hepatocytes, but inhibits the release of such factors from the cell.     

Ganglioside-mediated metabolic synchronization of protein synthesis activity in cultured hepatocytes

An ultradian oscillation of protein synthesis was detected by synchronization of metabolic activity in rat hepatocyte cultures. This oscillation occurs in dense cultures in fresh medium, but not in sparse ones. Metabolic synchronization of sparse cultures, however, was initiated by conditioned medium or addition of 0.3-0.5 microm of a mixture of bovine brain gangliosides to fresh culture medium along with either 0.06-0.2 microm GM1 or 0.1-0.2 microm GDIa. GTIb and GDIb did not produce oscillations, nor did human liver ganglioside GM3. High expression of GM1 ganglioside determinants in hepatocytes maintained in the conditioned medium purified polyclonal antibodies to GM1 was coupled with protein synthetic oscillatory activity, i.e. metabolic synchronization. Incubation of dense cultures with GM1-antibodies for 24 h decreased the amplitude of these oscillations. In sparse cultures maintained in fresh medium where protein synthesis showed no oscillatory pattern, GM1 expression was low.     

Disturbed Cooperation of Hepatocytes in the Rhythm of Protein Synthesis by Chelating Agent of Cytoplasmic Calcium BAPTA-AM

Previously we demonstrated synchronized oscillations of protein synthesis rate in hepatocyte cultures upon accumulation of monosialoganglioside GM1 in the medium or after introduction of exogenous GM1 to the medium. The synchronized oscillations of the protein synthesis rate in dense hepatocyte cultures were blocked 30 min after their treatment with 10–20 M BAPTA-AM, a chelating agent of cytoplasmic calcium. Enzyme immunoassay for GM1 demonstrated similar amounts of GM1 in the medium conditioned for 3 h by dense hepatocyte cultures pretreated with 20 M BAPTA-AM for 1 h and in the medium of normal dense cultures: 0.0060 ± 0.0005 and 0.0055 ± 0.0005 pmol/1000 cells, respectively. The content of GM1 was also similar in the normal and BAPTA-AM-pretreated hepatocytes: 0.158 ± 0.013 and 0.183 ± 0.014 pmol/1000 cells, respectively. The synchronized rhythm of protein synthesis has been confirmed in the diluted cultures in the medium conditioned by the normal dense cultures. However, the medium conditioned by the dense cultures pretreated with BAPTA-AM induced no synchronization of the diluted cultures. Since GM1 concentration was normal in this medium, we propose the effect of a physicochemical form of the gangliosides accumulated in the medium on their ability to synchronize the rhythm of protein synthesis.     

Calcium ions as a factor of cell-cell cooperation in hepatocyte cultures

Ultradian protein synthesis rhythm was used as a marker of cell cooperation in synchronous dense and non-synchronous sparse hepatocyte cultures. Phenylephrine (2 microM, 2 min), an alpha (1)-adrenoreceptor agonist, which exerts [Ca(2+)](cyt)elevation from intracellular stores, affected protein synthesis rhythm in sparse cultures, i.e. initiated cooperative activity of the cells. The same effect was produced by 2,5-di(tertiary-butyl)-1,4-benzohydroquinone (10 microM, 2 min), which increases [Ca(2+)](cyt)by a non-receptor pathway. Pretreatment of dense cultures with the intracellular calcium chelator, 1,2-bis (2-aminophenoxy) ethane-N,N,N',N'- tetraacetic acid (acetoxymethyl) ester (BAPTA-AM) at 10-20 microM for, 30-60 min resulted in loss of the rhythm of protein synthesis, i.e. loss of cooperative activity between the cells. The medium conditioned by control dense cultures initiated rhythm in sparse cultures, whereas the conditioned medium of cultures pretreated with BAPTA-AM did not. [Ca(2+)](cyt)increase is known to occur with monosialoganglioside GM1 treatment. By ELISA estimation, the GM1 content in 3 h conditioned medium was similar in control dense cultures to that in cultures pretreated with BAPTA-AM. Bearing in mind data on the Ca(2+)-dependence of vesicle formation and shedding, the conditioned medium was separated by 150000 g centrifugation to supernatant containing monomers and micelles, and a pellet containing vesicular form of gangliosides. Only the latter initiated cooperative activity of the cells of sparse cultures. These cultures were also synchronized by GM1-containing liposomes at lower concentrations than added free GM1, 0.0003 and 0.06 microM respectively. Thus, GM1 and calcium are both involved in cell-cell synchronization. Activation of gangliosides, including GM1 and elevation of [Ca(2+)](cyt,)is known to lead to changes of protein kinase activity and protein phosphorylation resulting in modulation of oscillations in protein metabolism.     

Aftereffect of synchronizers of protein synthesis rhythm in hepatocytes in vitro

The effect of gangliosides and phenylephrine synchronizing the protein synthesis rhythm was preserved in hepatocytes cultured in the normal serum-free medium for one-two days. Hence, the membrane signal triggers intracellular, as was shown by us earlier, calcium-dependent processes, which regulate the kinetics of protein synthesis for a certain time after the signal perception.     

Melatonin as the most effective organizer of the rhythm of protein synthesis in hepatocytes in vitro and in vivo

Recent data has extended a large array of melatonin functions by the discovery of melatonin's involvement in the organization and regulation of the rhythm of intracellular protein synthesis. An ultradian rhythm in total protein synthesis has been detected in primary hepatocyte cultures 5 min after addition of 1-5 nM melatonin to the medium. The melatonin effect was mediated via its receptors (as shown in experiments with luzindole), leading to the cell synchronization as well as the mean rate of protein synthesis rate being increased. The chain of processes synchronizing the oscillation of the rate protein synthesis throughout the hepatocyte population includes Ca2+ fluxes {experiments with BAPTA-AM [1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (acetomethyl ester)]}. Inhibition of protein kinase activity (experiments with H7) inhibited the synchronizing function of melatonin. Activation of protein kinase activity results in a shift of the protein synthesis oscillation; the effect was the same as melatonin added to the culture medium. In another series of experiments, after melatonin was intraperitoneally injected to rat (0.015-0.020 μg/kg), hepatocytes were isolated and cultures established. A synchronizing effect of melatonin in vivo was detected as early as in the estimates from the direct action of melatonin on cell cultures. In the cultures obtained from old rats provided with melatonin, the amplitude of protein synthesis rhythm was enhanced, i.e. cell-cell interactions were increased, as well as rate of the protein synthesis being enhanced.     

Phosphorylation of vertebrate nonmuscle and smooth muscle myosin heavy chains and light chains

In this article we review the various amino acids present in vertebrate nonmuscle and smooth muscle myosin that can undergo phosphorylation. The sites for phosphorylation in the 20 kD myosin light chain include serine-19 and threonine-18 which are substrates for myosin light chain kinase and serine-1 and/or-2 and threonine-9 which are substrates for protein kinase C. The sites in vertebrate smooth muscle and nonmuscle myosin heavy chains that can be phosphorylated by protein kinase C and casein kinase II are also summarized.Original data indicating that treatment of human T-lymphocytes (Jurkat cell line) with phorbol 12-myristate 13-acetate results in phosphorylation of both the 20 kD myosin light chain as well as the 200 kD myosin heavy chain is presented. We identified the amino acids phosphorylated in the human T-lymphocytes myosin light chains as serine-1 or serine-2 and in the myosin heavy chains as serine-1917 by 1-dimensional isoelectric focusing of tryptic phosphopeptides. Untreated T-lymphocytes contain phosphate in the serine-19 residue of teh myosin light chain and in a residue tentatively identified as serine-1944 in the myosin heavy chain.Abbreviations MLC myosin light chain - MHC myosin heavy chain - Tris tris(hydroxymethyl)aminomethane - EGTA [ethylenebis(oxyethylenenitrilo)]tetraacetic acid - EDTA ethylenediaminetetraacetate - TPCK N-tosyl-L-phenylalanine chloromethyl ketone - PMA phorbol 12-myristate 13-acetate     

Mesenchymal stromal cells synchronize the rhythm of protein synthesis under the effect of an exogenous signal

A comparative study was performed of dense 5-hour cultures of rat hepatocytes and equal-density cultures of mesenchymal stromal cells (MSC) isolated from human adipose tissue of rat bone marrow. The cells were grown on collagen-coated class slides in serum-free medium. Unlike in hepatocytes, no rhythm of protein synthesis was initially revealed in MSC, but such a rhythm manifested itself when the culture medium was supplemented with melatonin (2 nM, 5 min). The results of experiments with cytoplasmic calcium chelator BAPTA-AM and protein kinase inhibitor H7 indicate that the mechanism of protein synthesis synchronization in MSC consists in calcium-dependent phosphorylation of cell proteins.     

Vinculin phosphorylation in response to calcium and phorbol esters in intact cells

Vinculin phosphorylation in both chick embryo fibroblasts and Swiss 3T3 cells was increased by either calcium or biologically active phorbol esters. Increased phosphorylation of vinculin was noted as early as 10 min following phorbol 12-myristate 13-acetate treatment and was maximal at about 1 h. Maximal increases in phosphorylation were noted at approximately 100 nM phorbol 12-myristate 13-acetate. Phorbol 12,13-dibutyrate (80 nM), a less potent phorbol ester, resulted in smaller increases in vinculin phosphorylation than phorbol 12-myristate 13-acetate at equimolar concentrations. Phorbol, dibutyryl cAMP, and dibutyryl cGMP had no significant effect on phosphorylation. No correlation was found between vinculin phosphorylation and the morphological changes induced by phorbol esters. Tryptic peptide analysis of vinculin revealed multisite phosphorylation. Phosphorylation of only three of the peptides was significantly increased following phorbol 12-myristate 13-acetate treatment. Phosphoamino acid analysis revealed increases at both serine and threonine residues. The low level of phosphotyrosine present in control cells was not significantly increased by phorbol 12-myristate 13-acetate treatment. These findings combined with studies of vinculin phosphorylation by purified protein kinase C (Werth, D. K., Niedel, J. E., and Pastan I. (1983) J. Biol. Chem. 258, 11423-11426) suggest the hypothesis that protein kinase C may be involved in regulation of phosphorylation of vinculin, a cytoskeletal protein.