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.     

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.     

Small cooperative activity of old rat hepatocytes may depend on composition of the intercellular medium

Ultradian oscillations of protein synthesis were used as a marker of hepatocyte synchronous cooperative activity producing a common rhythm in vitro; amplitude of the rhythm defines expression of the cell cooperation. Dense synchronous and sparse non-synchronous rat hepatocyte cultures on slides in a serum-free incubation medium 199 supplemented with 0.2 mg/ml albumin and 0.5 microg/ml insulin have been studied. The amplitude of the rhythm averaged approximately 2x in dense cultures of young (3 month old) rats than in old (2 year old) rats. But some cultures of young rats had the amplitude patterns similar to cultures of old rats, and vice versa. Addition to the medium of either 0.3 microM bovine brain gangliosides or 2 microM phenylephrine resulted in increase of the oscillation amplitude in dense cultures of old rats to the level inherent in young ones. Addition to the medium of 10% rat blood serum in non-synchronous sparse cultures from young rats resulted in detection of a protein synthetic rhythm. Although after serum from young rats, the rhythm expression was high, the rhythm after serum from old rats had been given was weak. Addition of gangliosides to old-rat serum resulted in synchronization of sparse cultures with amplitudes inherent of young-rat serum. The data tend to the conclusion that cell cooperation depends to a greater extent on the composition of the medium rather than on the age of the cell or animal.     

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.     

Inhibition of DNA Synthesis in C6 Glioma Cells Following Cellular Incorporation of GM1 Ganglioside and Choleragenoid Exposure

The B subunit of cholera toxin, which is multivalent and binds specifically to GM1 ganglioside on the cell surface, has previously been used as a ganglioside-specific probe to regulate DNA synthesis in thymocytes and fibroblasts. To explore in more detail this growth-regulatory action of gangliosides, C6 glioma cells (which are GM1 ganglioside deficient) were used as a model system. When cultures of C6 cells were first treated with GM1, followed by exposure to the B subunit, proliferation was inhibited, as measured by 3H-labeled thymidine incorporation into DNA. Pretreatment of the cells with 50 microM GM1 for 15 min (followed by washing with fetal calf serum) and incubation with 1 microgram/ml of B subunit for 21 h was sufficient to reduce DNA synthesis to 15% of control values (and confirmed by autoradiographic analysis), although maximal inhibition could be achieved with as little as 30 min exposure to B, followed by washing. Furthermore, the B subunit inhibited the response of the C6 cells to basic fibroblast growth factor only following GM1 pretreatment. The B subunit-induced inhibition of DNA synthesis was specific for the ganglioside GM1, and was unrelated to increases of cyclic AMP. These results demonstrate that cell-incorporated GM1 ganglioside may act as a receptor capable of undergoing a specific ligand interaction, subsequently affecting molecular processes at the nuclear level.     

Cooperation of Hepatocytes in vitro in the Rhythm of Protein Synthesis is Promoted by the GM1 Ganglioside Contained in Vesicles and Liposomes

The medium conditioned by dense, self-synchronized hepatocyte cultures was centrifuged at 150000 g to obtain two fractions. The light fraction (supernatant fluid) contained ganglioside monomers and micelles, and the heavy fraction (pellet) contained gangliosides in the vesicles shed from the cell membrane. In the test populations of hepatocytes, the rhythm of protein synthesis was used as an indicator of cell synchronization resulting from their cooperative activity. Diluted hepatocyte cultures with asynchronous fluctuations of protein synthesis proved to be synchronized by both the initial conditioned medium and its vesicular fraction. Our previous studies have shown that this occurs under the effect of GM1 monosialoganglioside, which is released from cultured cells and accumulated in the conditioned medium. Liposomes consisting of GM1 and phosphatidylcholine from egg yolk (1 : 19 mol%), compared to free exogenous GM1, synchronized the rhythm of protein synthesis more effectively: synchronization was observed at a GM1 concentration in liposome suspension of only 0.0003 M, compared to 0.06 M and higher in the case of free GM1. Thus, GM1 as a component of membranes and monolayer lipid structures proved to be much more effective than free GM1 in promoting hepatocyte cooperation with respect to the rhythm of protein synthesis.     

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.     

Sialidase activities of cultured human fibroblasts and the metabolism of GM3 ganglioside

Free sialic acid has been found in the cell-conditioned medium of human foreskin fibroblasts. It is proposed that the accumulation of extracellular sialic acid may result from the hydrolysis of GM3 ganglioside on the cell surface of these fibroblasts. Sialidase activities with GM3 ganglioside and sialyllactitol as substrates were demonstrated in cell-conditioned medium, and the levels of their activities correlated positively with cell density. The GM3 sialidase activity at pH 4.5 was 4.1 and 38 pmol/h/ml of medium at sparse and confluent densities, respectively; the corresponding activities with sialyllactitol as the substrate were 12 and 75 pmol/h/ml of medium (pH 4.5). The pH versus activity profiles with GM3 as the substrate suggested the presence of a second sialidase with an optimal activity at pH 6.5 in the conditioned medium of preconfluent cells. This activity was virtually absent in the medium of contact-inhibited cells and could not be assayed with sialyllactitol as the substrate. The turnover of cell surface GM3 was assessed by pulse labeling human foreskin fibroblasts with a radioactive precursor of sialic acid ([1-14C]N-acetylmannosamine) and a radioactive precursor of ceramide ([3,3-3H2]serine). During a chase period of 24 h turnover of the doubly labeled cellular GM3 was observed; there was a loss of about 35% of the 14C-labeled sialic acid without any measureable loss of 3H-labeled ceramide from GM3. We have speculated that the enzyme-catalyzed removal of sialic acid from the GM3 ganglioside on the extracellular aspect of the plasma membrane may be a necessary event involved in the modulation of cell growth.     

Melatonin promotes and synchronizes protein synthesis in hepatocyte culture from old rats

The effect of 1 to 1000 nM melatonin was studied on daily cultures of rat hepatocytes on slides in serum-free medium. The minimum melatonin concentration (1 nM) proved to synchronize protein synthesis in asynchronous sparse cultures of hepatocytes from rats of different age, and a circahoralian rhythm of protein synthesis was revealed in them. In dense weekly synchronous hepatocytes from old rats (2.5 years old with the weight of about 600 g), melatonin improved cell synchronization to the level of young animals. Melatonin treatment increased the mean rate of protein synthesis in rats of different age.     

Mechanism for the negative regulation of cell proliferation by ganglioside GM3 in high glucose-treated glomerular mesangial cells

We recently identified ganglioside GM3 as a modulator of glomerular hypertrophy in streptozotocin-induced diabetic rats (Life Sci., 72: 1997-2006, 2003). This study examined whether alteration of ganglioside GM3 expression could modulate the high glucose-induced proliferation of glomerular mesangial cells (GMCs). GMCs isolated from rat kidneys were cultured under normal (5.6 mM) or high (25 mM) glucose condition for 24-72 hrs. Cell proliferation was predominantly stimulated when GMCs were cultured with high glucose as well as 20 microM of d-threo-PDMP, an inhibitor of ganglioside biosynthesis, for 24 hrs, whereas raising ambient glucose significantly reduced the mesangial sialic acid contents. Based upon mobility on high-performance thin-layer chromatography (HPTLC), GMCs showed a complex pattern of ganglioside expression that consisted of three major components of gangliosides, mainly GM3. High glucose induced a significant reduction of ganglioside expression with apparent changes in the composition of major ganglioside GM3, and semi-quantitative analysis by HPTLC showed that ganglioside GM3 was reduced to 62% of GMCs cultured under normal glucose condition. A prominent immunofluorescence microscopy using anti-GM3 monoclonal antibody also showed a dramatic disappearance of immunoreactivity in high glucose-treated GMCs. Moreover, high glucose significantly lowered the Km values of GM3 synthase (16 microM vs. 49 microM), but did not change the Vmax. These results provide the pathophysiological relationship between the high glucose-induced proliferation of GMCs and the decreased expression of ganglioside GM3, indicating a mechanism for the negative regulation of mesangial proliferation by ganglioside GM3. This mechanism may play an important role in the development of diabetic glomerulopathy.     

Nerve growth factor-induced neurite formation in PC12 cells is independent of endogenous cellular gangliosides

The PC12 rat pheochromocytoma cell line is an established model for nerve growth factor (NGF)-induced neurite formation. It has been shown that when gangliosides are added to the culture medium of PC12 cells, NGF-induced neurite formation of PC12 cells is enhanced. To determine the role of endogenous cellular gangliosides themselves in NGF-elicited neurite formation, we depleted cellular gangliosides using the new specific glucosylceramide synthase inhibitor, d, l-threo-1-phenyl-2- hexadecanoylamino-3-pyrrolidino-1-propanol.HCl (PPPP). 0.5-2 microM PPPP rapidly inhibited ganglioside synthesis and depletedcellular gangliosides. Nonetheless, over a concentration range of 5-100 ng/ml NGF, in both low serum and serum-free medium, neurite formation was normal. Even pretreatment of PC12 cells for up to 6 days with 1 microM PPPP followed by cotreatment with PPPP and NGF for 10 days, still did not inhibit neurite formation. The conclusion that ganglioside depletion did not block neurite formation stimulated by NGF was supported by the lack of effect of PPPP, under these same conditions, on cellular acetylcholine esterase activity, a neuronal differentiation marker (73.8 +/- 12.1 versus 67.2 +/- 4.6 nmol/min/mg protein at 50 ng/ml NGF; control versus 1 microM PPPP). These findings, together with previous studies showing enhancement of NGF-induced neurite formation by exogenous gangliosides, underscore the vastly different effects that exogenous gangliosides and endogenous gangliosides may have upon cellular functions.      

Promotion of Neuritogenesis in Mouse Neuroblastoma Cells by Exogenous Gangliosides. Relationship Between the Effect and the Cell Association of Ganglioside GM1

Ganglioside GM1 promoted neuritogenesis of neuroblastoma cells, neuro-2a clone, in monolayer culture. GM1 bound to neuro-2a cells in three distinct forms, one removable by treatment with serum-containing solutions, one serum-resistant and labile to trypsin treatment, and one resistant to serum and trypsin treatments. The proportions among the three forms of cell-associated GM1 varied in relation to duration of exposure to ganglioside, ganglioside concentration in the medium, and number of cells in culture. The form removable by serum was predominant at the initial stages of association and at the highest ganglioside concentrations (over 10(-6)M); the trypsin-labile and -stable forms tended to increase with increasing cell number and decreasing ganglioside concentration. The neuritogenic effect of GM1 was higher when neuro-2a cells were incubated for 24 h in the presence of GM1 and fetal calf serum. Under this condition the percentage of neurite-bearing cells increased from 11% of control to 62% at the optimal ganglioside concentration of 10-4M. The effect was still present, although to a lower extent (from 11% to 28% of neurite-bearing cells), when cells were first exposed for only 2 h to GM1, then washed and incubated for 24 h in the presence of fetal calf serum. The trypsin-labile and -stable forms of cell-associated GM1 had a fundamental role in the effect, whereas the form removable by serum was not involved. The preparation of GM1 used was extremely pure (99%) and, in particular, had a peptide contamination, if any, less than 1:20,000-1:50,000.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 μM or forskolin at 10 μM 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 μM or H8 (N-(2-[methylamino]ethyl)-5-isoquinolinesulfonamide hydrochloride) at 25 μM 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. cAMP-dependent protein kinases also affect the protein synthesis rhythm. 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. 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.     

Neuronal Ganglioside Increases Dependent on the Neuron-Glia Interaction in Primary Culture

Dissociated neuronal cells from rat embryonic hemispheres were cultivated on astroglial layers. The increase in ganglioside content of the cocultures was more rapid than that of neuronal cultures seeded on polylysine surfaces for the first 24 h, and the extent of the increase was greater 7 days after inoculation, probably because of interaction between the preformed astroglial layers and the neuronal cells in vitro. The promoted expression of the a-pathway gangliosides, GM1 and GD1a, was recognized by TLC and the increase in GM1 was immunologically ascertained. The incorporation of 3H-labeled N-acetyl-D-mannosamine into GD3 and b-series gangliosides was elevated for the first 24 h. However, cocultures in which there was no contact between neuronal cells and the astroglial sheet showed no appreciable increase in incorporation. Thus, cell surface changes were induced at the membrane glycolipid level in the neuronal cells by contact with astroglial layers. The synthesis and expression of neuronal gangliosides are discussed in relation to the onset of neuron--glia interaction.     

Synthesis, Shedding, and Intercellular Transfer of Human Medulloblastoma Gangliosides: Abrogation by a New Inhibitor of Glucosylceramide Synthase

Abstract: The biological activity of human medulloblastoma tumor gangliosides very likely involves the interaction of these molecules with host cells in the tumor microenvironment. To trace the hypothesized intercellular transfer of shed medulloblastoma gangliosides, we used an in vitro dual-chamber culture system in which the tumor cells, the shed gangliosides, and the target cells to which they might bind would not be perturbed during the transfer process. We observed that under these unmanipulated conditions, gangliosides were shed by the Daoy medulloblastoma cell line (∼300 pmol/10⁸ cells/h), traversed the chamber membrane, and stably bound to the target fibroblasts at the very high density of 10⁷ molecules per cell within 48 h. To determine if this substantial intercellular transfer of shed gangliosides, with its potential of modifying target cell function, could be blocked, we evaluated a new inhibitor of glucosylceramide synthase, dl - threo -1-phenyl-2-hexadecanoylamino-3-pyrrolidino-1-propanol (PPPP). PPPP (1.0 µ M ) reduced (90%) Daoy cell ganglioside content strikingly, without causing toxicity or inhibiting cell proliferation. Subsequently, ganglioside shedding by the medulloblastoma cells was diminished significantly (to ∼50 pmol/10⁸/h), and binding of radiolabeled shed medulloblastoma gangliosides to target fibroblasts was consequently almost completely abrogated. We conclude that the shedding and transfer of potentially biologically active human medulloblastoma gangliosides can be diminished effectively by PPPP.     

Self-synchronization of the protein synthesis rhythm in HaCaT cultures of human keratinocytes

In cultures of human keratinocytes HaCaT contained in a serum-free medium on glass, a circahoralian rhythm of protein synthesis was found similar to the one in hepatocytes in vitro. The intensity of the synthesis was determined by the inclusion of ³H-leucine corrected for the pool of free marked leucine. Rhythm was studied in washed 1- or 2-day cultures after the change of the medium. The medium conditioned with keratinocytes HaCaT synchronized the rarefied hepatocyte cultures nonsynchronous in the control. Therefore, the keratinocytes liberate synchronizing factors into the medium. A BAPTA-AM chelator of calcium ions eliminates the protein synthesis rhythm both in dense hepatocyte cultures synchronous in the control and in the HaCaT keratinocyte cultures. The effect of the H7 inhibitor of protein kinases was analogous. Thus, both in keratinocytes and hepatocytes, self-synchronization of fluctuations of the intensity of protein synthesis takes place. The mechanism of self-synchronization is the calcium-depending phosphorylation of cell proteins.     

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.     

Mitogenic effects of bacterial neuroaminidase and lactosylceramide on human cultured fibroblasts.

Exogenously added bacterial neuraminidase and lactosylceramide both stimulated the growth of cultured human skin fibroblasts. Neuraminidase (100 units/ml) increased DNA synthesis 1.9-fold and cell density 1.4-fold after 24 and 48 h, respectively, in culture. Treated fibroblasts contained less ganglioside NeuAc alpha 2-3Gal beta 1-4GlcCer (GM3), presumably due to neuraminidase-catalyzed hydrolysis to lactosylceramide. Addition of lactosylceramide (100 microM) to the fibroblast culture medium also increased DNA synthesis threefold within 24 h and cell density twofold after 48 h. These findings are compatible with a mechanism by which the proliferation of human fibroblasts is regulated by the relative levels of GM3 and lactosylceramide in the plasma membrane.     

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.