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.     

The possible connection of adenylic nucleotides to the rhythm of protein synthesis in hepatocytes in vitro

Circahoral protein synthesis rhythms observed in hepatocytes in vitro differ in phase from the oscillations of intracellular amount of ATP. ATP added to culture medium interferes with the rhythms of protein synthesis and intracellular DNA content. Addition of ADP increases both the incorporation level of hepatocytes and ATP content. The data obtained has been discussed.     

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.     

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.     

Relative value of light and food as synchronizers of liver phosphorylase circadian rhythm.

The role played by light and feeding schedules on the circadian rhythm of glycogen content and phosphorylase activity of the liver has been studied. In one experiment, mice were subjected to a regimem of constant darkness during 21 days and compared with mice kept in 12 hrs of light alternating with 12 hrs of darkness. Both groups received food and water ad libitum. Liver glycogen content as well as phosphorylase activity showed, with slight differences, similar circadian variations. In a second experiment, mice under similar lighting conditions (LD 12:12), with water access ad libitum, were divided into two groups; one was offered food ad libitum while the other group recieved food from 0700 to 1800 only. This experiment allowed up to compare two different schedules of food intake; ad libitum, normal schedule (from 1800 to 0600) and reversed schedule (from 0700 to 1800). A complete reversal of the circadian rhythm was observed after 21 days in the group with the reverted feeding schedule. We conclude that food can function as the primary synchronizer in spite of the lighting regimen.     

Amiloride inhibits protein synthesis in isolated rat hepatocytes

The effects of amiloride on Na⁺ ion influx, amino acid transport, protein synthesis and RNA synthesis have been studied in isolated rat hepatocytes. The initial rate of ²²Na⁺ uptake and the amount of ²²Na⁺ taken up at later time points were decreased in hepatocytes incubated in the presence of amiloride. Amiloride inhibited by about 25% the influx of α-methylamino[1?¹⁴C]isobutyric acid, a specific substrate for the A (Alanine preferring) system of neutral amino acid transport. By contrast, the activity of system L (Leucine preferring) was not affected by amiloride. Rates of protein synthesis were determined by using high extracellular concentrations of [¹⁴C]valine in order to maintain a constant amino acid precursor pool. Amiloride inhibited protein synthesis by 85% and had no effect on RNA synthesis. Half-maximal inhibition of protein synthesis occurred with amiloride at about 150 μM. In the absence of Na⁺ in the incubation medium, the rate of protein synthesis was reduced by about 35% and no further inhibition was observed with amiloride. These results suggest that in isolated rat hepatocytes protein synthesis is partially dependent on Na⁺, and that amiloride is an efficient inhibitor of protein synthesis.     

Plasma protein synthesis by isolated rat hepatocytes

A system of preparation of rat hepatocytes with extended viability has been developed to study the role of hormones and other plasma components upon secretory protein synthesis. Hepatocytes maintained in minimal essential medium reduced the levels of all amino acids in the medium except the slowly catabolized amino acids leucine, isoleucine, and valine, which steadily increase as the result of catabolism of liver protein. Although the liver cells catabolize 10-15% of their own protein during a 20-h incubation, the cells continue to secrete protein in a linear fashion throughout the period. The effects of insulin, cortisol, and epinephrine on general protein synthesis, and specifically on fibrinogen and albumin synthesis, have been tested on cells from both normal rats and adrenalectomized rats. Cells from normal animals show preinduction of tyrosine amino transferase (TAT), having at the time of isolation a high level of enzyme which shows only an increase of approximately 60% upon incubation with cortisol. In contrast, cells from adrenalectomized animals initially have a low level of enzyme which increases fourfold over a period of 9 h. The effects of both epinephrine and cortisol on protein synthesis are also much larger in cells from adrenalectomized animals. After a delay of several hours, cortisol increases fibrinogen synthesis sharply, so that at the end of the 20-h incubation, cells treated with hormone have secreted nearly 2.5 times as much fibrinogen as control cells. The effect is specific; cortisol stimulates neither albumin secretion nor intracellular protein synthesis. The combination of cortisol and epinephrine strongly depresses albumin synthesis in both types of cells. Insulin enhances albumin and general protein synthesis but has little effect on fibrinogen synthesis.     

Ecdysterone-induced protein synthesis in vitro

Ecdysterone added in vitro to wing tissue from diapausing Antheraea polyphemus pupae induced the synthesis of several epidermal cell proteins. This is one of few instances in which any steroid hormone in physiological concentrations has been able to induce specific protein synthesis in target tissue in vitro soon after hormone stimulation. Hormone-treated tissue was incubated with ³H-leucine while control tissue was incubated with ¹⁴C-leucine. Polyacrylamide gel electrophoretic distribution of labelled wing tissue proteins after ecdysterone stimulation in vitro for various periods of time was determined. The ${}^3\text{H}{}^{14}\text{C}$ ratio emphasized the areas of increased protein synthesis due to ecdysterone. These areas of increased protein synthesis were reproducible with several ecdysterone concentrations and with different incubation times. Induction of protein synthesis occurs at an earlier time period when the hormone dosage is higher, i.e. the lower the dosage, the longer it is necessary for exposure of tissue to hormone. α-Ecdysone, known to initiate the moulting process in vitro in some insect species, also induced protein synthesis. Cortisol, a mammalian steroid hormone, produced no hormone specific protein synthesis. Therefore, the results seen with ecdysterone and α-ecdysone are not the result of non-specific steroid stimulation. When no hormone was added to the incubation medium (control), only one area of the polyacrylamide gel demonstrated protein synthesis. Therefore, there are a few proteins being synthesized in vitro in wing tissue, removed from diapausing animals without hormone stimulation, which may be related to the ‘injury phenomenon’. Protein banding patterns were also determined and compared with the radioactivity profile. The study of such early biochemical and physiological responses of target tissue to hormones will aid in our understanding of a hormone's mechanism of action, since the earlier an event occurs, the more likely that it is the primary result of hormone stimulation.     

In vitro synthesis of alpha-fetoprotein by individual hepatocytes and microcolonies of human hepatocytes]

Alpha-fetoprotein (AFP) produced by individual hepatocytes and hepatocyte microcolonies was detected with microelectrophoresis-precipitation in polyacrylamide gel. Hepatic cells of 6--13-week-old human embryos were cultivated in vitro for 2 to 5 days. 23 of 28 individual cells, and 89 of 91 microcolonies, built up of 2--35 cells, were demonstrated to produce AFP within the range of 70--800 pg per 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.     

Studies on gluconeogenesis and protein synthesis in isolated hepatocytes.

Glucose production was studied in isolated hepatocytes using various substrates and with increasing substrate concentrations (0-10 mM). Fructose was the best gluconeogenic substrate while other substrates studied stimulated net glucose production in the following decreasing order: lactate, pyruvate, glycerol, galactose, alanine, and succinate. Studies on oxygen consumption showed that endogenous respiration was linear for 60 min and was not altered by extracellular calcium. Studies on the incorporation of 14C-leucine into protein was linear for only 3-4 hr in cells containing low glycogen. However, cells containing high glycogen incorporated 14C-leucine into protein linearly for 8-10 hr. About 3 mg of protein per g per hr was synthesized by isolated cells when incubated for 4 hr with amino acids mixture, glucose, lactate, and insulin.     

Spermidine level and protein synthesis are coregulated in nonproliferating hepatocytes

The relationship between polyamines and the rate of protein synthesis was investigated in non-proliferating cells: primary cultures of adult rat hepatocytes maintained in serum-free media, and treated with dexamethasone or dexamethasone + insulin. During the second day of culture, polyamine biosynthesis became induced along with the rate of protein synthesis. While the activity of ornithine decarboxylase and the intracellular concentration of putrescine increased only transiently and that of spermine declined, the rise of the protein synthetic rate was paralleled by that of the intracellular spermidine concentration. The polyamine analogue diamino-propanol specifically decreased spermidine content and the protein synthetic rate. The intracellular concentration of spermidine was found subject to tight homeostatic regulation, e.g. not being altered by the addition of up to 1 mM of this polyamine to the culture medium. In contrast, addition of putrescine or spermine led to an increase in their respective intracellular concentrations. These findings indicate that spermidine specifically of the polyamines is involved in protein synthesis in the intact hepatocyte. Moreover, spermidine may mediate part of the trophic action of dexamethasone and insulin upon cultured hepatocytes.     

Immunofluorescence localization of plasma protein synthesis in cultured chick hepatocytes.

Fibrinogen, albumin and the major apoprotein of high density lipoprotein (apoprotein A) were localized in a primary embryonic chick liver cell culture by indirect immunofluorescence staining. Changes in the pattern of plasma protein synthesis under a variety of conditions, as measured by the accumulation of secreted plasma proteins in the culture medium, could be studied at the cellular level because relative fluorescence intensities were shown to reflect synthetic rates. In all cases studied, the immunofluorescence of the hepatic parenchymal cells was of a similar intensity throughout the monolayers, indicating that the cells in culture constitute a homogeneous population with respect to the synthesis of these plasma proteins.     

Regulation of protein synthesis by estradiol-17beta in cultured hepatocytes

Estradiol-17beta added to cultured chick embryo hepatocytes induced the appearance in the medium of a phosphoprotein, identified as phosvitin on the basis of: (i) its behaviour on ionic exchange columns; (ii) its SDS-acrylamide gel electrophoretic mobility; (iii) its amino acid composition. The hormone treatment was also followed by a decreased synthesis of other proteins secreted by the hepatocytes.     

Demonstration of a hourly rhythm of protein synthesis in human stomach biopsies

The rhythmic changes in the rate of protein synthesis with a period of 30-40 minutes were demonstrated in biopsy specimens of patients with duodenal ulcer. The oscillation amplitude was up to 20-40%. Eight patients of the 22 did not show such a rhythm.     

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.     

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.     

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.