Mononuclear cell-mediated modulation of synovial cell metabolism. II. Increased hyaluronic acid synthesis by a monocyte cell factor (MCF)

Treatment of cultured human synovial cells with a mononuclear cell factor (MCF) enhanced their ability to synthesize glycosaminoglycans (GAG), but GAG repartition between extracellular, pericellular and intracellular compartments was found to be the same as in control. Hyaluronic acid (HA) production, which represents 80-90% of all secreted GAG, was stimulated 2 1/2-3-fold, but the HA molecular weight was not modified. The MCF increased the hyaluronate synthetase activity of synovial cells in similar proportions. Actinomycin D inhibited the increase in hyaluronate synthetase activity produced by MCF, indicating that this increase involves new synthesis of mRNA. Stimulation of both HA synthesis and hyaluronate synthetase activity by MCF was suppressed by 10(-4)-10(-5) M indomethacin (an inhibitor of cyclo-oxygenase), suggesting that MCF effect is prostaglandin-dependent.     

Interleukin 1 enhances synovial cell hyaluronate synthesis

Interleukin 1 enhances proliferation of murine thymocytes in the presence of lectins, and is also known to stimulate the release of prostaglandins and neutral proteases from a variety of cell types. We have previously shown that a factor isolated from the culture media of disaggregated lining cells of the human synovial membrane was indistinguishable from monocyte-derived interleukin 1. We report here that interleukin 1 from either source stimulates hyaluronate synthesis by synovial membrane cells. Upon gel filtration or isoelectric focusing of synovial cell supernatants, the hyaluronate-stimulatory activity co-fractionates with the interleukin 1 activity. Enhanced cell secretion of hyaluronate is a newly described metabolic effect of interleukin 1.     

Formation of proteoglycan aggregates in rat chondrosarcoma chondrocyte cultures treated with tunicamycin

Proteoglycan monomer and link protein isolated from the Swarm rat chondrosarcoma both contain glycosylamine-linked oligosaccharides. In monomer, these N-linked oligosaccharides are concentrated in a region of the protein core which interacts specifically with both hyaluronate and link protein to form proteoglycan aggregates present in cartilage matrix. Chondrocyte cultures were treated with tunicamycin to inhibit synthesis of the N-linked oligosaccharides, and the ability of the deficient proteoglycan and link protein to form aggregates was studied. Cultures were pretreated with tunicamycin for 3 h and then labeled with either [3H]mannose, [3H]glucosamine, [3H]serine, or with [35S]sulfate for 6 h in the presence of tunicamycin. Formation of link protein-stabilized proteoglycan aggregates in the culture medium was inhibited by up to 40% when the cells were treated with 3 micrograms of tunicamycin/ml, a concentration which inhibited 3H incorporation with mannose as a precursor by about 90%, but by only 15% with glucosamine as a precursor. When exogenous proteoglycan aggregate was added to the culture medium, however, it was found that both endogenous monomer and link protein synthesized in the presence of tunicamycin were fully able to form link-stabilized aggregates. This suggests that glycosylamine-linked oligosaccharides on monomer and on link protein are not necessary for their specific interactions with hyaluronate and with each other. Further, although tunicamycin did not inhibit net synthesis of hyaluronate, transfer of hyaluronate from the cell layer to the culture medium was retarded. This phenomenon accounted for most if not all of the decrease in the amount of proteoglycan which formed aggregates in the medium of cultures treated with tunicamycin.     

Cellular Mechanisms of Interferon Production

Rabbit kidney cell cultures stimulated with either double-stranded polyinosinate-polycytidylate (poly I:poly C) or with ultraviolet-irradiated Newcastle disease virus (UV-NDV) produce two types of interferon response, designated "early" and "late," respectively. The early response is suppressed by inhibitors of RNA or protein synthesis and is therefore thought to represent de novo synthesis of interferon. Circumstantial evidence suggested that this interferon response is regulated by a translation control mechanism. Late interferon production with poly I:poly C only took place in the presence of inhibitors of RNA or protein synthesis. The late interferon is therefore likely to be derived by the activation of an interferon precursor. The stimulation of late poly I:poly C-induced interferon production by cycloheximide suggested the existence of a second, posttranslational level of control of interferon production. This posttranslation control seems to be activated by interferon. UV-NDV can probably suppress the synthesis of the posttranslation inhibitory protein, and therefore it stimulates a late interferon response in the absence of inhibitors of RNA or protein synthesis. It is postulated that both the translation and posttranslation inhibitor participate in the development of a cellular refractory state to repeated interferon stimulation. The picture of interferon which emerges from this study is one of a heterogenous class of proteins whose production is controlled by cellular repressors acting at various levels.     

Paradoxical effects of protein synthesis inhibitors on uridine uptake in cultured cells: Possible role of uncharged tRNA in regulating metabolism

Previous studies (J. Biol. Chem, 253: 99–105, 1978) showed that thyrotropin-releasing hormone (TRH) acutely stimulated uridine uptake in pituitary cell (GH₄C₁) cultures. Studies on the role of protein synthesis in this response to TRH led to the finding that an inhibitor of ribosomal translation, cycloheximide, also stimulated uridine uptake acutely. Studies reported here attempt to determine the mechanism of cycloheximide action and whether cycloheximide and hormone stimulation of uridine uptake occurred by similar pathways. The experiments presented indicate that: (1) seven inhibitors of ribosomal translation stimulated uridine uptake; (2) in contrast, inhibition of protein synthesis at tRNA aminoacylation resulted in reduced rates of uridine uptake; (3) inhibition of tRNA aminoacylation blocked cycloheximide but not TRH stimulation of uptake; (4) cycloheximide stimulation of uptake was restricted to amino acid-depleted cultures; (5) amino acid supplementation stimulated uridine uptake with a time-course identical to that of cycloheximide; (6) cycloheximide and amino acid supplementation promoted reacylation of cellular tRNAs in amino acid-depleted cultures; and (7) cycloheximide stimulation of uridine uptake resulted from enhanced nucleoside phosphorylation rather than increased uridine transport. We conclude that cycloheximide and amino acid stimulation of uridine phosphorylation may be mediated through a common pathway involving the extent of amino-acylation of cellular tRNAs. Furthermore, cycloheximide and TRH stimulate uridine phosphorylation by pathways that are distinguishable. It is apparent that not all cellular effects of cycloheximde can be attributed solely to inhibition of the synthesis of proteins.     

Translation of chicken interferon messenger in a cell-free protein synthesis system and in a cell culture

A highly effective cell-free system for protein synthesis was obtained from rabbit reticulocytes and for the first time used for synthesis of biologically active chicken interferon. The optimal conditions for translation of its mRNA were developed. The translation efficacy in the cell-free system was 10-50 times higher than that in the culture of heterologous cells. The higher the purity level of RNA, the higher the translation level. With respect to poly (A+) RNA sedimenting in the sucrose gradient 9S the efficacy reached 2560 units per 1 microgram of RNA. By the content of poly (A), sequences and rate of the sedimentation, mRNA of the chicken interferon was similar to that of the human fibroblast cell interferon. The possible translation of mRNA of the chicken interferon at low concentrations of exogenic potassium ions in the cell-free system is explained by production of interferon in infected cells where the concentration of the intracellular potassium significantly decreases which is indicative of the mRNA interferon similarity with virus templates. It was found that only albino New Zealand rabbits, but also chinchilla may be used for preparation of the cell-free protein synthesizing system. Various exogenic templates in the mRNA-dependent cell-free system prepared from reticulocyte nonfractionated lysate by treatment with micrococcal nuclease stimulated the protein synthesis by 7-15 times.     

Rapid increase in poly(A) (+) mRNA content following inhibition of protein synthesis

When resting 3T6 cells undergo a serum-induced transition to the growing state, the cytoplasmic content of ribosomal, transfer and messenger RNA increase as the cells prepare for DNA synthesis. The normal linear increase in mRNA content occurs even when the production of ribosomes is blocked. In this paper we determine the effect of inhibiting protein synthesis on the increase in poly(A) (+) mRNA content. Resting cells were serum stimulated in the presence of cycloheximide or puromycin at levels which inhibit protein synthesis by greater than 95%. Cytoplasmic poly(A) (+) mRNA content was determined at various times thereafter. We found that mRNA content increased five to ten times more rapidly in drug treated cells than in control cells stimulated in the absence of inhibitors. mRNA content increased 50–70% by one hour, and 60–90% by two hours following stimulation in the presence of inhibitor, and remained more or less constant thereafter. In contrast, mRNA content increased linearly in control stimulated cultures and did not double until about 15 hours after stimulation. The rapid increase in mRNA content is most likely the result of inhibition of protein synthesis rather than a secondary effect of the drug since the same observations were made in growth stimulated cells if protein synthesis was blocked with either puromycin or cycloheximide. A similar effect was also observed with resting 3T6, exponentially growing 3T6 and growing HeLa cells following exposure to cycloheximide, although the magnitude of the increase was less than that observed with growth stimulated cells. Puromycin had negligible effect on mRNA content in resting or exponentially growing cells. The rapid increase in cytoplasmic poly(A) (+) mRNA content was not due to rapid unbalanced export of nuclear poly(A) (+) RNA into the cytoplasm since there was no decrease in nuclear poly(A) content following serum stimulation in the presence of cycloheximide.     

Continuous culture of normal adult mammalian hepatocytes exhibiting parenchymal functions

Summary Past in vitro studies of liver-cell functions have been performed on nonproliferating primary cells or serially propagated hepatic monolayers of neoplastic or fetal origin. We optimized conditions for the selective culture of adult rabbit and canine liver parenchymal cells and presently have four differentiated proliferating monolayer strains. At the 30th passage level these hepatic cultures still display the specific liver parenchymal functions of albumin and fibrinogen synthesis as well as tyrosine aminotransferase activity. Optimization of the conditions for hepatocyte culture was monitored by [³H]thymidine incorporation. Albumin and fibrinogen synthesis were measured by bioradioimmunoassay and tyrosine transaminase activity by a modification of Diamondstone's assay. Albumin and fibrinogen synthesis were correlated with hepatocyte growth kinetics. Supported by the Medical Staff Research and Education Fund, Wayne County General Hospital, Eloise, Michigan 48132, and American Cancer Society Institutional Grant No. 40M, The University of Michigan, Ann Arbor, Michigan 48109.     

Tunicamycin partially delays release of newly synthesized hyaluronate from Swarm rat chondrosarcoma chondrocytes

Tunicamycin (5-100 micrograms/ml) inhibits total [3H]hyaluronate synthesis in cultures of Swarm rat chondrosarcoma chondrocytes by approx. 15%. In agreement with previous results (Lohmander, L.S., Fellini, S.K., Kimura, J.H., Stevens, R.L. and Hascall, V.C. (1983) J. Biol. Chem. 258, 12280-12286) the relative decrease in [3H]hyaluronate radioactivity in the culture medium was greater than in the cell layer. Treated cultures show a concentration-related decrease in the proportion of medium 35S-labelled proteoglycans forming 'natural aggregates'. Pulse-chase experiments in cultures pretreated with tunicamycin (100 micrograms/ml, 13 h) showed that 30-40% of the total [3H]hyaluronate synthesized is released more slowly from these chondrocytes than from control culture chondrocytes. Release of some hyaluronate molecules may be delayed by 6 h or more. After a 24 h chase period almost all the [3H]hyaluronate is released from the cells. The proportion of 35S-labelled proteoglycans present as aggregates in the 24 h chase medium (57%) remained depressed compared to controls (81%), although the monomers could form aggregates if exogenous hyaluronate was added. Hyaluronate synthesized in the presence of tunicamycin has the same hydrodynamic size as control culture hyaluronate, as assessed by its sedimentation profile in CsSO4 gradients and its chromatographic profile on a dissociative Sephacryl S-1000 column.     

Effect of tunicamycin on the turnover of epidermal growth factor receptors in cultured calf aorta smooth muscle cells: Comparison with IMR-90 human lung fibroblasts

Treatment of cultured calf aorta smooth muscle cells with tunicamycin, a potent inhibitor of dolichol-mediated glycosylation, resulted in progressive loss of receptors for epidermal growth factor with 50% of receptors lost after 6 h. Receptor half-life was also 6 h with cycloheximide treatment but was 12 h with either actinomycin D or camptothesin treatment. The epidermal growth factor-induced processing (internalization and/or degradation) of residual receptors remaining after tunicamycin treatment appeared to be unaltered.50% decrease in ¹²⁵I-labeled epidermal growth factor binding was observed also with IMR-90 fibroblasts upon 6 h treatment with tunicamycin, although these cells were less sensitive to inhibition by tunicamycin of glycosylation and protein synthesis.     

Rapid changes in poly (A)(+) mRNA content in growth stimulated fibroblasts following perturbations in protein synthesis.

We have previously shown that when resting 3T6 cells are serum stimulated in the presence of inhibitors of protein synthesis, poly(A)(+) mRNA content increases extremely rapidly relative to cells stimulated in the absence of drug. Poly(A)(+) mRNA content nearly doubles within two hours, but then remains constant for at least ten hours (Johnson and Meister, '77). In this report we show that continuous exposure to both serum and cycloheximide are required to maintain this elevated mRNA level. Removal of either leads to an equally rapid decrease in poly(A)(+) mRNA content. If cycloheximide is withdrawn at either two or ten hours following serum stimulation in the presence of the drug, allowing the rapid (< 30 minutes) restoration of the rate of protein synthesis, we observe that poly(A)(+) mRNA content decreases within two hours to a level nearly equal to that found in resting cells prior to stimulation. If the drug is withdrawn but the serum stimulus is not, the rapid decrease in poly(A)(+) mRNA content is followed by an increase which is parallel to that which occurs in cultures stimulated in the absence of drug, but displaced from the latter by an interval approximately equal to the length of exposure of the drug. These results show that the mammalian cell is able to decrease as well as increase its content of poly(A)(+) mRNA in response to drug induced perturbations in the rate of protein synthesis. The changes in poly(A)(+) mRNA content occur extremely rapidly and may represent an attempt by the cell to correct the perturbation.     

Increased hyaluronate synthesis is required for fibroblast detachment and mitosis.

Human-embryo fibroblasts were synchronized by means of colchicine and cytochalasin, and the production of hyaluronate was determined by [3H]glucosamine incorporation and ion-exchange chromatography. Cells arrested by colchicine synthesized small amounts of hyaluronate, whereas cells blocked by cytochalasin were stimulated in hyaluronate production. When the colchicine block was released, there was an increased synthesis of hyaluronate, which appeared first in the cellular fraction and was then shed into the culture medium. After release of the cytochalasin block, the hyaluronate production declined to that found with unsynchronized cells. A comparable increase of hyaluronate synthase activity was observed during mitosis. When hyaluronate synthesis was blocked by periodate-oxidized UDP-glucuronic acid, the cells were arrested in mitosis before rounding of cells. These results suggest that hyaluronate synthesis is required for detachment and rounding of cells during mitosis.     

Uptake of hyaluronate by cultured cells

[¹⁴C]hyaluronate is internalized by adsorptive pinocytosis by cultured rat hepatocytes and human synovial cells, but not by human skin fibroblasts and smooth muscle cells. Hyaluronate oligosaccharides compete for the uptake of hyaluronate by hepatocytes without being internalized themselves at the doses used. It is suggested that for adsorptive pinocytosis a hyaluronate molecule has to bind to at least two receptors on the cell membrane.     

Effect of cycloheximide and tunicamycin on the gonadotrophin-releasing hormone stimulated distal glycosylation of luteinizing hormone by rat pituitary cells

We have previously demonstrated that gonadotrophin-releasing hormone (GnRH) induces not only changes in quantity but also in quality on secreted luteinizing hormone (LH), by increasing [14C]Leu (translation) and [3H]Gal (distal glycosylation) incorporation into newly synthesized hormone. In the present report, we have further examined the GnRH-induced [3H]Gal-LH synthesis and release by treating anterior pituitary cells with polypeptide synthesis and glycosylation inhibitors (cycloheximide and tunicamycin, respectively). Pituitary cells from ovariectomized adult rats were cultured for 4 days and then incubated for different periods (0-5 h) in medium containing [14C]Leu plus [3H]Man or [14C]Leu plus [3H]Gal in the absence (basal) or presence of 10 nmol/L GnRH with or without (control) cycloheximide (1.0 and 4.0 microg/mL) or tunicamycin (0.5 and 2.0 microg/mL). At the end of each incubation period, the cells and the medium were separated and processed for DNA uptake and newly synthesized LH (labeled LH, by immunoprecipitation with a-betaLH) determinations. The velocity of synthesis and release (between 0 and 2 h, and between 2 and 5 h) was calculated by regression analysis and the statistical significance of differences was determined by the slope test. GnRH enhanced the rates of synthesis and release of [14C]Leu-, [3H]Man-, and [3H]Gal-LH to 157 and 237; 164 and 190; and 272 and 508% of basal values, respectively. Cycloheximide totally blocked synthesis and release of [14C]Leu-LH and greatly reduced those of [3H]Man-LH, resulting in the loss of cellular responsiveness to GnRH. Addition of tunicamycin to the pituitary cells inhibited the rates of synthesis and release of [3H]Man-LH which had been induced by GnRH, without altering those of [14C]Leu-LH. These findings indicate that glycosylation is not a condition for GnRH-stimulated LH translation. The GnRH-increased [3H]Gal-LH rates of synthesis and release were affected to a lesser extent by the inhibitors. Thus, GnRH stimulation of distal glycosylation can occur, albeit at a reduced rate, even though protein synthesis and glycosylation are blocked. In conclusion, the present results corroborate that GnRH stimulates the addition of galactose residues into LH molecule. This effect is not simply the consequence of stimulating LH polypeptide chain synthesis. In addition, it is shown that GnRH-increased LH translation is independent of glycosylation.     

Accelerated poly(A) loss and mRNA stabilization are independent effects of protein synthesis inhibition on alpha-tubulin mRNA in Chlamydomonas.

In Chlamydomonas, the usual rapid degradation of tubulin mRNAs induced by flagellar amputation is prevented by inhibition of protein synthesis with cycloheximide. Evidence is presented that the ability of cycloheximide to stabilize alpha-tubulin mRNA depends on the time of addition. Addition of cycloheximide to cells before induction strongly stabilizes the induced mRNAs, while addition after their synthesis stabilizes them only transiently. Moreover, cycloheximide inhibition does not stabilize the same alpha-tubulin mRNA species in uninduced cells. These results suggest that cycloheximide is not acting to stabilize the induced alpha-tubulin mRNAs simply by preventing ribosome translocation. The stabilized state of tubulin mRNA was found to correlate with its occurrence on smaller polysomes but larger EDTA-released mRNP particles than the unstable state. A second effect of cycloheximide on the metabolism of induced tubulin mRNAs is to accelerate complete poly(A) removal. This effect of cycloheximide inhibition, unlike stabilization, occurs whenever cycloheximide is added to cells, and appears unrelated to stabilization. The effect is shown to be mRNA-specific; poly(A)-shortening on the rbcS2 mRNA is not altered in the presence of cycloheximide, nor do completely deadenylated molecules accumulate. Experiments in which cells were released from cycloheximide inhibition suggest that deadenylated alpha-tubulin mRNAs may be less stable than their polyadenylated counterparts during active translation.     

A possible role of autogenous IFN-beta for cytokine productions in human fibroblasts

It has been already known that human diploid fibroblasts are able to produce not only high levels of IFN-beta but also various kinds of cytokines by poly rI: poly rC, and some inflammatory cytokines are induced by IFN-beta gene activation. We also obtained similar results. However, in our system, cytokine productions were extremely enhanced by treating the cells with a low dose of type 1 IFN and the priming effects on cytokine productions were blocked by cycloheximide similar to those on IFN-beta productions. Most of cytokines were produced later than IFN-beta and synthesis patterns of their mRNA showed the same phenomena. We made clear that cytokine productions by poly rI: poly rC are mediated by secreted IFN-beta at a protein level using a monoclonal antibody against human IFN-beta. Further, it was shown that intra-cellular IFN-beta which is not secreted might also participate in cytokine productions. Meanwhile, IL-1beta induced various kinds of cytokines in human fibroblasts and production time courses of these cytokines were similar to those of poly rI: poly rC induced cytokines. Although secreted IFN-beta was not detected in IL-1beta stimulated culture, expression of IFN-beta mRNA was augmented. These results showed that priming effects of type 1 IFN on cytokine productions by poly rI: poly rC might not be the direct action, but successive IFN-beta production might be essential in the production processes of other cytokines. Further, it was suggested that inducible IFN-beta might also take part in IL-1beta-induced cytokine productions.     

Characterization of hCG regulation in cultured human amniotic fluid cells

Summary We showed previously that sodium butyrate stimulated human chorionic gonadotropin (hCG) measured by radioimmunoassay of medium from human second trimester amniotic fluid cell cultures, termed AF cells. We now find that stimulation of hCG in the presence of sodium butyrate takes as long as 20 h. When AF cells are preincubated with sodium butyrate, hCG levels increase in direct relation to length of the preincubation period. These findings suggest that elevation of hCG is not due merely to a release of hormone from the cells. Addition of cycloheximide or Actinomycin D inhibited protein synthesis and RNA synthesis, respectively, and prevented the stimulation of hCG by sodium butyrate. These results lend support for a mechanism of regulation involving protein and RNA synthesis, the increase in hCG levels being due to new synthesis of the hormone. Other agents reported to influence hCG production by different types of cell cultures include dibutyryl cyclic AMP, epidermal growth factor (EGF), methotrexate, and hydroxyurea. Dibutyryl cyclic AMP and EGF have no effect on hCG production in our AF cells: methotrexate causes a minimal increase, hydroxyurea causes a further increase, but sodium butyrate has the strongest stimulatory effect. We conclude that amniotic fluid cells in culture are susceptible to environmental agents capable of modulating synthesis of hCG by mechanisms involving synthesis of RNA and protein. Research supported by Grant HD 11379 from the National Institutes of Health.