Increased hyaluronic acid production on stimulation of DNA synthesis in chick embryo fibroblasts

Neutral sphingomyelinase 2 deficiency increases hyaluronan synthesis by up-regulation of Hyaluronan synthase 2 through decreased ceramide production and activation of Akt

Fibroblasts from the fro/fro mouse, with a deletion in the Smpd3 gene coding for the active site of neutral sphingomyelinase 2 (NSMase2), secreted increased amounts of hyaluronan (HA). This was reversed by transfection with the Smpd3 gene, suggesting a connection between sphingolipid and glycosaminoglycan metabolism. The deficiency of NSMase2 resulted in storage of sphingomyelin (SM) and cholesterol with a 50% reduction in ceramides (Cer). RT-PCR and Western blot analysis showed that increased HA secretion resulted from increased hyaluronan synthase 2 (HAS2) activity localized to sphingolipid-enriched lipid rafts. Although cholesterol levels were also elevated in lipid rafts from mouse fibroblasts deficient in lysosomal acid SMase activity (deletion of the Smpd1(-/-) gene), there was no increase in HA secretion. We then showed that in fro/fro fibroblasts, the reduced ceramide was associated with decreased phosphorylation of protein phosphatase 2A (PP2A) and increased phosphorylation of its substrate Akt-p, together with PI3K, PDK1, mTOR (mammalian target of rapamycin), and p70S6K, although PTEN was unaffected. Exogenous ceramide, as well as inhibitors of Akt (Akt inhibitor VIII), PI 3-kinase (LY294002 and wortmannin), and mTOR (rapamycin) reduced secretion of HA, whereas the NSMase2 inhibitor GW4869 increased HA synthesis and secretion. We propose that NSMase2/Cer are the key mediators of the regulation of HA synthesis, via microdomains and the Akt/mTOR pathway.

Impact of oestradiol and progesterone on the glycosaminoglycans and their depolymerizing enzymes of the rat mammary gland

The influence of oestradiol and progesterone either singly or in combination with each other on the levels of hyaluronic acid, heparan sulphate, chondroitin sulphate, and on the activity of hyaluronidase and chondroitinase were investigated in the mammary gland of ovary-intact and in ovariectomized rats, administered oestradiol and/or progesterone. Administration of oestradiol to ovary-intact rats elevated the levels of hyaluronic acid and decreased the levels of heparan sulphate while progesterone, when administered alone, could elevate only chondroitin sulphate when compared with controls. The steroids when administered in combination, however, increased the levels of all glycosaminoglycans studied. Ovariectomized animals showed a decrease in heparan sulphate alone as compared with controls while administration of oestradiol to these rats elevated the levels of both heparan sulphate and chondroitin sulphate as compared with ovariectomized rats. Also the administration of progesterone either singly or in combination increased the levels of heparan sulphate and also decreased the levels of hyaluronic acid with no impact on the levels of chondoritin sulphate. In ovary-intact animals administration of oestradiol alone had no effect on hyaluronidase activity. Progesterone either singly or in combination with oestradiol reduced the activity of hyaluronidase, whereas it had no influence on the activity of chondroitinase. The activities of both the enzymes were decreased in ovariectomized animals and administration of oestradiol and/or progesterone to the above groups resulted in an increase. This study demonstrates that oestradiol anzd progesterone play an important role in modulating glycosaminoglycans and their depolymerizing enzymes, thereby influencing the activities of the mammary epithelium.

Altered proteoglycan synthesis via the false acceptor pathway can be dissociated from beta-D-xyloside inhibition of proliferation

beta-D-Xylosides have been used to perturb proteoglycan (PG) synthesis to elucidate the function of PGs in a number of cellular processes, including proliferation, migration, and differentiation. This study was designed to examine whether specific xylosides affect the proliferation of several different cell types and, if so, whether this effect is dependent on altered PG synthesis via the false acceptor pathway. Both methylumbelliferyl beta-D-xylopyranoside and p-nitrophenyl beta-D-xylopyranoside (PNP beta-xyloside) inhibit cell proliferation and modulate PG synthesis; however, the alpha form of PNP xyloside which does not perturb PG synthesis inhibits the proliferation of cultured cells on a molar basis equally as well as the beta form. Conversely, beta-methyl xylopyranoside stimulates the synthesis of free glycosaminoglycan chains equally as well as PNP beta-xyloside and yet has no measurable effect on cell proliferation at comparable doses, indicating that cells can grow normally while experiencing disruption of their proteoglycan metabolism. At doses ranging from 0.5 to 5 mM, PNP beta-xyloside arrests cells in the G1 phase of the cell cycle at the same time point as serum starvation. It also delays the exist of cycling cells from the S phase. This treatment is not cytotoxic and is rapidly reversed by the replacement of PNP beta-xyloside containing medium with control medium. Dimethyl sulfoxide, the most commonly used solvent for beta-xyloside in proteoglycan studies, potentiates the inhibitory effect of PNP beta-xyloside on cell proliferation. These results indicate that the perturbation of PG synthesis via the false acceptor pathway can be uncoupled from control of cell proliferation.

Correlation of hyaluronic acid accumulation and the growth of preneoplastic mammary cells in collagen: a longitudinal study

Hyaluronic acid accumulation is characteristic of mammary tumor cells, and the amount that accumulates seems to correlate with the degree of malignancy of the producing cells. We have tested directly the relationship between hyaluronic acid accumulation and the replication rate of preneoplastic mammary cells in culture. We used nontumorigenic but immortal CL-S1 mouse mammary cells that were derived from a hyperplastic alveolar nodule. Using a collagen gel culture system, we found clear differences in the growth properties of cells before and after Passages 68 to 70. Late passage cells replicated earlier and faster than early passage cells in collagen and on plastic. The rate of cycling resembled that of tumorigenic mouse mammary cells during the first week of culture. Cells seeded at low densities cycled faster than those seeded at high densities during the second week in culture. Exogenous hyaluronic acid, at 10 to 1000 micrograms/ml, neither enhanced nor inhibited CL-S1 cell growth significantly in collagen, regardless of passage. However, by the third day in collagen, late passage cells produced 7 times more total glycosaminoglycans and 12 times more hyaluronic acid per cell than did early passage cells. Late passage cells also deposited 12 times more labeled hyaluronic acid in the matrix than did early passage cells, on a per-cell basis. After a decline in the deposition of hyaluronic acid in the extracellular matrix, growth ceased. The late passage cells did not grow in soft agar, indicating that they had not become neoplastic spontaneously during passage. However, their accelerated growth rate, coupled with the synthesis and secretion of large amounts of hyaluronic acid into the extracellular matrix, may characterize a distinct step in tumor progression in preneoplastic CL-S1 cells.

Growth-related production of proteoglycans and hyaluronic acid in synchronous arterial smooth muscle cells

1. The growth-stimulating effect of serum on the proteoglycan and hyaluronic acid production in arterial smooth muscle cells was investigated, using cells synchronized by serum deprivation. 2. After stimulation, synthesis of [35S]sulfated proteoglycans and [14C]hyaluronic acid increased during G1 and G2 phases (about 2- and 5-fold, respectively, in the culture medium), in comparison with quiescent cells. 3. Neither the size, nor the charge, nor the relative proportions of [35S]glycosaminoglycans of the proteoglycans were modified. 4. However, when the cells were stimulated to divide, increased synthesis of large [14C]hyaluronic acid was observed concomitantly with the production of higher hydrodynamic size [35S]proteoglycans, which aggregated with hyaluronic acid (20%).

Levels of [3H]glucosamine incorporation into hyaluronic acid by fibroblasts is modulated by culture conditions

Tissue culture conditions can modulate apparent levels of incorporation of the radiolabeled precursor [3H]glucosamine into hyaluronic acid in cells. A careful study was made on the effects of culture conditions on human skin fibroblasts. A newly described technique to measure hyaluronic acid was utilized based on incorporation of [3H]glucosamine into cetylpyridinium chloride-precipitable hyaluronidase-digestible material. The precipitate was collected on glass fiber filters using a manifold suction apparatus. A six-fold greater level of incorporation occurred in rapidly growing preconfluent than in confluent fibroblasts. Ascorbic acid stimulated incorporation with a maximum at 25 micrograms/ml. The same ascorbic acid optimum was observed for collagen prolylhydroxylation. When beta-hydroxybutyrate was used as an energy source instead of D-glucose, a 3.5-fold increase in levels was observed. All tissue-culture media examined supported comparable levels of incorporation, except for Roswell Park Memorial Institute Media-1640, in which cells had only half the level. Fetal calf serum supported high levels of incorporation in a dose-dependent manner, while newborn calf and calf sera supported much lower levels of incorporation. Under serum-free conditions, lactalbumin hydrolysate was best able to support incorporation of hyaluronic acid. In the search for mechanisms that modulate hyaluronic acid, it is critical to consider the tissue culture conditions under which incorporation of radiolabeled precursors are being examined.

Hyaluronate accumulation and nerve-dependent growth during regeneration of larval Ambystoma limbs

Hyaluronate-mediated expansion of the extracellular matrix has been suggested as an important element of growth and morphogenesis in several developing systems. In vitro, various growth factors have been shown to stimulate hyaluronate synthesis as well as cell proliferation. A similar link between proliferation and hyaluronate production during in vivo growth is difficult to demonstrate, because in most systems the source of growth-promoting factors is either not known or not amenable to experimental manipulation. During amphibian limb regeneration, cell proliferation depends upon paracrine release of factors from axons in the limb stump, and the nerve supply can be eliminated or augmented experimentally for study of growth in this system. Denervated and amputated limbs of larval salamanders do not begin to regenerate until distal areas of the limb stumps are reinnervated. We have used such limbs to examine the effect exerted by the reappearance of nerves on the amount of hyaluronate in the tissue undergoing the growth response. Hyaluronate was demonstrated by the metachromatic dye Ethyl Stains-all, which stains hyaluronate blue while sulfated glycosaminoglycans (GAGs) and proteins in the extracellular matrix stain various shades of violet, and by microspectrophotometry of alcian-blue-stained GAGs in serial sections pretreated with buffer or with Streptomyces hyaluronidase (SH) to remove hyaluronate specifically. Both methods showed little hyaluronate in the distal region of limb stumps prior to reinnervation, while reinnervated stumps had amounts of hyaluronate similar to those of control blastemas. Autoradiography of 3H-glucosamine-labeled limbs indicated that hyaluronate in the blastemas of reinnervated limb stumps included material newly synthesized by cells throughout the growing tissue.(ABSTRACT TRUNCATED AT 250 WORDS)

Hyaluronate inhibition of cell proliferation

The proliferation of rabbit synovial cells, 3T3 cells, or simian virus-transformed 3T3 cells in cell culture was inhibited by the addition of hyaluronate to the culture medium. This effect was markedly dependent on the molecular weight and concentration of the hyaluronate. At the molecular weight and concentration of hyaluronate present in normal synovial fluid, proliferation was inhibited. At lower molecular weights or concentrations, as found in rheumatoid synovial fluid, hyaluronate was significantly less inhibitory. Thus, the changes in synovial fluid hyaluronate that are associated with arthropathies may contribute to a favorable environment for rheumatoid pannus expansion.

Changes in the extracellular matrix and glycosaminoglycan synthesis during the initiation of regeneration in adult newt forelimbs

The extracellular matrix (ECM) of the distal tissues in a newt limb stump is completely reorganized in the 2-3-week period following amputation. In view of numerous in vitro studies showing that extracellular material influences cellular migration and proliferation, it is likely that the changes in the limb's ECM are important activities in the process leading to regeneration of such limbs. Using biochemical, autoradiographic, and histochemical techniques we studied temporal and spatial differences in the synthesis of glycosaminoglycans (GAGs) during the early, nerve-dependent phase of limb regeneration. Hyaluronic acid synthesis began with the onset of tissue dedifferentiation, became maximal within 1 weeks, and continued throughout the period of active cell proliferation. Chondroitin sulfate synthesis began somewhat later, increased steadily, and reached very high levels during chondrogenesis. During the first 10 days after amputation, distributions of sulfated and nonsulfated GAGs were both uniform throughout dedifferentiating tissues, except for a heavier localization near the bone. Since nerves are necessary to promote the regenerative process, we examined the neural influence on synthesis and accumulation of extracellular GAGs. Denervation decreased GAG production in all parts of the limb stump by approximately 50%. Newt dorsal root ganglia and brain-derived fibroblast growth factor each produced twofold stimulation of GAG synthesis in cultured 7-day regenerates. The latter effect was primarily on synthesis of hyaluronic acid. The results indicate that the trophic action of nerves on amphibian limb regeneration includes a positive influence on synthesis and extracellular accumulation of GAGs. Since the ECM exerts a major influence on cellular proliferation and migration, the effect of nerves on GAG metabolism may have considerable importance for growth and development of the early regenerate.

Cutaneous tissue repair: basic biologic considerations. I

Wound repair of the integument is reviewed in the context of new developments in cell biology and biochemistry. Injury of the skin and concomitant blood vessel disruption lead to extravasation of blood constituents, followed by platelet aggregation and blood clotting. These events initiate inflammation and set the stage for repair processes. The macrophage plays a pivotal role in the transition between wound inflammation and repair (granulation tissue formation), since this cell both scavenges tissue debris and releases a plethora of biologically active substances that include growth factors. Although concrete evidence is lacking, growth factors are probably at least partially responsible for the angiogenesis and fibroplasia (granulation tissue) that gradually fill the wound void. If the epidermal barrier is disrupted during injury, reepithelialization begins within 24 hours and proceeds first over the margin of residual dermis and subsequently over granulation tissue. The signals for angiogenesis, fibroplasia, neomatrix formation, and reepithelialization in wound repair are not known, but a number of possibilities are discussed. Matrix remodeling is the last stage of wound repair and gradually increases the scar tensile strength to 70% to 80% of normal skin.

Growth stimulatory precipitates of Ca2+ and pyrophosphate

Inorganic pyrophosphate (PPi) forms an insoluble precipitate with calcium in growth medium when its concentration exceeds about 0.1 mM. This PPi precipitate can reproduce the effects of 10% calf serum on all cell processes examined in Balb/c 3T3 cells, including hexose uptake and metabolism to lactate, 3H-uridine, and 3H-choline uptake, and the incorporation of 3H-leucine and 3H-thymidine into trichloroacetic acid (TCA)-insoluble material. Concentrations of PPi insufficient to form a precipitate are without effect on cell metabolism. The precipitates are most effective when prepared with concentrations of PPi just sufficient to result in precipitate formation and become considerably less effective as the PPi concentration increases, even though the quantity of precipitate formed continues to increase with PPi concentration up to 1 mM PPi. Precipitates formed at low PPi concentrations consist largely of Ca2+ (81% of cations), PPi (77% of anions), and Pi (23% of anions). Precipitates formed with higher concentrations of PPi contain proportionately less Ca2+ and Pi and more monovalent cations and PPi. We have distinguished cell surface-bound PPi from intracellular PPi by differential extraction. The quantity of surface-bound PPi increases sharply when the PPi concentration reaches the point of precipitate formation. If the precipitate is prevented from binding to the cell surface by inverting monolayer cultures in precipitate-containing medium, the cells are not stimulated. These findings suggest that the binding of PPi precipitate to the cell surface is involved in the stimulation of cell metabolism by PPi. PPi precipitates do not absorb serum mitogens or inhibitors from the culture medium, nor do they affect the binding of 125I-platelet-derived growth factor to its specific cell-surface receptor, suggesting that PPi precipitates do not act directly through either of these mitogen-receptor systems. In analogy to cell stimulation by epidermal growth factor and by antigens, we suggest that PPi may be active only in the form of a precipitate because multivalent binding of receptors with formation of clusters is required for stimulation. The inhibitory effects of high concentrations of PPi may be due to interference by free PPi with formation of active receptor clusters.

Fibronectin--mediator between cells and connective tissue

Fibronectin, previously also termed LETS-protein, is a high-molecular-weight protein (mol. w. ca. 450,000) present in the form of thin fibrils in the pericellular space of fibroblasts and other adherent cells, as well as in distinct areas of the connective tissue. A soluble form, immunologically identical and chemically at least very similar to the cell-attached protein, is found in plasma in a concentration of about 300 micrograms/ml. It is also denominated cold-insoluble globulin. The protein has affinity both to cell surfaces and to various matrix substances such as fibrin and collagen and, therefore, is capable of mediating cell attachment to these substrates. In addition, it serves as an opsonin for the phagocytosis of gelatin-containing compounds and probably is essential for the removal of soluble fibrin from the circulating blood by the reticulo-endothelial system. Bacterial cell walls are also recognized by fibronectin. A conversion of soluble fibronectin to fibrils is achieved by heparin which also enhances the binding of soluble fibronectin to cells. Heparin or, as suggested, the related heparan sulfate present on the surface of various cells, appears to function as a cofactor in the formation of pericellular fibrils. The fibronectin fibrils precipitated with heparin, compared to soluble fibronectin, show a considerably improved affinity to native collagen, especially to type III. Hyaluronic acid has an antagonistic function which, at higher concentrations, prevents the fibronectin fibrils from interacting with collagen and cell surfaces. Masking of fibronectin fibrils was also achieved by sulfated proteoglycans of cartilage. Virus-transformed fibroblasts produce less fibronectin and are less capable of maintaining surface pericellular fibrils. A reasonable explanation is that they have an elevated secretion of hyaluronic acid. The transformed cells attach only weakly to a surface and exhibit a rounded shape in contrast to healthy ones. This phenotype can be corrected to a great extent with fibronectin. It is suggested that fibronectin also influences the formation of connective tissue by accumulating collagen precursors on the surface of fibroblasts and facilitating fibrillogenesis.

Incorporation of [3H]glucosamine into glycosaminoglycans in different cell culture conditions by rabbit aortic smooth muscle cells

This study sought to elucidate the optimal cell culture conditions for studies concerned with the incorporation of [3H]glucosamine into glycosaminoglycans by rabbit aortic smooth muscle cells. The incorporation of radioactivity into extracellular sulphated glycosaminoglycans was linear for at least 72 h and that into pericellular sulphated glycosaminoglycans for up to 24 h. The incorporation of radiolabel into hyaluronic acid was linear only up to 12 h. In the exponential growth phase the incorporation of [3H]glucosamine into sulphated glycosaminoglycans and hyaluronic acid proved to be less marked than in the stationary growth phase, but the highest values were nevertheless obtained immediately after trypsinisation. When studied in the stationary growth phase, cell density and incorporation of [3H]glucosamine were positively correlated in the case of hyaluronic acid, but in the case of sulphated glycosaminoglycans there was a negative correlation. The serum concentration of the incubation medium and the incorporation of radioactivity into hyaluronic acid were positively related. With sulphated glycosaminoglycans this was the case only after a 7-day preincubation in the different serum concentrations. When incorporation was studied without preincubation, the incorporation of radioactivity into sulphated glycosaminoglycans proved to be negatively associated with the serum concentration of the medium. The environmental pH of the cells was associated with the incorporation of radioactivity into hyaluronic acid and sulphated glycosaminoglycans in that between pH values 6.8 and 7.9 the incorporation of radioactivity increased when the pH of the medium was raised.

Age-related changes in the distribution pattern of glycosaminoglycans synthesized by cultured human diploid fibroblasts (WI-38)

A gradual decline in the synthesis of glycosaminoglycans, as evidenced by reduced rates of incorporation of [35S] sulfate and [14C] glucosamine into cellular and medium glycosaminoglycans, was observed during the last (about 5) population doublings before phase-out. The decline was accompanied by a change in the distribution pattern of individual glycosaminoglycans with a relative decrease in the incorporation rate of [14C] glucosamine into cellular and medium hyaluronic acid. The incorporation rate of [14D] glucosamine and [35S] sulfate into cellular and medium heparan sulfate continually increased during the last population doublings ("senescence"). The possibility of a coupling between cell growth and hyaluronic acid synthesis or an involvement of hyaluronic acid in the adhesion of cells (among one another or/and to the substratum), and the functional significance of heparan sulfate as a growth inhibitor were discussed.

Cell cycle dependent rate of labelling of cellular and secreted glycosaminoglycans in mouse embryonic fibroblasts

Cultures of embryonic fibroblasts from Balb/c or CBA/J mice were given 12-h pulses of 14C-galactose, or were double-labelled with 3H-galactose and 35H-sulfate. The time course of the rates of labelling of glycosaminoglycans--galactose label was found in the uronic acid moiety--was studied in synchronously and asynchronously growing cultures. Partial synchrony was achieved by trypsinising quiescent, confluent cells and subsequent transfer of cells to new cultures with fresh medium. Synchrony was monitored by measurement of thymidine uptake in parallel cultures. The distribution of label in the hyaluronic acid, chondroitin sulfate, and heparan sulfate fractions from cells and culture media was determined at each time point. Peaks of DNA synthesis were accompanied by or followed 12 h later by a maximal rate of labelling with galactose of secreted glycosaminoglycans, and with the exception of hyaluronic acid--also of cellular glycosaminoglycans. The rate of labelling with galactose of glycosphingolipids in parallel cultures followed a different time course. In double-label experiments the rates of labelling of glycosaminoglycan sulfates with 3H-galactose and 35S-sulfate did not go parallel. In older, quiescent cultures the labelling rate with galactose decreased while the sulfation rate increased. It is discussed that the labelling rate with galactose is indicative of the biosynthetic rate of the glycosaminoglycans. The conclusion is reached that glycosaminoglycans are preferentially synthesized and secreted after the S phase of the cell cycle.

The cell substratum modulates skeletal muscle differentiation

During chick embryogenesis, massive alterations occur in the migrating cell's substratum, or extracellular matrix. The possibility that some of the components of this milieu play a regulatory role in cell differentiation was explored in a cell-culture system derived from embryonic chick skeletal muscle tissue. In particular, the effects of collagen and the glycosaminoglycans were studied. Collagen is required for muscle cell attachment and spreading onto plastic and glass tissue-culture dishes. A major constituent of the early embryonic extracellular space, hyaluronate (HA), while having no significant effect on collagen-stimulated cell attachment and spreading, was found to inhibit myogenesis. The muscle-specific M subunit of creatine kinase was preferentially inhibited. Control experiments indicated that the inhibition was specifically caused by HA and not by other glycosaminoglycans. A general metabolic inhibition of the cultures was not observed. Muscle cells could bind to HA-coated beads at all stages of differentiation but were inhibited only when HA was added within the first 24 h of culture. Endogenous GAG in the culture is normally degraded during the first 24 h after plating as well; this may parallel the massive degradation of HA that occurs in the early embryo in vivo. These findings suggest a regulatory role for HA in modulating skeletal muscle differentiation, with degradation of an inhibitory component of the cell substratum a requirement for myogenesis.

Effects of depletion of K+, Na+, or Ca2+ on DNA synthesis and cell cation content in chick embryo fibroblasts

Decreasing the K+ concentration of the medium from 5 mM to 0.59 mM decreased the K+ content of chick embryo fibroblasts to 22% of control values and increased the Na+ content to 820% of control values. The alteration of monovalent cation content occurred within two hours but had no effect on the rate of DNA synthesis, as measured by 3H-thymidine incorporation, for at least 16 hours. By decreasing the Na+ concentration in the medium, a 50% reduction in cellular Na+ could be obtained with no effect on thymidine incorporation. Since these changes in cellular Na+ or K+ are much larger than any known to occur under physiological conditions but have no effect on thymidine incorporation, we conclude that Na+ and K+ do not play a critical role in determining multiplication rate. Addition of 1.8 mEGTA to cells in media containing 1.7 mM Ca2+ and 0.8 mM Mg2+ inhibited thymidine incorporation and sharply decreased cellular K+ and increased cellular Na+ content. However, there was no reduction in total cellular Ca2+ levels. Likewise, decreasing the Ca2+ concentration of the medium below 0.01 mM inhibited thymidine incorporation, decreased cellular K+ and Mg2+, and increased cellular Na+ but did not affect total cellular Ca2+ levels. Inhibition of DNA synthesis, therefore, could not be correlated with changes in cellular Ca2+ levels.

Age-related decline in the synthesis of glycosaminoglycans by cultured human fibroblasts (WI-38)

A gradual decline in the synthesis of glycosaminoglycans, as evidenced by reduced rates of incorporation of [35S]-sulfate and [14C]-glucosamine into total cellular and extracellular glycosaminoglycans, occurred during the last 4 to 5 passages (1 : 2 splits) of WI-38 cultures before phase out. While labelling of cellular glycosaminoglycans by both radioactive precursors was reduced to about the same extent, a relatively greater decline in [35S]-sulfate than in [14C]-glucosamine incorporation into extracellular glycosaminoglycans was observed during the last passages. These changes in glycosaminoglycan metabolism are interpreted as an expression of cellular aging and a function of glycosaminoglycans in growth regulation (and possibly in the process of cellular senescence) is discussed.

Stimulatory effect of prostaglandins on the production of hexosamine-containing substances by cultured fibroblasts (4) adenosine 3':5'-cyclic monophosphate independent stimulation by prostaglandin F2alpha

The mechanism of the stimulatory effect of prostaglandin PG) F2alpha on the production of hexosamine-containing substances by cultured fibroblasts was studied with special reference to adenosine 3':5'-cyclic monophosphate (cAMP). At the stationary phase, the cells were exposed for 6 hrs to PGF2alpha, E1, cAMP or dibutyryl-cAMP in a wide range of concentrations. cAMP itself showed a slight stimulation on the production of hexosamine-containing substances, and the effect was enhanced by using the dibutyryl derivative. PGF2alpha had much a greater capacity than either the exogeneous cAMP or the dibutyryl-cAMP for enhancing the production of hexosamine-containing substances. To know whether cAMP is involved in the stimulatory effect of PGF2alpha, intracellular cAMP level was concomitantly measured in both PGF2alpha and PGE1 treated cultures. Although the cellular cAMP level in PGE1 treated cultures was much higher than that in the PGF2alpha treated cultures, the stimulatory effect on the production of hexosamine-containing substances in PGE1 treated cultures was always much smaller than that in the PGF2alpha treated cultures. Moreover, PGF2alpha had a significant stimulatory effect on the production of hexosamine-containing substances even at a low concentration as 100 pg/ml, which is small enough not to increase any cellular cAMP level. From these results, it was concluded that the stimulatory effect of PGF2alpha on the production of hexosamine-containing substances by cultured fibroblasts is not mediated by cAMP and is caused by a mechanism different from that caused by cAMP.

Reversible regulation by magnesium of chick embryo fibroblast proliferation

The rate of 3H-thymidine incorporation and of cell proliferation in chick embryo fibroblast cultures are reduced coordinately when the [Mg2+] of the external medium is reduced below the physiological concentration of about 0.8 mM. These effects of moderately reduced [Mg2+] and the accompanying change in appearance of the cells, resemble the effects produced by lowering the [serum] of the medium. Cells subjected to severe Mg2+ deprivation, especially at low [Ca2+], die and detach from the culture dish. Cells kept at a reduced rate of proliferation for three days by moderate Mg2+ deprivation are quickly restored to rapid proliferation upon restoration of the normal [Mg2+] of the medium. The rate of proliferation of the chick embryo cells is reduced markedly by lowering [Ca2+] about 100-fold, but unlike the case of Mg2+-deprivation this can occur without significant effect on the rate of 3H-thymidine incorporation. More severe Ca2+ deprivation, which does lower the rate of 3H-thymidine incorporation, produces retraction of cells from one another and from the dish, and results in a distinctly abnormal, rounded appearance. The results lend weight to the thesis that free [Mg2+] plays a central role within the cell in the coordinate control of metabolism and growth. They also suggest that the effects produced by varying [Ca2+] in the medium are caused by changes at the external surface of the cell.

Coordinate control of collagen synthesis and cell growth in chick embryo fibroblasts and the effect of viral transformation on collagen synthesis

Using collagenase digestion as an assay for collagen in partially synchronized secondary cultures of chick embryo fibroblasts, we find that the rate of collagen synthesis remains at a constant fraction of overall protein synthesis (5%) regardless of the growth rate of the cells even when the rate of protein synthesis is accelerated 5-fold by adding serum and altering the pH of the culture medium. However, in cells oncogenically transformed by Rous sarcoma virus, the relative rate of collagen synthesis was decreased by 50% 24 hours after infection and was 10% of the initial rate after 5 days. This selective decrease in rate of collagen synthesis could be reversed in cells infected with an RSV temperature-sensitive transformation-defective mutant at the non-permissive temperature, indicating that the decrease in the rate of collagen synthesis was not merely the result of viral infection but was a direct consequence of oncogenic transformation.

The effect of centrifugal force on glycosaminoglycan production by aortic smooth muscle cells in culture

Cultured smooth muscle cells from pig aorta subjected to centrifugation (48 h at 45 g over a 72-h period) increased their production of glycosaminoglycans by approximately 50%. The sulphated components, heparan sulphate, dermatan sulphate and chondroitin sulphate, showed a relatively greater increase than hyaluronic acid (66-34%). The results are consistent with the hypothesis that mechanical stress, such as hypertension, leads to increased accumulation of glycosaminoglycans in the aortic wall and that secondary trapping of lipoproteins by sulphated glycosaminoglycans produces atherosclerotic plaques.

Hormonal control of hyaluronic acid production in fibroblasts and its relation to nucleic acid and protein synthesis

Whole serum and elevated pH previously had been found to stimulate both cell multiplication and hyaluronic acid production by chick embryo fibroblasts in culture. In a study to determine whether cell multiplication and hyaluronic acid production both respond to a single well-defined substance, insulin was found to stimulate, and cortisol to inhibit both processes coordinately. It appears, therefore, that multiplication and differentiated function in fibroblasts respond to a common underlying regulatory signal. Inhibition of ribosomal RNA synthesis by actinomycin D does not prevent serum stimulation of hyaluronic acid production, but inhibition of total RNA synthesis does. If total RNA synthesis is inhibited only after the hyaluronic acid production has reached a new high level, it continues at that level for the next five hours. The stimulatory treatment causes an increase in the activity of the enzyme hyaluronate synthetase. Inhibition of protein synthesis prevents any increase in hyaluronic acid production, and reduces the basal level of production. Reduction of the availability of Mg2+ in the medium coordinately inhibits DNA synthesis and hyaluronic acid production. The results are discussed in the light of a model for coordinate control growth and metabolism based on the availability of Mg2+.

Enhanced synthesis and extracellular accumulation of hyaluronic acid during stimulation of quiescent human fibroblasts by mouse epidermal growth factor

The effect of mouse epidermal growth factor (mEGF) on the synthesis of glycosaminoglycans and glycoproteins by human fibroblasts has been studied. The addition of physiological concentrations (10(-9)M) of mEGF to quiescent cultures preincubated in the absence of serum was found to elicit an increased incorporation of 3H-glucosamine into the glycosaminoglycans and glycoproteins of both the cellular and extracellular fractions. Although the growth response to the factor, as measured by DNA replication, was minimal under these conditions as compared with the effect of serum, the mEGF-induced incorporation of glucosamine into these cellular constituents and into the extracellular glycoproteins was comparable to that elicited by serum shift-up. Serum, however, caused a significantly larger incorporation of glucoasimine into extracellular, acid-soluble glycosaminoglycans, which were shown to contain hyaluronic acid as the major component. As previously demonstrated, the growth response to mEGF can be enhanced several fold by an mEGF-binding arginine esterase, which is normally associated with the factor in vivo, and by ascorbate. The esterase was found to increase markedly the mEGF-induced incorporation of glucosamine into extracellular hyaluronic acid, while the addition of ascorbic acid did not significantly alter glucosamine incorporation.

Mutual potentiation by magnesium and calcium of growth in animal cells

The effects on DNA synthesis of various combinations of Mg2+ and Ca2+ in cultures of chick embryo cells have been studied. When [Mg2+] larger than or equal to 0.24 mM, reduction of Ca2+ from the standard concentration of 1.72 mM to 0.01 mM had no effect on the incorporation of [3H]thymidine ([3H]dThd) into DNA over a 16-hr period. When Mg2+ was reduced to 0.04 mM, [3H]dThd incorporation into DNA decreased directly with [Ca2+] below 1.72 mM and increased slightly up to [Ca2+] = 5.02 mM, where cell damage began to occur. The change in [Ca2+] necessary to maintain a half-maximal rate of [3H]dThd incorporation was found to depend inversely on the fourth power of the change in [Mg2+]. Chelation of Ca2+ with approximately equimolar ethylene glycol-bis(beta-aminoethyl ether)-N,N'-tetraacetic acid (EGTA) in the presence of [Mg2+] larger than or equal to 0.24 mM reduced [3H]dThd incorporation about 10-fold, and large excesses of EGTA did not further reduce it. The amount of EGTA required to produce a detectable inhibition of [3H]dThd incorporation was independent of [Mg2+] larger than or equal to 0.24 mM, as was the level of residual incorporation in excess EGTA. When [Mg2+] was reduced to 0.04 mM, however, [3H]dThd incorporation declined even when [EGTA] less than [Ca2+], and vanished when EGTA was in large excess. The results are discussed within the framework of a model for the regulation of cell metabolism and growth in which the availability of free Mg2+ is the central coordinating factor. The metabolic effects of Mg2+ depend on its distribution between elements such as ATP and binding sites on membranes. We propose that the major metabolic effects of varying [Ca2+] are produced indirectly through its competition with Mg2+ for membrane sites, thereby making more or less Mg2+ available for rate-limiting transphosphorylation reactions.

Fibroblast DNA synthesis activation in sponge induced granulation tissue. The effect of antineutrophil serum and cyclophosphamide

DNA synthesis in rat and rabbit polyvinyl sponge induced granulation tissue has been studied using thymidine (methyl-3H). Synthesis was determined by measurement of thymidine incorporation into cold trichloroacetic acid insoluble material and by autoradiography. Granulation tissue was removed and immediately incubated in vitro in the presence of thymidine (methyl-3H) for three hours. The label was incorporated into the nuclei of fibroblasts and, to a lesser extent, of endothelial cells. The labeled material was 93% lysable by DNase and its synthesis was inhibited by hydroxyurea and bleomycin. In this system synthesis was linear for two hours and then ceased. A marked increase in DNA synthesis occurred in tissue harvested at 44 hours after sponge implantation. This rise was confirmed by autoradiographic studies which showed an increase in nuclear labeling at two days after implantation. Neutropenia produced by injections of antineutrophil serum or cyclophosphamide failed to inhibit activation of DNA synthesis in fibroblasts or endothelial cells. Amonocytosis also had no effect on this process. Rates of thymidine incorporation into DNA and thymidine phosphates in vivo were similar to those found during in vitro incubations of granulation tissue.

Stimulation of lactic acid production in chick embryo fibroblasts by serum and high pH in the absence of external glucose

Lactic acid production by chick embryo fibroblasts occurs in the absence of exogenous glucose. Fifteen to 50-fold less lactic acid is formed in the absence of glucose than in its presence. Nevertheless, serum and pH stimulation enhances this residual lactic acid production to the same relative extent as when glucose is present. The amount of lactic acid formed cannot be accounted for by the catabolism of residual glucose in the medium since its concentration is less than one-tenth that of the lactic acid eventually produced. Moreover, the residual glucose concentration remains constant or increases during the course of the experiment. To a large extent lactic acid accumulation in the absence of external glucose is dependent on the presence of amino acids in the medium, but amino acid transport is not affected by the stimulatory agents used in this study. The results suggest that treatments which stimulate cell multiplication also activate those enzymatic pathways which convert amino acids to pyruvic and thence to lactic acid.

Nonspecific nature of the stimulus to DNA synthesis in cultures of chick embryo cells

The rate of DNA synthesis in chick embryo cultures deprived of serum is stimulated 5- to 20-fold by a large variety of substances, including subtoxic concentrations of certain metal ions such as Zn++, Cd++, and Hg++. The stimulatory concentrations of Zn++ and Cd++ have sharp optima, which are just below the concentrations that produce frank morphological damage in each case. A much wider gap exists between stimulatory and morphologically damaging concentrations of Hg++. These metal ions also stimulate RNA synthesis, and the uptake of 2-deoxy-D-glucose. The stimulatory effects of Zn++, but not those of Hg++, are prevented by treatment with EDTA. Although medium from cultures stimulated by Zn++ or Hg++ retains its stimulatory capacity for a new set of cultures, the capacity in the case of Zn++-treated cultures is almost entirely lost upon addition of EDTA. It is also lost upon dialysis of conditioned medium from cultures treated with either Zn++ or Hg++. It is concluded that the stimulatory effect is the direct result of interaction between metal ions and cells, and not to the release of growth-stimulatory materials from the cells. The stimulation is thus seen as a non-specific event resulting in an integrated, metabolic response by the cells.