Lipid requirement for cell cycling. The effect of selective inhibition of lipid synthesis

The importance of serum lipoproteins in the cytolytic action of 7 beta-hydroxycholesterol on cultured hepatoma cells

The toxicity of 7 beta-hydroxycholesterol for cultured HTC cells is 10 times greater if serum lipids and lipoproteins are absent from the culture medium. A water-soluble derivative of 7 beta-hydroxycholesterol, sodium 3,7-bishemisuccinate, showed the same toxicity as the original molecule and was also 8 times more toxic when serum lipids and lipoproteins were absent. But the rapid inhibition of DNA synthesis was similar in cells treated with both compounds, whether lipids and lipoproteins are present or not. Thus the absence of serum lipids and lipoproteins enhances the lytic effect of both substances but does not increase their intracellular action on DNA synthesis. This first parallel study on lipophilic 7 beta-hydroxycholesterol and its water-soluble homologue shows the importance of the serum lipids and lipoproteins in the cytotoxicity of such sterols.

The coordination of sterol and phospholipid synthesis in cultured myogenic cells. Effect of cholesterol synthesis inhibition on the synthesis of phosphatidylcholine

The coordination of biosynthesis of cholesterol and phosphatidylcholine has been investigated in a myoblast cell line L6, grown in lipid-depleted medium. The addition of 25-hydroxycholesterol or compactin to this medium inhibits cholesterol synthesis by over 95%. The rate of [3H]choline incorporation into phosphatidylcholine begins to decline after 6 h and eventually falls to 45% of control. Measurements of choline flux through the CDPcholine pathway and of the pool sizes of choline-containing intermediates indicate that the formation of CDPcholine is the rate-limiting step in phosphatidylcholine synthesis in L6. The rate of CDPcholine synthesis was measured in vivo by pulse-chase experiments. Culturing cells with 25-hydroxycholesterol or compactin results in an inhibition of this step, which parallels the inhibition of incorporation of [3H]choline into phosphatidylcholine. The specific activities of the enzymes of phosphatidylcholine synthesis were assayed under optimal substrate conditions. Growth in the presence of sterol-synthesis inhibitors for 24 h has a significant, but variable, effect on the activity of microsomal and cytosolic cholinephosphate cytidylytransferase. Inhibition is seen in approximately one-half of the preparations and ranges up to 60%. The degree of inhibition of the enzyme in vitro correlates with an elevation of cytosolic triacylglycerol and phospholipid levels, and is not eliminated by the inclusion of excess stimulatory phospholipids in the assay. The pool sizes of the substrates, cholinephosphate and CTP, are unaffected by cholesterol synthesis inhibition. In contrast to the effects on cholinephosphate cytidylytransferase, the microsomal enzymes glycerol-3-phosphate acyltransferase and choline phosphotransferase are stimulated 2-fold or more. Choline kinase specific activity was inhibited 2-fold after 24 h of treatment with 25-hydroxycholesterol; however, no effect on this step was observed in vivo. These results indicate that the coordination of cholesterol and phosphatidylcholine synthesis involves regulation at the cytidylytransferase-catalyzed step.

Growth stimulation of rous sarcoma virus-transformed BHK cells by biotin and serum lipids

Biotin or a serum lipid extract stimulated proliferation of G1 arrested Rous sarcoma virus-transformed BHK cells in modified Eagle's MEM (BM). The cells could be maintained continuously in BM plus biotin (BMB), but not in BM plus serum lipid extract (BM X L). Avidin inhibited growth stimulation when added to BMB, but did not inhibit growth when added to BM X L. 14C-acetate incorporation into total cellular lipids was stimulated in BMB, but not in BM. Thin-layer chromatography of the labeled cellular lipid extract indicated that relatively large amounts of 14C-acetate were incorporated into phosphatidylserine and little into the other major phospholipids. In the neutral lipids, the largest amount of incorporation was in cholesterol. G1 arrested cells multiplied rapidly in BM supplemented with dialyzed serum (BM X DS), but they did not multiply in BM with delipidized serum (BM X DLS). The addition of biotin or serum lipid extract to BM X DLS stimulated growth. Growth stimulation in BM X DLS by biotin was inhibited by avidin, but avidin had no effect on growth stimulation by serum lipid extract. Biotin stimulated additional multiplication in BM X DS and avidin inhibited this additional growth stimulation. These results suggest that growth stimulation requires lipids supplied by serum lipids or by de novo synthesis stimulated by biotin. In the absence of serum, the stimulation of the synthesis of growth factor(s) by biotin are also required for continuous multiplication.

Cell surface and cell division

A mathematical model of the regulation of cell division is suggested. The model is based on the hypothesis that the process giving rhythm to cell division is located in the cell membrane: i.e., the process of free-radical oxidation of membrane lipids. Much depends on the physical state of the membrane. In the membrane, phase transitions take place because of the changes in lipid composition. These transitions differ in normal and tumor cells: in normal cells they are sharp and hysteretic owing to the presence of a framework (membrane skeleton) on the surface of the membrane, while in tumor cells the integrity of the surface is violated so that the transitions are smooth. This model makes it possible to explain differences in the regulation of normal and cancer cell proliferation. Within the limits of the model, such phenomena as density dependent inhibition of growth, reverse transformation, influence of cyclic AMP and ions of Ca2+ on the cell cycle, the actions of serum and of proteases on the cycle, and so on, are explained. A rational scheme for the appearance of the selective damage found in tumor cells is proposed.

The activity of 3-hydroxy-3-methylglutaryl coenzyme A reductase and the rate of sterol synthesis diminish in cultures with high cell density

The specific activity of HMG-CoA reductase, the major rate-limiting enzyme in the sterol biosynthetic pathway, declined linearly with increasing cell density in four different lines of mammalian cell cultures. As expected, this caused the rates of sterol synthesis from [14C]acetate to decline in a parallel manner. The decrease in reductase activity in the dense cultures was also correlated with decreased incorporation of [14C]acetate into fatty acids and [3H]thymidine into DNA. In contrast, the activities of two enzymes, NADH dehydrogenase and 5'-nucleotidase, which are not involved in lipid synthesis, were independent of changes in cell density. The simplest explanation for these data is tht HMG-CoA reductase and the synthesis of sterol and fatty acids are regulated in concordance with the rate of cell growth and proliferation.

Regulation of 3-hydroxy-3-methylglutaryl CoA reductase by analogs of cholesterol and bile acids in cultured intestinal mucosa

Sodium fusidate and its glycine conjugate, which have the same detergent properties as bile acids, significantly (p less than 0.05) stimulate HMG-CoA reductase of cultured intestine below the critical micellar concentration (CMC) without affecting brush border enzymes. Above CMC, both amphiphiles are cytotoxic. At concentrations between 1 and 5 mM, sodium fusidate decreased cholesterol contents of cultured mucosa (P less than 0.05), the increase in synthesis only partially compensating for the sterol loss. Oxygenated sterols, 7-keto- and 25-hydroxycholesterol, also depleted mucosal cholesterol at 0.5 mM, exerting their effect differently by inhibiting HMG-CoA reductase (p less than 0.01). In contrast to their marked effect on total mucosal cholesterol contents, brush border cholesterol was unaffected by both cholesterol and bile acid analogs.

Changes in synthesis of sterols and fatty acids associated with inhibition of growth of L-M cells at high cell density

The relationship between cell density and de novo synthesis of sterols and fatty acids has been studied in monolayer cultures of L-M cells grown in serum-free medium. Incorporation of radioactivity from [14C] acetate or 3H2O into sterols and fatty acids declined sharply as cultures approached stationary phase. The activities of 3-hydroxy-3-methylglutaryl-CoA reductase and 3-hydroxy-3-methylglutaryl-CoA synthase declined in conjunction with the decrease in sterol synthesis; however, the activity of acetoacetyl-CoA thiolase did not decrease until after sterol synthesis had begun to decline. The magnitude of the initial decline in reductase activity was not diminished when activation of latent enzyme activity was prevented by addition of fluoride to cell homogenates. The diminution in the rate of fatty acid synthesis at high cell density was accompanied by a decrease in the activity of fatty acid synthetase, whereas the activity of acetyl-CoA carboxylase increased slightly. The data suggest that lipogenesis is regulated in coordination with the changes in the rate of cell proliferation that occur when L-M cells attain a high density in monolayer culture. Moreover, these studies establish the feasibility of using the L-M cell culture system to investigate the relationship between cell density and the enzymatic regulation of lipogenesis.

Regulation of 3-hydroxy-3-methylglutaryl-CoA reductase by endogenous sterol synthesis in cultured intestinal mucosa

In vitro regulation of the key enzyme of cholesterol synthesis, 3-hydroxy-3-methylglutaryl-CoA reductase (EC 1.1.1.34) by compactin, a competitive inhibitor of the enzyme, and mevalonate was studied in rabbit ileum organ culture. Addition of compactin suppressed ileum homogenate reductase activity by over 80% at concentrations up to 0.5 microgram/ml. In contrast, compactin at the same concentrations added to the culture medium induced reductase activity up to 240% of controls. This increase was blocked by cycloheximide and mevalonolactone at 10 mM, but not by mevalonate (salt form) and cholesterol. Similarly, in contrast to ionized mevalonate, mevalonolactone significantly suppressed reductase activity of cultured intestine at 1 and 10 mM by 23 and 62%, respectively. A minor effect was also observed with preformed enzyme in fresh mucosal homogenate. When endogenous cholesterol synthesis was blocked by compactin, mucosal alkaline phosphatase activity decreased progressively, whereas medium activity from desquamated cells did not change. This distribution of the villous cell marker enzyme is characteristic of a decrease in crypt cell renewal and/or villous cell differentiation. This effect of compactin was also reversible with mevalonolactone. The reductase enzyme induced by compactin was probably latent intracellularly, since tissue cholesterol contents dropped sharply after blockade of endogenous sterol synthesis.

Inhibition of DNA synthesis and cell cycle in Chinese hamster cells by sterol-binding polyene amphotericin B

Amphotericin B, a sterol-binding polyene antibiotic, was found to inhibit DNA synthesis more than protein or RNA synthesis of asynchronous cultures of Chinese hamster V79 cells. DNA synthesis in the asynchronous V79 cells was inhibited to 40--60% of the control activity in the presence of 50 micrograms/ml amphotericin B. However, addition of 50 micrograms/ml of polyene immediately after to onset of DNA synthesis (early S phase) caused a drastic reduction of DNA synthesis (below 10--20% of the control in synchronized V79 cells, whereas the inhibition was much lessened when the polyene was added 1 h later (middle S phase). In contrast, there was no inhibition of DNA synthesis by amphotericin B in an amphotericin-B-resistant (AMBR) clone that was derived from V79. Flow microfluorometry analysis confirmed that a large number of asynchronous V79 cells were arrested in the G1 phase of the cell cycle when treated with lower dose of amphotericin B. A higher dose of the polyene antibiotic also accumulated cells at the G2 (or at both S and G2) phase as well as the G1 phase. Morphological studies by scanning electron microscope showed an increased number of V79 cells with decreased microvilli in V79 cells treated with amphotericin B.

A chemically defined medium for the propagation of rat prostate adenocarcinoma cells

A chemically defined medium (MB-DF) has been developed for the propagation of the rat prostate adenocarcinoma cell line (PA-III). The medium (MB-DF) was supplemented with fetuin, insulin, transferrin, dexamethasone, and 5 alpha - dihydrotestosterone, but require no serum supplement. The adapted line, PA-IIIf, has been grown in this serum-free medium for 30 passages over a period of 12 months without losing the malignant or other characteristics of the parent line. When transplanted into syngeneic rats, the PA-IIIf cells reconstituted the adenocarcinoma and metastasized spontaneously via ipsilateral lymphatic channels to the lungs. This cell line will be of use in further analyses of enzymes associated with biological properties of the tumor cells.

Changes in sterol biosynthesis accompanying cessation of glial cell growth in serum-free medium

C-6 glioma cells, grown in medium supplemented with 5% delipidated foetal calf serum, were induced to enter a quiescent state by removing serum from the medium. Within 24h there was a 75-80% decline in the rate of incorporation of [(14)C]acetate or (3)H(2)O into digitonin-precipitable sterols. Experiments with [(3)H]mevalonolactone as a labelled sterol precursor suggested that the decline in sterol synthesis was regulated primarily at a point in the pathway before the formation of mevalonate. The specific activities of 3-hydroxy-3-methylglutaryl-CoA synthase and 3-hydroxy-3-methylglutaryl-CoA reductase decreased sharply in conjunction with the decline in sterol synthesis in the serum-free cultures; however, the activity of acetoacetyl-CoA thiolase was altered only slightly. The magnitude of the initial decline in reductase activity was not affected when 50-mm-NaF was included in the preincubation and assay buffers to prevent activation of physiologically inactive enzyme. However, after 6h of serum deprivation the decline in 3-hydroxy-3-methylglutaryl-CoA reductase activity was due to a decrease in the amount of latent activity. The sterol concentration in C-6 cells was unchanged after 24h in serum-free medium, although a 20% decrease in the sterol/fatty acid molar ratio occurred as a result of a small increase in the fatty-acid concentration. Incorporation of (3)H(2)O into fatty acids was inhibited in the serum-deprived glial cells; however, this inhibition developed more slowly and was not as pronounced as the diminution in sterol synthesis. The results suggest that in C-6 glia, which resemble the glial stem cells of the developing brain, the decreased demand for membrane sterols in the quiescent state results in a decline in sterol synthesis, mediated primarily through co-ordinate changes in the activities of 3-hydroxy-3-methylglutaryl-CoA synthase and 3-hydroxy-3-methylglutaryl-CoA reductase.

Apparent coordination of the biosynthesis of lipids in cultured cells: its relationship to the regulation of the membrane sterol:phospholipid ratio and cell cycling

The coordination of the syntheses of the several cellular lipid classes with one another and with cell cycle control were investigated in proliferating L6 myoblasts and fibroblasts (WI-38 and CEF). Cells cultured in lipid-depleted medium containing one of two inhibitors of hydroxymethylglutaryl-CoA reductase, 25-hydroxycholesterol or compactin, display a rapid, dose-dependent inhibition of cholesterol synthesis. Inhibition of the syntheses of each of the other lipid classes is first apparent after the rate of sterol synthesis is depressed severalfold. 24 h after the addition of the inhibitor, the syntheses of DNA, RNA, and protein also decline. The inhibition of sterol synthesis leads to a threefold reduction in the sterol:phospholipid ratio that parallels the development of proliferative and G1 cell cycle arrests and alterations in cellular morphology. All of these responses are reversed upon reinitiation of cholesterol synthesis or addition of exogenous cholesterol. A comparison of the timing of these responses with respect to the development of the G1 arrest indicates that the primary factor limiting cell cycling is the availability of cholesterol provided either from an exogenous source or by de novo synthesis. The G1 arrest appears to be responsible for the general inhibition of macromolecular synthesis in proliferating cells treated with 25-hydroxycholesterol. In contrast, the apparent coordinated inhibition of lipid synthesis is not a consequence of the G1 arrest but may in fact give rise to it. Sequential inhibition of lipid syntheses is also observed in cycling cells when the synthesis of choline-containing lipids is blocked by choline deprivation and is observed in association with G1 arrests caused by confluence or differentiation. In the nonproliferating cells, the syntheses of lipid and protein do not appear coupled.

Inhibition of human polymorphonuclear leukocyte chemotaxis by oxygenated sterol compounds

When preincubated with certain oxygenated sterol compounds in lipoprotein-depleted serum [20% (vol/vol)], human polymorphonuclear leukocytes show inhibition of chemotaxis toward the synthetic dipeptide N-formylmethionylphenylalanine without alteration of random movement or loss of cell viability. These effects can occur at sterol concentrations as low as 6.25 microM and after as little as 5 min of preincubation, but they are increased at higher concentrations and longer preincubation times. The inhibition can be almost completely reversed by preincubation in lipoprotein-replete serum [human AB serum, 20% (vol/vol)] and may be partially corrected by addition of free cholesterol (0.125 mM) to the medium. These effects are unlikely to be due to inhibition of cellular sterol synthesis, competition for chemotaxin membrane binding sites, or deactivation of the leukocytes but they may be a consequence of insertion of the sterol molecule into the leukocyte plasma membranes.

Enhanced sterol synthesis in concanavalin A-stimulated lymphocytes: correlation with phospholipid synthesis and DNA synthesis

Incorporation of (14C)choline and (3H)myo-inositol into the total lipid fraction, incorporation of (14C)acetate into the sterol fraction and incorporation of (3H)thymidine into DNA were studied in human lymphocyte cultures. Concanavalin A induced an increase in the incorporation of these labels with the following features: (a) Phospholipid synthesis was increased promptly. The lag time for the increase in sterol synthesis and DNA synthesis were 5 hours and 27 hours respectively; (b) The increase in phospholipid synthesis and sterol synthesis was proportional to ConA concentration initially. Cells treated with a high concentration of ConA showed very low levels of DNA synthesis; (c) The increase in phospholipid synthesis could be abolished immediately by alpha-Methyl-Mannoside. alpha-Methyl-Mannoside blunted but did not abolish the increase in sterol synthesis. alpha-Methyl-Mannoside enhanced DNA synthesis of those cells which had been treated by a high concentration of ConA; and (d) Selective inhibition of sterol synthesis with 25-hydroxycholesterol did not prevent the increase in phospholipid synthesis, but it blocked the increase in DNA synthesis. Supplement of LDL, HDL or total lipoproteins to lymphocyte cultures was effective in preventing the inhibition of DNA synthesis by 25-hydroxy-cholesterol. These results suggest that in lymphocyte activation by ConA phospholipid synthesis, sterol synthesis and DNA synthesis were sequentially increased. The rate of cellular commitment to mitogenesis was proportional to ConA concentrations. High concentrations of ConA arrested the cell growth at a postcommitment point in the G1 phase. Enhanced phospholipid synthesis was a precommitment event. Enhanced sterol synthesis was a postcommitment event and reflected the requirement of an increased cholesterol supply for the passage of cell growth through G1.

Biological activity of some oxygenated sterols

A group of oxygenated sterols has been identified as potent and specific inhibitors of sterol biosynthesis. The ability of these compounds to inhibit sterol synthesis in cultured cells and the ineffectiveness of cholesterol under the same conditions suggest that feedback regulation of sterol biosynthesis may be brought about by an oxygenated sterol rather than by cholesterol. The nature of the regulatory sterol may vary in different cells with their specific requirements for cholesterol as a structural component or as a precursor of other steroid products. The use of oxygenated sterols to block sterol synthesis in cultured cells provides new information regarding the role of sterol in cell membrane structure and function. For example, de novo sterol synthesis is required for DNA synthesis and cell division by some cultured cells. Studies with cultured cells, and with rats and mice in vivo, suggest that oxygenated sterols could be of value in the treatment of several important human diseases.