Inhibitory effect of transforming growth factor-beta on DNA synthesis of adult rat hepatocytes in primary culture

Transforming growth factor beta (TGF-beta) inhibits hepatocyte DNA synthesis independently of EGF binding and EGF receptor autophosphorylation

Subpicomolar concentrations of human platelet-derived transforming growth factor beta (TGF-beta) inhibited growth factor-stimulated DNA synthesis in primary cultures of adult rat hepatocytes. This inhibition was not the result of changes in the size of intracellular pools of 3H-thymidine and was not dependent on the state of confluence of the cells. A 24-hr exposure to TGF-beta either before or after insulin/EGF stimulation was as inhibitory on DNA synthesis between 48 and 72 hr of culture as was TGF-beta present throughout 72 hr of culture. From 12 hr in culture to 24 hr, hepatocyte EGF binding sites dropped from about 230,000 to 85,000 per cell with no significant change in Kd, but with a loss in capacity for EGF-induced receptor down-regulation. Maximally inhibitory concentrations of TGF-beta did not compete with EGF for the EGF receptor, and a 4- to 24-hr exposure to TGF-beta did not alter subsequent EGF binding. Coincubation of hepatocytes with TGF-beta and EGF did not influence the 60% reduction in EGF binding sites produced by EGF alone. In addition, TGF-beta did not prevent EGF-induced autophosphorylation of the 170,000 dalton EGF receptor in membranes from whole liver. Our studies suggest that TGF-beta regulates hepatocyte growth independently of changes in EGF receptor number, ligand affinity, or postbinding autophosphorylation.

Alteration in growth, cell morphology, and cytoskeletal structures of KB cells induced by epidermal growth factor and transforming growth factor-beta

Long-term biological effects of epidermal growth factor (EGF), insulin, insulin-like growth factor-I (IGF-I), and transforming growth factor-beta (TGF-beta) were examined with human epidermoid carcinoma KB cells. EGF inhibited the growth of KB cells in both serum-containing and serum-free synthetic media by reducing the growth rate and by lowering the saturation density. The cells cultured with EGF showed relatively high motility and grew dispersely as single cells, whereas the cells cultured in the absence of EGF grew in clusters. Although TGF-beta itself did not inhibit the growth of KB cells, it augmented the growth inhibition by EGF. TGF-beta also affected the cell morphology. In the presence of TGF-beta, the cells became flattened and actin stress fibers were well developed compared to those cultured in its absence. The effects of EGF on growth, cell motility, and cell morphology were reversible. Tyrosine phosphorylation of EGF receptors was continuously observed for at least 50 h in the presence of EGF. TGF-beta did not increase the phosphorylation induced by EGF. These results suggested that signals continuously transmitted through EGF receptors caused the changes in cell growth and morphology and that TGF-beta did not act on the cells by modulating binding of EGF to its receptors or activation of the receptor kinase. In contrast to EGF and TGF-beta, neither insulin nor IGF-I affected cell morphology or growth, although KB cells express their receptors and the receptor kinases were also continuously activated during exposure of the cells to insulin or IGF-I.

Transforming growth factor beta mRNA increases during liver regeneration: a possible paracrine mechanism of growth regulation

Transforming growth factor beta (TGF-beta) is a growth factor with multiple biological properties including stimulation and inhibition of cell proliferation. To determine whether TGF-beta is involved in hepatocyte growth responses in vivo, we measured the levels of TGF-beta mRNA in normal liver and during liver regeneration after partial hepatectomy in rats. TGF-beta mRNA increases in the regenerating liver and reaches a peak (about 8 times higher than basal levels) after the major wave of hepatocyte cell division and mitosis have taken place and after the peak expression of the ras protooncogenes. Although hepatocytes from normal and regenerating liver respond to TGF-beta, they do not synthesize TGF-beta mRNA. Instead, the message is present in liver nonparenchymal cells and is particularly abundant in cell fractions enriched for endothelial cells. TGF-beta inhibits epidermal growth factor-induced DNA synthesis in vitro in hepatocytes from normal or regenerating liver, although the dose-response curves vary according to the culture medium used. We conclude that TGF-beta may function as the effector of an inhibitory paracrine loop that is activated during liver regeneration, perhaps to prevent uncontrolled hepatocyte proliferation.

Purification and partial characterization of hepatocyte growth factor from plasma of a patient with fulminant hepatic failure

Human hepatocyte growth factor (hHGF) has been purified approximately 209,000-fold with 18% yield from plasma of a patient with fulminant hepatic failure. The purification involves heat treatment of plasma, ammonium sulfate precipitation, and chromatography on Affi-Gel Blue, heparin-Sepharose, and hydroxylapatite. Purified hHGF shows several bands with molecular weights between 76,000 and 92,000. Each band shows growth-stimulating activity on cultured hepatocytes which is proportional to the intensity of the band. After reduction of the sample with 2-mercaptoethanol, SDS-PAGE yields two chains with molecular weights of 31,500-34,500 and 54,000-65,000. The effect of hHGF on DNA synthesis by hepatocytes is half-maximal at 3.5 ng/ml. hHGF stimulates proliferation of cultured hepatocytes more effectively than human epidermal growth factor (hEGF) or insulin, and the effect of hHGF is additive or synergistic with the maximal effects of hEGF and insulin. These results suggest that hHGF is a new growth factor which is different from hEGF.

Different proliferative activity in vitro of periportal and perivenous hepatocytes

The different growth potentials of hepatocytes from different zones of the liver acinus were assessed in vitro by autoradiography with immunocytochemical discrimination of periportal and perivenous hepatocytes by the marker enzyme glutamine synthetase (GS) or their direct isolation by the digitonin/collagenase perfusion technique. All stimuli studied led to much higher labeling indices in GS-negative than in GS-positive cells in cultures both of all hepatocytes and of the perivenous subfraction. In contrast, the response of GS-negative hepatocytes in the periportal and in the perivenous subfractions differed only gradually depending of the growth stimulus. It is concluded that GS-positive hepatocytes are distinguished from all other hepatocytes by a completely different growth characteristics, which may play a dominant role in the regenerative remodelling of zone 3. The wave-like spatiotemporal pattern of DNA synthesis during liver regeneration, however, seems to be due to gradual changes in growth responsiveness of the hepatocytes along the acinus.

Transforming growth factor beta and inhibition of hepatocellular proliferation

Transforming growth factor beta (TGF beta) is a recently characterized polypeptide that elicits diverse biologic actions in a wide range of cell types in vitro. TGF beta is a bifunctional growth regulator of fibroblasts with either growth stimulation or growth inhibition but inhibits the growth of most epithelial cells. In addition, TGF beta can either block or induce the differentiation of certain cells. TGF beta reversibly inhibits DNA synthesis in normal adult rat hepatocytes and in cells isolated from regenerating liver 12 h and 18 h after partial hepatectomy. However, at 3 h and 6 h after hepatectomy there is a decrease in sensitivity of hepatocytes to growth inhibition by TGF beta. Recent data from other laboratories indicate that TGF beta expression increases substantially in liver after partial hepatectomy and that administration of purified TGF beta in vivo inhibits DNA synthesis in regenerating rat liver. Together with our observations, these findings suggest that TGF beta may play a central role as a negative paracrine growth regulator in adult rat liver.

Liver-specific growth factors

Experimental evidence of the existence of liver-specific growth factors has been collected for more than two decades. Blood-borne growth-promoting activity of hepatocytes may be separated into plasma and platelet-derived factors. Several groups have observed the stimulation of hepatocyte growth in vitro by some platelet-associated activity, which was recently isolated from rat platelets as a 27-kDa protein called platelet growth factor (PGF). There is evidence of at least two different growth factors for hepatocytes derived from platelet-poor rat plasma, 'hepatopoietin' A and B. The partial purification of several other factors has been reported. One of these factors was prepared from the plasma of patients with fulminant hepatic failure. In addition to these 'humoral' factors, cytosolic growth-promoting activity has been partially purified by several groups. While the humoral factors described so far are only active on normal hepatocytes, the cytosolic 'hepatic stimulator substance' (HSS) also promotes the proliferation of differentiated hepatoma cells. In addition, it appears to depend on the permissive action of epidermal growth factor (EGF). None of the liver-specific growth factors except PGF has been purified to homogeneity. Thus, their significance for the control of the proliferation of normal and transformed hepatocytes is still an unsettled issue.

Characterization of a hepatic proliferation inhibitor (HPI): effect of HPI on the growth of normal liver cells--comparison with transforming growth factor beta

Improvements in the purification of a hepatic proliferation inhibitor (HPI) from adult rat liver have yielded a product that has an inhibitory activity 1,000-fold greater than previously reported. The growth inhibitory activity, which could be eluted from SDS-PAGE at 17-19 kilodaltons (kD), was compared to that of transforming growth factor beta (TGF-beta). The ID50 of the HPI preparation in Fischer rat liver epithelial cells was 50 pg/ml (2.5 pM) compared to a value of 260 pg/ml (10.4 pM) obtained for pure human TGF-beta. Both inhibitors also modulated the stimulation of DNA synthesis in primary hepatocytes by either epidermal growth factor or a growth stimulatory activity prepared from serum of hepatectomized rats. The ID50s of HPI and TGF-beta in these cells were 250 pg/ml and 40 pg/ml, respectively. In contrast to TGF-beta the growth inhibitory activity of HPI was unaltered in the presence of an antibody raised against TGF-beta. The possible mechanism of action of HPI is discussed.

Purification and subunit structure of hepatocyte growth factor from rat platelets

A hepatocyte growth factor (HGF) that stimulates DNA synthesis of adult rat hepatocytes in primary culture was purified as a homogeneous material from platelets of 1000 rats by a four-step procedure: stimulation of its release from platelets by thrombin, cation-exchanger fast protein liquid chromatography (FPLC) on a Mono S column, heparin-Sepharose CL-6B chromatography, and reverse-phase HPLC on a C4 column. The purified HGF stimulated DNA synthesis of adult rat hepatocytes in primary culture at 1 ng/ml and was maximally effective at 5 ng/ml, being about twice as potent as EGF at this concentration. HGF did not stimulate DNA synthesis of Swiss 3T3 cells. It was found to be a heat- and acid-labile protein that was inactivated by reduction with dithiothreitol. The purified HGF had a molecular mass of 82 kDa, as estimated by SDS-PAGE, and was found to be a heterodimer which dissociated into a large subunit of 69 kDa and a small one of 34 kDa by SDS-PAGE under reducing conditions. These biological and chemical properties showed that HGF was not identical with any known growth factors, including platelet-derived growth factor (PDGF).

Effect of transforming growth factor beta (TGF-beta) on ATP citrate lyase in isolated hepatocytes

Transforming growth factor beta (TGF-beta) activates ATP citrate lyase in freshly isolated rat liver hepatocytes in a time dependent manner. Maximal stimulation of the enzyme occurred with less than thirty minutes of incubation of the cells with TGF-beta. The half-maximal effect on the enzyme determined in hepatocytes incubated with TGF-beta for 10 min at 37 degrees C was elicited by TGF-beta concentrations in the 10-11 - 10-12 M range. The potential role of TGF-beta stimulation of ATP citrate lyase activity in new membrane synthesis is discussed.

Direct analysis of growth factor requirements for isolated human fetal hepatocytes

Hepatocytes were isolated from human fetal liver in order to analyze the direct effects of growth factors and hormones on human hepatocyte proliferation and function. Mechanical fragmentation and then dissociation of fetal liver tissue with a collagenase/dispase mixture resulted in high yield and viability of hepatocytes. Hepatocytes were selected in arginine-free, ornithine-supplemented medium and defined by morphology, albumin production and ornithine uptake into cellular protein. A screen of over twenty growth factors, hormones, mitogenic agents and crude organ and cell extracts for effect on the stimulation of hepatocyte growth revealed that EGF, insulin, dexamethasone, and factors concentrated in bovine neural extract and hepatoma cell-conditioned medium supported attachment, maintenance and growth of hepatocytes on a collagen-coated substratum. The population of cells selected and defined as differentiated hepatocytes had a proliferative potential of about 4 cumulative population doublings. EGF and insulin synergistically stimulated DNA synthesis in the absence of other hormones and growth factors. Although neural extracts enhanced hepatocyte number, no effect on DNA synthesis of neural extracts or purified heparin-binding growth factors from neural extracts could be demonstrated in the absence or presence of defined hormones, hepatoma-conditioned medium or serum. Hepatoma cell-conditioned medium had the largest impact on both hepatocyte cell number and DNA synthesis under all conditions. Dialyzed serum protein (1 mg/ml) at 10 times higher protein concentration had a similar effect to hepatoma cell-conditioned medium (100 micrograms/ml). The results suggest that hepatoma cell conditioned medium may be a concentrated and less complicated source than serum for purification and characterization of additional normal hepatocyte growth factors.

In vitro effect of a glycopeptide acting in vivo on hepatocyte cell cycle

A factor specifically inhibiting the hepatocyte cell cycle in vivo was found to block the G1-S transition of liver cells in vitro. It proved to be non-toxic in our culture conditions, as judged by the reversibility of the effect on cell proliferation. It was not active on DNA synthesis in fibroblastic cell lines (3T3).

Interactions of interferons and transforming growth factors during clonal growth of mouse or human cells in soft agar and in mice

The mouse fibroblast-like transformed cell line C-243 adapted to growth in suspension was used as a source of virus-induced interferons (MulFN-alpha, beta), and spontaneously produced active growth factors. These factors were purified from C-243 cells grown as tumors in BALB/c mice, and had properties identical to those of TGF-alpha or TGF-beta isolated by others from different tissues. Exogenous TGF-alpha, beta stimulated colony formation by C-243 cells in soft agar, whereas MulFN-alpha, beta inhibited it. Clonal growth of human lung adenocarcinoma A549 cells in soft agar was inhibited as well by human interferons (types alpha, beta, or gamma) as by TGF-beta. Inhibition was dose-related. Pure EGF, which is an analogue of TGF-alpha, diminished the antiproliferative activity of interferons alpha, beta, and gamma in A549 cells. On the other hand, the anti-mitogenic action of IFN-beta and TGF-beta was clearly synergistic. In mice bearing C-243 cell tumors, TGF-alpha, beta stimulated growth, whereas MulFN-alpha, beta inhibited it. Stimulation of tumor growth was also observed after administration of anti-IFN serum that could neutralize endogenous IFN-alpha, beta. The simultaneous administration of MulFN-alpha, beta and TGF-alpha, beta diminished anti-tumor effects of IFN in mice. Our results suggest that both TGFs and IFNs are autocrine, positive or negative growth factors modulating the rate of proliferation and the neoplastic behavior of the cells. The final effects depend on the target-cell sensitivity and on the relative concentration of the various hormone-like factors. Cancer cells overstimulated by TGF-alpha, beta or by EGF may not respond to IFNs.

Transforming growth factor beta inhibits DNA synthesis in hepatocytes isolated from normal and regenerating rat liver

The inhibitory action of transforming growth factor beta (TGF beta) on DNA synthesis in hepatocytes isolated from the liver of normal rats or from the liver remnant of rats 18 h following partial hepatectomy was compared. Continuous exposure to TGF beta inhibited DNA synthesis of cultured hepatocytes to a similar degree in both groups when labelled with 3H thymidine from 24-48 h or 48-72 h. At 20 pM TGF beta, 3H-thymidine incorporation was reduced by 64-78% in hepatocytes from normal liver and by 60-73% in cells from 18 h regenerating liver. The nuclear labelling index was reduced by 70-80% in all cells. Exposure to TGF beta at concentrations up to 500 pM from 0-24 h had no effect on 3H-thymidine incorporation, but exposure at 20 pM for 24 h periods thereafter was uniformally effective. These results indicate that there is no change in sensitivity of hepatocytes from 18 h regenerating liver to TGF beta, compared with normal cells, and that TGF beta may act at some point in the G1 phase of the cell cycle to inhibit hepatocyte growth.

Inhibition of proliferation of cultured rat liver epithelial cells at specific cell cycle stages by transforming growth factor-beta

Proliferation of early-passage propagable cultured rat liver epithelial cells derived from normal adult rats is markedly inhibited by transforming growth factor-beta (TGF-beta). Inhibition, which is completely reversible, is effected at two distinct points of the cell cycle, the G1/S border and the G0 or early G1 phase. With increasing passages in culture, hepatic epithelial cells progressively become less sensitive to the inhibitory effect of TGF-beta.

Transforming growth factors and control of neoplastic cell growth

Transforming growth factors (TGFs) are peptides that affect the growth and phenotype of cultured cells and bring about in nonmalignant fibroblastic cells phenotypic properties that resemble those of malignant cells. Two types of TGFs have been well characterized. One of these, TGF alpha, is related to epidermal growth factor (EGF) and binds to the EGF receptor, whereas the other, TGF beta, is not structurally or functionally related to TGF alpha or EGF and mediates its effects via distinct receptors. TGF beta is produced by a variety of normal and malignant cells. Depending upon the assay system employed, TGF beta has both growth-inhibitory and growth-stimulating properties. Many of the mitogenic effects of TGF beta are probably an indirect result of the activation of certain growth factor genes in the target cell. The ubiquitous nature of the TGF beta receptor and the production of TGF beta in a latent form by most cultured cells suggests that the differing cellular responses to TGF beta are regulated either by events involved in the activation of the factor or by postreceptor mechanisms. The combined effects of TGF beta with other growth factors or inhibitors evidently play a central role in the control of normal and malignant cellular growth as well as in cell differentiation and morphogenesis. Since transforming growth factor as a concept has partially proven misleading and insufficient, there is a need to find a new nomenclature for these regulators of cellular growth and differentiation.

Partial purification and characterization of masking protein for beta-type transforming growth factor from rat platelets

beta-Transforming growth factor (TGF-beta) is stored in platelets and secreted as a high molecular weight latent form associated with a carrier protein of about 440 KD. This carrier protein could be separated from TGF-beta in 1 N acetic acid and could again mask the activity of TGF-beta under neutral conditions. Therefore, it was named the masking protein of TGF-beta. The masking protein was separated from TGF-beta by gel filtration on a Sephacryl S-300 column or by anion-exchanger FPLC on a Mono Q column in the presence of 6 M urea. Partially purified masking protein from rat platelets neutralized the activity of TGF-beta dose-dependently and was effective at 0.3 microgram/ml. This masking protein could also mask the activity of human TGF-beta, suggesting that it was not species specific. The masking protein was a heat- and acid-stable protein, but was inactivated by treatment with dithiothreitol. The Physiological role of the masking protein in the mechanisms of wound healing and liver regeneration is discussed.

Type beta transforming growth factor is a potent modulator of differentiated adrenocortical cell functions

Whereas TGF-beta exhibited no detectable effect on DNA synthesis, it was found to exert a striking inhibitory effect on the steroidogenic activities of bovine adrenocortical cells in culture. Basal, as well as ACTH- and angiotensin II- activated adrenocortical cortisol productions were inhibited in a time and dose-dependent manner following TGF-beta treatment. Half-maximum inhibition of ACTH- and AII-activated steroidogenesis was observed with TGF-beta concentrations of 0.40 and 0.12 ng/ml, respectively. This effect was half maximal after 6 hours of cell exposure to optimally effective TGF-beta concentrations (1 ng/ml) and reached a plateau after 12-15 hours, resulting in an average 60% inhibition in the steroidogenic response to ACTH and 90% in the case of AII. Supply of different exogenous steroid substrates to support steroidogenesis in adrenocortical cells pointed to a marked loss in steroid-17 alpha hydroxylase activity as a major alteration following TGF-beta treatment. TGF-beta thus appears as a potent modulator of differentiated adrenocortical cell functions in vitro; in this regard it may play a significant role in the development and the regulation of adrenal cortex in vivo.

Purification and characterization of a growth factor from rat platelets for mature parenchymal hepatocytes in primary cultures

A growth factor (HGF) stimulating DNA synthesis of adult rat hepatocytes in primary culture was found in rat platelets. HGF was purified from rat platelets to homogeneity by a three-step procedure: stimulation of its release from platelets by thrombin, cation-exchanger fast protein liquid chromatography on a Mono S column, and heparin-Sepharose chromatography. HGF was clearly distinguishable from the platelet-derived growth factor (PDGF) by fast protein liquid chromatography. HGF was a heat- and acid-labile cationic protein that was inactivated by reduction with dithiothreitol. Its molecular mass was estimated to be 27 kDa by NaDodSO4/PAGE and its amino acid composition was very different from that of PDGF. The purified HGF stimulated DNA synthesis in adult rat hepatocytes at 2 ng/ml and was maximally effective at 20 ng/ml; its effect was additive or synergistic with those of insulin and EGF, depending on their combinations. HGF did not stimulate DNA synthesis of Swiss 3T3 cells, while PDGF did not stimulate that of hepatocytes. Thus, HGF showed clearly different cell specificity from PDGF in its growth-promoting activities. These findings indicate that HGF is a growth factor in platelets for mature hepatocytes.

Transforming growth factor-beta inhibits endothelial cell proliferation

Transforming growth factor-beta (TGF-beta) is an inhibitor of the proliferation of bovine aortic endothelial cells in culture. Basal cell growth in serum-containing medium and cell proliferation stimulated by fibroblast growth factor (FGF) are inhibited by TGF-beta in a dose-dependent manner. Half-maximal inhibition occurs at an inhibitor concentration of 0.5-1.0 ng/ml. TGF-beta does not appear to be cytotoxic and cells treated with the inhibitor grow normally after removal of TGF-beta. High concentrations of FGF are ineffective in overcoming TGF-beta-induced inhibition of cell proliferation, suggesting that antagonism of growth factor-induced cell proliferation by TGF-beta is of a noncompetitive nature.

Differential effect of growth factors on growth stimulation and phenotypic stability of glutamine-synthetase-positive and -negative hepatocytes in primary culture

In rat liver parenchyma, two subpopulations of hepatocytes can be distinguished by the absence or presence of the marker enzyme, glutamine synthetase (GS). Hepatocytes in the perivenous zone immediately adjacent to the hepatic venules in the liver acinus are positive for GS. Using autoradiography in combination with immunocytochemistry, the response of these two hepatocyte populations (GS positive and GS negative) to a variety of growth factors (defined compounds or complex stimuli) was investigated in vitro. Irrespective of the individual growth-promoting activity (which varied considerably), all stimuli led to much higher labeling indices in GS-negative cells as compared to GS-positive cells. In GS-negative cells, the strongest effect was exerted by serum obtained from partially hepatectomized rats (labeling index, 67%) and the conditioned media of JM1 and JM2 hepatoma cells (63%-82%), followed by a combination of insulin and either norepinephrine (46%) or epidermal growth factor (EGF; 42%). In contrast, serum had the weakest influence on GS-positive cells (0.3%), while the other potent stimuli enhanced the labeling index of these cells by between 6% and 15% within 48 h. The percentage of labeled nuclei was higher in mononucleated than in binucleated GS-positive hepatocytes. The time course of thymidine incorporation was also different for the two subpopulations. Under all growth-promoting conditions, the stimulation of GS-negative cells peaked between 72 and 96 h, while it increased continuously in GS-positive cells for at least 120 h, particularly in the case of serum. In proliferating cultures, both the absolute and the relative number of GS-positive hepatocytes decreased, while no such effect was found in various nonproliferating control cultures maintained at low and high cell density. Similar results were found for GS activity. In contrast, the hormonal induction of tyrosine aminotransferase (TAT) was not affected. It is suggested that these differences in the growth response of GS-positive and -negative cells contribute to the acinar gradient in hepatocyte proliferation that occurs during liver regeneration. Furthermore, the striking phenotypic instability of GS-positive cells that have undergone DNA synthesis and mitosis supports the hypothesis that cellular reprogramming depends on passage through the cell cycle.