Differential effects of phorbol ester on the in vitro invasiveness of malignant and non-malignant human fibroblast cells

The effect of the phorbol ester tumor promoter 12-O-tetradecanoylphorbol 13-acetate (TPA) on cell invasion was studied using an in vitro assay for cell invasion through a reconstituted basement membrane matrix (Matrigel). TPA inhibited the invasiveness of malignant human fibrosarcoma HT1080 cells. In contrast, WI-38 lung fibroblasts, which show a very low invasive capacity, were stimulated (3-fold) to invade Matrigel after exposure to TPA for 48 hours. The inhibitory or stimulatory effects of TPA on cell invasion were correlated with a decrease or an increase in cell motility and collagenase IV activity, respectively. Synthetic diacylglycerols partially mimicked the inhibitory action of TPA on HT1080 cells but failed to stimulate WI-38 cell invasion. Immunoblots demonstrated that in both cell lines the alpha and beta isoforms of protein kinase C were equally down-regulated after a 5 hour exposure to TPA despite the basal low level of protein kinase C polypeptide in the malignant cells. Thus, whereas in WI-38 cells induction of an invasive behavior could be observed in the absence of protein kinase C, in the malignant cells disappearance of the kinase was associated with a non-invasive phenotype.     

Changes in enzymic activity during cultivation of human cells in vitro

The composition of chromatin, its template activity and the activity of certain chromatin-associated enzymes, including DNA polymerase (DP) and soluble RNase, DNase, DP and seryl tRNA synthetase, were examined in early and late passage of WI-38 cells and of WI-38VA13 cells.No significant changes in soluble RNase, DNase, seryl tRNA synthetase or soluble and chromatin-associated DP were found with increasing passage of WI-38 cells. The activity of seryl tRNA synthetase and DP in WI38VA13 cells was, however, significantly higher than WI-38 cells in all passages. A decline in RNA synthesizing activity of chromatin, an increase in the proportion of RNA and histone in chromatin, as well as an increase in the activities of ‘chromatin-associated enzymes’ (RNase, DNase, protease, nucleoside triphosphatase, DPN pyrophosphorylase) were noted in WI-38 cells with increasing passages. Although RNA synthesizing activity of chromatin from WI38VA13 cells was lower than that from WI-38 cells, the former also were much lower in ‘chromatin-associated enzymes’. An increase of chromatin-associated enzymes responsible for RNA, DNA and protein degradation in WI-38 cells in successive passages, and a much lower activity of these enzymes in WI-38VA13 cells (which have an indefinite doubling potential in vitro) suggests that an elevation in the activity of these enzymes, which would seriously interfere with the chromatin function, could result in ‘aging’ of WI-38 cells.     

Age-related alterations in plasma membrane glycoprotein content and scheduled or unscheduled DNA synthesis.

WI-38 cells of various ages and SV40-transformed WI-38 cells were examined for differences in plasma membrane composition of glycoproteins and DNA synthesis. Sialic acid per milligram of protein content of the membranes of WI-38 cells decreased with passage of time in culture. Other glycoprotein fractions and alkaline phosphatase activity disappeared in the WI-38 cells with passage of time in culture (Phase III). Studies of DNA repair correlated with changes observed in the plasma membrane glycoprotein content of WI-38 cells over a passage of time in culture were also reported. Both the extent and rate of ultraviolet-induced unscheduled DNA synthesis remained relatively constant during the passage of the WI-38 cells until late phase III. At that time the extent of unscheduled DNA synthesis was measurably reduced. The number of cells in a population of phase III cells able to perform semiconservative DNA synthesis diminished with age in culture but not to an extent capable of explaining the observed changes seen in membrane composition of semiconservative DNA synthesis during passage of the cells in culture. Cells with an extended lifespan SV40-transformed WI-38 (VA 13.2 RA) cells, did not vary in membrane composition, semiconservative DNA synthesis, or unscheduled DNA synthesis over 200 serial subpassages of the cells in culture.     

Inducers of DNA synthesis: levels higher in transformed cells than in normal cells

The objective of this study was to determine whether transformed cells have greater DNA synthesis-inducing ability (DSIA) than normal cells when fused with G1 phase cells. HeLa cells synchronized in G1 phase, prelabeled with large latex beads, were fused separately with (a) quiescent human diploid fibroblasts (HDF), (b) HDF partially synchronized in late G1, and random populations of (c) HeLa, (d) WI-38, (e) SV-40 transformed WI-38, (f) CHO, (g) chemically transformed mouse cells (AKR-MCA), and (h) T98G human glioblastoma cells (all prelabeled with small latex beads) using UV-inactivated Sendai virus. The fusion mixture was incubated with [3H] thymidine, sampled at regular intervals, and processed for radioautography. Among the heterodikaryons, the frequency of those with a labeled and an unlabeled nuclei (L/U) were scored as a function of time after fusion. The faster the induction of DNA synthesis in HeLa G1, the steeper the drop in the L/U class and hence the higher DSIA in the S phase cells. The DSIA, which is indicative of the intracellular levels of the inducers of DNA synthesis, was the highest in HeLa and virally transformed WI-38 cells and the lowest in normal human diploid fibroblasts (HDF) while those of chemically and spontaneously transformed cells are intermediate between these two extremes. Higher level of DNA synthesis inducers appears to be one of the pleotropic effects of transformation by DNA tumor viruses. These studies also revealed that initiation of DNA synthesis per se is regulated by the presence of inducers and not by inhibitors.     

Human cytomegalovirus stimulates host cell RNA synthesis.

Human cytomegalovirus infection of human fibroblast cells (WI-38) induced cellular RNA synthesis. The RNA synthesis in infected cultures preceded the synthesis of viral DNA and progeny virus by approximately 24 h. RNA species synthesized in infected cells included ribosomal 28S and 18S; and 4S transfer RNA; all were markedly increased in comparison to uninfected cells. This induction of host cell RNA synthesis was dependent upon a protein(s) that was synthesized during the early stages of infection.     

Inhibition of cellular transition from G1-resting to G1-prereplicative phase by aminonucleoside of puromycin.

Human embryonic lung fibroblasts (IMR-90 and WI-38) were arrested in the G1 phase of the cell cycle by serum deprivation and high population density. Within 1 hr after the addition of medium containing fresh serum, these cells showed an increase in rRNA synthesis. The inclusion of 100 micrograms per ml aminonucleoside of puromycin (AMS) in the fresh medium eliminated the serum stimulation of rRNA synthesis and prevented the cells from making the G1-resting phase to G1-prereplicative phase transition. AMS also prevented the synthesis of HnRNA normally found within 10 hr after serum stimulation. Serum-stimulated RNA synthesis in starved, SV-40 transformed fibroblasts (WI-38-VA-13 cells) was inhibited, but not completely prevented, by AMS indicating that transformed cells may produce specific RNA's that are not AMS-sensitive and that may be responsible for the failure of transformed cells to be arrested in G1.     

Expression of c-myc and induction of DNA synthesis by platelet-poor plasma in human diploid fibroblasts

When WI-38 human diploid fibroblasts become confluent, they stop synthesizing DNA and dividing. Addition of serum causes the quiescent cell to reenter the cell cycle. Prolonged quiescence after confluence decreases and delays the response to serum. For a few days after reaching confluence, WI-38 cells also respond to platelet-poor plasma. During this period, although not cycling, WI-38 cells still express c-myc and other growth-regulated genes, as measured by steady-state RNA levels. If the quiescence is prolonged further, c-myc expression (and that of two other growth-regulated genes) is no longer detectable, and its disappearance coincides with a loss of response to platelet-poor plasma. These results suggest that, also under physiological conditions, the expression of c-myc and other growth-regulated genes can cooperate with platelet-poor plasma in inducing cellular DNA synthesis in human diploid fibroblasts.     

Prostaglandin synthetase activity and hormone responsiveness in normal and SV40 transformed WI-38 fibroblasts.

Prostaglandin (PG) synthetase activity and selective hormone responsiveness were examined in normal and SV40 transformed WI-38 fibroblasts (VA13-2RA). The transformed VA13-2RA cells have significantly reduced rates of PGE1, PGE2, PGF1alpha and PGF2alpha synthesis as compared to the normal WI-38 fibroblast. The transformed cell in contrast to the normal cell hyperresponds to stimulation by L-epinephrine (10 muM) and PGE1 (8.5 muM) but is unresponsive to bradykinin (BK) as measured by the accumulation of intracellular cyclic AMP. Indomethacin treatment does not significantly alter the PGE1 and L-epinephrine (EPI) responsiveness of the normal WI-38 fibroblast, however it abolishes the BK response in these cells. These results provide further evidence for the dependency of cell activation by bradykinin on the PG synthetase system. No experimental data was found to support the role of PGs as negative regulators of PGE1 and EPI responsiveness in the WI-38 fibroblast. Using the VA13-2RA cells, limited attempts to recover PG synthetase activity comparable to that found in normal WI-38 cells were unsuccessful. The VA13-2RA cell and its normal counterpart represent models for investigating the role of PGs in cell function and the mechanism of BK activation and its effect on cell metabolism.     

Effect of lipopolysaccharide on C3 and C5 production by human lung cells

Although studies to date have demonstrated the ability of the monocyte/macrophage to produce C components in vitro, very few studies on C production by nonhepatic tissue cells have been reported. Recently, using 35S-methionine incorporation and immunoprecipitation techniques our laboratory has demonstrated the ability of tissue cells, i.e., the human lung type II pneumocyte (A549) and human lung fibroblast (WI-38), to synthesize and secrete a variety of early and terminal complement components, as well as several regulatory proteins in vitro, i.e., C1r, C1s, C4, C3, C5, C6, C7, C8, C9, factor B, factor H, factor I, and C1s inactivator. In our studies, we extended these observations by demonstrating the capability of LPS to modulate C3 production by A549 pneumocytes. Specifically, using a sensitive ELISA we demonstrated that A549 pneumocytes exposed to LPS induced an 80 to 180% increase in C3 levels when compared to untreated A549 cells. Interestingly, LPS had no effect on C5 production or total protein synthesis by A549 pneumocytes. In the case of the WI-38 fibroblast, LPS had no effect on 1) C3 production, 2) C5 production, or 3) total protein synthesis in vitro. These studies demonstrate that agents such as LPS have the potential to selectively regulate C production (i.e., C3) in individual lung cells in vitro, and suggests that in vivo LPS may alter the local tissue reservoir of C components during infection and lung injury, thus impacting on pulmonary inflammation and host defense.     

Activation of PERK in ET-1- and thrombin-induced pulmonary fibroblast differentiation: Inhibitory effects of curcumin

In the present study, we investigated the role of PKR-like endoplasmic reticular kinase (PERK), an endoplasmic reticulum (ER) stress kinase, in endothelin 1 (ET-1)- and thrombin-induced pulmonary fibrosis (PF), and the preventive effects of curcumin (CUR). Using the human embryonic WI-38 lung fibroblast cell line, ET-1 and thrombin induced the expression of ER stress-related proteins (CCAAT-enhancer-binding protein homologous protein, PERK, and binding immunoglobulin protein), a profibrogenic factor (cellular communication network factor 2 [CCN2]), and differentiation markers including α-smooth muscle actin (α-SMA), collagen I (Col I), and Col IV. Knockdown of PERK expression via small interfering RNA (siRNA) significantly reduced the increases in CCN2, α-SMA, Col I, and Col IV proteins in WI-38 cells according to western blot analysis and immunohistochemistry (IHC). Activation of c-Jun N-terminal kinase (JNK) was observed in ET-1- and thrombin-treated WI-38 cells, and the addition of a JNK inhibitor (SP) suppressed the induction of the indicated proteins by ET-1 and thrombin. Thapsigargin (TG), an ER stress inducer, elevated expressions of PERK and ER stress-related proteins with increased differentiation of WI-38 cells. Knockdown of PERK by siRNA or the PERK inhibitor glycogen synthesis kinase reduced expressions of the differentiation markers, α-SMA and Col IV, in WI-38 cells. CUR concentration-dependently inhibited ET-1- or thrombin-induced CCN2, α-SMA, and vimentin proteins with decreased levels of phosphorylated mitogen-activated protein kinase and PERK in WI-38 cells. An in vivo bleomycin-induced PF study showed that an intraperitoneal injection of CUR (30 mg/kg) reduced expressions of α-SMA, CCN2, Col IV, and vimentin in lung tissues via IHC staining using specific antibodies. This study is the first to demonstrate that PERK activation contributes to pulmonary fibroblast differentiation elicited by ET-1 or thrombin, and the inhibitory activity of CUR against PF is demonstrated herein.     

INTERMITTENT DNA SYNTHESIS AND PERIODIC EXPRESSION OF ENZYME ACTIVITY IN THE CELL CYCLE OF WI-38

Synchronous cultures of WI-38 were obtained using an automated system for detachment and partitioning of mitotic cells which operates without the use of inhibitors, altered medium, or lowered temperatures. The generation time in synchronous WI-38 is 19.5 h and the duration of S phase when determined from the percentage of labeled metaphase cells or nuclei is 12 h. DNA replication in WI-38 occurs in three temporally distinct and rapid bursts separated by intervals of greatly reduced synthesis within what is nominally described as the DNA synthetic (S) period. Lactate dehydrogenase (LDH) displayed maxima in G₁ between 2 and 4 h and again at 10 and 16 h. Peaks in LDH activity were coordinated with DNA replication in a fashion similar to that reported for diploid Chinese hamster cells. Oscillations in LDH activity are more pronounced in normal diploid fibroblasts than in established and neoplastic lines.     

DNA Synthesis and Fos and Jun Protein Expression in Mitotic and Postmitotic WI-38 Fibroblasts in Vitro

Normal human embryonic lung fibroblasts WI-38 differentiate spontaneously along the cell lineage mitotic fibroblasts (MF) I, II, and III and postmitotic fibroblasts (PMF) IV, V, VI, and VII in the fibroblast stem cell system in vitro, when appropriate methods are applied. The mitotic fibroblasts can be induced to shift to postmitotic fibroblasts by two treatments with mitomycin C (2× MMC) in a short period of time compared to spontaneous development. Mitotic and postmitotic fibroblast cell types have specific morphological and biochemical properties, e.g., [³⁵S]methionine polypeptide markers in 2D PAGE. Spontaneously arisen and experimentally induced (2× MMC) PMF have the same morphological and biochemical characteristics. Mitotic fibroblasts have 2n DNA and undergo DNA synthesis for reduplication. Postmitotic cells undergo, on average, two rounds of DNA synthesis for endoreduplication (polyploidization). Spontaneously arisen and experimentally induced postmitotic populations are composed of postmitotic fibroblasts PMF IV, V, and VI with 2n, 4n, and 8n DNA. DNA synthesis of mitotic and postmitotic WI-38 cell populations may be regulated by the expression of Fos and Jun proteins. The Fos level of MFs was higher by a factor of 15-24 and the Jun level of MFs by a factor of 4.2-6.3 than those of spontaneously arisen PMFs. In 2× MMC-induced PMFs, the Fos level was about 4.4-7.5 times higher and the Jun level 1.7-3.3 times higher than that of spontaneously arisen PMFs. The down-regulation of these two parameters is a normal event in the development of mitotic to postmitotic WI-38 fibroblasts in the fibroblast stem cell system and is not related to cellular aging.     

Differences in oxygen-dependent regulation of enzymes between tumor and normal cell systems in culture

Metabolic studies in tumor cells have indicated that bioenergetic regulatory mechanisms geared to acute changes in oxygen availability are abnormal. In the present studies we have examined bioenergetic adaptations to chronic oxygen depletion in culture maintained tumor cells in comparison to normal cell lines. Activities of two key glycolytic enzymes (pyruvate kinase (PyKI) and phosphofructokinase (PFK)) were measured in two tumor cell lines (fibrosarcoma (FS) and Hela) and two normal cell lines (rat lung fibroblasts (RLF) and WI-38) maintained in culture for up to 96 hours under aerobic (PO2 approximately 140) and hypoxic PO2 approximately 15) conditions. Exposure to low O2 tensions for 96 hours resulted in significant increases in PyKi and PFK in both RLF and WI-38, ut did not alter activities of these enzymes in either FS or HeLa cell systems. Activities of two enzymes involved in O2 metabolism (cytochrome oxidase (CyOx) and superoxide dismutase (SOD) were also measured in the two tumor cell lines and in RLF. chronic hypoxia significantly decreased the activities of CyOx and SOD in RLF cell systems but did not alter the activities of these enzymes in the tumor cells. In these studies, the tumor-derived cell lines do not demonstrate specific enzymatic responses to sustained oxygen depletion in vitro noted in normal cell systems, suggesting significant abnormalities in regulatory mechanisms geared to chronic changes in molecular O2.     

Lysosomal enzyme activities and RNA turnover rates in growing and nongrowing WI-38 and HeLa cells

Activities of three lysosomal enzymes--acid RNase. N-acetyl-beta-D-glucosaminidase and acid phosphatase--were determined during the growth cycles of WI-38 and HeLa cells, as well as in radiation-arrested WI-38 cells. In confluent and growth-arrested cultures of WI-38 cells, the lysosomal RNase increased six- to sevenfold; glucosaminidase, four- to fivefold; and phosphatase, two- to threefold. In HeLa cells, the lysosomal enzymes also increased in confluent cultures, but less than twofold; and the RNase level increased only transiently. In both WI-38 and HeLa cells, the rate of RNA breakdown also increased as cultures approached confluency. The rate of turnover of RNA, like the level of acid RNase, was higher in WI-38 cells than in HeLa cells (4 d half-life compared to 8 d). The increase in acid RNase could be prevented by incubation of cells in NH4Cl, but the rate of turnover in the presence of NH4Cl increased just as much when cells became confluent or stopped growth. The content of acid RNase could be changed more than 10-fold without altering the rate of RNA turnover. It is suggested that the increase in enzyme level is more important for possible autophagy or increased digestion of engulfed RNA, rather than for normal RNA turnover, when growth stops.     

The in vitro effects of opines and other compounds on DNAs originating from bacteria, and from healthy and tumorous plant tissues

Purified total DNAs were isolated from oncogenic or nononcogenic Agrobacterium tumefaciens cells as well as from normal and crown gall tissues. Opines (octopine, nopaline, lysopine), plant hormone (auxin IAA) and some carcinogenic compounds were used in order to correlate their effects on in vitro strand separation and synthesis of DNAs with in vivo tumorous cell multiplication. Octopine (or nopaline) induced chain opening of DNAs originating from octopine (or nopaline)-metabolizing bacteria and from same bacteria strain-induced tumorous cells. This phenomenon was measured by the increase in DNA hyperchromicity which is concentration dependent. The tested compounds stimulated the in vitro synthesis of the same DNAs. Under the same conditions, in vitro strand separation and synthesis of healthy plant DNA was not (or only slightly) enhanced, except in the case of particular hormone-connected healthy cell DNA. IAA and carcinogens stimulated in vitro synthesis and induced in vitro strand separation (dose-dependent effect) of DNAs isolated from crown gall cells and inducing bacteria. Compared to healthy cell DNAs, these DNAs were thus susceptible to structurally very diversified molecules and in this way behave as do mammalian tissue DNAs. The opine and IAA actions observed here were specific for plant tissue DNA; cancerous human or animal tissue DNAs were insensitive. By their presence in the crown gall cells, opines possibly maintain destabilized areas (required for rapid growth and division) on tumor cell DNA. The cooperative actions of IAA and opines as well as small RNA and RNA fragments on gene activation, might explain the autonomy of plant tumor cells.     

Synthesis of nuclear acidic proteins in density-inhibited fibroblasts stimulated to proliferate

Previous work from this laboratory (Rovera and Baserga, 1971) has shown that, when density-inhibited WI-38 human diploid fibroblasts are stimulated to proliferate by a change of medium, the synthesis of nuclear acidic proteins increases within 30 minutes after stimulation; several hours before DNA synthesis begins to increase. Similar results have now been obtained with density-inhibited 3T6 mouse fibroblasts, also stimulated by a change of medium. Gel electrophoretic analysis of nuclear acidic proteins in both WI-38 human diploid fibroblasts and 3T6 mouse fibroblasts stimulated to proliferate indicates that the increased synthesis of nuclear acidic proteins is limited to certain classes of proteins while other classes are totally unaffected. The increase in nuclear acidic proteins synthesis is inhibited when WI-38 cells or 3T6 cells are stimulated in the presence of 5-azacytidine (10 μg/ml), a treatment which also inhibits the subsequent stimulation of DNA synthesis. These results, confirming and extending similar findings previously reported in other models of stimulated DNA synthesis, lend further support to the hypothesis that nuclear acidic proteins may play a critical role in the control of DNA synthesis and cell division in mammalian cells.     

DNA hypermethylation in sodium butyrate-treated WI-38 fibroblasts

Sodium butyrate is very often used to alter gene expression in cultured cells. In this study, we examined the effects of this compound on various cellular events in WI-38 human embryonic lung fibroblasts in culture. During a 16-20-h treatment at sodium butyrate concentrations of between 5 and 20 mM, no adverse effects on cell morphology were observed. However, cell division and DNA synthesis were reversibly inhibited, the latter by 85, 80, and 70% at sodium butyrate concentrations of 5, 10, and 20 mM, respectively. Although overall protein synthetic activity was not significantly affected, RNA synthesis decreased to 76% of the control values at a sodium butyrate concentration of 5 mM. Butyrate treatment also caused hypermethylation of DNA cytosines as determined by differential digestion by MspI/HpaII restriction endonucleases and by high performance liquid chromatography analysis of the DNA. The 5-methylcytosine content of the DNA in untreated WI-38 fibroblasts was 2.94 +/- 0.46% of total cytosine residues, while in cultures treated with 5, 10, and 20 mM sodium butyrate, these values were 5.76 +/- 0.28, 5.91 +/- 0.37, and 6.8 +/- 0.44%, respectively. An interesting feature is that this hypermethylation occurred in DNA which was synthesized in the presence of sodium butyrate (newly synthesized) as well as in DNA which had been synthesized before butyrate administration (pre-existing DNA). The hypermethylated state was conserved only in the former situation, since the methylcytosines were rapidly lost in the subsequent generation in the latter case. It would therefore appear that methylcytosines are maintained after cell replication only if they are generated on newly synthesized DNA.