Characterization of the growth responses of hamster fibroblasts and chondrogenic cells to fibroblast growth factor

The effects of fibroblast growth factor (FGF) on hamster dermal fibroblasts and chondrogenic cells, both of mesodermal origin, were compared with special reference to growth stimulation and morphological changes in monolayer cultures, and colony formation in semisolid medium. FGF (10 to 200 ng/ml) caused appreciable cell proliferation of dermal fibroblasts but not of chondrogenic cells, while FGF (50-200 ng/ml) caused very marked dose-dependent morphological changes in monolayer cultures and colony formation in semisolid medium of both fibroblasts and chondrogenic cells. It is suggested that FGF is the same type of growth factor as the transforming growth factor(s) because, like the latter, it induces drastic morphological changes of normal mesodermal cells in monolayer cultures and their colony formation in semisolid medium.     

Effect of placental factors on growth and function of the human fetal adrenal in vitro

Conditioned medium from human placental monolayer cultures (PM) had a marked stimulatory effect on proliferation (3H-thymidine uptake) of human fetal zone adrenal cells in primary monolayer culture, even in the absence of serum. Epidermal growth factor (EGF) and fibroblast growth factor (FGF) also significantly stimulated fetal adrenal cell growth. However, the effects of PM differed from those of EGF and FGF in several respects: 1) maximal response to PM was 2-5 times greater; 2) mitogenic effects of EGF and FGF were suppressed by adrenocorticotropic hormone (ACTH), whereas that of 50% PM was not; 3) PM inhibited ACTH-stimulated steroidogenesis (dehydroepiandrosterone sulfate and cortisol), but EGF and FGF did not. Preliminary characterization studies have indicated that approximately half of the placental growth-promoting activity is heat resistant and sensitive to bacterial proteases, and that 50-60% of the activity is lost after dialysis with membranes having a molecular weight cutoff of 3500. These findings suggest a role for the placenta in the growth and differentiated function of the human fetal adrenal gland.     

Epidermal growth factor induces cell cycle arrest and apoptosis of squamous carcinoma cells through reduction of cell adhesion

Most squamous epithelial cells are strictly anchorage-dependent cell types. We observed that epidermal growth factor (EGF) promoted the growth of A431 squamous carcinoma cells in suspension cultures but suppressed cell growth and induced apoptosis in monolayer cultures, suggesting that loss of adhesion is responsible for the effects observed in monolayer culture, before cell death. Consistent with this finding, we demonstrated that EGF reduced cell attachment, cell-cell interaction, and cell spreading. Treatment with EGF increased cell adhesion-regulated expression of p21 but suppressed expressions of cyclin A, D1, cdk2, and retinoblastoma protein (pRb), leading to cell cycle arrest and adhesion-regulated programmed cell death. To test directly whether promoting cell adhesion could reduce the effects of EGF, we grew cultures on plates coated with type II collagen. On these plates, cell adhesion was enhanced and EGF treatment had little effect on cell adhesion and apoptosis when cells were attached to the collagen. The collagen effects were dose dependent, and cell cycle and cell cycle-associated proteins were altered accordingly. Finally, when cultures were plated on bacterial Petri dishes, which completely disrupted cell attachment to substratum, the level of apoptosis was greatly higher and cell cycle was arrested as compared with monolayer cultures. Taken together, our results strongly suggest that the EGF-induced cell cycle arrest and apoptosis in monolayer cultures was the result of a decline in cell adhesion.     

Growth and differentiation of alveolar bone cells in tissue-engineered constructs and monolayer cultures

The ability to enhance bone regeneration by implanting autologous osteoblasts in combination with an appropriate scaffold would be of great clinical interest. The aim of our study was to compare the growth and differentiation of alveolar bone cells in tissue-engineered constructs and in monolayer cultures, as the basis for developing procedures for routine preparation of bone-like tissue constructs. Alveolar bone tissue was obtained from four human donors and explant cultures of the cells were established. Expanded cells were seeded on macroporous hydroxyapatite granules, and cultured in medium supplemented with osteogenic differentiation factors for up to 3 weeks. Control monolayer cultures were established in parallel, and cultured in media with or without osteogenic supplements. Cell proliferation, alkaline phosphatase (AP) activity and gene expression of AP, osteopontin and osteocalcin were determined under different culture conditions at weekly intervals. Cells in tissue constructs exhibited growth patterns similar to those in control monolayer cultures: enhanced proliferation was noted during the first 2 weeks of cultivation, followed by a decrease in cell numbers. AP activity at 3 weeks was higher in all cultures in osteogenic medium than in control medium. Gene expression levels were stable in monolayer cultures in both types of media whereas, in tissue constructs, they exhibited patterns of osteogenic differentiation. Light and scanning electron microscopy examination of the cell-seeded constructs showed uniform cell distribution, as well as cell attachment and growth into the interior region of the hydroxyapatite granules. Our results show that bone-like constructs with viable cells exhibiting differentiated phenotype can be prepared by cultivation of alveolar-bone cells on the tested hydroxyapatite granules.     

Decreased level of PDGF-stimulated receptor autophosphorylation by fibroblasts in mechanically relaxed collagen matrices

The goal of our studies was to characterize the interrelationship between extracellular matrix organization and fibroblast proliferation in response to growth factors. We compared fibroblasts in monolayer culture with cells in contracted collagen matrices that were mechanically stressed or relaxed. In response to platelet-derived growth factor (PDGF), DNA synthesis by fibroblasts in mechanically relaxed collagen matrices was 80-90% lower than in monolayer culture and 50% lower than in mechanically stressed matrices. Fibroblasts in monolayer and contracted collagen matrix cultures contained similar levels of PDGF receptors, but differed in their autophosphorylation response. Cells in mechanically relaxed matrices showed lowest levels of autophosphorylation, 90% less than cells in monolayer culture. Experiments comparing receptor expression and capacity for PDGF- stimulated autophosphorylation showed that cells in mechanically relaxed collagen matrices never developed normal receptor autophosphorylation. Furthermore, when mechanically stressed collagen matrices were switched to mechanically relaxed conditions, capacity for receptor autophosphorylation decreased within 1-2 h and remained low. Based on immunomicroscopic observations and studies on down-regulation of receptors by PDGF binding, it appeared that most PDGF receptors in monolayer or contracted collagen matrix cultures were localized on the cell surface and accessible to PDGF binding. In related studies, we found that EGF receptors of fibroblasts in mechanically relaxed collagen matrices also showed low levels of autophosphorylation in response to EGF treatment. Based on these results, we suggest that mechanical interactions between cells and their surrounding matrix provide regulatory signals that modulate autophosphorylation of growth factor receptors and cell proliferation.     

Growth factor impact on articular cartilage subpopulations

We have examined the effects of growth factor stimulation on superficial and growth zone chondrocyte populations. Zonal articular chondrocytes from 8-month-old Spanish goat distal femurs were plated in monolayer cultures and stimulated by using insulin-like growth factor I (IGF-I), basic fibroblast growth factor (bFGF), and transforming growth factor-β1 (TGF-β1). Gene expression for collagen I and II, aggrecan, and superficial zone protein were evaluated every week for 3 weeks. Finally, proteoglycan and collagen deposition were measured for each experimental group. Major differences existed in the behavior of superficial and growth zone chondrocytes, the most apparent being the higher capacity for protein synthesis by the growth zone population. Variations also existed regarding growth factor treatment. TGF-β1 had the greatest effect on proliferation over 8 days. With respect to differentiation, IGF-I increased average collagen II gene expression in the growth zone populations in comparison with growth zone controls. IGF-I increased aggrecan gene expression for the same groups. Superficial zone populations exhibited lower collagen II, collagen I, and aggrecan gene expression than the growth zone populations under all conditions. However, superficial zone protein expression was dramatically elevated in superficial zone populations by TGF-β1. Collagen I expression showed a general increase under all conditions compared with initial values. Combined biosynthesis results showed that the superficial populations secreted little to no collagen, especially collagen II, in comparison with their growth zone counterparts. Glycosaminoglycan production was also much lower than for the growth zone groups. TGF-β1 and IGF-I increased collagen II production in the growth zone populations. TGF-β1 increased glycosaminoglycan secretions in the superficial zone populations and in the growth zone populations, whereas IGF-I produced an increase in glycosaminoglycan secretion only in the growth zone populations. Thus, growth factors elicit different proliferation, gene expression, and biosynthesis responses from zonal chondrocyte subpopulations.     

Growth of Fish Cell Lines on Microcarriers

Microcarrier beads were evaluated as substrates for the propagation of five anchorage-dependent fish cell lines. Growth of rainbow trout gonad (RTG-2) and Atlantic salmon cells was limited on microcarriers maintained in suspension. However, stationary microcarriers were suitable substrates for the growth of RTG-2, AS, Chinook salmon embryo (CHSE-214), and fathead minnow cells. Cell yields ranged from 2 × 10⁶ to 2.9 × 10⁶ cells per ml, representing 7- to 10-fold increases over the initial cell concentrations. The yield of new RTG-2 cells per unit volume of growth medium was 2.8 times greater in microcarrier cultures than in standard monolayer cultures. Northern pike cells failed to grow on microcarriers. Yields of infectious pancreatic necrosis virus propagated in microcarrier cultures of RTG-2 cells were more than twice the yields in standard monolayer cultures. The greater economy of microcarrier cultures in terms of growth vessel and medium requirements holds great promise for the large-scale production of anchorage-dependent fish cell cultures and fish viruses.     

The relationship of the saturation density of multilayer cell cultures to their mass exchange with the medium

Chinese hamster fibroblasts (CHF) and NIH 3T3 cells were cultured on a glass substrate at different distances from the porous membrane separating the cells from the perfusing medium. It is shown that with perfusion of medium above the membrane there is no movement of the medium near the cells. In both the types of culture, the cells grow in multilayers, however the multilayer character of growth in CHF is more pronounced than in NIH 3T3 cells. The saturation density of the cultures depends on the cell-membrane separation, and at separations of no more than 0.2 mm exceeds the saturation density in the monolayer by 8-10 fold. The dependences of the saturation density on separation are different for CHE and NIH 3T3 cells, indicating qualitative differences in the inhibition of cell growth in monolayers between these cultures. The results obtained indicate that the inhibition of cell growth in monolayer is due to mass exchange limitations, rather than to intercellular contact interactions.     

Transforming growth factor beta1 induces differentiation in human papillomavirus-positive keratinocytes.

Human papillomaviruses (HPVs) are implicated in the etiology of anogenital cancers. Expression of the HPV E6 and E7 oncoproteins is believed to contribute to the carcinogenic process. Progressive loss of the ability to differentiate and resistance to the growth-inhibitory effects of endogenous signals also appear important in multistep tumorigenesis. Transforming growth factor beta1 (TGF-beta1) is a potent growth inhibitor for a variety of cultured cells. There have been conflicting reports on the ability of TGF-beta1 to inhibit the growth of HPV-positive keratinocytes in monolayer cultures. We have employed the organotypic (raft) tissue culture system, which more accurately mimics the in vivo cellular environment and architecture. We have investigated the TGF-beta1 response of HPV-positive keratinocytes derived from neoplastic cervical biopsies. Growth of these cell lines as raft tissues showed that many were altered in the ability to stratify and synthesize differentiation-specific proteins. When the organotypic tissues were treated with TGF-beta1, a more complete differentiation of the keratinocytes was induced. Treatment with 12-0-tetradecanoylphorbol-13-acetate gave similar results. TGF-beta1 treatment of HPV-positive raft epithelia led to a dose-dependent increase in E7 RNA expression in contrast to results from previous studies with monolayer cultures. Furthermore, TGF-beta1 interfered with the proliferation of HPV-positive cell lines grown in monolayer cultures. Our results suggest that loss of the ability to express markers of differentiation, a characteristic of malignancy, is a two-step process. The first step is reversible; the second is irreversible.     

The radiation response of a human colon adenocarcinoma grown in monolayer, as spheroids, and in nude mice

A human colon adenocarcinoma cell line, WiDr, has been grown in monolayer, as multicellular spheroids, and as xenografted tumors in immune-deprived mice. The growth and radiation responses of the cells under these different growth conditions were compared. The mean doubling time of monolayer cultures was 0.8 day and the initial volume doubling times of spheroids and xenografts averaged 1.2 and 6 days, respectively. The mean total viable cell plating efficiencies were 82, 63, and 7% for cells from monolayers, spheroids, and xenografted tumors, respectively. The radiation responses of single cell suspensions prepared from WiDr tumors (8-10 mm in diameter), exponentially growing monolayer cultures (5 days growth), and spheroids (1200 microns in diameter) irradiated in air at 4 degrees C were similar. Values for D0 were 1.5 Gy and for n between 3 and 5. Nitrogen curves were characterized by a D0 of 5 Gy and n between 3 and 6. Oxygen enhancement ratios were approximately 3.3. Both spheroids and tumors had radioresistant components to the 37 degrees C/air-breathing survival curves with estimated hypoxic fractions of 8 and 12%, respectively. The final portion of the survival curves for irradiations in nitrogen and under normal growth conditions were parallel for both tumors and spheroids. Thus WiDr spheroids appear to model accurately the radiation sensitivity of WiDr tumors.     

Changes in protein content per cell during growth of mouse L cells

The relationship between cell density and protein content per cell was examined in monolayer and suspension cultures of mouse L cells. In monolayer cultures, the protein content per cell reached a maximum at 6 h after plating and retained this level for 18 h. Thereafter, the protein content per cell declined gradually during the exponential growth phase and finally returned to the initial level at the stationary phase. The changes were neither due to the effect of trypsinization nor to the exhaustion of the medium. The protein content per cell in a sparse culture was always greater than that in a dense culture for monolayer culture of L cells. In suspension culture the increase of protein content per cell during the lag phase was similar to that found in monolayer cultures. However, the gradual decline of protein content per cell observed during the exponential phase of monolayer cultures was not detected during that of a suspension culture. The results suggest that the decrease of protein content per cell in monolayer cultures may be related to some function of cell plasma membrane which could be inhibited by a cell-to-cell contact.     

Growth limitation of BHK-21 cells and its relation to folate metabolism

Summary The role of folate metabolism in growth control in monolayer and suspension cell cultures was studied in three related cell lines: BHK-21, polyoma-transformed BHK-21 (PyBHK), and an aminopterin-resistant derivative of BHK-21 (A5). BHK-21 cells had extremely low levels of dihydrofolate reductase, PyBHK had higher levels, and A5 had extremely high levels. Hypoxanthine and thymidine together, but not individually, induced BHK-21 to grow in agar, and stimulated its growth in agarose and monolayer culture. PyBHK and A5 grew spontaneously in agar, and hypoxanthine plus thymidine had little or no effect on their growth either in suspension or in monolayer cultures. We found that exogenous folinic acid, a derivative of folate metabolism that bypasses the function of dihydrofolate reductase, mimicked the gowth-stimulatory effects of exogenous hypoxanthine plus thymidine BHK-21. We conclude that the growth limination of BHK-21 in suspension culture is due, in part, to a deficiency of dihydrofolate reductase. This enzyme deficiency limits nucleoside synthesis and can be overcome by supplying end products of this pathway. This research was sponsored by NCI Contract No. N0-1-CP-2-3234, DHEW and by USPHS Medical Scientist Training Grant GM 02042-07.     

Method of total staining of monolayer cell cultures using vanadium hematoxylin]

Original method of cytological staining for monolayer cell cultures and outgrowth zone of tissue explants with vanadium hematoxylin is described. This staining method is simple, universal, reproducible and give opportunity to stain rapidly practically all cellular elements of cultivated monolayer with high degree of cytological resolution of intracellular structures (nucleus, cytoplasmic organelles etc.).     

Regulation of Collagen Synthesis in Human Dermal Fibroblasts in Contracted Collagen Gels by Ascorbic Acid, Growth Factors, and Inhibitors of Lipid Peroxidation

Ascorbic acid has been shown to stimulate collagen synthesis in monolayer cultures of human dermal fibroblasts. In the present studies, we examined whether the presence of a collagen matrix influences this response of dermal fibroblasts to ascorbic acid. Fibroblasts and collagen were mixed and allowed to gel and contract for 6 days to form a matrix prior to determining the concentration and time dependence for ascorbic acid to affect collagen synthesis by fibroblasts within the matrix. Collagen synthesis was stimulated at levels at or above 10 μM ascorbic acid and was maximal after 2 days of treatment. This concentration and time dependence is similar to that of cells grown in monolayer cultures. The effects of transforming growth factor-β (TGF-β) and fibroblast growth factor (FGF) were also examined in this model. TGF-β increased and FGF inhibited collagen synthesis in the gels, as has been shown for cells in monolayer cultures. The effects of potential inhibitors of lipid peroxidation induced by ascorbic acid were also examined in these matrices and compared to previous results obtained in monolayer cultures. Propyl gallate, cobalt chloride, α,α-dipyridyl, and α-tocopherol inhibited the ascorbic acid-mediated stimulation of collagen synthesis while mannitol had no effect. Natural retinoids inhibited total protein synthesis without the specific effect on collagen synthesis that was seen in monolayer cultures. These results indicate that ascorbic acid stimulates collagen synthesis in fibroblasts grown in a collagen matrix in a manner similar to that found in monolayer cultures. In contracting collagen gels, however, the magnitude of the effect is less and retinoids do not specifically inhibit collagen synthesis.     

Immunocytochemical and Biochemical Analysis of Carbonic Anhydrase in Primary Astrocyte Cultures from Rat Brain

Carbonic anhydrase (CA) was studied in primary monolayer cultures from neonatal rat cerebral hemispheres with both immunocytochemical and biochemical techniques. In such cultures, which consist predominantly of astrocytes, immunocytochemical staining for CA using antibody raised against the type II enzyme from rat erythrocytes resulted in positive staining of the flat, glial fibrillary acidic protein-positive, astrocytic monolayer. Smaller, process-bearing, round cells that grew on top of the astrocytes stained intensely for CA. We estimated that these cells represented 1% or less of the total cells in the cultures, and they have been identified by others as oligodendrocytes. The intensity of the staining of astrocytes for CA could be increased to that observed in oligodendrocytes when the astrocytes were made to round up and form processes by treatment with 2',3'-dibutyryl cyclic AMP. Enzymatic assays showed that CA activity of the cultures after 3 weeks of growth was 2.5- to 5-fold less than that found for cerebral homogenates from perfused 3-week-old rat brains. However, both activities were totally inhibited by acetazolamide with an I50 of 10(-8) M, confirming that both rat brain and the astrocyte cultures possess the high-activity type II enzyme. CA-II activity was unaffected by treatment of the cultures with a method reported to remove oligodendrocytes. Thus, the immunocytochemical and biochemical studies reported here demonstrate that astroglial cells in primary cultures from neonatal rat brain contain CA-II.     

Enhanced rates of fluid pinocytosis during exponential growth and monolayer regeneration by cultured arterial endothelial cells

Rates of fluid pinocytosis by bovine aortic endothelial cells were measured during various manipulations of growth status in vitro. Sparsely seeded cultures grew exponentially until a confluent monolayer was formed, at which time growth slowed. This change in growth rate coincided with a decline in the rate of pinocytosis to about one-third that in the growing cultures. During the subsequent attainment of maximal cell density in the confluent monolayer, the pinocytic rate remained constant. There was close correlation between ³H-thymidine labelling indices, as measured by autoradiography, and the rates of pinocytosis. Mechanical “wounding” of the confluent monolayer resulted in cell migration and proliferation. Twenty-four hours after “wounding,” rates of pinocytosis per mg. cell protein were significantly enhanced. When regeneration of the monolayer was blocked by cytochalasin B, pinocytosis remained at the same rate as in the uninjured, confluent monolayer. These experiments support, and extend to endothelium, earlier observations that in growing cells pinocytosis proceeds at a higher rate than in non-growing, quiescent cells. Furthermore, they raise the possibility that the transendothelial transport of macromolecules such as lipoproteins by receptor-in-dependent fluid pinocytosis in vivo may be altered by the growth status of the endothelium.     

Human three-dimensional fibroblast cultures express angiogenic activity

Human neonatal fibroblasts were cultured on a lactate-glycollate copolymer scaffold for 12-16 days to form a three-dimensional dermal equivalent tissue. The cellular content of vascular endothelial growth factor (VEGF) mRNA in these three-dimensional cultures was 22-fold greater than that observed in the same fibroblasts grown as monolayers. No induction was shown by hepatocyte growth factor (HGF) or angiopoietin 1 indicating that the effect was specific to VEGF. The predominant VEGF splice variant, detected by RT-PCR corresponded to the 121 amino acid form, with less of the 165 amino acid form. The cell-associated forms (189 and 206 amino acids) comprised less than 1% of the total VEGF mRNA. VEGF and HGF proteins, determined by ELISA, were secreted in physiologically significant amounts, 0.5-4 ng per 24 h/10(6) cells. Conditioned medium from the three-dimensional cultures stimulated proliferation of endothelial cells in a dose-dependent manner and induced cellular expression of integrin alpha(v)beta(3). Conditioned medium from the same dermal fibroblasts cultured in monolayer showed little angiogenic activity in any of these assays. Using the chorioallantoic membrane (CAM) angiogenesis assay, the cultures stimulated blood vessel production 2.8-fold over scaffold alone. VEGF-neutralizing antibody reduced the vessel development in the CAM to the level in the scaffold control. Anti-HGF antibody had no significant effect. In conclusion, three-dimensional cultures of dermal equivalent tissue express angiogenic activity to a greater extent than monolayer cultures, some of which can be assigned to VEGF.     

Transdifferentiation of "lentoid" structures in cultures derived from pigmented epithelium was inhibited by collagen.

Cells from pigmented retina of 8- to 9-day-old chick embryos were cultured under two different conditions: on noncoated (NS) or collagen-coated (CS) substrates. Although cells on CS seemed to start dividing 2 to 3 days earlier than those on NS, their early growth rates were basically similar. Cells on CS stopped growing after attaining confluency and formed a monolayer, while cells on NS continued to grow after confluency and overlapped each other. In early growth phase, cells on both substrates became depigmented. Cells became repigmented earlier on CS than on NS. The average melanin content of cells in confluent cultures on CS was two to three times higher than that of cells on NS. By Day 30 “lentoid bodies” were formed only in cultures on NS. Immunoelectrophoretic tests showed the presence of all crystallins (α-, β-, and δ) in cultures on NS but not in cultures on CS. It is concluded that a collagen substrate inhibits “transdifferentiation” of pigmented retinal cells into lens during cell culture.