Behavior of primary and serially transplanted estrogen-dependent renal carcinoma cells in monolayer and in collagen gel culture

Summary When estrogen is present in culture medium, enzyme-dissociated cells from estrogen-induced primary renal tumors in Syrian hamsters and from 1st to 4th serially transplanted carcinomas in monolayer culture contain progesterone receptor levels that are similar and comparable to those in tumors in vivo (i.e., 2 pmol/3×10⁶ cells). Despite the similarity of receptor levels in cultured cells isolated from primary and transplanted tumors, the ability of cells to be maintained in culture differs considerably from one tumor stage to another. When cultured as monolayers in plastic flasks, isolated cells from primary tumors exhibit a marked decline in cell number after 4 to 6 d in culture. On the other hand, monolayer-cultured cells from first and second transplantation tumors remain essentially constant in cell number over a 2 wk culture period and cells from third transplantation tumors undergo a two- to threefold increase in cell number during 2 wk in culture. When primary tumor cells are cultured in collagen gels, the decline in cell number over a 2 wk culture period is prevented and progesterone receptor levels remain elevated. Cells cultured from first transplantation tumors exhibit a delayed decline in cell number beginning after 2 wk in monolayer culture. The decline in cell number in monolayer culture, like that for cells from primary tumors, can be prevented by culturing cells from first transplantation tumors in collagen gels. Neither cells from primary nor first transplantation tumors exhibit significant increases in cell number in collagen gels. Increasing the serum concentration of growth medium to 30% does not stimulate growth of cells under these conditions. Cells isolated from fourth transplantation tumors undergo a fourfold increase in cell number over a 1 month culture period whether cells are cultured as monolayers or in collagen gels. This investigation was supported by Grant CA 22008 awarded by the National Cancer Institute, Department of Health, Education and Welfare, and by institutional research funds from Marquette University.     

Enamel protein and collagen production by cells subcultured from porcine tooth bud explants

Fibroblast (F) and epithelial (E) cells were obtained as primary outgrowths from explants of fetal porcine maxillary molars and subcultured up to four passages in monolayers enriched with either cell type. Histology of a tooth bud after 1 day in culture showed intact odontogenic E cell layers which were the probable source of the E cell outgrowths. After 2 months in culture, the fourth passage E cells demonstrated morphological differentiation by an alteration in cell packing and the formation of domes and nodules, when E and F cells were cocultured. Occasionally the nodules grew to considerable size, indicating the potential of these cells to aggregate and reorganize into odontogenic tissues even on culture dishes. The cells were characterized in monolayer culture by immunocytochemical staining. Laminin and type IV collagen staining was distributed diffusely throughout the culture, whereas type I collagen and osteonectin staining was predominantly localized in the F cells. Radiolabelled proteins from both E and F cell media produced similar collagen patterns (95% type I, 4% type V, 1% other), except that the F cells appeared to produce active collagenase. In addition, the E cells produced two radiolabelled proteins (relative masses of 50,000 and 53,000) that reacted with an affinity-purified antibody directed against porcine amelogenin. These experiments show that cells subcultured from tooth buds and grown in monolayer cultures can be used to study tooth organogenesis in vitro, as well as enamel protein biosynthesis.     

Activation of type I collagen genes in cultured scleroderma fibroblasts

Fibroblasts cultured from affected skin areas of five patients with cutaneous scleroderma were found to produce increased amounts of collagen when compared with nonaffected control cells. Total RNA was isolated from the cultures and analyzed for its level of pro alpha 1 (I)collagen mRNA by hybridization of RNA blots with a cloned cDNA probe. The levels of pro alpha 1 (I)collagen mRNAs relative to total RNA were two- to sixfold higher in the samples from affected cells, accounting for the increased synthesis of type I collagen. Cytoplasmic dot hybridizations were performed to measure the cellular content of pro alpha 1 (I)collagen mRNA: up to ninefold increases in the level of this mRNA per cell were found. Upon subculturing, scleroderma fibroblasts were found to reduce gradually the increased synthesis of collagen to the level of nonaffected controls by the tenth passage. The levels of type I collagen mRNAs were also reduced, but more slowly. The results suggest that in scleroderma fibroblasts the genes for type I collagen are activated at procollagen mRNA level or that they are more stable and that the activating factors are lost during prolonged cell culture because cells from affected areas lose their activated state.     

Procollagen mRNA metabolism during the fibroblast cell cycle and its synthesis in transformed cells.

Procollagen mRNA was isolated from mouse embryos and used for the synthesis of a highly labelled cDNA probe complementary to collagen mRNA. This probe was used for the investigation of procollagen mRNA metabolism during the cell cycle of 3T6 mouse embryo fibroblasts in culture. Titration hybridization experiments revealed that procollagen mRNA was present throughout the cell cycle following stumulation of confluent monolayers. Procollagen mRNA levels of sparse cultures appeared similar to those of unstimulated monolayers. The fluctuating levels of collagen synthesis during the cell cycle can be ascribed to changes in the amount of collagen mRNA present. In mouse sarcoma virus transformed 3T3 cells only 20--30% of the amount of procollagen mRNA in 3T3 cells is present indicating that the decline in collagen synthesis is due to mRNA availability.     

Osteogenic differentiation of human periosteal-derived cells in a three-dimensional collagen scaffold

This study examined the osteogenic differentiation of cultured human periosteal-derived cells grown in a three dimensional collagen-based scaffold. Periosteal explants with the appropriate dimensions were harvested from the mandible during surgical extraction of lower impacted third molar. Periosteal-derived cells were introduced into cell culture. After passage 3, the cells were divided into two groups and cultured for 28 days. In one group, the cells were cultured in two-dimensional culture dishes with osteogenic inductive medium containing dexamethasone, ascorbic acid, and β-glycerophosphate. In the other group, the cells were seeded onto a three-dimensional collagen scaffold and cultured under the same conditions. We examined the bioactivity of alkaline phosphatase (ALP), the RT-PCR analysis for ALP and osteocalcin, and measurements of the calcium content in the periosteal-derived cells of two groups. Periosteal-derived cells were successfully differentiated into osteoblasts in the collagen-based scaffold. The ALP activity in the periosteal-derived cells was appreciably higher in the three-dimensional collagen scaffolds than in the two-dimensional culture dishes. The levels of ALP and osteocalcin mRNA in the periosteal-derived cells was also higher in the three-dimensional collagen scaffolds than in the two-dimensional culture dishes. The calcium level in the periosteal-derived cells seeded onto three-dimensional collagen scaffolds showed a 5.92-fold increase on day 7, 3.28-fold increase on day 14, 4.15-fold increase on day 21, and 2.91-fold increase on day 28, respectively, compared with that observed in two-dimensional culture dishes. These results suggest that periosteal-derived cells have good osteogenic capacity in a three-dimensional collagen scaffold, which provides a suitable environment for the osteoblastic differentiation of these cells.     

Specific growth factors during the expansion and redifferentiation of adult human articular chondrocytes enhance chondrogenesis and cartilaginous tissue formation in vitro

Adult human articular chondrocytes were expanded in a medium with 10% serum (CTR) or further supplemented with different mitogens (i.e., EGF, PDGFbb, FGF-2, TGF beta 1, or FGF-2/TGF beta 1). Cells were then induced to redifferentiate in 3D pellets using serum-supplemented medium (SSM), serum-free medium (SFM), or SFM supplemented with factors inducing differentiation of chondroprogenitor cells (i.e., TGF beta 1 and/or dexamethasone). All factors tested during expansion enhanced chondrocyte proliferation and dedifferentiation, as assessed by the mRNA ratios of collagen type II to type I (CII/CI) and aggrecan to versican (Agg/Ver), using real-time PCR. FGF-2/TGF beta 1-expanded chondrocytes displayed the lowest doubling times, CII/CI and Agg/Ver ratios, averaging, respectively, 50, 0.2 and 15% of CTR-expanded cells. Redifferentiation in pellets was more efficient in SFM than SSM only for EGF-, PDGFbb- or FGF-2-expanded chondrocytes. Upon supplementation of SFM with TGF beta and dexamethasone (SFM TD), CII/CI ratios decreased 4.4-fold for EGF- and PDGFbb-expanded chondrocytes, but increased 96-fold for FGF-2/TGF beta 1-expanded cells. Chondrocytes expanded with FGF-2/TGF beta 1 and redifferentiated in SFM TD expressed the largest mRNA amounts of CII and aggrecan and generated cartilaginous tissues with the highest accumulation of glycosaminoglycans and collagen type II. Our results provide evidence that growth factors during chondrocyte expansion not only influence cell proliferation and differentiation, but also the cell potential to redifferentiate and respond to regulatory molecules upon transfer into a 3D environment.     

Production of glycosaminoglycans by human skin fibroblasts growing in a collagen lattice.

Production of glycosaminoglycans (GAG) by human skin fibroblasts cultured in collagen lattices closely resembled that already described for the same cells grown as monolayers on plastic. There was no inhibition of GAG corresponding to that of DNA and protein synthesis and similar controls by cell density and anti-inflammatory drugs operated in 3-dimensional as in 2-dimensional culture. The bulk of the GAG synthesised in lattice culture was hyaluronic acid, as in monolayers.     

Temperature-dependent enhancement of cell proliferation and mRNA expression for type I collagen and HSP70 in primary cultured goldfish cells

Goldfish (Carasius auratus) primary culture cells derived from caudal fin were incubated over a temperature range of 20-35 degrees C. The population doubling time of cells cultured at 20, 25, 30 and 35 degrees C were 34, 29, 17 and 14 h, respectively. Interestingly, cDNA-representational difference analysis revealed type I collagen alpha chain (colalpha(I)) as a candidate for a warm temperature-specific gene. mRNA levels of colalpha(I) increased with an increase of incubation temperature and days of culture. Furthermore, the cell growth rate and colalpha(I) mRNA levels were rapidly changed following temperature shifts. To examine the effects of culture temperature shift on the cellular physiological states, mRNA levels of HSP70 were additionally investigated. HSP70 mRNA levels in the cells cultured at 30 and 35 degrees C were again 2-3 times higher than those at 20 and 25 degrees C. When the culture temperature was shifted from 20 to 35 degrees C, HSP70 mRNA levels were rapidly increased within 1 h. Subsequently, mRNA levels of the 35 degrees C-treated cells decreased, but remained doubled compared with those of the 20 degrees C-treated cells, even 4 h following the temperature shift. When the culture temperature was lowered from 35 to 20 degrees C, HSP70 mRNA levels decreased to about 70% of the original levels in 4 h. These results indicate that goldfish cells cultured at different temperatures easily develop temperature-associated steady physiological states within 4 h of temperature shifts.     

Attenuation of collagen arthritis and modulation of delayed-type hypersensitivity by type II collagen reactive T-cell lines

T-cell lines were established from the lymph node cells of syngeneic Louvain (LOU) rats previously immunized with native chick type II collagen (CII) emulsified in incomplete Freund's adjuvant. The CII lines proliferated in vitro to type II collagen but not to type I collagen, ovalbumin (OV), or PPD. Control lines, developed from LOU rats immunized with OV emulsified in complete Freund's adjuvant, were OV specific because they did not respond to other antigens in vitro. CII line cells could adoptively transfer delayed-type hypersensitivity (DTH) but did not induce IgG antibody production to collagen. Moreover, the intravenous administration of 2 X 10(7) CII line cells prevented the subsequent induction of collagen arthritis following immunization and suppressed DTH to collagen without affecting antibody responses in the recipients. Spleen cells, but not sera, from these resistant rats decreased CII line reactivity in vitro. OV or irradiated CII lines had no effect on clinical or immunologic parameters in this model. These findings demonstrate protection from arthritis afforded by T-cell line transfer and suggest that the phenomenon results from down-regulation of the recipients' cellular immunity to collagen.     

Synergistic effect of tumor necrosis factor-alpha and interferon-gamma on collagen synthesis of human skin fibroblasts in vitro

The effect of tumor necrosis factor-alpha (TNF alpha) and interferon-gamma (IFN gamma) on collagen metabolism by human diploid fibroblasts in confluent monolayer culture was examined. Recombinant TNF alpha reduced collagen mRNA levels 2-fold and stimulated collagenase mRNA levels 5-fold, while recombinant IFN gamma affected only collagen mRNA levels. The combination of TNF alpha (10 ng/ml) and IFN gamma (100 ng/ml) resulted in a much stronger (about 30-fold) reduction of collagen mRNA levels indicating that the two cytokines act synergistically. In contrast no such synergism was observed with respect to collagenase mRNA levels. The effect of TNF alpha and IFN gamma on collagen metabolism reported here indicates a complex interaction of different cytokines in the control of tissue remodeling that occurs during inflammation, repair, or atrophy.     

Regulation of collagen synthesis in fibroblasts within a three-dimensional collagen gel

Fibroblasts cultivated within a three-dimensional collagen gel display an elongated, spindle-like morphology, reduce their proliferation rate, contact the gel to a very dense tissue, and modify their metabolic activity as compared to monolayer cultures. Collagen synthesis measured as protein-bound hydroxyproline is reduced to 5% of the values found in monolayer culture. The reduction involving type I and type III collagen is due to decreased de novo synthesis and not to enhanced degradation. Dot blot hybridization, Northern blot analysis, and in situ hybridization using collagen I- and III-specific cDNA probes demonstrate that reduced biosynthesis rates are reflected by a marked reduction of pro alpha 1 (I), pro alpha 2 (I), and pro alpha 1 (III) collagen mRNA indicating pretranslational regulation. A similar reduction was observed for actin mRNA whereas levels of tubulin mRNA were similar for fibroblasts in monolayer culture or cultivated within the three-dimensional collagen gels. The data suggest a specific reprogramming of various cellular activities in response to contact with the reconstituted extracellular matrix.     

A comparison of the effects of different substrata on chondrocyte morphology and the synthesis of collagen types IX and X

Summary Embryonic chick sternal chondrocytes were cultured either within three dimensional gels of type I collagen, type II collagen or agar, or as monolayers on plastic dishes coated with air-dried films of these matrix macromolecules. It was observed that cell shape and cell growth varied markedly between the different culture conditions. Flattened monolayers of cells on plastic or films of type I or type II collagen, proliferated more rapidly and reached a higher final cell density per culture than the more rounded cells found in the cultures on agar films or within three-dimensional gels. Biosynthetic studies demonstrated that in addition to the synthesis of type II collagen, all the cultures were producing collagen types IX and X. Chondrocytes cultured on plastic or films of the different matrix macromolecules all showed a similar expression of types IX and X collagen, independent of whether they displayed a flattened or round cell morphology. In contrast, marked variations in the proportions of the minor collagens, particularly type X collagen, were observed when the cells were cultured within three-dimensional gels. The data suggest that direct interaction of the cell surface with matrix constituents displaying a particular spatial array could be an important aspect in the control of type IX and X collagen expression by chondrocytes. The financial support of the Arthritis & Rheumatism Council and the Medical Research Council is gratefully acknowledged.     

The effect of collagen on the cyclic AMP content of embryonic somites.

Previous studies have demonstrated that collagen substrates stimulate in vitro somite chondrogenesis, and that agents that elevate intracellular cyclic AMP levels in hibit the ability of somites to respond to the inductive influence of collagen. In the present investigation, radiommunoassay was utilized to compare the cyclic AMP content of somite explants cultured on purified Type I collagen substrates with control explants cultured on Millipore filters. During the period of culture, the cyclic AMP content of collagen-treated explants is significantly lower than the cyclic AMP content of control explants. The cyclic AMP content of collagen-treated explants is 66% of control values as early as one hour following the initiation of culture, and the cyclic AMP content of collagen-treated explants remains lower than controls throughout the 3-day cultured period. The greatest difference in the cyclic AMP content of collagen-treated and control explants is observed at the seventeenth hour of culture, at which time the cyclic AMP content of collagen-treated explants is 56% of controls. These results combined with previous studies provides support for the hypothesis that collagen elicits a reduction in the cyclic AMP content of embroyic somites and that this reduction is necessary to trigger chondrogenic differentiation.     

Immunological effects of collagen and collagen peptide from blue shark cartilage on 6T-CEM cells

The physicochemical and in vitro mechanism of immunologic tolerance of pepsin-soluble collagen and its peptide, CII-P, from blue shark cartilage were studied. Protein patterns showed three identical (α₁)₃ chains, suggesting that it was a type-II collagen (CII). CII-P had high antioxidant activity and low carbohydrate content. Collagens had better biocompatibility with decreased the viability of 6T-CEM cell compared to control cells (without collagen). Immunological indices such as FAS/APO-1, cytokine, and caspase levels were higher in CII-treated 6T-CEM cells. Collagen bound to 6T-CEM cell receptors in a dose-dependent manner, and an optimum effect was observed with 10 μg/mL collagen. The high carbohydrate content of CII could activate the FAS receptor, which led to increased apoptotic gene expression in 6T-CEM cells. Breakdown of 6T-CEM cell nuclei through the induction of apoptosis by CII was confirmed by fluorescence microscopy. Collagen molecular weight and glycosylation patterns were crucial factors for immunologic tolerance and 6T-CEM cellular apoptosis.     

Lactating goat mammary gland cells in culture.

1. Isolated mammary gland cells were cultured embedded in collagen gels or as monolayers on floating collagen gels. Under these conditions the cells were able to grow for at least 6 weeks during five passages. Growth was sustained in M199/F12 (1:1) supplemented with insulin, hydrocortisone, epidermal growth factor, tri-iodothyronine, estradiol and bovine serum albumin. 2. The cells secreted lactose into the medium in significant amounts throughout the culture period. 3. Prolactin had a slightly stimulatory effect as had fetal bovine serum on growth and protein synthesis, but none of these factors were obligatory in this respect. Insulin-like growth factor I (Somatomedin C) could replace high concentrations of insulin whereas bovine growth hormone had no detectable effect. 4. Depending on the hormone content of the medium and the age of the culture, different labelling patterns of the arachidonic acid-containing phospholipids were observed. The effect of prolactin on phosphatidyl inositol and arachidonic acid metabolism was studied.     

An arthritogenic monoclonal antibody to type II collagen, CII-C1, impairs cartilage formation by cultured chondrocytes

Antibodies to type II collagen (CII) cause articular damage in collagen-induced arthritis (CIA) in mice as judged by passive transfer to naive animals of mAb to CII. We tested the hypothesis that mAb degrade cartilage structure by reacting with functionally important regions of the collagen molecule by examining the effects of an arthritogenic mAb to CII, CII-C1, on cultured bovine chondrocytes at high density, at days 7 and 14. The effects were compared of CII-C1, an isotype-matched control mAb, or medium alone, on chondrocyte proliferation and viability, cell morphology, matrix structure by light and electron microscopy, and matrix synthesis by metabolic labelling with 3H-proline for collagen or 35SO4 for proteoglycans. Chondrocytes in culture remained viable, proliferated, and produced an extracellular matrix in which CII was the major collagen. The addition of CII-C1, but not a control mAb, increased the synthesis of CII and proteoglycan, and caused disorganization of the extracellular matrix and thin collagen fibrils ultrastructurally. Moreover, using a cell-free assay, CII-C1 inhibited the normal self-assembly of collagen fibrils from CII in solution. The finding that the mAb to CII, CII-C1 has striking degradative effects in vitro on cartilage synthesis suggests that antibodies to collagen perpetuate the chronic phase of CIA and that, in mice at least, such antibodies are an important component of pathogenesis.     

Comparative analysis of casein synthesis during mammary cell differentiation in collagen and mammary gland development in vivo

Substrata upon which epithelial cells are cultured modulate their morphology,growth, and ability to differentiate. Mouse mammary epithelial cells cannot be induced to synthesize caseins, a marker of cell differentiation, when grown on a plastic surface. An analysis was made of the effect of time within a collagen matrix on the ability of normal mammary epithelial cells to be induced to synthesize caseins and that response was compared to mammary gland development in vivo. Primary cultures of mammary cells from unprimed virgin BALB/c mice were embedded in rat-tail collagen gel mixtures and maintained in growth medium. Induction medium containing lactogenic hormones was added at various times. The cells were monitored every 3-7 days over a period of 8 weeks for cell growth, casein synthesis, and ability to grow in vivo in cleared mammary fat pads. Casein accumulation was assayed quantitatively by an ELISA competition assay and qualitatively by the immunoblot procedure using specific antisera prepared against purified mouse caseins. No marked differences in cell numbers and transplantability potential were observed among cells cultured for various times in collagen. Mammary cells grown in collagen for up to 8 weeks retained the capacity to grow in vivo as normal ductal outgrowths. The duration of culture within collagen prior to hormonal stimulation did influence the kinetics of casein synthesis. Cells cultured for 1 week in growth medium did not accumulate detectable levels of casein until after 3 weeks of induction, whereas cells cultured for 2 or 4 weeks responded by accumulating caseins after 2 weeks and 3 days of induction, respectively. While the levels of total caseins that accumulated under optimal conditions of induction in culture approached levels found during lactation in vivo, the relative proportion of specific casein polypeptides synthesized in culture was altered from alpha casein (43K) in favor of the beta casein (30K) species. These results suggest that a period of culture within collagen is required to permit mammary epithelial cells to become responsive for hormone-induced differentiation. It is possible that during growth within the collagen the cells synthesize and deposit extracellular matrix components important in modulating gene expression.