Requirements for maintaining the embryonic state of avian tendon cells in culture

Summary Primary avian tendon cells (PAT) maintain their embryonic state when cultured in medium F-12 with very low serum (0.2%) and ascorbate (50 μg per ml); that is, they retain the potential for devoting 20–30% of their total protein synthesis to collagen. However, if the cells are left at a confluent cell density or are derived from confluent cultures, this potential is irreversibly decreased. This effect, along with poor medium formulations, probably accounts for the “dedifferentiation” process that occurs when fibroblasts are cultured. In contrast, PAT cells kept at subconfluent cell densities retain the ability to synthesize high levels of collagen. The one limitation in obtaining long-term cultures of high collagen-producing tendon cells in the inability of serum at low concentrations to remain a potent mitogen after a few subcultures. The quantitative loss of function has long been considered to be a cell culture artifact; however, we propose that this drop in collagen synthesis is a reflection of the developmental programing of these cells. In separate series of experiments using organ cultures, we show that tendon tissue from the embryo makes over 30% collagen, whereas, “young” tendons make 18% and “older” tendons from the adult make less than 1%. Therefore, a quantitative drop in collagen synthesis would be expected if normal development were to occur in culture. Our data are consistent with the idea that cultures of embryonic tendon cells are triggered to mature by a mechanism that correlates with high cell density. This investigation was supported in part by National Science Foundation Grant PCM 77-14982; in part by the Division of Biomedical and Environmental Research of the Department of Energy under contract W-7405-ENG-48; and by a National Institutes of Health Fellowship IF32 CA 05807-01, from the National Cancer Institute to R. I. S.     

Role of procollagen mRNA levels in controlling the rate of procollagen synthesis.

Two factors must be present for primary avian tendon cells to commit 50% of their total protein production to procollagen: ascorbate and high cell density. Scorbutic primary avian tendon cells at high cell density (greater than 4 X 10(4) cells per cm2) responded to the addition of ascorbate by a sixfold increase in the rate of procollagen synthesis. The kinetics were biphasic, showing a slow increase during the first 12 h followed by a more rapid rise to a maximum after 36 to 48 h. In contrast, after ascorbate addition, the level of accumulated cytoplasmic procollagen mRNA (alpha 2) showed a 12-h lag followed by a slow linear increase requiring 60 to 72 h to reach full induction. At all stages of the induction process, the relative increase in the rate of procollagen synthesis over the uninduced state exceeded the relative increase in the accumulation of procollagen mRNA. A similar delay in mRNA induction was observed when the cells were grown in an ascorbate-containing medium but the cell density was allowed to increase. In all cases, the rate of procollagen synthesis peaked approximately 24 h before the maximum accumulation of procollagen mRNA. The kinetics for the increase in procollagen synthesis are not, therefore, in agreement with the simple model that mRNA levels are the rate-limiting factor in the collagen pathway. We propose that the primary control point is at a later step. Further support for this idea comes from inhibitor studies, using alpha, alpha'-dipyridyl to block ascorbate action. In the presence of 0.3 mM alpha, alpha'-dipyridyl there was a specific two- to threefold decrease in procollagen production after 4 h, but this was unaccompanied by a drop in procollagen mRNA levels. Therefore, inhibitor studies give further support to the idea that primary action of ascorbate is to release a post-translational block.     

Modeling tendon morphogenesis in vivo based on cell density signaling in cell culture

 A mathematical model of tendon morphogenesis is presented that is consistent with the dramatic transitions seen in this tissue as it progresses from rapid growth early in development to no growth in the adult. To accomplish this change, the embryonic chick tendon is hypercellular with each cell dedicating half of its protein production to procollagen but over time, as growth subsides, the tissue gradually becomes hypocellular with each cell producing only about 1% procollagen. Making this transition from the embryonic to the adult state, forming a roughly cylindrical tissue composed of ∼90% collagen, and linking the correct muscle to the right bone, is a complex task. The proposed solution requires only two factors: an activator of growth and an inhibitor complex, composed of the activator and another molecule that modifies the activity of the activator. From a diverse set of cell culture observations, these two factors were deduced as the primary components of the mechanism that allows cells to signal their presence to their neighbors. Since cell density signaling is the principal regulator of both collagen synthesis and cell proliferation, its components should play the key role in tendon development. A mathematical model based on the changes in the concentrations of these factors with cell density correlates well with the transitions observed in vivo. Furthermore, the model predicts that in the maturing chicken there should be a high cell density region at the muscle tendon interface. Experimental observations of frozen sections of tendon from a 4 month old chicken confirm this prediction. Received 12 October 1995     

Prolyl hydroxylase production can be uncoupled from the regulation of procollagen synthesis

Primary avian tendon (PAT) cells increase the production of procollagen from 10-12% to 40-50% of total protein synthesis in response to the addition of ascorbate and an increasing cell density. We now show that prolyl hydroxylase (PH) also increases its activity by greater than five-fold in response to increasing cell density; but unlike procollagen production, this is independent of the presence of ascorbate. The increased activity is a result of greater enzyme production and not a shift in the ratio of inactive to active forms which remains constant at about 10% of the total enzyme proteins. We present the possibility that at low cell density the levels of PH activity could limit production of collagen.     

Primary avian tendon cells in culture. An improved system for understanding malignant transformation

Primary avian tendon (PAT) cells which maintain their differentiated state in culture are rapidly transformed by Rous sarcoma virus. By criteria of morphology, increased rate of 2-deoxyglucose uptake, and loss of density dependent growth control, PAT cells transform as well as their less differentiated counterpart, chick embryo fibroblasts. In addition, the percentage of collagen produced by PAT cells drops on transformation by an order of magnitude, from 23 to 2.5%, but is unaffected by viral replication of a transformation-defective mutant. The responsiveness of normal and transformed PAT cells to various environmental factors changes dramatically upon transformation. Normal PAT cells respond to the presence of ascorbate and high cell density by raising the level of collagen synthesis from 5 to 23%. Transformed PAT cells are totally unresponsive. These and previously reported results lead us to postulate that the break-down in the normal regulatory mechanisms used by the cell to maintain the differentiated state is related to or is responsible for the onset of malignant transformation.     

Role of ascorbic acid in procollagen expression and secretion by human intestinal smooth muscle cells

The role of ascorbate in the production and secretion of procollagen by human intestinal smooth muscle cells and the conditions in culture for optimal ascorbate bioefficacy were studied. Procollagen synthesis and secretion were determined by the incubation of cells with L-[5-³H]proline, and the quantitation of radiolabelled procollagen bands in the cell layer and the culture medium by polycrylamide slab gel electrophoresis and densitometry. When cells were cultured without ascorbate in the culture medium, procollagen secretion into the medium was 75% less than in cells receiving fresh ascorbate daily. In the cell layer, in contrast, procollagen accumulation was fourfold greater in the scorbutic cells than in the ascorbate-replete cells. These findings contrasted with those in a control line of scorbutic human dermal fibroblasts in which a 95% decrease in procollagen secretion was not associated with any procollagen accumulation in the cells. In the intestinal smooth muscle cells, the absence of ascorbate resulted in a 25 and 50% decrease in steady-state levels of procollagen I and III mRNA, respectively, compared to a 40 and 75% decrease in fibroblasts. Heat inactivation of the serum in the culture medium augmented the promotion of procollagen secretion by ascorbate two- to fourfold. L-ascorbate phosphate did not increase the activity of L-ascorbate when replaced in medium either daily or every 4 days, and its efficacy was not augmented by serum heat inactivation. The changing of culture medium induced collagen secretion in the absence of ascorbate, but this process was markedly enhanced by ascorbate and induced a transient decrease in the steady-state levels of both procollagen and nonprocollagen mRNAs. The predominant action of L-ascorbate on HISM cells in vitro is to promote procollagen secretion and not procollagen synthesis. L-ascorbate-phosphate is not an adequate substitute for L-ascorbate in this cell line. © 1995 Wiley-Liss, Inc.     

A simple fractionation of chicken egg yolk yields a protein component that stimulates cell proliferation and differentiation in primary avian tendon cells

Summary An easily prepared and stable protein fraction from chick egg yolk promotes cell division (40 h generation time) and expression of procollagen (60% of total protein synthesis) in primary avian tendon cells in a serum-free medium. The activity of this yolk fraction (YF) is proteinaceous as reflected by its sensitivity to protease treatment. Yolk fraction is resolved into four major components on sodium dodecyl sulfate polyacrylamide gel electrophoresis with apparent molecular weights of 82,70,42,35 (× 10⁻³). Under nondenaturing conditions, YF runs as a mixture of high molecular weight aggregates on Sephacryl G-200. We postulate that the active part of YF could be the in ovo growth promoter for embryonic chick tendon cells. This work was supported in part by National Institutes of Health grant CA 37958 and in part by the Office of Health and Environmental Research, Office of Energy Research, U.S. Department of Energy, under Contract DE-AC03-76SF00098.     

Decreased levels of alpha 1(I) procollagen mRNA in dermal fibroblasts grown on fibrin gels and in response to fibrinopeptide B

We have investigated human neonatal fibroblast synthetic activity in response to fibrin substrates and components of fibrin formation and degradation. Greater than threefold downregulation of procollagen mRNA levels was seen 24 hours after fibroblasts were grown on fibrin gels as compared to tissue culture plastic. This downregulation occurred in both reptilase-generated fibrin (retention of fibrinopeptide B) and thrombin-generated fibrin (loss of both fibrinopeptide A and B). However, fibroblasts grown on fibrin retained their capacity to respond to the stimulatory action of transforming growth factor (TGF)-beta 1. Fibroblasts seeded on reptilase-generated fibrin displayed an abnormal morphology manifested by dendritic appearance and cell rounding, while fibroblast attachment was enhanced by 30% on thrombin-generated fibrin substrate (P < 0.02). Fibrinopeptides A and B, which are generated during fibrin formation, increased and decreased procollagen mRNA levels, respectively. Tissue plasminogen activator (t-PA) increased procollagen mRNA and TGF-beta 1 levels as early as 6 hours after cells were grown on tissue culture plastic, but this stimulation did not occur in cells cultured on a fibrin substrate. We conclude that alpha 1(I) procollagen mRNA levels in cultures of human dermal fibroblasts are consistently down-regulated by a fibrin substrate and are directly and profoundly influenced by complex interactions between components involved in the formation and removal of fibrin. © 1995 Wiley-Liss, Inc.     

High serum levels interfere with the normal differentiated state of avian tendon cells by altering translational regulation

In low serum (0.2%) medium, ascorbate stimulates primary avian tendon cells to increase procollagen synthesis from 12 to 50% of total protein synthesis. This is reversibly blocked by an increase of serum levels from 0.2 to 3%. Ascorbate in low serum medium has been shown previously to stimulate the procollagen pathway by sequentially increasing by sixfold the secretion rate constant, then translation rates, and finally mRNA levels. We now show that addition of ascorbate to cultures containing 3% serum induces a sixfold increase in the secretion rate constant but translation rates and mRNA levels remain unchanged. In fully induced cells, an increase in serum levels causes a down-regulation of procollagen synthesis. In this case, the translational products of the induced cell are rapidly altered (less than 1 h), with noncollagen protein synthesis being stimulated preferentially over procollagen synthesis. This change is not reflected in procollagen mRNA levels since they remain constant for at least 6 h following addition of high serum. After 48 h in high serum, the induction of procollagen synthesis by ascorbate is reversed and the level of procollagen mRNA drops to that of uninduced cells. The data are consistent with the model that serum acts primarily at the translational level. High serum levels break the coupling in the ascorbate induction process that ties the stimulation of procollagen secretion rates to the increase in procollagen translation rates, and this prevents the maintenance of the induced state.     

Relative content of isoaccepting tRNAs for glycine and proline in avian tendon cells with different rates of procollagen synthesis

The relative amounts of iso-tRNAs^Gly and iso-tRNAs^Pro existing in chick embryo tendon are indicative of a specialization of the tRNA population for collagen synthesis. These amounts are not modified (i) in primary avian tendon (PAT) cells in culture for which the procollagen production varies from about 10% of total protein synthesis to 60% and (ii) in tendons from immature chicks, which show a 3-fold decrease of procollagen production with increasing age. The characteristic tRNA pattern was not maintained in cells which had lost the ability to make high levels of collagen as observed in the cases of: (i) PAT cells reaching confluency; (ii) virus-transformed PAT cells and (iii) tendon from adult chick. Our data are consistent with the idea that tendon tRNA specialization for collagen synthesis is a differentiation feature independent of the expression level of the collagenic function but related to its maintenance.     

Relative content of isoaccepting tRNAs for glycine and proline in avian tendon cells with different rates of procollagen synthesis

The relative amounts of iso-tRNAsGly and iso-tRNAsPro existing in chick embryo tendon are indicative of a specialization of the tRNA population for collagen synthesis. These amounts are not modified (i) in primary avian tendon (PAT) cells in culture for which the procollagen production varies from about 10% of total protein synthesis to 60% and (ii) in tendons from immature chicks, which show a 3-fold decrease of procollagen production with increasing age. The characteristic tRNA pattern was not maintained in cells which had lost the ability to make high levels of collagen as observed in the cases of: (i) PAT cells reaching confluency; (ii) virus-transformed PAT cells and (iii) tendon from adult chick. Our data are consistent with the idea that tendon tRNA specialization for collagen synthesis is a differentiation feature independent of the expression level of the collagenic function but related to its maintenance.     

Cultured proliferating rat mammary epithelial cells

Summary Normal epithelial cells from the rat mammary gland proliferated in culture when plated with lethally irradiated cells of the LA7 rat mammary tumor line. Proliferation of the normal rat cells occured as the LA7 cells slowly died from the radiation. By labeling the cultures with³H-thymidine it was determined that most of the proliferating rat cells were those adjacent to the LA7 feeder cells. The epithelial cells from the primary culture proliferated after subsequent passages if the cells were plated at each subculture with newly irradiated LA7 cells. If the cells were plated at a ratio of ∼1:8 rat:LA7 a confluent layer of normal rat cells covered the plastic substrate after 6 to 7 wk. The cells have so far been carried up through Passage 7, which amounted to ∼19 doublings in cell number, and still proliferate vigorously. The growth medium for this culture system was Dulbecco’s modified Eagle’s medium:Ham’s F12 1:1 supplemented with fetal bovine serum, insulin, and antibiotics. The presence in the cells of keratin, desmosomes, and cell junctions attested to their epithelial origin. The cultures were composed of cells with diploid or near diploid chromosome numbers. Samples of the cultured cells were implanted into the cleared fat pads of nude mice. Most of the implants from Passage 2 formed normal mammary ductal structures, but the incidence of outgrowths decreased significantly with later passages until no out-growths resulted from the implantation of cells from Passage 5. The one unusual, feeder-independent cell line that arose from a primary culture seemed to be immortal in culture, contained a hyperdiploid chromosome complement, and formed abnormal structures when implanted into cleared fat pads. This work was supported by the Veterans Administration, Washington, DC, and by CA grant 05388 from the U.S. Public Health Service, Washington, DC.     

Regulation of protein secretion in Chinese hamster ovary cells by cell cycle position and cell density : Plasminogen activator, procollagen and fibronectin

To study the relationship between cell growth control, cell contact, and protein secretion, we examined the production of plasminogen activator, procollagen, and fibronectin by Chinese hamster ovary (CHO) fibroblasts, both as a function of position in the cell cycle and as a function of cell density. CHO fibroblasts that were synchronized at hourly intervals throughout the cell cycle by mitotic selection in an automated roller bottle apparatus secreted plasminogen activator only during the G2 and M phases of the cell cycle (10–14 h after mitotic selection). Cell-associated plasminogen activator activity was variable during G1 and S, but was greatly reduced during G2 and M. In contrast, secretion of the connective tissue matrix proteins, procollagen and fibronectin, was controlled by cell density rather than by cell cycle position. Type III procollagen and fibronectin were secreted throughout the cell cycle with no pronounced variations. Type I procollagen was not secreted by cycling cells and was observed in confluent cultures only after 24–48 h. To correlate these changes in protein secretion patterns with cell shape and contact, we used scanning electron microscopy (SEM) to study the appearance of CHO cells after mitotic selection. Actively dividing cells retained a high proportion of rounded, ruffled, and blebbed cells during all phases of the cell cycle. Only with increased cell density in contact-inhibited confluent cultures did most cells begin to flatten and spread. Thus, secretion of and attachment to extracellular matrix did not occur in rapidly dividing cells, but appeared to require the increased cell-cell contact and spreading that accompanies contact inhibition of growth. On the other hand, increased secretion of plasminogen activator was directly related to cell division and may be part of a sequence of events that allows cells growing in culture to loosen extracellular attachments in preparation for rounding and cytokinesis.     

Cortisol decreases the cellular concentration of translatable procollagen mRNA species in cultured human skin fibroblasts

The effect of cortisol on the cellular concentration of translatable procollagen mRNAs was studied in cultured human skin fibroblasts. Cortisol selectively decreased the amount of procollagen mRNAs, in comparison to the total mRNA activity, when the cells were grown in enriched medium conditions, i.e., with 10% newborn calf serum. The selective decrease was first observed after 6 h exposure to 1 μM cortisol. In depleted medium conditions, i.e., with 2% newborn calf serum, the initial response was a stimulatory one, followed after about 12 h by a decrease in the procollagen mRNA activity. The results suggest that the selective inhibitory effect of cortisol on the cellular concentration of translatable procollagen mRNA species needs an optimal serum concentration. Furthermore, the results give support to the hypothesis that the decrease in the procollagen mRNA concentration after cortisol administration is a secondary response, preceeded by the induction of some intracellular regulation system.     

Cell density and proliferation modulate collagen synthesis and procollagen mRNA levels in arterial smooth muscle cells.

Collagen synthesis and procollagen mRNA levels were determined and compared in (1) sparse, rapidly proliferating smooth muscle cells (SMC); (2) postconfluent, density-arrested SMC; and (3) sparse, nonproliferating (mitogen-deprived) rabbit arterial SMC. Collagen synthesis per SMC was decreased by 70% in postconfluent versus proliferating cells. However, relative collagen synthesis, expressed as the percentage of total protein synthesis, increased from 3.7% in sparse cultures to approximately 7% in postconfluent cultures. Slot blot analyses demonstrated that the relative steady state alpha 1(I) and alpha 1(III) procollagen mRNA levels were also increased in postconfluent cultures when compared to sparse cultures. As with collagen synthesis per cell, the mRNA levels per cell for types I and III procollagen in postconfluent cells, determined by densitometry of blots, were likewise approximately half that found in sparse, proliferating cells. In a separate study to determine if cell-cell contact was necessary for eliciting these changes in collagen synthesis, we determined collagen synthesis in mitogen-deprived and proliferating SMC cultures at low density. Mitogen-deprived cultures synthesized only 10% the amount of collagen produced (per cell) by proliferating cultures in 10% fetal bovine serum. Relative collagen synthesis in proliferating and nonproliferating cultures was 5.0 and 8.3%, respectively. These results demonstrate elevated collagen synthesis, per cell, by proliferating cultures compared with nonproliferating cultures, regardless of whether cells were rendered quiescent by density arrest or by mitogen deprivation. Results also suggest a pretranslational mechanism for the regulation of collagen synthesis in rabbit aortic smooth muscle cells.     

Production of interferon-α in high cell density cultures of recombinant Escherichia coli and its single step purification from refolded inclusion body proteins

Escherichia coli TG1 transformed with a temperature-regulated interferon-α expression vector was grown to high cell density in defined medium containing glucose as the sole carbon and energy source, utilizing a simple fed-batch process. Feeding was carried out to achieve an exponential increase in biomass at growth rates which minimized acetate production. Thermal induction of such high cell density cultures resulted in the production of ∼4 g interferon-α/l culture broth. Interferon-α was produced exclusively in the form of insoluble inclusion bodies and was solubilized under denaturing conditions, refolded in the presence of arginine and purified to near homogeneity, utilizing single-step ion-exchange chromatography on Q-Sepharose. The yield of purified interferon-α was ∼300 mg/l with respect to the original high cell density culture broth (overall yield of ∼7.5% active interferon-α). The purified recombinant interferon-α was found by different criteria to be predominantly monomeric and possessed a specific bioactivity of ∼2.5 × 10⁸ IU/mg based on viral cytopathic assay. Received: 8 October 1999 / Received revision: 8 December 1999 / Accepted: 12 December 1999     

Macro- and microvascular endothelial cells in vitro: Maintenance of biochemical heterogeneity despite loss of ultrastructural characteristics

Summary Microvascular endothelial cells from bovine adrenal medulla and brain and macrovessel endothelial cells from bovine aorta were isolated and cultured under similar conditions in order to determine morphologic and biochemical heterogeneity in vitro. All three cell types exhibited nearly identical ultrastructural morphology and two-dimensional gel protein patterns of³⁵S-methionine-labeled whole cells. Two-dimensional gel analysis of³⁵S-methionine-labeled plasma membrane proteins however, revealed two-dimensional gel protein patterns unique to the tissue type from which the endothelial cells were isolated. This suggests that the functional significance of these specific endothelial cell types is manifested primarily in surface-associated proteins and that many of the differences are sustained in culture. To determine the potential of aorta, brain, and adrenal medulla endothelial cell (EC) cultures to respond to developmentally significant signals, morphology, growth pattern, and cell surface proteins were monitored in the presence and absence of growth factors. A 17 to 26% increase in cell density as well as an increase in the number of elongated and overlapping cells resulted when all three EC types were exposed to a mitogenic medium. Additionally, expression of specific glycoprotein profiles, as determined by Concanavalin A Western blotting of two-dimensional gels, was dependent on the presence or absence of growth factors in the medium. The ability to induce this morphologic and biochemical variation in the three endothelial cell types was maintained into later passage. Taken together, these data imply that endothelial cells isolated from different tissues exhibit and maintain biochemical heterogeneity and do not completely dedifferentiate into a common endothelial cell type in culture. Furthermore, expression of specific subsets of cell surface proteins is dependent on environmental conditions, and in some cases is both cell-type and media-type dependent. Thus, even though endothelial cells are considered terminally differentiated cells, there exists additional or “latent” heterogeneity in the ability of these different cells to respond to “developmental signals” (i.e. mitogenic medium) in vitro. This work was supported in part by a grant from the American Heart Association (860929), NIH (GM29127), and a Biomedical Research Grant from the University of Massachusetts.     

Requirement of hydrocortisone and insulin for extended proliferation and passage of rat keratinocytes

Summary A procedure for the preparation and cultivation of rat epidermal basal cells from full thickness skin resulted in greater than 99% viability and 90% plating efficiency. However, attempts to subculture monolayers of these epithelial cells grown in medium with serum as the only supplement were totally unsuccessful. When hydrocortisone and insulin were added to the medium, subcultivation of primary growth was obtained. It was demonstrated that hydrocortisone at concentrations as low as 0.1 μg/ml was necessary for at least the initial attachment of the cells to the substrate—an essential step in subcultivation. Increasing concentrations of insulin (0.1 to 50 μg/ml) caused the rate of proliferation and the cell density to increase, but insulin alone did not support subcultivation. This work was supported by Grants 1-R01-CA-19988 and 5-R01-AM-15206 from the National Institutes of Health, U.S. Public Health Service.