Cell density regulates prolyl 4-hydroxylase activity independent of mRNA levels.

In embryonic avian tendon, cell density regulates collagen production. This control is propagated through the alpha-subunit of prolyl 4-hydroxylase where protein levels were previously shown to rise fivefold with increasing cell density. In contrast, mRNA levels are now shown not to change by both Northern and RNAse protection assays. This lack of increase contrasts with previous reports as does the mRNA length: this is 50% larger as confirmed by sequencing the 3' end. Alternative sites for cell density regulation of the enzyme could rely on its sensitivity to sulfhydryl groups. Using a fluorescent sulfhydryl probe as well as a sulfhydryl inhibitor, one observes a strong cell density response, supporting the hypothesis that cellular redox potential could alter protein stability.

Expression of the nicotinic receptor alpha 7 gene in tendon and periosteum during early development.

One of the most abundant nicotinic acetylcholine receptors expressed in the central and peripheral nervous systems is a species that contains the alpha 7 gene product, binds alpha-bungarotoxin with high affinity, and has a high relative permeability to calcium. The alpha 7 gene is also expressed at low levels in embryonic muscle tissue. We show here that the alpha 7 gene is expressed in tendon fibroblasts and periosteal cells during development. In situ hybridizations identify alpha 7 transcripts in tissue sections containing embryonic tendon and periosteum. RNase protection experiments demonstrate alpha 7 mRNA in primary tendon cells grown in culture. Immunofluorescence with subunit-specific monoclonal antibodies reveals alpha 7 protein in embryonic tendon. Immunoprecipitation assays with the antibodies indicate that the alpha 7-containing species in tendon is capable of binding alpha-bungarotoxin and that a similar species can be identified at low levels on the surface of fibroblasts in culture. The results show that the alpha 7 gene product is expressed in a range of tissues, including cells thought to be nonexcitable. The distribution of alpha 7 expression early in development and the ability of alpha 7-containing receptors to elevate intracellular calcium suggest that the gene may influence a variety of calcium-dependent events during embryogenesis.

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 approximately 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.

Evidence supporting the role of a proteinaceous, loosely bound extracellular molecule in the cell density signaling between tendon cells.

Normal cells in culture respond to cell density by altering their proliferation rates and their pattern of protein expression. Primary avian tendon (PAT) cells are a case in point where procollagen production increases approximately 10-fold at high cell density while proliferation almost ceases. In an earlier report focusing on the cell density regulation of procollagen expression, the signaling mechanism communicating the presence of other cells was shown to have the characteristics of a loosely bound component of the cell layer. Extending these studies to the cell density regulation of proliferation, the cell density signal (CDS) was again shown to be altered by medium agitation, stimulating cell division. Agitation, however, was only disruptive to cell signaling when there was a high ratio of medium to cells. When sufficient cells were present, agitation was less effective. Therefore, the CDS controlling procollagen production and the CDS controlling the inhibition of growth seemed to be linked because the signaling mechanism is disrupted in a parallel manner by agitation. However, the proliferative response of PAT cells is more complex in that there is also a positive influence at moderate cell density (> 2 x 10(4) cells/cm2) on the rate of cell division. As a consequence, PAT cells would not proliferate into an area of low cell density, but within the same dish would rapidly fill an area of moderate density. PAT cells were capable of filling a gap between high cell density areas if the gap was less than 2 mm. Medium agitation also affected cells at low cell density in a different manner. It was inhibitory if all the cells were at low cell density but it was stimulatory if the cells at low cell density were in close proximity to cells at high cell density. In addition, medium conditioned by agitation over cells at a high cell density would stimulate cells at low cell density to divide and grow out into low cell density regions. Using the growth-promoting activity of the conditioned medium as an assay, this component of the CDS was shown to have unique characteristics: heat, pH, dithiothreitol (DTT) stable; tris ion and protease sensitive. By gel exclusion chromatography it was larger than 100 kDa. But after DTT treatment its mobility shifted to < 30 kDa while retaining activity.

Ascorbate stabilizes the differentiated state and reduces the ability of Rous sarcoma virus to replicate and to uniformly transform cell cultures.

In primary avian tendon cells, Rous sarcoma virus can coexist or completely take over the cell. Infection, at high multiplicity or under conditions that promote high virus production (no ascorbate and high serum concentrations), results in almost complete oncogenic transformation of the culture. This is indicated in part by a radical change in morphology, growth at high cell density, and a dramatic drop in the production of procollagen from approximately 50% to approximately 3% of total protein synthesis. In contrast, infection at low multiplicity, infection with a replication defective virus, or the presence of ascorbate restrict the ability of the virus to transform the culture. Thus, there appears to be a balance between the normal and transformed states of the cell that can be shifted depending on the cellular environment and the level of infection. Ascorbate stabilizes the normal state by reducing virus production and promoting the synthesis of differentiated proteins.

Cell-to-cell signaling in the regulation of procollagen expression in primary avian tendon cells.

High cell density is required for high procollagen expression (50% of total protein synthesis) in primary avian tendon (PAT) cells but the signaling mechanism that triggers this response has been difficult to decipher. By using a quantitative in situ hybridization assay for procollagen mRNA, cell density dependent changes in procollagen expression can be followed at the single cell level. PAT cells can then be shown to respond to the presence of their neighbors over approximately 1-mm distance. The cell density signal remains effective independent of the medium volume to cell ratio but becomes sensitive to dispersion and dilution when the medium is agitated. PAT cells respond to a reduction in cell density, when neighboring cells are scraped away, by outgrowth (approximately 1 mm) and reestablishment of a cell density gradient in cellular procollagen mRNA levels. However, removing neighboring cells while preventing migration off of their own extracellular matrix retards the drop in procollagen mRNA levels. The evidence, taken as a whole, is consistent with a model whereby the cell density signal is a loosely bound component of the cell layer thereby restricting its diffusion to two dimensions but making it susceptible to dispersion by medium agitation.

Effectiveness of isoascorbate versus ascorbate as an inducer of collagen synthesis in primary avian tendon cells.

In contrast to most biologically active molecules, the isomeric form of ascorbate retains significant biological activity. Moreover, in studies in vitro the isomer was found to be an equally effective cofactor in the enzymatic proline hydroxylation reaction. This raises questions about whether the lower biological activity in vivo results from selective transport into the cell, greater instability of the molecule, or stereospecificity by certain enzyme complexes. Distinguishing these possibilities can be accomplished most directly using a cell culture model. In this study primary avian tendon (PAT) cells were used. With PAT cells isoascorbate was shown to be three- to fivefold less active at inducing procollagen production than ascorbate. Isoascorbate was also internalized by the cell at about one-fifth the ascorbate level. In addition, isoascorbate was degraded in the medium at a slightly higher rate (half-life of 1.6 h) than ascorbate (2.1 h). The data are consistent with a model that postulates that once inside the cell isoascorbate is equally effective at inducing procollagen production but selectivity at the transport step restricts the percentage that is actually internalized. In addition, both ascorbate and isoascorbate were found to degrade very quickly inside the cell in the highly oxygenated environment of cell culture (approximately 2 h half-life). When ascorbate was added to the medium (100 micrograms/mL) the level inside the cell quickly reached a maximum (less than 2 h) and declined rapidly.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

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

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 (X 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.

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.

Procollagen secretion meets the minimum requirements for the rate-controlling step in the ascorbate induction of procollagen synthesis.

Ascorbate addition to primary avian tendon cells has been shown previously to cause a approximately 6-fold increase in procollagen translation that is first observable after 4 h and reaches a maximum level after 48 h. Similarly, procollagen mRNA has been shown to increase after ascorbate addition by approximately 6-fold starting at 12 h and reaching a maximum level by 72 h. The rate constant for procollagen secretion is now shown to also react to ascorbate by a 6-fold change. This results in a drop in the half-life of procollagen within the cell from 120 to 20 min. In sharp contrast to the other steps in the procollagen pathway, the change in the secretion rate constant is extremely fast occurring in less than 30 min. Moreover, after ascorbate addition, greater than 80% of the internal procollagen can be secreted at the fast rate. Since this change results from an increase in hydroxylation of proline residues and since the hydroxylation reaction has been localized to the endoplasmic reticulum, this evidence strongly supports the model that the slow step in the secretion pathway is transport out of the endoplasmic reticulum. Further support for this comes from electron microscope autoradiography of [3H]proline-labeled cells where the labeled procollagen pool within the cells was highly localized to the endoplasmic reticulum.

Ascorbate stimulation of PAT cells causes an increase in transcription rates and a decrease in degradation rates of procollagen mRNA.

Procollagen alpha 2 (I) mRNA can be induced congruent to 6-fold in primary avian tendon (PAT) cells on addition of ascorbate to the culture medium. Previously, we have shown that the induction is linear after a 12 h lag and requires a total of 60-72 h to achieve maximum levels. We have now investigated in more detail the changes that have occurred in the metabolism of procollagen mRNA in fully induced cells to account for the observed induction. Ascorbate was found to triple the rate of procollagen gene transcription. In addition, there was a stabilization of the mRNA causing the half-life to increase from 10.5 h to 20 h. The increased stability of the procollagen mRNA, however, did not correlate with its ability to bind to oligo (dT)-cellulose. Since a 3-fold change in transcription rates and a 2-fold increase in half-life would account for the 6-fold overall increase in procollagen mRNA levels, we conclude that these are the primary alterations caused by ascorbate addition that give rise to the specific increase in procollagen mRNA.

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.

Ascorbate induction of collagen synthesis as a means for elucidating a mechanism of quantitative control of tissue-specific function.

Ascorbic acid displays the characteristics of an ideal inducer of tissue-specific function in primary avian tendon cells in culture. It is a highly specific, potent stimulator of collagen synthesis, it demonstrates slow reversible kinetics, and it has no effect on growth rate of the cultured cells. Kinetic analysis of ascorbate induction of collagen synthesis was used to determine the critical steps in this complex biosynthetic pathway. Full hydroxylation of the proline residues in collagen, although probably a necessary step for collagen induction, was in itself not sufficient for achieving either increased secretion or increased synthesis. On the other hand, an increase in secretion rate, which required both the presence of ascorbate and a high cell density, did correlate with the later stimulation in procollagen production. The process of procollagen secretion, therefore, meets the minimal requirements for the rate-limiting step. The fact that the cells maintained a large pool of intracellular procollagen despite changes in the rates of translation or secretion led us to postulate a possible feedback between the level of the internal procollagen pool and the rate of procollagen synthesis.

Ascorbic acid inhibits replication and infectivity of avian RNA tumor virus.

Ascorbic acid, at nontoxic concentrations, causes a substantial reduction in the ability of avian tumor viruses to replicate in both primary avian tendon cells and chicken embryo fibroblasts. The virus-infected cultures appear to be less transformed in the presence of ascorbic acid by the criteria of morphology, reduced glucose uptake, and increased collagen synthesis. The vitamin does not act by altering the susceptibility of the cells to initial infection and transformation, but instead appears to interfere with the spread of infection through a reduction in virus replication and virus infectivity. The effect is reversible and requires the continuous presence of the vitamin in the culture medium.

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.

Dependence of the differentiated state on the cellular environment: modulation of collagen synthesis in tendon cells.

In an adequate environment, primary avian tendon cells are capable of retaining both the full expression of differentiated function and a correct morphological orientation for 1 week in culture. At high density and in the presence of ascorbate, they are fully stabilized in that they devote 25-30% of their total protein synthesis to collagen, a level comparable to that in tendon cells in ovo. However, either at low density or in medium without ascorbate, they synthesize collagen at only a third of this level. If plated on a collagen matrix, these cells will orient themselves in a manner similar to that of tendon cells in vivo. Furthermore, they are capable of fully modulating the percentage of collagen synthesis upon addition or removal of ascorbate and serum. The variation in the percentage of collagen produced is a result of alterations in collagen synthesis rather than of changes in total protein synthesis or hydroxylation of proline in collagen. Primary avian tendon cells, therefore, provide a suitable model for understanding the stability of the differentiated state, the mechanism of action of ascorbate, and the regulation of collagen biosynthesis.