Ubiquitin-Like Protein from Human Placental Extract Exhibits Collagenase Activity

An aqueous extract of human placenta exhibits strong gelatinase/collagenase activity in zymography. 2-D gel electrophoresis of the extract with gelatin zymography in the second dimension displayed a single spot, identified as ubiquitin-like component upon MALDI/TOF MS/MS analysis. Immunoblot indicated presence of ubiquitin and absence of collagenase in the extract. Collagenase activity of the ubiquitin-like component was confirmed from the change in solubility of collagen in aqueous buffer, degradation of collagen by size-exclusion HPLC and atomic force microscopy. Quantification with DQ-gelatin showed that the extract contains 0.04 U/ml of collagenase activity that was inhibited up to 95% by ubiquitin antibody. Ubiquitin from bovine erythrocytes demonstrated mild collagenase activity. Bioinformatics studies suggest that placental ubiquitin and collagenase follow structurally divergent evolution. This thermostable intrinsic collagenase activity of placental extract might have wide physiological relevance in degrading and remodeling collagen as it is used as a drug for wound healing and pelvic inflammatory diseases.     

A specific collagenase from rabbit fibroblasts in monolayer culture

1. Explants of rabbit skin and synovium in tissue culture secreted a specific collagenase into their culture media. Primary cultures of fibroblast-like cells, which were obtained from these tissues and maintained in culture for up to 14 subculture passages, also secreted high activities of a specific collagenase into serum-free culture medium. Secretion of enzyme activity from the cell monolayer was at constant rate for over 100h and continued for up to 8 days in serum-free culture medium. The enzymic activity released was proportional to the number of cells in the monolayer. 2. The fibroblast collagenase was maximally active between pH7 and 8. At 24 degrees C the collagenase decreased the viscosity of collagen in solution by 60%. The collagen molecule was cleaved into three-quarters and one-quarter length fragments as demonstrated by electron microscopy of segment-long-spacing crystallites (measured as native collagen molecules aligned with N-termini together along the long axis), and by polyacrylamide-gel electrophoresis of the denatured products. The collagenase hydrolysed insoluble collagen, reconstituted collagen fibrils and gelatin, but had no effect on haemoglobin or Pz-Pro-Leu-Gly-Pro-d-Arg (where Pz=4-phenylazobenzyloxycarbonyl). 3. The fibroblast collagenase was partially purified by gel filtration and the molecular weight was estimated as 38000. The activity of the partially purified enzyme was stimulated by 4-chloromercuribenzoate, inhibited by EDTA, cysteine, 1,10-phenanthroline and serum, but was unaffected by di-isopropyl phosphorofluoridate, Tos-LysCH(2)Cl and pepstatin. 4. Long-term cell cultures originating from rabbit skin or synovium from rabbits with experimentally induced arthritis also secreted specific collagenase. Human fibroblasts released only very small amounts of collagenase.     

Collagenase of human skin basal cell epithelioma.

Collagenase of human basal cell epithelioma was purified by sequential ammonium sulfate precipitation, Sephadex gel filtration and affinity chromatography on collagen-polyacrylamide gel. The collagenase, when partially purified, was found to have an approximate molecular weight of 50,000. The purified enzyme contained no caseinolytic activity. On polyacrylamide gel electrophoresis, the purified enzyme gave a single protein band. The purified collagenase cleaved native acid-soluble guinea pig skin collagen at 37 degrees C with a pH optimum of 8. The enzyme was inhibited by EDTA, cysteine, and human serum but not by soybean trypsin inhibitor. Heparin did not stimulate the enzyme activity. Purified collagenase reduced the specific viscosity of native acid-soluble guinea pig skin collagen to 50 per cent of its original value at 27 degrees C. Polyacrylamide gel disc electrophoresis of the reaction products showed bands corresponding to alphaA, betaA, and alphaB fragments. Electron microscopic examination of SLS aggregates of the reaction products showed that the cleavage site by the enzyme was at a point 75 per cent from the "A" end (TCA75) and 25 per cent from the "B" end (TCB25) of the collagen molecule.     

Tetradecanoyl phorbol acetate stimulates latent collagenase production by cultured human endothelial cells

Angiogenesis is associated with the fragmentation of blood vessel basement membranes. Since collagen is a major constituent of basement membranes, cultured human endothelial cells derived from umbilical cord veins were assayed for their ability to produce collagenase. Unstimulated cultured human endothelial cells did not secrete detectable levels of active collagenase into the culture medium. However, if the post-culture medium was treated with trypsin or plasmin, low levels of collagenolytic activity were detected, indicating that endothelial cells secrete small amounts of latent collagenase. Addition of the tumor promoter 12-O-tetradecanoyl phorbol-13-acetate (TPA) to the culture medium stimulated the secretion of collagenase by endothelial cells 5–30 fold. More than 90% of the collagenase was secreted in the latent form. Stimulation of collagenase production was detected at 10^?9 M TPA and was maximal at 10^?8 M TPA. An increase in the rate of collagenase production could be detected within 3 hr after the addition of TPA, and full induction occurred by 12 hr. Cycloheximide (3 μg/ml) or actinomycin D (0.1 μg/ml) inhibited both basal levels of collagenase production and the stimulation of collagenase production by TPA. Phorbol-12,13-didecanoate (PDD), a tumor-promoting analog of TPA, also stimulated collagenase production when administered at the same concentrations that were effective for TPA. However, 4-O-methyl TPA and 4-αPDD, two analogs of TPA which are not tumor promoters, did not stimulate collagenase production at concentrations up to 10^?7 M. The collagenase produced by endothelial cells was a typical vertebrate collagenase as judged by the following criteria: it cleaved collagen into only two fragments which were three quarters and one quarter of the length of the intact molecule; it was inhibited by EDTA and human serum; it was not inhibited by inhibitors of serine, thiol or aspartate proteases. Thus TPA causes an increase in the production of latent collagenase by cultured human endothelial cells.     

Inhibition of type I collagen film degradation by tumour cells using a specific antibody to collagenase and the specific tissue inhibitor of metalloproteinases (TIMP)

Rabbit VX2 tumour cells in culture produced a collagenolytic activity which was shown to be immunologically identical to collagenase from rabbit articular chondrocytes and bone. VX2 cells degraded type I collagen films spontaneously and did not produce detectable levels of the tissue inhibitor of metalloproteinases (TIMP). Chondrocytes, however, required both stimulation of collagenase synthesis and activation to effect lysis and were observed to make appreciable amounts of TIMP. The degradation of type I collagen films by VX2 tumour cells was significantly inhibited by both a specific antibody to rabbit collagenase and by purified TIMP, thus demonstrating the unequivocal role of collagenase in this model system.     

Activation of latent rheumatoid synovial collagenase by human mast cell tryptase

The functional role of mast cells in rheumatoid synovium was investigated by assessing the ability of mast cell tryptase to activate latent collagenase derived from rheumatoid synoviocytes. Tryptase, a mast cell neutral protease, was demonstrated in situ to reside in rheumatoid synovial mast cells, by an immunoperoxidase technique using a mouse mAb against tryptase, and in vitro to be released by dispersed synovial mast cells after both immunologic and nonimmunologic challenge. Each rheumatoid synovial mast cell contains an average of 6.2 pg of immunoreactive tryptase and the percent release values of this protease correlated with those of histamine (r = 0.58, p less than 0.01). The ability of purified tryptase to promote collagenolysis was demonstrated in a dose-dependent fashion using latent collagenase derived from rheumatoid synovium, synovial fluid, IL-1-stimulated cultured synoviocytes, and partially purified latent collagenase derived from conditioned media, with between 10 and 92% of the collagen substrate degraded. [3H] Collagen, treated with tryptase-activated latent collagenase, was subjected to electrophoresis on SDS polyacrylamide gels and autoradiography showed the collagen degradation pattern (A, B) characteristically produced by collagenase. Mast cell lysates also activated synovial latent collagenase yielding 24% digestion of collagen substrate. This activator in mast cell lysates could be inhibited by diisopropylflurophosphate or by immunoadsorption of tryptase. Thus, mast cells may activate metalloproteinases and play a role in the catabolism of collagen that occurs in rheumatoid synovium.     

Purification, characterization and inhibition of human skin collagenase

1. The neutral collagenase released into the culture medium by explants of human skin tissue was purified by ultrafiltration and column chromatography. The final enzyme preparation had a specific activity against thermally reconstituted collagen fibrils of 32mug of collagen degraded/min per mg of enzyme protein, representing a 266-fold increase over that of the culture medium. Electrophoresis in polyacrylamide disc gels showed it to migrate as a single protein band from which enzyme activity could be eluted. Chromatographic and polyacrylamide-gel-elution experiments provided no evidence for the existence of more than one active collagenase. 2. The molecular weight of the enzyme estimated from gel filtration and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis was approx. 60000. The purified collagenase, having a pH optimum of 7.5-8.5, did not hydrolyse the synthetic collagen peptide 4-phenylazobenzyloxycarbonyl-Pro-Leu-Gly-Pro-d-Arg-OH and had no non-specific proteinase activity when examined against non-collagenous proteins. 3. It attacked undenatured collagen in solution at 25 degrees C, producing the two characteristic products TC(A)((3/4)) and TC(B)((1/4)). Collagen types I, II and III were all cleaved in a similar manner by the enzyme at 25 degrees C, but under similar conditions basement-membrane collagen appeared not to be susceptible to collagenase attack. At 37 degrees C the enzyme attacked gelatin, producing initially three-quarter and one-quarter fragments of the alpha-chains, which were degraded further at a lower rate. As judged by the release of soluble hydroxyproline peptides and electron microscopy, the purified enzyme degraded insoluble collagen derived from human skin at 37 degrees C, but at a rate much lower than that for reconstituted collagen fibrils. 4. Inhibition of the skin collagenase was obtained with EDTA, 1,10-phenanthroline, cysteine, dithiothreitol and sodium aurothiomaleate. Cartilage proteoglycans did not inhibit the enzyme. The serum proteins alpha(2)-macroglobulin and beta(1)-anti-collagenase both inhibited the enzyme, but alpha(1)-anti-trypsin did not. 5. The physicochemical and enzymic properties of the skin enzyme are discussed in relation to those of other human collagenases.     

The presence of collagenase in collagen preparations.

The frequently observed instability of neutral salt solutions of native collagen extracted from various sources and partially purified by standard procedures has been studied by disc electrophoresis in polyacrylamide gel and by electron microscopic examination of segment long spacing crystallites. The phenomenon has revealed time and temperature dependency, pH optima near neutrality, and inhibition by sodium EDTA and serummin addition, collagen breakdown has been found to be quantitatively related to the state of aggregation of the substrate, being more marked in reconstituted collagen gels than in collagen in solutionma typical pattern of animal collagenase degradation of native collagen into two fragments designated as TC-A and TC-B has been observed under certain conditions. It is concluded that the degradation of native collagen in neutral salt solution is due to a specific collagenase, and that this enzyme probably remains bound to collagen throughout the process of extraction and partial purification. Experiments with gelatin suggest that, in addition to collagenase, a nonspecific proteolytic activity may also be present in collagen preparations.     

Activation of human breast carcinoma collagenase through plasminogen activator

Latent collagenase activity was detected in the media of a well-characterized line of human breast carcinoma cells maintained for over two years in culture. The media also contained sufficient plasminogen activator to convert extrinsically added plasminogen to plasmin which in turn activated the collagenase. During culture of the breast carcinoma in serum-free medium, collagenase activity was maximum on day 12 whereas plasminogen activator activity changed little with time. Using type I collagen as a substrate, the activated breast tumor collagenase produced $\text{3}\text{4}\text{?}\text{1}\text{4}$ fragments consistent with a mammalian collagenase. These findings suggest a pathologic role of plasminogen activator in the activation of latent collagenase during tumor invasion.A number of investigators have postulated that proteases may play a role in tumor invasion (1–5). Collagenase is one such protease which is active at neutral pH and specifically cleaves triple helical collagen into two ($\text{3}\text{4}\text{?}\text{1}\text{4}$ fragments (6). Secretion of collagenase by tumor cells migrating from the primary mass provides an attractive hypothesis for the mechanism of tumor invasion of surrounding host connective tissue—since the local environment would likely be at neutral pH. Consequently, a number of investigators have reported significant levels of collagenase activity in a wide variety of tumors (7–14). Abramson (13) has correlated aggressive $\text{in vivo}$ growth in carcinomas of the head and neck with collagenase activity, and Kuettner et al. (14) have postulated that inhibitors of collagenase may prevent tumors from invading cartilage.Collagenase is produced in both latent and active forms (6). The latent form can be activated with brief protease treatment (15). Since one of the proteases capable of activating collagenase is plasmin (15), the possibility arose that tumor cells could activate collagenase through plasminogen activator. Plasminogen activator secreted by tumor cells (4, 5) could convert plasminogen zymogen to plasmin which would in turn activate latent tumor collagenase. Testing this hypothesis $\text{in vitro}$ was the subject of the present study.Previous studies on collagenase from human carcinoma (7, 13, 14) have suffered from the drawback that contaminating inflammatory cells and fibroblasts may have been the source of the collagenase. Therefore, we have studied collagenase production from cultured human breast carcinoma cells which have been well characterized to be mammary epithelial in origin, malignant in karyotype, and able to grow in nude mice. Production of collagenase from these cells is therefore unequivocally of human carcinoma origin. The time course of latent collagenase and plasminogen activator secretion by these cultured tumor cells was studied following withdrawal of serum. To test whether plasminogen activator was secreted in sufficient amounts to indirectly activate latent collagenase, collagenase activity of the culture media was studied after the extrinsic addition of plasminogen. Finally, to verify that the tumor-secreted collagenase cleaved type I collagen at a single locus, enzyme degradation products were studied by gel electrophoresis.     

Serine proteinase activation of latent human skin collagenase

Latent and active collagenase were demonstrated following direct extraction from normal skin homogenates with 0.1M calcium chloride at 60 degrees C. 83% of the collagenase activity was in latent form and could be maximally activated with trypsin. Partial activation of the latent enzyme could also be demonstrated by incubation of the skin extract without added trypsin. This endogenous activation was inhibited by the addition of soya bean trypsin inhibitor, trasylol, di-isopropylphosphofluoridate and phenylmethanesulphonylfluoride, none of which inhibited collagenase directly. This suggests that the skin extracts contain a collagenase activating enzyme with the inhibition profile of a serine proteinase. A chymotryptic proteinase with a similar inhibition profile was extracted from normal human skin and partially purified. This enzyme activated fibroblast procollagenase derived from tissue culture of normal skin. The procollagenase was also partially activated by plasmin and chymotrypsin. This is the first demonstration of a collagenase activating enzyme in human skin and raises the possibility that collagenase activation by this mechanism may be responsible for collagen degradation in some disease processes.     

Serotonin: an inducer of collagenase in myometrial smooth muscle cells.

Rat myometrial smooth muscle cells in culture actively produce collagenase in medium containing fetal bovine serum, but not in medium containing newborn bovine serum or containing fetal serum adsorbed with dextran-coated charcoal. A dialyzable molecule has been isolated from fetal bovine serum, which restores the ability of the smooth muscle cells to produce collagenase. The molecule has been purified and identified as serotonin (5-hydroxytryptamine). Cells cultured in medium depleted of serotonin for 3 days fail to produce collagenase, as assessed both enzymatically and immunologically. Addition of serotonin promptly restores the ability of the cells to produce the enzyme. The EC50 for serotonin is approximately 2 microM; maximum stimulation of collagenase production is observed at 5 microM. The response is specific for serotonin: a wide variety of compounds tested, either related to serotonin or of potential reproductive significance, were without effect in the induction of collagenase production by the cells. No changes in DNA content, general protein synthesis, or cellular collagen production were observed as a consequence of serotonin depletion or restoration, suggesting a selective effect of the compound on collagenase production. The effect of serotonin was also selective to myometrial smooth muscle cells; collagenase-producing fibroblasts from skin and cervix displayed no serotonin requirement for enzyme production. Studies using specific agonists or antagonists for a variety of serotonin receptor subtypes suggest that the 5-HT-2 receptor mediates the serotonin induction of collagenase in these cells. Preliminary evidence indicates that cultured human myometrial smooth muscle cells are also dependent upon serotonin for collagenase production. The evidence in this study suggests the possibility that serotonin serves as a signal to begin the massive collagen degradation that occurs in the postpartum uterus.     

The presence of collagenase in collagen preparations

The frequently observed instability of neutral salt solutions of native collagen extracted from various sources and partially purified by standard procedures has been studied by disc electrophoresis in polyacrylamide gel and by electron microscopic examination of segment long spacing crystallites. The phenomenon has revealed time and temperature dependency, pH optima near neutrality, and inhibition by sodium EDTA and serum. In addition, collagen breakdown has been found to be quantitatively related to the state of aggregation of the substrate, being more marked in reconstituted collagen gels than in collagen in solution. A typical pattern of animal collagenase degradation of native collagen into two fragments designated as TC^A and TC^B has been observed under certain conditions. It is concluded that the degradation of native collagen in neutral salt solution is due to a specific collagenase, and that this enzyme probably remains bound to collagen throughout the process of extraction and partial purification. Experiments with gelatin suggest that, in addition to collagenase, a nonspecific proteolytic activity may also be present in collagen preparations.     

Functional evaluation of cultured rabbit osteoblast-like cells

For the improvement of the adult osteoblast culture, the osteoblasts of young adult rabbit endosteal from long bones were isolated by collagenase digesting separation. 0.1% of type-I collagen precoated culture flasks were used as substrate for isolated bone cell growth. Morphological examination of cultured cells under a phase-contrast microscope, SEM and TEM observations showed a structure similar to osteoblast in vivo. Histochemical examination of alkaline phosphatase demonstrated 97% purity of cultured osteoblasts. The presence of calcium deposit activity in cultured cells was demonstrated by Van Kossa stain. High activity of alkaline phosphatase and inorganic pyrophosphatase in cultured osteoblasts as determined by biochemical analysis. High calcium uptake in cultured osteoblasts was demonstrated by radioisotope labelled 45CaCl12. According to these methods, it was indicated that the cells isolated from young rabbit long bone endosteal were osteoblast-like and still maintained their biological function. Our system for culturing osteoblast-like cells is a successful attempt in growing bone tissue in vitro starting from isolated bone cells. Therefore, this modified method for bone cell culture on collagen precoated culture flasks could be used as the experimental model in studies concerning the osteoblasts in vitro.     

Stimulation of collagenase production by collagen in mammalian cell cultures.

In this study, we investigated the possible regulatory role of collagen in collagenase production by cultured human skin fibroblasts and human and rabbit synovial cells. Addition of types I, II or III collagen in solution to the culture media markedly stimulated trypsin-activable collagenase activity in these cultures. In the human cell cultures the stimulatory effect of collagen was further enhanced by a soluble factor isolated from human monocyte culture media (Dayer, Russell and Krane, 1977). Both native and denatured forms of collagen stimulated enzyme production; their relative efficacy varied among the different types. The native form of both types I and II collagen showed a greater effect on collagenase production than the corresponding denatured form, whereas with type III collagen the denatured form was more effective.     

Characterization and serum inhibition of neutral collagenase from cultured dog gingival tissue.

1. Explants of dog gingiva, maintained in culture for 9 days in the absence of serum, released a collagenase (EC 3.4.24.3) into the medium. The yield of active enzyme reached a maximum after 5-8 days with concomitant release of collagen degradation products from the explants. 2. The enzyme attacked undenatured collagen in solution at 25 degrees C resulting in a 58% loss of specific viscosity and producing the two characteristic products TCA(3/4) and TCB(1/4). Electron microscopy of segment-long-spacing crystallites of these reaction products showed the cleavage locus of the collagen molecule at interband 40. 3. Optimal enzyme activity was observed over the pH range 7.5-8.5 and a molecular weight of approximately 35,000 was derived from gel filtration studies. EDTA, 1,10-phenanthroline, cysteine and dithiothreitol all inhibited collagenase activity. Proteoglycan derived from porcine and human cartilage did not inhibit the enzyme. 4. The enzyme was inhibited by the dog serum proteins alpha2-macroglobulin and a smaller component of molecular weight approximately 40,000. This small component was purified by column chromatography utilising Sephadex G-200, DEAE A-50, and G-100 (superfine grade). Agarose electrophoresis of the purified component showed it to represent a beta-serum protein. alpha1-Antitrypsin did not inhibit the enzyme. 5. The physiological importance of the natural serum inhibitors and gingival collagenase are discussed in relation to latent enzyme and periodontal disease.     

Effect of 1,25-dihydroxyvitamin D-3 on phosphate uptake into chick intestinal brush border membrane vesicles

The production of collagenase by human skin explants in culture is prevented by 10(-8) M dexamethasone, 5 . 10(-4) M dibutyryl cyclic AMP, or 2.5 . 10(-3) M theophylline. Decreases in collagenase activity are paralleled by reductions in the degradation of explant collagen during the culture period. Progesterone, which effectively inhibits collagenase production in rat uterine explant cultures, has no effect on human skin explants. The inhibition by cyclic AMP is nucleotide specific. When partially inhibitory concentrations of dexamethasone and dibutyryl cyclic AMP, or dexamethasone and theophylline, are added to culture medium together, the resultant inhibition is that predicted by additivity. Synergistic inhibition, as observed in rat uterus between progesterone and dibutyryl cyclic AMP, fails to occur. Dexamethasone inhibits the production of collagenase by cultured explants of rat uterus, with complete inhibition occurring at 10(-7) M steroid. Synergism between glucocorticoids and dibutyryl cyclic AMP or between dexamethasone and progesterone could not be demonstrated in the uterine culture system. These results suggest the existence of three regulatory systems for the control of collagenase production in mammalian tissues, and that cooperativity between systems may occur on a tissue-specific basis.     

Effects of procollagen peptides on the translation of type II collagen messenger ribonucleic acid and on collagen biosynthesis in chondrocytes

Type II procollagen messenger ribonucleic acid (mRNA) was isolated from chick sternum and rat chondrosarcoma cells and translated in a reticulocyte lysate cell-free system. A high molecular weight band was identified as type II procollagen by gel electrophoresis, collagenase digestion, and specific immunoprecipitation. The translation of type II mRNA was specifically inhibited by addition of type I procollagen amino-terminal extension peptide. When this peptide was added to the media of cultured fetal calf chondrocytes, chick sternal chondrocytes, or chick tendon fibroblasts, no inhibition of collagen synthesis was evident. These data suggest a general regulation of collagen biosynthesis by these peptides in the cell-free translation system. However, as indicated by the cell culture experiments, cellular characteristics and evolutionary divergence of animal species seem to restrict the effect of the peptides.     

Collagenase synthesis in clonal rabbit odontoblast-like cells (RP cells)

Post-confluent cultures of cloned rabbit odontoblast-like cells (RP: Rabbit Pulp cells) produced latent collagenase, which was isolated from serum-containing culture media by heparin-Sepharose affinity chromatography. RP collagenase was purified 4,420-fold from serum-containing medium to a specific activity of 1,313 units/mg with a yield of 14% by heparin-Sepharose affinity chromatography, carboxymethyl-cellulose ion-exchange chromatography, and by immunoadsorption chromatography. The RP cell culture appears to be a suitable model to use for studying collagenase synthesis in mineralized tissue-forming cells and for elucidating the mechanism of collagen degradation in pulp tissue and dentin matrix.     

Production of procollagenase by cultured human keratinocytes

Using a collagen film assay utilizing 14C-labeled type I collagen, we demonstrated that cultured human keratinocytes produced a procollagenase after treatment with the tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA). Production of collagenase paralleled alterations in cellular morphology induced by TPA. When procollagenase was immunoprecipitated with antibody to human fibroblast collagenase and analyzed on sodium dodecyl sulfate-polyacrylamide gels, the zymogen was revealed as a 56- and 51-kDa doublet. The keratinocyte-derived collagenase was a neutral metalloprotease, required activation with trypsin for detection in the collagenase assay and produced the characteristic three-quarter and one-quarter length collagen cleavage products when incubated with type I collagen at 25 degrees C. The enzyme was inhibited by serum and cysteine and was largely unaffected by serine, thiol, and carboxyl protease inhibitors. Cycloheximide inhibited the TPA-induced production of collagenase, suggesting that the procollagenase was not stored preformed in the keratinocytes. Keratinocytes treated with a tumor-promoting analogue of TPA also produced collagenase, but cells treated with cytochalasin B, interleukin-1, or two non-tumor promoting phorbol esters did not. Keratinocyte-derived collagenase may play a role in wound healing and morphogenesis.     

Comparison of collagen gels and mammary extracellular matrix as substrata for study of terminal differentiation in rabbit mammary epithelial cells

Mammary epithelial cells were prepared by collagenase digestion of tissue from mid-pregnant rabbits and cultured for up to 6 days on either collagen gels or an extracellular matrix prepared from the same tissue. The behaviour of the cells in serum-supplemented medium containing combinations of insulin, prolactin, hydrocortisone, estradiol and progesterone were monitored by measuring rates of casein synthesis, lactose synthesis, DNA synthesis and protein degradation. After 6 days, epithelial cells on floating collagen gels showed substantial increases in casein synthesis and DNA synthesis over freshly-prepared cells, following a decline during the first 3 days when the collagen gels are contracting. The optimum hormone combination for casein synthesis was insulin + prolactin + hydrocortisone, whereas for optimum DNA synthesis the additional presence of estradiol and progesterone was required. Cells on extracellular matrix showed increased rates of both casein synthesis and DNA synthesis by day 6 in the presence of insulin + prolactin + hydrocortisone, with additional estradiol + progesterone having an inhibitory effect. Whereas on day 2 rates of intracellular protein degradation were generally lower in cells on extracellular matrix, by day 6 rates of protein degradation were lowest in cells cultured on collagen gels with insulin + prolactin + hydrocortisone. In all cases, rates of lactose synthesis fell to low levels as the culture proceeded. Pulse-chase labelling of freshly-prepared cells with [32P]orthophosphate in medium containing serum and insulin + prolactin + hydrocortisone demonstrated that newly-synthesized casein was degraded during its passage through the epithelial cell. The influences of the collagen gels and extracellular matrix and of the hormone combinations on epithelial cell differentiation and secretory activity are discussed.