Insulin stimulates secretion of a collagenase inhibitor by Swarm rat chondrosarcoma chondrocytes

Swarm rat chondrosarcoma chondrocytes produce an inhibitor of collagenase similar to that found in bovine articular chondrocytes and extracts of bovine scapular cartilage. These cells synthesize normal levels of cartilage type proteoglycans when cultured in serum free medium with insulin. Collagen synthesis is also increased when insulin is added to chondrosarcoma chondrocytes. We have demonstrated that insulin stimulates collagenase inhibitor production by these chondrocytes. Enhancement of inhibitory activity occurs over the range of 10 to 1000 ng/ml. A 3.2 fold stimulation was observed at a concentration of 1 microgram/ml. There was a lag period of 24 to 48 hours before the insulin effect became evident. Latent or active collagenase was not detectable under these conditions. These results suggest that the hormone insulin controls the levels of collagen in this tumor by stimulating synthesis of collagen and inhibitors of collagenase.     

Human skin fibroblast collagenase inhibitor. Comparative studies in human connective tissues, serum, and amniotic fluid

In order to gain insight into the biological significance of a collagenase inhibitor secreted by human skin fibroblasts, we examined various human connective tissues and body fluids for such a protein. The inhibitors found in these tissues were compared immunologically to skin fibroblast inhibitor by Ouchterlony analysis and by the development of a highly specific enzyme-linked immunosorbent assay (ELISA). Using this ELISA, cell cultures of human skin fibroblasts, corneal fibroblasts, gingival fibroblasts, and adult and fetal lung fibroblasts secreted similar amounts of immunoreactive inhibitor protein. Each culture medium displayed a reaction of immunologic identity with skin fibroblast inhibitor when examined in Ouchterlony gel diffusion. In testing for functional inhibitory activity, the same 1:1 stoichiometry of collagenase inhibition was observed in each culture medium that characterizes the human skin inhibitor. Other mesodermally derived human cell types, including human fetal osteoblasts, uterine smooth muscle cells, fibrosarcoma cells, and explants of tendon and articular cartilage behaved in the same manner as the fibroblast cultures. Because collagenase inhibitors with biochemical similarities to skin fibroblast inhibitor have been described in serum and in amniotic fluid, we also examined these sources of inhibitory proteins. The data indicate that both serum and amniotic fluid contain collagenase inhibitors which are immunologically and functionally identical with the skin fibroblast inhibitor. The concentration of inhibitor in serum, as measured by ELISA assay, is 1.03 +/- 0.27 micrograms/ml. The results suggest that collagenase inhibitors which are functionally equivalent and immunologically identical with human skin fibroblast collagenase inhibitor are synthesized by many, if not all, fetal and adult mesodermal tissues in the human organism. The inhibitor apparently gains access to certain body fluids such as serum and amniotic fluid. This inhibitor protein may, therefore, function in the regulation of collagen degradation in most human connective tissues.     

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.     

Autocrine control of collagenase synthesis by synovial fibroblasts

Fibroblasts respond to exogenous stimuli, such as Interleukin 1, phorbol esters, or crystals of monosodium urate monohydrate, by synthesizing and secreting large quantities of collagenase. Here we show that addition of exogenous stimuli results in the production of an autologous protein that is, itself, capable of inducing collagenase. This autocrine has been partially purified. Activity resides in a protein(s) with a pl of 5 or 8 and with Mr of approximately 15K. Conversely, conditioned medium taken from unstimulated cultures contains an inhibitor of collagenase synthesis. This protein, which has a Mr approximately 20-25k by HPLC gel filtration antagonizes collagenase synthesis induced by phorbol esters, exogenous parallel 1, and the autologous inducer. We conclude that synovial fibroblasts regulate collagenase synthesis via an autocrine mechanism that includes the synthesis of both an inducer and inhibitor. Both proteins are active at nanomolar amounts and may function as polypeptide hormones in regulating collagenase synthesis and, hence, connective tissue remodeling.     

Purification and partial amino acid sequence of a bovine cartilage-derived collagenase inhibitor

An inhibitor of mammalian collagenase from bovine scapular cartilage has been purified to homogeneity. The inhibitor, extracted from cartilage using 2 M NaCl, was applied to an A-1.5m gel filtration column. Inhibitor eluted at an apparent Mr of 28,000. Further purification was achieved by ion exchange chromatography, gel filtration, and reverse-phase high performance liquid chromatography. A purification of greater than 1,000-fold was achieved. The inhibitor was judged homogeneous by the appearance of a single band on a silver-stained 15% sodium dodecyl sulfate-polyacrylamide gel. Reduced inhibitor had an Mr of 27,400, unreduced inhibitor had an Mr of 23,900. NH2-terminal sequence data were obtained for the first 45 residues. The bovine cartilage-derived inhibitor exhibits greater than 65% homology over the first 23 residues with a collagenase inhibitor purified from human skin fibroblasts maintained in cell culture. This is the first demonstration that collagenase inhibitors extracted directly from tissue may be similar to those obtained from culture medium.     

Coordinate increase in collagenase mRNA and enzyme levels in human fibroblasts treated with the tumor cell factor, TCSF

Cocultures of human fibroblasts and LX-1 human lung carcinoma cells expressed 8-10 fold higher levels of collagenase mRNA than the sum of the individual cells, in parallel with similar increases in collagenase activity. Addition of the tumor cell collagenase stimulatory factor, TCSF, purified from LX-1 cells, to these fibroblasts also gave a 3-4 times increase in collagenase mRNA level. However, various fibroblast cell lines differed in their response to TCSF stimulation. Thus one cell line, GM 1391, did not respond to TCSF but responded to another potent collagenase stimulator, tetradecanoyl phorbol ester. Another cell line 5383 did not respond significantly to either agent. In each case collagenase activity and mRNA levels responded in a parallel fashion.     

Metalloproteinase inhibitors from bovine cartilage and body fluids

Inhibitors of the mammalian metalloproteinases, collagenase, proteoglycanase and gelatinase were isolated from bovine cartilage (extracts and culture medium) and bovine amniotic fluid and serum. These inhibitors either bind or do not bind to concanavalin-A--Sepharose, with Mr (gel filtration) of about 30 000 and 20 000, respectively. Cartilage and chondrocyte culture media contained only concanavalin-A-binding inhibitors whereas cartilage extracts contained only a non-binding inhibitor: serum and amniotic fluid contained both forms of inhibitory activities. In moist biochemical respects, particularly in their abilities to inhibit metalloproteinases, all of the inhibitors were found to be similar. It is concluded that the forms of the inhibitors that differ in Mr may be closely related to the tissue inhibitor of metalloproteinases (TIMP) previously purified from rabbit and human sources. These findings help to clarify other studies on collagenase inhibitors and support the concept that TIMP-like inhibitors may be important in the control of connective tissue degradation.     

The Role of the Biochemical and Biophysical Environment in Chondrogenic Stem Cell Differentiation Assays and Cartilage Tissue Engineering

The field of regenerative medicine offers hope for the development of a cell-based therapy for the repair of articular cartilage (AC). Yet, the greatest challenge in the use of stem cells for tissue repair, is understanding how the cells respond to stimuli and using that knowledge to direct cell fate. Novel methods that utilize stem cells in cartilage regeneration will require specific spatio-temporal controls of the biochemical and biophysical signaling environments. Current chondrogenic differentiation research focuses on the roles of biochemical stimuli like growth factors, hormones, and small molecules, and the role of the physical environment and mechanical stimuli, such as compression and shear stress, which likely act through mechanical receptors. Numerous signals are associated with chondrogenic-like activity of cells in different systems, however many variables for a controlled method still need to be optimized; e.g., spatial and temporal application of the stimuli, and time of transplantation of an engineered construct. Understanding the necessary microenvironmental signals for cell differentiation will advance cell therapy for cartilage repair.     

Comparison of androgen biosynthesis in isolated leydig cells from rat and mouse testis: incubation and superfusion studies

Production of testosterone by highly purified Leydig cells prepared from rat and mouse testes is compared. Testosterone formation is improved to a higher degree in rat (2.7-fold) than in mouse (1.7-fold) cells by collagenase treatment of the testis compared with mechanical isolation. Mouse Leydig cells respond to exogenous stimuli (choriogonadotropin, dibutyryl cyclic AMP) with 2.4-fold higher testosterone secretion than rat cells. A 1.7-fold increased conversion of androgen precursors to testosterone by mouse compared with rat Leydig cells is demonstrated in static incubations as well as in steady-state superfusion experiments and can be derived from enhanced androstenedione reduction and a less inhibitory effect of progesterone on this process in mouse Leydig cells.     

Clonal growth of differentiated rabbit cartilage cells

Single cell suspensions have been prepared from rabbit cartilage by collagenase digestion in the presence of fetal bovine serum. When inoculated into medium F12 supplemented with 5% fetal bovine serum and 5% rabbit serum, the cartilage cell suspensions yield large healthy colonies of epithelial-like cells with an average plating efficiency of 47%. At the end of a 14 day incubation period, the centers of many of the colonies are thickened into multilayered aggregates. Such colonies exhibit serveral cartilage-like properties, including metachromatic staining with toluidine blue, dense brown staining with bismark brown, bright green staining with alcian green, and a refractile matrix which can be seen with the phase contrast microscope to surround the living cells. Similar properties have also been observed in second and third passage subcultures.     

β1-Integrins in the cartilage matrix

Integrins are cell-surface receptors that mediate cell attachment to extracellular matrix components. The pericellular matrix in cartilage not only is a mechanical framework, but is also important for chondrocyte differentiation and stabilization of the phenotype. The interaction between chondrocytes and pericellular matrix is mediated, in part, by integrin receptors. We have previously demonstrated the presence of beta1-integrins in the cartilage matrix of organoid culture of limb buds from 12-day-old mouse embryos by immunohistological methods. In order to corroborate these findings, we have further investigated the distribution of integrins in the cartilage matrix by immunoelectron microscopy and by immunoprecipitation methods. Cartilage tissue of limb buds of 17-day-old mouse embryos was treated with collagenase and the cell-free and cellular protein-free supernatant was removed and used for immunoprecipitation experiments. Immunoprecipitation with antibodies against beta1-, alpha1-, alpha3-, and alpha5beta1-integrins and collagen type II, followed by immunoblotting with the same antibodies, demonstrated the presence of these integrins and collagen type II in the supernatant. The integrins found in the cartilage matrix could have been either secreted or shed by the cells. The question as to whether they have a function in the cartilage matrix, such as interlinking, in the matrix organization or in the stabilization of matrix components remains to be elucidated.     

Temperature-dependent dissociation of Lucké renal adenocarcinoma cells

Fragments of Lucké renal adenocarcinoma were subjected to dissociation by rapid shaking after exposure to a divalent cation-free electrolyte solution, with or without 5 X 10(-4) M ethylenediaminetetraacetate (EDTA), at 7 degrees C and 28 degrees C. More cells detached at 28 degrees C than at 7 degrees C. Dissociation of cells from normal mesonephros fragments was minimal at both temperatures. It has been shown else-where that this frog tumor elaborates collagenase in a temperature-dependent manner. More collagenase is detected at 30 degrees C than at 7 degrees C. Normal kidney elaborates low levels of collagenase at both temperatures. Because our results suggested the possibility that some dissociation of the tumor cells may have been attributable to tumor-elaborated collagenase, we studied the effect of two collagenase inhibitors on dissociation. Both EDTA at high concentration and cysteine inhibit collagenase and both diminished tumor-cell dissociation.     

Degradation of cartilage proteoglycan and collagen by synovial cells. Stimulation by macrophages under activation by phagocytosis, lymphocyte factors, bacterial products or other inflammatory stimuli

When cultured together with dead 35S-labelled cartilage discs or at the surface of [3H]proteoglycan/[14C]collagen-coated plates, synovial cells from either arthritic or normal rabbit joints digested both the proteoglycan and the collagen of the substrates after a lag-period of 1-2 days. These digestions were inversely related to the age (number of subculture passages) of the synovial cells and they could be modulated by serum components that were either inhibitory or stimulatory. They were dependent on a protein synthesis by the cells and were paralleled, in young cultures, by the release of collagenase and of a proteoglycan-degrading neutral proteinase. The co-culture of synovial cells with macrophages or their culture with macrophage-conditioned culture media caused a more rapid and more extensive degradation of collagen and proteoglycan due to the stimulation of the synovial cells by a nondialysable macrophage factor. The production of this synovial cell-activating 'matrix regulatory monokine' by the macrophage was enhanced by several immunological or inflammatory stimuli such as lymphocyte factors, phagocytosis, asbestos fibres, endotoxin, adjuvant muramyl dipeptide or chemotactic formyl-methionyl peptide, as well as by other membrane-active agents (phorbol myristate acetate, concanavalin A). It is presumed that these interactions are of importance in the development of cartilage destruction in rheumatoid and other chronic inflammatory arthritis.     

Adult ventricular myocytes isolated from CHF 146 and CHF 147 cardiomyopathic hamsters

Single ventricular myocytes have been isolated from normal and cardiomyopathic hamsters using a collagenase method. The procedure produces calcium-tolerant myocytes that are viable and appear on light and electron microscopic examination to be healthy. These cells respond to electrical stimulus and have normal intracellular resting and action potentials.     

Interchain disulfide bonds at the COOH-terminal end of procollagen synthesized by matrix-free cells from chick embryonic tendon and cartilage.

Matrix-free cells from tendons and cartilage of chick embryos were incubated in suspension, and the procollagens secreted by the cells were isolated in the presence of protease inhibitors. Tendon procollagen was shown to contain both NH_2? and COOH-terminal extensions and interchain disulfide bonds were located in the COOH-terminal region. A disulfide-linked fragment previously isolated after digestion of the molecule with bacterial collagenase was shown to originate from the COOH-terminal end. Cartilage procollagen was also shown to contain interchain disulfide bonds in the COOH-terminal region.     

Temperature-dependent dissociation of Lucké renal adenocarcinoma cells

Abstract. Fragments of Lucké renal adenocarcinoma were subjected to dissociation by rapid shaking after exposure to a divalent cation-free electrolyte solution, with or without 5 × 10⁻⁴ ethylenediaminetetraacetate (EDTA), at 7° C and 28° C. More cells detached at 28° C than at 7° C. Dissociation of cells from normal mesonephros fragments was minimal at both temperatures. It has been shown elsewhere that this frog tumor elaborates collagenase in a temperature-dependent manner. More collagenase is detected at 30° C than at 7° C. Normal kidney elaborates low levels of collagenase at both temperatures. Because our results suggested the possibility that some dissociation of the tumor cells may have been attributable to tumor-elaborated collagenase, we studied the effect of two collagenase inhibitors on dissociation. Both EDTA at high concentration and cysteine inhibit collagenase and both diminished tumor-cell dissociation.     

Quantitative ultrasonic assessment for detecting microscopic cartilage damage in osteoarthritis

Osteoarthritis (OA) is one of the most prevalent chronic conditions. The histological cartilage changes in OA include surface erosion and irregularities, deep fissures, and alterations in the staining of the matrix. The reversibility of these chondral alterations is still under debate. It is expected that clinical and basic science studies will provide the clinician with new scientific information about the natural history and optimal treatment of OA at an early stage. However, a reliable method for detecting microscopic changes in early OA has not yet been established. We have developed a novel system for evaluating articular cartilage, in which the acoustic properties of the articular cartilage are measured by introducing an ultrasonic probe into the knee joint under arthroscopy. The purpose of this study was to assess microscopic cartilage damage in OA by using this cartilage evaluation system on collagenase-treated articular cartilage in vivo and in vitro. Ultrasonic echoes from articular cartilage were converted into a wavelet map by wavelet transformation. On the wavelet map, the maximum magnitude and echo duration were selected as quantitative indices. Using these indices, the articular cartilage was examined to elucidate the relationships of the ultrasonic analysis with biochemical, biomechanical and histological analyses. In the in vitro study, the maximum magnitude decreased as the duration of collagenase digestion increased. Correlations were observed between the maximum magnitude and the proteoglycan content from biochemical findings, and the maximum magnitude and the aggregate modulus from biomechanical findings. From the histological findings, matrix staining of the surface layer to a depth of 500 mum was closely related to the maximum magnitude. In the in vivo study, the maximum magnitude decreased with increasing duration of the collagenase injection. There was a significant correlation between the maximum magnitude and the aggregate modulus. The evaluation system therefore successfully detected microscopic changes in degenerated cartilage with the use of collagen-induced OA.