In vitro carcinogenesis of mammary epithelial cells byN-nitroso-N-methylurea using a collagen gel matrix culture

Summary Carcinogenesis is a lengthy process which eventually culminates in the transformed phenotype, cancer. However, much remains to be defined about the process of transformation. In vivo models for the study of the carcinogenic process present limitations because it is not possible to detect the premalignant stages in the animals. An in vitro model, on the other hand, facilitates the study of the carcinogenic process because it enables one to dissect out the crucial events required for carcinogenesis to occur. As carcinogenesis is believed to be a multistep process; initiation, promotion, and progression, a multistep, in vitro system has been devised in our laboratory to mimic each of these stages. We have previously shown the formation of “microtumors” in collagen gels, induced by 7,12-dimethylbenz(a)anthracene. In the present study the direct acting water soluble, mammary carcinogen,N-nitroso-N-methylurea (NMU) was used for tumorigenesis of mammary epithelial cells in culture. Mammary epithelial cells from virgin Sprague-Dawley rats were propagated and exposed to single or multiple doses of NMU while growing as a monolayer in glass petri dishes (initiation). Initiated cells were then plated into a collagen gel matrix culture. Prolonged growth in the collagen gels afforded for the progression of the transformed cells into discernable microtumors in the three-dimensional matrix of the collagen. The morphology of these “tumors” was determined by histologic sections of the gels. Fewer, if any, such structures existed in the untreated gels.     

Animal models for breast cancer

Rodent mammary tumors induced by chemical carcinogens have proven to be very useful in the genetic analysis of initiation, promotion and progression of mammary carcinogenesis. We are studying rat mammary carcinomas induced by the chemical carcinogen, N-nitroso-N-methylurea. The earliest genetic event observed in the mammary gland is the activation of Ha-ras oncogenes, which is followed by promotion of the initiated cells by hormones involved in puberty. Preferential amplification of the mutated Ha-ras allele, of PRAD-1 and IGF2, loss of expression of the mitogenic growth factor gene, MK, and mutation in the tumor suppressor gene, p53, are seen in the mammary tumors during tumor progression.     

Isolation of EpH4 mammary epithelial cell subpopulations which differ in their morphogenetic properties

Summary EpH4 is a nontumorigenic cell line derived from spontaneously immortalized mouse mammary gland epithelial cells (Fialka et al., 1996). When grown in collagen gels, EpH4 cells give rise to different types of structures, e.g., solid cords or branching tubes. By removing and subsequently dissociating single three-dimensional colonies of defined morphology, we have isolated six clonal subpopulations of EpH4 cells which display distinct morphogenetic properties in collagen gel cultures. Thus, cells from the H₁B clone form branching cords devoid of a central lumen, K₃A₃ cells from cords enclosing small multifocal lumina, and J₃B₁ cells form large cavitary structures containing a wide lumen. I₃G₂ cells form either cords or tubes, depending on the type of serum added to the culture medium. Finally, when grown in serum-free medium, Be1a cells form spherical cysts, whereas Be4a cells form long, extensively branched tubes. In additional assays of morphogenesis, i.e., cell sandwiching between two collagen gels or culture on a thick layer of Matrigel (a laminin-rich extracellular matrix), all clones form epithelial-cell-lined cavitary structures, except H₁B cells which are unable to generate lumina under these conditions. The EpH4 sublines we have isolated provide an in vitro system for studying the mechanisms responsible for lumen formation and branching morphogenesis, as well as for identifying the factors which subvert these developmental processes during mammary carcinogenesis.     

Similar growth pattern of mouse mammary epithelium cultivated in collagen matrix in vivo and in vitro

Mouse mammary ductal cells cultured in type I collagen gels give rise to three-dimensional multicellular outgrowths consisting of thin spikes which are often branched, and which may have pointed or blunt ends. The significance of these spikes to normal ductal morphogenesis has been unclear, since identical structures are not known to occur in vivo; conversely, it has not been possible to maintain in gel culture the highly structured end buds which are characteristic of ductal elongation in the animal. In order to evaluate whether the pattern of radiating spikes observed in collagen gel cultures results from chemical or physical peculiarities of the culture environment, a small volume of unpolymerized type I collagen solution was injected into mammary gland-free fat pads of young adult mice. After the bubble of collagen had polymerized, an implant of mammary ductal epithelium was introduced into the center of the gel. Histological examination of the implants after 3 to 6 days of growth revealed numerous small epithelial spikes, similar to those observed in gel culture, extending into the fibrous matrix. The early stages of regeneration of mammary implants placed in gland-free fat pads were then examined without the addition of exogenous collagen. In cases where the epithelium happened to contact a fibrous region of the fatty stroma, spikes were also seen to form in these natural collagenous substrates. Whether or not exogenous collagen was used, normal end buds were formed only when epithelial spikes contacted adipocytes. It was concluded that the three-dimensional pattern of radiating tubules in collagen gels in vitro is not merely an artifact of culture, but has a counterpart in vivo whereever regenerating mammary epithelium is surrounded by fibrous stroma. A model is presented in which the pattern of epithelial outgrowth is determined by the physical characteristics of the surrounding stroma; in collagen matrix a comparatively primitive and unspecialized type of morphogenesis occurs which may not require the participation of stromal cells. In contrast, epithelial-adipocyte interactions appear to be necessary for the formation of end buds and subsequent morphogenesis of fully structured mammary ducts.     

Characterization of morphogenetic and invasive abilities of human mammary epithelial cells: Correlation with variations of urokinase-type plasminogen activator activity and type-1 plasminogen activator inhibitor level

Urokinase-type plasminogen activator (uPA) and one of its inhibitors, the PAI-1, are involved in the proteolytic cascade of matrix degradation during in vivo morphogenesis or metastasis. In the present study, we have characterized the in vitro morphological behavior of human normal and malignant mammary epithelial cells and determined the levels of uPA activity and PAI-1 during these events. Two-dimensional cultures in the presence of inductive fibroblast-conditioned medium (CM) allowed migration of HBL-100 cells and MDA-MB-231 cells. Normal human mammary epithelial cells (HMEC) and MCF-7 cells failed to migrate under these conditions. The epithelial cell migration correlated with an increase in the uPA activity whereas their immobility correlated with both increases in uPA activity and PAI-1 level. In three-dimensional cultures in collagen gel, fibroblasts or fibroblast CM induced branching tubular morphogenesis to HMEC, cord-like extensions to HBL-100 cells and a greater invasiveness ability to MDA-MB-231 cells. These events correlated with an increased uPA activity. In contrast, no morphological rearrangement was observed in MCF-7 cells and this correlated with both increases in uPA activity and PAI-1 level. Altogether, these results show that the in vitro mammary epithelial behavior is under the influence of mesenchymal inductive signals and is in agreement with modifications of uPA activity and PAI-1 levels. Our culture system gives a suitable model to study the mechanisms of mammary development and metastasis and to highlight the involvement of proteases and their inhibitors in cell-cell positioning and cell-matrix reorganization.     

Quantitating the frequency of initiation and cH-ras mutation in in situ N-methyl-N-nitrosourea-exposed rat mammary gland

Mammary carcinogenesis is a multistep process consisting minimally of initiation and promotion/progression stages. The rate-limiting stage in the carcinogenesis process is undetermined but can in part be addressed by estimating the frequency of initiation, a heritable early event. Here, we use an in vivo limiting dilution transplantation assay to estimate initiation frequency in a rat mammary epithelial stem-like cell population that was exposed in situ to 50 mg/kg N-methyl-N-nitrosourea (NMU) administered i.v. We estimate that this dose resulted in the killing of 65% of exposed mammary cells. Known numbers of cells surviving NMU exposure were grafted into fat-pads of recipient rats in which the cells grew and differentiated into structurally and functionally normal mammary glands. Recipient rats were hormonally manipulated to provide maximal promotion of initiated cells. Mammary carcinomas developing at graft sites were quantitated over a 2-year period. Based on these results, we estimate that at least 1 surviving NMU-exposed mammary cell in 7,200 was initiated. Seventeen % of these graft site carcinomas had an activated H-ras oncogene with a G to A mutation in codon 12. This suggests that at least 1 mammary cell in 43,000 was mutated in this fashion by in situ exposure to NMU. These data suggest that cH-ras represents approximately 1 of 5 of the initiation events produced by NMU exposure of rat mammary glands.     

Cultures from adult rat liver cells. I. Establishment of monolayer cell-cultures from normal liver

Establishment of monolayer cell-cultures from adult normal rat liver is described using cells isolated by a collagenase-hyaluronidase perfusion technique. The cells plated originally were polygonal in shape and contained a large number of mitochondria. However, cells with less granules were also observed in the primary culture, after a few days of plating. In subsequent subcultures, the latter type of cells could be grown continuously. After an initial lag, the cells attained a doubling time of 55 hours and a plating efficiency of 20%. The cells are “normal” with respect to their karyology, morphology and growth pattern. Difficulties encountered during the culture and the possible uses of these cultured cells in studies on carcinogenesis in vitro are discussed.     

Follicle-like structure and polarized monolayer: Role of the extracellular matrix on thyroid cell organization in primary culture

The thyroid follicle, the morphofunctional unit of thyroid gland, is a spheroidal structure formed by a monolayer of polarized cells surrounding a closed cavity in which thyroglobulin accumulates. Newly isolated porcine thyroid cells reorganize into two types of structures which differ by the orientation of cell polarity: in follicle-like structures, obtained in the presence of TSH, the apical pole delineates a closed cavity and cells express most parameters characteristic of thyroid function; in inside-out follicles the apical pole is oriented towards the culture medium and cells do not express properly the thyroid function. The organization of newly formed follicles can be modified by stimulation of cell migration or by interaction of their apical poles with a new cell environment. Seeded on a hard surface (glass, plastic), cells of follicle-like structures or inside-out follicles formed in suspension migrate giving a monolayer. On the contrary, cells organized into a monolayer treated with hexamethylene bisacetamide, reorganize into follicle-like structures. Inside-out structures reoganize upon interaction of their apical poles with collagen I gel, a coherent matrix, or with a reconstituted basement membrane (RBM), a soft matrix. Overlaid with collagen I, monolayers reorganize into follicles. Embedded in collagen I or in RBM, inside-out follicles reorient their polarity giving functional follicles. On the RBM surface, cells pull on the gel and embed themselves in the soft matrix gel, finally reorienting their polarity to inside-in polarity. When comparing thyroid cells with other epithelial cell types (mammary cells, Sertoli cells), it appears that the obtention in culture of follicle-like structures, ie closed inside-in polarized cell organization, is the best way to express in culture both morphology and function of any specific epithelial tissue, the polarized monolayer in porous bottom culture chamber coming just behind.     

Modification of expression of the malignant phenotype in radiation-initiated cells

Carcinogenesis is a multistage process consisting minimally of initiation and promotion/progression stages. Radiation and many environmental xenobiotics are potent initiating agents. We have shown that initiation of carcinogenesis in vivo by these agents is a common cellular event. In the irradiated thyroid (5 Gy) at least one in 20 cells is initiated. Initiation by both radiation and chemicals has also been shown to be a common cellular event in the mammary gland. Initiation therefore is most likely not the sole rate-limiting event in the carcinogenic process. The propensity of the initiated cell to express the malignant phenotype is modulated by many factors, including environmental chemicals and physiological and genetic factors. Scopal and abscopal physiological factors can either enhance or suppress the progression of initiated cells to a frank tumour. For example, prolactin enhances the rate of progression of radiation and chemically initiated mammary tumours while glucocorticoids suppress this progression. TSH enhances the progression of radiation-initiated thyroid tumours while a scopal factor associated with unirradiated thyroid cells suppresses progression of this tumour type.     

Types and amounts of carcinogens as potential human cancer hazards

Current knowledge on the mechanisms of chemical carcinogenesis forms the basis for application of select short-term in vitro and in vivo tests to detect potential human carcinogens, for ultimate application to hazard assessment. Chemical carcinogenesis involves a series of distinct steps, proceeding from the initiation of a neoplastic cell, through its promotion, development, and progression to cancer. Some chemicals act in each of these stages as initiators, cocarcinogens, promoters, or inhibitors of carcinogenesis. Chemicals can be classified as operating by genotoxic or epigenetic mechanisms, and appropriate tests can be used to detect such properties. These abbreviated tests provide enhanced qualitative decision-making potential since they are based on mechanisms of action. Advances in molecular biology may provide additional tests to detect cancer risk. The quantitative data available from in vitro dose-response studies indicate that carcinogenic effects are dose dependent and, therefore, a threshold or no-effect level probably exists, which is low for potent carcinogens (especially genotoxins) and high for weaker ones (particularly epigenetic agents).Presented at a Symposium: Quantitative Assessment of Cancer Risk-Integration of Biological Events, organized by the Carcinogenesis Specialty Section, Society of Toxicology, (chairmen N.P. Page and D.V. Singh), Washington, D.C., February 23–27,1987.     

Influence of Matricial Molecules on Growth and Differentiation of Entrapped Chondrocytes

Primary cultures of rabbit articular chondrocytes have been cultivated normally and within three-dimensional systems using different alginate matrices. The in vitro proliferation capacity of the cells immobilized in the calcium alginate beads was investigated. The growth curve showed that chondrocytes are able to grow and to divide for several days inside the beads; in parallel an increase in protein contents was also measured. The differentiated phenotype of rabbit articular chondrocytes consists of cartilage-specific proteoglycans. During serial monolayer cultures this phenotype was lost and replaced by a low level of proteoglycan synthesis. On the contrary when cultivated in beads, entrapped cells maintained their differentiated pheno-type over time; the rates of proteoglycan were similar to those of primary chondrocytes. All these parameters were tested comparatively using different substrata in monolayer cultures and in alginate gels. Assays were carried out to assess the influence of type I collagen, type IV collagen, and of fibronectine on the growth as well as on the differentiation phenotype. The encapsulation methodology is readily applicable to the culture of chondrocytes in single beads, in multiwell dishes, or to mass culture for a bioproduction of extracellular matrix components.     

A conundrum in molecular toxicology: Molecular and biological changes during neoplastic transformation of human cells

The process of multistage carcinogenesis lends itself to the concept that the effects of carcinogens are mediated through dose-related, multi-hit, linear changes. Multiplein vitro model systems have been developed that are designed to examine the cellular changes associated with the progression of cells through the different stages in the process; however, these systems may have inherent limitations due to the cell lines used for these studies, the manner of assessing the effects of the carcinogens, and the subsequent growth and differentiation of the exposed cells. Each of these variables results in increasing levels of uncertainty relative to the correlation of the events with the actual process of human tumor development. Therefore, the prediction of the ultimate effect of any carcinogen is difficult. Moreover, relationships between individual biological endpoints resulting from carcinogen treatment appear at best to be approximations. The presence of an activated carcinogen inside the cell can give rise to multiple outcomes, only some of which may be critical events. For example, site-specific modification of the 12th and 13th codons of H-ras is different than that in the adjacent 14th and 15th codons. It is interesting to speculate what effect these differences might have on a biological outcome, e.g., transformation to anchorage-independent growth. The use of different model systems to examine the effects of activated carcinogens also creates additional problems. Comparisons ofin vitro transformed cells with similar cells isolated from human tumors indicate that the culture environment appears to influence the expression of a particular phenotype, in that human tumor cells in culture express many of the same parameters as those found in cells transformed with carcinogensin vitro. If the process of transformation is linear, then less aggressive phenotypes should progress to a more aggressive transformed stage. However, in carcinogen-transformed human cells, the populations exhibit phenotypic diversity in that many of the transformed cells differentiate and fial to continue to divide in culture. Historically, we have assumed only a limited role for epigenetic modulation of molecular changes that occur during progression; however, our data suggest quite strongly that nonmalignant tumor populations can be converted to a more malignant phenotype without additional mutations taking place and, conversely, malignant populations can be downregulated to a nontumorigenic phenotype. Tumor cell plasticity is not only a fundamental characteristic of diverse types of human tumors, but also appears as an integral characteristic of carcinogen-transformed cellsin vitro.Abbreviations AIG anchorage-independent growth - B[a]P benzo[a]pyrene - BPDE-I benzo[a]pyrene diol epoxide I - I-NP 1-nitrosopyrene - PCR polymerase chain reaction - PDL population doubling(s)     

Correlation of hyaluronic acid accumulation and the growth of preneoplastic mammary cells in collagen: A lonitudinal study

Summary Hyaluronic acid accumulation is characteristic of mammary tumor cells, and the amount that accumulates seems to correlate with the degree of malignancy of the producing cells. We have tested directly the relationship between hyaluronic acid accumulation and the replication rate of preneoplastic mammary cells in culture. We used nontumorigenic but immortal CL-S1 mouse mammary cells that were derived from a hyperplastic alveolar nodule. Using a collagen gel culture system, we found clear differences in the growth properties of cells before and after Passages 68 to 70. Late passage cells replicated earlier and faster than early passage cells in collagen and on plastic. The rate of cycling resembled that of tumorigenic mouse mammary cells during the first week of culture. Cells seeded at low densities cycled faster than those seeded at high densities during the second week in culture. Exogenous hyaluronic acid, at 10 to 1000μg/ml, neither enhanced nor inhibited CL-S1 cell growth significantly in collagen, regardless of passage. However, by the third day in collagen, late passage cells produced 7 times more total glycosaminoglycans and 12 times more hyaluronic acid per cell than did early passage cells. Late passage cells also deposited 12 times more labeled hyaluronic acid in the matrix than did early passage cells, on a per-cell basis. After a decline in the deposition of hyaluronic acid in the extracellular matrix, growth ceased. The late passage cells did not grow in soft agar, indicating that they had not become neoplastic spontaneously during passage. However, their accelerated growth rate, coupled with the synthesis and secretion of large amounts of hyaluronic acid into the extracellular matrix, may characterize a distinct step in tumor progression in preneoplastic CL-S1 cells.     

In vitro comparison of six different matrix systems for the cultivation of human chondrocytes

Summary In recent years, a great variety of different matrix systems for the cultivation of chondrocytes have been developed. Although some of these scaffolds show promising experimental results in vitro, the potential clinical value remains unclear. In this comparative study, we propagated human articular chondrocytes precultivated in monolayer culture on six different scaffolds (collagen gels, membranes and sponges) under standardized in vitro conditions. Mechanical properties of the matrix systems were not improved significantly by cultivation of human chondrocytes under the given in vitro conditions. The gel systems (CaReS, Ars Artho, Germany and Atelocollagen, Koken, Japan) showed a homogeneous cell distribution; chondrocytes propagated on Chondro-Gide (Geistlich Biomaterials, Switzerland) and Integra membranes (Integra, USA) were building multilayers. Only few cells penetrated the two Atelocollagen honeycomb sponges (Koken, Japan). During cultivation, chondrocytes propagated on all systems showed a partial morphological redifferentiation, which was best with regard to the gel systems. In general, only small amounts of collagen type-II protein could be detected in the pericellular region and chondrocytes failed to build a territorial matrix. During the first two weeks of cultivation, the two gel systems showed a significantly higher collagen type-II gene expression and a lower collagen type-I gene expression than the other investigated matrix systems. Although collagen gels seem to be superior when dealing with deep cartilage defects, membrane systems might rather be useful in improving conventional autologous chondrocyte transplantation or in combination with gel systems.     

Fibronectin production by cultured human lung fibroblasts in three-dimensional collagen gel culture

Summary In vivo, fibroblasts are distributed in a three-dimensional (3-D) connective tissue matrix. Fibronectin is a major product of fibroblasts in routine cell culture and is thought to regulate many aspects of fibroblast biology. In this context, we sought to determine if the interaction of fibroblasts with a 3-D matrix might affect fibronectin production. To examine this hypothesis, fibronectin production by fibroblasts cultured in a 3-D collagen gel or on plastic dishes was measured by ELISA. Fibroblasts in 3-D gel culture produced more fibronectin than those in monolayer culture. Fibroblasts in 3-D culture produced increasing amounts of fibronectin when the collagen concentration of the gel was increased. The 3-D nature of the matrix appeared to be crucial because plating the fibroblasts on the surface of a plastic dish underneath a collagen gel was not different from plating them on a plastic dish in the absence of collagen. In addition to increased fibronectin production, the distribution of the fibronectin produced in 3-D culture was different from that of monolayer culture. In monolayer culture, more than half of the fibronectin was released into the culture medium. In 3-D culture, however, approximately two-thirds remained in the collagen gel. In summary, the presence of a 3-D collagen matrix increases fibroblast fibronectin production and results in greater retention of fibronectin in the vicinity of the producing cells.     

Morphological and functional differentiation of cryopreserved lactating bovine mammary cells cultured on floating collagen gels

Cryopreserved bovine mammary epithelial cells prepared from lactating mammary tissue synthesize and secrete the milk proteins alpha_s1-casein, lactoferrin (Lf), and alpha-lactalhumin during in vitro culture on collagen gels in serum-free medium. Each milk protein is differently regulated by detachment and thickness of the collagen substratum, fetal calf scrum, and prolactin in the medium. Collagen detachment did not modulate lactoferrin secretion but strongly induced casein secretion, with detachment on day 6 (after formation of cell sheets) inducing casein secretion to 3 μg/ml medium, which was 2–3-fold higher than for cells on collagen detached on day 2 (prior to cell spreading to form sheets), and ten-fold higher than for cells grown on collagen not detached. Alpha-lactalbumin secretion was also induced, but only to low levels, in cells grown on detached but not on attached collagen. Cells grown on thin collagen gels secreted lower levels of lactoferrin and casein compared to cells on thick collagen. Lactoferrin but not casein secretion was increased in cells grown in the presence of fetal calf serum. Casein but not lactoferrin secretion was completely dependent on prolactin. Cells grown serum-free on collagen gels detached on day 6 of culture showed a polarized epithelial cell layer with high differentiation evidenced by the apical microvilli, tight junctions, and fat droplets surrounded by casein-containing secretory vesicles. An underlying layer of myoepithelial-like cells was also evident. These studies show for eryopreserved primary bovine mammary cells prepared from lactating mammary tissue the induction of highly differentiated and polarized cell morphology and ultrastructure with concomitant induction of the secretion of casein, lactoferrin. and alpha-lactalbumin in vitro, and that the non-coordinate regulation of milk protein secretion by substratum, prolactin, and serum likely involves alternate routing and control of secretion pathways for casein and lactoferrin.     

Subculture of rabbit articular chondrocytes within a collagen gel: growth and analysis of differentiation

Primary cultures of rabbit articular chondrocytes have been subcultured within three-dimensional (3D) collagen gels. Under these conditions, the cells remained viable and divided, but with a lower proliferation rate than that observed in control monolayer cultures. Flow cytometric analysis of progression of the cells into the cell cycle has confirmed and extended these findings. Also the cellular volume was decreased in 3D-culture, being in the same range as thein vivo size of cartilage cells. Specific staining for proteoglycans and type II collagen immunolocalization on sections of gels showed the expression of differentiated phenotypes and revealed the accumulation of these matrix components in the immediate surroundings of the cells. The use of Ultroser G (a serum substitute) improved the conditions for 3D- culture of rabbit articular chondrocytes.     

Modulation of Expression and Assembly of Vinculin duringin VitroFibrillar Collagen-Induced Angiogenesis and Its Reversal

A model of collagen-inducedin vitroangiogenesis was used to investigate the modulation of expression and assembly of focal adhesion plaque-associated proteins during the process of differentiation. Human umbilical vein endothelial cells (HUVEC), first attached on an adhesive substratum (gelatin-, fibronectin-, or laminin-coated dish) or adherent collagen gel and then covered by an overlaying collagen gel, organized within 3–4 days in tube-like structures (TLS). Removing the overlaying collagen gel from fully differentiated HUVEC induced a reversion of the process and HUVEC returned to a monolayer pattern. Modulations of focal adhesion-associated proteins occurring in HUVEC during thein vitrodifferentiation process and its reversal were investigated by Western blot analysis. A significant decrease of expression of vinculin, the integrin α₂subunit, talin, α-actinin, and actin was observed in TLS whereas the amount of FVIII-related antigen did not vary as compared to control monolayer cultures. During reversal, all the reduced proteins were markedly reexpressed. Human skin fibroblasts (HSF), submitted to the same experimental conditions, did not form TLS. Most of the focal adhesion proteins in HSF were similarly modulated by an overlaying collagen gel with the exception of vinculin, which was not modified. This particular protein was therefore more thoroughly investigated. In a nondifferentiated monolayer of HUVEC, a significant proportion of vinculin was organized into a detergent-resistant juxtamembranous structure (focal adhesion plaque) which disassembled early in TLS formation and reassembled during the reversal of the process. The reduction of vinculin during TLS formation was preceded by a downregulation of its mRNA while this mRNA was upregulated during reversal of the morphotype. These results suggest that the modulations of the cytoskeletal and focal adhesion proteins and more specifically of vinculin coupled to its subcellular redistribution are critical and early events in the cascade of mechanochemical signaling duringin vitroangiogenesis induced by fibrillar collagen.     

P38 mitogen‐activated protein kinase promotes dedifferentiation of primary articular chondrocytes in monolayer culture

Articular cartilage is an avascular tissue with poor regenerative capacity following injury, a contributing factor to joint degenerative disease. Cell‐based therapies for cartilage tissue regeneration have rapidly advanced; however, expansion of autologous chondrocytes in vitro using standard methods causes ‘dedifferentiation’ into fibroblastic cells. Mitogen‐activated protein kinase (MAPK) signalling is crucial for chondrocyte metabolism and matrix production, and changes in MAPK signals can affect the phenotype of cultured cells. We investigated the effects of inhibition of MAPK signalling on chondrocyte dedifferentiation during monolayer culture. Blockade of extracellular signal‐regulated kinase (ERK) and c‐Jun N‐terminal kinase (JNK) signalling caused a significant increase in cartilage gene expression, however, also caused up‐regulation of fibrotic gene expression. Inhibition of p38 MAPK (p38) caused a significant up‐regulation of collagen type II while suppressing collagen type I expression. P38 inhibition also resulted in consistently more organized secretion of collagen type II protein deposits on cell culture surfaces. Follow‐on pellet culture of treated cells revealed that MAPK inhibition reduced cell migration from the pellet. ERK and JNK inhibition caused more collagen type I accumulation in pellets versus controls while p38 inhibition strongly promoted collagen type II accumulation with no effect on collagen type I. Blockade of all three MAPKs caused increased GAG content in pellets. These results indicate a role for MAPK signalling in chondrocyte phenotype loss during monolayer culture, with a strong contribution from p38 signalling. Thus, blockade of p38 enhances chondrocyte phenotype in monolayer culture and may promote more efficient cartilage tissue regeneration for cell‐based therapies.     

Increased yield of mouse mammary tumor virus (MMTV) by cultivation of monolayer-derived mammary tumor cells in suspension

Summary The MJY-alpha epithelial-like mammary tumor cell line was adapted for cultivation in suspension using a shaker culture technique. Replication of suspension (MJY-beta) cells was more sensitive than monolayer cells to decreases in the concentration of serum in the medium. Comparison of amino acid incoerporation and lactate production rates revealed additional differences between monolayer and suspension cultures. In addition, growth in susfpension resulted in 10- to 400-fold increases in mouse mammary tumor virus (MMTV) production by the mammary tumor cells. Incrases in MMTV yield were detected within 48 h of culture initiation and MMTV production remained elevated throughout 20 cell passages in suspension. Exposure of MJY-beta cells to 14 μM hydrocorticone further increased MMTV yield two-to five-fold. The MJY-beta suspension cultures demonstrated that these epithelial-like cells do not require attachment to a solid substrate for replication or for MMTV production. Loss of structural polarization associated with growth as a monolayer resulted in stimulation of MMTV production greater than and independent of steroid exposure. This work was supported by the T. J. Martell Foundation for Cancer and Leukemia Research and by USPHS grant 5P-30CA23102. F. M. is a trainee on MSTP grant GM07280 from the National Institute of Health. This work was submitted in partial fullfillment of the requirements for the Ph. D. degree (F. M.).