Radial gradient culture on the inner surface of collagen tubes: Organoid growth of normal rat bladder and rat bladder cancer cell line NBT-II

Summary Radial histophysiologic gradient culture uses thin walled, permeable collagen tubes to house inocula in the form of either tissue explants, aggregates of cells, or dissociated cells. The outgrowth from these incoula spreads on the inner surface of the cylindrical tube, completely lining the lumen. Metabolites are exchanged through the wall of the collagen tube by diffusion from the pool of medium surrounding the cylinder. Urothelial cells form organoid stratified epithelium. A histophysiologic gradient occurs with the basal surface of the epithelium attached to the collagen wall. At this interface, for normal bladder, the initiation of epithelial renewal is seen in the basal zone, as shown by incorporation of tritiated thymidine. The simulation of conditions in nature is attained by the exchange of metabolites between the pool of medium and the basal zone of the epithelium. NBT-II appears as two concentric stratified epithelia. Isotopic labelling is seen throughout the epithelium attached to the collagen membrane. In the superficial stratified epithelium remnants of nuclei are seen without isotopic labelling. Preparation of living cultures and, after fixation, of histologic sections is technically easy. The work was supported by research grant CA-14137 from the National Bladder Cancer Program of the National Cancer Institute, Bethesda, MD. Editor’s Statement Histiotypic cultures of normal and cancer tissues may develop into an important diagnostic tool that may supplement the information obtained by classical histopathology. These methods also offer the possibility of probing the mechanism of genesis and maintenance of tissue architecture. Gordon H. Sato     

Reconstitution of the malignant phenotype of genitourinary cancer in gradient culture

Summary The diagnosis of cancer is made on histologic examination by recognizing the characteristics of the malignant phenotype, i.e. abnormal cells in abnormal groupings, often in abnormal locations. Histophysiologic gradient culture reconstitutes conditions that meet the spatial imperatives of tissues in nature. A variety of carcinomas arise in the genitourinary system involving both glandular and stratified epithelium. To be considered here are the contrasting polarizations of proliferation of normal and neoplastic rat urothelium, the continuity of sheets of epithelium in nature, the poorly understood stable and unstable interepithelial boundaries, and the formation of organoid endocrinelike tissue in histophysiologic gradient culture of normal human amnion epithelium. This work was supported by research grant CA-14137 from the National Cancer Institute, Bethesda, MD, grant 1793 from the Council for Tobacco Research, and grants from the American Fund for Alternatives to Animal Research.     

Radial histophysiologic gradient culture chamber: Rationale and preparation

Summary Histophysiologic gradient culture methods reconstitute important spatial relationships that occur in nature between a parenchyma and its supporting stroma. At the epithelial-stromal interface, epithelia are firmly attached to the stromal substrate, initiation of renewal takes place, and metabolites are exchanged by a process of diffusion between epithelium and substrate. Other spatial imperatives characteristic of stratified epithelium are high density of cells, gradients of maturation, and continuity of epithelia along the entire course of the stromal-parenchymal interface. In radial gradient culture these relationships of epithelial cells, and supporting substrates are reconstituted. The culture chamber consists of a thin-walled cylinder, 2 to 3 mm in diameter and 3 cm long. The wall is a transparent collagen membrane in whose substance is embedded a reinforcing nylon mesh. To prepare a culture, one end of the cylinder is ligated, 1 or 2 particulate inocula are inserted in the open end of the cylinder, guided toward the ligature, and the open end is ligated. Subsequently, during incubation in a container with medium, the explants attach and proliferate. Proliferation and migration result in the cylinder being completely lined by a complex organoid tissue with structural characteristics of the original tissue. The tissue patterns in radial gradient culture of two human cell lines, RT-4, a bladder cancer, and 87×50, and ovarian cancer, are illustrated.     

Morphogenesis and oncogenesis of MCF-10A mammary epithelial acini grown in three-dimensional basement membrane cultures

The three-dimensional culture of MCF-10A mammary epithelial cells on a reconstituted basement membrane results in formation of polarized, growth-arrested acini-like spheroids that recapitulate several aspects of glandular architecture in vivo. Oncogenes introduced into MCF-10A cells disrupt this morphogenetic process, and elicit distinct morphological phenotypes. Recent studies analyzing the mechanistic basis for phenotypic heterogeneity observed among different oncogenes (e.g., ErbB2, cyclin D1) have illustrated the utility of this three-dimensional culture system in modeling the biological activities of cancer genes, particularly with regard to their ability to disrupt epithelial architecture during the early aspects of carcinoma formation. Here we provide a collection of protocols to culture MCF-10A cells, to establish stable pools expressing a gene of interest via retroviral infection, as well as to grow and analyze MCF-10A cells in three-dimensional basement membrane culture.     

Growth of intestinal epithelium in organ culture is dependent on EGF signalling

Differentiation of endoderm into intestinal epithelium is initiated at E13.5 of mouse development when there are significant changes in morphology resulting in the conversion of undifferentiated stratified epithelium into a mature epithelial monolayer. Here we demonstrate that monolayer formation is associated with the selective apoptosis of superficial cells lining the lumen while cell proliferation is progressively restricted to cells adjacent to the basement membrane. We describe an innovative embryonic gut culture system that maintains the three-dimensional architecture of gut and in which these processes are recapitulated in vitro. Explants taken from specific regions of the gut and placed into organ culture develop and express molecular markers (Cdx1, Cdx2 and A33 antigen) in the same spatial and temporal pattern observed in vivo indicating that regional specification is maintained. Inhibition of the epidermal growth factor receptor (EGFR) tyrosine kinase using the specific inhibitor AG1478 significantly reduced the proliferation and survival of cells within the epithelial cell layer of cultured gut explants. This demonstrates an essential role for the EGF signalling pathway during the early stages of intestinal development.     

Repopulation of a human alveolar matrix by adult rat type II pneumocytes in vitro : A novel system for type II pneumocyte culture

This paper describes the preparation of lung acellular alveolar matrix fragments and culture of rat type II pneumocytes directly on the alveolar epithelial basement membrane, thereby permitting study of the effect of lung basement membrane on the morphology and function of type II cells. Collagen types I, III, IV and V, laminin and fibronectin were located by immunofluorescence in the lung matrix with the same patterns as those described for the normal human lung. Transmission electron microscopy (TEM) of the fragments revealed intact epithelial and endothelial basement membranes. The matrix maintained the normal three-dimensional alveolar architecture. Glycosaminoglycans were still present by Alcian Blue staining. Isolated adult rat type II pneumocytes cultured on 150 micron thick fragments of acellular human alveolar extracellular matrix undergo gradual cytoplasmic flattening, with loss of lamellar bodies, mitochondria, and surface microvilli. These changes are similar to the in vivo differentiation of type II pneumocytes into type I pneumocytes. The type II pneumocyte behaviour on the lung epithelial basement membrane contrasted sharply with that of the same cell type cultured on a human amnionic basement membrane. On the latter surface the cells retained their cuboidal shape, lamellar bodies and surface microvilli for up to 8 days. These observations suggest that the basement membranes from different organ systems exert differing influences on the morphology and function of type II pneumocytes and that the alveolar and amnionic basement membranes may have differing three-dimensional organizations. The technique of direct culture of type II cells on the lung basement membrane provides a useful tool for studying the modulating effect of the basement membrane on alveolar epithelial cells.     

Induction of enamel matrix protein expression in an ameloblast cell line co-cultured with a mesenchymal cell line in vitro

Interactions between epithelium and mesenchyme are important for organ and tissue development. In this study, in order to mimic interactions between epithelium and mesenchyme during native tooth development, we constructed three-dimensional culture systems in vitro using a collagen membrane. Two types of collagen membrane-based in vitro culture systems were constructed in which dental epithelial and dental follicle cell lines were cultured. One co-culture method involved inoculation of one cell line into one side of the collagen membrane, and the other cell line into the opposite side of the membrane (sandwich co-culture). As a control, the second method involved culture of one of the cell lines on a culture dish and the second cell line on a collagen membrane, facing away from the first cell line (separate co-culture). The HAT-7 cells were also grown as a monolayer culture on collagen. Ameloblast differentiation in these cultures was investigated by analysis of the mRNA and/or protein expression of ameloblastin and amelogenin. Our results suggest that interaction of epithelial and mesenchymal cells via the extracellular matrix is important for tooth differentiation in vitro. Our culture system should be a useful method for investigation of epithelial-mesenchymal interactions.     

Isolation of Mammary Epithelial Cells from Three-dimensional Mixed-cell Spheroid Co-culture

While enormous efforts have gone into identifying signaling pathways and molecules involved in normal and malignant cell behaviors^1-2, much of this work has been done using classical two-dimensional cell culture models, which allow for easy cell manipulation. It has become clear that intracellular signaling pathways are affected by extracellular forces, including dimensionality and cell surface tension^3-4. Multiple approaches have been taken to develop three-dimensional models that more accurately represent biologic tissue architecture³. While these models incorporate multi-dimensionality and architectural stresses, study of the consequent effects on cells is less facile than in two-dimensional tissue culture due to the limitations of the models and the difficulty in extracting cells for subsequent analysis.The important role of the microenvironment around tumors in tumorigenesis and tumor behavior is becoming increasingly recognized⁴. Tumor stroma is composed of multiple cell types and extracellular molecules. During tumor development there are bidirectional signals between tumor cells and stromal cells⁵. Although some factors participating in tumor-stroma co-evolution have been identified, there is still a need to develop simple techniques to systematically identify and study the full array of these signals⁶. Fibroblasts are the most abundant cell type in normal or tumor-associated stromal tissues, and contribute to deposition and maintenance of basement membrane and paracrine growth factors⁷.Many groups have used three dimensional culture systems to study the role of fibroblasts on various cellular functions, including tumor response to therapies, recruitment of immune cells, signaling molecules, proliferation, apoptosis, angiogenesis, and invasion^8-15. We have optimized a simple method for assessing the effects of mammary fibroblasts on mammary epithelial cells using a commercially available extracellular matrix model to create three-dimensional cultures of mixed cell populations (co-cultures)^16-22. With continued co-culture the cells form spheroids with the fibroblasts clustering in the interior and the epithelial cells largely on the exterior of the spheroids and forming multi-cellular projections into the matrix. Manipulation of the fibroblasts that leads to altered epithelial cell invasiveness can be readily quantified by changes in numbers and length of epithelial projections²³. Furthermore, we have devised a method for isolating epithelial cells out of three-dimensional co-culture that facilitates analysis of the effects of fibroblast exposure on epithelial behavior. We have found that the effects of co-culture persist for weeks after epithelial cell isolation, permitting ample time to perform multiple assays. This method is adaptable to cells of varying malignant potential and requires no specialized equipment. This technique allows for rapid evaluation of in vitro cell models under multiple conditions, and the corresponding results can be compared to in vivo animal tissue models as well as human tissue samples.     

Preparation of mammalian plasma membranes by aqueous two-phase partition

Plasma membranes are readily purified from crude mixtures by the technique of aqueous two-phase partition. This procedure has been used widely to prepare plasma membrane fractions, highly purified, from both green and dark-grown plant materials. Only recently, however, has the method been applied to animal cells and tissues to supplant previous protocols where preparative sucrose and other gradient procedures were employed. The method based on aqueous two-phase partition, is rapid, reproducible and facile. It is especially useful for tissue culture cells since gradient methods often are complicated by alterations in plasma membrane density with different culture conditions and the presence of extensive cytoskeleton-membrane interactions. Homogenates prepared either in dilute 1 mM bicarbonate or isotonic sucrose are first centrifuged to concentrate the plasma membrane vesicles. The concentrated membranes are then combined with a mixture of dextran and polyethylene glycol that will of itself spontaneously separate into a polyethylene glycol-rich upper phase and a dextran-rich lower phase. The mixture is usually centrifuged to accelerate phase separation. The plasma membranes enter the upper, polyethylene glycol-rich phase, whereas contaminating membranes remain with the dextran of the lower phase. The yield of plasma membranes is 20% or more of those present in homogenates and the fraction purity is 90% or greater.     

Primary culture in chemically defined medium of human fetal mammary epithelial cells within reconstituted matrix]

A serum-free primary culture system has been developed which allows for three-dimensional growth and differentiation of normal human fetal mammary epithelial cells within an extracellular matrix preparation. Human fetal mammary epithelial cells were isolated from the mammary glands of human female fetuses, 17 to 39 weeks-old. The "organoids" were embedded within a reconstituted basement membrane matrix prepared from the Engelbreth-Holm-Swarm (EHS) sarcoma according to the method of Hahm and Ip. "Organoids" were grown in either serum-free medium or in medium with fetal calf serum (FCS). The "organoid" proliferated over a 2 to 3 weeks culture period and remained viable for 1 or 2 months within the basement membrane matrix in serum free medium. Several types of colonies were observed; including alveolar-like budding clusters obtained from cultures of mammary gland from fetuses of over 20 weeks age, units with ductule-like projections and stellate-type colonies. Cell proliferation was dependent on the culture medium (with FCS no proliferation was obtained) and on the substratum (without matrix, significantly less growth and development occurred). These types of colonies are obtained when a glandular differentiation of cells budding from the malpighian epithelium is observed. Light microscopic and transmission electron microscopic studies were undertaken at the time of culture. This unique system using normal fetal mammary epithelial cells thus provides a model in which the regulation of human mammary development can be investigated.     

A 3D Human Lung Tissue Model for Functional Studies on Mycobacterium tuberculosis Infection

Tuberculosis (TB) still holds a major threat to the health of people worldwide, and there is a need for cost-efficient but reliable models to help us understand the disease mechanisms and advance the discoveries of new treatment options. In vitro cell cultures of monolayers or co-cultures lack the three-dimensional (3D) environment and tissue responses. Herein, we describe an innovative in vitro model of a human lung tissue, which holds promise to be an effective tool for studying the complex events that occur during infection with Mycobacterium tuberculosis (M. tuberculosis). The 3D tissue model consists of tissue-specific epithelial cells and fibroblasts, which are cultured in a matrix of collagen on top of a porous membrane. Upon air exposure, the epithelial cells stratify and secrete mucus at the apical side. By introducing human primary macrophages infected with M. tuberculosis to the tissue model, we have shown that immune cells migrate into the infected-tissue and form early stages of TB granuloma. These structures recapitulate the distinct feature of human TB, the granuloma, which is fundamentally different or not commonly observed in widely used experimental animal models. This organotypic culture method enables the 3D visualization and robust quantitative analysis that provides pivotal information on spatial and temporal features of host cell-pathogen interactions. Taken together, the lung tissue model provides a physiologically relevant tissue micro-environment for studies on TB. Thus, the lung tissue model has potential implications for both basic mechanistic and applied studies. Importantly, the model allows addition or manipulation of individual cell types, which thereby widens its use for modelling a variety of infectious diseases that affect the lungs.     

The WD40 protein Morg1 facilitates Par6–aPKC binding to Crb3 for apical identity in epithelial cells

Formation of apico-basal polarity in epithelial cells is crucial for both morphogenesis (e.g., cyst formation) and function (e.g., tight junction development). Atypical protein kinase C (aPKC), complexed with Par6, is considered to translocate to the apical membrane and function in epithelial cell polarization. However, the mechanism for translocation of the Par6–aPKC complex has remained largely unknown. Here, we show that the WD40 protein Morg1 (mitogen-activated protein kinase organizer 1) directly binds to Par6 and thus facilitates apical targeting of Par6–aPKC in Madin-Darby canine kidney epithelial cells. Morg1 also interacts with the apical transmembrane protein Crumbs3 to promote Par6–aPKC binding to Crumbs3, which is reinforced with the apically localized small GTPase Cdc42. Depletion of Morg1 disrupted both tight junction development in monolayer culture and cyst formation in three-dimensional culture; apico-basal polarity was notably restored by forced targeting of aPKC to the apical surface. Thus, Par6–aPKC recruitment to the premature apical membrane appears to be required for definition of apical identity of epithelial cells.     

Organotypical tissue cultures from adult murine colon as an in vitro model of intestinal mucosa

Together with animal experiments, organotypical cell cultures are important models for analyzing cellular interactions of the mucosal epithelium and pathogenic mechanisms in the gastrointestinal tract. Here, we introduce a three-dimensional culture model from the adult mouse colon for cell biological investigations in an in vivo-like environment. These explant cultures were cultured for up to 2 weeks and maintained typical characteristics of the intestinal mucosa, including a high-prismatic epithelium with specific epithelial cell-to-cell connections, a basal lamina and various connective tissue cell types, as analyzed with immunohistological and electron microscopic methods. The function of the epithelium was tested by treating the cultures with dexamethasone, which resulted in a strong upregulation of the serum- and glucocorticoid-inducible kinase 1 similar to that found in vivo. The culture system was investigated in infection experiments with the fungal pathogen Candida albicans. Wildtype but not Deltacph1/Deltaefg1-knockout Candida adhered to, penetrated and infiltrated the epithelial barrier. The results demonstrate the potential usefulness of this intestinal in vitro model for studying epithelial cell-cell interactions, cellular signaling and microbiological infections in a three-dimensional cell arrangement.     

Engineering slit-like channels for studying the growth of epithelial tissues in 3D-confined spaces

The development of epithelial lumens in ducts is essential to the functioning of various organs and in organogenesis. Ductal elongation requires the collective migration of cell cohorts in three-dimensional (3D) confined spaces, while maintaining their epithelial integrity. Epithelial lumens generally adopt circular morphologies, however abnormalities in complex physiological environments can lead to the narrowing of glandular spaces that adopt elongated and slit-like morphologies. Here, we describe a simple method to form epithelial tissues in microchannels of various widths (100–300 µm) with a constant height of 25 µm that mimic elongated geometries of glandular spaces. The significance of this biomimetic platform has been evidenced by studying the migration of epithelial cell sheets inside these narrow slits of varying dimensions. We show that the growth of epithelial tissues in 3D-confined slits leads to a gradient of cell density along the slit axis and that the migration cell velocity depends on the extent of the spatial confinement. Our findings indicate that nuclear orientation is higher for leader cells and depends on the slit width, whereas YAP protein was predominantly localized in the nucleus of leader cells. This method will pave the way to studies aiming at understanding how 3D-confined spaces, which are reminiscent of in vivo pathological conditions, can affect the growth and the homeostasis of epithelial tissues.     

Expression of the differentiated phenotype by epithelial cells in vitro is regulated by both biochemistry and mechanics of the substratum

In this paper I sought to determine how the expression of differentiated traits of chick retinal pigmented epithelial (RPE) cells in vitro can be modulated by varying both the biochemical and the spatial complexity, and the mechanical properties, of the growth substratum. I have used glass derivatized with proteins of a basement membrane extract (nondeformable, two-dimensional substratum) and gels of reconstituted basement membrane extract (viscoelastic, three-dimensional substratum). These two biochemically similar substrata were compared to an inert substratum (untreated glass) and to the native basement membrane of the RPE, i.e., Bruch's Membrane. With immunofluorescence microscopy, I have shown that RPE cells, given space, will spread on their native basement membrane and form stress fibres and focal contacts, analogous to the stress fibres and integrin-, talin-, and vinculin-containing focal contacts of the cells grown on glass. Therefore, the stress fibres and focal contacts present in cultured cells are not artifacts of growth in vitro, but are a natural cellular response to the nondeformability of commonly used tissue culture substrata. The proteins of the basement membrane promote expression of some of the differentiated traits by RPE cells in vitro: however, the fully differentiated phenotype is expressed by RPE cells only when their spreading is prevented by low resilience of a substratum. Basement membrane gels generally are not resilient enough to support RPE cell spreading; however, the cells spread and form stress fibres, and integrin-, talin-, and vinculin-containing focal contacts when they are presented with areas of the gel which locally acquired higher resilience. The extent of cell spreading is determined by the deformability of substratum, hence elastic forces operating within the substratum determine the maximal cell traction allowable and, indirectly, the cytoarchitecture. Therefore, in addition to biochemical composition, the mechanical properties of substrata play important role in regulation of expression of the differentiated phenotype of cells in vitro and, possibly, in vivo.     

Epithelial cell differentiation in organotypic cultures of fetal rat lung

The purpose of this investigation was to examine the suitability of an organotypic lung-cell culture model for the study of factors influencing fetal lung-cell differentiation. It has been reported that the use of carbon-stripped (hormone-depleted) bovine fetal calf serum in monolayer cell cultures of fetal rat lung prevents continued epithelial cell differentiation in vitro. In this study, organotypic cultures of fetal rat lung cells taken at day 20 of gestation (late canalicular stage) were prepared with a carbon-stripped medium. These organotypic cultures were examined by light, scanning, and transmission electron microscopy for comparison with controls prepared with unstripped bovine fetal calf serum. Highly organized three-dimensional tubular epithelial structures resembling saccules of immature lung were observed within the gelatin sponge matrix. Morphometric analysis of day 20 carbon-stripped samples revealed that 74.6% of the epithelial cells in the tubular structures contained osmiophilic lamellar bodies characteristic of type II pneumonocytes. Control specimens had 71.2% cells with lamellar bodies and did not differ significantly from the experimental group. These data are similar to those obtained with organ cultures of fetal rat lung but are in contrast to findings with monolayer culture systems. The observations of this study suggest that 1) the hormones extracted from bovine fetal calf serum by carbon-stripping are not solely responsible for the continued fetal lung cell differentiation observed in vitro, and 2) that spatial relationships between lung cells in vitro may be a significant factor in the control of differentiation.     

Long-term liver cell cultures in bioreactors and possible application for liver support

Hybrid artificial liver systems are being developed as a temporary extracorporeal liver support therapy. A short overview is given which emphasizes the development of hepatocyte culture models for bioreactors, subsequent in vitro studies, animal studies and the clinical application of hybrid liver support systems.An own bioreactor construction has been designed for the utilization of hepatocytes and sinusoidal endothelial cells. The reactor is based on capillaries for hepatocyte aggregate immobilization, coated with biomatrix. Four separate capillary membrane systems, each permitting a different function, are woven in order to create a three-dimensional network. Cells are perfused via independent capillary membrane compartments. Decentralized oxygen supply and carbon dioxide removal with low gradients is possible. There is a decentralized co-culture compartment for nonparenchymal liver cells. The use of identical parallel units to supply a few hepatocytes facilitates scale-up.     

Morphogenetic Analysis of Spiralian Development

Pattern formation in molluscs is illustrated by the exampleof the larval head pattern of gastropods. The egg cell at thebeginning of development is provided with a spatial patternof developmental factors lying in the surface membrane, by whichthe main axes of the future embryo and the frame of referenceof ooplasmic segregation are determined. Ooplasmic segregationleads to a gradient-like distribution of pole plasm substancealong the main axis and to the formation of RNA-rich granulain the vegetative cells, which play a part in the inductionof bilateral symmetry in the animal hemisphere. The patternof larval head organs arises by interaction of the axial gradientand a dorsoventral concentration gradient of an inductive substance.