A cell line (MDCK) of dog kidney origin grows on a glass surface as a mosaic of epithelium with many multicellular hemispherical vesicles. The cells lining the blisters actively secrete into the cyst cavities. Suspensions of these cells injected intravenously in the chick embryo produce brain metastases resembling adenocarcinoma.
Tissue culture cell line MDCK grew with the histologic characteristics of a papillary adenocarcinoma when cultured in vitro in a three‐dimensional matrix of collagen‐coated cellulose spongeor when inoculated in the chick embryo. When suspensions of cells were injected intravenously in the chicknumerous implants were seen in the brain one week later. Transplanted to the chorio‐allantois with fragments of embryonic heartMDCK was found in the cardiac mesenchyme and within the lumens of many vessels of the transplanted heart. MDCK also exhibited the physiologic characteristics of renal tubular epithelium. Cultured on a glass surfaceMDCK formed a monolayer of epithelium interspersed with numerous blisterseach of which was composed of many cells. The walls of the blisters and the contiguous monolayers on glass were made up of polarized epithelium with microvilli on the medium‐bathed surface. Time lapse movies demonstrated that the blisters were in active fluid transport. Low concentrations of ouabain abolished the blistering overnightsuggesting inhibition of an ATPase essential for the sodium‐potassium pump associated with the plasma membrane.
A model for the study of angiogenesis in vitro is described. Rat aortas, cultured in a tridimensional matrix of clotted chick plasma, gave rise to luxuriant outgrowth of vascular channels. We studied this process with light microscopic, radioautographic, and ultrastructural techniques. On the 2nd d of culture, endothelial cells sprouted from the intima of the aorta and its collateral branches into the surrounding clot, forming solid cellular cords. A complex vascular network was established within the 1st wk by spindly, poorly differentiated endothelial cells. At this stage cells were migrating, branching, and proliferating in a longitudinal fashion (labeling index: 67.4% +/- 7.7). Lumens, when present, appeared as slitlike spaces enclosed with junctional complexes. By the end of the 2nd wk the migratory activity decreased and proliferation occurred mostly in a cross-sectional plane, with formation of large patent lumens (labeling index: 48% +/- 3.1). Vascular channels were lined by prominent endothelial cells rich in rough endoplasmic reticulum, polysomes, mitochondria. Golgi apparatuses, and coated vesicles. Cells were enveloped with a ruthenium red positive layer, particularly abundant on the luminal surface and in the interendothelial space. A discontinuous basal lamina was present along the abluminal side. At 28 d the labeling index was reduced to 2.25% +/- 0.9. The still viable endothelium exhibited numerous microfilaments and microtubules, decreased cytoplasmic organelles, and increased pinocytotic activity. This experimental model, histophysiologic gradient culture, provides us with a new tool for the study of vascular morphogenesis, angiogenesis dependent growth of tumors, and neoplastic intravasation.
On solid substrates MDCK, a cell line derived from normal dog kidney, forms a confluent monolayer that is studded with "blisters". Previous studies with this cell line suggest that these hemicysts develop as a result of active fluid accumulation between cell sheet and substratum. One factor that may determine when and how hemicysts appear only in localized sites is the interruption of occluding junctions in nonhemicyst areas. To study this possibility, we compared the permeability characteristics of the occluding junctions in hemicysts and in an uninterrupted monolayer of MDCK grown on a permeable support of collagen-coated nucleopore filter. The spontaneous electrical potential differences were small, without statistical differences between them. Relative ionic permeability coefficients were evaluated from the voltage deflections to imposed salt gradients or to a single ion substitution across both structures. The results showed that the relative permeability ratios for Na+, K+, choline+, and Cl- were the same in hemicysts and the uninterrupted monolayer. These and other results indicate that the junctional complex encircling the apical surface of a sheet of MDCK cells can provide an effective permeability barrier constituting a true occluding junction with the same properties in hemicyst and nonhemicyst areas.
Certain epithelial cell lines have morphologic, physiologic, biochemical and pharmacologic characteristics of transporting epithelia from intact organs. In this paper we show that dibutyryl cyclic AMP, 5' AMP, adenosine and cyclic AMP phosphodiesterase inhibitors stimulate hemicyst formation by the dog kidney cell line MDCK. It is suggested that this effect is explained by elevation of intracellular cyclic AMP levels by means of an exogenous non-metabolizable source of cyclic AMP, phosphodiesterase inhibition or adenyl cyclase stimulation. Since hemicyst formation is in part due to transepithelial fluid transport, these findings raise the possibility that this fraction might be modulated by cAMP in an established cell line. We believe that cultured epithelial cells may provide an exploitable model system to investigate at the cellular and subcellular levels, the mechanism by which cyclic AMP modifies water and solute movements across epithelia.
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