Epithelia cells assemble into sheets that compartmentalize organs and generate tissue barriers. This is achieved by forming polarized membrane domains, which are connected by junctional complexes. While much is known about the organization of the basal membrane due to its easy accessibility by high and super-resolution microscopy, the apical and lateral membrane domains remain poorly characterized. Here we describe our methods to study the molecular organization of apical and lateral membrane domains by combining 2D and 3D epithelial cell culture with super-resolution STED microscopy. We show that inverted cell monolayers enable live cell imaging of the apical membrane with a resolution sufficient to resolve the densely packed micro-villi of human enterocytes. Furthermore, 3D cell culture enables us to resolve adhesion complexes in the lateral domain of kidney derived cells. We envision that these methods will help to reveal the supra-molecular structure of lateral and apical membrane domains in epithelial cells.
Formation of fluid filled lumen by epithelial tissues is a fundamental process for organ development. How epithelial cells regulate the hydraulic and cortical forces to control lumen morphology is not completely understood. Here, we quantified the mechanical role of tight junctions in lumen formation using genetically modified MDCKII cysts. We found that the paracellular ion barrier formed by claudin receptors is not required for hydraulic inflation of lumen. However, depletion of the zonula occludens scaffold resulted in lumen collapse and folding of apical membranes. Combining quantitative measurements and perturbations of hydrostatic lumen pressure and junctional tension with modelling, we were able to predict lumen morphologies from the pressure-tension force balance. We found that in MDCK tissue the tight junction promotes formation of spherical lumen by decreasing cortical tension via inhibition of myosin. In addition, we found that the apical surface area of cells is largely uncoupled from lumen volume changes, suggesting that excess apical area contributes to lumen opening in the low-pressure regime. Overall, our findings provide a mechanical understanding of how epithelial cells use tight junctions to modulate tissue and lumen shape.
Imaging dynamics of cellular morphogenesis with high spatial-temporal resolution in 3D is challenging, due to the low spatial resolution along the optical axis and photo-toxicity. However, some cellular structures are planar and hence 2D imaging should be sufficient, provided that the structure of interest can be oriented with respect to the optical axis of the microscope. Here, we report a 3D microfabrication method which positions and orients cell divisions very close to the microscope coverglass. We use this approach to study cytokinesis in fission yeasts and polarization to lumen formation in mammalian epithelial cells. We show that this method improves spatial resolution on range of common microscopies, including super-resolution STED. Altogether, this method could shed new lights on self-organization phenomena in single cells and 3D cell culture systems.
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