Synthesis and assembly of tight junctions are studied in monolayers of MDCK cells plated at a density sufficient for confluence, allowed to attach for 1 hr, and transferred to fresh media without cells containing or not Ca2+. 20 hr later, while monolayers with Ca2+ have fully developed junctions that confer an electrical resistance across of 346 +/- 51 omega cm2, those without Ca2+ have a negligible resistance. If at this time Ca2+ is added, junctions assemble and seal with a fast kinetics, that can be followed through the development of electrical resistance, penetration of ruthenium red, and electron microscopy. Drugs that impair synthesis, maturation and transport of proteins (cycloheximide, tunicamycin, monensin) indicate that protein components are synthesized early upon plating, do not seem to require N-glycosylation, and are stored in the Golgi compartment. Upon addition of Ca2+ they are transferred to the membrane with the participation of microfilaments but not of microtubules. These components seem to insert directly in the position they occupy in the strands, and the cell circles its perimeter with one strand as early as 15 min, even if in some segments it only consists of a row of particles. New strands develop in association with previous ones, and the pattern completes in 4 to 6 hr. Ca2+ is required for the maintenance of the assembly and also for the sealing with neighboring cells. These processes cannot occur below 25 degrees C. Serum is not required. Polarized distribution of intramembrane particles (IMP) in apical and basolateral regions follows the same time course as junction formation, in spite of the fence constituted by those strands that are already assembled. This suggests that IMP do not redistribute by lateral displacements in the plane of the membrane, but by removal and insertion in the apical and basolateral domains.
Upon transferring confluent monolayers of Madin-Darby canine kidney (MDCK) cells from a low-Ca2+ medium (1-5 microM) to one with 1.8 mM Ca2+ (Ca switch), tight junctions (TJs) assemble and seal, and transepithelial electrical resistance (TER) develops in 4-5 h, presumably through exocytotic fusion that incorporates junctional components to the surface membrane. In the present work we test this possibility and observe 1) that the Ca switch raises the cytosolic concentration of this ion; 2) that it also increases the membrane area by 22%; 3) that chloroquine, a drug which prevents exocytosis, blocks both the increase of surface membrane and the sealing of TJs; and 4) that if monolayers are not permanently switched to 1.8 mM Ca2+, but are subject to a 15-min pulse, cytosolic free Ca2+ concentration [( Ca2+]c) transiently increases but returns to low values (14 +/- 11 nM) and TER does not develop. Comparisons of the time course of TJ sealing with levels of [Ca2+]c, as well as the relationship between these parameters and extracellular Ca2+ levels, suggest that this ion may act from the extracellular side or in a narrow intracellular domain in the close vicinity of the plasma membrane.
Epithelial cells establish tight junctions (TJs) that offer an ample range of transepithelial electrical resistances (TER), in adjustment to physiological requirements. In the present work, we demonstrate that cells from different animal origins, co-cultured in monolayers, can make sealed TJs, suggesting that this structure has a basic universal structure. TJs cannot be established, however, if one of the partners does not normally express TJs, indicating that each neighbor has to contribute its moiety. Furthermore, we observe that clones of the same cell line, with widely different values of TER, do not differ in the number and length of their junctional strands, suggesting that the difference is due to their ability to express ionic channels traversing their strands. The value of TER achieved in mixed monolayers of cells of the same or different lines is the one that may be expected by taking into account the proportion of each type in the mixture and adding in parallel the electrical resistance that they exhibit in pure monolayers. Therefore, epithelial TJs appear to behave as parallel resistances.
In previous works it was demonstrated that the monolayer of MDCK cells behaves as a leaky epithelium where the electrical resistance across reflects the sealing capacity of the occluding junction. In the present work we study whether this sealing capacity can be modified by temperature and whether this is accompanied by changes in the structure of the occluding junction. Monolayers were prepared on disks of nylon cloth coated with collagen and mounted as a flat sheet between two Lucite chambers. The changes in resistance elicited by temperature were large (306% between 3 and 37 degrees C), fast (less than 2 sec), and reversible. An Arrhenius plot of conductance versus the inverse of temperature shows a broken curve (between 22 and 31 degrees C), and the activation energies calculated (3.2 and 4.0 kcal X mol-1) fall within the expected values for processes of simple diffusion. The morphology of the occluding junction was evaluated in freeze-fracture replicas by counting the number of strands and the width of the band occupied by the junction every 133 nm. In spite of the change by 306% of the electrical resistance and the phase transition, we were unable to detect any appreciable modification of the morphology of the occluding junction. Since the freeze-fracture replicas also show a density of intramembrane particles (IMP) different in the apical from that in the basolateral regions of the plasma membrane, as well as differences between face E and face P, we also investigated whether this is modified by temperature. Cold increases the population of IMP, but does not affect their polarization with the incubation time it takes to elicit changes in electrical resistance.
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