Polarized expression of Shaker channels in epithelial cells.

The polarized distribution of ion channels into an apical or a basolateral domain is a fundamental feature of the transporting-epithelial phenotype. To study the molecular motifs of the channel that may serve as addressing signal(s), as well as the cellular mechanisms that interpret it and deliver the protein accordingly, we study the fate of transfected ShIR K+ channels (a non-inactivating Shaker channel) tagged with an HA epitope, as well as several other deletants and mutants. Surface expression is triggered by Ca2+-activated cell-cell contacts, through a cascade including a phospholipase C, a protein kinase C, and the cytoskeleton of actin and tubulin, and is partially impaired by suppressing N-glycosylation with tunicamycin. Using domain-specific biotinylation we show that the channel is delivered preferentially to the basolateral domain thanks to a segment between amino acids 571 and 613, and is retained on the membrane surface due to a region involving the last three amino acids (threonine, aspartic acid, valine, TDV) of the COOH terminal. Its association with the cytoskeleton seems to take the form of a scaffold comprising actin, a-actinin, b-tubulin, mLin7 and CASK. We also observe that membrane expression of ShIR channels depends entirely on its sequence of amino acids and the conformation that the molecule may adopt, but not on its ability to translocate K+ across the membrane.

Molecular characterization of the tight junction protein ZO-1 in MDCK cells.

Most of the information on the structure and function of the tight junction (TJ) has been obtained in MDCK cells. Accordingly, we have sequenced ZO-1 in this cell type, because this protein is involved in the response of the TJ to changes in Ca2+, phosphorylation, and the cytoskeleton. ZO-1 of MDCK cells comprises 6805 bp with a predicted open reading frame of 1769 amino acids. This sequence is 92 and 87% homologous to human and mouse ZO-1, respectively. Two nuclear sorting signals located at the PDZ1 and GK domains and 17 SH3 putative binding sites at the proline-rich domain were detected. We found two new splicing regions at the proline-rich region: beta had not been reported in human and mouse counterparts, and gamma, which was previously sequenced in human and mouse ZO-1, is now identified as a splicing region. The expression of different beta and gamma isoforms varies according to the tissue tested. With the information provided by the sequence, Southern blot, and PCR experiments we can predict a single genomic copy of MDCK-ZO-1 that is at least 13.16 kb long. MDCK-ZO-1 mRNA is 7.4 kb long. Its expression is regulated by calcium, while the expression of MDCK-ZO-1 protein is not.

[The role of cellular contacts in the recovery of the ion channels of epithelial cell membranes]. / El papel de los contactos celulares en la recuperación de canales iónicos de membranas de células epiteliales.

Cationic currents in mature MDCK cells are almost exclusively due to K+ channels. Harvesting with trypsin-EDTA destroys 80-90% of these channels. Upon replating, K+ currents recover in 12-20 h, by means a process that requires synthesis of proteins and of RNA. In the present work we demonstrate that this restoration depends on a Ca2+ activated-cell contact. Thus, cells in confluent monolayers bathed with 1.8 mM Ca2+ have a K+ current of 343 +/- 82 pA; confluent without Ca2+ have only 90 +/- 12 pA (27% of control; and without cell-cell contacts incubated with 1.8 mM Ca2+ (subconfl+Ca2+) have 104 +/- 21 pA (31% of control). This demonstration that the expression of K+ channels depends on Ca-activated cell-attaching molecules suggests that a molecule of the type of uvomorulin is involved.

Morphogenesis of the epithelial cell transporting phenotype: synthesis and distribution of ion channels.

The exchange of substances between higher organisms and the environment takes place across epithelia consisting of one or more cell layers. To perform this function, epithelial cells have two basic differentiated properties: 1) they form tight junctions (TJs) that seal the extracellular space, and 2) they are polarized into an apical and a basolateral domain, with entirely different structural, biochemical and physiological properties. Our understanding of the mechanisms involved in the expression of these properties has been greatly enhanced by the availability of epithelial cell lines that form TJs and polarize in vitro under conditions suitable for experimental control. In this article we summarize our studies on the synthesis and polarized expression of ion channels in epithelial cells. MDCK cells have four types of K+ channels in the apical domain, and a fifth one in the basolateral domain. The basolateral side also has a population of CI- channels. Each type of channel is absolutely polarized. Harvesting with trypsin-EDTA reduces the area of the plasma membrane by 50% and the channel population by 90%. Upon plating, these channels are recovered within a few hours. We describe here the main extracellular and intracellular mechanisms involved in these phenomena.

Morphogenesis of the epithelial cell transporting phenotype: systhesis and distribution of ion channels

The exchange of substance between higher organisms and the environment takes place across epithelia consisting of one or more cell layers. To perform this function, epithelial cells have two basic differentiated properties: 1) they form tight junctions (Tjs) that seal the extracellular space, and 2) they are polarized into an apical and a basolateral domain, with entirely different structural, biochemical and physiological properties. Our understanding of the mechanisms involved in the expression of these properties has been greatly enchanced by the availability of epithelial cell lines that form Tjs and polarize in vitro under conditions suitable for experimental control. In this article we summarize our studies on the synthesis and polarized expression of ion channels in epithelial cells. MDCK cells have four types of K+ channels in the apical domain, and a fifth one in the basolateral domain. The basolateral side also has a population of Cl- channels. Each type of channel is absolutely polarized. Harvesting with trypsin-EDTA reduces the area of the plasma membrane by 50 per cent and the channel population by 90 per cent. Upon plating, these channels are recovered within a few hours. We describe here the main extracellular and intracellular mechanisms involved in these phenomena.

Ouabain resistance of the epithelial cell line (Ma104) is not due to lack of affinity of its pumps for the drug.

Na+, K(+)-pumps of most eukaryotic animal cells bind ouabain with high affinity, stop pumping, and consequently loose K+, detach from each other and from the substrate, and die. Lack of affinity for the drug results in ouabain resistance. In this work, we report that Ma104 cells (epithelial from Rhesus monkey kidney) have a novel form of ouabain-resistance: they bind the drug with high affinity (Km about 4 x 10(-8) M), they loose their K+ and stop proliferating but, in spite of these, up to 100% of the cells remain attached in 1.0 microM ouabain, and 53% in 1.0 mM. When 4 days later ouabain is removed from the culture medium, cells regain K+ and resume proliferation. Strophanthidin, a drug that attaches less firmly than ouabain, produces a similar phenomenon, but allows a considerably faster recovery. This reversal may be associated to the fact that, while in ouabain-sensitive MDCK cells Na+, K(+)-ATPases blocked by the drug are retrieved from the plasma membrane, those in Ma104 cells remain at the cell-cell border, as if they were cell-cell attaching molecules. Cycloheximide (10 micrograms/ml) and chloroquine (10 microM) impair this recovery, suggesting that it also depends on the synthesis and insertion of a crucial protein component, that may be different from the pump itself. Therefore ouabain resistance of Ma104 cells is not due to a lack of affinity for the drug, but to a failure of its Na+, K(+)-ATPases to detach from the plasma membrane in spite of being blocked by ouabain.

A novel type of cell-cell cooperation between epithelial cells.

Ma104 cells (renal, epithelial) have a peculiar way of resisting ouabain: their Na+,K(+)-pumps bind the drug with high affinity, cellular K+ is lost and cell division arrested, but cells do not detach as most cell types do. Then, if up to 4 days later the drug is removed, Ma104 cells recover K+ and resume proliferation (Contreras et al., 1994). In the present work, we investigate whether Ma104 cells are able to protect ouabain-sensitive MDCK cells in co-culture. The main finding is that they do, but in this case protection is not elicited by the usual mechanism of maintaining the K+ content of neighboring cells through cell-cell communications. Ma104 cells treated with ouabain simply remain attached to the substrate and to their MDCK neighbors, and both cells lose K+. This attachment includes tight junctions, because the transepithelial electrical resistance of the monolayers is not abolished by ouabain. Although the beta-subunit of the Na+,K(+)-ATPase is known to possess molecular characteristics of cell-cell attachment molecules, attachment between Ma104-MDCK cells does not seem to be mediated by this enzyme, as immunofluorescence analysis reveals that Na+,K(+)-ATPase is only inserted in the plasma membrane facing a neighboring cell of the same type.

Expression of potassium channels in epithelial cells depends on calcium-activated cell-cell contacts.

Harvesting MDCK cells with trypsin-EDTA reduces potassium currents (IK) to a mere 10%, presumably by hydrolysis of K+ channels, but replating at confluence restores them in 12-18 hr, through a process that requires transcription, translation and exocytic fusion of intracellular membrane vesicles to the plasma membrane (Ponce & Cereijido, 1991; Ponce et al., 1991a). In the present work we find that this restoration of IK also requires cell-cell contacts and the presence of 1.8 mM Ca2+. The role of extracellular Ca2+ may be substituted by 2.0 microM TRH, 10 nM PMA or 200 micrograms/ml DiC8. drugs that stimulate the system of phospholipase C (PLC) and protein kinase C (PKC). Conversely, the recovery of IK triggered by Ca-dependent contacts can be blocked by 110 microM neomycin, 2.0 microM H7, and 250 nM staurosporine, inhibitors of PLC and PKC. These results suggest that the expression of new K+ channels depends on Ca(2+)-activated contacts with neighboring cells and that the information is conveyed through PLC and PKC, a process in keeping with changes in its enzymatic activity and cellular distribution of PKC. Plasma membrane is also reduced and restored upon harvesting and replating, and depends on Ca(2+)-activated contracts. However, the effects of the chemicals tested on IK differ from the ones they elicit on the recovery of plasma membrane, suggesting that cells can independently regulate their population of K+ channels and the surface of their membrane.

Peptidyl-tRNA hydrolase is involved in lambda inhibition of host protein synthesis.

Escherichia coli rap mutants do not support vegetative growth of bacteriophage lambda and die upon transcription of lambda DNA bar sites. Bacteria harbouring a pth(ts) mutation synthesize thermosensitive peptidyl-tRNA hydrolase (Pth) and die at 42 degrees C from a defect in protein synthesis. We present evidence that both rap and pth(ts) mutations affect the same gene: (i) peptidyl-tRNA hydrolase activity was found to be defective in rap mutants; (ii) at a threshold temperature, pth cells, like rap mutants, prevented lambda growth and were killed by transcription of cloned bar sites; (iii) sequencing a 1600 bp DNA fragment comprising both loci revealed an ORF located within the limits set by a complementation analysis and encoding a putative polypeptide of 21 kDa; (iv) cloning and sequencing of rap and pth(ts) mutant DNAs both revealed single nucleotide transitions from the wild type ORF sequence, resulting in Arg134 to His and Gly101 to Asp changes respectively. Analysis of plasmid-directed proteins identified a polypeptide of approximately 21 kDa; the N-terminal sequence, amino acid composition and isoelectric point of this protein match those expected from the ORF nucleotide sequence. We propose that Pth activity, directly or indirectly, is the target for lambda bar RNA leading to rap cell death.