Biological tubes composed of polarized epithelial cells perform many functions in multicellular organisms. The establishment and maintenance of epithelial polarity depend on polarized trafficking of membrane components to the apical or basolateral domains of epithelial cells, but exactly how trafficking regulates epithelial polarity is unclear. In this issue, two papers describe a new and unexpected role for the post-Golgi vesicle coat clathrin and its adaptor AP-1 in apical sorting and lumen formation in the C. elegans intestine.
On , Grégoire Michaux and colleagues report that the clathrin adaptor AP-1 is required for epithelial polarity in the C. elegans intestine. Depletion of AP-1 subunits does not affect the establishment of epithelial polarity or the formation of the intestinal lumen, the researchers report. However, they show that AP-1 is essential for the apical localisation of the oligopeptide transporter PEPT-1 and the polarity proteins PAR-6 and CDC-42, and for the basolateral distribution of the monocarboxylate transporter SLCF-1. They also show that AP-1 depletion triggers the formation of ectopic apical lumens between intestinal cells along the lateral membranes later during embryogenesis.
On , Verena Gobel and colleagues perform an unbiased RNAi screen for apicobasal polarity and tubulogenesis defects in the C. elegans intestine and identify clathrin and AP-1 as being required for apical polarity and lumen formation. The researchers show that clathrin/AP-1-mediated polarized transport co-operates with a sphingolipid-dependent apical sorting process. Furthermore, they report, the depletion of clathrin, AP-1 or glycosphingolipid biosynthetic enzymes causes a set of apical membrane proteins (including PAR-6) to mislocalise basolaterally and generate ectopic lateral lumens. Finally, they show that clathrin-coated and sphingolipid-rich vesicles assemble at polarized plasma membrane domains in a co-dependent and AP-1-dependent manner.
Together, these findings suggest that clathrin/AP-1 controls both basolateral and apical sorting, an unexpected finding given that, until now, clathrin and its AP-1 adaptor had been thought to regulate only basolateral sorting in mammalian epithelia. Importantly, these findings indicate that this newly discovered clathrin/AP-1 function in apical sorting is required to regulate epithelial polarity in vivo in a tubular epithelium and that the clathrin/AP-1 apical sorting pathway converges with a sphingolipid-dependent apical trafficking path.
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