Kristin M. Klueg

Endocytosis of the ligand delta; is required for activation of the receptor Notch during Drosophila development. The Notch extracellular domain (NotchECD) dissociates from the Notch intracellular domain (NotchICD) and is trans-endocytosed into delta;-expressing cells in wild-type imaginal discs. Reduction of dynamin-mediated endocytosis in developing eye and wing imaginal discs reduces Notch dissociation and Notch signalling. Furthermore, dynamin-mediated delta endocytosis is required for Notch trans-endocytosis in Drosophila cultured cell lines. Endocytosis-defective delta proteins fail to mediate trans-endocytosis of Notch in cultured cells, and exhibit aberrant subcellular trafficking and reduced signalling capacity in Drosophila. We suggest that endocytosis into delta-expressing cells of NotchECD bound to delta plays a critical role during activation of the Notch receptor and is required to achieve processing and dissociation of the Notch protein.

Molecular evidence has established that direct heterotypic interactions occur between the Drosophila receptor Notch and the ligands Delta and Serrate, and that homotypic interactions occur between Delta molecules on opposing cell surfaces. Using an aggregation assay developed for Drosophila cultured cells, we have compared the affinities of these interactions. We find that the heterotypic interactions between Notch and the ligands Delta and Serrate have higher affinities than homotypic interactions between Delta molecules. Contrary to previous suggestions, our evidence implies that the interactions between Serrate and Notch are similar in affinity to those between Delta and Notch. We find that Fringe does not detectably affect the ligand-receptor interactions of the Notch pathway in cultured cells. Furthermore, we find that Serrate, like Delta, is a transmembrane ligand that can participate in reciprocal trans-endocytosis of ligand and receptor between expressing cells. Our findings imply that qualitative differences between Delta- and Serrate-mediated Notch signalling depend on characteristics other than intrinsic ligand-receptor affinities or the ability to participate in reciprocal ligand and receptor trans-endocytosis.

Delta functions as a cell nonautonomous membrane-bound ligand that binds to Notch, a cell-autonomous receptor, during cell fate specification. Interaction between Delta and Notch leads to signal transduction and elicitation of cellular responses. During our investigations to further understand the biochemical mechanism by which Delta signaling is regulated, we have identified four Delta isoforms in Drosophila embryonic and larval extracts. We have demonstrated that at least one of the smaller isoforms, Delta S, results from proteolysis. Using antibodies to the Delta extracellular and intracellular domains in colocalization experiments, we have found that at least three Delta isoforms exist in vivo, providing the first evidence that multiple forms of Delta exist during development. Finally, we demonstrate that Delta is a transmembrane ligand that can be taken up by Notch-expressing Drosophila cultured cells. Cell culture experiments imply that full-length Delta is taken up by Notch-expressing cells. We present evidence that suggests this uptake occurs by a nonphagocytic mechanism.