Abstract
Traffic of the integral yeast membrane protein chitin synthase III (Chs3p) from the trans-Golgi network (TGN) to the cell surface and to and from the early endosomes (EE) requires active protein sorting decoded by a number of protein coats. Here we define overlapping signals on Chs3p responsible for sorting in both exocytic and intracellular pathways by the coats exomer and AP-1, respectively. Residues 19DEESLL24, near the N-terminal cytoplasmically-exposed domain, comprise both an exocytic di-acidic signal and an intracellular di-leucine signal. Additionally we show that the AP-3 complex is required for the intracellular retention of Chs3p. Finally, residues R374 and W391, comprise another signal responsible for an exomer-independent alternative pathway that conveys Chs3p to the cell surface. These results establish a role for active protein sorting at the trans-Golgi en route to the plasma membrane (PM) and suggest a possible mechanism to regulate protein trafficking.
Highlights
The selective packaging of transmembrane cargo proteins into transport vesicles requires specific recognition of signals within the cytosolic part of the cargo by coat protein complexes
We have previously reported that a number of clathrin adaptor proteins are involved in transporting Chs3p between the trans-Golgi network (TGN) and endosomes [33,36]
Mutations in adaptor protein complexes (APs)-1, AP-3, GGA1/2, Ent3/5 or the DEESLL signal cause Chs3p to be rerouted to the plasma membrane (PM) via a poorly understood alternative pathway, independent of exomer
Summary
The selective packaging of transmembrane cargo proteins into transport vesicles requires specific recognition of signals within the cytosolic part of the cargo by coat protein complexes. Later in the secretory pathway, the adaptor protein complexes (APs), Golgi-localized gamma earcontaining ARF-binding proteins (GGAs), and epsin-related proteins sort transmembrane proteins between the TGN, endosomes, and lysosomes [3,4,5]. These transport events are usually mediated by tyrosine-based sorting signals or di-leucine-based signals (for review [6]). The second is found in the vacuolar membrane protein Sna2p and is of the sequence YSHL [22]
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