Abstract
The mammalian Golgi reassembly stacking protein (GRASP) proteins are Golgi-localized homotypic membrane tethers that organize Golgi stacks into a long, contiguous ribbon-like structure. It is unknown how GRASPs undergo trans pairing given that cis interactions between the proteins in the plane of the membrane are intrinsically favored. To test the hypothesis that myristoylation of the self-interacting GRASP domain restricts its orientation on the membrane to favor trans pairing, we established an in vitro assay that recapitulates GRASP-dependent membrane tethering and used neutron reflection under similar conditions to determine the orientation of the GRASP domain. In vivo, the membrane association of GRASP proteins is conferred by the simultaneous insertion of an N-terminal myristic acid and binding to a Golgi-associated binding partner. In our assay, the latter contact was replaced using a C-terminal hexa-His moiety, which bound to Ni(2+)-conjugated lipids incorporated into a substrate-supported bilayer lipid membrane. Nonmyristoylated protein lacked a fixed orientation on the membrane and inefficiently tethered liposomes. In contrast, myristoylated GRASP promoted tethering and exhibited a unique membrane complex. Thus, myristoylation restricts the membrane orientation of the GRASP domain favoring interactions in trans for membrane tethering.
Highlights
An unknown mechanism promotes trans interactions by the Golgi reassembly stacking protein (GRASP) homotypic membrane tethers rather than unproductive cis interactions
Because orientation is difficult to determine in vivo, we developed an in vitro assay of GRASP-mediated tethering on sparsely tethered bilayer lipid membranes where protein orientation can be determined with neutron scattering
GRASP Domain-mediated Liposome Tethering to Supported Membranes—To quantify the tethering activity of the GRASP domain in vitro, we developed a fluorescence-based assay that reports the tethering of liposomes to a supported planar bilayer
Summary
An unknown mechanism promotes trans interactions by the GRASP homotypic membrane tethers rather than unproductive cis interactions. The relative positions of the internal ligand and the PDZ1 binding groove on the molecule [11] suggest that GRASP orientation on the membrane could provide a mechanism that favors homotypic interactions in trans over those in cis [15]. For such a mechanism to work, the orientation of the protein with respect to the membrane needs to be tightly controlled, raising the possibility that N-myristoylation, as a second anchor point for the protein on the membrane, could set this orientation. Neutron reflection revealed decisive differences in GRASP membrane orientation conferred by myristoylation, yielding a model of how orientation promotes trans-membrane tethering
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