The mechanisms by which a cell uses and adapts its functional membrane organization are poorly understood and are the subject of ongoing investigation and discussion. Here, we study one proposed mechanism: the crosslinking of membrane components. In immune cell signaling (and other membrane-associated processes), a small change in the clustering of specific membrane proteins can lead to large-scale reorganizations that involve numerous other membrane components. We have investigated the large-scale physical effect of crosslinking a minor membrane component, the ganglioside GM1, in simple lipid models of the plasma membrane containing sphingomyelin, cholesterol, and phosphatidylcholine. We observe that crosslinking GM1 can cause uniform membranes to phase-separate into large, coexistent liquid ordered and liquid disordered membrane domains. We also find that this lipid separation causes a dramatic redistribution of a transmembrane peptide, consistent with a raft model of membrane organization. These experiments demonstrate a mechanism that could contribute to the effects of crosslinking observed in cellular processes: Domains induced by clustering a small number of proteins or lipids might rapidly reorganize many other membrane proteins.ganglioside ͉ clustering ͉ cholera toxin ͉ bilayer C rosslinking or clustering of specific biological membrane components is an indispensable element of many membrane-associated processes. In receptor signaling, transport vesicle biogenesis, cell polarization, and viral budding, a critical clustering event coincides with and is necessary for the initiation of a complex cellular process. Proposed mechanisms for these observations vary significantly between different experimental systems, and there is no expectation that the same mechanism should apply to each case. However, a recurring theme is that crosslinking (clustering or oligomerization) induces or stabilizes a structure that then recruits downstream machinery (1-6). The correlation between crosslinking and membrane domain formation is particularly well established for immune-recognition receptor signaling in B, T, and mast cells (7)(8)(9)(10). Here, we demonstrate in simple model membranes that crosslinking of a minor lipid species can induce membrane domains to form by promoting large-scale phase separation.The lipid raft hypothesis (1, 11) is a prominent model of cellular membrane organization. Discussions of individual cellular membrane functions often invoke the involvement of lipid rafts. This model proposes that some membrane proteins are segregated from each other by their preferential partitioning into regions of different membrane order, perhaps different phase, within a continuous cellular membrane. The interplay between lipid membrane phase behavior and lateral protein distribution is proposed to be involved in fundamental membrane-associated cellular processes, including signaling, endocytosis, exocytosis, protein sorting, polarization, motility, and several stages in the infectious cycle of many viruses (1-4, 6,...
