Acute ligand-independent Src activation mimics low EGF-induced EGFR surface signalling and redistribution into recycling endosomes.

Src, a non-receptor tyrosine kinase, is a key signal transduction partner of epidermal growth factor (EGF) receptor (EGFR). In human breast cancer, EGFR and Src are frequently over-expressed and/or over-activated. Although reciprocal activation is documented, mechanisms underlying Src:EGFR interactions are incompletely understood. We here exploited ts/v-Src thermo-activation in MDCK monolayers to test whether acute Src activation impacts on signalling and trafficking of non-liganded EGFR. We found that thermo-activation caused rapid Src recruitment to the plasma membrane, concomitant association with EGFR, and its phosphorylation at Y845 and Y1173 predominantly at the cell surface. Like low EGF concentrations, activated Src (i) decreased EGF surface binding without affecting the total EGFR pool; (ii) triggered EGFR endocytosis via clathrin-coated vesicles; (iii) and led to its sequestration in perinuclear/recycling endosomes with avoidance of multivesicular bodies and lysosomal degradation. Combined Src activation and EGF were synergistic for EGFR-Y845 and -Y1173 phosphorylation at some endosomes. We conclude that acute effects of Src in MDCK cells may mimic those of low EGF on EGFR activation and redistribution. Src:EGFR interactions may be sufficient to trigger EGFR activation and might contribute to its local signalling, without requiring either soluble extracellular signal or receptor over-expression.

Three unrelated sphingomyelin analogs spontaneously cluster into plasma membrane micrometric domains.

Micrometric lipid compartmentation at the plasma membrane is disputed. Using live confocal imaging, we found that three unrelated fluorescent sphingomyelin (SM) analogs spontaneously clustered at the outer leaflet into micrometric domains, contrasting with homogeneous labelling by DiIC18 and TMA-DPH. In erythrocytes, these domains were round, randomly distributed, and reversibly coalesced under hypotonicity. BODIPY-SM and -glucosylceramide showed distinct temperature-dependence, in the same ranking as Tm for corresponding natural lipids, indicating phase behaviour. Scanning electron microscopy excluded micrometric surface structural features. In CHO cells, similar surface micrometric patches were produced by either direct BODIPY-SM insertion or intracellular processing from BODIPY-ceramide, ruling out aggregation artefacts. BODIPY-SM surface micrometric patches were refractory to endocytosis block or actin depolymerization and clustered upon cholesterol deprivation, indicating self-clustering at the plasma membrane. BODIPY-SM excimers further suggested clustering in ordered domains. Segregation of BODIPY-SM and -lactosylceramide micrometric domains showed coexistence of distinct phases. Consistent with micrometric domain boundaries, fluorescence recovery after photobleaching (FRAP) revealed restriction of BODIPY-SM lateral diffusion over long-range, but not short-range, contrasting with comparable high mobile fraction of BODIPY-lactosylceramide in both ranges. Controlled perturbations of endogenous SM pool similarly affected BODIPY-SM domain size by confocal imaging and its mobile fraction by FRAP. The latter evidence supports the hypothesis that, as shown for BODIPY-SM, endogenous SM spontaneously clusters at the plasmalemma outer leaflet of living cells into ordered micrometric domains, defined in shape by liquid-phase coexistence and in size by membrane tension and cholesterol. This proposal remains speculative and calls for further investigations.