Glucosylhydroxyceramides Modulate Secretion Machinery of a Subset of Plasmodesmata Proteins and a Change in the Callose Accumulation

The plasma membranes encapsulated in the plasmodesmata (PDs) with symplasmic nano-channels contain abundant lipid rafts, which are enriched by sphingolipids and sterols. The attenuation of sterol compositions has demonstrated the role played by lipid raft integrity in the intercellular trafficking of glycosylphosphatidylinositol (GPI)-anchored PD proteins, particularly affecting in the callose enhancement. The presence of callose at PD is tightly attributed to the callose metabolic enzymes, callose synthases (CalSs) and β-1,3-glucanases (BGs) in regulating callose accumulation and callose degradation, respectively. Sphingolipids have been implicated in signaling and membrane protein trafficking, however the underlying processes linking sphingolipid compositions to the control of symplasmic apertures remain unknown. A wide variety of sphingolipids in plants prompts us to investigate which sphingolipid molecules are important in regulating symplasmic apertures. Here, we demonstrate that perturbations of sphingolipid metabolism by introducing several potential sphingolipid (SL) pathway inhibitors and genetically modifying SL contents from two independent SL pathway mutants are able to modulate callose deposition to control symplasmic connectivity. Our data from pharmacological and genetic approaches show that the alteration in glucosylhydroxyceramides (GlcHCers) particularly disturb the secretory machinery for GPI-anchored PdBG2 protein, resulting in an over accumulated callose. Moreover, our results reveal that SL-enriched lipid rafts link symplasmic channeling to PD callose homeostasis by controlling the targeting of GPI-anchored PdBG2. This study elevates our understanding of the molecular linkage underlying intracellular trafficking and precise targeting to specific destination of GPI-anchored PD proteins incorporated with GlcHCers contents.