Fluorescence imaging of lamellipodin-mediated biomolecular condensates on solid supported lipid bilayer membranes.

Biomolecular condensates play a major role in numerous cellular processes, including several that occur on the surface of lipid bilayer membranes. There is increasing evidence that cellular membrane trafficking phenomena, including the internalization of the plasma membrane through endocytosis, are mediated by multivalent protein-protein interactions that can lead to phase separation. We have recently found that proteins involved in the clathrin-independent endocytic pathway named Fast Endophilin Mediated Endocytosis can undergo liquid-liquid phase separation (LLPS) in solution and on lipid bilayer membranes. Here, the protein solution concentrations required for phase separation to be observed are significantly smaller compared to those required for phase separation in solution. LLPS is challenging to systematically characterize in cellular systems in general, and on biological membranes in particular. Model membrane approaches are more suitable for this purpose as they allow for precise control over the nature and amount of the components present in a mixture. Here we describe a method that enables the imaging of LLPS domain formation on solid supported lipid bilayers. These allow for facile imaging, provide long-term stability, and avoid clustering of vesicles and vesicle-attached features (such as buds and tethers) in the presence of multi-valent membrane interacting proteins.

Association between RAPH1 Gene Haplotypes and CHE2 Locus Phenotypes.

The human butyrylcholinesterase (BChE) is a serum esterase that has been associated with body mass index (BMI) and obesity. Its activity is conditioned by alleles of BCHE gene and the CHE2 locus that codifies an unknown BChE-binding protein (C5 complex). The hypothesis that the CHE2 locus is the RAPH1 gene, which encodes lamellipodin (Lpd), was raised in a study that observed Lpd peptides released from denatured BChE tetramers. The aim of this study was to test this hypothesis by evaluating SNPs of RAPH1 gene (rs2246118:C > T, rs3814365:A > G and rs2465520:C > T) in 34 CHE2 C5+ and 92 CHE2 C5- individuals, corresponding to the presence and absence of C5 complex. The results showed association of two haplotypes (CAC and TGC) with CHE2 C5+ phenotype. RAPH1 haplotypes was also associated with intense (TGC) and faint (CAC) CHE2 C5+ phenotypes. BChE activity was higher in intense CHE2 C5+ than faint CHE2 C5+ phenotype. Our results corroborate the hypothesis that the RAPH1 gene is the CHE2 locus and suggest that the variable expressivity of the CHE2 C5+ phenotypes is, at least in part, due to its genetic heterogeneity, which is leading to increased BChE activity only in individuals with intense CHE2 C5+ phenotype.