Diagnosis of paroxysmal nocturnal hemoglobinuria by fluorescent clostridium septicum alpha toxin

Affinity Purification of Glycosylphosphatidylinositol-anchored Proteins by Alpha-Toxin

The glycosylphosphatidylinositol (GPI)-anchor modification attaches a lipid anchor to the C-terminus of a protein, tethering the protein to the cell surface membrane. From this membrane-bound state, GPI-anchored proteins (GPI-APs) can be released into the extracellular space by multiple mechanisms, including proteolytic shedding and GPI lipase activity. Since the core GPI structure is co-released with the protein by GPI lipase activity, while removed from the protein by proteolytic cleavage, affinity purification by alpha-toxin (αToxin), which binds to the core domain of the GPI-anchor, isolates GPI-containing proteins from the culture medium. The following method details a technique for affinity purification of GP-APs using His-tagged αToxin for identification of GPI-anchored proteins, analysis of the GPI-anchor status of a protein of interest, or purification for subsequent biochemical analysis.

Heparan Sulfated Glypican-4 Is Released from Astrocytes by Proteolytic Shedding and GPI-Anchor Cleavage Mechanisms

Astrocytes provide neurons with diffusible factors that promote synapse formation and maturation. In particular, glypican-4/GPC4 released from astrocytes promotes the maturation of excitatory synapses. Unlike other secreted factors, GPC4 contains the C-terminal GPI-anchorage signal. However, the mechanism by which membrane-tethered GPC4 is released from astrocytes is unknown. Using mouse primary astrocyte cultures and a quantitative luciferase-based release assay, we show that GPC4 is expressed on the astrocyte surface via a GPI-anchorage. Soluble GPC4 is robustly released from the astrocytes largely by proteolytic shedding and, to a lesser extent, by GPI-anchor cleavage, but not by vesicular release. Pharmacological, overexpression, and loss of function screens showed that ADAM9 in part mediates the release of GPC4 from astrocytes. The released GPC4 contains the heparan sulfate side chain, suggesting that these release mechanisms provide the active form that promotes synapse maturation and function. Overall, our studies identified the release mechanisms and the major releasing enzyme of GPC4 in astrocytes and will provide insights into understanding how astrocytes regulate synapse formation and maturation.