Gelsolin

 ( Proteins ) 

Gelsolin's activity is stimulated by calcium ions (Ca²⁺). Although the protein retains its overall structural integrity in both activated and deactivated states, the S6 helical tail moves like a latch depending on the concentration of calcium ions. The C-terminal end detects the calcium concentration within the cell. When there is no Ca²⁺ present, the tail of S6 shields the actin-binding sites on one of S2's helices. When a calcium ion attaches to the S6 tail, however, it straightens, exposing the S2 actin-binding sites. The N-terminal is directly involved in the severing of actin. S2 and S3 bind to the actin before the binding of S1 severs actin-actin bonds and caps the barbed end.

Gelsolin can be inhibited by a local rise in the concentration of phosphatidylinositol (4,5)-bisphosphate (PIP₂), a PPI. This is a two step process. Firstly, (PIP₂) binds to S2 and S3, inhibiting gelsolin from actin side binding. Then, (PIP₂) binds to gelsolin’s S1, preventing gelsolin from severing actin, although (PIP₂) does not bind directly to gelsolin's actin-binding site.

Gelsolin's severing of actin, in contrast to the severing of microtubules by katanin, does not require any extra energy input.

Gelsolin also inhibits apoptosis by stabilizing the mitochondria. Prior to cell death, mitochondria normally lose membrane potential and become more permeable. Gelsolin can impede the release of cytochrome C, obstructing the signal amplification that would have led to apoptosis.

Actin can be cross-linked into a gel by actin cross-linking proteins. Gelsolin can turn this gel into a sol, hence the name gelsolin.