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Securin

Securin is a protein involved in control of the metaphase-anaphase transition and anaphase onset. Following bi-orientation of chromosome pairs and inactivation of the spindle checkpoint system, the underlying regulatory system, which includes securin, produces an abrupt stimulus that induces highly synchronous chromosome separation in anaphase. Securin is a protein involved in control of the metaphase-anaphase transition and anaphase onset. Following bi-orientation of chromosome pairs and inactivation of the spindle checkpoint system, the underlying regulatory system, which includes securin, produces an abrupt stimulus that induces highly synchronous chromosome separation in anaphase. Securin is initially present in the cytoplasm and binds to separase, a protease that degrades the cohesin rings that link the two sister chromatids. Separase is vital for onset of anaphase. This securin-separase complex is maintained when securin is phosphorylated by Cdk1, inhibiting ubiquitination. When bound to securin, separase is not functional. In addition, both securin and separase are well-conserved proteins (Figure 1). Note that separase cannot function without initially forming the securin-separase complex. This is because securin helps properly fold separase into the functional conformation. However, yeast does not appear to require securin to form functional separase as anaphase occurs in yeast with a securin deletion mutation. Securin has 5 known phosphorylation sites that are targets of Cdk1; 2 sites at the N-terminal in the Ken-Box and D-box region are known to affect APC recognition and ubiquitination (Figure 2). To initiate the onset of anaphase, securin is dephosphorylated by Cdc14 and other phosphatases. Dephosphorylated securin is recognized by the Anaphase-Promoting Complex (APC) bound primarily to Cdc20 (Cdh1 is also an activating substrate of APC). The APCCdc20 complex ubiquitinates securin and targets it for degradation by 26S proteasome. This results in free separase that is able to destroy cohesin and initiate chromosome separation. It is thought that securin integrates multiple regulatory inputs to make separase activation switch-like, resulting in sudden, coordinated anaphase. This likely involves a network with several feedback loops, including positive feedback which leads to switch-like behavior. One proposed signaling pathway generating switch-like behavior contains a positive feedback loop for activation of Cdc14 by separase, leading to dephosphorylation and degradation of securin (Figure 3).

[ "Sister chromatids", "Cell cycle", "Anaphase" ]
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