Okadaic acid suppresses calcium regulation of mitosis onset in sea urchin embryos.

R Patel, M Whitaker
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引用次数: 17

Abstract

We show that a phosphatase inhibitor, okadaic acid, induces premature and persistent mitosis during the first cell cycle in sea urchin embryos. Okadaic acid-induced mitosis requires protein synthesis, suggesting that it activates the protein synthesis-requiring mitotic H1 kinase. By microinjecting the calcium chelators BAPTA and EGTA and by measuring Cai using fura-2, an indicator dye, we show that okadaic acid-induced mitosis is independent of the calcium signal that usually triggers mitosis onset in sea urchin embryos. Disabling the calmodulin kinase II that is thought to respond to the mitotic Cai signal using a peptide inhibitor fails to prevent mitosis in response to okadaic acid. These data suggest that okadaic acid bypasses calcium regulation of mitosis by inducing constitutive phosphorylation of a site on the H1 kinase that is normally under the control of the calmodulin-regulated kinase.

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冈田酸抑制海胆胚胎有丝分裂发生的钙调控。
我们发现一种磷酸酶抑制剂,冈田酸,在海胆胚胎的第一个细胞周期中诱导过早和持久的有丝分裂。冈田酸诱导的有丝分裂需要蛋白质合成,这表明它激活了需要蛋白质合成的有丝分裂H1激酶。通过微量注射钙螯合剂BAPTA和EGTA,并使用fura-2(一种指示染料)测量Cai,我们发现在海胆胚胎中,冈田酸诱导的有丝分裂独立于通常触发有丝分裂的钙信号。使用肽抑制剂使被认为对有丝分裂Cai信号作出反应的钙调蛋白激酶II失活,不能阻止冈田酸对有丝分裂的反应。这些数据表明,冈田酸通过诱导H1激酶上一个位点的组成性磷酸化来绕过钙对有丝分裂的调节,而H1激酶通常受钙调素调节激酶的控制。
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