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冷水海洋海绵 Geodia barretti 释放的两种溴化环状二肽作为化学防御协同作用。

Two brominated cyclic dipeptides released by the coldwater marine sponge Geodia barretti act in synergy as chemical defense.

机构信息

Division of Pharmacognosy, Department of Medicinal Chemistry, Biomedical Center, Uppsala University, Box 574, SE-751 23 Uppsala, Sweden.

出版信息

J Nat Prod. 2011 Mar 25;74(3):449-54. doi: 10.1021/np1008812. Epub 2011 Feb 21.

Abstract

The current work shows that two structurally similar cyclodipeptides, barettin (1) and 8,9-dihydrobarettin (2), produced by the coldwater marine sponge Geodia barretti Bowerbank act in synergy to deter larvae of surface settlers and may also be involved in defense against grazers. Previously, 1 and 2 were demonstrated to bind specifically to serotonergic 5-HT receptors. It may be suggested that chemical defense in G. barretti involves a synergistic action where one of the molecular targets is a 5-HT receptor. A mixture of 1 and 2 lowered the EC(50) of larval settlement as compared to the calculated theoretical additive effect of the two compounds. Moreover, an in situ sampling at 120 m depth using a remotely operated vehicle revealed that the sponge releases these two compounds to the ambient water. Thus, it is suggested that the synergistic action of 1 and 2 may benefit the sponge by reducing the expenditure of continuous production and release of its chemical defense substances. Furthermore, a synergistic action between structurally closely related compounds produced by the same bioenzymatic machinery ought to be the most energy effective for the organism and, thus, is more common than synergy between structurally indistinct compounds.

摘要

目前的工作表明,两种结构相似的环二肽,barettin(1)和 8,9-二氢 barettin(2),由冷水海洋海绵 Geodia barretti Bowerbank 产生,协同作用以阻止浮游生物幼虫的附着,并且可能也参与了对食草动物的防御。此前,1 和 2 被证明能特异性结合 5-羟色胺能 5-HT 受体。可以推测,G. barretti 的化学防御涉及协同作用,其中一个分子靶标是 5-HT 受体。1 和 2 的混合物降低了幼虫附着的 EC(50),与两种化合物的理论相加效果相比。此外,使用远程操作车辆在 120 米深处进行的原位采样显示,海绵将这两种化合物释放到周围水中。因此,人们认为 1 和 2 的协同作用可以通过减少其化学防御物质的持续生产和释放的支出而使海绵受益。此外,由相同生物酶机制产生的结构上密切相关的化合物之间的协同作用对于生物体来说应该是最有效的能量,因此比结构上不同的化合物之间的协同作用更为常见。

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