Ishida Hiroaki, Huang Hao, Yamniuk Aaron P, Takaya Yoshiaki, Vogel Hans J
Structural Biology Research Group, Department of Biological Sciences, University of Calgary, Calgary, AB, Canada.
J Biol Chem. 2008 May 23;283(21):14619-28. doi: 10.1074/jbc.M801398200. Epub 2008 Mar 17.
The intracellular calcium ion is one of the most important secondary messengers in eukaryotic cells. Ca(2+) signals are translated into physiological responses by EF-hand calcium-binding proteins such as calmodulin (CaM). Multiple CaM isoforms occur in plant cells, whereas only a single CaM protein is found in animals. Soybean CaM isoform 1 (sCaM1) shares 90% amino acid sequence identity with animal CaM (aCaM), whereas sCaM4 is only 78% identical. These two sCaM isoforms have distinct target-enzyme activation properties and physiological functions. sCaM4 is highly expressed during the self-defense reaction of the plant and activates the enzyme nitric-oxide synthase (NOS), whereas sCaM1 is incapable of activating NOS. The mechanism of selective target activation by plant CaM isoforms is poorly understood. We have determined high resolution NMR solution structures of Ca(2+)-sCaM1 and -sCaM4. These were compared with previously determined Ca(2+)-aCaM structures. For the N-lobe of the protein, the solution structures of Ca(2+)-sCaM1, -sCaM4, and -aCaM all closely resemble each other. However, despite the high sequence identity with aCaM, the C-lobe of Ca(2+)-sCaM1 has a more open conformation and consequently a larger hydrophobic target-protein binding pocket than Ca(2+)-aCaM or -sCaM4, the presence of which was further confirmed through biophysical measurements. The single Val-144 --> Met substitution in the C-lobe of Ca(2+)-sCaM1, which restores its ability to activate NOS, alters the structure of the C-lobe to a more closed conformation resembling Ca(2+)-aCaM and -sCaM4. The relationships between the structural differences in the two Ca(2+)-sCaM isoforms and their selective target activation properties are discussed.
细胞内钙离子是真核细胞中最重要的二级信使之一。Ca(2+)信号通过诸如钙调蛋白(CaM)等EF手型钙结合蛋白转化为生理反应。植物细胞中存在多种CaM亚型,而动物体内仅发现一种CaM蛋白。大豆CaM亚型1(sCaM1)与动物CaM(aCaM)的氨基酸序列同一性为90%,而sCaM4仅为78%。这两种sCaM亚型具有不同的靶酶激活特性和生理功能。sCaM4在植物的自卫反应过程中高度表达,并激活一氧化氮合酶(NOS),而sCaM1则无法激活NOS。植物CaM亚型选择性激活靶标的机制尚不清楚。我们已经测定了Ca(2+)-sCaM1和Ca(2+)-sCaM4的高分辨率核磁共振溶液结构。并将它们与先前测定的Ca(2+)-aCaM结构进行了比较。对于蛋白的N叶,Ca(2+)-sCaM1、Ca(2+)-sCaM4和Ca(2+)-aCaM的溶液结构彼此非常相似。然而,尽管与aCaM具有高度的序列同一性,但Ca(2+)-sCaM1的C叶具有更开放的构象,因此比Ca(2+)-aCaM或Ca(2+)-sCaM4具有更大的疏水靶蛋白结合口袋,通过生物物理测量进一步证实了其存在。Ca(2+)-sCaM1的C叶中单一的Val-144 --> Met取代恢复了其激活NOS的能力,使C叶的结构转变为更类似于Ca(2+)-aCaM和Ca(2+)-sCaM4的封闭构象。讨论了两种Ca(2+)-sCaM亚型的结构差异与其选择性靶标激活特性之间的关系。
