通过对7种脊椎动物同种异构体的同源性建模,水通道蛋白8的结构预览

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology
Andreas Kirscht, Yonathan Sonntag, Per Kjellbom, Urban Johanson
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引用次数: 6

摘要

水通道蛋白(AQPs)促进小的中性极性分子穿过细胞膜。在动物中有四个不同的AQP亚家族,其中AQP8同源物构成了最小的亚家族之一,在人类中只有一个成员。AQP8通过动物细胞的各种膜传导水、氨、尿素、甘油和H2O2。这一被动通道与许多现象有关,如线粒体体积变化、氨神经毒性和氧化应激相关的线粒体功能障碍。目前,没有实验确定AQP8的结构,因此对该亚家族的结构理解有限。最近解决的植物AQP结构AtTIP2;1与AQP8s具有共同的结构和功能特征,为构建同源模型开辟了道路,可能比以前的模型更准确。在这里,我们提出了7种脊椎动物AQP8s的同源模型。仅基于AtTIP2;1结构进行建模,除了孔被AtTIP2中不存在的苯丙氨酸阻断外,得到了合理的模型;为了获得一个开放的孔,这些模型补充了基于细菌水特异性AQP EcAqpZ的模型,为每个AQP8异构体创建了一个嵌合单体模型。选择性过滤器(也称为芳香/精氨酸区)定义了渗透底物的轮廓,由AtTIP2中的五个氨基酸残基组成;1,包括来自环c的组氨酸。与AtTIP2相比;1,模拟AQP8s的选择性过滤器的不同之处在于,由于苯基丙氨酸取代了环c的组氨酸,它们稍微更窄,更疏水。模型不排除C环下存在与AtTIP2结构相似的侧孔;我们的模型一致认为aqp8可能具有类似于AtTIP2的选择性过滤器。AQP8s选择性过滤器中预期残基构型的详细描述为突变研究的规划和结果合理化提供了一个很好的起点。我们基于几个模板编译混合模型的策略也可能对结构信息有限的其他aqp有用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A structural preview of aquaporin 8 via homology modeling of seven vertebrate isoforms

A structural preview of aquaporin 8 via homology modeling of seven vertebrate isoforms

Aquaporins (AQPs) facilitate the passage of small neutral polar molecules across membranes of the cell. In animals there are four distinct AQP subfamilies, whereof AQP8 homologues constitute one of the smallest subfamilies with just one member in man. AQP8 conducts water, ammonia, urea, glycerol and H2O2 through various membranes of animal cells. This passive channel has been connected to a number of phenomena, such as volume change of mitochondria, ammonia neurotoxicity, and mitochondrial dysfunction related to oxidative stress. Currently, there is no experimentally determined structure of an AQP8, hence the structural understanding of this subfamily is limited. The recently solved structure of the plant AQP, AtTIP2;1, which has structural and functional features in common with AQP8s, has opened up for construction of homology models that are likely to be more accurate than previous models.

Here we present homology models of seven vertebrate AQP8s. Modeling based on the AtTIP2;1 structure alone resulted in reasonable models except for the pore being blocked by a phenylalanine that is not present in AtTIP2;1. To achieve an open pore, these models were supplemented with models based on the bacterial water specific AQP, EcAqpZ, creating a chimeric monomeric model for each AQP8 isoform. The selectivity filter (also named the aromatic/arginine region), which defines the permeant substrate profile, comprises five amino acid residues in AtTIP2;1, including a histidine coming from loop C. Compared to AtTIP2;1, the selectivity filters of modelled AQP8s only deviates in that they are slightly more narrow and more hydrophobic due to a phenylalanine replacing the histidine from loop C. Interestingly, the models do not exclude the existence of a side pore beneath loop C similar to that described in the structure of AtTIP2;1.

Our models concur that AQP8s are likely to have an AtTIP2;1-like selectivity filter. The detailed description of the expected configuration of residues in the selectivity filters of AQP8s provides an excellent starting point for planning of as well as rationalizing the outcome of mutational studies. Our strategy to compile hybrid models based on several templates may prove useful also for other AQPs for which structural information is limited.

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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
发文量
0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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