The Arabidopsis cytoskeletal genome.

The arabidopsis book Pub Date : 2003-01-01 Epub Date: 2003-09-30 DOI:10.1199/tab.0096
Richard B Meagher, Marcus Fechheimer
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Abstract

In the past decade the first Arabidopsis genes encoding cytoskeletal proteins were identified. A few dozen genes in the actin and tubulin cytoskeletal systems have been characterized thoroughly, including gene families encoding actins, profilins, actin depolymerizing factors, α-tubulins, and β-tubulins. Conventional molecular genetics have shown these family members to be differentially expressed at the temporal and spatial levels with an ancient split separating those genes expressed in vegetative tissues from those expressed in reproductive tissues. A few members of other cytoskeletal gene families have also been partially characterized, including an actin-related protein, annexins, fimbrins, kinesins, myosins, and villins. In the year 2001 the Arabidopsis genome sequence was completed. Based on sequence homology with well-characterized animal, fungal, and protist sequences, we find candidate cytoskeletal genes in the Arabidopsis database: more than 150 actin-binding proteins (ABPs), including monomer binding, capping, cross-linking, attachment, and motor proteins; more than 200 microtubule-associated proteins (MAPs); and, surprisingly, 10 to 40 potential intermediate filament (IF) proteins. Most of these sequences are uncharacterized and were not identified as related to cytoskeletal proteins. Several Arabidopsis ABPs, MAPs, and IF proteins are represented by individual genes and most were represented as as small gene families. However, several classes of cytoskeletal genes including myosin, eEF1α, CLIP, tea1, and kinesin are part of large gene families with 20 to 70 potential gene members each. This treasure trove of data provides an unprecedented opportunity to make rapid advances in understanding the complex plant cytoskeletal proteome. However, the functional analysis of these proposed cytoskeletal proteins and their mutants will require detailed analysis at the cell biological, molecular genetic, and biochemical levels. New approaches will be needed to move more efficiently and rapidly from this mass of DNA sequence to functional studies on cytoskeletal proteins.

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拟南芥细胞骨架基因组。
在过去十年中,人们首次发现了编码细胞骨架蛋白的拟南芥基因。肌动蛋白和微管蛋白细胞骨架系统中的几十个基因已被彻底鉴定,包括编码肌动蛋白、轮廓蛋白、肌动蛋白解聚因子、α-微管蛋白和β-微管蛋白的基因家族。传统的分子遗传学表明,这些家族成员在时间和空间水平上的表达是不同的,在无性组织中表达的基因与在生殖组织中表达的基因之间存在着古老的分离。其他细胞骨架基因家族的一些成员也得到了部分鉴定,包括肌动蛋白相关蛋白、附件蛋白、纤毛蛋白、驱动蛋白、肌球蛋白和绒毛蛋白。2001 年,拟南芥基因组序列完成。根据与动物、真菌和原生动物序列的同源性,我们在拟南芥数据库中发现了候选的细胞骨架基因:150 多种肌动蛋白结合蛋白(ABPs),包括单体结合蛋白、盖帽蛋白、交联蛋白、附着蛋白和马达蛋白;200 多种微管相关蛋白(MAPs);以及令人惊讶的 10 至 40 种潜在的中间丝蛋白(IF)。其中大部分序列尚未定性,也未确定与细胞骨架蛋白有关。拟南芥的一些 ABPs、MAPs 和 IF 蛋白是由单个基因代表的,大多数是作为小型基因家族代表的。然而,包括肌球蛋白、eEF1α、CLIP、tea1 和驱动蛋白在内的几类细胞骨架基因属于大型基因家族,每个家族有 20 至 70 个潜在基因成员。这一数据宝库为快速了解复杂的植物细胞骨架蛋白质组提供了前所未有的机会。然而,要对这些拟议的细胞骨架蛋白及其突变体进行功能分析,需要在细胞生物学、分子遗传学和生物化学水平上进行详细分析。我们需要新的方法来更有效、更快速地从大量 DNA 序列转向细胞骨架蛋白的功能研究。
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