A cell fractionation and quantitative proteomics pipeline to enable functional analyses of cotton fiber development

Youngwoo Lee, Heena Rani, Eileen L Mallery, Daniel B Szymanski
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Abstract

Cotton fibers are aerial trichoblasts that employ a highly polarized diffuse growth mechanism to emerge from the developing ovule epidermis. After executing a complicated morphogenetic program, the cells reach lengths over 2 cm and serve as the foundation of a multi-billion-dollar textile industry. Important traits such as fiber diameter, length, and strength are defined by the growth patterns and cell wall properties of individual cells. At present, the ability to engineer fiber traits is limited by our lack of understanding regarding the primary controls governing the rate, duration, and patterns of cell growth. To gain insights into the compartmentalized functions of proteins in cotton fiber cells, we developed a label-free liquid chromatography mass spectrometry method for systems level analyses of fiber proteome. Purified fibers from a single locule were used to fractionate the fiber proteome into apoplast (APOT), membrane-associated (p200), and crude cytosolic (s200) fractions. Subsequently, proteins were identified, and their localizations and potential functions were analyzed using combinations of size exclusion chromatography, statistical and bioinformatic analyses. This method had good coverage of the p200 and apoplast fractions, the latter of which was dominated by proteins associated with particulate membrane-enclosed compartments. The apoplastic proteome was diverse, the proteins were not degraded, and some displayed distinct multimerization states compared to their cytosolic pool. This quantitative proteomic pipeline can be used to improve coverage and functional analyses of the cotton fiber proteome as a function of developmental time or differing genotypes.
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通过细胞分馏和定量蛋白质组学管道对棉花纤维发育进行功能分析
棉纤维是一种气生三叶体,采用高度极化的扩散生长机制,从发育中的胚珠表皮中长出。在执行复杂的形态发生程序后,这些细胞的长度超过 2 厘米,成为价值数十亿美元的纺织业的基础。纤维的直径、长度和强度等重要特性是由单个细胞的生长模式和细胞壁特性决定的。目前,由于我们对细胞生长的速度、持续时间和模式的主要控制缺乏了解,因此对纤维特性进行工程设计的能力受到了限制。为了深入了解棉花纤维细胞中蛋白质的分区功能,我们开发了一种无标记液相色谱质谱方法,用于纤维蛋白质组的系统级分析。我们使用从单个棉纤维室纯化的纤维,将纤维蛋白质组分为凋亡体(APOT)、膜相关(p200)和粗胞浆(s200)部分。随后,采用尺寸排阻色谱法、统计学和生物信息学分析相结合的方法鉴定蛋白质,并分析其定位和潜在功能。这种方法很好地覆盖了 p200 和凋亡体部分,其中凋亡体部分主要是与微粒膜封闭区相关的蛋白质。凋亡体蛋白质组具有多样性,蛋白质没有降解,而且与细胞质池相比,一些蛋白质显示出不同的多聚化状态。这种定量蛋白质组管道可用于提高棉花纤维蛋白质组的覆盖率和功能分析,使其成为发育时间或不同基因型的函数。
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