Streamlining Protein Fractional Synthesis Rates Using SP3 Beads and Stable Isotope Mass Spectrometry: A Case Study on the Plant Ribosome.

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Dione Gentry-Torfer, Ester Murillo, Chloe L Barrington, Shuai Nie, Michael G Leeming, Pipob Suwanchaikasem, Nicholas A Williamson, Ute Roessner, Berin A Boughton, Joachim Kopka, Federico Martinez-Seidel
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引用次数: 0

Abstract

Ribosomes are an archetypal ribonucleoprotein assembly. Due to ribosomal evolution and function, r-proteins share specific physicochemical similarities, making the riboproteome particularly suited for tailored proteome profiling methods. Moreover, the structural proteome of ribonucleoprotein assemblies reflects context-dependent functional features. Thus, characterizing the state of riboproteomes provides insights to uncover the context-dependent functionality of r-protein rearrangements, as they relate to what has been termed the ribosomal code, a concept that parallels that of the histone code, in which chromatin rearrangements influence gene expression. Compared to high-resolution ribosomal structures, omics methods lag when it comes to offering customized solutions to close the knowledge gap between structure and function that currently exists in riboproteomes. Purifying the riboproteome and subsequent shot-gun proteomics typically involves protein denaturation and digestion with proteases. The results are relative abundances of r-proteins at the ribosome population level. We have previously shown that, to gain insight into the stoichiometry of individual proteins, it is necessary to measure by proteomics bound r-proteins and normalize their intensities by the sum of r-protein abundances per ribosomal complex, i.e., 40S or 60S subunits. These calculations ensure that individual r-protein stoichiometries represent the fraction of each family/paralog relative to the complex, effectively revealing which r-proteins become substoichiometric in specific physiological scenarios. Here, we present an optimized method to profile the riboproteome of any organism as well as the synthesis rates of r-proteins determined by stable isotope-assisted mass spectrometry. Our method purifies the r-proteins in a reversibly denatured state, which offers the possibility for combined top-down and bottom-up proteomics. Our method offers a milder native denaturation of the r-proteome via a chaotropic GuHCl solution as compared with previous studies that use irreversible denaturation under highly acidic conditions to dissociate rRNA and r-proteins. As such, our method is better suited to conserve post-translational modifications (PTMs). Subsequently, our method carefully considers the amino acid composition of r-proteins to select an appropriate protease for digestion. We avoid non-specific protease cleavage by increasing the pH of our standardized r-proteome dilutions that enter the digestion pipeline and by using a digestion buffer that ensures an optimal pH for a reliable protease digestion process. Finally, we provide the R package ProtSynthesis to study the fractional synthesis rates of r-proteins. The package uses physiological parameters as input to determine peptide or protein fractional synthesis rates. Once the physiological parameters are measured, our equations allow a fair comparison between treatments that alter the biological equilibrium state of the system under study. Our equations correct peptide enrichment using enrichments in soluble amino acids, growth rates, and total protein accumulation. As a means of validation, our pipeline fails to find "false" enrichments in non-labeled samples while also filtering out proteins with multiple unique peptides that have different enrichment values, which are rare in our datasets. These two aspects reflect the accuracy of our tool. Our method offers the possibility of elucidating individual r-protein family/paralog abundances, PTM status, fractional synthesis rates, and dynamic assembly into ribosomal complexes if top-down and bottom-up proteomic approaches are used concomitantly, taking one step further into mapping the native and dynamic status of the r-proteome onto high-resolution ribosome structures. In addition, our method can be used to study the proteomes of all macromolecular assemblies that can be purified, although purification is the limiting step, and the efficacy and accuracy of the proteases may be limited depending on the digestion requirements. Key features • Efficient purification of the ribosomal proteome: streamlined procedure for the specific purification of the ribosomal proteome or complex Ome. • Accurate calculation of fractional synthesis rates: robust method for calculating fractional protein synthesis rates in macromolecular complexes under different physiological steady states. • Holistic ribosome methodology focused on plants: comprehensive approach that provides insights into the ribosomes and translational control of plants, demonstrated using cold acclimation [1]. • Tailored strategies for stable isotope labeling in plants: methodology focusing on materials and labeling considerations specific to free and proteinogenic amino acid analysis [2].

利用 SP3 珠和稳定同位素质谱法简化蛋白质的分数合成率:植物核糖体案例研究。
核糖体是一种典型的核糖核蛋白组装体。由于核糖体的进化和功能,r 蛋白具有特定的理化相似性,这使得核糖核蛋白组特别适用于定制的蛋白质组分析方法。此外,核糖核蛋白组装的结构蛋白质组反映了与环境相关的功能特征。因此,表征核糖体的状态有助于揭示 r 蛋白重排与核糖体密码相关的上下文依赖性功能,这一概念与组蛋白密码相似,在组蛋白密码中,染色质重排影响基因表达。与高分辨率核糖体结构相比,omics 方法在提供定制解决方案以缩小核糖体目前存在的结构与功能之间的知识差距方面处于劣势。纯化核糖体和随后的枪式蛋白质组学通常涉及蛋白质变性和蛋白酶消化。其结果是核糖体群体水平上 r 蛋白的相对丰度。我们以前的研究表明,为了深入了解单个蛋白质的化学计量学,有必要通过蛋白质组学测量结合的 r 蛋白,并通过每个核糖体复合物(即 40S 或 60S 亚基)的 r 蛋白丰度总和对其强度进行归一化处理。这些计算确保了单个 r 蛋白的化学计量代表了每个家族/类群相对于复合体的比例,从而有效揭示了在特定生理情况下哪些 r 蛋白会变成亚化学计量。在这里,我们提出了一种优化方法,用于分析任何生物体的核糖蛋白质组,以及通过稳定同位素辅助质谱测定的 r 蛋白合成率。我们的方法能在可逆变性状态下纯化 r 蛋白,这为自上而下和自下而上相结合的蛋白质组学提供了可能。与之前在高酸性条件下使用不可逆变性来解离 rRNA 和 r 蛋白质的研究相比,我们的方法通过混沌 GuHCl 溶液对 r 蛋白质组进行较温和的原生变性。因此,我们的方法更适合保存翻译后修饰(PTMs)。随后,我们的方法会仔细考虑 r 蛋白的氨基酸组成,选择合适的蛋白酶进行消化。我们通过提高进入消化管道的标准化 r 蛋白组稀释液的 pH 值,并使用消化缓冲液来确保蛋白酶消化过程的最佳 pH 值,从而避免非特异性蛋白酶裂解。最后,我们提供了 R 软件包 ProtSynthesis,用于研究 r 蛋白的部分合成率。该软件包使用生理参数作为输入,以确定肽或蛋白质的部分合成率。一旦测量了生理参数,我们的方程就能对改变所研究系统生物平衡状态的处理方法进行公平比较。我们的方程利用可溶性氨基酸的富集、生长速率和蛋白质的总积累来校正肽的富集。作为一种验证手段,我们的管道不会在非标记样本中发现 "错误 "富集,同时还能过滤掉具有不同富集值的多个独特肽段的蛋白质,而这种情况在我们的数据集中并不多见。这两方面反映了我们工具的准确性。如果同时采用自上而下和自下而上的蛋白质组学方法,我们的方法就有可能阐明单个 r 蛋白家族/谱系的丰度、PTM 状态、部分合成率以及动态组装到核糖体复合物中的情况,从而进一步将 r 蛋白组的原生状态和动态状态映射到高分辨率核糖体结构上。此外,我们的方法还可用于研究所有可纯化的大分子组装体的蛋白质组,尽管纯化是限制性步骤,而且根据消化要求,蛋白酶的功效和准确性可能会受到限制。主要特点 - 核糖体蛋白组的高效纯化:简化了核糖体蛋白组或复合 Ome 的特定纯化程序。- 精确计算部分合成率:采用稳健的方法计算不同生理稳定状态下大分子复合物中的部分蛋白质合成率。- 以植物为重点的整体核糖体方法:利用冷适应[1]演示的综合方法可深入了解植物的核糖体和翻译控制。- 量身定制的植物稳定同位素标记策略:该方法侧重于游离氨基酸和蛋白源氨基酸分析所需的材料和标记注意事项[2]。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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