Posttranslational Modifications of Intact Proteins Detected by NMR Spectroscopy: Application to Glycosylation

Posttranslational modifications (PTMs) are an integral part of the majority of proteins. The characterization of structure and function of PTMs can be very challenging especially for glycans. Existing methods to analyze PTMs require complicated sample preparations and suffer from missing certain modifications, the inability to identify linkage types and thus chemical structure. We present a direct, robust, and simple NMR spectroscopy method for the detection and identification of PTMs in proteins. No isotope labeling is required, nor does the molecular weight of the studied protein limit the application. The method can directly detect modifications on intact proteins without sophisticated sample preparation. This approach is well suited for diagnostics of proteins derived from native organisms and for the quality control of biotechnologically produced therapeutic proteins.     

质谱技术鉴定细胞中组蛋白翻译后修饰的研究进展*

组蛋白是真核细胞中构成染色质内核小体的主要元件,其翻译后修饰蕴藏着组蛋白密码,是表观遗传学的重要内容,影响染色质的结构和功能,进而调控基因表达。组蛋白翻译后修饰形式的鉴定是揭示组蛋白密码的关键,目前质谱技术已经成为分析组蛋白及其翻译后修饰的重要工具。本文综述了组蛋白翻译后修饰鉴定方法的新进展,介绍了基于质谱技术“bottom up”和“top down”的组蛋白分析策略,及CID、ECD和ETD等鉴定组蛋白修饰位点的质谱碎片裂解技术,并结合当前研究进展,评述了质谱技术在组蛋白翻译后修饰谱的鉴定、组蛋白各种变体的测定、以及在生理过程中组蛋白修饰丰度动态变化的定量分析等方面应用的新进展。     

蛋白质中新型赖氨酸翻译后修饰的结构简介

近年来各种新型蛋白质赖氨酸翻译后修饰被逐渐发现。这些翻译后修饰在蛋白质组中广泛存在,具有高度的结构多样性,并对染色体结构和基因表达具有重要的表观遗传调控作用。本文将从化学的角度对这些新型赖氨酸翻译后修饰的发现与结构特点进行简述,以期对教学与科研有帮助。     

翻译后修饰蛋白质组学分离方法的研究进展

蛋白质翻译后修饰（PTMs）是调节细胞内生理活动的重要途径。该文总结了近年来PTMs蛋白质组学相关的分离方法,包括反相（RP）色谱法、离子交换（IEX）色谱法、亲水相互作用色谱（HILIC）法、多孔石墨化碳（PGC）色谱法、毛细管电泳（CE）法及分子筛色谱（SEC）法等。这些新方法为磷酸化、乙酰化、糖基化等PTM肽段或蛋白质的鉴定提供了更高的分离度和灵敏度。此外,该文也介绍了蛋白质领域其他重要分离方法的研究进展,这些方法可能被进一步应用于PTMs蛋白质组学的研究中。     

MS analysis reveals O-methylation of L-lactate dehydrogenase from pancreatic ductal adenocarcinoma cells

L-lactate dehydrogenase (LDH) converts pyruvate to lactate when oxygen is absent or in short supply, and the enzyme plays a crucial role in cancer metabolism. The functions of many mammalian proteins are modulated by posttranslational modifications (PTMs), and it has been reported that LDH was subjected to several PTMs, including phosphorylation, acetylation, and methylation. In this present work, we characterized the PTMs of LDH from pancreatic ductal adenocarcinoma (PDAC) cells by electrophoresis and mass spectrometry, and identified 13 O-methylated residues from the enzyme. In addition, our qualitative analysis revealed differential methylation of LDH from normal duct cells. The preliminary findings from this study provide important biochemical information toward further understanding of the LDH modifications and their functional significance in pathophysiological processes of pancreatic cancer.     

Elucidating the role of C-terminal post-translational modifications using protein semisynthesis strategies: α-synuclein phosphorylation at tyrosine 125

Despite increasing evidence that supports the role of different post-translational modifications (PTMs) in modulating α-synuclein (α-syn) aggregation and toxicity, relatively little is known about the functional consequences of each modification and whether or not these modifications are regulated by each other. This lack of knowledge arises primarily from the current lack of tools and methodologies for the site-specific introduction of PTMs in α-syn. More specifically, the kinases that mediate selective and efficient phosphorylation of C-terminal tyrosine residues of α-syn remain to be identified. Unlike phospho-serine and phospho-threonine residues, which in some cases can be mimicked by serine/threonine → glutamate or aspartate substitutions, there are no natural amino acids that can mimic phospho-tyrosine. To address these challenges, we developed a general and efficient semisynthetic strategy that enables the site-specific introduction of single or multiple PTMs and the preparation of homogeneously C-terminal modified forms of α-syn in milligram quantities. These advances have allowed us to investigate, for the first time, the effects of selective phosphorylation at Y125 on the structure, aggregation, membrane binding, and subcellular localization of α-syn. The development of semisynthetic methods for the site-specific introduction of single or PTMs represents an important advance toward determining the roles of such modifications in α-syn structure, aggregation, and functions in heath and disease.     

生物正交反应法制备含有赖氨酸翻译后修饰类似物的蛋白质

翻译后修饰一直是表观遗传学的重要研究内容,尤其是近年来多种新型天然蛋白质中翻译后修饰被发现广泛存在于蛋白质组中。细胞生物学证明这些翻译后修饰对染色体结构和基因转录功能有关,但是其中具体的分子生物学机制还处于未知状态。为了后续的进一步研究,人们需要发展制备方法以求获取足量具有特定翻译后修饰的蛋白质。本文将讨论利用生物正交反应的手段制备含有这些新型赖氨酸翻译后修饰的蛋白的探索,期对教学与科研有助。     

Multiplex Identification of Post-Translational Modifications at Point-of-Care by Deep Learning-Assisted Hydrogel Sensors

Multiplex detection of protein post-translational modifications (PTMs), especially at point-of-care, is of great significance in cancer diagnosis. Herein, we report a machine learning-assisted photonic crystal hydrogel (PCH) sensor for multiplex detection of PTMs. With closely-related PCH sensors microfabricated on a single chip, our design achieved not only rapid screening of PTMs at specific protein sites by using only naked eyes/cellphone, but also the feasibility of real-time monitoring of phosphorylation reactions. By taking advantage of multiplex sensor chips and a neural network algorithm, accurate prediction of PTMs by both their types and concentrations was enabled. This approach was ultimately used to detect and differentiate up/down regulation of different phosphorylation sites within the same protein in live mammalian cells. Our developed method thus holds potential for POC identification of various PTMs in early-stage diagnosis of protein-related diseases.     

Systematic screening of protein modifications in four kinases using affinity enrichment and mass spectrometry analysis with unrestrictive sequence alignment

Protein kinases transfer phosphate groups from ATP to substrate proteins, they are known to be involved in diverse cellular processes. They are also important therapeutic targets in pharmaceutical design. Previous studies indicated that multiple post-translational modifications (PTMs) exist in kinases in addition to phosphorylation, and these PTMs play an important role in regulating kinases activities. Nevertheless, a comprehensive analysis for PTMs of kinases is insufficient due to technical limitations, which prevent us from better understanding their functional regulation. Here, we have developed a novel strategy that combines glutathione S-transferase tag affinity enrichment with nano-liquid chromatography coupled with tandem mass spectrometry analysis and non-restrictive protein sequence alignment for identification of diverse PTMs in four yeast kinases. The method allows us to enrich and analyze the entire protein isomers and to minimize the loss of all isomers of protein sample during protein purification. In our study, nineteen phosphorylation sites and several other types of PTMs sites were localized in 4 protein kinases. In addition, we found that some interesting mass shifts can not match those of the known PTMs. It suggested the existence of some undescribed PTMs in the proteins. Accordingly, this study showed that the novel strategy holds a great potential for identification of full-spectrum PTMs in proteins. Our data serves as a stepping stone for future functional studies.     

Current approaches for global post-translational modification discovery and mass spectrometric analysis

More and more attention is being focused on the analysis of post-translational modifications (PTMs) on proteins as researchers are continually learning how essential they are for proper cellular function. As there are hundreds of different types of known PTMs, traditional methods of modification analysis are incapable of comprehensively monitoring for post-translational modifications, a task which is a necessity for truly understanding a cell's biology. This review highlights recent developments in novel multiplexed methods of PTM analysis including: fluorescent stain and immuno-based methods, hardware-based mass spectrometric methods and computational-based mass spectrometric methods. Many of these techniques show great promise and will likely be a valuable resource for the biological community.     

In-gel NHS-propionate derivatization for histone post-translational modifications analysis in Arabidopsis thaliana

Post-translational modifications (PTMs) on histone are highly correlated with genetic and epigenetic regulation of gene expression from chromatin. Mass spectrometry (MS) has developed to be an optimal tool for the identification and quantification of histone PTMs. Derivatization of histones with chemicals such as propionic anhydride, N-hydroxysuccinimide ester (NHS-propionate) has been widely used in histone PTMs analysis in bottom-up MS strategy, which requires high purity for histone samples. However, biological samples are not always prepared with high purity, containing detergents or other interferences in most cases. As an alternative approach, an adaptation of in gel derivatization method, termed In-gel NHS, is utilized for a broader application in histone PTMs analysis and it is shown to be a more time-saving preparation method.     

Differentially Isotope‐Labeled Nucleosomes To Study Asymmetric Histone Modification Crosstalk by Time‐Resolved NMR Spectroscopy

Post‐translational modifications (PTMs) of histones regulate chromatin structure and function. Because nucleosomes contain two copies each of the four core histones, the establishment of different PTMs on individual “sister” histones in the same nucleosomal context, that is, asymmetric histone PTMs, are difficult to analyze. Here, we generated differentially isotope‐labeled nucleosomes to study asymmetric histone modification crosstalk by time‐resolved NMR spectroscopy. Specifically, we present mechanistic insights into nucleosomal histone H3 modification reactions in cis and in trans, that is, within individual H3 copies or between them. We validated our approach by using the H3S10phK14ac crosstalk mechanism, which is mediated by the Gcn5 acetyltransferase. Moreover, phosphorylation assays on methylated substrates showed that, under certain conditions, Haspin kinase is able to produce nucleosomes decorated asymmetrically with two distinct types of PTMs.     

Mapping Post-translational Modifications of Histones H2A, H2B and H4 in Schizosaccharomyces pombe

Core histones are known to carry a variety of post-translational modifications (PTMs), including acetylation, phosphorylation, methylation and ubiquitination, which play important roles in the epigenetic control of gene expression. The nature and biological functions of these PTMs in histones from plants, animals and budding yeast have been extensively investigated. In contrast, the corresponding studies for fission yeast were mainly focused on histone H3. In the present study, we applied LC-nano-ESI-MS/MS, coupled with multiple protease digestion, to identify PTMs in histones H2A, H2B and H4 from Schizosaccharomyces pombe (S. pombe), the typical model organism of fission yeast. Various protease digestions provided high sequence coverage for PTM mapping, and accurate mass measurement of fragment ions allowed for unambiguous differentiation of acetylation from tri-methylation. Many modification sites conserved in other organisms were identified in S. pombe. In addition, some unique modification sites, including N-terminal acetylation in H2A and H2B as well as K123 acetylation in H2A.β, were observed. Our results provide a comprehensive picture of the PTMs of histones H2A, H2B and H4 in S. pombe, which serves as a foundation for future investigations on the regulation and functions of histone modifications in this important model organism.     

The role of post-translational modifications for learning and memory formation

Learning and memory depend on molecular mechanisms involving the protein machinery. Recent evidence proposes that post-translational modifications (PTMs) play a major role in these cognitive processes. PTMs including phosphorylation of serine, threonine, and tyrosine are already well-documented to play a role for synaptic plasticity of the brain, neurotransmitter release, vesicle trafficking and synaptosomal or synaptosomal-associated proteins are substrates of a series of specific protein kinases and their counterparts, protein phosphatases. But protein phosphorylation is only one out of many possible PTMs and first work shows a role of palmitoylation as well as glycosylation for proteins involved in memory formation. Recent technology may now allow reliable detection and even quantification of PTMs of proteins involved in the cognitive system. This will contribute to the understanding of mechanisms for learning and memory formation at the chemical level and has to complement determination of protein levels and indeed determination of protein expression per se generates limited information. The many other PTMs expected including protein nitrosylation and alkylation will even represent targets for pharmacological interventions but in turn increase the complexity of the system. Nevertheless, determination of the presence and the function of PTMs is mandatory and promising cognitive research at the protein chemical level.     

Top‐down characterization of mouse core histones

Histone post‐translational modifications (PTMs) play various roles in chromatin‐related cellular processes, and comprehensive analysis of these combinatorial PTMs at the intact protein level by top‐down proteomics is the method of choice to reveal their crosstalk and biological functions. Here, we report our top‐down characterization of the core histones from mouse fibroblasts cells NIH/3T3, which is a classic model used in many kinds of research. With nanoRPLC‐MS/MS analysis and ProteinGoggle database search, 547 protein species were identified with spectrum‐level FDR ≤ 1%, where PTMs in 51 protein species were unambiguously localized with PTM scores ≥1. High‐resolution MS/MS data also allowed the unambiguous identification of acetylation instead of trimethylation. This study presents a general picture of combinatorial PTMs of mouse core histones, which serves as a basic reference for all future related biological studies.     

Quantitative chemical proteomics approach to identify post-translational modification-mediated protein-protein interactions

Post-translational modifications (PTMs) (e.g., acetylation, methylation, and phosphorylation) play crucial roles in regulating the diverse protein-protein interactions involved in essentially every cellular process. While significant progress has been made to detect PTMs, profiling protein-protein interactions mediated by these PTMs remains a challenge. Here, we report a method that combines a photo-cross-linking strategy with stable isotope labeling in cell culture (SILAC)-based quantitative mass spectrometry to identify PTM-dependent protein-protein interactions. To develop and apply this approach, we focused on trimethylated lysine-4 at the histone H3 N-terminus (H3K4Me(3)), a PTM linked to actively transcribed gene promoters. Our approach identified proteins previously known to recognize this modification and MORC3 as a new protein that binds H3M4Me(3). This study indicates that our cross-linking-assisted and SILAC-based protein identification (CLASPI) approach can be used to profile protein-protein interactions mediated by PTMs, such as lysine methylation.     

Posttranslational modification of indoleamine 2,3-dioxygenase

Protein posttranslational modifications (PTMs) perform essential roles in the biological regulation of a cell. PTMs are extremely important because they can change a protein's physical or chemical properties, conformation, activity, cellular location, or stability. In fact, most proteins are altered by the addition or removal of a chemical moiety on either an amino acid or the protein's N- or C-terminus. Some PTMs can be added and removed dynamically as a mechanism for reversibly controlling protein function. Thus, identifying the PTM sites is critical to fully understand the biological roles of any given protein. Mass spectrometry (MS) is a widely used analytical strategy to identify PTMs. We have used an automated two-dimensional liquid chromatography (LC) system coupled with electrospray ionization quadrupole ion-trap MS to identify PTMs for indoleamine 2,3-dioxygenase 1 (IDO1), one of the tryptophan catabolic enzymes. IDO1 promotes immune tolerance by suppressing local T-cell responses under various physiological and pathophysiological conditions, such as pregnancy in mammals, tumor resistance, autoimmunity, and chronic inflammation. Although many studies have demonstrated the biological importance of IDO activity, the PTMs of IDO enzymes remain largely unknown. Only a few important PTMs of IDO1 have been found, such as nitration, N-terminal acetylation, and phosphorylation. In this review, we analyze the PTMs of IDO1 using our two-dimensional LC-MS/MS system, and provide an overview of our current understanding.     

Simultaneous detection of protein phosphorylation and acetylation by high-resolution NMR spectroscopy

Post-translational protein modifications (PTMs) such as phosphorylation and acetylation regulate a large number of eukaryotic signaling processes. In most instances, it is the combination of different PTMs that "encode" the biological outcome of these covalent amendments in a highly dynamic and cell-state-specific manner. Most research tools fail to detect different PTMs in a single experiment and are unable to directly observe dynamic PTM states in complex environments such as cell extracts or intact cells. Here we describe in situ observations of phosphorylation and acetylation reactions by high-resolution liquid-state NMR spectroscopy. We delineate the NMR characteristics of progressive lysine acetylation and provide in vitro examples of joint phosphorylation and acetylation events and how they can be deciphered on a residue-specific basis and in a time-resolved and quantitative manner. Finally, we extend our NMR investigations to cellular phosphorylation and acetylation events in human cell extracts and demonstrate the unique ability of NMR spectroscopy to simultaneously report the establishment of these PTMs by endogenous cellular enzymes.     

泛素化蛋白的化学合成及半合成

蛋白质翻译后修饰（post-translational modifications,PTMs）在调节蛋白质的结构和功能上发挥着重要作用,异常的蛋白质翻译后修饰会导致某些疾病的发生.泛素化（ubiquitination）作为一类重要的蛋白质翻译后修饰,已经被证明与细胞的稳态以及细胞内部的多条信号通路有关,主要参与细胞内蛋白的定位、调节和降解以及细胞周期、基因表达、信号传递、损伤修复、炎症免疫等多种生命过程.然而,对于泛素蛋白的相关研究虽然进行了多年,但是许多重要的科学问题尚未研究清楚,其中如何高效地获得大量、均一的泛素化蛋白是最重要的挑战之一.近年来,蛋白质化学合成及半合成手段的发展,很大程度上解决了这一难题.本文主要针对目前常用的泛素化蛋白的化学合成和半合成方法进行综述.