Acetylation of p53 inhibits its ubiquitination by Mdm2

In response to DNA damage, the activity of the p53 tumor suppressor is modulated by protein stabilization and post-translational modifications including acetylation. Interestingly, both acetylation and ubiquitination can modify the same lysine residues at the C terminus of p53, implicating a role of acetylation in the regulation of p53 stability. However, the direct effect of acetylation on Mdm2-mediated ubiquitination of p53 is still lacking because of technical difficulties. Here, we have developed a method to obtain pure acetylated p53 proteins from cells, and by using an in vitro purified system, we provide the direct evidence that acetylation of the C-terminal domain is sufficient to abrogate its ubiquitination by Mdm2. Importantly, even in the absence of DNA damage, acetylation of the p53 protein is capable of reducing the ubiquitination levels and extending its half-life in vivo. Moreover, we also show that acetylation of p53 can affect its ubiquitination through other mechanisms in addition to the site competition. This study has significant implications regarding a general mechanism by which protein acetylation modulates ubiquitination-dependent proteasome proteolysis.     

Regulatory cross-talk between lysine acetylation and ubiquitination: role in the control of protein stability

It is now becoming apparent that cross-talk between two protein lysine modifications, acetylation and ubiquitination, is a critical regulatory mechanism controlling vital cellular functions. The most apparent effect is the inhibition of proteasome-mediated protein degradation by lysine acetylation. Analysis of the underlying mechanisms, however, shows that, besides a direct competition between the two lysine modifications, more complex and indirect processes also connect these two signalling pathways. These findings point to protein lysine acetylation as a potential regulator of various cellular functions involving protein ubiquitination.     

Proteomics reveals evidence of cross-talk between protein modifications in bacteria: focus on acetylation and phosphorylation

Recent advances in gel-free, mass spectrometry-based proteomics have firmly established existence of serine phosphorylation, threonine phosphorylation, tyrosine phosphorylation and lysine acetylation on many bacterial proteins. Intriguingly, numerous proteins have been shown to be modified by both modifications, leading to the emerging concept of cross-talk between posttranslational modifications in bacteria. This concept is further supported by biological follow-up studies that are starting to reveal bacterial proteins and processes regulated by multiple modifications. In this review, we provide an overview of the large-scale studies involving protein phosphorylation and acetylation in bacteria and discuss some of the current examples of cross-talk between these and other bacterial modifications.     

A method to distinguish between lysine acetylation and lysine ubiquitination with feature selection and analysis

Lysine acetylation and ubiquitination are two primary post-translational modifications (PTMs) in most eukaryotic proteins. Lysine residues are targets for both types of PTMs, resulting in different cellular roles. With the increasing availability of protein sequences and PTM data, it is challenging to distinguish the two types of PTMs on lysine residues. Experimental approaches are often laborious and time consuming. There is an urgent need for computational tools to distinguish between lysine acetylation and ubiquitination. In this study, we developed a novel method, called DAUFSA (distinguish between lysine acetylation and lysine ubiquitination with feature selection and analysis), to discriminate ubiquitinated and acetylated lysine residues. The method incorporated several types of features: PSSM (position-specific scoring matrix) conservation scores, amino acid factors, secondary structures, solvent accessibilities, and disorder scores. By using the mRMR (maximum relevance minimum redundancy) method and the IFS (incremental feature selection) method, an optimal feature set containing 290 features was selected from all incorporated features. A dagging-based classifier constructed by the optimal features achieved a classification accuracy of 69.53%, with an MCC of .3853. An optimal feature set analysis showed that the PSSM conservation score features and the amino acid factor features were the most important attributes, suggesting differences between acetylation and ubiquitination. Our study results also supported previous findings that different motifs were employed by acetylation and ubiquitination. The feature differences between the two modifications revealed in this study are worthy of experimental validation and further investigation.     

Identification of the Acetylation and Ubiquitin-Modified Proteome during the Progression of Skeletal Muscle Atrophy

Skeletal muscle atrophy is a consequence of several physiological and pathophysiological conditions including muscle disuse, aging and diseases such as cancer and heart failure. In each of these conditions, the predominant mechanism contributing to the loss of skeletal muscle mass is increased protein turnover. Two important mechanisms which regulate protein stability and degradation are lysine acetylation and ubiquitination, respectively. However our understanding of the skeletal muscle proteins regulated through acetylation and ubiquitination during muscle atrophy is limited. Therefore, the purpose of the current study was to conduct an unbiased assessment of the acetylation and ubiquitin-modified proteome in skeletal muscle during a physiological condition of muscle atrophy. To induce progressive, physiologically relevant, muscle atrophy, rats were cast immobilized for 0, 2, 4 or 6 days and muscles harvested. Acetylated and ubiquitinated peptides were identified via a peptide IP proteomic approach using an anti-acetyl lysine antibody or a ubiquitin remnant motif antibody followed by mass spectrometry. In control skeletal muscle we identified and mapped the acetylation of 1,326 lysine residues to 425 different proteins and the ubiquitination of 4,948 lysine residues to 1,131 different proteins. Of these proteins 43, 47 and 50 proteins were differentially acetylated and 183, 227 and 172 were differentially ubiquitinated following 2, 4 and 6 days of disuse, respectively. Bioinformatics analysis identified contractile proteins as being enriched among proteins decreased in acetylation and increased in ubiquitination, whereas histone proteins were enriched among proteins increased in acetylation and decreased in ubiquitination. These findings provide the first proteome-wide identification of skeletal muscle proteins exhibiting changes in lysine acetylation and ubiquitination during any atrophy condition, and provide a basis for future mechanistic studies into how the acetylation and ubiquitination status of these identified proteins regulates the muscle atrophy phenotype.     

The origins and evolution of ubiquitination sites

Protein ubiquitination is central to the regulation of various pathways in eukaryotes. The process of ubiquitination and its cellular outcome were investigated in hundreds of proteins to date. Despite this, the evolution of this regulatory mechanism has not yet been addressed comprehensively. Here, we quantify the rates of evolutionary changes of ubiquitination and SUMOylation (Small Ubiquitin-like MOdifier) sites. We estimate the time at which they first appeared, and compare them to acetylation and phosphorylation sites and to unmodified residues. We observe that the various modification sites studied exhibit similar rates. Mammalian ubiquitination sites are weakly more conserved than unmodified lysine residues, and a higher degree of relative conservation is observed when analyzing bona fide ubiquitination sites. Various reasons can be proposed for the limited level of excess conservation of ubiquitination, including shifts in locations of the sites, the presence of alternative sites, and changes in the regulatory pathways. We observe that disappearance of sites may be compensated by the presence of a lysine residue in close proximity, which is significant when compared to evolutionary patterns of unmodified lysine residues, especially in disordered regions. This emphasizes the importance of analyzing a window in the vicinity of functional residues, as well as the capability of the ubiquitination machinery to ubiquitinate residues in a certain region. Using prokaryotic orthologs of ubiquitinated proteins, we study how ubiquitination sites were formed, and observe that while sometimes sequence additions and rearrangements are involved, in many cases the ubiquitination machinery utilizes an already existing sequence without significantly changing it. Finally, we examine the evolution of ubiquitination, which is linked with other modifications, to infer how these complex regulatory modules have evolved. Our study gives initial insights into the formation of ubiquitination sites, their degree of conservation in various species, and their co-evolution with other posttranslational modifications.     

P53蛋白赖氨酸甲基化与去甲基化

P53作为肿瘤抑制因子和转录调节因子在控制细胞周期、凋亡和DNA修复方面发挥重要作用。P53蛋白的稳定性和转录激活活性的调节主要依赖磷酸化、乙酰化、泛素化等多种翻译后修饰。最近研究发现一些组蛋白赖氨酸甲基转移酶和去甲基化酶可使P53蛋白C-端赖氨酸残基发生甲基化或去甲基化,调节P53蛋白的稳定性和转录激活活性。甲基化和去甲基化与其它翻译后修饰相互作用构成“P53密码”调节P53蛋白功能。     

Distinctive core histone post-translational modification patterns in Arabidopsis thaliana

Post-translational modifications of histones play crucial roles in the genetic and epigenetic regulation of gene expression from chromatin. Studies in mammals and yeast have found conserved modifications at some residues of histones as well as non-conserved modifications at some other sites. Although plants have been excellent systems to study epigenetic regulation, and histone modifications are known to play critical roles, the histone modification sites and patterns in plants are poorly defined. In the present study we have used mass spectrometry in combination with high performance liquid chromatography (HPLC) separation and phospho-peptide enrichment to identify histone modification sites in the reference plant, Arabidopsis thaliana. We found not only modifications at many sites that are conserved in mammalian and yeast cells, but also modifications at many sites that are unique to plants. These unique modifications include H4 K20 acetylation (in contrast to H4 K20 methylation in non-plant systems), H2B K6, K11, K27 and K32 acetylation, S15 phosphorylation and K143 ubiquitination, and H2A K144 acetylation and S129, S141 and S145 phosphorylation, and H2A.X S138 phosphorylation. In addition, we found that lysine 79 of H3 which is highly conserved and modified by methylation and plays important roles in telomeric silencing in non-plant systems, is not modified in Arabidopsis. These results suggest distinctive histone modification patterns in plants and provide an invaluable foundation for future studies on histone modifications in plants.     

Synthesis of proteins with defined posttranslational modifications using the genetic noncanonical amino acid incorporation approach

Posttranslational modifications modulate the activities of most eukaryotic proteins and play a critical role in all aspects of cellular life. Understanding functional roles of these modifications requires homogeneously modified proteins that are usually difficult to purify from their natural sources. An emerging powerful tool for synthesis of proteins with defined posttranslational modifications is to genetically encode modified amino acids in living cells and incorporate them directly into proteins during the protein translation process. Using this approach, homogenous proteins with tyrosine sulfation, tyrosine phosphorylation mimics, tyrosine nitration, lysine acetylation, lysine methylation, and ubiquitination have been synthesized in large quantities. In this review, we provide a brief introduction to protein posttranslational modifications and the genetic noncanonical amino acid (NAA) incorporation technique, then discuss successful applications of the genetic NAA incorporation approach to produce proteins with defined modifications, and end with challenges and ongoing methodology developments for synthesis of proteins with other modifications.     

Molecular implementation and physiological roles for histone H3 lysine 4 (H3K4) methylation

Chromosomal surfaces are ornamented with a variety of post-translational modifications of histones, which are required for the regulation of many of the DNA-templated processes. Such histone modifications include acetylation, sumoylation, phosphorylation, ubiquitination, and methylation. Histone modifications can either function by disrupting chromosomal contacts or by regulating non-histone protein interactions with chromatin. In this review, recent findings will be discussed regarding the regulation of the implementation and physiological significance for one such histone modification, histone H3 lysine 4 (H3K4) methylation by the yeast COMPASS and mammalian COMPASS-like complexes.     

Post-translational modifications of lysine-specific demethylase 1

Lysine-specific demethylase 1 (LSD1) is crucial for regulating gene expression by catalyzing the demethylation of mono- and di-methylated histone H3 lysine 4 (H3K4) and lysine 9 (H3K9) and non-histone proteins through the amine oxidase activity with FAD⁺ as a cofactor. It interacts with several protein partners, which potentially contributes to its diverse substrate specificity. Given its pivotal role in numerous physiological and pathological conditions, the function of LSD1 is closely regulated by diverse post-translational modifications (PTMs), including phosphorylation, ubiquitination, methylation, and acetylation. In this review, we aim to provide a comprehensive understanding of the regulation and function of LSD1 following various PTMs. Specifically, we will focus on the impact of PTMs on LSD1 function in physiological and pathological contexts and discuss the potential therapeutic implications of targeting these modifications for the treatment of human diseases.     

Dual Coordination of Post Translational Modifications in Human Protein Networks

Post-translational modifications (PTMs) regulate protein activity, stability and interaction profiles and are critical for cellular functioning. Further regulation is gained through PTM interplay whereby modifications modulate the occurrence of other PTMs or act in combination. Integration of global acetylation, ubiquitination and tyrosine or serine/threonine phosphorylation datasets with protein interaction data identified hundreds of protein complexes that selectively accumulate each PTM, indicating coordinated targeting of specific molecular functions. A second layer of PTM coordination exists in these complexes, mediated by PTM integration (PTMi) spots. PTMi spots represent very dense modification patterns in disordered protein regions and showed an equally high mutation rate as functional protein domains in cancer, inferring equivocal importance for cellular functioning. Systematic PTMi spot identification highlighted more than 300 candidate proteins for combinatorial PTM regulation. This study reveals two global PTM coordination mechanisms and emphasizes dataset integration as requisite in proteomic PTM studies to better predict modification impact on cellular signaling.     

Bioinformatic analysis and post-translational modification crosstalk prediction of lysine acetylation

Recent proteomics studies suggest high abundance and a much wider role for lysine acetylation (K-Ac) in cellular functions. Nevertheless, cross influence between K-Ac and other post-translational modifications (PTMs) has not been carefully examined. Here, we used a variety of bioinformatics tools to analyze several available K-Ac datasets. Using gene ontology databases, we demonstrate that K-Ac sites are found in all cellular compartments. KEGG analysis indicates that the K-Ac sites are found on proteins responsible for a diverse and wide array of vital cellular functions. Domain structure prediction shows that K-Ac sites are found throughout a wide variety of protein domains, including those in heat shock proteins and those involved in cell cycle functions and DNA repair. Secondary structure prediction proves that K-Ac sites are preferentially found in ordered structures such as alpha helices and beta sheets. Finally, by mutating K-Ac sites in silico and predicting the effect on nearby phosphorylation sites, we demonstrate that the majority of lysine acetylation sites have the potential to impact protein phosphorylation, methylation, and ubiquitination status. Our work validates earlier smaller-scale studies on the acetylome and demonstrates the importance of PTM crosstalk for regulation of cellular function.     

组蛋白修饰调节机制的研究进展

表观遗传学涉及到DNA甲基化、组蛋白修饰、染色体重塑和非编码RNA调控等内容,其中组蛋白修饰包括组蛋白的乙酰化、磷酸化、甲基化、泛素化及ADP核糖基化等,这些多样化的修饰以及它们时间和空间上的组合与生物学功能的关系又可作为一种重要的表观标志或语言,因而被称为“组蛋白密码”．相同组蛋白残基的磷酸化与去磷酸化、乙酰化与去乙酰化、甲基化与去甲基化等,以及不同组蛋白残基的磷酸化与乙酰化、泛素化与甲基化、磷酸化与甲基化等组蛋白修 饰之间既相互协同又互相拮抗,形成了一个复杂的调节网络．对组蛋白修饰内在调节机制的研究将丰富“组蛋白密码”的内涵．