PTEN蛋白的翻译后修饰

第10号染色体缺失的磷酸酶与张力蛋白同源物(phosphatase and tensin homolog,PTEN)基因所编码的PTEN蛋白兼具有脂质和蛋白磷酸酶活性,它的表达、活性和稳定性受到各种结合蛋白、酶和因子的调节。结合最新研究,本文将集中对PTEN上氨基酸残基位点的各种翻译后修饰进行一综述。     

Post-translational isoprenylation of tryptophan

Bacillus subtilis and related bacilli produce a post-translationally modified oligopeptide, ComX pheromone, that stimulates natural genetic competence controlled by quorum sensing. The ComX pheromones are formed by geranylation or farnesylation on a tryptophan residue at the 3 position of its indole ring. This results in the formation of a tricyclic structure including, a newly formed five-membered ring, similar to proline. Isoprenylation of ComX to form ComX pheromones is essential for pheromonal activity, and is functionally more crucial than its amino acid sequence. The ComX pheromone is the first example of isoprenoidal modifiations of tryptophan residues in living organisms and post-translational isoprenylation of any amino acid in prokaryotes. Because the presence of geranylated compounds is unusual in primary and secondary metabolites outside the plant kingdom, post-translational geranylation in bacilli is unprecedented in nature.     

Post-translational modification of proteins

Many proteins, especially those produced by eukaryotic cells, undergo extensive, essentially irreversible, modifications after their synthesis. This review focuses on three classes of such reactions: proteolytic cleavages, formation of S-S cystine bonds, and formation of asparagine-linked carbohydrate chains. Emphasis is placed on the mechanism of these reactions, and on the importance of these modifications for the proper structure, function and stability of the affected proteins. Using recombinant DNA techniques, it is now possible to synthesize the polypeptide portion of many proteins, such as mammalian peptide hormones and enzymes, in bacterial and yeast cells. These host cells, however, may be unable to carry out essential post-translational modifications. Ways in which the properly modified form of these ‘engineered’ proteins can be produced are considered.     

Post-translational modifications of lantibiotics

Several newly reported post-translational modification reactions are involved in lantibiotic biosynthesis. A short overview of the present knowledge on the post-translational modifications and on the enzymes involved in lantibiotic biosynthesis is given. The oxidative decarboxylation of the epidermin precursor peptide EpiA is described in detail. The FMN-containing oxidoreductase EpiD is involved in the formation of the C-terminal S-[(Z)-2-aminovinyl]-D-cysteine residue of epidermin: under reducing conditions the side chain of the C-terminal cysteine residue of EpiA is converted to an enethiol. EpiD has no absolute substrate specificity and can be used for modification of peptides having the C-terminal consensus motif [V/I/L/(M)/F/Y/W]-[A/S/V/T/C/(I/L)]-C.Abbreviations Dha 2,3-didehydroalanine - Dhb (Z)-2,3-didehydrobutyrine - ES-MS Electrospray Mass Spectrometry - FAD Flavin Adenine Dinucleotide - FMN Flavin Mononucleotide - MBP Maltose-Binding Protein - TFA TrifluoroAcetic Acid - TLC Thin-Layer Chromatography     

肽酰精氨酸的翻译后修饰

肽酰精氨酸残基甲基化作用是细胞质与细胞核内蛋白质翻译后修饰的普遍方式。精氨酸残基甲基化蛋白质与许多细胞生物学过程有关,包括转录调节、RNA代谢和DNA损伤修复等。生物体内精氨酸N-甲基转移酶类、肽酰精氨酸脱亚氨酶类与JMJD6等催化肽酰精氨酸残基进行甲基化、瓜氨酸化和去甲基化的动态修饰。这种动态修饰对细胞生物学功能有重要调节作用。     

Post-translational modification of RAS proteins

Mutations of RAS genes drive cancer more frequently than any other oncogene. RAS proteins integrate signals from a wide array of receptors and initiate downstream signaling through pathways that control cellular growth. RAS proteins are fundamentally binary molecular switches in which the off/on state is determined by the binding of GDP or GTP, respectively. As such, the intrinsic and regulated nucleotide-binding and hydrolytic properties of the RAS GTPase were historically believed to account for the entirety of the regulation of RAS signaling. However, it is increasingly clear that RAS proteins are also regulated by a vast array of post-translational modifications (PTMs). The current challenge is to understand what are the functional consequences of these modifications and which are physiologically relevant. Because PTMs are catalyzed by enzymes that may offer targets for drug discovery, the study of RAS PTMs has been a high priority for RAS biologists.     

The vitamin K-dependent carboxylation reaction

Summary Gammacarboxyglutamic acid (Gla) is an abnormal amino acid, which occurs in a number of proteins. It was discovered about 10 years ago in the four vitamin K-dependent blood clotting factors and it could be demonstrated that Gla is formed in a post-translational modification step, which requires a carboxylating enzyme system (carboxylase) and vitamin K. Since at the time of this discovery the earlier mentioned clotting factors were the only proteins known to be synthesized in a vitamin K-dependent way, it has been assumed for many years that the blood clotting system was unique in this respect. Recently it has been demonstrated, however, that vitamin K-dependent carboxylase is not restricted to the liver (the place of synthesis of the clotting factors) but that it is also present in other tissues such as lung, kidney, spleen and testis. Moreover, numerous Gla-containing proteins have been detected, although in most cases their function is not wholly understood. It seems that (like for instance the glycosylation) the vitamin K-dependent carboxylation is a normal post-translational. modification, which is required for the correct function of a certain class of Ca²⁺-binding proteins.     

Post-translational phosphorylation of proteodermatan sulfate

In cultured human skin fibroblasts, the core protein of the small proteodermatan sulfate becomes phosphorylated post-translationally but before the glycosaminoglycan chains are synthesized. This phosphorylation can occur when the intracellular transport is inhibited by carbonyl cyanide m-chlorophenylhydrazone or when the attachment of asparagine-linked oligosaccharides is prevented by tunicamycin. Serine and glycosaminoglycan chains were identified as phosphorylation sites of secreted proteodermatan sulfate. Upon alkaline borohydride treatment and degradation by chondroitin ABC lyase, the main phosphorylated product co-chromatographed with an unsulfated 3H-labeled hexasaccharide prepared analogously from [3H]galactose/[35S]sulfate-labeled proteodermatan sulfate.     

Post-translational processing of bovine chondromodulin-I

Chondromodulin-I (ChM-I) is a small glycoprotein that is abundant in fetal cartilage. Mature chondromodulin-I is processed from a larger precursor form, presumably at a proteolytic site RERR-ELVR. The precursor, mature chondromodulin-I and two processed products, the remnant left after removal of mature chondromodulin-I and a smaller, unglycosylated form, were identified using antipeptide antisera. The products of chondromodulin-I precursor processing were seen in cultured chondrocytes, a stable long-term culture chondrosarcoma cell line, as well as Chinese hamster ovary (CHO) cells transfected with an expression plasmid that contained cDNA coding for the chondromodulin-I precursor. Pulse-chase analysis allowed a processing pathway to be analyzed for chondromodulin-I. To further dissect the processing events, three constructs that express recombinant wild-type or mutant chondromodulin-I were transfected into CHO cells. We showed that chondromodulin-I is cleaved intracellularly at the predicted cleavage site, and that the mature glycopeptide is rapidly secreted immediately after processing. The chondromodulin-1 precursor has a short half-life and is not readily apparent in tissue samples, suggesting that chondromodulin is not a member of the juxtacrine family of growth factors, despite some similarities. The smaller unglycosylated form of chondromodulin-I was only observed in cartilage and not in short-term cultures or transfected cells, suggesting an extracellular processing event. No processing occurred when the precursor cleavage site was mutated to RERQ-SLVR or when precursor chondromodulin-I was expressed in the furin-deficient CHO cell line, suggesting the involvement of furin in processing.     

神经肽前体的翻译后加工

神经肽前体的翻译后加工是神经肽生物合成中的重要环节,它具有顺序专一性、组织特异性以及生理调控性。     

Post-translational regulation of signaling mucins

Signaling mucins are large transmembrane glycoproteins that regulate signal transduction pathways. Recent advances have shown that two major types of post-translational modifications, protein glycosylation and proteolytic processing, play important and unexpected roles in regulating signaling mucin function. New O-glycosyltransferases and proteases have been identified, and the structure of the domain that undergoes auto-proteolysis has been solved. A picture is beginning to emerge where specific glycosyl modifications and regulated processing control the signaling and adherence properties of signaling glycoproteins and contribute to the routing of signals to specific pathways.     

Post-translational modifications of superoxide dismutase

Post-translational modifications of proteins control many biological processes through the activation, inactivation, or gain-of-function of the proteins. Recent developments in mass spectrometry have enabled detailed structural analyses of covalent modifications of proteins and also have shed light on the post-translational modification of superoxide dismutase. In this review, we introduce some covalent modifications of superoxide dismutase, nitration, phosphorylation, glutathionylaion, and glycation. Nitration has been the most extensively analyzed modification both in vitro and in vivo. Reaction of human Cu,Zn superoxide dismutase (SOD) with reactive nitrogen species resulted in nitration of a single tryptophan residue to 6-nitrotryptophan, which could be a new biomarker of a formation of reactive nitrogen species. On the other hand, tyrosine 34 of human MnSOD was exclusively nitrated to 3-nitrotyrosine and almost completely inactivated by the reaction with peroxynitrite. The nitrated MnSOD has been found in many diseases caused by ischemia/reperfusion, inflammation, and others and may have a pivotal role in the pathology of the diseases. Most of the post-translational modifications have given rise to a reduced activity of SOD. Since phosphorylation and nitration of SOD have been shown to have a possible reversible process, these modifications may be related to a redox signaling process in cells. Finally we briefly introduce a metal insertion system of SOD, focusing particularly on the iron misincorporation of nSOD, as a part of post-translational modifications.     

Post-translational regulation of sphingosine kinases

Sphingosine kinases (SKs) catalyse the conversion of sphingosine to sphingosine 1-phosphate (S1P), a signalling lipid that is involved in a plethora of cellular processes including proliferation, apoptosis, calcium homeostasis, angiogenesis, vascular and neuronal maturation, cell migration and immune responses. Over the last few years, it has become clear that SKs are subject to various forms of post-translational regulation which play important roles in the function of these enzymes. Moreover, dysregulation of SKs has been implicated in many pathological conditions, such as cancer. Here we review the various mechanisms of post-translational regulation of the SKs with the view that such knowledge may lead to the development of therapeutic strategies to modulate the activities of these enzymes in the treatment of cancer and a range of other conditions. This article is part of a Special Issue entitled Advances in Lysophospholipid Research.