古菌蛋白质修饰研究进展

20世纪50年代中期,在古菌的表层(S-层)首次发现了糖蛋白;21世纪初又在空肠弯曲菌(Campylobacter jejuni)中发现了蛋白质N-糖基化修饰。由此,同行开始认识到,蛋白质的糖基化修饰广泛存在于古菌、细菌及真核生物三域中。近十年来,古菌蛋白质糖基化修饰的研究取得了进展,特别是古菌蛋白质N-糖基化修饰研究进展快速。但对古菌糖蛋白O-糖基化修饰和脂修饰的了解甚少。本文综述了古菌蛋白质糖基化修饰的研究进展。     

丝状真菌糖生物学

蛋白质的糖基化修饰是一种保守的真核生物蛋白质翻译后修饰,存在于从酵母到人的所有真核生物中,赋予了蛋白质功能的多样性。目前对蛋白质糖基化修饰的了解主要来源于对酵母和哺乳动物细胞的研究,但单细胞真核生物或动物细胞水平的研究,很难反映糖基化修饰在多细胞真核生物的发育分化过程中的复杂功能。由于丝状真菌是多细胞真核生物,有相对简单的发育分化过程,因而是研究多细胞真核生物糖基化功能的理想模型之一,在过去10年中,丝状真菌的糖生物学研究开始受到重视,目前的研究结果表明糖基化修饰与丝状真菌的生长、发育密切相关。     

细菌糖基化基本元件及其应用研究进展

近年来,细菌糖基化修饰系统的研究受到了越来越广泛的关注。已有文献报道了诸多细菌糖基化修饰系统,包括最具有代表性的空肠弯曲杆菌的N-糖基化修饰系统以及脑膜炎奈瑟菌的O-糖基修饰系统。本文在已有的研究基础上进行了系统的归纳总结,讨论对细菌蛋白质糖基化系统的理解,同时综述了细菌蛋白质糖基化应用方面的相关进展。     

糖基转移酶和去糖基化酶

在糖基化工程中,通过酶法对蛋白质进行糖基化修饰和对天然糖蛋白去糖基化是研究糖蛋白结构与功能的重要手段。本文综述了近年来所纯化的主要的糖基化转移酶和去糖基化酶的性质和应用。     

蛋白质糖基化工程

糖基化是蛋白质的一种重要的翻译后修饰,对蛋白质的结构和功能有重要影响。蛋白质糖基化工程是通过对蛋白质表面的糖链进行改造,从而改良蛋白质性质的一种技术。综述了蛋白质糖基化工程的原理、方法和应用。     

糖基化对蛋白质稳定性的影响研究进展

蛋白质的糖基化修饰是广泛存在于真核细胞中的蛋白修饰形式之一,在决定蛋白质的多种生物学功能并且能保护蛋白质免受热力学降解方面发挥重要作用。蛋白质的糖基化修饰包括N-糖基化和O-糖基化,本文简要介绍体内糖基化的过程,并结合近几年文献就糖基化对蛋白质稳定性的影响做一综述。     

酵母糖基化改造工程研究进展

酵母真核表达系统是常用的安全性较高的外源蛋白表达系统。酵母细胞内存在翻译后糖基化修饰过程,对其糖基化修饰系统进行改造可用于生产人源糖蛋白。研究表明,可以通过基因工程手段消除酵母特有的内源糖基化反应、引入哺乳动物细胞表达系统中糖基化类型等方法对酵母糖基化路径进行改造。近年来许多研究通过对酵母菌株糖基化位点突变、基因缺失等方法对酵母糖基化系统进行改造,探究糖基化修饰对蛋白质功能的影响,这为利用酵母生产治疗性蛋白和新型糖基化疫苗提供了新的思路。本综述将对近年来酵母糖基化改造成果及研究进展进行综述。     

蛋白质O-GlcNAc糖基化修饰对tau蛋白磷酸化修饰的影响

蛋白质的O位N-乙酰葡萄糖胺(O-GlcNAc)糖基化修饰是一种新近发现的广泛存在于细胞核蛋白与细胞浆蛋白的蛋白质翻译后修饰.其性质与经典的膜蛋白和分泌蛋白的糖基化修饰不同,而与蛋白质磷酸化修饰更相似.O-GlcNAc糖基化和磷酸化均修饰tau蛋白的丝氨酸和苏氨酸残基,通过改变O-GlcNAc糖基化供体底物浓度以及其关键酶活性等方法,改变分化后成神经细胞样的PC12细胞中的蛋白质O-GlcNAc糖基化修饰水平,然后用特异性识别不同位点磷酸化的tau蛋白抗体,进行蛋白质印迹分析来检测tau蛋白磷酸化水平的变化.结果发现细胞内蛋白质O-GlcNAc糖基化对tau蛋白磷酸化的影响,在不同的磷酸化位点其影响不同.增加蛋白质O-GlcNAc糖基化修饰导致tau蛋白大多数磷酸位点的磷酸化水平降低,反之亦然.这些结果说明,tau磷酸化在大多数位点受到O-GlcNAc糖基化修饰的负性调节.这一研究为阐明调节tau蛋白磷酸化水平的机理和阿尔茨海默病脑中tau异常过度磷酸化的分子机制提供了新的线索.     

糖基转移酶在去糖基化酶

在糖基化工程中,通过酶法对蛋白质进行糖基化和修饰和对天然糖蛋白去糖基化是研究糖蛋白结构与功能的重要手段。本文综述了近年来所纯化的主要的糖基化转移酶和去糖基化酶的性质和应用。     

病毒抗原糖基化与免疫关系的研究进展

糖基化是蛋白质的一种重要的翻译后修饰,在影响蛋白质的结构和功能方面扮演着重要角色。许多病毒抗原都有糖基化的现象,糖基化会改变病毒对宿主的免疫逃避、病毒抗原的免疫原性等。了解病毒抗原糖基化与免疫之间的关系,将有助于抗病毒疫苗的研究。     

Automated measurement of site‐specific N‐glycosylation occupancy with SWATH‐MS

Asparagine‐linked glycosylation is a common post‐translational modification of proteins catalyzed by oligosaccharyltransferase that is important in regulating many aspects of protein function. Analysis of protein glycosylation, including glycoproteomic measurement of the site‐specific extent of glycosylation, remains challenging. Here, we developed methods combining enzymatic deglycosylation and protease digestion with SWATH‐MS to enable automated measurement of site‐specific occupancy at many glycosylation sites. Deglycosylation with peptide‐endoglycosidase H, leaving a remnant N‐acetylglucosamine on asparagines previously carrying high‐mannose glycans, followed by trypsin digestion allowed robust automated measurement of occupancy at many sites. Combining deglycosylation with the more general peptide‐N‐glycosidase F enzyme with AspN protease digest allowed robust automated differentiation of nonglycosylated and deglycosylated forms of a given glycosylation site. Ratiometric analysis of deglycosylated peptides and the total intensities of all peptides from the corresponding proteins allowed relative quantification of site‐specific glycosylation occupancy between yeast strains with various isoforms of oligosaccharyltransferase. This approach also allowed robust measurement of glycosylation sites in human salivary glycoproteins. This method for automated relative quantification of site‐specific glycosylation occupancy will be a useful tool for research with model systems and clinical samples.     

昆虫杆状病毒系统表达外源蛋白的糖基化

昆虫表达系统作为一类应用广泛的真核表达系统 ,具有与多数高等真核生物相类似的翻译后修饰的过程。但其生产的重组糖蛋白一般仅具有高甘露糖或寡甘露糖型糖链 ,难以生成复杂构型糖链成为该系统的缺陷之一。综述了目前昆虫杆状病毒系统表达外源蛋白的糖基化研究进展。     

毕赤酵母表达系统在外源蛋白表达中的研究及应用

巴斯得毕赤酵母（Pichia pastoris）表达系统作为一个日臻完善的外源蛋白真核表达系统由于它所具有的一些其它表达系统不可比拟的优势而得到越来越广泛的应用。分别从该表达系统的优点、外源基因整合及调控机理、表达蛋白糖基化及翻译后修饰等方面综述了其在外源蛋白表达中的研究进展及应用。     

Theoretical and experimental characterization of the scope of protein O-glycosylation in Bacteroides fragilis

Among bacterial species demonstrated to have protein O-glycosylation systems, that of Bacteroides fragilis and related species is unique in that extracytoplasmic proteins are glycosylated at serine or threonine residues within the specific three-amino acid motif D(S/T)(A/I/L/M/T/V). This feature allows for computational analysis of the proteome to identify candidate glycoproteins. With the criteria of a signal peptidase I or II cleavage site or a predicted transmembrane-spanning region and the presence of at least one glycosylation motif, we identified 1021 candidate glycoproteins of B. fragilis. In addition to the eight glycoproteins identified previously, we confirmed that another 12 candidate glycoproteins are in fact glycosylated. These included four glycoproteins that are predicted to localize to the inner membrane, a compartment not previously shown to include glycosylated proteins. In addition, we show that four proteins involved in cell division and chromosomal segregation, two of which are encoded by candidate essential genes, are glycosylated. To date, we have not identified any extracytoplasmic proteins containing a glycosylation motif that are not glycosylated. Therefore, based on the list of 1021 candidate glycoproteins, it is likely that hundreds of proteins, comprising more than half of the extracytoplasmic proteins of B. fragilis, are glycosylated. Site-directed mutagenesis of several glycoproteins demonstrated that all are glycosylated at the identified glycosylation motif. By engineering glycosylation motifs into a naturally unglycosylated protein, we are able to bring about site-specific glycosylation at the engineered sites, suggesting that this glycosylation system may have applications for glycoengineering.     

Glycosylation of a disintegrin and metalloprotease 17 affects its activity and inhibition

ADAM17 (a disintegrin and metalloprotease 17) is believed to be a tractable target in various diseases, including cancer and rheumatoid arthritis; however, it is not known whether glycosylation of ADAM17 expressed in healthy cells differs from that found in diseased tissue and, if so, whether glycosylation affects inhibitor binding. We expressed human ADAM17 in mammalian and insect cells and compared their glycosylation, substrate kinetics, and inhibition profiles. We found that ADAM17 expressed in mammalian cells was more heavily glycosylated than its insect-expressed analog. To determine whether differential glycosylation modulates enzymatic activity, we performed kinetic studies with both ADAM17 analogs and various TNFα-based substrates. The mammalian form of ADAM17 exhibited 10- to 30-fold lower k_cat values than the insect analog, while the K_M was unaffected, suggesting that glycosylation of ADAM17 can potentially play a role in regulating enzyme activity in vivo. Finally, we tested ADAM17 forms for inhibition by several well-characterized inhibitors. Active-site zinc-binding small molecules did not exhibit differences between the two ADAM17 analogs, while a non-zinc-binding exosite inhibitor of ADAM17 showed significantly lower potency toward the mammalian-expressed analog. These results suggest that glycosylation of ADAM17 can affect cell signaling in disease and might provide opportunities for therapeutic intervention using exosite inhibitors.     

Glycosylation affects ligand binding and function of the activating natural killer cell receptor 2B4 (CD244) protein

2B4 (CD244) is an important activating receptor for the regulation of natural killer (NK) cell responses. Here we show that 2B4 is heavily and differentially glycosylated in primary human NK cells and NK cell lines. The differential glycosylation could be attributed to sialic acid residues on N- and O-linked carbohydrates. Using a recombinant fusion protein of the extracellular domain of 2B4, we demonstrate that N-linked glycosylation of 2B4 is essential for the binding to its ligand CD48. In contrast, sialylation of 2B4 has a negative impact on ligand binding, as the interaction between 2B4 and CD48 is increased after the removal of sialic acids. This was confirmed in a functional assay system, where the desialylation of NK cells or the inhibition of O-linked glycosylation resulted in increased 2B4-mediated lysis of CD48-expressing tumor target cells. These data demonstrate that glycosylation has an important impact on 2B4-mediated NK cell function and suggest that regulated changes in glycosylation during NK cell development and activation might be involved in the regulation of NK cell responses.     

High-performance targeted mass spectrometry with precision data-independent acquisition reveals site-specific glycosylation macroheterogeneity

Protein glycosylation is a critical post-translational modification that regulates the structure, stability, and function of many proteins. Mass spectrometry is currently the preferred method for qualitative and quantitative characterization of glycosylation. However, the inherent heterogeneity of glycosylation makes its analysis difficult. Quantification of glycosylation occupancy, or macroheterogeneity, has proven to be especially challenging. Here, we used a variation of high-resolution multiple reaction monitoring (MRM^HR) or pseudo-MRM for targeted data-independent acquisition that we term SWAT (sequential window acquisition of targeted fragment ions). We compared the analytical performance of SWATH (sequential window acquisition of all theoretical fragment ions), SWAT, and SRM (selected reaction monitoring) using a suite of synthetic peptides spiked at various concentrations into a complex yeast tryptic digest sample. SWAT provided superior analytical performance to SWATH in a targeted approach. We then used SWAT to measure site-specific N-glycosylation occupancy in cell wall glycoproteins from yeast with defects in the glycosylation biosynthetic machinery. SWAT provided robust measurement of occupancy at more N-glycosylation sites and with higher precision than SWATH, allowing identification of novel glycosylation sites dependent on the Ost3p and Ost6p regulatory subunits of oligosaccharyltransferase.     

Glycosylation of alpha-1-proteinase inhibitor and haptoglobin in ovarian cancer: evidence for two different mechanisms

The change in glycosylation of the two acute-phase proteins, alpha-1-proteinase inhibitor (API) and haptoglobin (Hp), in progressive ovarian cancer is different. This has been shown by monosaccharide analysis and lectin-binding studies of proteins purified from serum. In the glycan chains of API, there is decreased branching (more biantennary chains), less branches ending in alpha 2-3 sialic acid, more branches ending in alpha 2-6 sialic acid and more fucose, probably linked alpha 1-6 to the core region. On the other hand, Hp shows increased branching (more triantennary chains), more branches ending in alpha 2-3 sialic acid, less branches ending in alpha 2-6 sialic acid, and more fucose, probably in the alpha 1-3 linkage at the end of the chains. This is surprising because API and Hp are thought to be glycosylated by a common pathway in the liver. We have also shown that the fucose-specific lectin,lotus tetragonolobus, extracts abnormal forms of both Hp and API in ovarian cancer, but the expression of this Hp is related to tumour burden and the expression of this API is related to lack of response to therapy. It is suggested that this difference in the behaviour of API and Hp in ovarian cancer may be associated with the different changes in their glycosylation. Of the many mechanisms that could explain these findings, a likely one is that a pathological process is removing API with triantennary chains from the circulation. In addition to their normal roles (API-enzyme inhibitor and Hp-transport protein) these proteins are reported to have many other effects in biological systems, such as immunosuppression. As correct glycosylation of API and Hp is required for their normal stability/activity, changes in glycosylation could affect their functions in ovarian cancer and these modifications could alter the course of the disease.     

Asparagine 81, an invariant glycosylation site near apyrase conserved region 1, is essential for full enzymatic activity of ecto-nucleoside triphosphate diphosphohydrolase 3

N-linked glycosylation is important for the function, cellular localization, and oligomerization of membrane-bound ecto-nucleoside triphosphate diphosphohydrolases (eNTPDases). NTPDase3 is a prototypical cell membrane-associated eNTPDase, which is equally related and enzymatically intermediate to the other two cell surface membrane NTPDases (NTPDase1 and 2). The protein sequence of NTPDase3 contains seven putative N-glycosylation sites located in the ecto-domain. Only one of these putative glycosylation sites, asparagine 81 in NTPDase3, which is located near apyrase conserved region 1 (ACR1), is invariant in all the cell surface membrane eNTPDases. Using site-directed mutagenesis, mutants were constructed to eliminate this highly conserved N-glycosylation site in NTPDase3. The results indicate that glycosylation at this position is essential for full enzymatic activity, with mutant ATPase activity decreased more than ADPase activity. Enzymatic deglycosylation of this site is shown to be responsible for the inactivation of the wild-type enzyme by treatment with peptide N-glycosidase-F. In addition, glycosylation of this conserved site is necessary for the stabilization/stimulation of nucleotidase activity upon treatment with the lectin concanavalin A. However, lack of glycosylation at this site did not result in large changes in tertiary or quaternary structure, as measured by Cibacron blue binding, chemical cross-linking, and native gel electrophoretic analysis. Since this N-glycosylation site is invariant in cell membrane eNTPDases, it is postulated that glycosylation of this residue near ACR1 is crucial for full enzymatic activity of the cell membrane NTPDases.