Quantitative analysis of both protein expression and serine / threonine post-translational modifications through stable isotope labeling with dithiothreitol

While phosphorylation and O-GlcNAc (cytoplasmic and nuclear glycosylation) are linked to normal and pathological changes in cell states, these post-translational modifications have been difficult to analyze in proteomic studies. We describe advances in beta-elimination / Michael addition-based approaches which allow for mass spectrometry-based identification and comparative quantification of O-phosphate or O-GlcNAc-modified peptides, as well as cysteine-containing peptides for expression analysis. The method (BEMAD) involves differential isotopic labeling through Michael addition with normal dithiothreitol (DTT) (d0) or deuterated DTT (d6), and enrichment of these peptides by thiol chromatography. BEMAD was comparable to isotope-coded affinity tags (ICAT; a commercially available differential isotopic quantification technique) in protein expression analysis, but also provided the identity and relative amounts of both O-phosphorylation and O-GlcNAc modification sites. Specificity of O-phosphate vs. O-GlcNAc mapping is achieved through coupling enzymatic dephosphorylation or O-GlcNAc hydrolysis with differential isotopic labeling. Blocking of cysteine labeling by prior oxidation of a cytosolic lysate from mouse brain allowed specific targeting of serine / threonine post-translational modifications as demonstrated through identification of 21 phosphorylation sites (5 previously reported) in a single mass spectrometry analysis. These results demonstate BEMAD is suitable for large-scale quantitative analysis of both protein expression and serine / threonine post-translational modifications.     

Structural properties of recombinant ovalbumin and its transformation into a thermostabilized form by alkaline treatment.

The recombinant ovalbumin produced in Escherichia coli was purified from the cytoplasmic fraction and analyzed for its chemical and conformational properties. The recombinant ovalbumin displayed almost exactly the same circular dichroism and intrinsic tryptophan fluorescence spectra as egg white ovalbumin. As in the egg white protein, four cysteine sulfhydryls and one cystine disulfide were contained in the recombinant protein, according to the results of amino acid analyses; the disulfide bond was found by a peptide mapping analysis to correspond to the native cystine, Cys73-Cys120. According to a gel electrophoresis analysis, the presence of the disulfide bond was accounted for by specific oxidation of the corresponding cysteine residues during purification of the cytoplasmic protein. Unlike the identity in the conformational and peptide structures, none of the post-translational modifications (N-terminal acetylation, phosphorylation, and glycosylation) that are known with egg white ovalbumin were detected in the recombinant protein. The recombinant ovalbumin was transformed into a thermostabilized form in a similar manner to the transformation of egg white protein into S-ovalbumin; alkaline treatment increased the temperature for thermostability by 8.7 degrees C. These data strongly suggest that the post-translational modifications of ovalbumin are not related to the formation mechanism for S-ovalbumin.     

Mass spectrometric analysis of posttranslational modifications of a carrot extracellular glycoprotein

Expression of extracellular dermal glycoprotein (EDGP) is induced by biotic or abiotic stress. The amino acid sequence alignment showed that EDGP shared significant homology with proteins from legumes, tomato, Arabidopsis, wheat, and cotton. These proteins are involved in signal transduction or stress response systems. Most of the Cys residues in these proteins are conserved, suggesting that they share similar tertiary structures. Surface plasmon resonance (SPR) analysis shows that EDGP binds a soybean 4-kDa hormone-like peptide (4-kDa peptide) in vitro and reduction of EDGP decreased significantly the binding activity, implying that posttranslational modifications are important for its function. Therefore, we investigated the posttranslational modifications in EDGP using mass spectrometry. As the result, six disulfide bonds in EDGP were identified: Cys(70)-Cys(158), Cys(84)-Cys(89), Cys(97)-Cys(113), Cys(100)-Cys(108), Cys(201)-Cys(426), and Cys(332)-Cys(378). In addition, the N-terminal glutamine was cyclized into pyroglutamic acid. All four putative glycosylation sites were occupied by N-linked glycans, which have similar masses of m/z 1171. Finally, measuring the mass of the native protein showed that the posttranslational modifications of EDGP (pI 9.5) involved only disulfide bonds, N-terminal modification, and glycosylation.     

马槟榔甜蛋白基因（MBL11）的剪切重组和结构分析

马槟榔甜蛋白（mabinlin II）是我国所特有且唯一的植物甜蛋白,在体外至今没有得到具有甜味的基因表达产物。本文采用基因工程手段对基因进行剪切重组,将重组基因构建成植物表达载体转入拟南芥中,通过RT-．PCR检测导入基因的表达,同时采用生物信息学方法对MBL II基因及其重组基因进行分析和甜味检测显示,转基因拟南芥不具有明显的甜味,但RT-PCR的结果显示,MBL II基因及其重组基因可在转基因的拟南芥中表达。根据生物信息学方法分析结果推测,导入拟南芥中的重组马槟榔甜蛋白可能是具有甜味的蛋白。     

Generation of glycosylated remnant epitopes from human collagen type II by gelatinase B

Gelatinase B/matrix metalloproteinase-9 (MMP-9) is an inflammatory mediator and effector. Considerable amounts of gelatinase B are released by neutrophils in the synovial cavity of patients with rheumatoid arthritis, and gelatinase B-deficient mice are resistant against antibody-induced arthritis. Native human collagen type II is susceptible to cleavage by various collagenases (MMP-1, MMP-8, and MMP-13), which cleave at a single position in the triple helix. Although the triple-helical structure may persist after this single cleavage, we show that gelatinase B degrades the resulting fragments into small remnant peptides. These were identified by mass spectrometry and Edman degradation. Localization of 31 cleavage sites shows that the immunodominant epitopes remain intact after cleavage and may become available, processed as antigens and presented in MHC-II molecules. Furthermore, most post-translational modifications were identified on the fragments, including nine glycosylation sites. In particular, it is shown for the first time by structural analysis that in natural human collagen II, lysines in the main immunodominant epitope are modified by partial hydroxylation and partial glycosylation. Determination of T-cell reactivity against such fragments indicates that, besides the two known main immunodominant epitopes, other glyco-epitopes may be present in collagen II. This reinforces the role of glycopeptide antigens in autoimmunity.     

Proteomics reveals N-linked glycoprotein diversity in Caenorhabditis elegans and suggests an atypical translocation mechanism for integral membrane proteins

Protein glycosylation is one of the most common post-translational modifications in eukaryotes and affects various aspects of protein structure and function. To facilitate studies of protein glycosylation, we paired glycosylation site-specific stable isotope tagging of lectin affinity-captured N-linked glycopeptides with mass spectrometry and determined 1,465 N-glycosylated sites on 829 proteins expressed in Caenorhabditis elegans. The analysis shows the diversity of protein glycosylation in eukaryotes in terms of glycosylation sites and oligosaccharide structures attached to polypeptide chains and suggests the substrate specificity of oligosaccharyltransferase, a single multienzyme complex in C. elegans that incorporates an oligosaccharide moiety en bloc to newly synthesized polypeptides. In addition, topological analysis of 257 N-glycosylated proteins containing a putative single transmembrane segment that were identified based on the relative positions of glycosylation sites and transmembrane segments suggests that an atypical non-cotranslational mechanism translocates large N-terminal segments from the cytosol to the endoplasmic reticulum lumen in the absence of signal sequence function.     

Profiling impaired hepatic endoplasmic reticulum glycosylation as a consequence of ethanol ingestion

Alcoholic liver disease (ALD) is a prominent cause of morbidity and mortality in the United States. Alterations in protein folding occur in numerous disease states, including ALD. The endoplasmic reticulum (ER) is the primary site of post-translational modifications (PTM) within the cell. Glycosylation, the most abundant PTM, affects protein stability, structure, localization, and activity. Decreases in hepatic glycosylation machinery have been observed in rodent models of ALD, but specific protein targets have not been identified. Utilizing two-dimensional gel electrophoresis and liquid chromatography-tandem mass spectrometry, glycoproteins were identified in hepatic microsomal fractions from control and ethanol-fed mice. This study reports for the first time a global decrease in ER glycosylation. Additionally, the identification of 30 glycoproteins within this fraction elucidates pathway-specific alterations in ALD impaired glycosylation. Among the identified proteins, triacylglycerol hydrolase (TGH) is positively affected by glycosylation, showing increased activity following the addition of sugar moieties. Impaired TGH activity is associated with increased cellular storage of lipids and provides a potential mechanism for the observed pathologies associated with ALD.     

Over-expression and production of plant allergens by molecular farming strategies

Recombinant allergens have become a valuable tool for diagnosis and may also be used for therapy in the near future. To supply the required large amounts of functional recombinant proteins on a cost-effective basis, the production of allergens in plants by molecular farming is an alternative to microbial expression systems. Especially as post-translational modifications of the allergens, e.g., phosphorylation and glycosylation, may be important for recognition by the human immune system, the plant-based production of recombinant allergens enables the correct folding, glycosylation, and other modifications of the recombinant allergen. An introduction to the methods for plant transformation via the tumor-inducing bacterium, Agrobacterium tumefaciens, is given in this paper.     

The chaperone and potential mannan-binding lectin (MBL) co-receptor calreticulin interacts with MBL through the binding site for MBL-associated serine proteases

The chaperone calreticulin has been suggested to function as a C1q and collectin receptor. The interaction of calreticulin with mannan-binding lectin (MBL) was investigated by solid-phase binding assays. Calreticulin showed saturable and time-dependent binding to recombinant MBL, provided that MBL was immobilized on a solid surface or bound to mannan on a surface. The binding was non-covalent and biphasic with an initial salt-sensitive phase followed by a more stable salt-insensitive interaction. For plasma-derived MBL, known to be complexed with MBL-associated serine proteases (MASPs), no binding was observed. Interaction of calreticulin with recombinant MBL was fully inhibited by recombinant MASP-2, MASP-3 and MAp19, but not by the MASP-2 D105G and MAp19 Y59A variants characterized by defective MBL binding ability. Furthermore, MBL point mutants with impaired MASP binding showed no interaction with calreticulin. Comparative analysis of MBL with complement component C1q, its counterpart of the classical pathway, revealed that they display similar binding characteristics for calreticulin, providing further indication that calreticulin is a common co-receptor/chaperone for both proteins. In conclusion, the potential MBL co-receptor calreticulin binds to MBL at the MASP binding site and the interaction may involve a conformational change in MBL.     

LC-MS for protein characterization: current capabilities and future trends

With advances in ionization methods and instrumentation, liquid chromatography (LC)/mass spectrometry (MS) has become a powerful technology for protein characterization. This review article will describe the general approaches on LC-MS analysis in protein characterization, including bottom-up and top-down strategies. Discussions will be given on characterization of recombinant proteins, and post-translational and protein modifications such as disulfide bonds, glycosylation and phosphorylation using LC-MS. New research directions in this area will also be presented to illustrate future prospects of LC-MS in protein characterization, including application to proteomics.     

LC-MS for protein characterization: current capabilities and future trends

With advances in ionization methods and instrumentation, liquid chromatography (LC)/mass spectrometry (MS) has become a powerful technology for protein characterization. This review article will describe the general approaches on LC-MS analysis in protein characterization, including bottom-up and top-down strategies. Discussions will be given on characterization of recombinant proteins, and post-translational and protein modifications such as disulfide bonds, glycosylation and phosphorylation using LC-MS. New research directions in this area will also be presented to illustrate future prospects of LC-MS in protein characterization, including application to proteomics.     

Structural characterization of human recombinant and bone-derived bone sialoprotein. Functional implications for cell attachment and hydroxyapatite binding.

Human bone sialoprotein (BSP) comprises 15% of the total noncollagenous proteins in bone and is thought to be involved in bone mineralization and remodeling. Recent data suggest a role for BSP in breast cancer and the development of bone metastases. We have produced full-length recombinant BSP in a human cell line and purified the protein from human bone retaining the native structure with proper folding and post-translational modifications. Mass spectrometry of bone-derived BSP revealed an average mass of 49 kDa and for recombinant BSP 57 kDa. The post-translational modifications contribute 30-40%. Carbohydrate analysis revealed 10 different complex-type N-glycans on both proteins and eight different O-glycans on recombinant BSP, four of those were found on bone-derived BSP. We could identify eight threonines modified by O-glycans, leaving the C terminus of the protein free of glycans. The recombinant protein showed similar secondary structures as bone-derived BSP. BSP was visualized in electron microscopy as a globule linked to a thread-like structure. The affinity for hydroxyapatite was higher for bone-derived BSP than for recombinant BSP. Cell adhesion assays showed that the binding of BSP to cells can be reversibly diminished by denaturation.     

Post-translational processing events in the secretion pathway of human protein C, a complex vitamin K-dependent antithrombotic factor.

Human protein C (HPC) undergoes several post-translational modifications, including gamma-carboxylation, N-linked glycosylation, and internal proteolytic processing. We have utilized a recombinant human kidney cell line (293) secreting correctly modified HPC (rHPC) to study the processing reactions for the modification of this complex protein. gamma-Carboxylation was shown to proceed via a vitamin K-dependent pathway and was required for both efficient secretion and anticoagulant activity. rHPC was rapidly secreted following the addition of vitamin K to depleted cells, and secretion was not inhibited by cyclohexamide indicating that non gamma-carboxylated rHPC accumulates as an intracellular releasable pool. However, in cells grown in the presence of vitamin K, the majority of intracellular rHPC was gamma-carboxylated, suggesting that this post-translational modification is not rate limiting for secretion under conditions optimal for vitamin K-dependent carboxylation. Nonglycosylated rHPC was found to be secreted inefficiently, and processing of the N-linked core in the endoplasmic reticulum, but not in the Golgi, was required for secretion. Further, the intracellular rHPC present in vitamin K-supplemented cells was core glycosylated, but not processed past the high mannose step. gamma-Carboxylation occurred after core glycosylation, indicating that this modification is not cotranslational. Further, glycosylation and gamma-carboxylation were not coupled and did not need to proceed sequentially. Proteolytic processing of the internal KR dipeptide was found to occur late in the secretion pathway, and the cleavage was calcium-dependent. The secretion rate of rHPC was also calcium-dependent but was independent of the calcium effect on internal KR dipeptide removal, indicating that cleavage is not required for efficient secretion. Our results define the sequence of processing events, the subcellular localization of the processing reactions, and the rate-limiting steps in the secretion pathway for this complex protein.     

Structural requirements for additional N-linked carbohydrate on recombinant human erythropoietin

N-Linked glycosylation is a post-translational event whereby carbohydrates are added to secreted proteins at the consensus sequence Asn-Xaa-Ser/Thr, where Xaa is any amino acid except proline. Some consensus sequences in secreted proteins are not glycosylated, indicating that consensus sequences are necessary but not sufficient for glycosylation. In order to understand the structural rules for N-linked glycosylation, we introduced N-linked consensus sequences by site-directed mutagenesis into the polypeptide chain of the recombinant human erythropoietin molecule. Some regions of the polypeptide chain supported N-linked glycosylation more effectively than others. N-Linked glycosylation was inhibited by an adjacent proline suggesting that sequence context of a consensus sequence could affect glycosylation. One N-linked consensus sequence (Asn123-Thr125) introduced into a position close to the existing O-glycosylation site (Ser126) had an additional O-linked carbohydrate chain and not an additional N-linked carbohydrate chain suggesting that structural requirements in this region favored O-glycosylation over N-glycosylation. The presence of a consensus sequence on the protein surface of the folded molecule did not appear to be a prerequisite for oligosaccharide addition. However, it was noted that recombinant human erythropoietin analogs that were hyperglycosylated at sites that were normally buried had altered protein structures. This suggests that carbohydrate addition precedes polypeptide folding.     

Mass spectrometry of natural and recombinant proteins and glycoproteins

Most modern protein sequence analysis is carried out using classical, wet-chemical Edman degradation technology. However, an increasing number of studies on both natural and recombinant genetically engineered proteins demands the use of new technologies capable of assigning structural features such as glycosylation, which cannot be assigned by Edman sequence analysis. The most important alternative and complementary procedure at present is the use of high-mass mass spectrometry. This brief article introduces some of the principles and applications of the technique. Protein research laboratories, both academic and industrial will make increasing use of these techniques to complement classical gas phase sequencing, and to identify post-translational modifications including glycosylation, phosphorylation, SS bridge assignment and processing events, including the formation of ‘ragged ends’.     

Post-translational modifications of human thrombin-activatable fibrinolysis inhibitor (TAFI): evidence for a large shift in the isoelectric point and reduced solubility upon activation

Thrombin-activable fibrinolysis inhibitor (TAFI) is distinct from pancreatic procarboxypeptidase B in several ways. The enzymatic activity of TAFIa is unstable and decays with a half-life of a few minutes. During this study, we observed that (i) the isoelectric point (pI) of TAFI shifts dramatically from pH 5 toward pH 8 upon activation and (ii) TAFIa is significantly less soluble than TAFI. The structural bases for these observations were investigated by characterizing all post-translational modifications, including attached glycans and disulfide connectivity. The analyses revealed that all five potential N-glycosylation sites were utilized including Asn22, Asn51, Asn63, Asn86 (located in the activation peptide), and Asn219 (located in the catalytic domain). Asn219 was also found in an unglycosylated variant. Four of the glycans, Asn51, Asn63, Asn86, and Asn219 displayed microheterogeneity, while the glycan attached to Asn22 appeared to be homogeneous. In addition, bisecting GlcNAc attached to the trimannose core was detected, suggesting an origin other than the liver. Monosaccharide composition and LC-MS/MS analyses did not produce evidence for O glycosylation. TAFI contains eight cysteine residues, of which two, Cys69 and Cys383, are not involved in disulfides and contain free sulfhydryl groups. The remaining six cystines form disulfides, including Cys156-Cys169, Cys228-Cys252, and Cys243-Cys257. This pattern is homologous to pancreatic procarboxypeptidase B, and it is therefore unlikely that permutations in the cysteine connectivity are responsible for the enzymatic instability. LC-MS/MS analyses covering more than 90% of the TAFI amino acid sequence revealed no additional modifications. When these results are taken together, they suggest that the inherent instability of TAFIa is not caused by post-translational modifications. However, after activation, TAFIa loses 80% of the attached glycans, generating a large shift in pI and a propensity to precipitate. These changes are likely to significantly affect the properties of TAFIa as compared to TAFI.     

Odorant and pheromone binding by aphrodisin, a hamster aphrodisiac protein

Aphrodisin is a soluble glycoprotein of hamster vaginal discharges, which stimulates male copulatory behavior. Natural aphrodisin was purified and its post-translational modifications characterized by MALDI-MS peptide mapping. To evaluate its ability to bind small volatile ligands, the aphrodisiac protein was expressed in the yeast Pichia pastoris as two major isoforms differing in their glycosylation degree, but close in conformation to the natural protein. Dimeric recombinant aphrodisins were equally able to efficiently bind odors (2-isobutyl-3-methoxypyrazine and methyl thiobutyrate) and a pheromone (dimethyl disulfide), suggesting that they could act as pheromone carriers instead of, or in addition to, direct vomeronasal neuron receptor activators.     

ThiS可能作为一个原核翻译后修饰分子通过二硫键结合细胞蛋白

泛素及其相关蛋白是真核细胞中广泛存在的结构高度保守的一类小分子蛋白,参与蛋白翻译后修饰. 尽管在少数原核种属含有Pupylation这样的翻译后修饰,在原核细胞中尚未发现通用的泛素样修饰系统. ThiS是原核细胞广泛存在的泛素样小蛋白分子,它作为硫转运蛋白参与辅助因子的合成. 当与靶蛋白融合重组表达时,ThiS可降低靶蛋白在大肠杆菌中的稳定性. 本研究旨在探讨ThiS是否可能在原核细胞中参与翻译后修饰. ThiS在大肠杆菌中重组表达时,它可与细胞蛋白游离巯基发生共价结合,但与真核细胞泛素修饰不同,ThiS是通过12位半胱氨酸的游离巯基与蛋白形成二硫键,而不是通过C端活化的硫代羧基的转化过程发生共价结合. 在细胞内,氧化应激可诱导ThiS与蛋白的共价结合. 结果提示,ThiS在大肠杆菌中与细胞蛋白的结合,可能与真核细胞泛素化修饰在功能上存在进化联系;原核细胞中这种ThiS的结合形式可能代表一种古老的原核泛素样修饰方式.     

Thiazolyl Peptide Antibiotic Biosynthesis: A Cascade of Post-translational Modifications on Ribosomal Nascent Proteins

Antibiotics of the thiocillin, GE2270A, and thiostrepton class, which block steps in bacterial protein synthesis, contain a trithiazolyl (tetrahydro)pyridine core that provides the architectural constraints for high affinity binding to either the 50 S ribosomal subunit or elongation factor Tu. These mature antibiotic scaffolds arise from a cascade of post-translational modifications on 50–60-residue prepeptide precursors that trim away the N-terminal leader sequences (∼40 residues) while the C-terminal 14–18 residues are converted into the mature scaffold. In the producing microbes, the genes encoding the prepeptide open reading frames are flanked in biosynthetic clusters by genes encoding post-translational modification enzymes that carry out lantibiotic-type dehydrations of Ser and Thr residues to dehydroamino acid side chains, cyclodehydration and oxidation of cysteines to thiazoles, and condensation of two dehydroalanine residues en route to the (tetrahydro)pyridine core. The trithiazolyl pyridine framework thus arises from post-translational modification of the peptide backbone of three Cys and two Ser residues of the prepeptide.     

Two-dimensional electrophoresis of recombinant human erythropoietin: a future method for the European Pharmacopoeia?

Quality assurance of recombinant protein drugs concerning identity and purity represents a difficult task, in particular, when post-translational modifications lead to a heterogeneous mixture of biomolecules. We chose Neorecormon (rh-EPO, Roche) for our studies to demonstrate the efficiency of two-dimensional electrophoresis (2-DE) to analyse post-translationally modified recombinant drugs. More than 40 protein spots in the range from isoelectric point (pI) 3.5-4.5 and 32-45 kDa could be separated. Enzymatic deglycosylation revealed that the heterogeneity of the protein pattern is mainly caused by variations in glycosylation. In comparison to the separately performed isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, as requested by the European Pharmacopoeia, we see a great synergy to use 2-DE for the analysis of rh-EPO. A by far higher resolution can be achieved, allowing an improved differentiation of the various rh-EPO glycoforms. Sequential deglycosylation of sialic acids, N-glycosides and the O-glycoside lead to significant shifts both in apparent relative molecular mass and pI. Comparing the 2-DE patterns of rh-EPO before and after deglycosylation allows on the one hand valuable information to be gained on the glycosylation of the recombinant protein and shows on the other hand how significantly the 2-DE protein pattern can be influenced by the glycosylation. As the equipment for the performance of 2-DE has improved significantly over the last decade, we see 2-DE as a reliable method, which should be approved for the routine quality assurance of recombinant drugs and also recommended for the European Pharmacopoeia.