Glycoprotein-specific ubiquitin ligases recognize N-glycans in unfolded substrates

Misfolded or unassembled polypeptides in the endoplasmic reticulum (ER) are retro-translocated into the cytosol and degraded by the ubiquitin-proteasome system. We reported previously that the SCF(Fbs1,2) ubiquitin-ligase complexes that contribute to ubiquitination of glycoproteins are involved in the ER-associated degradation pathway. Here we investigated how the SCF(Fbs1,2) complexes interact with unfolded glycoproteins. The SCF(Fbs1) complex was associated with p97/VCP AAA ATPase and bound to integrin-beta1, one of the SCF(Fbs1) substrates, in the cytosol in a manner dependent on p97 ATPase activity. Both Fbs1 and Fbs2 proteins interacted with denatured glycoproteins, which were modified with not only high-mannose but also complex-type oligosaccharides, more efficiently than native proteins. Given that Fbs proteins interact with innermost chitobiose in N-glycans, we propose that Fbs proteins distinguish native from unfolded glycoproteins by sensing the exposed chitobiose structure.     

Dual enzymatic properties of the cytoplasmic peptide: N-glycanase in C. elegans

The endoplasmic reticulum-associated degradation (ERAD) of misfolded (glyco)proteins ensures that only functional, correctly folded proteins exit from the ER and that misfolded ones are degraded by the ubiquitin-proteasome system. During the degradation of misfolded glycoproteins, some of them are subjected to deglycosylation by the cytoplasmic peptide:N-glycanase (PNGase). The cytosolic PNGase is widely distributed throughout eukaryotes. Here we show that the nematode Caenorhabditis elegans PNG-1, the cytoplasmic PNGase orthologue in this organism, exhibits dual enzyme functions, not only as PNGase but also as an oxidoreductase (thioredoxin). Using an in vitro assay as well as an in vivo assay system in budding yeast, the N-terminal thioredoxin domain and the central transglutaminase domain were found to be essential for oxidoreductase activity and PNGase activity, respectively. Occurrence of a C. elegans mutation affecting a catalytic residue in the PNGase domain strongly suggests the functional importance of this protein in higher eukaryotes.     

Misfolding of glycoproteins is a prerequisite for peptide: N-glycanase mediated deglycosylation

Peptide:N-glycanase (PNGase) is a deglycosylating enzyme that catalyzes the hydrolysis of the beta-aspartylglycosylamine bond of aspargine-linked glycopeptides and glycoproteins. Earlier studies from our laboratory indicated that PNGase catalyzed de-N-glycosylation was limited to glycopeptide substrates, but recent reports have demonstrated that it also acts upon full-length misfolded glycoproteins. In this study, we utilized two glycoprotein substrates, yeast carboxypeptidase and chicken egg albumin (ovalbumin), to study the deglycosylation activity of yeast PNGase and its mutants. Our results provide further evidence that PNGase acts upon full-length glycoprotein substrates and clearly establish that PNGase acts only on misfolded or denatured glycoproteins.     

A neural-specific F-box protein Fbs1 functions as a chaperone suppressing glycoprotein aggregation

Fbs1 is an F-box protein present abundantly in the nervous system. Similar to the ubiquitously expressed Fbs2, Fbs1 recognizes N-glycans at the innermost position as a signal for unfolded glycoproteins, probably in the endoplasmic reticulum-associated degradation pathway. Here, we show that the in vivo majority of Fbs1 is present as Fbs1-Skp1 heterodimers or Fbs1 monomers but not SCF(Fbs1) complex. The inefficient SCF complex formation of Fbs1 and the restricted presence of SCF(Fbs1) bound on the endoplasmic reticulum membrane were due to the short linker sequence between the F-box domain and the sugar-binding domain. In vitro, Fbs1 prevented the aggregation of the glycoprotein through the N-terminal unique sequence of Fbs1. Our results suggest that Fbs1 assists clearance of aberrant glycoproteins in neuronal cells by suppressing aggregates formation, independent of ubiquitin ligase activity, and thus functions as a unique chaperone for those proteins.     

The N-terminus of yeast peptide: N-glycanase interacts with the DNA repair protein Rad23

Yeast peptide: N-glycanase (PNGase) is involved in the proteasomal degradation of misfolded glycoproteins where it interacts with the DNA repair protein Rad23 as first detected in a yeast two-hybrid assay and subsequently confirmed by biochemical in vivo analyses. Limited proteolysis of PNGase with trypsin led to the removal of both an N-terminal and a C-terminal stretch. Based on these truncations the N-terminal region of yeast PNGase was identified as being responsible for binding to Rad23. Secondary structure predictions of this region suggest that it is composed of a single, solvent-exposed alpha-helix. The interaction between PNGase and Rad23 was studied using surface plasmon resonance revealing an equilibrium binding constant of approximately 2.5 microM. The oligomeric nature of Rad23 was also investigated using sedimentation equilibrium analysis. Although Rad23 exists as a dimer in solution, the monomeric form of Rad23 associates with a PNGase monomer in a 1:1 stoichiometric ratio.     

Molecular identification and characterization of peptide: N-glycanase from Schizosaccharomyces pombe

Peptide:N-glycanase (PNGase) is an enzyme responsible for deglycosylation of misfolded glycoproteins in so-called endoplasmic reticulum-associated degradation (ERAD) system. In this study, we reported the molecular identification and characterization of SpPNGase (Schizosaccharomyces pombe PNGase). Enzymatic analysis revealed that SpPNGase deglycosylated the misfolded glycoproteins and distinguished native and denatured high-mannose glycoproteins in vitro. The deglycosylation activity was lost with the addition of chelating agent EDTA and was not restored by re-addition of metal ions. By construction of deletion mutant, we confirmed that N-terminal α-helix of SpPNGase was responsible for the protein-protein interaction. Combining the results from ternary structure prediction and dendrogram analysis, we suggested that the N-terminal α-helices of PNGase are derived from evolutionary motif/peptide fusion.     

PNG1, a yeast gene encoding a highly conserved peptide:N-glycanase

It has been proposed that cytoplasmic peptide:N-glycanase (PNGase) may be involved in the proteasome-dependent quality control machinery used to degrade newly synthesized glycoproteins that do not correctly fold in the ER. However, a lack of information about the structure of the enzyme has limited our ability to obtain insight into its precise biological function. A PNGase-defective mutant (png1-1) was identified by screening a collection of mutagenized strains for the absence of PNGase activity in cell extracts. The PNG1 gene was mapped to the left arm of chromosome XVI by genetic approaches and its open reading frame was identified. PNG1 encodes a soluble protein that, when expressed in Escherichia coli, exhibited PNGase activity. PNG1 may be required for efficient proteasome-mediated degradation of a misfolded glycoprotein. Subcellular localization studies indicate that Png1p is present in the nucleus as well as the cytosol. Sequencing of expressed sequence tag clones revealed that Png1p is highly conserved in a wide variety of eukaryotes including mammals, suggesting that the enzyme has an important function.     

Discovery and characterization of a novel extremely acidic bacterial N-glycanase with combined advantages of PNGase F and A

Peptide-N4-(N-acetyl-β-glucosaminyl) asparagine amidases [PNGases (peptide N-glycosidases), N-glycanases, EC 3.5.1.52] are essential tools in the release of N-glycans from glycoproteins. We hereby report the discovery and characterization of a novel bacterial N-glycanase from Terriglobus roseus with an extremely low pH optimum of 2.6, and annotated it therefore as PNGase H⁺. The gene of PNGase H⁺ was cloned and the recombinant protein was successfully expressed in Escherichia coli. The recombinant PNGase H⁺ could liberate high mannose-, hybrid- and complex-type N-glycans including core α1,3-fucosylated oligosaccharides from both glycoproteins and glycopeptides. In addition, PNGase H⁺ exhibited better release efficiency over N-glycans without core α1,3-fucose compared with PNGase A. The facile expression, non-glycosylated nature, unusual pH optimum and broad substrate specificity of this novel type of N-glycanase makes recombinant PNGase H⁺ a versatile tool in N-glycan analysis.     

The retrotranslocation protein Derlin-1 binds peptide:N-glycanase to the endoplasmic reticulum

The deglycosylating enzyme, peptide:N-glycanase, acts on misfolded N-linked glycoproteins dislocated from the endoplasmic reticulum (ER) to the cytosol. Deglycosylation has been demonstrated to occur at the ER membrane and in the cytosol. However, the mechanism of PNGase association with the ER membrane was unclear, because PNGase lacked the necessary signal to facilitate its incorporation in the ER membrane, nor was it known to bind to an integral ER protein. Using HeLa cells, we have identified a membrane protein that associates with PNGase, thereby bringing it in close proximity to the ER and providing accessibility to dislocating glycoproteins. This protein, Derlin-1, has recently been shown to mediate retrotranslocation of misfolded glycoproteins. In this study we demonstrate that Derlin-1 interacts with the N-terminal domain of PNGase via its cytosolic C-terminus. Moreover, we find PNGase distributed in two populations; ER-associated and free in the cytosol, which suggests the deglycosylation process can proceed at either site depending on the glycoprotein substrate.     

多肽∶N-寡糖酶在小鼠人工隐睾中表达下调

真核多肽∶N-寡糖酶（peptide∶N-glycanase或PNGase）可切除错误折叠糖蛋白上的N-寡糖链,并可与内质网关联降解（endoplasmic reticulum-associated degradation, ERAD）途径中的多种关键成分相结合.然而,对于PNGase的生理功能及其与疾病的关系尚无明确报道.本研究利用重组技术表达和纯化了包含人PNGase N末端片段的融合蛋白,并经融合蛋白免疫与亲和层析纯化家兔抗血清,制备了PNGase的特异性抗体.利用该抗体和Western 印迹技术研究了PNGase在小鼠组织中的表达.结果显示PNGase在7种小鼠组织（脑、心、肺、肝、脾、肾、睾丸）中均有不同程度的表达,其中表达量最高者为睾丸;PNGase表达水平在不同品系小鼠（C57BL/6N、BALB/cAnN和昆明小鼠）间有显著差异.在小鼠单侧隐睾模型中首次观察到,与对照侧阴囊内的正常睾丸相比,隐睾内PNGase含量明显下降,提示PNGase在睾丸生精过程中可能有重要作用.     

A simple, sensitive in vitro assay for cytoplasmic deglycosylation by peptide: N-glycanase

A cytoplasmic peptide: N-glycanase (PNGase) has been implicated in the proteasomal degradation of aberrant glycoproteins synthesized in the endoplasmic reticulum. The reaction is believed to be important for subsequent proteolysis by the proteasome since bulky N-glycan chains on misfolded glycoproteins may impair their efficient entry into the interior of the cylinder-shaped 20S proteasome, where its active site resides. This cytoplasmic enzyme was first detected in 1993 by a simple, sensitive assay method using 14C-labeled glycopeptide as a substrate. The deglycosylation reaction by PNGase brings about two major changes on substrate the peptide; one is removal of the N-glycan chain and the other is the introduction of a negative charge into the core peptide by converting the glycosylated asparagine residue(s) into an aspartic acid residue(s). The assay method we developed monitors these major changes in the core peptide, and the respective changes were detected by distinct analytical methods: i.e., paper chromatography and paper electrophoresis. This chapter will describe the simple, sensitive in vitro assay method for PNGase.     

Cytoplasmic peptide:N-glycanase and catabolic pathway for free N-glycans in the cytosol

Peptide:N-glycanase (PNGase) releases N-glycans from glycoproteins/glycopeptides. Cytoplasmic PNGase is widely recognized as a component of machinery for ER-associated degradation (ERAD), i.e. proteasomal degradation of misfolded, newly synthesized (glyco)proteins that have been exported from the ER. The enzyme belongs to the “transglutaminase superfamily” that contains a putative catalytic triad of cysteine, histidine, and aspartic acid. The mammalian orthologues of PNGase contain the N-terminal PUB domain that serves as the protein–protein interaction domain. The C-terminus of PNGase was recently found to be a novel carbohydrate-binding domain. Taken together, these observations indicate that C-terminus of mammalian PNGase is important for recognition of the substrates while N-terminus of this enzyme is involved in assembly of a degradation complex.     

Nonreductive chemical release of intact N-glycans for subsequent labeling and analysis by mass spectrometry

A novel strategy is proposed, using cost-saving chemical reactions to generate intact free reducing N-glycans and their fluorescent derivatives from glycoproteins for subsequent analysis. N-Glycans without core α-1,3-linked fucose are released in reducing form by selective hydrolysis of the N-type carbohydrate–peptide bond of glycoproteins under a set of optimized mild alkaline conditions and are comparable to those released by commonly used peptide-N-glycosidase (PNGase) F in terms of yield without any detectable side reaction (peeling or deacetylation). The obtained reducing glycans can be routinely derivatized with 2-aminobenzoic acid (2-AA), 1-phenyl-3-methyl-5-pyrazolone (PMP), and potentially some other fluorescent reagents for comprehensive analysis. Alternatively, the core α-1,3-fucosylated N-glycans are released in mild alkaline medium and derivatized with PMP in situ, and their yields are comparable to those obtained using commonly used PNGase A without conspicuous peeling reaction or any detectable deacetylation. Using this new technique, the N-glycans of a series of purified glycoproteins and complex biological samples were successfully released and analyzed by electrospray ionization mass spectrometry (ESI–MS) and tandem mass spectrometry (MS/MS), demonstrating its general applicability to glycomic studies.     

Endo-β-N-acetylglucosamidases (ENGases) in the fungus Trichoderma atroviride: Possible involvement of the filamentous fungi-specific cytosolic ENGase in the ERAD process

N-Glycosylation is an important post-translational modification of proteins, which mainly occurs in the endoplasmic reticulum (ER). Glycoproteins that are unable to fold properly are exported to the cytosol for degradation by a cellular system called ER-associated degradation (ERAD). Once misfolded glycoproteins are exported to the cytosol, they are subjected to deglycosylation by peptide:N-glycanase (PNGase) to facilitate the efficient degradation of misfolded proteins by the proteasome. Interestingly, the ortholog of PNGase in some filamentous fungi was found to be an inactive deglycosylating enzyme. On the other hand, it has been shown that in filamentous fungi genomes, usually two different fungi-specific endo-β-N-acetylglucosamidases (ENGases) can be found; one is predicted to be localized in the cytosol and the other to have a signal sequence, while the functional importance of these enzymes remains to be clarified. In this study the ENGases of the filamentous fungus Trichoderma atroviride was characterized. By heterologous expression of the ENGases Eng18A and Eng18B in Saccharomyces cerevisiae, it was found that both ENGases are active deglycosylating enzymes. Interestingly, only Eng18B was able to enhance the efficient degradation of the RTL protein, a PNGase-dependent ERAD substrate, implying the involvement of this enzyme in the ERAD process. These results indicate that T. atroviride Eng18B may deglycosylate misfolded glycoproteins, substituting the function of the cytoplasmic PNGase in the ERAD process.     

A glycosylated type I membrane protein becomes cytosolic when peptide: N-glycanase is compromised

The human cytomegalovirus-encoded glycoprotein US2 catalyzes proteasomal degradation of Class I major histocompatibility complex (MHC) heavy chains (HCs) through dislocation of the latter from the endoplasmic reticulum (ER) to the cytosol. During this process, the Class I MHC HCs are deglycosylated by an N-glycanase-type activity. siRNA molecules designed to inhibit the expression of the light chain, beta(2)-microglobulin, block the dislocation of Class I MHC molecules, which implies that US2-dependent dislocation utilizes correctly folded Class I MHC molecules as a substrate. Here we demonstrate it is peptide: N-glycanase (PNGase or PNG1) that deglycosylates dislocated Class I MHC HCs. Reduction of PNGase activity by siRNA expression in US2-expressing cells inhibits deglycosylation of Class I MHC HC molecules. In PNGase siRNA-treated cells, glycosylated HCs appear in the cytosol, providing the first evidence for the presence of an intact N-linked type I membrane glycoprotein in the cytosol. N-glycanase activity is therefore not required for dislocation of glycosylated Class I MHC molecules from the ER.     

Lectin-like ERAD players in ER and cytosol

Protein quality control in the endoplasmic reticulum (ER) is an elaborate process conserved from yeast to mammals, ensuring that only newly synthesized proteins with correct conformations in the ER are sorted further into the secretory pathway. It is well known that high-mannose type N-glycans are involved in protein-folding events. In the quality control process, proteins that fail to achieve proper folding or proper assembly are degraded in a process known as ER-associated degradation (ERAD). The ERAD pathway comprises multiple steps including substrate recognition and targeting to the retro-translocation machinery, retrotranslocation from the ER into the cytosol, and proteasomal degradation through ubiquitination. Recent studies have documented the important roles of sugar-recognition (lectin-type) molecules for trimmed high-mannose type N-glycans and glycosidases in the ERAD pathways in both ER and cytosol. In this review, we discuss a fundamental system that monitors glycoprotein folding in the ER and the unique roles of the sugar-recognizing ubiquitin ligase and peptide:N-glycanase (PNGase) in the cytosolic ERAD pathway.     

The structural basis of the difference in sensitivity for PNGase F in the de-N-glycosylation of the native bovine pancreatic ribonucleases B and BS

In glycoanalysis protocols, N-glycans from glycoproteins are most frequently released with peptide- N (4)-( N-acetyl-beta-glucosaminyl)asparagine amidase F (PNGase F). As the enzyme is an amidase, it cleaves the NH-CO linkage between the Asn side chain and the Asn-bound GlcNAc residue. Usually, the enzyme has a low activity, or is not active at all, on native glycoproteins. A typical example is native bovine pancreatic ribonuclease B (RNase B) with oligomannose-type N-glycans at Asn-34. However, native RNase BS, generated by subtilisin digestion of native RNase B, which comprises amino acid residues 21-124 of RNase B, is sensitive to PNGase F digestion. The same holds for carboxymethylated RNase B (RNase B (cm)). In this study, NMR spectroscopy and molecular modeling have been used to explain the differences in PNGase F activity for native RNase B, native RNase BS, and RNase B (cm). NMR analysis combined with literature data clearly indicated that the N-glycan at Asn-34 is more mobile in RNase BS than in RNase B. MD simulations showed that the region around Asn-34 in RNase B is not very flexible, whereby the alpha-helix of the amino acid residues 1-20 has a stabilizing effect. In RNase BS, the alpha-helix formed by amino acid residues 23-32 is significantly more flexible. Using these data, the possibilities for complex formation of both RNase B and RNase BS with PNGase F were studied, and a model for the RNase BS-PNGase F complex is proposed.     

High pressure NMR reveals that apomyoglobin is an equilibrium mixture from the native to the unfolded

Pressure-induced reversible conformational changes of sperm whale apomyoglobin have been studied between 30 bar and 3000 bar on individual residue basis by utilizing 1H/15N hetero nuclear single-quantum coherence two-dimensional NMR spectroscopy at pH 6.0 and 35 degrees C. Apomyoglobin showed a series of pressure-dependent NMR spectra as a function of pressure, assignable to the native (N), intermediates (I), molten globule (MG) and unfolded (U) conformers. At 30 bar, the native fold (N) shows disorder only in the F helix. Between 500 bar and 1200 bar, a series of locally disordered conformers I are produced, in which local disorder occurs in the C helix, the CD loop, the G helix and part of the H helix. At 2000 bar, most cross-peaks exhibit severe line-broadening, suggesting the formation of a molten globule, but at 3000 bar all the cross-peaks reappear, showing that the molten globule turns into a well-hydrated, mobile unfolded conformation U. Since all the spectral changes were reversible with pressure, apomyoglobin is considered to exist as an equilibrium mixture of the N, I, MG and U conformers at all pressures. MG is situated at 2.4+/-(0.1) kcal/mol above N at 1 bar and the unfolding transition from the combined N-I state to MG is accompanied by a loss of partial molar volume by 75+/-(3) ml/mol. On the basis of these observations, we postulate a theorem that the partial molar volume of a protein decreases in parallel with the loss of its conformational order.     

Quantitative glycomics of human whole serum glycoproteins based on the standardized protocol for liberating N-glycans

Global glycomics of human whole serum glycoproteins appears to be an innovative and comprehensive approach to identify surrogate non-invasive biomarkers for various diseases. Despite the fact that quantitative glycomics is premised on highly efficient and reproducible oligosaccharide liberation from human serum glycoproteins, it should be noted that there is no validated protocol for which deglycosylation efficiency is proven to be quantitative. To establish a standard procedure to evaluate N-glycan release from whole human serum glycoproteins by peptide-N-glycosidase F (PNGase F) treatment, we determined the efficiencies of major N-glycan liberation from serum glycoproteins in the presence of reducing agents, surfactants, protease treatment, or combinations of pretreatments prior to PNGase F digestion. We show that de-N-glycosylation efficiency differed significantly depending on the condition used, indicative of the importance of a standardized protocol for the accumulation and comparison of glycomics data. Maximal de-N-glycosylation was achieved when serum was subjected to reductive alkylation in the presence of 2-hydroxyl-3-sulfopropyl dodecanoate, a surfactant used for solubilizing proteins, or related analogues, followed by tryptic digestion prior to PNGase F treatment. An optimized de-N-glycosylation protocol permitted relative and absolute quantitation of up to 34 major N-glycans present in serum glycoproteins of normal subjects for the first time. Moreover PNGase F-catalyzed de-N-glycosylation of whole serum glycoproteins was characterized kinetically, allowing accurate simulation of PNGase F-catalyzed de-N-glycosylation required for clinical glycomics using human serum samples. The results of the current study may provide a firm basis to identify new diagnostic markers based on serum glycomics analysis.