Inhibition of glycoprotein synthesis in the endoplasmic reticulum as a novel anticancer mechanism of (-)-epigallocatechin-3-gallate

(-)-Epigallocatechin-3-gallate (EGCG) has been found to trigger the unfolded protein response (UPR) likely due to the inhibition of glucosidase II, a key enzyme of glycoprotein processing and quality control in the endoplasmic reticulum (ER). These findings strongly suggest that EGCG interferes with glycoprotein maturation and sorting in the ER. This hypothesis was tested in SK-Mel28 human melanoma cells by assessing the effect of EGCG and deoxynojirimycin (DNJ) on the synthesis of two endogenous glycoproteins. Both tyrosinase and vascular endothelial growth factor (VEGF) protein levels were remarkably reduced despite unaltered mRNA expression in EGCG- or DNJ-treated cells compared to control. The hindrance of tyrosinase and VEGF protein synthesis could be prevented by proteasome inhibitor, lactacystine. Collectively, our results support that glucosidase II inhibitor EGCG interferes with protein processing and quality control in the ER, which diverts tyrosinase, VEGF, and likely other glycoproteins towards proteasomal degradation. This mechanism provides a novel therapeutic approach in dermatology and might play an important role in the antitumor effect or hepatotoxicity of EGCG.     

Trypanosoma cruzi calreticulin is a lectin that binds monoglucosylated oligosaccharides but not protein moieties of glycoproteins

Trypanosoma cruzi is a protozoan parasite that belongs to an early branch in evolution. Although it lacks several features of the pathway of protein N-glycosylation and oligosaccharide processing present in the endoplasmic reticulum of higher eukaryotes, it displays UDP-Glc:glycoprotein glucosyltransferase and glucosidase II activities. It is herewith reported that this protozoan also expresses a calreticulin-like molecule, the third component of the quality control of glycoprotein folding. No calnexin-encoding gene was detected. Recombinant T. cruzi calreticulin specifically recognized free monoglucosylated high-mannose-type oligosaccharides. Addition of anti-calreticulin serum to extracts obtained from cells pulse-chased with [35S]Met plus [35S]Cys immunoprecipitated two proteins that were identified as calreticulin and the lysosomal proteinase cruzipain (a major soluble glycoprotein). The latter but not the former protein disappeared from immunoprecipitates upon chasing cells. Contrary to what happens in mammalian cells, addition of the glucosidase II inhibitor 1-deoxynojirimycin promoted calreticulin-cruzipain interaction. This result is consistent with the known pathway of protein N-glycosylation and oligosaccharide processing occurring in T. cruzi. A treatment of the calreticulin-cruzipain complexes with endo-beta-N-acetylglucosaminidase H either before or after addition of anti-calreticulin serum completely disrupted calreticulin-cruzipain interaction. In addition, mature monoglucosylated but not unglucosylated cruzipain isolated from lysosomes was found to interact with recombinant calreticulin. It was concluded that the quality control of glycoprotein folding appeared early in evolution, and that T. cruzi calreticulin binds monoglucosylated oligosaccharides but not the protein moiety of cruzipain. Furthermore, evidence is presented indicating that glucosyltransferase glucosylated cruzipain at its last folding stages.     

Processing enzyme glucosidase II: proposed catalytic residues and developmental regulation during the ontogeny of the mouse mammary gland

Following the action of glucosidase I to clip the terminal alpha1,2-linked glucose, glucosidase II sequentially cleaves the two inner alpha1,3-linked glucose residues from the Glcalpha1,2Glcalpha1,3Glcalpha1,3Man(9)GlcNAc(2) oligosaccharide of the incipient glycoprotein as it undergoes folding and maturation. Glucosidase II belongs to family 31 glycosidases. These enzymes act by the acid-base catalytic mechanism. The cDNA of the wild-type and several mutant forms of the fusion protein of the enzyme in which mutations were introduced in the conserved motif D(564)MNE(567) were expressed in Sf9 cells, and the proteins were purified on Ni-NTA matrix. The catalytic activity of the purified proteins was determined with radioactive Glc(2)Man(9)GlcNAc(2) substrate. The results show that the aspartate and glutamate within the D(564)MNE(567) motif can serve for catalysis, most likely as the acid-base pair within the active site of the enzyme. The developmental regulation of glucosidase II was studied during the ontogeny of the mouse mammary gland for its growth and differentiation. The mRNA of both alpha and beta subunits of the enzyme, immunoreactive alpha and beta subunits, and enzyme activity were measured over the complete developmental cycle. The changes in all the parameters were consistent with similar fluctuations with several other enzymes of the N-glycosylation machinery reported earlier, reaching a three- to fourfold increase over the basal level in the virgin gland at the peak of lactation. Altogether it appears that there is a coordinated regulation of the enzymes involved in protein N-glycosylation during the development of the mouse mammary gland.     

N-linked oligosaccharide processing enzyme glucosidase II produces 1,5-anhydrofructose as a side product

alpha-1,4-Glucan lyase cleaves alpha-1,4-linkages of nonreducing termini of alpha-1,4-glucans to produce 1,5-anhydrofructose (1,5-AnFru). The enzymes isolated from fungi and algae show high homology with glycoside hydrolase family 31. Purification of alpha-1,4-glucan lyase from rat liver using DEAE Cellulose chromatography resulted in separation of two enzymatic active fractions, one was bound to the column and the other was in the flow-through. Partial amino acid sequence determined from the lyase, retained on the anion exchange column, were identical with that of the N:-linked oligosaccharide processing enzyme glucosidase II. The lyase showed similar enzymatic properties as the microsomal glucosidase such as inhibition by 1-deoxynojirimycin and castanospermine. On the other hand, glucosidase II purified from rat liver microsomes produced not only glucose but also a small amount of 1,5-AnFru using maltose as substrate. Furthermore, CHO cells overexpressing pig liver glucosidase II showed a 1.5- to 2-fold higher lyase activity compared to the nontransfected CHO cells. Conversely, no lyase activity was detectable either in PHAR2.7, the glucosidase II-deficient mutant from a mouse lymphoma cell line, or in Saccharomyces cerevisiae strain YG427 having the glucosidase II gene disrupted. These data demonstrate that glucosidase II possesses an additional enzymatic activity of releasing 1,5-AnFru from maltose.     

The cellulose-deficient Arabidopsis mutant rsw3 is defective in a gene encoding a putative glucosidase II,an enzyme processing N-glycans during ER quality control

rsw3 is a temperature-sensitive mutant of Arabidopsis thaliana showing radially swollen roots and a deficiency in cellulose. The rsw3 gene was identified by a map-based strategy, and shows high similarity to the catalytic alpha-subunits of glucosidase II from mouse, yeast and potato. These enzymes process N-linked glycans in the ER, so that they bind and then release chaperones as part of the quality control pathway, ensuring correct protein folding. Putative beta-subunits for the glucosidase II holoenzyme identified in the Arabidopsis and rice genomes share characteristic motifs (including an HDEL ER-retention signal) with beta-subunits in mammals and yeast. The genes encoding the putative alpha- and beta-subunits are single copy and, like the rsw3 phenotype, widely expressed. rsw3 reduces cell number more strongly than cell size in stamen filaments and probably stems. Most features of the rsw3 phenotype are shared with other cellulose-deficient mutants, but some--notably, production of multiple rosettes and a lack of secreted seed mucilage--are not and may reflect glucosidase II affecting processes other than cellulose synthesis. The rsw3 root phenotype develops more slowly than the rsw1 and rsw2 phenotypes when seedlings are transferred to the restrictive temperature. This is consistent with rsw3 reducing glycoprotein delivery from the ER to the plasma membrane whereas rsw1 and rsw2 act more rapidly by affecting the properties of already delivered enzymes.     

Identity of neutral alpha-glucosidase AB and the glycoprotein processing enzyme glucosidase II. Biochemical and genetic studies

We have previously partially purified, characterized, and chromosomally mapped a human isozyme of alpha-glucosidase which is active at neutral pH. This isozyme appears as a doublet of enzyme activity on native gel electrophoresis and was termed neutral alpha-glucosidase AB. We now report genetic and biochemical evidence that neutral alpha-glucosidase AB is synonymous with the glycoprotein processing enzyme glucosidase II. We have found that a mutant mouse lymphoma line which is deficient in glucosidase II is also deficient in neutral alpha-glucosidase AB, as defined electrophoretically and quantitatively (less than 0.5% of parental). In contrast, both mutant and parental cell lines exhibited several lysosomal hydrolases which are processed by glucosidase II. We have also further purified the human neutral alpha-glucosidase A component of neutral alpha-glucosidase AB 740-fold from placenta in order to compare its biochemical properties with those described for rat liver and pig kidney glucosidase II. Both glucosidase II and neutral alpha-glucosidase AB are high-molecular mass (greater than 200,000 dalton) anionic glycoproteins which bind to concanavalin A, have a broad pH optima (5.5-8.5), and have a similar Km for maltose (4.8 versus 2.1 mM) and the artificial substrate 4-methylumbelliferyl-alpha-D-glucopyranoside (35 versus 19 microM). Similar to human neutral alpha-glucosidase AB, purified rat glucosidase II migrates as a doublet of enzyme activity on native gel electrophoresis. Although rat glucosidase II has been reported to have a subunit size of 67 kDa, pig glucosidase II has been found to have a subunit size of 100 kDa, like the 98-kDa major protein in purified human neutral alpha-glucosidase A. Although we have not demonstrated that neutral alpha-glucosidase AB is microsomal nor that it hydrolyzes the natural substrate of glucosidase II, we believe that the genetic evidence is compelling for and the biochemical data consistent with the hypothesis that neutral alpha-glucosidase AB and glucosidase II are synonymous. These and previous results would localize glucosidase II to the long arm of human chromosome II.     

A novel approach for N-glycosylation studies using detergent extracted microsomes

Recently, it has become apparent that asparagine-linked (N-linked) oligosaccharide at an early stage of processing can play an important role in quality control of the secretory pathway. Here, we have developed a system for better understanding of the N-glycosylation machinery and its involvement in quality control in the endoplasmic reticulum (ER). Rough microsomes (RM) treated with 0.18% Tx-100 (TxRM) preserved translocation activities to a similar extent detected in RM. TxRM were depleted of many soluble proteins including glucosidase II, BiP and Erp72, but maintained approximately 80% of calnexin, a membrane protein. More importantly, TxRM revealed insufficient glycosylation of T cell receptor-α (TCR-α), suggesting that a factor or factors extracted with 0.18% Tx-100 is responsible for facilitating the transfer of oligosaccharides to the protein. In addition, the top band of TCR-α translated in TxRM migrated slower than that in RM, but faster than that in RM treated with castanospermine (CST), an inhibitor of glucosidase I/II. This suggests that the trimming of the inner two glucose sugars is impaired by the loss of glucosidase II. Furthermore, we demonstrated that TCR-α coprecipitated with calnexin migrated between unglucosylated and diglucosylated forms on SDS-PAGE. Thus, the treatment of RM with low concentration of detergent is a very powerful method for elucidating not only N-glycosylation processes but also other biological functions such as quality control in the ER. (Mol Cell Biochem 278: 157–163, 2005)     

Endoplasmic reticulum stress underlying the pro-apoptotic effect of epigallocatechin gallate in mouse hepatoma cells

It has been recently reported that tea flavanols, including epigallocatechin gallate (EGCG), efficiently inhibit glucosidase II in liver microsomes. Since glucosidase II plays a central role in glycoprotein processing and quality control in the endoplasmic reticulum we investigated the possible contribution of endoplasmic reticulum stress and unfolded protein response (UPR) to the pro-apoptotic activity of EGCG in mouse hepatoma cells. The enzyme activity measurements using 4-methylumbelliferyl-alpha-d-glucopyranoside substrate confirmed the inhibition of glucosidase II in intact and alamethicin-permeabilized cells. EGCG treatment caused a progressive elevation of apoptotic activity as assessed by annexin staining. The induction of CHOP/GADD153, the cleavage of procaspase-12 and the increasing phosphorylation of eIF2alpha were revealed in these cells by Western blot analysis while the induction of endoplasmic reticulum chaperones and foldases was not observed. Time- and concentration-dependent depletion of the endoplasmic reticulum calcium stores was also demonstrated in the EGCG-treated cells by single-cell fluorescent detection. The massive alterations in the endoplasmic reticulum morphology revealed by fluorescent microscopy further supported the development of UPR. Collectively, our results indicate that EGCG interferes with protein processing in the endoplasmic reticulum presumably due to inhibition of glucosidase II and that the stress induces an incomplete unfolded protein response with dominantly pro-apoptotic components.     

The role of glucosidase II and endomannosidase in glucose trimming of asparagine-linked oligosaccharides

This review covers various aspects of glucose trimming reactions occurring on asparagine-linked oligosaccharides. Structural and functional features of two enzymes, glucosidase II and endo-alpha-mannosidase, prominently involved in this process are summarized and their striking differences in terms of substrate specificities are highlighted. Recent results of analyses by immunoelectron microscopy of their distribution pattern are presented which demonstrate that glucose trimming is not restricted to the endoplasmic reticulum (ER) but additionally is a function accommodated by the Golgi apparatus. The mutually exclusive subcellular distribution of glucosidase II and endomannosidase are discussed in terms of their significance for quality control of protein folding and N-glycosylation.     

Golgi apparatus immunolocalization of endomannosidase suggests post-endoplasmic reticulum glucose trimming: implications for quality control

Trimming of N-linked oligosaccharides by endoplasmic reticulum (ER) glucosidase II is implicated in quality control of protein folding. An alternate glucosidase II-independent deglucosylation pathway exists, in which endo-alpha-mannosidase cleaves internally the glucose-substituted mannose residue of oligosaccharides. By immunogold labeling, we detected most endomannosidase in cis/medial Golgi cisternae (83.8% of immunogold labeling) and less in the intermediate compartment (15.1%), but none in the trans-Golgi apparatus and ER, including its transitional elements. This dual localization became more pronounced under 15 degrees C conditions indicative of two endomannosidase locations. Under experimental conditions when the intermediate compartment marker p58 was retained in peripheral sites, endomannosidase was redistributed to the Golgi apparatus. Double immunogold labeling established a mutually exclusive distribution of endomannosidase and glucosidase II, whereas calreticulin was observed in endomannosidase-reactive sites (17.3% in intermediate compartment, 5.7% in Golgi apparatus) in addition to the ER (77%). Our results demonstrate that glucose trimming of N-linked oligosaccharides is not limited to the ER and that protein deglucosylation by endomannosidase in the Golgi apparatus and intermediate compartment additionally ensures that processing to mature oligosaccharides can continue. Thus, endomannosidase localization suggests that a quality control of N-glycosylation exists in the Golgi apparatus.     

Two isoforms of trimming glucosidase II exist in mammalian tissues and cell lines but not in yeast and insect cells

We previously cloned glucosidase II and provided in vivo evidence for its involvement in protein folding quality control. DNA-sequencing of different clones demonstrated the existence of two isoforms of glucosidase II which differed by 66 nucleotides due to alternative splicing. The existence of two enzyme isoforms in various organs of pig and rat as well as human, bovine, rat, and mouse cell lines could be demonstrated by RT-PCR and Western blotting. Furthermore, the two isoforms of glucosidase II could be detected in embryonic and postnatal rat kidney and liver. In yeast, Saccharomyces cerevisiae, and in insects, Drosophila S2 cells, only one isoforms of the enzyme was detectable. The ubiquitous occurrence of the two glucosidase II isoforms in mammalian tissues and cell lines might be indicative of a special function of each isoform.     

A new stress protein: synthesis of Schizosaccharomyces pombe UDP--Glc:glycoprotein glucosyltransferase mRNA is induced by stress conditions but the enzyme is not essential for cell viability.

We have identified and begun the characterization of the gene encoding UDP-Glc:glycoprotein glucosyltransferase in Schizosaccharomyces pombe. This gene, here designated gpt1, codes for a polypeptide having a signal peptide of 18 amino acids followed by 1429 amino acids with no transmembrane domain, as expected for a soluble protein of the endoplasmic reticulum (ER). The C-terminal tetrapeptide PDEL most probably corresponds to a novel ER retention signal in this fission yeast. Synthesis of the corresponding mRNA was induced 2- to 9-fold by conditions known to affect glycoprotein folding in the ER (e.g. heat shock, culture in the presence of a Ca2+ionophore, 2-mercaptoethanol or inhibitors of protein N-glycosylation such as tunicamycin or 2-deoxyglucose). This is the first evidence obtained in vivo that supports the proposed involvement of the enzyme in the quality control of glycoprotein folding in the ER. Thus far, the said involvement was inferred solely from the ability of the enzyme to glucosylate misfolded but not native glycoproteins in cell-free assays. The gpt1 gene was disrupted and gpt1- cells were found to be viable. Moreover, no significant differences in the growth rate patterns at 18, 28 or 39 degrees C or in cell morphology between gpt1+ and gpt1- cells were observed, although they differed slightly in size.     

Immunolocalization of the oligosaccharide trimming enzyme glucosidase II

We used immunoelectron microscopy to localize glucosidase II in pig hepatocytes. The enzyme trims the two inner alpha 1,3-linked glucoses from N-linked oligosaccharide precursor chains of glycoproteins. Immunoreactive enzyme was concentrated in rough (RER) and smooth (SER) endoplasmic reticulum but not detectable in Golgi apparatus cisternae. Transitional elements of RER and smooth membraned structures close to Golgi apparatus cisternae contained labeling for glucosidase II. Specific labeling was also found in autophagosomes. These results indicate strongly that glucosidase II acts on glycoproteins before their transport to, and processing in Golgi apparatus cisternae, and suggest that an important transitional region for glucosidase II exists between RER and Golgi apparatus cisternae. Degradation in autophagolysosomes could form a normal catabolic pathway for glucosidase II.     

Retention of glucose units added by the UDP-GLC:glycoprotein glucosyltransferase delays exit of glycoproteins from the endoplasmic reticulum

It has been proposed that the UDP-Glc:glycoprotein glucosyltransferase, an endoplasmic reticulum enzyme that only glucosylates improperly folded glycoproteins forming protein-linked Glc1Man7-9-GlcNAc2 from the corresponding unglucosylated species, participates together with lectin- like chaperones that recognize monoglucosylated oligosaccharides in the control mechanism by which cells only allow passage of properly folded glycoproteins to the Golgi apparatus. Trypanosoma cruzi cells were used to test this model as in trypanosomatids addition of glucosidase inhibitors leads to the accumulation of only monoglucosylated oligosaccharides, their formation being catalyzed by the UDP- Glc:glycoprotein glucosyltransferase. In all other eukaryotic cells the inhibitors produce underglycosylation of proteins and/or accumulation of oliogosaccharides containing two or three glucose units. Cruzipain, a lysosomal proteinase having three potential N-glycosylation sites, two at the catalytic domain and one at the COOH-terminal domain, was isolated in a glucosylated form from cells grown in the presence of the glucosidase II inhibitor 1-deoxynojirimycin. The oligosaccharides present at the single glycosylation site of the COOH-terminal domain were glucosylated in some cruzipain molecules but not in others, this result being consistent with an asynchronous folding of glycoproteins in the endoplasmic reticulum. In spite of not affecting cell growth rate or the cellular general metabolism in short and long term incubations, 1-deoxynojirimycin caused a marked delay in the arrival of cruzipain to lysosomes. These results are compatible with the model proposed by which monoglucosylated glycoproteins may be transiently retained in the endoplasmic reticulum by lectin-like anchors recognizing monoglucosylated oligosaccharides.     

Genetic tailoring of N-linked oligosaccharides: the role of glucose residues in glycoprotein processing of Saccharomyces cerevisiae in vivo

In higher eukaryotes a quality control system monitoring the folding state of glycoproteins is located in the ER and is composed of the proteins calnexin, calreticulin, glucosidase II, and UDP-glucose: glycoprotein glucosyltransferase. It is believed that the innermost glucose residue of the N- linked oligosaccharide of a glycoprotein serves as a tag in this control system and therefore performs an important function in the protein folding pathway. To address this function, we constructed Saccharomyces cerevisiae strains which contain nonglucosylated (G0), monoglucosylated (G1), or diglucosylated (G2) glycoproteins in the ER and used these strains to study the role of glucose residues in the ER processing of glycoproteins. These alterations of the oligosaccharide structure did not result in a growth phenotype, but the induction of the unfolded protein response upon treatment with DTT was much higher in G0 and G2 strains as compared to wild-type and G1 strains. Our results provide in vivo evidence that the G1 oligosaccharide is an active oligosaccharide structure in the ER glycoprotein processing pathway of S.cerevisiae. Furthermore, by analyzing N- linked oligosaccharides of the constructed strains we can directly show that no general glycoprotein glucosyltransferase exists in S. cerevisiae.      

莱芜猪肝脏组织全长cDNA文库的构建和鉴定

目的:构建莱芜猪肝脏组织全长cDNA文库,以便研究与莱芜猪优良性状相关的基因。方法:采用改良的异硫氰酸酸胍一步法制备总RNA;利用SMART技术,以PrimeScript反转录酶逆转录合成第一链cDNA,通过LD-PCR扩增获得cDNA双链;经蛋白酶K消化和CHROMA SPIN-400柱分级分离后,收集500 bp以上的cDNA片段,并与pMD18-T载体连接,转化大肠杆菌DH5α感受态细胞,建成原始文库;随机挑取单菌落,用HindⅢ和EcoRⅠ进行双酶切鉴定重组子插入片段大小。结果:经鉴定,原始文库的滴度为2.8×105 cfu/mL,重组率约为98%,插入片段大小为0.5～2 kb,平均插入片段长度大于1 kb。结论:建立的cDNA文库质量良好,可以用于目的基因的筛选。     

Deletion of the glucosidase II gene in Trypanosoma brucei reveals novel N-glycosylation mechanisms in the biosynthesis of variant surface glycoprotein

The trypanosomatids are generally aberrant in their protein N-glycosylation pathways. However, protein N-glycosylation in the African trypanosome Trypanosoma brucei, etiological agent of human African sleeping sickness, is not well understood. Here, we describe the creation of a bloodstream-form T. brucei mutant that is deficient in the endoplasmic reticulum enzyme glucosidase II. Characterization of the variant surface glycoprotein, the main glycoprotein synthesized by the parasite with two N-glycosylation sites, revealed unexpected changes in the N-glycosylation of this molecule. Structural characterization by mass spectrometry, nuclear magnetic resonance spectroscopy, and chemical and enzymatic treatments revealed that one of the two glycosylation sites was occupied by conventional oligomannose structures, whereas the other accumulated unusual structures in the form of Glcalpha1-3Manalpha1-2Manalpha1-2Manalpha1-3(Manalpha1-6)Manbeta1-4GlcNAcbeta1-4GlcNAc, Glcalpha1-3Manalpha1-2Manalpha1-2Manalpha1-3(GlcNAcbeta1-2Manalpha1-6)Manbeta1-4GlcNAcbeta1-4GlcNAc, and Glcalpha1-3Manalpha1-2Manalpha1-2Manalpha1-3(Galbeta1-4GlcNAcbeta1-2Manalpha1-6)Manbeta1-4GlcNAcbeta1-4GlcNAc. The possibility that these structures might arise from Glc1Man9GlcNAc2 by unusually rapid alpha-mannosidase processing was ruled out using a mixture of alpha-mannosidase inhibitors. The results suggest that bloodstream-form T. brucei can transfer both Man9GlcNAc2 and Man5GlcNAc2 to the variant surface glycoprotein in a site-specific manner and that, unlike organisms that transfer exclusively Glc3Man9GlcNAc2, the T. brucei UDP-Glc: glycoprotein glucosyltransferase and glucosidase II enzymes can use Man5GlcNAc2 and Glc1Man5GlcNAc2, respectively, as their substrates. The ability to transfer Man5GlcNAc2 structures to N-glycosylation sites destined to become Man(4-3)GlcNAc2 or complex structures may have evolved as a mechanism to conserve dolichol-phosphate-mannose donors for glycosylphosphatidylinositol anchor biosynthesis and points to fundamental differences in the specificities of host and parasite glycosyltransferases that initiate the synthesis of complex N-glycans.