Molecular cloning and functional expression of Lewis type α1,3/α1,4-fucosyltransferase cDNAs from Mangifera indica L.

In higher plants, complex type N-glycans contain characteristic carbohydrate moieties that are not found in mammals. In particular, the attachment of the Lewis a (Lea) epitope is currently the only known outer chain elongation that is present in plant N-glycans. Such a modification is of great interest in terms of the biological function of complex type N-glycans in plant species. However, little is known regarding the exact molecular basis underlying their Lea expression. In the present study, we cloned two novel Lewis type fucosyltransferases (MiFUT13) from mango fruit, Mangifera indica L., heterologously expressed the proteins and structurally and functionally characterized them. Using an HPLC-based assay, we demonstrated that the recombinant MiFUT13 proteins mediate the α1,4-fucosylation of acceptor tetrasaccharides with a strict preference for type I-based structure to type II. The results and other findings suggest that MiFUT13s are involved in the biosynthesis of Lea containing glycoconjugates in mango fruits.

1α,25-Dihydroxyvitamin D3 enhances γ-glutamyl transpeptidase activity in LLC-PK1 porcine kidney epithelial cells.

Mammalian γ-glutamyl transpeptidase (GGT) is expressed most highly in the kidney and serves to recover the constituent amino acids of glutathione in the proximal tubules. Serum GGT is used as a marker for obstructive jaundice and alcoholic liver disease and it has been reported that urinary GGT is a potential marker for bone resorption. The present study investigated the effect of derivatives of vitamin D3 on GGT activity in LLC-PK1 porcine renal tubular epithelial cells in order to analyze the biochemical basis of bone metabolism-associated alterations in GGT activity in the kidney. In the presence of 1α,25-dihydroxyvitamin D3 [1,25(OH)2VD3], GGT activity was observed to be significantly increased in LLC-PK1 cells, with an increase in GGT activity also found in the cell medium. While the stimulatory effect of 1-OH-VD3 was similar to that of 1,25(OH)2VD3, vitamin D3 and 25-OH-VD3 had no effect on GGT activity. The increased GGT activity caused by 1,25(OH)2VD3 in LLC-PK1 cells was the result of long-term stimulation of the cells, in contrast to the GGT-induced increase in alkaline phosphatase, which is more transient. Polymerase chain reaction analysis revealed that the 1,25(OH)2VD3­induced increase in GGT activity was due to prolonged GGT turnover, rather than increased GGT expression, as no increase in GGT mRNA expression was observed. Thus, it is likely that the expression of GGT is not entirely constitutive in the kidney, but is altered under certain conditions, including under hormonal regulation.

MD-2-dependent human Toll-like receptor 4 monoclonal antibodies detect extracellular association of Toll-like receptor 4 with extrinsic soluble MD-2 on the cell surface.

MD-2 is essential for lipopolysaccharide (LPS) recognition of Toll-like receptor 4 (TLR4) but not for cell surface expression. The TLR4/MD-2 complex is formed intracellularly through co-expression. Extracellular complex formation remains a matter for debate because of the aggregative nature of secreted MD-2 in the absence of TLR4 co-expression. We demonstrated extracellular complex formation using three independent monoclonal antibodies (mAbs), all of which are specific for complexed TLR4 but unreactive with free TLR4 and MD-2. These mAbs bound to TLR4-expressing Ba/F3 cells only when co-cultured with MD-2-secreting Chinese hamster ovary cells or incubated with conditioned medium from these cells. All three mAbs bound the extracellularly formed complex indistinguishably from the intracellularly formed complex in titration studies. In addition, we demonstrated that two mAbs lost their affinity for TLR4/MD-2 on LPS stimulation, suggesting that these mAbs bound to conformation-sensitive epitopes. This was also found when the extracellularly formed complex was stimulated with LPS. Additionally, we showed that cell surface TLR4 and extrinsically secreted MD-2 are capable of forming the functional complex extracellularly, indicating an additional or alternative pathway for the complex formation.

Measurement of peroxiredoxin-4 serum levels in rat tissue and its use as a potential marker for hepatic disease.

Peroxiredoxin (Prx)-4, a secretable endoplasmic reticulum (ER)-resident isoform of the mammalian Prx family, functions as a thioredoxin-dependent peroxidase. It is acknowledged that Prx-4 plays a role in the detoxification of hydrogen peroxide, and potentially other peroxides, which may be generated during the oxidative folding of proteins and oxidative stress in the ER. The present study was undertaken in order to specifically quantify the tissue levels of Prx-4. To accomplish this, an enzyme-linked immunosorbent assay was developed using a specific polyclonal antibody produced by immunizing a rabbit with native recombinant rat Prx-4 protein. The assay was used to detect Prx-4 in the range of 0.1 and 10 ng/ml, and to investigate tissue distribution in rats. Using this immunoassay, we found that the serum levels of Prx-4 were substantially lower in asymptomatic Long-Evans Cinnamon rats, a rat model of Wilson's disease, compared to normal rats. In addition, the treatment of rat hepatoma cells with N-acetylcysteine led to a significant increase in the release of Prx-4 protein into the medium; thus, it appears likely that the secretion of Prx-4 is associated with the redox state within cells. These results suggest that serum Prx-4 has potential for use as a biomarker for hepatic oxidative stress.

Different consequences of reactions with hydrogen peroxide and t-butyl hydroperoxide in the hyperoxidative inactivation of rat peroxiredoxin-4.

Eukaryotic typical 2-Cys type peroxiredoxin (Prx) is inactivated by hyperoxidation of the peroxidatic cysteine to a sulphinic acid in a catalytic cycle-dependent manner. This inactivation process has been well documented for cytosolic isoforms of Prx. However, such a hyperoxidative inactivation has not fully been investigated in Prx-4, a secretable endoplasmic reticulum-resident isoform, in spite of being a typical 2-Cys type, and details of this process are reported herein. As has been observed in many peroxiredoxins, the peroxidase activity of Prx-4 was almost completely inhibited in the reaction with t-butyl hydroperoxide. On the other hand, when H(2)O(2) was used as the substrate, the peroxidase activity significantly remained after oxidative damage. In spite of these different consequences, mass spectrometric analyses indicated that both reactions resulted in the same oxidative damage, i.e. sulphinic acid formation at the peroxidatic cysteine, suggesting that another cysteine in the active site confers the peroxidase activity. As suggested by the analyses using cysteine-substituted mutants sulphinic acid formation at the peroxidatic cysteine may play a role in the development of the possible alternative mechanism, thereby sustaining the peroxidase activity that prefers H(2)O(2).

N-Glycosylation engineering of lepidopteran insect cells by the introduction of the beta1,4-N-acetylglucosaminyltransferase III gene.

The baculovirus-insect cell expression system is in widespread use for expressing post-translationally modified proteins. As a result, it is potentially applicable for the production of glycoproteins for therapeutic and diagnostic purposes. For practical use, however, remodeling of the biosynthetic pathway of host-cell N-glycosylation is required because insect cells produce paucimannosidic glycoforms, which are different from the typical mammalian glycoform, due to trimming of the non-reducing terminal beta1,2-GlcNAc residue of the core structure by a specific beta-N-acetylglucosaminidase. In order to establish a cell line which could be used as a host for the baculovirus-based production of glycoproteins with mammalian-type N-glycosylation, we prepared and characterized Spodoptera frugiperda Sf21 cells that had been transfected with the rat cDNA for beta1,4-N-acetylglucosaminyltransferase III (GnT-III), which catalyzes the addition of a bisecting GlcNAc. As evidenced by structural analyses of N-glycans prepared from whole cells and the expressed recombinant glycoproteins, the introduction of GnT-III led to the production of bisected hybrid-type N-glycans in which the beta1,2-GlcNAc residue at the alpha1,3-mannosyl branch is completely retained and which has the potential to be present in mammalian cells. These results and other related findings suggest that bisected oligosaccharides are highly resistant to beta-N-acetylglucosaminidase activity of the S. frugiperda fused lobes gene product, or other related enzymes, which was confirmed in Sf21 cells. Our present study demonstrates that GnT-III transfection has the potential to be an effective approach in humanizing the N-glycosylation of lepidopteran insect cells, thereby providing a possible preliminary step for the generation of complex-type glycoforms if the presence of a bisecting GlcNAc can be tolerated.

Fucosylation of chitooligosaccharides by human alpha1,6-fucosyltransferase requires a nonreducing terminal chitotriose unit as a minimal structure.

FUT8, a eukaryotic alpha1,6-fucosyltransferase, catalyzes the transfer of a fucosyl residue from guanine nucleotide diphosphate-beta-l-fucose to the innermost GlcNAc of an asparagine-linked oligosaccharide (N-glycan). The catalytic domain of FUT8 is structurally similar to that of NodZ, a bacterial alpha1,6-fucosyltransferase, which acts on a chitooligosaccharide in the synthesis of Nod factor. While the substrate specificities for the nucleotide sugar and the N-glycan have been determined, it is not known whether FUT8 is able to fucosylate other sugar chains such as chitooligosaccharides. The present study was conducted to investigate the action of FUT8 on chitooligosaccharides that are not generally thought to be a substrate in mammals, and the results indicate that FUT8 is able to fucosylate such structures in a manner comparable to NodZ. Surprisingly, structural analyses of the fucosylated products by high performance liquid chromatography, mass spectrometry and nuclear magnetic resonance indicated that FUT8 does not utilize the reducing terminal GlcNAc for fucose transfer but shows a preference for the third GlcNAc residue from the nonreducing terminus of the acceptor. These findings suggest that FUT8 catalyzes the fucosylation of chitooligosaccharide analogous to NodZ, but that a nonreducing terminal chitotriose structure is required for the reaction. The substrate recognition by which FUT8 selects the position to fucosylate might be distinct from that for NodZ and could be due to structural factor requirements which are inherent in FUT8.

Expression of N-terminally truncated forms of rat peroxiredoxin-4 in insect cells.

Peroxiredoxins (Prxs), a family of thioredoxin-dependent peroxidases, are highly conserved in many organisms and function in detoxifying reactive oxygen species as well as other cellular processes. Six members of the Prx family are known in mammals, i.e., Prx-1 through -6. Among these proteins, only Prx-4 appears to contain a signal peptide that serves for localization in the endoplasmic reticulum, membrane translocation and secretion into the extracellular space, as demonstrated in a previous study using a baculovirus-insect cell system. The present study was conducted to determine whether the signal peptide-truncated mutant of rat Prx-4 is expressed as an enzymatically active form and is produced in large amounts. Two N-terminally truncated mutants were prepared by deletion of only the signal peptide and the larger region encompassing both the signal and the unique extension to Prx-4. These mutants were successfully produced within Spodoptera frugiperda 21 cells by infection with the recombinant baculoviruses, rather than by extracellular secretion. Both mutants were efficiently purified to homogeneity by two column chromatography steps. Biochemical characterization of the purified proteins showed that the truncated enzymes are enzymatically active and form an oligomeric structure, as reported for the mammalian Prx family. The findings also suggest that the unique extension plays a role in the regulation of non-covalent oligomerization. More than 4 mg of the purified proteins can be obtained from cells grown in monolayer cultures in twenty 75 cm(2) tissue culture flasks. The procedures described in this study permit recombinant Prx-4 to be prepared more efficiently and easily for purposes of crystallization and antibody preparation.

Bidirectional N-acetylglucosamine transfer mediated by beta-1,4-N-acetylglucosaminyltransferase III.

beta-1,4-N-Acetylglucosaminyltransferase III (GnT-III) catalyzes the formation of the bisecting GlcNAc and plays a regulatory role in the biosynthesis of the N-linked oligosaccharide. In this study, we examined whether the glycosyl transfer catalyzed by GnT-III is reversible, and, in addition, investigated the equilibrium of the GnT-III-catalyzed reaction. Incubation of the agalactosyl-bisected biantennary oligosaccharide with GnT-III in the presence of the sufficiently high concentration of uridine diphosphate (UDP) resulted in conversion of the bisected oligosaccharide into the nonbisected one. This reaction was accompanied by the stoichiometric formation of UDP-GlcNAc, which appeared to result from the transfer of GlcNAc from the oligosaccharide to UDP. Thus, these results indicate that GnT-III is capable of perceivably catalyzing the reverse reaction in vitro, as found in some glycosyltransferases. When the equilibrium of the reaction was kinetically analyzed, it was found that the state of the equilibrium is greatly displaced toward the formation of the bisecting GlcNAc. In terms of free energy change, as estimated, the reaction by GnT-III can be comparable to the hydrolysis of ATP. Although GnT-III catalyzes bidirectional transfer of GlcNAc between the oligosaccharide and UDP, the removal of the bisecting GlcNAc is unlikely in vivo, due to the displacement of the equilibrium. It is known that equilibria of certain glycosyltransferase reactions are not biased as greatly as the case of GnT-III, and thus it seems likely that there are a variety of equilibrium states in glycosyltransferase reactions. In living cells, the assembly of oligosaccharides could be regulated by not only rate control but also equilibrium control.

Identification of Pex5pM, and retarded maturation of 3-ketoacyl-CoA thiolase and acyl-CoA oxidase in CHO cells expressing mutant Pex5p isoforms.

Recently, we isolated CHO cells, termed SK32 cells, that express mutant Pex5p (G432R), and showed mislocalization of catalase in the cytosol, but peroxisomal localization of 3-ketoacyl-CoA thiolase (thiolase) in the mutant cells [Ito, R. et al. (2001) Biochem. Biophys. Res. Commun. 288, 321-327]. While analyzing the mutant cells, we found a novel Pex5p isoform (Pex5pM), which was shorter by seven amino acids than Pex5pL and longer by 30 amino acids than Pex5pS. Similar levels of mRNA syntheses for the PEX5 gene were observed in both the wild type and mutant cells, but the protein levels of Pex5p isoforms were markedly reduced in the mutant cells cultured at 37 degrees C and only slightly discernible at 30 degrees C, suggesting that they could be rapidly degraded. Furthermore, we characterized the peroxisomal localization of thiolase and acyl-CoA oxidase (Aox) in SK32 cells. The proteins in the organelle fraction were protected from proteinase K-digestion in the mutant cells, indicating that they were translocated inside peroxisomes. However, the conversion of Aox from component A to components B and C was completely prevented at both 30 and 37 degrees C, and the precursor form of thiolase was partially processed to the mature one in a temperature-sensitive manner. Transformed SK32 cells stably expressing one of the wild type Pex5p isoforms were isolated, and then the maturation steps for thiolase and Aox were examined. Pex5pM and S restored the processing of the two enzymes, but Pex5pL did not. In addition, Pex5pL prevented the maturation of thiolase observed at 30 degrees C. These results indicate that (i) the novel Pex5pM is functional and (ii) a seven amino acids-insertion, which is present in the L isoform but absent in the M isoform, plays some role in the process of maturation of thiolase and Aox.

Altered antigenic disposition of peroxisomal urate oxidase in PEX5-defective Chinese hamster ovary cells.

Since Chinese hamster ovary (CHO) cells never express urate oxidase (UO), we tried to establish cell lines stably producing UO in order to elucidate the peroxisomal import process. The enzyme is a peroxisome targeting signal 1 (PTS1) protein harboring SKL motif at the carboxy-terminus [Biochem. Biophys. Res. Commun. 158 (1989) 991] and PEX5 protein (Pex5p) is supposed to be involved in the import process [Nat. Genet. 9 (1995) 115; J. Cell Biol. 130 (1995) 51]. We transfected a cDNA encoding rat UO into both wild type and PEX5-defective CHO cells to isolate each cell line stably producing the enzyme. While we examined the import process of UO in mutant cells, we noticed an interesting observation by using polyclonal antibody U1 or U2, which separately recognizes epitopes of UO. U1 antibody mainly interacts with epitopes in the amino-terminal region of UO. On the other hand, U2 antibody reacts with many epitopes distributed in the broad region of UO molecule. When UO produced in cultured cells was stained with U2 antibody, the enzyme was detected in peroxisomes of both wild type and PEX5-mutant cells. Whereas, U1 antibody stained the peroxisomal UO in wild type cells, but not in PEX5-mutant cells. These immunocytochemical observations suggest that the epitopes at the amino-terminal region of UO will be concealed in mutant cells. When the mutant cells were transfected with wild type PEX5 cDNA, U1 antibody came to react with UO in peroxisomes of mutant cells. The restoration indicates that the exposure of N-terminal epitopes of UO will depend upon the functional Pex5p. Immunoelectron microscopic observation showed that the peroxisomal import of UO was partially retarded in PEX5 mutant cells. The observation also supported the fact that UO was mainly localized in the peroxisomal matrix of wild type cells but in the membrane of mutant cells.

Different accumulations of 3-ketoacyl-CoA thiolase precursor in peroxisomes of Chinese hamster ovary cells harboring a dysfunction in the PEX2 protein.

The peroxisomal localization of 3-ketoacyl-CoA thiolase (hereafter referred to as thiolase) was characterized in five Chinese hamster ovary (CHO) mutant cell lines each harboring a dysfunction in the PEX2 protein. PT54 (Pex2pN100) cells carry a nonsense mutation that results in the PEX2 protein truncated at amino acid position 100. SK24 (Pex2pC258Y) cells carry a missense mutation resulting in the amino acid substitution of a cysteine residue by a tyrosine residue at amino acid position 258 of the PEX2 protein. The WSK24 (Pex2pC258Y/+wild) cell line is a stable transformant of SK24 (Pex2pC258Y) cells transfected with wild-type rat PEX2 cDNA. The SPT54 (Pex2pN100/+Pex2pC258Y) and WPT54 (Pex2pN100/+wild) cell lines are stable transformants of PT54 (Pex2pN100) cells transfected with the mutant PEX2 cDNA from SK24 (Pex2pC258Y) cells and wild-type rat PEX2 cDNA, respectively. In these cell lines, except PT54 (Pex2pN100), thiolase appeared to be localized in peroxisomes, as it is in the wild-type cells. When the molecular size of the enzyme was examined on SDS-polyacrylamide gel electrophoresis, the peroxisome-localized enzyme exhibited a larger precursor form in these mutant cells. The characterizations with salt wash, sodium carbonate extraction and proteinase K digestion indicated that the precursor forms of the enzyme were accumulated at different states in peroxisomes of these mutant cells. The dispositions on the peroxisomal membrane were further sustained by differential permeabilization using digitonin, followed by immunocytochemical fluorescence. These results suggest that PEX2 protein functions differently on two processes of the maturation and the disposition in the import pathway of thiolase.