Yoshitaka Ikeda

Advances in our understanding of peroxiredoxin, a multifunctional, mammalian redox protein

Abstract Organisms living under aerobic conditions have developed various anti-oxidative mechanisms to protect them from damage by reactive oxygen species (ROS). A novel family of anti-oxidative proteins, designated as peroxiredoxin (Prx), has been identified in the past two decades and currently comprises six members in mammals. They share a common reactive Cys residue in the N-terminal region, and are capable of serving as a peroxidase and involve thioredoxin and/or glutathione as the electron donor. Prx1 to Prx4 have an additional Cys residue in the conserved C-terminal region, and are cross members as judged by the amino acid sequence similarity. Prx5 also contains an additional Cys in its C-terminal region which is less conserved. On the other hand, Prx6 has only one unique Cys. These Prx family members are distributed in the cytosol, mitochondria, peroxisome and plasma, all of which are potential sites of ROS production. In addition to their role as a peroxidase, however, a body of evidence has accumulated to suggest that individual members also serve divergent functions which are associated with various biological processes such as the detoxification of oxidants, cell proliferation, differentiation and gene expression. It would be expected that these functions might not necessarily depend on peroxidase activity and, therefore, it seems likely that the divergence is due to unique molecular characteristics intrinsic to each member. A comparative study of the divergence would lead to a better understanding of the biological significance of the Prx family.

The α1-6-fucosyltransferase gene and its biological significance

Abstract GDP- L -Fuc: N -acetyl-β- D -glucosaminide α1-6-fucosyltransferase (α1-6FucT) catalyzes the transfer of fucose from GDP-Fuc to N -linked type complex glycoproteins. This enzyme was purified from a human fibroblast cell line, porcine brain, a human gastric cancer cell line and human blood platelets. cDNA cloning of porcine and human α1-6FucT was performed from a porcine brain and gastric cancer cell cDNA libraries, respectively. Their homology is 92.2% at the nucleotide level and 95.7% at the amino acid level. No putative N -glycosylation sites were found in the predicted amino acid sequence. No homology to other fucosyltransferases such as α1-2FucT, α1-3FucT and α1-4FucT was found except for a region consisting of nine amino acids. The α1-6FucT gene is located at chromosome 14q24.3, which is also a different location from other fucosyltransferases reported to date. The α1-6FucT gene is the oldest gene family in the phylogenic trees among the nine cloned fucosyltransferase genes. α1-6FucT is widely expressed in various rat tissues and the expression of α1-6FucT in the liver is enhanced during hepatocarcinogenesis of LEC rats which develop hereditary hepatitis and hepatomas. In cases of human liver diseases, α1-6FucT is expressed in both hepatoma tissues and their surrounding tissues with chronic liver disease, but not in the case of normal liver. Serum α1-6-fucosylated α-fetoprotein (AFP) has been employed for an early diagnosis of patients with hepatoma. The mechanisms by which α1-6 fucosylation of AFP occurs in the hepatoma is not due to the up-regulation of α1-6FucT alone. Interestingly, when the α1-6FucT gene is transfected into Hep3B, a human hepatoma cell line, tumor formation in the liver of nude mice after splenic injection is dramatically suppressed. In this review, we focus on α1-6FucT and summarize its properties, gene expression and biological significance.

Peroxiredoxin 4 knockout results in elevated spermatogenic cell death via oxidative stress

Prx (peroxiredoxin) is a multifunctional redox protein with thioredoxin-dependent peroxidase activity. Prx4 is present as a secretory protein in most tissues, whereas in sexually mature testes it is anchored in the ER (endoplasmic reticulum) membrane of spermatogenic cells via an uncleaved N-terminal hydrophobic peptide. We generated a Prx4 knockout mouse to investigate the function of Prx4 in vivo. Prx4(-/y) mice lacking Prx4 expression in all cells were obtained by mating Prx4(flox/+) female mice with Cre-transgenic male mice that ubiquitously expressed Cre recombinase. The resulting Prx4(-/y) male mice were fertile, and most organs were nearly normal in size, except for testicular atrophy. The number of deoxynucleotidyl transferase-mediated dUTP nick end labelling-positive spermatogenic cells was higher in Prx4(-/y) mice than in Prx4(+/y) mice and increased remarkably in response to warming the lower abdomen at 43 degrees C for 15 min. Cells reactive to antibodies against 4-hydroxynonenal and 8-hydroxyguanine were high in the Prx4(-/y) mice and concomitant with elevated oxidation of lipid and protein thiols. The cauda epididymis of Prx4(-/y) mice contained round spermatocytes, which were not found in Prx4(+/y) mice, and displayed oligozoospermia. However, mature spermatozoa from the epididymis of Prx4(-/y) mice exhibited normal fertilization In vitro. Taken together, these results indicate that spermatogenic cells lacking Prx4 are more susceptible to cell death via oxidative damage than their wild-type counterparts. Our results suggest that the presence of Prx4, most likely the membrane-bound form, is important for spermatogenesis, but not an absolute requisite.

Implication of N-acetylglucosaminyltransferases III and V in cancer: gene regulation and signaling mechanism

N-acetylglucosaminyltransferases III (GnT-III) and V (GnT-V) play a pivotal role in the processing of N-linked glycoproteins, and are highly involved in cancer progression and metastasis. Expression of GnT-III and GnT-V in the liver is enhanced during hepatocarcinogenesis, although they are not expressed in the normal liver. Gene expression of GnT-V is regulated by a transcriptional factor, ets-1, which is involved in angiogenesis and invasion of tumor cells. When the formation of the product of GnT-V, GlcNAc-beta1-6 branches, is inhibited by overexpression of GnT-III, lung metastasis of melanoma cells is suppressed. Modification of glycoprotein receptors such as the receptors for epidermal growth factor and nerve growth factor by GnT-III sense transfection changes an intracellular signaling pathway, which may lead to a variety of biological alterations in tumor cells. In this review, we focus on cancer progression and metastasis in relation to GnT-III and GnT-V.

A glycomic approach to the identification and characterization of glycoprotein function in cells transfected with glycosyltransferase genes

The transfection of glycoprotein glycosyltransferase genes into cells leads to modification of both the structure and function of the glycoproteins and as a result, changes in glycome patterns. N‐glycan branching enzymes hold some promise as a model system for the identification of glycome patterns. Both N‐acetylglucosaminyltransferase III and α1–6 fucosyltransferase are typical glycosyltransferases, which are involved in the branching of N‐glycans. The resulting enzymatic products, bisecting N‐GlcNAc and α1–6 fucose residues, are no longer modified by other glycosyltransferases and it is a relatively simple task to identify their modification by means of lectins. In this review, the glycome patterns of glycosyltransferase gene transfectants and the nontransfectants were compared by two‐dimensional gel electrophoresis and lectin staining, and the biological significance of the two genes are described. Analyses of glycome patterns by transfecting glycosyltransferase genes will lead to new fields of study in the area of postgenome research.

Regulation of the GnT-V promoter by transcription factor Ets-1 in various cancer cell lines.

Although the precise role of oligosaccharides in metastasis is presently unknown, numerous studies suggest that the β1–6 branching structure of N-linked oligosaccharides plays a role in tumor metastasis.N-Acetylglucosaminyltransferase V (GnT-V), which catalyzes the formation of the β1–6 branch, therefore appears to play a crucial role in tumor metastasis. Recently, we demonstrated that the expression of the GnT-V gene is regulated by a transcriptional factor, Ets-1 (Kang, R., Saito, H., Ihara, Y., Miyoshi, E., Koyama, N., Sheng, Y., and Taniguchi, N. (1996) J. Biol. Chem. 271, 26706–26712). In this study, we report an investigation of the general requirement for Ets-1 in the expression of GnT-V in cancer cell lines. In 16 cancer cell lines, the levels of GnT-V mRNA were closely correlated with ets-1 expression (r = 0.97; p < 0.0001). An increase in ets-1 levels by transfection of its cDNA led to an enhancement in GnT-V expression in cells that normally expressed low levels of ets-1. In contrast, the transfection of dominant negative ets-1 into cells that express high levels of ets-1 resulted in a decrease in GnT-V expression. Although Ets-1 cooperates with c-Jun in certain gene expressions, this was not the case in the regulation of theGnT-V gene. These results suggest that Ets-1 plays a significant role in regulating the expression of GnT-V in a variety of cancers and might be involved in the potential for malignancy via the action of GnT-V.

Accelerated impairment of spermatogenic cells in sod1-knockout mice under heat stress

For normal spermatogenesis, the temperature of the scrotum is lower than that of the body. The mechanism by which mammalian testes undergoes cell death as the result of exposure to heat continues to be a matter of debate. Since generation of reactive oxygen species (ROS) during heat stress and involvement in spermatogenic cell damage are postulated, we induced experimental cryptorchidism in the testes of SOD1-knockout mice and examined effects of the gene deficiency. The cleavage of DNA in testicular cells, as judged by TUNEL staining, were elevated in SOD1-knockout mice at an earlier stage than in the wild-type mice. To confirm responsiveness of SOD1 for this high susceptibility to heat stress, spermatogenic cells were isolated from SOD1-knockout and wild-type mice and cultured at 32.5 and 37°C. The cells isolated from SOD1-knockout were more vulnerable at both temperatures than those from wild-type mice. The exposure of cultured rat spermatogenic cells to ROS induced the release of cytochrome c from mitochondria, while Sertoli cells were more resistant under the same conditions. Tiron, a superoxide scavenger, suppressed the heat-induced release of cytochrome c from mitochondria. Collectively, these data suggest that ROS are generated during heat stress and cause spermatogenic cell death. Alternatively, since even a short exposure triggers harmful damage to spermatogenic cells, generated ROS may function as a type of signal for cell death rather than directly causing oxidative damage to cells.

The Asn-420-linked sugar chain in human epidermal growth factor receptor suppresses ligand-independent spontaneous oligomerization. Possible role of a specific sugar chain in controllable receptor activation.

To elucidate a role(s) of Asn-linked sugar chain(s) in the function of epidermal growth factor receptor (EGFR), a series of the EGFR mutants were prepared in which potential glycosylation sites in the domain III were eliminated by site-directed mutagenesis. Although the wild-type and mutants of Asn-328, Asn-337, and Asn-389 underwent autophosphorylation in response to epidermal growth factor (EGF), the Asn-420 → Gln mutant was found to be constitutively tyrosine-phosphorylated. This abnormal ligand-independent phosphorylation of the mutant appears to be due to a ligand-independent spontaneous oligomer formation, as shown by a cross-linking experiment using the purified soluble extracellular domain (sEGFR). As revealed by the dissociation of the Asn-420 → Gln sEGFR oligomer by simple dilution, it seems likely that the equilibrium is shifted toward oligomer formation to an unusual degree. Furthermore, it was also found that the mutation caused a loss of the ability to bind EGF. These findings suggest that the sugar chain linked to Asn-420 plays a crucial role in EGF binding and prevents spontaneous oligomerization of the EGFR, which may otherwise lead to uncontrollable receptor activation, and support the view of a specific role of an Asn-linked sugar chain in the function of a glycoprotein.

Core fucosylation of E-cadherin enhances cell-cell adhesion in human colon carcinoma WiDr cells

α1,6‐Fucosyltransferase (Fut8), an enzyme that catalyzes the introduction of α1,6 core fucose to the innermost N‐acetylglucosamine residue of the N‐glycan, has been implicated in the development, immune system, and tumorigenesis. We found that α1,6‐fucosyltransferase and E‐cadherin expression levels are significantly elevated in primary colorectal cancer samples. Interestingly, low molecular weight population of E‐cadherin appeared as well as normal sized E‐cadherin in cancer samples. To investigate the correlation between α1,6‐fucosyltransferase and E‐cadherin expression, we introduced α1,6‐fucosyltransferase in WiDr human colon carcinoma cells. It was revealed that the low molecular weight population of E‐cadherin was significantly increased in α1,6‐fucosyltransferase‐transfected WiDr cells in dense culture, which resulted in an enhancement in cell–cell adhesion. The transfection of mutated α1,6‐fucosyltransferase with no enzymatic activity had no effect on E‐cadherin expression, indicating that core fucosylation is involved in the phenomena. In α1,6‐fucosyltransferase knock down mouse pancreatic acinar cell carcinoma TGP49 cells, the expression of E‐cadherin and E‐cadherin dependent cell–cell adhesion was decreased. The introduction of α1,6‐fucosyltransferase into kidney epithelial cells from α1,6‐fucosyltransferase–/– mice restored the expression of E‐cadherin and E‐cadherin‐dependent cell–cell adhesion. Based on the results of lectin blotting, peptide N‐glycosidase F treatment, and pulse‐chase studies, it was demonstrated that the low molecular weight population of E‐cadherin contains peptide N‐glycosidase F insensitive sugar chains, and the turnover rate of E‐cadherin was reduced in α1,6‐Fucosyltransferase transfectants. Thus, it was suggested that core fucosylation regulates the processing of oligosaccharides and turnover of E‐cadherin. These results suggest a possible role of core fucosylation in the regulation of cell–cell adhesion in cancer. (Cancer Sci 2009; 100: 888–896)

Role of N-glycans in growth factor signaling

Secreted proteins and membrane proteins are frequently post-translationally modified by oligosaccharides. Therefore, many glycoproteins are involved in signal transduction. One example is growth factor receptors, which are membrane proteins that often contain oligosaccharides. The oligosaccharides in those growth factor receptors play crucial roles in receptor functions. An analysis of glycosyltransferase-transfectants revealed that the branching structures of oligosaccharide also serve as important determinants. For example, N-glycans of epidermal growth factor receptor (EGFR) are involved in receptor sorting, ligand binding and dimerization. The addition of a bisecting GlcNAc to N-glycans increases the endocytosis of EGFR. N-glycans of Trk, a high affinity nerve growth factor receptor, also affect its function. Thus, oligosaccharides play an important role in growth factor signaling. Published in 2004.