Learning/Memory Impairment and Reduced Expression of the HNK-1 Carbohydrate in ��4-Galactosyltransferase-II-deficient Mice

The glycosylation of glycoproteins and glycolipids is important for central nervous system development and function. Although the roles of several carbohydrate epitopes in the central nervous system, including polysialic acid, the human natural killer-1 (HNK-1) carbohydrate, α2,3-sialic acid, and oligomannosides, have been investigated, those of the glycan backbone structures, such as Galβ1-4GlcNAc and Galβ1-3GlcNAc, are not fully examined. Here we report the generation of mice deficient in β4-galactosyltransferase-II (β4GalT-II). This galactosyltransferase transfers Gal from UDP-Gal to a nonreducing terminal GlcNAc to synthesize the Gal β1-4GlcNAc structure, and it is strongly expressed in the central nervous system. In behavioral tests, the β4GalT-II^-/- mice showed normal spontaneous activity in a novel environment, but impaired spatial learning/memory and motor coordination/learning. Immunohistochemistry showed that the amount of HNK-1 carbohydrate was markedly decreased in the brain of β4GalT-II^-/- mice, whereas the expression of polysialic acid was not affected. Furthermore, mice deficient in glucuronyltransferase (GlcAT-P), which is responsible for the biosynthesis of the HNK-1 carbohydrate, also showed impaired spatial learning/memory as described in our previous report, although their motor coordination/learning was normal as shown in this study. Histological examination showed abnormal alignment and reduced number of Purkinje cells in the cerebellum of β4GalT-II^-/- mice. These results suggest that the Galβ1-4GlcNAc structure in the HNK-1 carbohydrate is mainly synthesized by β4GalT-II and that the glycans synthesized by β4GalT-II have essential roles in higher brain functions, including some that are HNK-1-dependent and some that are not.The glycosylation of glycoproteins, proteoglycans, and glycolipids is important for their biological activities, stability, transport, and clearance from circulation, and cell-surface glycans participate in cell-cell and cell-extracellular matrix interactions. In the central nervous system, several specific carbohydrate epitopes, including polysialic acid (PSA),³ the human natural killer-1 (HNK-1) carbohydrate, α2,3-sialic acid, and oligomannosides play indispensable roles in neuronal generation, cell migration, axonal outgrowth, and synaptic plasticity (1). Functional analyses of the glycan backbone structures, like lactosamine core (Galβ1-4GlcNAc), neolactosamine core (Galβ1-3GlcNAc), and polylactosamine (Galβ1-4GlcNAcβ1-3) have been carried out using gene-deficient mice in β4-galactosyltransferase-I (β4GalT-I) (2, 3), β4GalT-V (4), β3-N-acetylglucosaminyl-transferase-II (β3GnT-II) (5), β3GnT-III (Core1-β3GnT) (6), β3GnT-V (7), and Core2GnT (8). However, the roles of these glycan backbone structures in the nervous system have not been examined except the olfactory sensory system (9).β4GalTs synthesize the Galβ1-4GlcNAc structure via the β4-galactosylation of glycoproteins and glycolipids; the β4GalTs transfer galactose (Gal) from UDP-Gal to a nonreducing terminal N-acetylglucosamine (GlcNAc) of N- and O-glycans with a β-1,4-linkage. The β4GalT family has seven members (β4GalT-I to VII), of which at least five have similar Galβ1-4GlcNAc-synthesizing activities (10, 11). Each β4GalT has a tissue-specific expression pattern and substrate specificity with overlapping, suggesting each β4GalT has its own biological role as well as redundant functions. β4GalT-I and β4GalT-II share the highest identity (52% at the amino acid level) among the β4GalTs (12), suggesting these two galactosyltransferases can compensate for each other. β4GalT-I is strongly and ubiquitously expressed in various non-neural tissues, whereas β4GalT-II is strongly expressed in neural tissues (13, 14). Indeed, the β4GalT activity in the brain of β4GalT-I-deficient (β4GalT-I^-/-) mice remains as high as 65% of that of wild-type mice, and the expression levels of PSA and the HNK-1 carbohydrate in the brain of these mice are normal (15). These results suggest β4GalTs other than β4GalT-I, like β4GalT-II, are important in the nervous system.Among the β4GalT family members, only β4GalT-I^-/- mice have been examined extensively; this was done by us and another group. We reported that glycans synthesized by β4GalT-I play various roles in epithelial cell growth and differentiation, inflammatory responses, skin wound healing, and IgA nephropathy development (2, 16-18). Another group reported that glycans synthesized by β4GalT-I are involved in anterior pituitary hormone function and in fertilization (3, 19). However, no other nervous system deficits have been reported in these mice, and the role of the β4-galactosylation of glycoproteins and glycolipids in the nervous system has not been fully examined.In this study, we generated β4GalT-II^-/- mice and examined them for behavioral abnormalities and biochemical and histological changes in the central nervous system. β4GalT-II^-/- mice were impaired in spatial learning/memory and motor coordination/learning. The amount of HNK-1 carbohydrate was markedly decreased in the β4GalT-II^-/- brain, but PSA expression was not affected. These results suggest that the Galβ1-4GlcNAc structure in the HNK-1 carbohydrate is mainly synthesized by β4GalT-II and that glycans synthesized by β4GalT-II have essential roles in higher brain functions, including ones that are HNK-1 carbohydrate-dependent and ones that are independent of HNK-1.     

Specific enzyme complex of beta-1,4-galactosyltransferase-II and glucuronyltransferase-P facilitates biosynthesis of N-linked human natural killer-1 (HNK-1) carbohydrate

Human natural killer-1 (HNK-1) carbohydrate is highly expressed in the nervous system and is involved in synaptic plasticity and dendritic spine maturation. This unique carbohydrate, consisting of a sulfated trisaccharide (HSO(3)-3GlcAβ1-3Galβ1-4GlcNAc-), is biosynthesized by the successive actions of β-1,4-galactosyltransferase (β4GalT), glucuronyltransferase (GlcAT-P and GlcAT-S), and sulfotransferase (HNK-1ST). A previous study showed that mice lacking β4GalT-II, one of seven β4GalTs, exhibited a dramatic loss of HNK-1 expression in the brain, although β4GalT-I-deficient mice did not. Here, we investigated the underlying molecular mechanism of the regulation of HNK-1 expression. First, focusing on a major HNK-1 carrier, neural cell adhesion molecule, we found that reduced expression of an N-linked HNK-1 carbohydrate caused by a deficiency of β4GalT-II is not likely due to a general loss of the β1,4-galactose residue as an acceptor for GlcAT-P. Instead, we demonstrated by co-immunoprecipitation and endoplasmic reticulum-retention analyses using Neuro2a (N2a) cells that β4GalT-II physically and specifically associates with GlcAT-P. In addition, we revealed by pulldown assay that Golgi luminal domains of β4GalT-II and GlcAT-P are sufficient for the complex to form. With an in vitro assay system, we produced the evidence that the kinetic efficiency k(cat)/K(m) of GlcAT-P in the presence of β4GalT-II was increased about 2.5-fold compared with that in the absence of β4GalT-II. Finally, we showed that co-expression of β4GalT-II and GlcAT-P increased HNK-1 expression on various glycoproteins in N2a cells, including neural cell adhesion molecule. These results indicate that the specific enzyme complex of β4GalT-II with GlcAT-P plays an important role in the biosynthesis of HNK-1 carbohydrate.     

Expression of N-acetyllactosamine and beta1,4-galactosyltransferase (beta4GalT-I) during adenoma-carcinoma sequence in the human colorectum.

We set out to determine the expression profiles of glycoproteins possessing N-acetyllactosamine, a precursor carbohydrate of sialyl Le(x), during colorectal cancer development. We immunohistochemically analyzed the distribution of N-acetyllactosamine as well as of beta4GalT-I, a member of the beta1, 4-galactosyltransferase family responsible for N-acetyllactosamine biosynthesis, in normal mucosa and in adenoma and carcinoma of the human colorectum. Using monoclonal antibody H11, N-acetyllactosamine was barely detectable in the normal mucosa. In low-grade adenoma, however, N-acetyllactosamine was weakly but definitely expressed on the cell surface, and its expression level was moderately increased in high-grade adenoma and markedly increased in carcinoma in situ as well as in advanced carcinoma. To detect beta4GalT-I, we used a newly developed polyclonal antibody (designated A18G), which is specific for the stem region of human beta4GalT-I. Faint expression of beta4GalT-I was detectable in normal mucosa, and the expression level was moderately increased in low-grade adenoma and in high-grade adenoma and markedly increased in carcinoma in situ and advanced carcinoma. The expression of N-acetyllactosamine was highly correlated with the expression of beta4GalT-I in these tumor cells. These results indicate that the expression level of beta4GalT-I is apparently enhanced during tumorigenesis in the colorectum and that beta4GalT-I mostly directs the carcinoma-associated expression of N-acetyllactosamine on the colorectal tumor cell surface. (J Histochem Cytochem 47:1593-1601, 1999)     

Polylactosamine synthesis and branch formation of N-glycans in beta1,4-galactosyltransferase-1-deficient mice

Analysis of glycans from erythrocyte membrane glycoproteins from beta1,4-galactosyltransferase-1 (beta4GalT-1)-deficient mice revealed moderately decreased galactosylation but comparable polylactosamine content compared to control beta4GalT-1(+/-) mice. The increased expression of more branched N-glycans was observed in beta4GalT-1(-/-) mice, and its extent was more remarkable in elder beta4GalT-1(-/-) mice (28 weeks old) than in younger beta4GalT-1(-/-) mice (6-9 weeks old). In relation to this issue, the less galactosylation of biantennary glycans was observed in the elder group, suggesting that beta4GalTs actually compete with N-acetylglucosaminyltransferases IV and V in erythroid cells. In contrast, approximately 80% of core 2 O-glycans were not beta1,4-galactosylated regardless of age of the knockout mice. These results suggest that beta4GalT-1 expressed in erythroid cells may regulate a constant branch formation of N-glycans and plays a predominant role in beta1,4-galactosylation of core 2 O-glycan.     

Integrin-dependent neuroblastoma cell adhesion and migration on laminin is regulated by expression levels of two enzymes in the O-mannosyl-linked glycosylation pathway, PomGnT1 and GnT-Vb

O-mannosyl-linked glycans constitute a third of all brain O-linked glycoproteins, and yet very little is understood about their functions. Several congenital muscular dystrophies with central nervous system defects are caused by genetic disruptions in glycosyltransferases responsible for the synthesis of O-mannosyl glycans. The glycosyltransferase GnT-Vb, also known as GnT-IX, is expressed abundantly in the brain and testis and is proposed to be the enzyme that branches O-mannosyl-linked glycans. In this study, we show in a human neuronal model that GnT-Vb expression enhances neurite outgrowth on laminin. GnT-Vb has been shown to perform both N-linked and O-mannosyl-linked glycosylation. To determine if the effect on neurite outgrowth was due to N-linked or O-mannosyl-linked glycosylation by GnT-Vb we suppressed the expression of glycosyltransferases important for the elongation of both N-linked and O-mannosyl-linked glycans using RNA interference. Our results suggest that GnT-Vb and PomGnT1, enzymes involved in the O-mannosyl glycosylation pathway, play an active role in modulating integrin and laminin-dependent adhesion and migration of human neuronal cells.     

Beta 1,4-galactosyltransferase (beta 4GalT)-IV is specific for GlcNAc 6-O-sulfate. Beta 4GalT-IV acts on keratan sulfate-related glycans and a precursor glycan of 6-sulfosialyl-Lewis X

The Galbeta1-->4(SO(3)(-)-->6)GlcNAc moiety is present in various N-linked and O-linked glycans including keratan sulfate and 6-sulfosialyl-Lewis X, an L-selectin ligand. We previously found beta1,4-galactosyltransferase (beta4GalT) activity in human colonic mucosa, which prefers GlcNAc 6-O-sulfate (6SGN) as an acceptor to non-substituted GlcNAc (Seko, A., Hara-Kuge, S., Nagata, K., Yonezawa, S., and Yamashita, K. (1998) FEBS Lett. 440, 307-310). To identify the gene for this enzyme, we purified the enzyme from porcine colonic mucosa. The purified enzyme had the characteristic requirement of basic lipids for catalytic activity. Analysis of the partial amino acid sequence of the enzyme revealed that the purified beta4GalT has a similar sequence to human beta4GalT-IV. To confirm this result, we prepared cDNA for each of the seven beta4GalTs cloned to date and examined substrate specificities using the membrane fractions derived from beta4GalT-transfected COS-7 cells. When using several N-linked and O-linked glycans with or without 6SGN residues as acceptor substrates, only beta4GalT-IV efficiently recognized 6SGN, keratan sulfate-related oligosaccharides, and Galbeta1-->3(SO(3)(-)-->6GlcNAcbeta1-->6) GalNAcalpha1-O-pNP, a precursor for 6-sulfosialyl-Lewis X. These results suggested that beta4GalT-IV is a 6SGN-specific beta4GalT and may be involved in the biosynthesis of various glycoproteins carrying a 6-O-sulfated N-acetyllactosamine moiety.     

Molecular cloning and enzymatic characterization of a UDP-GalNAc:GlcNAc(beta)-R beta1,4-N-acetylgalactosaminyltransferase from Caenorhabditis elegans

A common terminal structure in glycans from animal glycoproteins and glycolipids is the lactosamine sequence Gal(beta)4GlcNAc-R (LacNAc or LN). An alternative sequence that occurs in vertebrate as well as in invertebrate glycoconjugates is GalNAc(beta)4GlcNAc-R (LacdiNAc or LDN). Whereas genes encoding beta4GalTs responsible for LN synthesis have been reported, the beta4GalNAcT(s) responsible for LDN synthesis has not been identified. Here we report the identification of a gene from Caenorhabditis elegans encoding a UDP-GalNAc:GlcNAc(beta)-R beta1,4-N-acetylgalactosaminyltransferase (Ce(beta)4GalNAcT) that synthesizes the LDN structure. Ce(beta)4GalNAcT is a member of the beta4GalT family, and its cDNA is predicted to encode a 383-amino acid type 2 membrane glycoprotein. A soluble, epitope-tagged recombinant form of Ce(beta)4GalNAcT expressed in CHO-Lec8 cells was active using UDP-GalNAc, but not UDP-Gal, as a donor toward a variety of acceptor substrates containing terminal beta-linked GlcNAc in both N- and O-glycan type structures. The LDN structure of the product was verified by co-chromatography with authentic standards and (1)H NMR spectroscopy. Moreover, Chinese hamster ovary CHO-Lec8 and CHO-Lec2 cells expressing Ce(beta)4GalNAcT acquired LDN determinants on endogenous glycoprotein N-glycans, demonstrating that the enzyme is active in mammalian cells as an authentic beta4GalNAcT. The identification and availability of this novel enzyme should enhance our understanding of the structure and function of LDN-containing glycoconjugates.     

The acceptor substrate specificity of human beta4-galactosyltransferase V indicates its potential function in O-glycosylation.

In order to assess the function of the different human UDP-Gal:GlcNAc beta4-galactosyltransferases, the cDNAs of two of them, beta4-GalT I and beta4-GalT V, were expressed in the baculovirus/insect cell expression system. The soluble recombinant enzymes produced were purified from the medium and used to determine their in vitro substrate specificities. The specific activity of the recombinant beta4-GalT V was more than 15 times lower than that of beta4-GalT I, using GlcNAc beta-S-pNP as an acceptor. Whereas beta4-GalT I efficiently acts on all substrates having a terminal beta-linked GlcNAc, beta4-GalT V appeared to be far more restricted in acceptor usage. Beta4-GalT V acts with high preference on acceptors that contain the GlcNAc beta1-->6GalNAc structural element, as found in O-linked core 2-, 4- and 6-based glycans, but not on substrates related to V-linked or blood group I-active oligosaccharides. These results suggest that beta4-GalT V may function in the synthesis of lacNAc units on O-linked chains, particularly in tissues which do not express beta4-GalT I, such as brain.     

H (0) blood group determinant is present on soluble human L-selectin expressed in BHK-cells.

In the present study we show that the H (0) blood group determinant Fuc alpha1-2Gal beta1-4GlcNAc beta1-R is present on N-linked glycans of soluble human L-selectin recombinantly expressed in baby hamster kidney (BHK) cells. The glycans were isolated using complementary HPLC techniques and characterized by a combination of exoglycosidase digestion and mass spectrometry. The linkage of the fucose residues was determined by incubation of the glycans with specific fucosidases. The H blood determinant Fuc alpha1-2Gal beta1-4GlcNAc beta1 was detected for bi-, 2,4 branched tri- and tetraantennary structures. To our knowledge, the proposed oligosaccharide structures represent a new glycosylation motif for recombinant glycoproteins expressed on BHK cells.     

UDP-N-Acetyl-α-D-glucosamine as acceptor substrate of β-1,4-galactosyltransferase. Enzymatic synthesis of UDP-N-acetyllactosamine

The capacity of UDP-N-acetyl-alpha-D-glucosamine (UDP-GlcNAc) as an in vitro acceptor substrate for beta-1,4-galactosyltransferase (beta4GalT1, EC 2.4.1.38) from human and bovine milk and for recombinant human beta4GalT1, expressed in Saccharomyces cerevisiae, was evaluated. It turned out that each of the enzymes is capable to transfer Gal from UDP-alpha-D-galactose (UDP-Gal) to UDP-GlcNAc, affording Gal(beta1-4)GlcNAc(alpha1-UDP (UDP-LacNAc). Using beta4GalT1 from human milk, a preparative enzymatic synthesis of UDP-LacNAc was carried out, and the product was characterized by fast-atom bombardment mass spectrometry and 1H and 13C NMR spectroscopy. Studies with all three beta4GalTs in the presence of alpha-lactalbumin showed that the UDP-LacNAc synthesis is inhibited and that UDP-alpha-D-glucose is not an acceptor substrate. This is the first reported synthesis of a nucleotide-activated disaccharide, employing a Leloir glycosyltransferase with a nucleotide-activated monosaccharide as acceptor substrate. Interestingly, in these studies beta4GalT1 accepts an alpha-glycosidated GlcNAc derivative. The results imply that beta4GalT1 may be responsible for the biosynthesis of UDP-LacNAc, previously isolated from human milk.     

Molecular Cloning of Pigeon UDP-galactose:��-d-Galactoside ��1,4-Galactosyltransferase and UDP-galactose:��-d-Galactoside ��1,4-Galactosyltransferase, Two Novel Enzymes Catalyzing the Formation of Gal��1�C4Gal��1�C4Gal��1�C4GlcNAc Sequence

We previously found that pigeon IgG possesses unique N-glycan structures that contain the Galα1–4Galβ1–4Galβ1–4GlcNAc sequence at their nonreducing termini. This sequence is most likely produced by putative α1,4- and β1,4-galactosyltransferases (GalTs), which are responsible for the biosynthesis of the Galα1–4Gal and Galβ1–4Gal sequences on the N-glycans, respectively. Because no such glycan structures have been found in mammalian glycoproteins, the biosynthetic enzymes that produce these glycans are likely to have distinct substrate specificities from the known mammalian GalTs. To study these enzymes, we cloned the pigeon liver cDNAs encoding α4GalT and β4GalT by expression cloning and characterized these enzymes using the recombinant proteins. The deduced amino acid sequence of pigeon α4GalT has 58.2% identity to human α4GalT and 68.0 and 66.6% identity to putative α4GalTs from chicken and zebra finch, respectively. Unlike human and putative chicken α4GalTs, which possess globotriosylceramide synthase activity, pigeon α4GalT preferred to catalyze formation of the Galα1–4Gal sequence on glycoproteins. In contrast, the sequence of pigeon β4GalT revealed a type II transmembrane protein consisting of 438 amino acid residues, with no significant homology to the glycosyltransferases so far identified from mammals and chicken. However, hypothetical proteins from zebra finch (78.8% identity), frogs (58.9–60.4%), zebrafish (37.1–43.0%), and spotted green pufferfish (43.3%) were similar to pigeon β4GalT, suggesting that the pigeon β4GalT gene was inherited from the common ancestors of these vertebrates. The sequence analysis revealed that pigeon β4GalT and its homologs form a new family of glycosyltransferases.     

Identification of the Drosophila core 1 beta1,3-galactosyltransferase gene that synthesizes T antigen in the embryonic central nervous system and hemocytes

T antigen (Galbeta1-3GalNAcalpha1-Ser/Thr), the well-known tumor-associated antigen, is a core 1 mucin-type O-glycan structure that is synthesized by core 1 beta1,3-galactosyltransferase (C1beta3GalT), which transfers Gal from UDP-Gal to Tn antigen (GalNAcalpha1-Ser/Thr). Three putative C1beta3GalTs have been identified in Drosophila. However, although all three are expressed in embryos, their roles during embryogenesis have not yet been clarified. In this study, we used P-element inserted mutants to show that CG9520, one of the three putative C1beta3GalTs, synthesizes T antigen expressed on the central nervous system (CNS) during embryogenesis. We also found that T antigen was expressed on a subset of the embryonic hemocytes. CG9520 mutant embryos showed the loss of T antigens on the CNS and on a subset of hemocytes. Then, the loss of T antigens was rescued by precise excision of the P-element inserted into the CG9520 gene. Our data demonstrate that T antigens expressed on the CNS and on a subset of hemocytes are synthesized by CG9520 in the Drosophila embryo. In addition, we found that the number of circulating hemocytes was reduced in third instar larvae of CG9520 mutant. We, therefore, named the CG9520 gene Drosophila core 1 beta1,3-galactosyltransferase 1 because it is responsible for the synthesis and function of T antigen in vivo.     

Drosophila beta 1,4-N-acetylgalactosaminyltransferase-A synthesizes the LacdiNAc structures on several glycoproteins and glycosphingolipids

The GalNAcbeta1,4GlcNAc (LacdiNAc or LDN) structure is a more common structural feature in invertebrate glycoconjugates when compared with the Galbeta1,4GlcNAc structure. Recently, beta1,4-N-acetylgalactosaminyltransferase (beta4GalNAcT) was identified in some invertebrates including Drosophila. However, the LDN structure has not been reported in Drosophila, and the biological function of LDN remains to be determined. In this study, we examined acceptor substrate specificity of Drosophila beta4GalNAcTA by using some N- and O-glycans on glycoproteins and neutral glycosphingolipids (GSLs). GalNAc was efficiently transferred toward N-glycans, O-glycans, and the arthro-series GSLs. Moreover, we showed that dbeta4GalNAcTA contributed to the synthesis of the LDN structure in vivo. The dbeta4GalNAcTA mRNA was highly expressed in the developmental and adult neuronal tissues. Thus, these results suggest that dbeta4GalNAcTA acts on the terminal GlcNAc residue of some glycans for the synthesis of LDN, and the LDN structure may play a role in the physiological or neuronal development of Drosophila.     

Expression of protein kinase C genes during ontogenic development of the central nervous system.

We have analyzed the RNA expression of three protein kinase C (PKC) genes (alpha, beta, and gamma) in human and murine central nervous systems during embryonic-fetal, perinatal, and adult life. Analysis of human brain poly(A)+ RNA indicates that expression of PKC alpha and beta genes can be detected as early as 6 weeks postconception, undergoes a gradual increase until 9 weeks postconception, and reaches its highest level in the adult stage, and that the PKC gamma gene, although not expressed during embryonic and early fetal development, is abundantly expressed in the adult period. Similar developmental patterns were observed in human spinal cord and medulla oblongata. A detailed analysis of PKC gene expression during mammalian ontogeny was performed on poly(A)+ RNA from the brain cells of murine embryos at different stages of development and the brain cells of neonatal and adult mice. The ontogenetic patterns were similar to those observed for human brain. Furthermore, we observed that the expression of PKC gamma is induced in the peri- and postnatal phases. These results suggest that expression of PKC alpha, beta, and gamma genes possibly mediates the development of central neuronal functions, and expression of PKC gamma in particular may be involved in the development of peri- and postnatal functions.