Mammalian sulfoglycolipids comprise two major members, sulfatide (HSO3-3-galactosylceramide) and seminolipid (HSO3-3-monogalactosylalkylacylglycerol). Sulfatide is a major lipid component of the myelin sheath and serves as the epitope for the well known oligodendrocyte-marker antibody O4. Seminolipid is synthesized in spermatocytes and maintained in the subsequent germ cell stages. Both sulfoglycolipids can be synthesized in vitro by using the isolated cerebroside sulfotransferase. To investigate the physiological role of sulfoglycolipids and to determine whether sulfatide and seminolipid are biosynthesized in vivo by a single sulfotransferase, Cst-null mice were generated by gene targeting. Cst ؊/؊ mice lacked sulfatide in brain and seminolipid in testis, proving that a single gene copy is responsible for their biosynthesis. Cst ؊/؊ mice were born healthy, but began to display hindlimb weakness by 6 weeks of age and subsequently showed a pronounced tremor and progressive ataxia. Although compact myelin was preserved, Cst ؊/؊ mice displayed abnormalities in paranodal junctions. On the other hand, Cst ؊/؊ males were sterile because of a block in spermatogenesis before the first meiotic division, whereas females were able to breed. These data show a critical role for sulfoglycolipids in myelin function and spermatogenesis.
Myelinated axons are divided into four distinct regions: the node of Ranvier, paranode, juxtaparanode, and internode, each of which is characterized by a specific set of axonal proteins. Voltage-gated Na+ channels are clustered at high densities at the nodes, whereas shaker-type K+ channels are concentrated at juxtaparanodal regions. These channels are separated by the paranodal regions, where septate-like junctions are formed between the axon and the myelinating glial cells. Although oligodendrocytes and myelin sheaths are believed to play an instructive role in the local differentiation of the axon to distinct domains, the molecular mechanisms involved are poorly understood. In the present study, we have examined the distribution of axonal components in mice incapable of synthesizing sulfatide by disruption of the galactosylceramide sulfotransferase gene. These mice displayed abnormal paranodal junctions in the CNS and PNS, whereas their compact myelin was preserved. Immunohistochemical analysis demonstrated a decrease in Na+ and K+ channel clusters, altered nodal length, abnormal localization of K+ channel clusters appearing primarily in the presumptive paranodal regions, and diffuse distribution of contactin-associated protein along the internode. Similar abnormalities have been reported previously in mice lacking both galactocerebroside and sulfatide. Interestingly, although no demyelination was observed, these channel clusters decreased markedly with age. The initial timing and the number of Na+ channel clusters formed were normal during development. These results indicate a critical role for sulfatide in proper localization and maintenance of ion channels clusters, whereas they do not appear to be essential for initial cluster formation of Na+ channels.
We have isolated a cDNA clone encoding human 3-phosphoadenylylsulfate:galactosylceramide 3-sulfotransferase (EC 2.8.2.11). Degenerate oligonucleotides, based on amino acid sequence data for the purified enzyme, were used as primers to amplify fragments of the gene from human renal cancer cell cDNA by the polymerase chain reaction method. The amplified cDNA fragment was then used as probe to screen a human renal cancer cell cDNA library. The isolated cDNA clone contained an open reading frame encoding 423 amino acids including all of the peptides that were sequenced. The deduced amino acid sequence predicts a type II transmembrane topology and contains two potential N-glycosylation sites. There is no significant homology between this sequence and either the sulfotransferases cloned to date or other known proteins. Northern blot analysis demonstrated that a 1.9-kilobase mRNA was unique to renal cancer cells. When the cDNA was inserted into the expression vector pSVK3 and transfected into COS-1 cells, galactosylceramide sulfotransferase activity in the transfected cells increased from 8-to 16-fold over that of controls, and the enzyme product, sulfatide, was expressed on the transformed cells.Sulfoglycolipids are a class of acidic glycolipids containing sulfate esters on their oligosaccharide chains which were originally found in the human brain by Thudichum (1). Sulfoglycolipids are abundant in myelin, spermatozoa, kidney, and small intestine (for review, see Ref.2) and have been implicated in a variety of physiological functions through their interactions with extracellular matrix proteins, cellular adhesive receptors, blood coagulation systems, complement activation systems, cation transport systems, and microorganisms (for a review, see Ref.3). The addition of sulfate ester is catalyzed by a sulfotransferase with PAPS 1 serving as the sulfate donor.
Galactosylceramide (GalC) and its sulfated analogue, sulfatide, are major galactosphingolipid components of myelin and oligodendrocyte plasma membranes in the nervous system. We previously hypothesized that these galactolipids play functional roles in the regulation of oligodendrocyte terminal differentiation by acting as sensors/transmitters of environmental information. Evidence strongly supports this idea. First, these molecules are initially expressed on the cell surface at the interface at which oligodendrocyte progenitors first enter terminal differentiation. Second, exposure of oligodendrocyte progenitors to anti-GalC/-sulfatide (RmAb) or antisulfatide (O4), but not anti-GalC (O1), antibodies leads to the reversible arrest of oligodendrocyte lineage progression at this interface. Third, in cerebroside galactosyl transferase-null mice (Cgt(-/-)) that are unable to synthesize either GalC or sulfatide, terminal differentiation and morphological maturation of oligodendrocytes are enhanced. In the present study, we examined oligodendrocytes differentiation in cerebroside sulfotransferase-null mice (Cst(-/-)) that lack sulfatide but express GalC. We show that cerebroside sulfotransferase mRNA expression begins already in the embryonic spinal cord and progressively increases with age, that the late progenitor marker POA is not synthesized in the absence of this enzyme, and that, most notably, there is a two- to threefold enhancement in the number of terminally differentiated oligodendrocytes both in culture and in vivo, similar to that in mice lacking both GalC and sulfatide. We conclude that primarily sulfatide, rather than GalC, is a key molecule for the negative regulation of oligodendrocyte terminal differentiation.
We have isolated a mouse cDNA clone encoding 3′‐phosphoadenylylsulfate–galactosylceramide 3′‐sulfotransferase (cerebroside sulfotransferase; CST; EC 2.8.2.11) from a kidney cDNA library, using a human CST cDNA clone [Honke, K., Tsuda, M., Hirahara, Y., Ishii, A., Makita, A. & Wada, Y. (1997) J. Biol. Chem.272, 4864–4868] as a probe. A recombinant protein of the cloned cDNA showed CST activity. The deduced protein is composed of the same 423 amino acids as human CST and its sequence exhibits 84% identity with that of the human counterpart. Northern‐blot analysis and subquantitative reverse transcription‐PCR (RT‐PCR) analysis showed that the CST gene is preferentially transcribed in stomach, small intestine, brain, kidney, lung, and testis, in that order. To examine differences in transcripts in various tissues, we isolated CST cDNA clones from stomach, small intestine, brain, kidney, and testis by 5′‐RACE analysis. We found seven different nucleotide sequences in the 5′‐UTR, while the DNA sequences of all the isolated cDNA clones were identical in the coding region. In addition, we isolated CST genomic DNA clones from a mouse genomic library. The clones covered all the 5′‐UTR sequences and coding exons including 3′‐UTR. RT‐PCR analyses of CST mRNAs from various tissues confirmed that CST transcripts are tissue‐specifically spliced by alternative use of multiple exons 1. These observations suggest that the tissue‐specific expression of the CST gene is explained by alternative usage of multiple 5′‐UTR exons flanked with tissue‐specific promoters.
Chondroitin 4-sulfotransferase, which transfers sulfate from 3-phosphoadenosine 5-phosphosulfate to position 4 of N-acetylgalactosamine in chondroitin, was purified 1900-fold to apparent homogeneity with 6.1% yield from the serum-free culture medium of rat chondrosarcoma cells by affinity chromatography on heparin-Sepharose CL-6B, Matrex gel red A-agarose, 3,5-ADP-agarose, and the second heparin-Sepharose CL-6B. SDS-polyacrylamide gel electrophoresis of the purified enzyme showed two protein bands. Molecular masses of these protein were 60 and 64 kDa under reducing conditions and 50 and 54 kDa under nonreducing conditions. Both the protein bands coeluted with chondroitin 4-sulfotransferase activity from Toyopearl HW-55 around the position of 50 kDa, indicating that the active form of chondroitin 4-sulfotransferase is a monomer. Dithiothreitol activated the purified chondroitin 4-sulfotransferase. The purified enzyme transferred sulfate to chondroitin and desulfated dermatan sulfate. Chondroitin sulfate A and chondroitin sulfate C were poor acceptors. Chondroitin sulfate E from squid cartilage, dermatan sulfate, heparan sulfate, and completely desulfated N-resulfated heparin hardly served as acceptors of the sulfotransferase. The transfer of sulfate to the desulfated dermatan sulfate occurred preferentially at position 4 of the N-acetylgalactosamine residues flanked with glucuronic acid residues on both reducing and nonreducing sides.Chondroitin sulfate proteoglycan is found in various tissues and thought to play important roles in various cellular interactions involving cell adhesion (1, 2), regulation of neurite outgrowth (3-6), migration of neural crest cells (7), binding of phospholipase A 2 (8), and an adherence receptor for Plasmodium falciparum-infected erythrocytes (9). In most of mammalian and avian chondroitin sulfate proteoglycans, the glycosaminoglycan chains bear sulfate at position 4 or 6 of N-acetylgalactosamine residues. The ratio of chondroitin 4-sulfate/chondroitin 6-sulfate has been reported to vary with the development of animals (10 -12), malignant change (13), and leukocyte differentiation (14). Sulfation of positions 4 and 6 of GalNAc residue was shown to be catalyzed by different sulfotransferases (15); chondroitin 4-sulfotransferase (C4ST) 1 and chondroitin 6-sulfotransferase (C6ST). Characterization of the purified sulfotransferases and molecular cloning of these cDNAs are basically important to reveal the functional roles of these chondroitin sulfate isomers. We have purified C6ST from the culture medium of chick chondrocytes (16) and cloned the cDNA (17). Unexpectedly, the purified C6ST was found to catalyze not only chondroitin but also keratan sulfate (18) and sialyl N-acetyllactosamine oligosaccharides (19). We previously observed that C4ST was also secreted to the culture medium of chick chondrocytes (20), but the purification of C4ST from the culture medium of chick chondrocytes has been hampered by the presence of an excess amount of C6ST. Unlike chick chondrocytes, rat chondrosa...
Sulfatide species with various fatty acid chains in oligodendrocytes at different developmental stages determined by imaging mass spectrometry
HSO3-3-galactosylceramide (Sulfatide) species comprise the major glycosphingolipid components of oligodendrocytes and myelin and play functional roles in the regulation of oligodendrocyte maturation and myelin formation. Although various sulfatide species contain different fatty acids, it is unclear how these sulfatide species affect oligodendrogenesis and myelination. The O4 monoclonal antibody reaction with sulfatide has been widely used as a useful marker for oligodendrocytes and myelin. However, sulfatide synthesis during the pro-oligodendroblast stage, where differentiation into the oligodendrocyte lineage has already occurred, has not been examined. Notably, this stage comprises O4-positive cells. In this study, we identified a sulfatide species from the pro-oligodendroblast-to-myelination stage by imaging mass spectrometry. The results demonstrated that short-chain sulfatides with 16 carbon non-hydroxylated fatty acids (C16) and 18 carbon non-hydroxylated fatty acids (C18) or 18 carbon hydroxylated fatty acids (C18-OH) existed in restricted regions of the early embryonic spinal cord, where pro-oligodendroblasts initially appear, and co-localized with Olig2-positive pro-oligodendroblasts. C18 and C18-OH sulfatides also existed in isolated pro-oligodendroblasts. C22-OH sulfatide became predominant later in oligodendrocyte development and the longer C24 sulfatide was predominant in the adult brain. Additionally, the presence of each sulfatide species in a different area of the adult brain was demonstrated by imaging mass spectrometry at an increased lateral resolution. These findings indicated that O4 recognized sulfatides with short-chain fatty acids in pro-oligodendroblasts. Moreover, the fatty acid chain of the sulfatide became longer as the oligodendrocyte matured. Therefore, individual sulfatide species may have unique roles in oligodendrocyte maturation and myelination. Read the Editorial Highlight for this article on page 356.
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