The 3-fucosyl-N-acetyllactosamine (Lewis x, CD15, SSEA-1) carbohydrate epitope is widely distributed in many tissues and is developmentally expressed in some rodent and human tissues, i.e. brain and lung, and mouse early embryo. In such tissues, the Lewis x epitope is considered to be involved in cell-cell interactions. We isolated a novel mouse ␣1,3-fucosyltransferase gene, named mFuc-TIX, from an adult mouse brain cDNA library using the expression cloning method. On flow cytometric analysis, Namalwa cells transfected stably with the mFuc-TIX gene showed a marked increase in Lewis x epitopes but not sialyl Lewis x epitopes. As seen experiments involving oligosaccharides as acceptor substrates, mFuc-TIX transfers a fucose to lacto-N-neotetraose but not to either ␣2,3-sialyl lacto-N-neotetraose or lacto-N-tetraose. The substrate specificity of mFuc-TIX was similar to that of mouse myeloid-type ␣1,3-fucosyltransferase (mFuc-TIV). The deduced amino acid sequence of mFuc-TIX, consisting of 359 residues, indicated a type II membrane protein and shows low degrees of homology to the previously cloned ␣1,3-fucosyltransferases, i.e. mFuc-TIV (48.4%), mouse Fuc-TVII (39.1%), and human Fuc-TIII (43.0%), at the amino acid sequence level. A phylogenetic tree of the ␣1,3-fucosyltransferases constructed by the neighbor-joining method showed that mFuc-TIX is quite distant from the other ␣1,3-fucosyltransferases. Thus, mFuc-TIX does not belong to any subfamilies of known ␣1,3Fuc-Ts. The mFuc-TIX transcript was mainly detected in brain and kidney with the Northern blotting and competitive reverse transcription-polymerase chain reaction methods, whereas the mFuc-TIV transcript was not detected in brain with these methods. On in situ hybridization, the mFuc-TIX transcript was detected in neuronal cells but not in the glial cells including astrocytes. These results strongly indicated that mFuc-TIX participates in the Lewis x synthesis in neurons of the brain and may be developmentally regulated.
The expression of type-1 Lewis antigens on erythrocytes and in digestive organs is determined by a Lewis type alpha(1,3/1, 4)-fucosyltransferase (Lewis enzyme) encoded by the Fuc-TIII gene ( FUT3 gene; Lewis gene). We have classified the Lewis alleles in the Japanese population into four types, the wild-type allele ( Le ) and three mutated alleles, i.e., le1, which has missense mutations T59G and G508A, le2, which has T59G and T1067A, and le3, which has only T59G. Here we carried out an extensive study on the biological properties of the three mutant Lewis enzymes, the le1, le2, and le3 enzymes, using native tissues and obtained the following results. (1) In in vivo and in vitro experiments, the le1 and le2 enzymes were found to be susceptible to protease digestion probably because the one missense mutation in the catalytic domains, i.e., Gly170 to Ser in the le1 enzyme and Ile356 to Lys in the le2 enzyme, makes the three-dimensional structures of the enzymesunstable, while the le3 and wild-type Lewis enzymes wereresistant to protease digestion. (2) The le1 and le2 enzymes cannot synthesize type 1 Lewis antigens on either glycolipids or mucins. The le3 enzyme cannot synthesize Lewis-active glycolipids, which result in the Lewis antigen-negative phenotype of erythrocytes, while it can synthesize Lewis antigens on mucins in normal and cancerous colon tissues. The missense mutation, Leu20 to Arg, in the transmembrane domain reduces retention of the le3 enzyme in the Golgi membrane resulting in an apparent reduction of enzyme activity as revealed by the lack of Lewis antigen synthesis. (3) The Lewis gene dosage actually has effects in vivo on the amount of the Lewis enzyme, its activity, and finally the amounts of Lewis carbohydrate antigens. This is the first article that clearly demonstrates the gene dosage effects on the amount of the glycosyltransferase protein, its activity, and the amounts of carbohydrate products in vivo.
Lewis b (Le b ) antigens are gradiently expressed from the proximal to the distal colon, i.e., they are abundantly expressed in the proximal colon, but only faintly in the distal colon. In the distal colon, they begin to increase at the adenoma stage of cancer development and then increase with cancer progression. We aimed to clarify the molecular basis of Le b antigen expression in correlation with the expression of other type I Lewis antigens, such as Lewis a (Le a ) and sialylated Lewis a (sLe a ), in colon cancer cells. Considering the Se genotype and the relative activities of the H and Se enzymes, the amounts of Le b antigens were proved to be determined by both the H and Se enzymes in noncancerous and cancerous colon tissues. But the Se enzyme made a much greater contribution to determining the Le b amounts than the H enzyme. In noncancerous colons, the Se enzyme were gradiently expressed in good correlation with the Le b expression, while the H enzyme was constantly expressed throughout the whole colon. In distal colon cancers, the H and Se enzymes were both significantly upregulated in comparison with in adjacent noncancerous tissues. In proximal colon cancers, expression of the H enzyme alone was highly augmented. The augmented expression of Le b antigens in distal colon cancers is caused mainly by upregulation of the Se enzyme and partly by the H enzymes, while it is caused by upregulation of the H enzyme alone in proximal colon cancers. The Se gene dosage profoundly influences the amounts of the Le b , Le a , and sLe a antigens in whole colon tissues, regardless of whether they are noncancerous or cancerous tissues. It suggests that the Se enzyme competes with α2,3 sialyltransferase(s) and the Le enzyme for the type I acceptor substrates.
Immunohistochemical staining showed an aberrant expression of Le(a) antigen in the intestinal metaplastic glands of the gastric mucosa of secretors, as reported by others. In this study, we have demonstrated for the first time that the Lewis enzyme is well colocalized with Le(a) antigen, indicating that the Lewis enzyme is responsible for Le(a) antigen synthesis in the gastric mucosa. The staining intensity of the Lewis enzyme was much stronger in the cells with intestinal metaplasia than the cells without metaplasia, regardless of the secretor status. The amount of transcript of the Lewis gene was related to the degree of metaplasia; i.e., the more severe the metaplastic change was, the more abundantly the transcripts of the Lewis gene were expressed. This augmentation of the Lewis enzyme in metaplastic tissues was also confirmed by Western blotting analysis using a specific antibody against the Lewis enzyme. We conclude that intestinal metaplastic change of gastric mucosa is usually accompanied by a marked augmentation of the Lewis enzyme expression, which results in the enhanced expression of Le(a) antigens, particularly in secretors.
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