Expression of CD15 (FAL) on myeloid cells and chromosomal localization of the gene

Surface antigen changes during normal neutrophilic development: a critical review

Neutrophil surface molecules function in part as biological sensors. Surface antigens undergo several changes during neutrophilic maturation to accommodate the cell's function. Surface antigens may appear with neutrophilic maturation, such as CD16b, CD35, and CD10; disappear with maturation, such as CD49d and CD64; be maintained during maturation, such as CD32, CD59, and CD82; or disappear with maturation but reappear after neutrophilic extravasation, such as CD49b. This article reviews the alterations in surface antigen expression during normal neutrophilic granulopoiesis.

Expression cloning and characterization of a novel murine alpha1, 3-fucosyltransferase, mFuc-TIX, that synthesizes the Lewis x (CD15) epitope in brain and kidney

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 alpha1,3-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 alpha2,3-sialyl lacto-N-neotetraose or lacto-N-tetraose. The substrate specificity of mFuc-TIX was similar to that of mouse myeloid-type alpha1,3-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 alpha1,3-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 alpha1, 3-fucosyltransferases constructed by the neighbor-joining method showed that mFuc-TIX is quite distant from the other alpha1, 3-fucosyltransferases. Thus, mFuc-TIX does not belong to any subfamilies of known alpha1,3Fuc-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.

Lectin binding and uptake in human (myelo)monocytic cell lines: HL60 and U937

The terminal carbohydrate residues of the human (myelo) monocytic cell lines HL60 and two subclones of U937 were investigated by the use of lectins. Several terminal carbohydrate residues, including N-acetylglucosamine and carbohydrates of the complex type, were detected on all three cell lines. Except for galactose residues, the two subclones of U937 had almost identical terminal carbohydrate residues. The differences between the two U937 subclones and HL60 were more pronounced, the latter expressing fucose residues, which might be part of the CD15 cell adhesion molecules. Some of the differences of the carbohydrate residues between the cell lines could be attributed to their differentiation within the myelomonocytic cell lineage. Lectins that bound to the cell surface were internalized via either clathrin-coated pits and vesicles or nonspecific endocytosis, indicating that functionally different classes of cell surface glycoproteins are involved in lectin binding and internalization.