Structural Study of the Blood Group A Active Glycolipids of Hog Gastric Mucosa

Distinct expression profiles of UDP-galactose: β-D-galactoside α1,4-galactosyltransferase and UDP-galactose: β-D-galactoside β1,4-galactosyltransferase in pigeon, ostrich and chicken

We previously identified two novel enzymes in pigeon, α1,4- and β1,4-galactosyltransferases (GalTs), which are responsible for the biosynthesis of the Galα1-4Gal and Galβ1-4Gal sequences on glycoproteins, respectively. No such glycan structures and/or enzymes have been found in mammals, suggesting that the expression of these enzymes diverged during the course of vertebrate evolution. To compare their expression profiles among avian species, we first established a method for detecting the activities of these two GalTs based on the two-dimensional high pressure liquid chromatography mapping technique, using 2-aminopyridine-derivatized asialo-biantennary N-glycans as an acceptor substrate. When we analyzed the activities of GalTs in pigeon liver extracts in the presence of UDP-Gal, 13 different products containing Galα1-4Galβ1-4GlcNAc, Galβ1-4Galβ1-4GlcNAc and/or Galα1-4Galβ1-4Galβ1-4GlcNAc branches were identified. The newly formed glycosidic linkages of the enzymatic products were determined by nuclear magnetic resonance and methylation analysis, as well as by galactosidase digestions. The activities of both α1,4- and β1,4-GalTs were detected in various tissues in pigeon, although their relative activities were different in each tissue. In contrast, ostrich expressed β1,4-GalT, but not α1,4-GalT, in all tissues analyzed, whereas neither α1,4- nor β1,4-GalT activity was detected in chicken. These results indicate that α1,4- and β1,4-GalTs are expressed in a species-specific manner and are distributed throughout the entire body of pigeon or ostrich when the enzymes are present.

Molecular cloning of pigeon UDP-galactose:beta-D-galactoside alpha1,4-galactosyltransferase and UDP-galactose:beta-D-galactoside beta1,4-galactosyltransferase, two novel enzymes catalyzing the formation of Gal alpha1-4Gal beta1-4Gal beta1-4GlcNAc sequence

We previously found that pigeon IgG possesses unique N-glycan structures that contain the Gal alpha1-4Gal beta1-4Gal beta1-4GlcNAc sequence at their nonreducing termini. This sequence is most likely produced by putative alpha1,4- and beta1,4-galactosyltransferases (GalTs), which are responsible for the biosynthesis of the Gal alpha1-4Gal and Gal beta1-4Gal 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 alpha4GalT and beta4GalT by expression cloning and characterized these enzymes using the recombinant proteins. The deduced amino acid sequence of pigeon alpha4GalT has 58.2% identity to human alpha4GalT and 68.0 and 66.6% identity to putative alpha4GalTs from chicken and zebra finch, respectively. Unlike human and putative chicken alpha4GalTs, which possess globotriosylceramide synthase activity, pigeon alpha4GalT preferred to catalyze formation of the Gal alpha1-4Gal sequence on glycoproteins. In contrast, the sequence of pigeon beta4GalT 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 beta4GalT, suggesting that the pigeon beta4GalT gene was inherited from the common ancestors of these vertebrates. The sequence analysis revealed that pigeon beta4GalT and its homologs form a new family of glycosyltransferases.

Blood groups and transfusions in pigs

The blood groups of pigs are important to transplantation research because some are also important transplantation antigens and because pigs undergoing organ or hematopoietic transplantation may require transfusion support. There is considerable literature on the subject but much of it is not in transplant related journals. We will review this literature and also give some practical advice on transfusion support.

Introduction to porcine red blood cells: implications for xenotransfusion

Advances in the field of xenotransplantation raise the intriguing possibility of using porcine red blood cells (pRBCs) as an alternative source for blood transfusion. The domestic pig is considered the most likely donor species for xenotransplantation. However, identification of xenoantigens on porcine erythrocytes and elucidation of their possible roles in antibody-mediated RBC destruction are necessary for developing clinical strategies to circumvent immunological incompatibility between humans and pigs. Although the alphaGal epitope (Galalpha1,3Galbeta1,4GIcNAc-R) is the major xenoantigen on porcine erythrocytes and is responsible for the binding of the majority of human natural antibodies, other non-alphaGal xenoantigens have been identified. The importance of these non-alphaGal xenoantigens in binding human natural antibodies and subsequently triggering immunological responses cannot be underestimated. Our data suggest that non-alphaGal xenoantigen(s) identified on the porcine erythrocyte membrane are not only recognized by xenoreactive human natural antibodies but are also involved in complement-mediated hemolysis.

Chemical characterization of a blood group H type pentaglycosylceramide of human small intestine

A blood group H type pentaglycosylceramide was isolated in relatively large amounts from human adult small intestine (52 mg from one individual) and human meconium (fetal origin). The structure was made likely by mass spectrometry and NMR spectroscopy of non-degraded permethylated and permethylated-LiAlH4-reduced glycolipid and by degradation to be Fuc alpha 1 leads to 2Gal beta 1 leads to 3GlcNAc beta 1 leads to 3Gal beta 1 leads to 4Glc beta 1 leads to 1Cer. The ceramide was composed mainly of phytosphingosine and 2-hydroxy 16-24 carbon fatty acids. This novel type 1 chain species (Gal beta 1 leads to 3GlcNAc) was not accompanied by the type 2 chain isomer (Gal beta 1 leads to 4GlcNAc) which in contrast is the sole species in human erythrocyte and dog small intestine.

Synthesis of glycolipids

The chemical syntheses of naturally occurring glycolipids derived from sphingosine bases and glycerol derivatives, and the syntheses of polyisoprenoid lipid intermediates and other miscellaneous glycolipids recorded up to the end of 1977 are reviewed.

Isolation and characterization of a sulfated glyceroglucolipid from alveolar lavage of rabbit

A major acidic glycolipid of the rabbit alveolar lavage has been isolated and characterized. The isolation procedure involved extraction of lipids, column fractionation on DEAE-Sephadex and silicic acid, and thin-layer chromatography. Chemical analysis of the glycolipid revealed the presence of glucose, fatty acids, glycerol mono-ethers and sulfate. By partial acid and alkaline methanolysis, oxidation with periodate and chromium trioxide, and methylation analysis of the native and desulfated compound, the structure of this glycolipid is proposed to be: SO3H-6Glc alpha 1 leads to 6Glc alpha 1 leads to 6Glc alpha 1 leads to 6Glc alpha 1 leads to 3-1,(3)-O-alkyl-2-0-acylglycerol.

Blood-group-(A + H) complex fucolipids of hog gastric mucosa

A new group complex glycosphingolipids exhibiting blood-group-(A + H) activity was isolated from the lipid extract of hog gastric mucosa. Four components of this group have been purified to homogeneity and their structures and immunological properties were studied. The branched structures of glycolipids were identified by partial acid hydrolysis, sequential degradation with specific glycosidases, oxidation with periodate and chromium trioxide, and comparison of the permethylation products of the native and defucosylated compounds. The structures of these fucolipids are proposed to be as follows.

The nature of ABH blood group antigens in human gastric secretion

The origin of blood group ABH activity in human gastric content was investigated. Dialyzed and lyophilized samples of ten individual gastric secretions were assayed for ABH antigen under various conditions. The native activity persisted in delipidated residue of the respective secretions, but was completely missing in the lipid extracts of the analyzed samples. The alkaline degradation of the native and delipidated samples led to total loss of blood group activity of the analyzed materials, but no effect on A-active glycosphingolipid was evolved. Purified glycolipid portion of the lipid extract was lacking ABH activity and was shown to have distinct composition. This fraction contained only glyceroglucolipids and neither sphingosine nor other carbohydrates were present. On the basis of blood group activity assays of the native, delipidated, alkaline degraded samples and also on glycolipid analysis it was established that the ABH blood group activity of stomach secretion originated entirely from the glycoprotein portion of these samples.

ABH-blood-group antigens and glycolipids of human saliva

The nature of ABH-blood-group antigens in saliva was investigated. Human saliva was examined serologically for ABH-blood-group activity in its native form and after various treatments. The activity of the native form persisted in the delipidated samples, but was entirely lost after alkaline degradation. The lipid portion of saliva was completely inactive in the ABH hemagglutination inhibition system. The same results were obtained when purified glycolipid fraction of saliva was used instead of whole lipid extract. Neither alkaline treatment nor excessive amounts of salivary lipids effected antigenic activity of A-active glycosphingolipids of hog gastric mucosa admixed to saliva samples before alkaline degradation and/or in presence of large amounts of salivary lipids. The isolated glycolipid fractions contained at least eight glycolipids, each of which was composed of glucose, glyceryl ethers and fatty acids and differed from others with respect to number of glucose residues. Sphingosine and sugar residues involved in formation of ABH antigenic determinants were not detected. These findings together with data on stomach secretion [1,2] led us to the conclusion that ABH-blood-group antigens of saliva are exclusively of glycoprotein nature.

Glyceroglucolipids of the human saliva

Seven individual glycolipids (I--VII) have been isolated from the lipid extract of human saliva. All glycolipids contained glucose, glyceryl ethers and fatty acids, and differed from each other primarily with respect to the number of glucose residues. In addition, glycolipid V contained also the sulfate ester group. The structures of these glycolipids were identified by partial acid and alkaline hydrolysis, oxidation with periodate and chromium trioxide and methylation studies, as: Glc(alpha1 leads to 3)-diglyceride (glycolipid I), Glc(alpha1 leads to 6)Glc(alpha1 leads to 3)-diglyceride (glycolipids II and III), Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 3)-diglyceride (glycolipid IV), SO3H-6Glc(alpha1 leads to 6)Glc(alpha1 leads to 3)-diglyceride (glycolipid V), Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 3)-diglyceride (glycolipid VI) and Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 6)Glc(alpha1 lead to 6)Glc(alpha1 leads to 6)Glc(alpha1 leads to 3)-diglyceride (glycolipid VII). Diglyceride portion of these compounds consists of 1-O-alkyl-2-O-acyl-glycerol with the docosanoate and glyceryl-monodocosyl being the predominant acyl and alkyl components.

Forssman glycolipid variants of dog gastric mucosa. Structure of a branched ceramide octasaccharide

A fucose-containing ceramide octasaccharide exhibiting Forssman antigenic activity, and reacting in human H anti-H and anti-A systems, was isolated from water-soluble glycolipids of dog gastric mucosa. Defucosylation of the glycolipid resulted in the loss of H-activity, but had no effect on its Forssman nor blood-group A antigenic activity. The branched structure of glycolipid was identified by partial acid hydrolysis, sequential degradation with specific glycosidases and comparison of the permethylation products of the native and enzyme-degraded compound. The structure of this glycolipid is proposed to be: formula.

Ganglioside structures and distribution: are they localized at the nerve ending?

Gangliosides generally provide a small portion of the complex carbohydrate content of cell surfaces. An exception is the central nervous system where they comprise up to 5--10% of the total lipid of some membranes. This tissue is unique in that the quantity of lipid-bound sialic acid exceeds that of the protein-bound fraction. Over 30 different molecular species have been characterized to date. These range in complexity from sialosylgalactosyl ceramide with 2 sugars to the pentasialoganglioside of fish brain with 9 carbohydrate units. Virtually all cellular and subcellular fractions of brain that have been carefully examined contain gangliosides to one degree or another, but the majority of brain ganglioside is located in the neurons. Their mode of distribution within the neuron has not been entirely clarified by subcellular studies. Calculations based on reported values for axon terminal density and synaptosomal ganglioside concentration in the rat reveal that nerve endings contribute less than 12% of total cerebral cortical ganglioside. It is concluded that the plasma membranes of neuronal processes contain most of the neuronal ganglioside. These and other considerations suggest the possibility that gangliosides may be distributed over the entire neuronal surface.

Structural studies on branched fucosphingolipids of hog gastric mucosa

A structural studies have been performed on new complex glycolipids extracted from hog gastric mucosa by 0.4 M sodium acetate in methanol-chloroform-water, and which were purified to homogeneity by DEAE-Sephadex and Florisil column chromatography and by preparative thin-layer chromatography in three solvent systems. Five branched fucolipids have been purified from this extract, three of which have been characterized previously [1] and remaining two were subject of this investigations. Based on the results of partial acid hydrolyses, oxidation with periodate and chromium trioxide, permethylation and serological activities following structures were proposed.

Water-soluble glycosphingolipids of dog gastric mucosa. Characterization of a branched ceramide heptasaccharide

Two glycosphingolipids, the carbohydrate portion of which consisted of galactose, glucose and N-acetylgalactosamine, have been isolated from the aqueous phase of buffered tetrahydrofuran extract of dog gastric mucosa. The structures of these glycolipids were identified by partial acid hydrolysis, sequential degradation with specific glycosidases and methylation analysis. The structure of glycolipid I (GalNAcalpha1 leads to 3GalNAcbeta1 leads to 3Galalpha1 leads to 4Galbeta1 leads to 4Glc leads to ceramide) was found to be identical to that of Forssman hapten. The branched structure of glycolipid II, as determined by the combination of enzymatic degradation and comparison of the permethylation products of the enzyme-degraded compounds, is proposed to be: See Source.

Branched blood group A-active fucolipids of hog gastric mucosa

New complex glycolipids have been extracted from hog gastric mucosa with the mixture of 0.4 M sodium acetate in methanol/chloroform/water. Three A-active fucolipids having branched carbohydrate chains have been purified from this extract. The postulated structures of these glycolipids are based on the results of partial acid hydrolysis, oxidation with periodate and chromium trioxide, and permethylation studies.

The glycosphingolipids of rat sublingual and submaxillary glands

1. Glycosphingolipids have been isolated from rat sublingual and submaxillary glands by the procedure involving lipid extraction, column fractionation and thin-layer chromatography. 2. The major neutral glycosphingolipids in rat sublingual and submaxillary glands were monohexosylceramide, dihexosylceramide, tetrahexosylceramide and pentahexosylceramide. Both types of glands exhibited a low content of trihexosylceramide. The fucose-containing glycosphingolipids were not found. 3. The acidic glycosphingolipids in rat sublingual and submaxillary glands were composed of monohexose sulfatide, dihexose sulfatide and monosialo-and disialogangliosides of hematoside series. In addition, small quantities of gangliosides containing hexosamines were also present. 4. The distribution of acidic and neutral glycosphingolipids was similar in the sublingual and submaxillary glands, except for the tetrahexosylceramide and sultatides. Sublingual glands contained 1.5 and 3.0 times as much tetrahexosylceramide and sulfatides, respectively, as did submaxillary glands. 5. The glycosphingolipids of submaxillary and sublingual glands showed large similarity in fatty acid composition. The fatty acid composition of gangliosides resembled each other, but differed remarkably from those of sulfatides and neutral glycosphingolipids in the docosanoate content.

Enzymatic synthesis of two fucose-containing glycolipids with fucosyltransferases of human serum

Lacto-N-neotetraosylceramide incubated with human serum fucosyltransferase preparations gave rise to two fucoglycolipids. The faster migrating fucoglycolipid I on the basis of its thin-layer chromatographic mobility, susceptibility to alpha(1 leads to 2) fucosidase from Trichomonas foetus, radio-immunoprecipitation with Ulex europeus lectin and studies with Oh (Bombay) sera was identified as H-active glycolipid (H-I). The most probable structure of fucoglycolipid II should be that with fucose linked alpha(1 leads to 3) to N-acetylglucosamine. Lactosylceramide, ceramide trihexoside and globoside were not substrates for human serum fucosyltransferases. Lacto-N-neotetraosyl ceramide served as a fucose acceptor for all serum preparations tested while asialoganglioside was a substrate only when serum preparations containing H-gene dependent alpha-2-L-fucosyltransferase were used. With asialoganglioside only one radioactive reaction product was formed.

Characterization of three new fucolipids from hog gastric mucosa

Three new fucolioids have been isolated from the water-soluble glycolipid fraction of hog gastric mucosa. Fucolipid A and C exhibited blood-group-A activity, whereas Fucolipid B was not active in A-anti-A, B-anti-B and H-anti-H systems. The structures of these glycolipids were identified by partial acid hydrolysis and methylation analysis, as: (see article)

Identification of a novel hepraglycosylceramide with two fucose residues and a terminal hexosamine

A polar fucose-containing glycosphingolipid fraction isolated from dog small intestine has been characterized by mass spectrometry of intact methylated, and methylated and reduced (LiAlH4) glycolipid. The native fraction, which was homogenous on thin-layer chromatography, was shown after methylation to be a mixture of two compounds. One was identified as a hexaglycoslyceramide with the following composition and sequence: fucose-hexose(fucose)-hexosamine-hexose-hexose-ceramide, with a terminal saccharide structure similar to blood group Leb determinants. The second compound was a novel heptaglycosyceramide with the sequence: hexosamine(fucose)-hexose-tfucose)-hexosamine-hexose-hexose-ceramide. This glycolipid was also detected in human small intestine and pancreas. The dog intestinal fraction had phytosphingosine as its major base and contained almost exclusively 2-hydroxy fatty acids (16 : 0--24 : 0). The fraction of human pancreas differed in having spingosine as its major base and normal fatty acids (16 : 0--24 :0) as major acids.

Main structures of the Forssman glycolipid hapten and a Leb-like glycolipid of dog small intestine, as revealed by mass spectrometry. Difference in ceramide structure related to tissue localization

Two glycolipids of dog small intestine, one with Forssman activity and one with Leb-like activity, have been characterized by mass spectrometry of methylated, and methylated and reduced (LiAlH4) derivatives. The Forssman glycolipid was conclusively shown to be a pentaglycosylceramide with the carbohydrate sequence hexosamine-hexosamine-hexose-hexose-hexose-ceramide, and with sphingosine (dihydroxy base) as major long-chain base and normal fatty acids as the only fatty acids. The Leb-like glycolipid was a hexaglycosyl-ceramide with sequence fucose-hexose-[fucose-] hexosamine-hexose-hexose-ceramide and with phytosphingosine (trihydroxy base) as major long-chain base and only 2-hydroxy fatty acids as fatty acids. The difference of two hydroxy groups in the ceramide between the two glycolipids may be related to a different tissue localization. As shown by immunofluorescense study the Forssman activity was associated with the lamina propria and the Leb-like activity to the glandular epithelium of dog small intestine.

Blood group A active difucosyl glycolipid from hog gastric mucosa

A new difucosyl glycolipid exhibiting blood group A activity was isolated from water-soluble glycolipid fraction of hog gastric mucosa. The structure of this glycolipid was identified by partial acid hydrolysis, sequential degradation with specific glycosidases and methylation analysis, as: "see article".