Expression of Lewis histo-blood group glycolipids in the plasma of individuals of Le(a+b+) and partial secretor phenotypes

Red cell Lewis antigens are carried by glycosphingolipids passively absorbed from plasma. Plasma was collected from a spectrum of individuals with normal and unusual Lewis/secretor phenotypes in order to investigate the glycolipid basis for the unusual phenotypes. Samples were obtained from: a Le(a+b–) ABH nonsecretor who secreted Lewis substances; a Le(a+b–) partial secretor; Le(a+b+) partial secretors; Le(a+b+) secretors; and a full range of normal Lewis/secretor phenotypes as controls. The Le(a+b+) samples represented Polynesian, Asian and Réunion Island ethnic backgrounds. Nonacid glycolipids were prepared, separated by thin-layer chromatography, and then immunostained with potent monoclonal antibodies of known specificity. Despite different serological profiles of the Le(a+b–) and Le(a+b+) Polynesian samples, their plasma glycolipid expressions were very similar, with both Le^a and Le^b co-expressed. The copresence of Le^a and Le^b in Le(a+b+) samples is in marked contrast to Caucasians with normal Lewis phenotypes, who have predominantly either Le^a or Le^b. These results suggest that there is a range of the secretor transferases in different individuals, possibly due to different penetrance or to several weak variants. We also show that Lewis epitopes on longer and/or more complex core chains appear to be predominant in the Polynesian Le(a+b+) samples. The formation of these extended glycolipids is compatible with the concept that in the presence of reduced secretor fucosyltransferase activity, increased elongation of the precursor chain occurs, which supports the postulate that fucosylation of the precursor prevents or at least markedly reduces chain elongation.Abbreviations CBA chromatogram binding assay - TLC thin-layer chromatography     

Lewis phenotypes and secretor character in the "Castilla la Nueva"-region (Spain). ABH and Lewis antigen levels in salivary secretion

In 1980 blood and saliva samples were taken from Spanish students of the University of Madrid. Red cells were analysed for A1B2BO and Lewis blood groups. Saliva samples were tested to detect the specific group substances ABH, Lea and Leb. A slightly higher frequency of the "le" gene (0.419) was found in our sample as compared to other Spanish samples. The phenotype frequencies of ABH secretors (77.2%) and non-secretors (22.8%) are in the range of other European populations. The levels of A and B antigens of individuals belonging to these blood groups were similar, whereas the average titration of the H substance showed the relation O greater than A2 greater than A1 greater than A1B greater than B. Analysis of variance proved this heterogeneity to be statistically significant. The amount of Lea substance in non-secretors was higher than in secretors. This shows again that the ABH secretor status has some influence on the quantity of this antigen. The average titration of the Leb substance in secretors was higher than that of Lea in individuals belonging to O, A and AB blood groups, but not in those with blood group B.     

Genetics of plasma concentration of von Willebrand factor.

The plasma concentration of von Willebrand factor (vWf) shows a very wide range in individuals without bleeding disorders. In a twin study we found that 60% of the variance of the plasma concentration of vWf is due to genetic factors. Individuals with AB0 blood group 0 have a lower concentration of vWf than individuals with blood group A, B or AB. Thirty percent of the genetic variance was due to an effect of the AB0 locus. Since the Lewis substances show great structural similarity to the ABH blood group substances we compared the vWf concentration in individuals with and without the Lea antigen on the red cell surface. Individuals lacking the Lea antigen had a lower vWf concentration than individuals who had this antigen. Le(a+b-) people are nonsecretors and Le(a-b+) people are secretors of ABH substance. The lowest vWf concentration was found in blood group 0 secretors. Both the AB0 locus and the Secretor locus may be major loci for the determination of the plasma concentration of vWf.     

Immunochemical and immunohistological expression of Lewis histo-blood group antigens in small intestine including individuals of the Le(a+b+) and Le(a−b−) nonsecretor phenotypes

Histological samples and total non-acid glycosphingolipids were prepared from small intestine of human cadavers with the Le(a+b+) and Le(a–b–) nonsecretor phenotypes and contrasted with the more common Lewis phenotypes. Glycolipid fractions were analysed by thin-layer chromatography and tested for Lewis activity with monoclonal antibodies reactive to Lewis epitopes. Paraffin-embedded small intestine sections were also fluorescently immunostained with anti-Lewis antibodies. Unlike the common Lewis positive phenotypes, we were immunochemically able to demonstrate the copresence of large amounts of Le^a and Le^b glycolipids in the Le(a+b+) sample. In addition we demonstrated increased formation of extended Lewis structures in this phenotype. By immunohistochemistry Le^a, Le^b and type 1 precursor chain epitopes could be demonstrated in the brush border. These results show that the expression of the Le(a+b+) phenotype at the erythrocyte phenotyping level parallels the small intestinal expression of this phenotype, and the patterns of Lewis antigen expressions are unique to this phenotype. By immunohistochemistry and immunochemistry we also demonstrated the presence of trace amounts of Lewis active glycoconjugates in the small intestine of the Le(a–b–) nonsecretor and Le(a+b–) samples. In the Le(a–b–) nonsecretor Le^a and Le^b activity was absent and type 1 precursor was present in brush border, while Le^b activity was immunohistologically demonstrated in the Golgi apparatus of the deep glands. Trace amounts of both Le^a and Le^b glycolipids were identified in this sample. In parallel trace Le^b activity could also be detected in the glycolipids of the Le(a+b–) sample and could be immunohistologically demonstrated to be fully expressed in occasional cells in the deep glands of the small intestine, a pattern quite dissimilar to that of the Le(a–b–) nonsecretor. The results in this paper show that the expression of Lewis glycoconjugates in the small intestine parallel the expression of Lewis erythrocyte phenotypes. However, inappropriate Lewis activity is also seen in individuals of other phenotypes and the mechanisms by which these Lewis antigens are made appears to be different for different phenotypes.Abbreviations FITC fluorescein isothiocyanate - HPLC high-performance liquid chromatography - NeuAc N-acetyl-d-neuraminic acid - RBC red blood cell - TLC thin-layer chromatography - TRITC tetramethyl rhodamine isothiocyanate     

The Le(a+b+) phenotype in Polynesians

The presence of the rare Lewis phenotype Le(a+b+) is reported in various Polynesian groups, including Maoris, Samoans, Cook Islanders, Nuieans and Tokelau Islanders. The phenotype was found in Polynesians of all blood groups and the frequency was significantly increased in group 0 persons. The phenotype was not significantly associated with H reactivity in group A donors and showed no correlation with age or sex.     

Molecular mechanisms of expression of Lewis b antigen and other type I Lewis antigens in human colorectal cancer.

Lewis b (Leb) 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 Leb antigen expression in correlation with the expression of other type I Lewis antigens, such as Lewis a (Lea) and sialylated Lewis a (sLea), in colon cancer cells. Considering the Se genotype and the relative activities of the H and Se enzymes, the amounts of Leb 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 Lebamounts than the H enzyme. In noncancerous colons, the Se enzyme were gradiently expressed in good correlation with the Leb 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 Leb 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 Leb, Lea, and sLea antigens in whole colon tissues, regardless of whether they are noncancerous or cancerous tissues. It suggests that the Se enzyme competes with alpha2,3 sialyltransferase(s) and the Le enzyme for the type I acceptor substrates.     

Enzymatic synthesis of blood-group Lewis-specific glycolipids.

A blood-group Lewis precursor glycolipid was isolated from the plasma of a Lewis-negative individual [Le(a--b--)] and treated with fucosyltransferases from human gastric mucosa and GDP-fucose. Subsequently the glycolipid was adsorbed onto Le(a--b--) erythrocytes and the presence of blood-group Lewis antigens was assessed by passive hemagglutination with anti-Lewis sera. It was shown that the precursor glycolipid was enzymatically transformed to blood-group Lewis a (Lea) and Lewis b (Leb) specific glycolipids. Leb-glycolipid was also synthesized by fucosylation of an isolated Lea-glycolipid. Moreover Le(a--b--) erythrocytes were shown to develop Lea and Leb activities when subjected to enzymatic fucosylation, thus showing that Lewis-negative cells carry blood-group Lewis precursor glycolipid on the surface of their membrane. Le(a + b--) erthrocytes, upon enzymatic fucosylation, acquired Leb activity.     

Expression of Lewis antigenic determinants in colorectal adenocarcinomas

Expression of type 1 and type 2 chain Lewis antigens was studied in 32 rectal adenocarcinoma specimens; the results were correlated with the patients' Lewis phenotype and secretor status. In addition, the pattern of expression of these antigens was analyzed in adjacent and distant normal mucosa. We used an indirect immunofluorescence technique with p-phenylenediamine counterstaining (Oriol technique) and a panel of monoclonal antibodies directed against the different antigenic specificities. Normal distal colonic mucosa only expresses monofucosylated structures (Lea and X) arising from activity of the alpha 1-3,4-fucosyltransferase coded by the Le gene. Rectal adenocarcinomas also show Lea and X, but also reexpress blood group antigens ABH and exhibit difucosylated determinants (Leb and Y). The accumulation of mono- and difucosylated type 2 chain in neoplastic processes, independently of the Le and Se genes, could be due to the enzymes coded by reactivation of the H and X genes. Blood group antigens form a complex signal code, genetically regulated, which intervenes in differentiation, growth and cellular recognition processes, and which may undergo important modifications during malignant transformation. These alterations could be useful in the diagnosis and prognosis of some types of carcinoma.     

Human salivary fucosyltransferases: Evidence for two distinct α-3-L-fucosyltransferase activities one of which is associated with the lewis blood group Le gene

The occurrence of GDP-L-fucose:N-acetyl-β-D-glucosaminyl α-3-L-fucosyltransferase activity in human saliva was independent of Lewis blood group and ABH secretor status except insofar as the mean level of activity was higher in saliva from individuals with an $\text{Le}$ gene than in those whose red cells and saliva grouped as Le(a-b-). In contrast GDP-L-fucose:D-glucose α-3-L-fucosyltransferase activity was detectable in saliva from all Le(a+b-) and Le(a-b+) individuals but was absent from the salivas of Le(a-b-) donors. Isoelectric focusing experiments supported the inference that there are two distinct α-3-L-fucosyltransferase activities in saliva. Both enzymes appear to catalyse the transfer of L-fucose to the C-3 position of N-acetyl-β-D-glucosamine but only the transferase dependent upon the expression of the $\text{Le}$ gene has the capacity to transfer L-fucose to the C-3 position of D-glucose.     

Red cell H-deficient,salivary ABH secretor phenotype of Reunion island. Genetic control of the expression of H antigen in the skin

Based on the genetic model proposing thatH andSe are two structural genes, we predicted that the red cell H-deficient, salivary ABH secretor phenotype should be found on Reunion island, where a large series of H-deficient non-secretor families have been previously described. Two such Reunion individuals are now reported. POU [A_h, Le(a–b+), secretor of A, H, Le^a and Le^b in saliva] and SOU [O_h, Le(a–b+), secretor of H, Le^a and Le^b in saliva]. Both are devoid of H -2-fucosyltransferase activity in serum. In addition, the preparation of total non-acid glycosphingolipids from plasma and red cells of POU revealed the type 1ALe^b heptaglycosylceramide and small amounts of the monofucosylated type 1 A hexaglycosylceramide. Both glycolipids possess an H structure probably synthesised by the product of theSe gene. No other blood group A glycolipids, with types 2, 3 or 4 chains, normally present in the presence of the product of theH gene, were found on red cells or plasma of POU.TheH,Se andLe genetic control of the expression of ABH and related antigens in different tissue structures of the skin is described in 54 H-normal individuals of known ABO, secretor and Lewis phenotypes; in one red cell H-deficient salivary secretor (SOU); and in one H-deficient non-secretor (FRA). Sweat glands express ABH under the control of theSe gene. Sweat ducts express ABH under the control of bothH andSe genes and Lewis antigens under the control ofLe and bothH andSe genes. Epidermis, vascular endothelium and red cells express ABH under the control of theH gene. The products ofH andSe genes are usually expressed in different cells. However, the results illustrate that in some structures, like the epithelial cells of sweat ducts, both the products ofH andSe genes can contribute to the synthesis of the same Le^b structure.     

Isolation, composition and reactivity of the neutral glycoproteins from human meconiums with specificities of the ABO and Lewis systems.

Blood-group-specific A1, B, AB, H and Lea neutral glycoproteins were isolated from suitable pools of human normal meconiums by a preliminary fractionation with a cationic detergent at pH5 and 9 (borate), followed by ion-exchange and gel chromatography. The ABH materials have sedimentation coefficients of about 10S-11S, whereas the Lea preparation, not strictly homogeneous, shows a coefficient of 7S. From the detailed analytical data collected, the following relations are deduced between these various substances; they all possess a common peptide core; there are stable ratios of N-acetylglucosamine/N-acetylgalactosamine in the B, H and Lea materials and of N-acetylglucosamine/galactose in A, H and Lea materials, from which the numbers of A and B determinants are estimated. In the ABH substances, the ratio of glucosamine to the sum of threonine and serine is stable. Presumably because of genetic factors, the amount of fucose varies among the different glycoproteins, but it is always definitely lower than in the average cyst substances. Various serological tests and precipitin methods were used to measure the potency, purity and integrity of the preparations, including comparisons between A1 and A2 substances from this source. The Leb activity did not appear as high as it is in glycoproteins from adults and a possible interpretation would be the immature Lewis system as observed on erythrocytes; this could explain their very strong inhibiting power towards iso-agglutinins. This family of substances with various specificities has common features with that prepared from ovarian cysts, but differs clearly on some points.     

Gene pool of Dagestan ethnic groups: polymorphism of classical gene markers in the Darghin ethnic group

The work is part of a study of the gene pool for Daghestan ethnic groups. In total, 38 alleles and eight genotypes were studied at 14 loci (AB0, Rhesus, P, Lewis, Kell, HP, GC, C'3, TF, 6-PGD, GLO1, ESD, ACP, and PGM1) of immunogenetic and biochemical polymorphic gene systems. A high frequency of allele d of the Rhesus system was observed in all populations examined (0.399-0.474). Among the rare haplotypes of the Rhesus system, we observed CDE in the Degva population, Cde in the Sergokala and Degva populations, and cdE in the Sergokala and Vanashimakhi populations. The typical Caucasian ACP1c allele of the ACP1 locus, which is rather uncommon, was observed at a relatively high frequency in three (Segokala, Vanashimakhi, and Gubden) of the four local populations under study. In the Lewis system, a high frequency of the Le(a+b+) phenotype, which is characteristic of early childhood, was detected in the adult populations of Sergokala and Degva. The rare PGM1v allele of the phosphoglucomutase 1 system (PGM 1) was additionally observed in the Sergokala population. Statistical analysis identified 19 cases where the observed phenotype frequencies significantly differed from the frequencies expected from the Hardy--Weinberg equilibrium.     

Glycosphingolipids of human large intestine: detailed structural characterization with special reference to blood group compounds and bacterial receptor structures

Non-acid glycosphingolipid expression was studied in the large intestines from four individuals with the A1Le(a-b+), BLe(a-b+), and OLe(a-b+) blood group phenotypes. In the A1Le(a-b+) case, specimens were taken from the ascending and sigmoid parts of the large intestine in order to compare the expression of glycolipids in the proximal and distal regions of the intestine. In one blood group OLe(a-b+) individual, epithelial cells were isolated from the residual stroma to compare the glycolipid compositions in these two tissue compartments. GlcCer, GalCer, LacCer, Gb3Cer, and Gb4Cer were the major compounds in all three individuals, as shown by mass spectrometry, proton NMR spectroscopy, and degradation studies. The Lea-5 glycolipid was the major complex blood group glycolipid in all individuals, except in the proximal ascending part of the large intestine of the A1Le(a-b+) case, in which the Leb-6 glycolipid was predominant. There were trace amounts of blood group ABH glycolipids, in agreement with the ABO blood group phenotypes of the donors, Lewis antigens with more than six sugar residues in the carbohydrate chain, and blood group X and Y glycolipid antigens. The epithelial cells were dominated by monoglycosylceramides and the Lea-5 glycolipid, while only trace amounts of di-, tri-, and tetraglycosylceramide structures were present. No reactivity was seen in the epithelial cell fraction with Gal alpha 1-4Gal specific Escherichia coli, anti-Pk, or anti-P antibodies, indicating the absence of the glycolipid-borne Gal alpha 1-4Gal sequence in human large intestinal epithelial cells.     

侗族九个红细胞血型系统和ABH分泌型的分布

报道了广西侗族的ABO、MNSs、Rhesus、Duffy、Kidd、P、Diego、Lewis和Xg等九种红细胞血型系统和ABH唾液分泌型的分布。共调查了201名父母均系侗族而彼此无血缘的学生,其中男116名,女85名。结果表明,广西侗族中ABO系统的r基因(0.6286)、MN系统的m基因(0.6294)、Duffy系统的Fy~a基因(0.9651)、Kidd系统的JK~a基因(0.4628)和Rhesus系统的CDe染色体(0.7532)等频率都很高,ABO系统的q基因(0.1672)、P系统的P_1基因(0.1333)和Lewis系统的Le~a基因(0.3232)等频率较低。MNSs系统的S基因(0.0124)频率很低,而MS染色体连锁率却为零。Xg系统的Xg~a基因频率(0.3746)与汉族和维吾尔族一样,处于低水平。Lewis系统的Le(a )表型者中发现八例是ABH唾液分泌型,但分泌的物质不是A便是B,而分泌H物质的唾液分泌型者全部都是Le(a-)型。六个民族间遗传距离分析表明,侗族与壮族在血缘上最近,其次是与朝鲜族、蒙古族、汉族相近,而与维吾尔族最远。     

Glycolipids of human large intestine: difference in glycolipid expression related to anatomical localization, epithelial/non-epithelial tissue and the ABO, Le and Se phenotypes of the donors

Human large intestine specimens were obtained during elective surgery from donors of known blood group ABO, Lewis and secretor phenotypes. The intestinal epithelial cells were isolated from the non-epithelial tissue in one case and in another case mucosa tissue was obtained by scraping. Total non-acid glycolipid and ganglioside fractions were isolated from the tissue specimens, analyzed by thin-layer chromatography and detected by chemical reagents and autoradiography after staining the plate with various blood group monoclonal antibodies and bacterial toxins. The amount of non-acid glycolipids present in the large intestine epithelial cells was 3.9 micrograms/mg of cell protein and in the non-epithelial tissue 0.39 mg/g dry tissue weight. The epithelial cells contained monoglycosylceramides and blood group Lea pentaglycosylceramides as major compounds together with small amounts of diglycosylceramides. In addition, trace amounts of tri- and tetra-glycosylceramides together with more complex glycolipids were present. The non-epithelial tissue contained mono-, di-, tri- and tetra-glycosylceramides as major non-acid components. Blood group ABH glycolipids were present in trace amounts in the non-epithelial part of the large intestine. Lea pentaglycosylceramide was the major blood group glycolipid present in all Le-positive individuals independent of the secretor status. Leb glycolipids were present in trace amounts in secretor individuals but completely lacking in non-secretors. Trace amounts of X antigens were found in all individuals, while Y antigens were only present in secretor individuals. The Lea, Leb, X and Y glycolipids were located in the epithelial cells. The gangliosides were present mainly in the non-epithelial tissue (65-350 nmol of sialic acid/g dry weight) and only trace amounts (less than 0.014 nmol/mg of cell protein) were found in the epithelial cells. The major gangliosides of the non-epithelial tissue were identified as GM3, GM1, GD3, GD1b, GT1b and GQ1b. In addition, several minor gangliosides were also present. Binding of cholera toxin to the thin-layer plate revealed trace amounts of the GM1 ganglioside in the epithelial cell ganglioside fraction.     

Non-acid glycosphingolipid expression in plasma of an A1 Le(a-b+) secretor human individual: identification of an ALeb heptaglycosylceramide as major blood group component.

Total non-acid glycosphingolipids were isolated from plasma of an A1 Le(a-b+) secretor individual with Refsum's disease (phytanic acid storage disease). The glycolipids were separated into 11 fractions by open column chromatography and by HPLC. The fractions were analyzed by thin-layer chromatography and tested for different blood group A activities as well as blood group Le(a )and Leb activity. The fractions were structurally characterized by proton NMR spectroscopy and FAB mass spectrometry and in selected cases by EI mass spectrometry of the permethylated and permethylated-reduced derivatives. Degradation analysis was performed on partially permethylated or permethylated-reduced alditol acetates. The dominating blood group compound was found to be a blood group A active type 1 chain difucosylheptaglycosylceramide. Other blood group compounds were identified as a blood group A active type 1 chain monofucosylhexaglycosylceramide, a blood group Leb hexaglycosylceramide, a blood group H active type 1 chain pentaglycosylceramide, and a globotetraosylceramide (the P-antigen). The presence of a Le(a) glycosphingolipid and blood group A type 3/4 chain structures were also found by immunostaining. Glucosyl-, lactosyl-, and globotriaosylceramides were the dominating short chain compounds. The amount of phytanic acid incorporated into the monoglycosylceramide fraction was found to be less than 5% of the fatty acids.     

Complementation of N-hydroxyethyl-N-chloroethylnitrosourea hypersensitivity of Mex- cells by microinjection of mRNA from Mex+ cells

Chinese hamster ovary (CHO-9) and HeLa MR cells lack detectable amounts of O6-alkylguanine DNA alkyltransferase (phenotypically Mex-) and are hypersensitive to the toxic effect of N-hydroxyethyl-N-chloroethylnitrosourea (HeCNU), as compared to Mex+ derivatives. Microinjection of size-fractionated polyA+ mRNA extracted from HeLa S3 (Mex+) into CHO-9 and HeLa MR cells, or from ataxia telangiectasia (Mex+) into HeLa MR cells, gave rise to an increase in survival following treatment with toxic doses of HeCNU. Transient complementation of the Mex- phenotype was achieved with an RNA population 0.8-1 kb in size.     

Leb-active glycolipid in human plasma: Measurement by radioimmunoassay

A radioimmunoassay that measures Le^b-active glycolipids in human plasma has been developed using antiserum from a goat immunized with a Le^b blood group hapten, lacto-N-difucohexaose I, conjugated to polylysine. Binding by the antiserum of lacto-N-difucohexaose I conjugated to ¹²⁵I-labeled bovine serum albumin is specifically inhibited by Le^b-active ceramide hexasaccharide. Plasma levels of the glycolipid are quantitated by comparing the inhibitory activity of plasma with that of the purified Le^b-active glycolipid. Plasma samples from 35 blood group O Le(a ? b +) individuals contain Le^b-active ceramide hexasaccharide at an average concentration of 0.9 μg/ml (range: 0.2 to 2.5 μg/ml); no Le^b-active glycolipid (less than 0.02 μg/ml) could be detected in plasma from blood group O Le(a + b?) or O Le(a? b?) individuals. Plasma from A₁ Le(a ? b+) individuals contains less Le^b-active glycolipid than plasma from A₂ Le(a? b+) individuals: its level in 19 samples of A, Le(a? b+) plasma averages 0.2 μg/ml (range: 0.1 to 0.45 μg/ml), and its level in 9 samples of A₂ Le(a? b+) plasma averages 1.1 μg/ml (range 0.8 to 1.3 μg/ml). About one-third of the total Le^b-active glycolipid in whole blood is associated with erythrocytes and the rest is found in plasma.     

Qualitative difference of subcellular localization of tumor-associated carbohydrate (Le(x)) antigens in renal cell carcinoma and normal kidney.

Renal cell carcinomas are immunohistochemically positive for oligosaccharides with the Le(x) determinant (Gal beta 1----4[Fuc alpha 1----3]GlcNAc) and its derivatives, as oncofetal antigens, and their expression is closely related to a better prognosis of the patients. This study was designed to clarify the difference in antigen localization at the ultrastructural level between renal cell carcinoma and normal tissues. In normal kidneys, Le(x) detected by monoclonal antibody (MAb) FH 2 and sialylated extended Le(x) (sialyl Le(x)-i) by MAb FH 6 were identified along the plasma membrane of microvilli of proximal tubule epithelial cells, with occasional immunoreactivity along the basolateral plasma membranes. Intracellular localization was very sparse. Renal cell carcinoma showed localization of Le(x) and sialyl Le(x)-i antigens along the cell membrane and in the cytosol as aggregates or filaments. Immunoreactive materials were also observed in the lumen formed among carcinoma cells. The cytosolic immunoreactivity, not observed in the normal kidney, was regarded as "abnormal cytosolic accumulation" of the antigens. This pattern was more pronounced in clear-cell carcinoma. Pretreatment of specimens with chloroform-methanol, which extracts glycolipids, decreased immunoreactivity in carcinoma tissues, particularly that in the cytosol. The extracts contained substances immunoreactive for MAb FH6. Our study has demonstrated that (a) remarkable changes occur in the ultrastructural localization patterns of sialyl Le(x)-i and Le(x) in renal cell carcinoma and (b) considerable amounts of glycolipids are contained in the substances with sialyl Le(x)-i deposited in the cytosol of clear-cell carcinoma.     

Genetic transformation of somatic cells. VIII. The effect of the DNA methylation inhibitor 5-azacytidine on the stability of thymidine kinase-negative and -positive phenotypes of transformant clone cells

A study was made of the effect of an DNA methylation inhibitor 5-azacytidine (azaC) on the frequency of reversion to a thymidine kinase-positive (TK+) phenotype in 5-bromodeoxy-uridine (BrdU)-resistant subclones obtained from clones of Chinese hamster cells transformed by thymidine kinase gene (tk-gene) of Herpes simplex virus type 1 (HSV1). It is shown that in 8 of 15 BrdU-resistant subclones azaC increases 2-1000-fold the frequency of reversion to TK+ phenotype. Variations in the inducibility of reversions to TK+ phenotype indicate that the DNA methylation associated with TK- phenotype affects but differently tk gene of HSV1. Cultivation of TK+ cells of transformant clones in the presence of azaC may lead to stabilization (or decrease in the rate of the loss) of TK+ phenotype, or may not influence the stability of transformant phenotype. The reaction of TK+ cells of transformant clones depends both on genetically determined rate of the loss of TK+ phenotype, and on the structure of transforming DNA introduced to cells. A conclusion is drawn that the TK- phenotype of transformant clone cells arises due to processes which are not associated with methylation of tk gene of HSV1 in spite of the fact that such a methylation may later stabilize significantly the TK- phenotype.