Dolichos biflorus agglutinin (DBA) reacts selectively with mast cells in human connective tissues

B4GALNT2 and xenotransplantation: A newly appreciated xenogeneic antigen

Analysis of non‐Gal antibody induced after pig‐to‐baboon cardiac xenotransplantation identified the glycan produced by porcine beta‐1,4‐N‐acetyl‐galactosaminyltransferase 2 (B4GALNT2) as an immunogenic xenotransplantation antigen. The porcine B4GALNT2 enzyme is homologous to the human enzyme, which synthesizes the human SDa blood group antigen. Most humans produce low levels of anti‐SDa IgM which polyagglutinates red blood cells from rare individuals with high levels of SDa expression. The SDa glycan is also present on GM2 gangliosides. Clinical GM2 vaccination studies for melanoma patients suggest that a human antibody response to SDa can be induced. Expression of porcine B4GALNT2 in human HEK293 cells results in increased binding of anti‐SDa antibody and increased binding of Dolichos biflorus agglutinin (DBA), a lectin commonly used to detect SDa. In pigs, B4GALNT2 is expressed by vascular endothelial cells and endothelial cells from a wide variety of pig backgrounds stain with DBA, suggesting that porcine vascular expression of B4GALNT2 is not polymorphic. Mutations in B4GALNT2 have been engineered in mice and pigs. In both species, the B4GALNT2‐KO animals are apparently normal and no longer show evidence of SDa antigen expression. Pig tissues with a mutation in B4GALNT2, added to a background of alpha‐1,3‐galactosyltransferase deficient (GGTA1‐KO) and cytidine monophosphate‐N‐acetylneuraminic acid hydroxylase deficient (CMAH‐KO), show reduced antibody binding, confirming the presence of B4GALNT2‐dependent antibodies in both humans and non‐human primates. Preclinical xenotransplantation using B4GALNT2‐deficient donors has recently been reported. Elimination of this source of immunogenic pig antigen should minimize acute injury by preformed anti‐pig antibody and eliminate an induced clinical immune response to this newly appreciated xenotransplantation antigen.

Effect of horse gram lectin (Dolichos biflorus agglutinin) on degranulation of mast cells and basophils of atopic subjects: identification as an allergen

Horse gram (Dolichos biflorus) is widely consumed in the tropical south Asian countries including rural areas of India. Since D. biflorus agglutinin (DBA) is an important dietary lectin in horse gram, we have studied its effect on the degranulation of mast cells and basophils of atopic subjects. Allergy to horse gram lectin has not been reported so far. Skin prick test (SPT) was performed with 100 microg/mL of DBA. DBA-specific IgE was detected by dot-blot, and ELISA. Histamine release (HR) assay was carried out using leukocytes from non-atopic and atopic subjects, and rat peritoneal exudate cells. Among the atopic group, 10 of 48 subjects (21%) were found to be positive for DBA by SPT, and none were positive in the non-atopic group (n=20). Two subjects out of the ten who tested positive for DBA by SPT were found to be sensitized to DBA as revealed by the presence of specific IgE by ELISA and dot-blot. The HR was found to be 2- to 3-fold higher in DBA-allergic subjects than in non-atopic and atopic subjects. Basophil HR by DBA was found to be similar in both non-atopic and atopic subjects. However, DBA induces activation of mast cells in vivo in a sub-population (21%) of atopic subjects. Two subjects have been identified as having food allergy to horse gram based on the presence of DBA-specific IgE with a positive correlation to basophil HR. This is the first report of food allergy to horse gram, and DBA has been identified as an allergen.

Lectin histochemistry of normal human lung

This study aimed to identify and specify the glycotypes of cell populations in normal human lung including types I and II pneumocytes, alveolar macrophages and mast cells, and also in the larger tissue structures of lung, including blood vessels and bronchi/bronchioles, using lectin- and immuno-histochemistry on paraffin-embedded tissue from 11 normal cases. The alveolar macrophages were anti-CD68 positive whereas the cells lining the alveolar walls were positive for cytokeratins. The alveolar macrophages in normal lung tissues showed a broad spectrum of staining for different subsets of N-linked saccharides, N-acetylgalactosamine, N-acetylglucosamine, terminal beta-D-galactose and sialyl groups. This study showed that some lectins could be used as specific markers for some cell types i.e. Galanthus nivalis and Narcissus pseudonarcissus lectins for macrophages, Psophocarpus tetragonolobus lectin-II for capillary endothelium, Dolichos biflorus agglutinin for bronchial epithelial cells, Lycopersicon esculentum, Phytolacca americana or Triticum vulgaris (succinylated) for type I pneumocytes and Hippeastrum hybrid or Maclura pomifera lectins for type II pneumocytes. Patchy staining of type I pneumocytes by peanut agglutinin indicated the possibility of two distinct populations of these cells or a pattern of differentiation that is unapparent morphologically.

Culture and characterization of human junctional epithelial cells

This study was undertaken to establish a culture of junctional epithelial cells derived from gingival tissue attached to the tooth surface and to characterize these cells immunocytochemically and ultrastructurally. Primary cultures of cells were obtained from the junctional tissue explanted on type I collagen-coated dishes and immersed in Dulbecco's modified Eagle's medium containing 10% fetal bovine serum (FBS). Cells were subcultured with conditioned serum-free keratinocyte medium (keratinocyte-SFM + 5% FBS) on dishes coated with solubilized extract of the basement membrane. After 24 hours, the medium was changed to keratinocyte-SFM (0.09 mM Ca2+). The cell-doubling time was 40.5 hours. As a control, cells from gingival tissue were cultured by the same method. Cells from junctional tissue and gingival tissue were compared immunocytochemically using monoclonal antibodies to keratin, vimentin, and desmoplakins I and II and using Dolichos biflorus agglutinin (DBA). The keratin AE1 and AE3 was expressed by all of culture cells. The vimentin (specific for the intermediate filament of mesenchymal cells) was also expressed by all cells. The expression pattern of keratin 19 was observed not only by cells from junctional tissue but also by cells from gingival tissue. All keratin peptides were expressed in both cells. However, DBA reacted only with cells from the junctional tissue. Anti-desmoplakin I and II reacted with both cells, however, the staining patterns differed. DBA-positive cultured epithelial cells from the junctional tissue showed poor tonofilament bundles and were rich in cytoplasmic organelles. These findings suggest that junctional epithelial cells can be isolated from junctional tissue and cultured under improved conditions.

Changes in expression of the oligosaccharides in the human fetal skin

Lectin histochemistry was used to investigate the glycoconjugate saccharidic moieties in the skin of human fetuses ranging in age from the 8th to the 13th week of gestation. For this purpose, seven HRP-conjugated lectins were employed (Con A, WGA, PNA, DBA, SBA, UEAI and LTA). The distribution and changes of the sugar residues of glycoconjugates at the level of the various layers of the fetal epidermis, as well of the underlying mesenchyme were studied. We have shown that UEAI reactivity is a characteristic finding of the cells of the intermediate layer at the 11th and 12th week of gestation. LTA reactivity was detected only at the free border of the peridermal cells from the 10th to the 13th week of gestation. We demonstrated the presence of PNA binding sites at both the basal and peridermal cells from the 8th week of gestation, whereas other authors have stated that the appearance of PNA reactivity coincides with the onset of fetal skin stratification (11th-12th week of gestation). Moreover, some typical features in lectin reactivity at the level of the mesenchymal cells and fibres have been pointed out.

A role for mast cells in the progression of Duchenne muscular dystrophy? Correlations in dystrophin-deficient humans, dogs, and mice

Dystrophin deficiency has been shown to be the underlying cause of Duchenne muscular dystrophy. Although dystrophin-deficient homologous animal models have been identified (dog, mouse, and cat), the clinical expression of the biochemical defect is species-specific. Thus, while the genetics and biochemistry of Duchenne dystrophy is understood, the pathophysiological cascade leading to muscle weakness in only humans and dogs remains obscure. To begin to dissect the pathophysiology at the histological level, we undertook a systematic study of mast cells in normal and dystrophin-deficient muscle. Mast cells have been implicated in the development of fibrosis in other disorders, and progressive fibrosis has been hypothesized to mediate the failure of muscle regeneration in human and dog dystrophin deficiency. Our results show a strong correlation between mast cell content and localization, and the clinico-histopathological progression in humans, dogs and mice. The mast cell increases were disease specific: other dystrophic myopathies with normal dystrophin generally did not show substantial increases in mast cell content or degranulation. Our data suggest that mast cell accumulation and degranulation may cause the grouped necrosis characteristic of dystrophin deficiency in all species.

Isolation, identification and quantitative evaluation of specific cell types from the mammalian gastric mucosa

Functional in vitro studies with isolated gastric mucosal cells require cytological identification of different cell types in suspension or primary culture. Since suitable techniques have not been well established, different staining methods for the discrimination of dispersed pig and guinea pig gastric cells have been developed on the basis of modified previous protocols for enzymatic cell dispersion. Chief and parietal cells were visualized by combined periodic acid-Schiff stains. Surface mucous and mucous neck cells were identified by affinity-labelling, using lectins with selective staining properties in situ. Two of the lectins were found to be specific markers for gastric polymorphonuclear cells. The following vital tests were found to be useful: succinic dehydrogenase for parietal cells, Nile blue/brilliant cresyl blue stains for chief cells, and different phagocytosis assays for endothelial cells and gastric phagocytes. Endocrine cells were characterized by immunocytochemistry using specific antibodies against gastrin, somatostatin, histamine and serotonin. The same technique using a vimentin antibody was performed for the identification of fibroblasts. Proliferation of mucosal cells in primary culture was monitored by the incorporation of bromo-deoxyuridine, which was subsequently detected by a monoclonal antibody.

Histochemical and cytochemical localization of blood group antigens

The oligosaccharide structures of blood group antigens are not the primary gene products; they are constructed in a stepwise manner by adding particular sugar to precursor oligosaccharides via several glycosyltransferases coded for by different blood group genes (Watkins 1966, 1978, 1980). Consequently, final profiles of antigens expressed in each cell type are influenced by many different factors such as the intrinsic composition of glycosyltransferase species which are defined by the genotype of the individuals, relative activity or amount of these enzymes (repression, derepression or induction of the enzymes), competition between enzymes with overlapping substrate specificity, the organization of the enzymes in membranes, utilizability of precursors and specific substrate sugars, and the activity level of degradating enzymes. Changes in the antigen profiles during maturation, differentiation and malignant transformation are thought to be intimately related to the variability of these factors. Although great importance attaches to histo- and cytochemical information on the distribution and levels of glycosyltransferases and messenger RNA corresponding to the relevant enzyme, detailed and precise localization of the blood group antigens and their variants is the base line for analyzing these complex factors. On the basis of individual genotype and histochemical findings about the antigen distribution and the interrelationship between cells and cellular components producing different antigenic structures (cellular and subcellular mosaicism), we can deduce precursor oligosaccharide levels as well as the status of gene activation and its primary product, glycosyltransferases. Thus, these findings are a prerequisite for further analysis at the molecular genetic level. As emphasized in this article, lectin staining or immunostaining methods with MAbs combined with glycosidase digestion procedures are powerful tools for in situ analysis of carbohydrate structures in histochemical systems. Although in some cases valuable results have been obtained by applying the technique, our knowledge concerning the distribution of complex carbohydrate structures is still far from satisfactory. Along with well defined MAbs and lectins, the key to developing our methods further is successful introduction of glycosidases, in particular, endoglycosidases since these reagents are indispensable for analyzing the inner core structures and glycoconjugate species of the blood group antigens. Application of these techniques at the ultrastructural level is an alluring possibility, even though many difficulties must be overcome. Although their functional roles have not yet been determined, a diverse array of macromolecules is known to be decorated with blood group-related antigens.(ABSTRACT TRUNCATED AT 400 WORDS)

Lectin binding patterns of human tissue mast cells indicate marked phenotypical diversity

Glycoconjugate expression by human tissue mast cells (MCs) from various sources (including lymph nodes with signs of chronic non-specific lymphadenitis, skin lesions of urticaria pigmentosa, and bone marrow infiltrates associated with systemic mastocytosis) was studied histochemically with a broad panel of fluorescein-labelled lectins. Of the 19 lectins applied, 11 (sugar specificities: fucose, N-acetylgalactosamine and neuraminic acid) did not stain any MCs, while 8 (sugar specificities: mannose, N-acetylglucosamine, and galactose) were found to bind to MCs. These lectins exhibited different binding patterns in various disease entities. Only a few of these 8 lectins (in particular, phythaemagglutinin-L) produced strong staining of the MCs in most or all of the cases. Some (e. g. phythemagglutinin-E) produced only weak staining, and this in only a few cases. The lectins used, however, did not distinguish between reactive and tumorous MCs. Although lectins are therefore unlikely to be of use in resolving problems of differential diagnosis concerning proliferation of MCs, our investigation has shown that tissue MCs exhibit marked phenotypical diversity with regard to their lectin-binding properties.

Difference in the ability of blood group-specific lectins and monoclonal antibodies to recognize the ABH antigens in human tissues

Twelve different kinds of blood group-specific lectins have been used along with monoclonal anti-A, -B and -H antibodies for detecting the corresponding antigens in selected human tissues. Although most of the lectins recognized the antigens in the tissue sections examined, they displayed marked differences in their recognition patterns in certain tissues. Helix asparsa agglutinin (HAA), Helix pomatia agglutinin (HPA) and monoclonal anti-A antibody recognized A antigens in the mucous cells of salivary glands from blood group A or AB nonsecretor as well as secretor individuals, whereas Dolichos biflorus agglutinin (DBA), Griffonia simplicifolia agglutinin-I (GSA-I), Sophora japonica agglutinin (SJA) and Vicia villosa agglutinin (VVA) did not bind to them from nonsecretors. A antigens in endothelial cells, lateral membrane of pancreatic acinar cells and small mucouslike cells of submandibular glands from some individuals were likewise recognized by HAA and HPA but not by other blood group A-specific lections. In contrast, both HAA and HPA did not recognize the A antigens in mucous cells of Brunner's glands while other A-specific lectins and monoclonal anti-A antibody reacted specifically with the antigens. Such a difference was not observed with lectins specific for blood group B. However, the B antigens in Brunner's glands were recognized by these lectins but not with monoclonal anti-B antibody. The difference in labelling ability was also noted among the blood group H-specific lectins and monoclonal anti-H antibody in endothelial cells of blood vessels. Ulex europaeus agglutinin-I reacted with these cells irrespective of ABO and the secretor status of the individuals, while Anguilla anguilla agglutinin and monoclonal anti-H antibody reacted only with those cells from blood group O individuals. No reaction was observed with Lotus tetragonolobus agglutinin in these tissue sites. These results suggest a great diversity of blood group antigens in different human tissues.

Mast cells in neuromuscular diseases

The lectin Dolichos biflorus agglutinin has been used to identify mast cells in normal skeletal muscle and to investigate changes in their number in a wide range of human neuromuscular diseases and in rat muscle damaged by the local anaesthetic bupivacaine. Few mast cells were found in the perimysium of normal skeletal muscle but numbers were increased in human muscle biopsies which showed necrosis and regeneration of fibrosis. In bupivacaine-induced muscle damage, increased mast cell counts occurred during the necrotic phase and particularly during the phase of active regeneration. In addition, increased numbers of mast cells were observed in the underlying histologically normal muscle. These results show that mast cells are influenced by pathological changes in skeletal muscle and, in view of the known functions of mast cells in other tissues, it is possible that they are capable of modulating disease processes in muscle.

Binding of the blood group-reactive lectins to human adult kidney specimens

The binding of a panel of blood group-reactive lectins to frozen sections of human kidney was studied with a special emphasis on reactivity with endothelia and basement membranes. The blood group A-reactive lectins, all specific for alpha-D-N-acetylgalactosamine (GalNAc), Helix aspersa (HAA), Helix pomatia (HPA), and Griffonia simplicifolia I-A4 (GSA-I-A4) agglutinins bound to the endothelium in specimens with blood groups A and AB. In other samples, these lectins reacted predominantly with tubular basement membranes, as well as with certain tubules. Both Dolichos biflorus (DBA) and Vicia villosa agglutinins (VVA), reported to react with blood group A1 substance, failed to reveal endothelia in most specimens, but bound differently to tubules in all blood groups. The blood group B-reactive lectins, specific for alpha-D-galactose (alpha-Gal) or GalNAc, respectively, GSA-I-B4 and Sophora japonica agglutinin (SJA), bound to the endothelia in specimens from blood group B or AB and in other specimens bound only to certain tubules. Among the blood group O-reactive lectins, specific for alpha-L-fucose (Fuc), Ulex europaeus I agglutinin (UEA-I) conjugates, but not other lectins with a similar nominal specificity, bound strongly to endothelia in specimens with blood group O. The UEA-I conjugates bound distinctly more faintly to endothelia in specimens of other blood groups. The present results indicate that lectins, binding to defined blood group determinants, react with endothelia in specimens of the respective blood group status. Furthermore, they suggest that basement membranes and some tubules in the human kidney show a distinct heterogeneity in their expression of saccharide residues, related to their blood group status.

Dolichos biflorus agglutinin (DBA) reveals a similar basal cell differentiation in normal and psoriatic epidermis

Binding of N-acetyl galactosamine (GalNAc)-specific Dolichos biflorus agglutinin (DBA) conjugates to frozen sections of normal epidermis and of psoriatic uninvolved and lesional skin was studied in fluorescence microscopy. The DBA conjugates bound only to single basal cell layer in normal and uninvolved psoriatic epidermis from patients with different blood group status. In the lesional area of psoriatic skin a similar reaction with a single basal cell layer was revealed. Other lectin-conjugates applied, presenting also GalNAc specificity, reacted with most cell layers of normal and both uninvolved and lesional psoriatic epidermis and gave an attenuated reaction with the middle epidermal layers. The results show that the basal cell characteristics are confined only to the cells along the basal membrane also in psoriatic epidermis, although cells in three lowest layers may be able to proliferate.

The use of lectins in histopathology

Lectins are proteins and glycoproteins extracted predominantly from plants which have the capacity to bind sugars specifically. This property makes them of interest for histopathology since they will bind to saccharides forming parts of glycoproteins and glycolipids of tissue constituents. Lectins have and can be used as reagents for mucin histochemistry, to identify specific cells, in the recognition of glycoprotein alterations in disease states, in studies of infectious diseases, and in the assessment of glycoconjugate alterations occurring with malignancy. They can be used for both light microscopic and ultrastructural localisation and various methods are available. It is important though, to consider the nature of the glycoconjugates under study and select lectins appropriately because of their varying specificities and binding characteristics. A panel of lectins should be used to study a particular configuration. Care should be taken with tissue fixation and processing. It must be remembered that an open and critical mind should be kept concerning interpretation of results. At the present time lectins have a limited value diagnostically, but the binding of Ulex europeus agglutinin to endothelium is certainly of value.

Saccharide residues in human gingiva as revealed with fluorochrome-coupled lectins

The histochemical binding of 16 fluorochrome-conjugated lectins to human marginal gingiva was investigated. Of a total of 14 galactose/N-acetylgalactosamine (Gal/GalNAc)-specific lectins, Dolichos biflorus (DBA), Helix pomatia (HPA), and Helix aspersa agglutinins (HAA) were blood group A-reactive whereas Griffonia simplicifolia I-B4 (GSA-I-B4) and Sophora japonica (SJA) agglutinins were blood group B-reactive. HPA, HAA and GSA-I-B4 bound to all suprabasal epithelial cells and to vascular endothelia in tissues with compatible blood groups and detected only upper epithelial cells in tissues lacking the respective blood group antigens. SJA, on the other hand, bound to suprabasal epithelial cells and to endothelial cells in specimens from blood group B, AB and A individuals. DBA gave a heterogeneous labeling of upper epithelial cells in blood group A, AB and B specimens but not in O specimens and did not react with endothelia in any of the tissue samples. DBA bound, instead, consistently to mast cells in gingival lamina propria. Of the other Gal/GalNAc-reactive lectins, 2 bound to suprabasal epithelial cells and 7 to all viable cell layers in gingival epithelium. The binding of these lectins was blood group-independent. Of the fucose-specific lectins, Ulex europaeus agglutinin I (UEA-I) gave an intense suprabasal cell membrane-type of epithelial fluorescence in blood group O specimens and a more diffuse staining in other specimens and recognized endothelial cells in a blood group-independent way. Anguilla anguilla agglutinin (AAA) gave a blood group-independent epithelial staining and bound heterogeneously to endothelial cells only in blood group O samples.(ABSTRACT TRUNCATED AT 250 WORDS)