Lectin Peanut Agglutinin Research Articles

Expression of glycoconjugates in laryngeal cancer

Using the six lectins PNA, SNA, WGA, UEA-1 Amaranthin, and MAA, a cytochemical study was performed to observe the expression of glycoconjugates in squamous cell carcinomas of the larynx in 14 patients and in 3 normal laryngeal epithelia. SNA (Sambucus nigra agglutinin) failed to stain the cytoplasm in normal squamous epithelium of the larynx, but the cytoplasm of the epithelial dysplasia and carcinoma cells reacted to SNA, showing more intensely stained cytoplasma of carcinoma as compared to those of the epithelial dysplasia. PNA (Peanut agglutinin) specifically stained cell membranes of middle layer and basal cells in the normal squamous epithelium and epithelial dysplasias, but in squamous cell carcinomas, a lack of cell membrane staining of various degrees was noted. There was a similarity in the other lectin staining expressions in the normal controls and epithelial dysplasia and carcinoma. The expression of these six lectins was not related to the TNM-classification. Lectin staining may be a useful marker in either early diagnosis of cancer or the assessment of cellular differentiation.

Selective Expression of PNA‐Binding Glycoconjugates by Invasive Human Melanomas: A New Marker of Metastatic Potential

Alterations of cell-surface glycoconjugates have been associated with invasiveness and metastatic capacity in a number of experimental and human tumors (bladder and colon cancer). We have recently shown that human melanoma cells from variants selected for high metastatic potential in an animal model bind the lectin peanut agglutinin (PNA), and that human melanoma cell populations enriched for PNA binding cells generated a higher frequency of metastases when xenografted into immune suppressed neonatal rats. We have therefore sought cells binding PNA in biopsied human melanocytic tumors and compared frequencies of PNA binding by cells from benign nevi, early and late primary melanomas, and metastatic melanomas. Sections of conventionally processed tissues were deparaffinised and exposed to biotinylated PNA; PNA fixation was revealed by the avidine/peroxidase/AEC technique. In 51 specimens tested, PNA appears to react electively with invasive tumors, since only one of the 7 early primary melanomas (Clark I-II) reacted while 13/23 late primary melanomas (Clark III-V), and 4/21 melanoma metastases were reactive. In addition, only 1/17 benign nevi bound PNA. In primary tumors, the reactive cells were exclusively invasive tumors cells in the dermis. PNA reactive material was observed in the cytoplasm and plasma membrane of reactive cells. Hence, alterations in composition and cellular localisation of glycoconjugates detectable by lectin histochemistry in melanoma cells may be markers of metastatic potential that may be applicable on an individual patient basis.

Binding of serum autoantibodies to sialidase-treated tracheal epithelial cells. Determination of autoantibodies isotypes in normal and influenza virus infected guinea pig sera

Cultured epithelial cells isolated from guinea pig trachea were treated with Vibrio cholerae sialidase. The treatment was not cytotoxic and resulted in membrane desialylation as assessed by measurement of sialic acids released, along with an increased fixation of the galactose-specific lectin peanut agglutinin. After incubation in serum from normal guinea pigs, membrane-bound immunoglobulins were detected using peroxidase-labelled antibodies. Sialidase-treated cells bound significantly more IgM than controls (P < 0.0005), whereas binding of IgG was not significantly different between treated and untreated cells (0.1 < P < 0.375); IgA were never detected. In influenza-infected guinea-pigs, as assessed by reactivity with peanut agglutinin, the tracheal and lung epithelium, as well as alveolar cells were hyposialylated. In these animals, the level of serum IgG autoantibodies capable to bind sialidase treated cultured cells increased, while the level of IgM autoantibodies did not change. These autoantibodies may participate in cellular dysfunctions and modified bronchoreactivity that occur during infection of the respiratory tract by sialidase-producing microorganisms, either through activation of the complement system, or subsequently to their reaction with cells expressing membrane complement and/or Fc receptors.

Differential glycosylation of auditory and vestibular hair bundle proteins revealed by peanut agglutinin.

Up to four morphologically distinct types of cross-link are found between the stereocilia in the hair bundles of avian hair cells. These links are involved in mechanotransduction, force transmission across the bundle, and maintenance of hair bundle structure. They appear to be specialisations of the cell coat, but very little is known about their molecular composition. Chick inner ear tissues were therefore screened with a number of different lectins to find markers for specialisations of the hair bundle surface. One lectin, peanut agglutinin (PNA), which recognises the dissacharide Gal beta 1-3GalNAc, was found to be a fairly selective marker for vestibular hair bundles, but it does not stain the stereocilia of auditory hair cells. The staining patterns observed with PNA in the vestibular system closely resemble those seen with a monoclonal antibody (mab) directed against a 275 kD component of the hair cell's apical surface known as the hair-cell antigen (HCA). However, unlike PNA, the mab recognises both vestibular and auditory hair cells. A detailed comparison of the fluorescence staining patterns observed with PNA and the anti-HCA mab indicates that binding sites for both ligands spatially codistribute on the surface of vestibular hair cells. The lectin and the anti-HCA mab binding sites are both sensitive to trypsin treatment, and, with sections of the vestibular system, PNA pretreatment blocks subsequent anti-HCA mab staining. Immunoelectron microscopy of vestibular hair bundles shows that PNA and the anti-HCA mab both label a type of cross-link known as the shaft connector. This link type is present on both auditory and vestibular hair bundles but reacts with PNA only in the vestibular system. The lectin jacalin, which has greater specificity for Gal beta 1-3GalNAc than does PNA, also only labels vestibular and not auditory hair bundles. Although terminal sialic acid residues can block both PNA and jacalin binding, neuraminidase treatment does not unmask cryptic binding sites for these lectins on auditory hair cells but does reveal PNA and jacalin staining at a number of other locations in the inner ear. The results obtained with the lectins PNA and jacalin indicate that either the HCA or other components of the shaft links are differentially glycosylated in the vestibular and auditory epithelia of the bird. The functional significance for such a difference in glycosylation remains to be determined, but auditory and vestibular hair cells operate over different frequency ranges, and variations in glycosylation might confer different micromechanical properties on the hair bundles in these two systems.

Identification of Gal(β1–3)GalNAc bearing glycoproteins at the nodes of ranvier in peripheral nerve

A subset of human anti-GM1 ganglioside antibodies cross-reacts with Gal(beta 1-3)GalNAc bearing glycoproteins in peripheral nerve and spinal cord. The same oligosaccharide determinant is recognized by the lectin peanut agglutinin (PNA) which binds at the nodes of Ranvier in intact peripheral nerve. The Gal(beta 1-3)GalNAc bearing glycoproteins were isolated using PNA lectin affinity chromatography followed by separation on Western blot, and the proteins were subjected to partial amino acid sequence analysis. Two major PNA binding glycoproteins were identified in peripheral nerve and spinal cord; one had an approximate molecular weight of 120 kD and had sequence homology to the oligodendrocyte-myelin glycoprotein (OMgp). The other migrated between 70 and 80 kD and had sequence homology to the hyaluronate binding domain of versican, which has been reported to share sequence homology with the 70 kD proteins hyaluronectin and the glial hyaluronic acid binding protein (GHAP). By immunocytochemistry, OMgp was localized to the paranodal region of myelin, and the protein homologous to the hyaluronate binding domain of versican was localized to the nodal gap in peripheral nerve. These PNA binding glycoproteins might be target antigens for autoantibodies in peripheral nerve.

Mucin-associated T antigens in benign and malignant epithelium of the gall bladder, extrahepatic bile ducts and ampulla of Vater

The mucin-associated antigens Tn, sialosyl-Tn (STn), T and sialosyl-T (STAg) antigens accumulate through aberrant and incomplete glycosylation in malignant epithelial cells. Their diagnostic and prognostic significance in tumours of the colon and cervix has been described, and a possible role for Tn antigen in cell-to-cell adhesion has been suggested. These antigens have been demonstrated through peanut agglutinin (PNA) lectin binding and more recently using specific monoclonal antisera. Differences between the two methods have been described, which may be due to fixation schedules and/or specificity. We have investigated the effect of fixation on the binding of biotinylated PNA lectin and compared its reactivity with the immunoreactivity of monoclonal antisera to Tn, STn, T and STAg antigens in benign and malignant epithelium of the gall bladder, extrahepatic bile ducts and ampulla of Vater. We found that short-term fixation in formol sublimate resulted in poor PNA binding. All other tested fixation schedules showed strong perinuclear binding, similar to that found on cryostat sections. When compared with monoclonal antisera, PNA binding demonstrated the lowest specificity in benign epithelium. In both benign and malignant epithelium, the two methods cannot substitute for each other. STn and STAg antigens were found to be oncodevelopmental throughout the extrahepatic biliary tract. When used in a panel, they are useful as diagnostic markers of malignancy in gall bladder epithelium.

The human blue opsin promoter directs transgene expression in short-wave cones and bipolar cells in the mouse retina.

Transgenic mouse lines were generated using either 3.8 or 1.1 kb of 5' upstream flanking sequence from the human blue opsin gene fused to the lacZ or human growth hormone reporter gene. Mice were analyzed for appropriate cell-specific and developmental expression patterns. In 13 independently derived lines of animals, transgene expression was limited to photoreceptor and inner nuclear layer cells. Photoreceptors were identified as cone cells based on morphological criteria and colocalization of transgene expression with the cone-associated marker, peanut agglutinin lectin. More specifically, transgene-positive photoreceptors were identified as short-wave cone cells (S-cones) by using the short-wave color opsin-specific antibody, OS-2. Reporter-gene-positive cells of the inner nuclear layer were identified as bipolar cells based on morphological criteria. Transgenes and the endogenous mouse short-wave opsin gene were transcriptionally coactivated at embryonic day 13. These results show that 3.8 or 1.1 kb of human blue opsin upstream flanking sequences are capable of directing expression in short-wave cone cells in a spatially and temporally appropriate fashion and that the human blue opsin gene is the homologue of the short-wave-sensitive pigment, S-opsin, in the short-wave cones of the mouse retina. Expression in the bipolar cells may reflect regulatory mechanisms that are common to these cells and to the cone photoreceptors.

Glycoconjugates mark a transient barrier to neural crest migration in the chicken embryo

We report that two molecular markers correlate with a transient inhibition of neural crest cell entry into the dorsolateral path between the ectoderm and the somite in the avian embryo. During the period when neural crest cells are excluded from the dorsolateral path, both peanut agglutinin lectin (PNA)-binding activity and chondroitin-6-sulfate (C6S) immunoreactivity are expressed within this path. Both markers decline as neural crest cells enter. Moreover, both markers are absent after an experimental manipulation that accelerates neural crest entry into this path. Specifically, dermamyotome deletions abolish expression of both markers and allow neural crest cells to enter the dorsolateral path precociously. After partial deletions, dermatome remnants remain. These remnants retain PNA and C6S labeling and impede migration locally. Local glycoconjugate expression thus correlates directly with avoidance responses. Since both PNA-binding activity and C6S expression also typify inhibitory somitic tissues, molecules indicated by these markers (or co-regulated molecules) are likely to inhibit both neural crest and axon advance.

High expresion rate of Tn antigen in metastatic lesions of uterine cervical cancers

The significance of altered expression of MN blood group antigens was examined by studies on the expressions of Thomsen-Friedenreich antigen (T antigen) and Tn antigen in primary and metastatic lesions of 29 human uterine cervical cancers. These antigens were measured by the avidin-biotin-peroxidase (ABC) method with peanut agglutinin (PNA) lectin for T antigen and Vicia villosa agglutinin (VVA) lectin for Tn antigen. Proportion of cancer cells expressing Tn antigen was higher in the metastatic lesions than in the primary tumors in 10 of the 29 cases, less in the metastasis than in the primary tumor in one case, and similar in the primary and metastatic lesions in the other 18 cases. Reaction for Tn antigen was positive in 24 (82.8%) of the 29 metastases, and in 17 (58.5%) of the 29 primary lesions. Thus, the rate of Tn antigen expression was significantly higher in the metastases than in the primary lesions ( P < 0.05). On the other hand, there was no significant difference between the immunoreactivities of T antigen in metastases and primary tumors. These findings support our previous suggestion that expression of Tn antigen is closely related to the metastasis to regional lymph nodes and may reflect an important role of this carbohydrate in the process of metastasis of cervical cancer.

Histochemical markers reveal an unexpected heterogeneous composition of the renal embryonic collecting duct epithelium

The ampullary collecting duct epithelium acts as an inductor in the embryonic and neonatal kidney. It induces the formation of all nephron generations and thus determines the whole architecture of the kidney. As the organ matures, the collecting duct epithelium itself transdifferentiates. The ampullary inductor epithelium, which appears homogeneous as revealed by light microscopy, develops into the well-known heterogeneous epithelium of the mature collecting duct consisting of light principal and dark intercalated cells. Up to now the mechanisms initiating and regulating this transdifferentiation step are unknown. Only very few data are available concerning functional characteristics of the ampullary epithelial cells of neonatal rabbit kidney. Therefore, a characterization of the collecting duct ampullary cells was carried out by means of immunohistological techniques using a set of different monoclonal antibodies and the lectin peanut agglutinin. All epithelial cells within the ampullary tip and neck were positive for cytokeratin 19, an intermediate filament protein. On the other hand, the monoclonal antibody CD 7 revealed a clear cut boundary between the ampullary neck and the ampullary tip region. Furthermore, after incubation with the monoclonal antibody BO-7 specifically reacting with intercalated cells of the mature collecting duct, both labeled and unlabeled cells were observed within the whole ampullary epithelium. These results were confirmed by scanning electron microscopical investigations which revealed two distinct epithelial cell populations. Thus, an unexpected heterogeneity of the ampullary epithelium could be demonstrated.

Characterization of glycoproteins fromChlamydia trachomatisusing lectins

Glycoproteins in Chlamydia trachomatis, serotype L1, elementary bodies were studied by lectin blotting. A panel of 23 lectins representing a variety of sugar specificities was used. The pattern of lectin-binding specificities at a peptide band was studied in order to determine the type and structure of its glycoconjugate. To establish chlamydial origin of the glycopeptide bands in the blot, control samples from non-infected host cell membranes were run in parallel. Terminal mannosidic structures were demonstrated in a 72 kDa glycopeptide (gp72) by its selective binding of Galanthus nivalis lectin (GNA). Sialic acids were found in two chlamydial glycopeptides, gp40 and gp64, which appear to carry O-linked glycoconjugates as they bound the peanut agglutinin (PNA, both gp40 and gp64) and jackfruit lectin (Jac, only gp40). Such structures were also present in other chlamydial glycopeptides. Lectins with specificities for fucose in different links, galactose and N-acetyl glucosamine bound to several chlamydial peptides. On the basis of our results we suggest an alternative mechanism for uptake of chlamydial elementary bodies into host cells, namely phagocytosis mediated by eukaryotic cell surface lectins.

Peanut Agglutinin Lectin Immunohistochemical Staining of Normal and Neoplastic Canine Tissues

Peanut lectin binding sites were demonstrated in normal canine tissues and in 114 canine tumors by avidin biotin complex immunohistochemical staining on unfixed cryostat tissue sections. Peanut agglutinin (PNA) receptors occurred in a variety of normal cells and tissues, including lymphoid follicle center cells; cortical thymocytes; basal cells and the stratum spinosum of stratified squamous epithelium; columnar epithelium of the gastrointestinal tract; parietal cells and chief cells of the stomach; some endothelial cells; myelin; chondrocytes; spermatogenic cells; cells of the adrenal medulla; Bowman's capsule and the distal convoluted tubules of the kidney; prostatic, perianal and endometrial epithelium; and the extracellular matrix of connective tissues. Neoplastic cell staining was sporadic and was most often observed in benign or well-differentiated neoplastic tissues in which the corresponding normal cells also expressed PNA binding sites. However, PNA also bound to some tumor cells in which the analogous normal tissues were unstained, including cells of some fibrosarcomas, rhabdomyosarcomas, hemangiopericytomas and proliferating myoepithelial cells in mixed mammary tumors. Although PNA binding is complex and heterogeneous in canine tissues and does not appear to immunohistochemically detect a moiety associated with neoplastic transformation per se in the majority of canine tumors, the expression of PNA receptors may be associated with neoplastic changes in some mesenchymal cell populations.

The peanut-agglutinin (PNA)-binding surface components of malignant plasma cells.

Plasma cells within bone marrow aspirates from multiple myeloma patients have been shown to be reactive with the lectin peanut agglutinin (PNA). This has been recently exploited by using PNA for purging bone marrow of malignant cells in autotransplantation therapy of the disease. The purpose of this investigation was to isolate and characterize the PNA-binding proteins of myeloma cells. We used the malignant plasma cell-derived line Karpas-620 (K620) as a model, and showed by affinity chromatography, SDS-PAGE, and immunoprecipitation that, among several PNA-binding proteins, a major one is an incompletely sialylated form of CD44. CD44 is a well-known homing receptor protein which is rich in carbohydrate and usually completely sialylated so that it does not react with PNA. We have then examined the PNA reactivity of myeloma cells from different patients and showed a clear difference in the profile of PNA-binding proteins from case to case. Moreover, in contrast to K620 cells, some of the patient plasma cells tested did not have a PNA-binding form of CD44. In conclusion, therefore, we have shown that a number of different proteins participate in PNA binding by malignant plasma cells. Moreover, we have demonstrated a novel, incompletely sialylated form of CD44 on a myeloma cell line. It is known that the level of glycosylation of CD44 and other proteins may affect their function, but how this relates to the malignant behaviour of plasma cells remains to be determined.

Localization of GM1 and Gal(beta 1-3)GalNAc antigenic determinants in peripheral nerve.

Anti-GM1 antibodies in patients with motor neuropathy or motor neuron disease frequently recognize the Gal(beta 1-3)GalNAc epitope, which is shared by several glycoproteins in peripheral nerve. In this study, cholera toxin (CT), which is specific for GM1, and the lectin peanut agglutinin (PNA), which binds to Gal(beta 1-3)GalNAc-bearing glycoproteins, were used in tissue section and intraneural injection studies to examine the distribution of GM1 and Gal(beta 1-3)GalNAc epitopes in human and rat peripheral nerve by epifluorescence and confocal microscopy. In tissue sections, CT stained the compact myelin in both human and rat nerves, whereas PNA was localized at the outer edge of the myelin sheath or Schwann cell membrane. Following intraneural injection into rat sciatic nerves, both CT and PNA bound to the nodes of Ranvier, although CT was concentrated in the paranodal myelin region whereas PNA was concentrated at the nodal gap. These structures may be targets for anti-GM1 antibodies in peripheral nerve.

Development and Fate of Interphotoreceptor Matrix Components During Dysplastic Photoreceptor Differentiation: A Lectin Cytochemical Study of Rod-Cone Dysplasia 1

The autosomal recessive retinal degeneration rod-cone dysplasia 1 ( rcd1) affects Irish setter dogs during early postnatal development. The disease is the result of a cyclic guanosine monophosphate metabolic abnormality and morphological evidence of disease onset correlates with initiation of photoreceptor outer segment formation. Rod photoreceptors are affected earlier and more severely than cones. Postnatal development of specific interphotoreceptor matrix (IPM) constituents was examined in tissue sections and extracted matrix preparations from control and affected dogs using peanut agglutinin (PNA) and wheat germ agglutinin (WGA) lectin cytochemistry. These lectins bind two photoreceptor-specific domains through their affinity for specific terminal carbohydrate sequences present on proteoglycans and glycoproteins in the IPM. Development of rod and cone matrix domains in the normal dog occurs in parallel to the development and differentiation of outer segments (between postnatal days 10 and 60 in the dog); during this period the lectin specificity or distribution in the rcd1 retina did not differ from the normal control. Structural changes of the matrix domains were present and reflected the morphological alterations of the diseased and degenerating photoreceptor cells. Cone domains were present around severely degenerated cone cells as long as these cells were found within the interphotoreceptor space. The matrix domain investing surviving cones did not differ significantly from the normal to indicate an altered binding specificity or structure. The rod domain was still present around rod inner segments in late degeneration. The matrix domains are present in the IPM as long as the photoreceptor cell body remains in the interphotoreceptor space; photoreceptor loss results in disappearance of the matrix. We detected no change in matrix composition or distribution with the lectins used, either during development or degeneration, despite the serious biochemical and structural abnormalities of the photoreceptor cell that are characteristic of the disease.

Regulation of alpha 2,3-sialyltransferase expression correlates with conversion of peanut agglutinin (PNA)+ to PNA- phenotype in developing thymocytes.

Staining of thymus tissue with the plant lectin peanut agglutinin (PNA) is a classic technique for defining the cortical (PNA+) and medullary (PNA-) regions of this tissue. These two regions are primarily composed of immature and mature thymocytes, respectively. Conversion of the PNA+ to the PNA- phenotype has been attributed to masking of the cell surface carbohydrate receptors of PNA by sialic acid during the intrathymic maturation of these cells. We present evidence that the regulated expression of a single glycosyltransferase, a Gal beta 1,3GalNAc alpha 2,3-sialyltransferase, can account for this glycosylation change. This enzyme sialylates the preferred ligand of PNA, Gal beta 1,3GalNAc, forming the sequence NeuAc alpha 2,3Gal beta 1,3GalNAc, thus masking PNA binding sites. Expression of the enzyme is inversely proportional to expression of the PNA receptor, as evidenced by analysis of T-lymphoblastoid cell lines and by in situ hybridization experiments in human thymic tissue.

PNA lectin-based separation of thymocytes into mature and immature subpopulations: CD4-8- double negative cells display characteristics of PNAlo mature thymocytes.

Cortical (immature) thymocytes are widely reported to express intermediate to high levels of receptors for the lectin, peanut agglutinin (PNA). Light-scatter studies of murine fetal thymocytes stained with PNA or anti-mouse CD4 and CD8 monoclonal antibodies indicated, however, that the most immature CD4-8- (DN) thymocyte subpopulation binds levels of PNA commonly described as PNAlo. Evaluation of the PNA binding characteristics of fetal thymocytes negative for the CD8 antigen confirmed the existence of a major population (approximately 20% of total cells) of CD4-8- PNAlo fetal thymocytes. The majority of these DN thymocytes were subsequently found to bind sub-agglutinating levels of PNA, similar to mature CD4+ or CD8+ single positive (SP) thymocytes. Given this information, an immunomodulating compound (2,3,7,8-tetrachlorodibenzo-p-dioxin; TCDD) known to produce a maturational delay in murine thymocytes was tested for a possible concurrent effect on thymocyte PNA lectin binding. A TCDD-induced increase in DN thymocytes was found to be paralleled by an increase of equal magnitude in PNAlo thymocytes. Taken together, these data provide evidence that acquisition of the PNA receptor may be a maturational event occurring during the DN stage of thymocyte ontogeny. Further, these results suggest that separation of thymocytes into mature (medullary) and immature (cortical) subpopulations by PNA agglutination may result in contamination of medullary cells by the most immature (DN) subpopulation of thymocytes.

Amphotericin B-induced carbohydrate changes on the Trypanosoma cruzi surface membrane.

Changes in the cell surface carbohydrates of Trypanosoma cruzi epimastigotes induced by Amphotericin B (AmB) were assessed by chemical methods and by agglutination assay employing a panel of highly purified lectins of various sugar specificities. Escherichia coli K12 with mannose-sensitive fimbriae was also used as an agglutination probe. Amphotericin B caused a decrease in the total carbohydrate content of all glycoconjugate fractions isolated. Exposure to AmB strongly affected the mannose/galactose ratio (1:5) in the CHCl3/methanol/H2O soluble fraction. These sugars in 1.4:1 ratio were the major hexose components of control cells. The decrease in the mannose content (48 to 15%) after AmB treatment agrees with the marked decrease in the T. cruzi cell surface receptors for fimbriated E. coli K12. Also, an increase in the galactose content (74%) as compared with control cells (34%) is in agreement with the peanut agglutinin and Euonymus europaeus lectins agglutination results. Differences in the cell surface carbohydrates induced by AmB could be associated with alterations in the membrane structure and organization.

High progesterone concentrations induce acrosome reaction with a low cytotoxic effect

To determine the optimal conditions to obtain live acrosome-reacted spermatozoa for micromanipulation. Experiments were performed to determine time and dose-dependent effects of calcium ionophore A23187 or steroids on acrosome reaction of fertile donor sperm. The percentages of total reacted and live reacted spermatozoa were assessed with the peanut agglutinin lectin procedure. Incubation with 1 mmol/L progesterone (P) induced 48% +/- 17% acrosome reaction after 6 hours. Motility and viability remained high (49% +/- 3% and 70% +/- 2%, respectively) and thus the percentage of live reacted spermatozoa was 27% +/- 5%. Incubation with A23187 (5 mumol/L for 30 minutes) gave similar results for the percentage of live reacted spermatozoa (26% +/- 4%) but with a lower motility and viability (25% +/- 7% and 53% +/- 2%, respectively; P less than 0.05). These results show that high concentration of P is an effective way to induce acrosome reaction in preparation for micromanipulation.

Quantitative analysis of activated Kupffer cells in viral hepatitis: application of computer image analysis for lectin histochemistry.

Lectin histochemistry revealed that Kupffer cells in the normal liver bound lectins such as Concanavalin A (Con A), Ricinus communis agglutinin (RCA) and Wheat germ agglutinin (WGA), but did not bind Peanut agglutinin (PNA), Dolichos fibflorus agglutinin (DBA), Ulex europaeus agglutinin I (UEA-I) or Soybean agglutinin (SBA). Kupffer cells in viral liver diseases, however, bound the PNA lectin and the binding was specific to Kupffer cells in liver parenchyma. Computer image analysis was performed using light micrographs of sections stained with immunoperoxidase and diaminobenzidine (DAB). The dark brown area of reaction products was detected by analyzing each color component (red, green and blue) in the picture and was expressed as the percent area in the parenchyma. Quantitative analysis revealed the percent area occupied by Kupffer cells positive for the PNA lectin was as follows: acute hepatitis, 2.83 +/- 0.74; chronic persistent hepatitis, 2.51 +/- 0.88; chronic aggressive hepatitis, activity moderate and severe, 4.71 +/- 2.23 and 3.45 +/- 1.84; and liver cirrhosis, 1.96 +/- 0.99. The percent area of Kupffer cells was significantly higher in CAH2A than that in chronic persistent hepatitis or in liver cirrhosis. These results suggest that the PNA lectin could be used as a marker for activated Kupffer cells and that activated Kupffer cells were increased in volume in chronic aggressive hepatitis.