Lectin-binding glycoconjugates in Paramecium primaurelia: changes with cellular age and starvation

 Lectins with different sugar specificities and binding to phagosome-lysosome systems as well as cell surface constituents were used to study glycoconjugate variation throughout culture and clonal life in Paramecium primaurelia, particularly during the transition period from logarithmic to stationary growth phase and in relation to clonal decline, respectively. These lectins include Griffonia simplicifolia agglutinin II (GS II), Ricinus communis agglutinin (RCA₁₂₀), Arachis hypogea agglutinin (PNA), succinyl concanavalin A (succinyl-con A), and Triticum vulgaris agglutinin (WGA). The labeling obtained varies both according to the lectin used and to the culture and clonal age of the cells. Negative results were obtained in logarithmic growth phase cells and in clonal young cells by using lectin GS II. Conversely, lectins RCA₁₂₀ and PNA bind to the cell surface, the oral region as well as cilia, and do not undergo modifications with culture or clonal age and after permeabilization. WGA binds to constituents of the cell surface, trichocyst tips, food vacuoles, the oral region, and cilia but the extent of labeling decreases as culture age increases; during clonal decline, cells show the same labeling pattern as starved cells. Finally, the lectin succinyl-con A shows a large amount of binding sites on the cell surface, on trichocyst tips, and in the oral region of logarithmic-phase cells, whereas the number of sites decreases in late stationary phase. The data obtained partly differ from those reported in the literature and the differences can be attributed to the culture conditions and species examined. Nevertheless, the assumption that a rearrangement of some glycoconjugates of membrane throughout culture and clonal life of Paramecium is confirmed. Accepted: 25 November 1996     

Assessing acrosomal status of bovine sperm using fluoresceinated lectins

Binding of 12 lectins to bull sperm was analyzed to select a lectin that bound preferentially to the acrosomal region. Peanut agglutinin (PNA) and Pisum sativum agglutinin (PSA) were suitably specific for intracellular, acrosome-associated glycoconjugates. Peanut agglutinin exhibited almost no detectable binding to sperm surface receptors, but intense binding to the area of the acrosome anterior to the equatorial segment. In contrast, PSA bound intensely to anterior and equatorial acrosomal regions, and weakly to the other regions of the sperm. Acrosomal labeling by both lectins decreased when sperm were induced to acrosome-react with calcium ionophore. To determine if these lectins could be used to assess acrosomal status, we compared the percentage of acrosome-reacted sperm that were detected by staining with naphthol yellow and erythrosin B with the percentage that were detected by lectin labeling. The incidence of reacted sperm detected by PSA labeling was not significantly different from that detected by naphthol yellow/ erythrosin B (P = 0.46). The incidence of reacted sperm detected by PNA was correlated with the incidence detected by naphthol yellow/erythrosin B, but was significantly lower (P = 0.003). We conclude that labeling permeabilized sperm with fluoresceinated PSA can serve as a rapid assay for acrosomal status.     

Separation of germ cells from somatic cells in mouse testis by affinity for a lectin, peanut agglutinin

A new method for the separation of germ cells from somatic cells in the mouse testis was accomplished by making use of the differences in cell surface affinity for a lectin, peanut agglutinin (PNA). The separation procedure was based on the specific presence of PNA receptor on testicular germ cells and its absence on somatic cells, such as Leydig, Sertoli and peritubular cells. As a result, more than 99% of cells in PNA receptor-positive (PNA+) fractions were identified as germ cells by immunoperoxidase reaction with specific antiserum to mouse testicular germ cells. In contrast, Leydig cells were enriched in PNA receptor-negative (PNA-) fractions, i.e., 65% of cells in these fractions were cytochemically stained for 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) activity.     

Aged mice exhibit distinct peripheral B-cell phenotypes differing in apoptotic susceptibility: an ex vivo analysis.

BACKGROUND: Age-related changes in the antibody response have been classically associated with alterations in T-cell help, but increasing evidence shows that intrinsic B-cell defects exist. This article analyzes the apoptotic susceptibility of peripheral B-cells in aged and young control mice. MATERIALS AND METHODS: Freshly isolated lymphocytes from spleen and Peyer's patches (PPs) were labeled for B-cell lineage (B220(+) cells) and germinal center B subset (GCs, B220(+)/PNA(+) cells). Alternatively, splenic B-cells purified by MACS were used. Apoptosis was monitored by the Annexin V binding, incorporation of 3,3(')-dihexyloxacarbocyanine iodide (DiOC(6)(3)), propidium iodide (PI) staining, and morphological changes. Moreover, intracellular Bcl-2 expression and Bad phosphorylation status were also analyzed in B-cells. RESULTS: We showed in aging mice an enhanced Annexin V(+)/PI(-) cell percentage in splenic B-lymphocytes, which was correlated with a lower DeltaPsi(m). By contrast, no change in apoptosis was observed in compartments known to be enriched in activated B-cells (GCs and PPs). Analysis of Bcl-2 levels revealed no modification. When using B-cells purified by MACS, we strongly confirm data obtained on staining cells. Moreover, enhanced spontaneous apoptosis of splenic B-cells in aged mice was found to be correlated with a reduced phosphorylated Bad expression. CONCLUSION: Increased apoptosis of resting B-cells in old mice may be determined by an altered Bad phosphorylation, which in turn contributes to cell death by lowering the mitochondrial threshold for apoptosis.     

Effect of Hypoxia on Endothelial Cell Surface Glycoprotein Expression: Modulation of Glycoprotein IIIa and Other Specific Surface Glycoproteins

Exposure to hypoxia alters many aspects of endothelial cell metabolism and function; however, changes in surface glycoconjugates under these conditions have not been extensively evaluated. In the current studies, we examined surface glycoproteins of cultured bovine aortic (BAEC) and pulmonary arterial (BPAEC) endothelial cells under standard culture conditions (21% oxygen) and following exposure to hypoxia (0% oxygen) for varying time periods (30 min to 18 h) using a system of biotinylation, lectin binding (concanavalin A, Con A; Griffonia simplicifolia , GSA; Arachis hypogaea, PNA; Ricinus communis, RCA; or Triticum vulgaris, WGA), subsequent strep-avidin binding, and staining. Using these methods, we identified differences in lectin binding between the two cell types cultured in 21% oxygen with all lectins except PNA. With exposure to 0% oxygen, there was no change in lectin binding to most surface glycoproteins. Several surface glycoproteins, including glycoprotein IIIa on both cell types, demonstrated a time-dependent decrease in lectin binding; in addition, there was an increase in lectin binding to a few specific surface glycoproteins on each cell type within 30-60 min of exposure to 0% oxygen. These changes in specific surface glycoproteins were confirmed in both cell types by ¹²⁵I labeling. Increased lectin binding was observed for Con A binding BAEC glycoproteins at molecular weight (MW) 116, 130, and 205 kDa, GSA binding BAEC glycoproteins at MW 120 and 205 kDa, and RCA binding BPAEC glycoproteins at MW 140 and 205 kDa. Increased binding of WGA or PNA was not observed during exposure to hypoxia. The specificity of lectin binding was further confirmed by competitive inhibition with the appropriate sugar. These studies demonstrate that there are baseline differences between BAEC and BPAEC cell surface glycoproteins and that exposure to hypoxia is associated with little change in lectin binding to most surface glycoproteins. There is, however, increased surface expression of a few glycoproteins that differ depending of the origin of the endothelial cell. Although the mechanism of this increase in lectin binding is not yet clear, subsequent studies suggested that it is due to increased availability of select carbohydrate moieties. The time course of these alterations suggests a possible role in the endothelial cell response to decreases in ambient oxygen tension.     

Mechanism of sodium uptake in PNA negative MR cells from rainbow trout, Oncorhynchus mykiss as revealed by silver and copper inhibition

The rate of acid-stimulated and phenamil-sensitive sodium (Na(+)) uptake was measured in three different cell lineages: pavement cells (PVC), total mitochondrion-rich (MR) cell populations, and peanut lectin agglutinin-negative mitochondrion-rich cells (PNA(-) MR) isolated from the rainbow trout gill epithelium. Despite the presence of basal levels of Na(+) uptake in PVC, this transport was not enhanced by acidification, nor was it inhibited by independent treatment with bafilomycin (i.e., a V-type H(+)-ATPase inhibitor), phenamil (i.e., a specific inhibitor of ENaC), or Ag (a specific inhibitor of active Na(+) transport in fish). In contrast, Na(+) uptake in PNA(-) MR cells was increased by ~220% above basal levels following acidification of near 0.4 pH units in the presence of 1.0 mM external Na(+). Acid-stimulated Na(+) transport was entirely inhibited by both phenamil and bafilomycin. Silver (Ag) and copper (Cu), which are known to interfere with active Na(+) transport in fish, were also responsible for inhibiting acid stimulated Na(+) uptake in PNA(-) MR cells, but by themselves had no effect on basal Na(+) transport. Thus, we demonstrate that Ag specifically prevented acid-stimulated Na(+) uptake in PNA(-) MR cells in a dose-dependent manner. We also demonstrate rapid (<1 min) and significant inhibition of carbonic anhydrase (CA) by Ag in PNA(-) MR cells, but not in PVC. These data lend further support to the idea of a PNA(-) MR cell type as the primary site for Na(+) uptake in the freshwater (FW) gill phenotype of rainbow trout. Moreover, these findings provide support for the importance of intracellular protons in regulating the movement of Na(+) across the apical surface of the fish gill.     

The human lymph node germinal center cell: characterization and isolation by using two-color flow cytometry

The germinal center of lymphoid tissues is a critical microenvironmental site of B cell activation and differentiation in response to antigenic stimuli. However, characterization of germinal center cells (GCC) in tissue sections has proved technically difficult. Therefore, we have employed two-color flow cytometric analysis of suspended human tonsillar lymphocytes in order to define more precisely the immunologic features of GCC. These cells were identified in suspension by virtue of their specific surface binding of the lectin peanut agglutinin (PNA), confirmed by tissue immunoperoxidase studies. Phycoerythrin-labeled lectin was used in combination with a variety of fluorescein-labeled antibodies in order to identify subpopulations of tonsillar lymphocytes. The majority of PNA+ cells were B cells, and both PNA+ and PNA- B cells stained for surface immunoglobulin light chains. PNA+ cells lacked surface IgD, but included cells with surface IgG and IgM. Both PNA+ and PNA- cells stained for B1, B2, BA-1, Leu-12, Leu-14, CR-I, and HLA-DR antigens, whereas CALLA was present only on PNA+ cells. There were differences between PNA+ and PNA- cells in the relative expression of B1 and B2 antigens, possibly reflecting differences in B cell activation or maturation. A small proportion of T cells were PNA+, including both helper/inducer and suppressor/cytotoxic phenotypes. PNA+ cells included both small and large lymphoid cells, and almost all DNA synthetic activity was associated with the large PNA+ cells. PNA+ B cells isolated by cell sorting had morphologic features characteristic of GCC. Therefore, PNA+ cells in suspension appeared to represent GCC, and features of these cells that cannot be convincingly shown in tissue section studies were demonstrated by flow cytometry.     

Alterations in PNA binding of keratinocytes in oral keratosis

Abstract

Changes in the expression of peanut lectin (PNA) were examined in keratinocytes of oral keratosis showing a mixture of hyperortho- and hyperparakeratinized epithelium. In the hyperorthokeratinized epithelium, which was reacted with anti-filaggrin antibody in both granular and cornified cells, PNA bound to the surface of keratinocytes from the spinous layer to the granular layer. Neither anti-filaggrin nor PNA reactions were detected in keratinocytes of the hyperparakeratinized epithelium. After neuraminidase pretreatment, however, PNA staining appeared in all cells, except cornified cells, of both hyperortho- and hyperparakeratinized epithelia. These findings suggest that PNA-binding epitopes in keratinocytes were modified by sialic acid during the hyperparakeratotic process of oral keratosis.     

Specific Lectin Binding to Beta1 Integrin and Fibronectin on the Apical Membrane of Madin-Darby Canine Kidney Cells

Although lectins have previously been used to identify specific cell types in the kidney and various other tissues, the proteins labeled were not identified. We hypothesized that fluorescently labeled lectins could provide a useful tool for direct labeling of membrane-associated glycoproteins. Protein fractions from Madin-Darby canine kidney (MDCK) cells were exposed to a panel of 16 fluorescently labeled lectins to identify suitable lectin-protein pairs. Peanut agglutinin (PNA) selectively bound a 220-240 kDa O-linked glycoprotein with a slightly acidic isoelectric point, while Sambucus nigra agglutinin (SNA) labeled a 130 kDa glycoprotein with a highly acidic isoelectric point. Both proteins were readily labeled by lectins applied to the apical surface of living confluent cells. The proteins were isolated by lectin affinity columns and identified by mass spectrometry. Peptides from the PNA-binding protein shared molecular weight and amino acid composition with fibronectin. Fragments of the SNA-binding protein showed amino-acid identity with peptides from beta1 integrin. The identities of these proteins were validated by Western blotting. Binding of PNA to a 220 kDa protein was inhibited by an anti-fibronectin antibody, and binding of a 130 kDa protein by SNA was diminished by an anti-beta1 integrin antibody. We conclude that PNA and SNA can be used as specific markers for fibronectin and beta1 integrin, respectively, in MDCK cells.     

Distribution of lectin binding glycoprotein in osteoclasts

Arachis hypogaea (PNA) lectin, specific for Gal-B-1,3-GalNac disaccharide and Wheat germ (WGA) lectin, specific for (GlcNac) and terminal neuraminic acid were used to identify histiocytic giant cells, osteoclast like giant cells and osteoclasts. PNA lectin, without neuraminidase predigestion was not bound by the giant cells, while they showed a strong reaction with WGA lectin. Neuraminidase pretreatment decreased WGA lectin binding, which supports that neuraminic acid plays a role in the binding of WGA. On the other hand, neuraminidase digestion liberated large amounts of PNA binding sites in every type of giant cells examined, showing a strong, intracytoplasmic granular staining. This observation is indicative of presence of PNA binding sites masked by neuraminic acid. Instead of the intracytoplasmic PNA binding in some osteoclasts a well defined part of the cytomembrane was heavily stained. We suppose that this PNA binding part of cytomembrane equals to the zone of resorption, characterized by the ruffled border of osteoclasts. Our findings indicate that a neuraminic acid substituted PNA binding glycoprotein is synthetized both in osteoclasts and histiocytic giant cells which may indicate a common origin of these cell types.     

Distribution of lectin binding glycoprotein in osteoclasts

Summary Arachis hypogaea (PNA) lectin, specific for Gal-B-1, 3-GalNac disaccharide and Wheat germ (WGA) lectin, specific for (GlcNac) and terminal neuraminic acid were used to identify histiocytic giant cells, osteoclast like giant cells and osteoclasts. PNA lectin, without neuraminidase predigestion was not bound by the giant cells, while they showed a strong reaction with WGA lectin. Neuraminidase pretreatment decreased WGA lectin binding, which supports that neuraminic acid plays a role in the binding of WGA. On the other hand, neuraminidase digestion liberated large amounts of PNA binding sites in every type of giant cells examined, showing a strong, intracytoplasmic granular staining. This observation is indicative of presence of PNA binding sites masked by neuraminic acid. Instead of the intracytoplasmic PNA binding in some osteoclasts a well defined part of the cytomembrane was havily stained. We suppose that this PNA binding part of cytomembrane equals to the zone of resorption, characterized by the ruffled border of osteoclasts. Our findings indicate that a neuraminic acid substituted PNA binding glycoprotein is synthetized both in osteoclasts and histiocytic giant cells which may indicate a common origin of these cell types.     

Identification of peanut agglutinin-binding glycoproteins on immature human thymocytes

Previous studies in our laboratory have shown that peanut agglutinin (PNA), a lectin specific for the disaccharide Gal beta 3GalNAc, binds to immature (cortical) thymocytes of mouse and man and not to the mature (medullary) cells. Using lectin overlay of protein blots and lectin-affinity chromatography, we have found that the major PNA-binding glycoproteins on total as well as on immature (PNA+) human thymocytes correspond to two bands of Mr 170,000 and 180,000. Another glycoprotein, of Mr 110,000, also binds PNA but to a lesser extent. All three glycoproteins contain sialic acid as demonstrated by cell surface labeling with NaIO4-NaB3H4, binding of wheat germ agglutinin, and reaction with alkaline phosphatase-hydrazide. After treatment with sialidase, binding of PNA to these glycoproteins is significantly enhanced.     

Identification of UEA I-binding surface glycoproteins of cultured human endothelial cells

Ulex europaeus agglutinin (UEAI) binds mainly to endothelial cells in human tissues. In cultured human umbilical vein endothelial cells TRITC-UEAI gave an even surface staining but no binding to pericellular material. After permeabilization of the cells UEAI decorated the Golgi apparatus as a juxtanuclear structure. Electrophoresis of Triton X-100 lysates of 35S-methionine labeled cells bound to lectin agarose beads showed that a similar set of polypeptides was recognized by UEA-I and WGA while distinctly different polypeptides were bound to LcA-agarose. Surface labelling revealed major glycoproteins with Mr 220 kD, 160 kD, 140 kD, 120 kD, 80 kD and 50 kD, most of which could be extracted with Triton X-100. However, only the 140 kD gp, 120 kD gp and 80 kD gp showed binding to UEA 140 kD gp, 120 kD gp and 80 kD gp showed binding to UEA I-lectin. The results show that among a distinct set of surface glycoproteins in cultured human endothelial cells only a few have alpha-l-fucosyl moieties capable of binding to UEAI lectin.     

Lectin binding by structures of the submandibular gland of the rat during postnatal ontogenesis in the presence of thyroid pathology

Redistribution of lectin receptor sites in rat submandibular gland under hypo- and hyperthyroidism has been investigated using lectin-peroxidase technique. Lectin preparation include con A, peanut agglutinin (PNA), wheat germ agglutinin (WGA) and fucose-specific lectin from Laburnum anagyroides bark (LAB). Submandibular gland is excised on the 1st, 10th, 20th and 40th days of postnatal life and in adult rats. Hyperthyroidism, as well as hypothyroidism cause a considerable decrease of con A, WGA and LAB binding with simultaneous enhancement of PNA binding in all investigated groups of the animals. The only exception from this regularity is noted for con A: hypothyroidism in adult rats and on the 40th day of postnatal development causes enhancement of this lectin binding to granular duct epitheliocytes. Selective staining of mast cells with PNA and of separate neurocytes with con A is also demonstrated; these cells staining is affected neither by hyperthyroidism, nor by hypothyroidism. Possible interpretation of the observed phenomena is discussed.     

Histochemical analysis of the chemical structure of blood group-related carbohydrate chains in serous cells of human submandibular glands using lectin staining and glycosidase digestion

Using lectin staining methods in combination with exo- and endo-glycosidase digestion procedures, we analyzed the chemical structure of different types of blood group-related substances in serous cells of formalin-fixed, paraffin-embedded human submandibular glands. Serous cells produced only H antigen; A and B antigens were not present, and the expression of H antigen is dependent on the secretor status of the tissue donor. Although reactivity with Ulex europaeus agglutinin I (UEA-I) was not markedly reduced by alpha-L-fucosidase digestion, an affinity for peanut agglutinin (PNA) was seen after fucosidase digestion in the cells from secretors. In those from nonsecretors, no PNA reactivity appeared after enzyme digestion. On the other hand, sialidase digestion elicited PNA reactivity in serous cells irrespective of the donor's secretor status. PNA reactivity observed after fucosidase or sialidase digestion was susceptible to endo-alpha-N-acetylgalactosaminidase (endo-GalNAc-dase) digestion. SBA reactivity in UEA-I-negative cells from secretors, or in cells from fetuses and newborn infants, was markedly reduced by beta-galactosidase digestion. After galactosidase digestion, reactivity with Griffonia simplicifolia agglutinin II (GSA-II) appeared in the corresponding cells. This GSA-II reactivity was almost completely eliminated by subsequent beta-N-acetylhexosaminidase digestion. Whereas PNA reactivity in these cells was not reduced by beta-galactosidase treatment, it was significantly diminished by endo-GalNAc-dase digestion. These results suggest that at least two kinds of precursor disaccharides are produced in submandibular serous cells, i.e., SBA-reactive D-galactose-(beta 1-3,4)-N-acetyl-D-glucosamine and PNA-reactive D-galactose-(beta 1-3)-N-acetyl-D-galactosamine alpha 1-serine or threonine (O-glycosidically linked Type 3 chain or T antigen). Final fucosylation and synthesis of these two types of precursor chain appear to be under the control of the secretor gene.     

Lectin histochemistry of 1,2-dimethylhydrazine-induced rat colon neoplasia

Lectins linked to fluorescein were used as carbohydrate probes to examine the goblet cell mucin and epithelial cell surface glycoconjugate alterations in an experimental rodent model of colonic neoplasia induced with parenteral 1,2-dimethylhydrazine dihydrochloride. Lectins derived from Triticum vulgare (WGA), Ricinus communis (RCA1), and Limulus polyphemus (LPA) showed reduced labeling of goblet cell mucin in these tumors, while binding with peanut lectin from Arachis hypogaea (PNA), a lectin ordinarily failing to bind to mucin in normal colon, was positive. In addition, RCA1 and LPA showed increased cell surface labeling of neoplastic epithelial cells. Finally, alterations were observed in lectin binding to "transitional" colonic mucosa adjacent to colonic tumors from carcinogen-treated rats. These findings indicate that significant alterations in both membrane and mucin glycoconjugates occur in colonic tumors and mucosa adjacent to tumors in a chemically induced experimental animal model of human colon cancer.     

Binding of fluorescein isothiocyanate conjugated lectins to rat spermatogenic cells in tissue sections

Summary The testes from three months old Spague-Dawley rats were fixed in Bouin's fluid or neutral buffered 10% formalin, embedded in paraffin, sectioned and after deparaffination stained with the following fluorescein isothiocyanate coupled lectins: PNA, WGA, Con A, RCA, SBA, DBA and UEA. The results show that there are considerable differences in the staining pattern of various spermatogenic cells between different lectins. The fixation in Bouin's fluid enhanced the staining of all the lectins compared to formalin fixation in which only a weak staining could be seen in the acrosomes of spermatids after WGA or PNA staining. PNA and WGA stained specifically the acrosome of the developing spermatids, which was seen from the beginning of the acrosome formation and lasted up to late spermiogenesis. However, the staining with PNA decreased in the late spermatids whereas the intensity of the staining remained unchanged with WGA. Con A did not stain the acrosome but stained unspecifically the cytoplasm of all spermatogenic cells. RCA stained faintly the acrosome throughout the spermatid differentiation. DBA and UEA stained specifically the chromosomes of B spermatogonia. DBA also faintly stained the cell membranes of early spermatids. SBA did not show any specific staining of the spermatogenic cells. Based on this it is suggested that the carbohydrates and glycoproteins which are known to be present in the acrosome are formed already in the beginning of the acrosome formation. The decrease in the PNA staining in late spermatids possibly reflects the fact that the receptor molecules are not synthesized in late spermatids but are formed in earlier developmental stages and are thereafter preserved in the acrosome. The enhancement of lectin binding caused by Bouin's fixative might also be applied to other tissues where previous experiments with formalin fixed tissue have failed to show any staining.     

Characterization of carbohydrates of adult Echinococcus granulosus by lectin-binding analysis

The identification of lectin-binding structures in adult worms of Echinococcus granulosus was carried out by lectin fluorescence; the distribution of carbohydrates in parasite glycoconjugates was also studied by lectin blotting. The lectins with the most ample recognition pattern were ConA, WGA, and PNA. ConA showed widespread reactivity in tegument and parenchyma components, including the reproductive system, suggesting that mannose is a highly expressed component of the adult glycans. Although reproductive structures appeared to be rich in N-acetyl-D-glucosamine (GlcNAc)-N-acetyl neuraminic acid (NeuAc) and galactose (Gal) as demonstrated by their strong reactivity with WGA and PNA, respectively, some differences were observed in their labeling patterns. This was very clear in the case of the vagina, which only reacted with WGA. Furthermore, WGA and ConA both had reactivity with the excretory canals. RCA, the other Gal binding lectin used, only reacted with the tegument, suggesting that widespread PNA reactivity with the reproductive system is related to the presence of the D-Gal-beta-(1,3)D-GalNAc terminal structure. UEA I failed to bind to any parasite tissues as determined by lectin fluorescence, whereas DBA and SBA showed a very faint staining of the tegument. However, in transferred glycans, N-acetyl-D-galactosamine (GalNAc) and fucose (Fuc) containing glycoproteins were distinctly detected.     

Histochemical localization of galactose-containing glycoconjugate at peripheral nodes of Ranvier in the rat

Lectin-horseradish peroxidase conjugates were used to study glycoconjugates in paraffin sections of dorsal roots of the rat spinal cord. Griffonia simplicifolia-B4 isolectin (GSA I-B4) and peanut agglutinin (PNA) stained strongly the nodes of Ranvier, localizing, respectively, terminal alpha- and beta-D-galactose. Sialidase digestion did not increase staining with PNA at the node of Ranvier, suggesting the presence of a neutral glycoconjugate. Staining of the nodal but not the internodal axolemma was observed with PNA. The outer surface of the myelin sheath in axons of the dorsal root stained strongly with GSA I-B4 but only weakly with PNA, demonstrating an abundance of terminal alpha-galactose. PNA staining was enhanced in this site by sialidase digestion, showing terminal sialic acid-beta-galactose dimers. The presence of sialic acid here was further evidenced by labeling of these membranes with the lectin derived from the slug, Limax flavus (LFA). Affinity for a high iron diamine-Alcian blue (pH 2.5) sequence demonstrated, in addition, the presence of sulfate esters in glycoconjugates on the outer myelin membrane. GSA I-B4 imparted strong reactivity to nonmyelinated fibers in the dorsal root and the spinal nerve. The present findings appear to reflect several localizations of biochemically described nervous system glycoproteins containing O-glycosidically linked side chains terminated by alpha- and beta-D-galactose.     

A Comparative Nuclear Localization Study of Galectin-1 with Other Splicing Components

Using both conventional and laser confocal fluorescence microscopy, the intracellular distribution of galectin-1 in HeLa cells was analyzed and compared with the localization of previously documented markers of the nucleus and cytoplasm. The Sm epitopes of the small nuclear ribonucleoprotein complexes (snRNPs) and the non-snRNP splicing factor SC35 yielded only nuclear staining. On the other hand, the enzyme lactate dehydrogenase was cytoplasmic. In contrast to these patterns in which nuclear versus cytoplasmic localizations appeared to be mutually exclusive, galectin-1, as well as galectin-3, yielded simultaneous nuclear and cytoplasmic staining. Confocal microscopy showed galectin-1 fluorescence throughout most of the sections from the top of the cell to the bottom. Through the middle sections, as the plane of focus cuts through the nucleus, there was definite fluorescence staining in the nuclear compartment. This nuclear localization was critically dependent on the type of detergent used to permeabilize the cell: cells treated with saponin or digitonin yielded exclusively cytoplasmic staining while Triton X-100-treated cells showed nuclear as well as cytoplasmic labeling. Finally, double-immunofluorescence analysis showed that, within the nucleoplasm, the following pairs of nuclear antigens could be colocalized in certain speckled structures: (a) SC35 versus Sm; (b) galectin-1 versus Sm; (c) galectin-3 versus Sm; and (d) galectin-1 versus galectin-3. These results establish the presence of galectin-1 in the nuclei of HeLa cells, a conclusion consistent with the identification of the protein in nuclear extracts of the same cells and with its documentation as a factor in pre-mRNA splicing.