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.

Although musculoskeletal pain is one of the most common causes of chronic pain and physical disability in both developing and developed countries, relatively little is known about the nerve fibers and mechanisms that drive skeletal pain. Small diameter sensory nerve fibers, most of which are C-fiber nociceptors, can be separated into two broad populations: the peptide-rich and peptide-poor nerve fibers. Peptide-rich nerve fibers express substance P (SP) and calcitonin gene related peptide (CGRP). In contrast, the peptide-poor nerve fibers bind to isolectin B4 (IB(4)) and express the purinergic receptor P(2)X(3) and Mas-related G protein-coupled receptor member d (Mrgprd). In the present report, we used mice in which the Mrgprd(+) nerve fibers express genetically encoded axonal tracers to determine the peptide-rich and peptide-poor sensory nerve fibers that innervate the glabrous skin of the hindpaw as compared to the bone marrow, mineralized bone and periosteum of the femur. Whereas the skin is richly innervated by CGRP(+), SP(+), P(2)X(3)(+) and Mrgprd(+) sensory nerve fibers, the bone marrow, mineralized bone and periosteum receive a significant innervation by SP(+) and CGRP(+), but not Mrgprd(+)and P(2)X(3)(+) nerve fibers. This lack of redundancy in the populations of C-fibers that innervate the bone may present a unique therapeutic opportunity for targeting skeletal pain as the peptide-rich and peptide-poor sensory nerve fibers generally express a different repertoire of receptors and channels to detect noxious stimuli. Thus, therapies that target the specific types of C-nerve fibers that innervate the bone may be uniquely effective in attenuating skeletal pain as compared to skin pain.

After traumatic spinal cord injury (SCI), disruption and plasticity of the microvasculature within injured spinal tissue contribute to the pathological cascades associated with the evolution of both primary and secondary injury. Conversely, preserved vascular function most likely results in tissue sparing and subsequent functional recovery. It has been difficult to identify subclasses of damaged or regenerating blood vessels at the cellular level. Here, adult mice received a single intravenous injection of the Griffonia simplicifolia isolectin B4 (IB4) at 1-28 days following a moderate thoracic (T9) contusion. Vascular binding of IB4 was maximally observed 7 days following injury, a time associated with multiple pathologic aspects of the intrinsic adaptive angiogenesis, with numbers of IB4 vascular profiles decreasing by 21 days postinjury. Quantitative assessment of IB4 binding shows that it occurs within the evolving lesion epicenter, with affected vessels expressing a temporally specific dysfunctional tight junctional phenotype as assessed by occludin, claudin-5, and ZO-1 immunoreactivities. Taken together, these results demonstrate that intravascular lectin delivery following SCI is a useful approach not only for observing the functional status of neovascular formation but also for definitively identifying specific subpopulations of reactive spinal microvascular elements. J. Comp. Neurol. 507:1031-1052, 2008.(c) 2007 Wiley-Liss, Inc.

Expression of sugar residues and the nature of oligosaccharide linkage during keratinocyte maturation in the epidermis of the Breton dog were studied with the use of lectin histochemistry. Thirteen lectins were used. Labelling was not observed with GSA I-B4, GSA II, UEA-I, and LTA. The cytoplasm of keratinocytes reacted with PNA, HPA, Con A, and WGA from the basal layer to the granular layer. PNA and Con A showed highest reactivity in the granular cell layer. The cell surface showed increased reactivity with PNA, HPA, and WGA with maturation of keratinocytes. KOH-neuraminidase treatment (KOH-Neu) increased PNA and RCA120 staining during keratinocyte differentiation thus indicating an increase in oligosaccharides terminating with sialic acid-Galbeta(1,3)GalNAc and sialic acid-Galbeta(1,4)GlcNAc, respectively. Labelling of the glycocalyx of basal and spinous keratinocytes with SNA and MAA revealed terminal Neu5acalpha(2,6)Gal/GalNAc and Neu5acalpha(2,3)Galbeta(1,4)GlcNAc. KOH-Neu-DBA showed oligosaccharides terminating with sialic acid-GalNAcalpha(1,3)GalNAc in the spinous and granular layers. A selective glycocalyx labelling of granular keratinocytes was observed with DBA and SBA. Reactions with MAA, PNA, DBA, RCA120, SBA, HPA, and WGA disappeared after the beta-elimination reaction. Our findings indicate that Breton dog epidermis contains more O-linked than N-linked oligosaccharides and confirm that different subpopulations of keratinocytes can be distinguished by lectin histochemistry.

BACKGROUND: In order to extend previous observations on the heterogeneity in labeling of rat vascular endothelium by the lectins GS I and LEA [1,2], we have conducted a survey of several organs with a lectin panel with greater variety of carbohydrate specificity.MATERIAL AND METHODS: Submandibular gland, duodenum, distal colon, liver, kidney, heart, skeletal muscle, adrenal gland, ovary, cerebral and cerebellar cortex of a rat have been examined by light and electron microscopy using lectin-gold probes on Lowicryl K4M embedded tissue.RESULTS: Five lectins (LCA, con A, LEA, RCA, WGA) labeled vascular endothelial cells in the connective tissue of all the organs studied, while PNA, EEA, TPA, LABA, UEA I expressed no detectable affinity towards endothelial cells. HPA and GS I reacted with most endothelial cells, except those in the kidney glomeruli, liver sinusoids and zona fasciculata of adrenal gland. In cerebral and cerebellar cortex GS I reacted witn pericytes of large vessels, but not with endothelial cells of the capillary bed. SDS-PAGE extracts of heart, skeletal muscle and cerebral cortex reveal that differences in GS I labeling depend, at least in part, on 40 and 200 kD glycoproteins, present in heart and skeletal muscle, but not cerebral cortex.CONCLUSIONS: Data indicate, that GS I, widely used for selective histochemical labeling of rat endothelial cells is not uniform endothelial marker in all organs. More precise investigation of these lectin reactive determinants in rat vascular endothelium, including developmental changes, isolation and enzyme-FACE sequencing of their carbohydrate moieties, generation of antibodies and their possible organ specific binding affinities could give new insight into the physiological role of GS I and HPA binding glycoproteins in rat endothelium.

Quantification of changes in gastrointestinal morphology and mucus gel has been difficult to study. In the present study, we investigated changes in rat intestine under total parenteral nutrition (TPN) using fluoresceinated lectin staining and image analysis. Wistar rats (n = 34) were divided into two groups: one group received TPN for 2 weeks, and a control group received standard rat chow and water ad libitum for the same period. A 1-cm segment of distal ileum was removed and cut into cross sections. Sections were stained with hematoxylin and eosin, and to stain the mucus, periodic acid-Schiff (PAS), alcian blue (AB), and fluoresceinated lectin, that is, FITC-labeled Ulex europaeus agglutinin I (FITC-UEA-I), were used. Light microscope images were stored in a personal computer and analyzed using image analysis. We measured perimeter length, mucosal thickness, villus area, villus surface area index, mucus stain-positive area, mucosal area ratio, and mucosal surface area ratio. Perimeter length, mucosal thickness, villus area, and villus surface area index in the TPN group were significantly less than those in the control group (P < 0.001 for each parameter). In all mucus stainings, the stain-positive area in the TPN group was significantly less than that in the control group. However, there were no significant differences in mucosal area or mucosal surface area ratios between the two groups. The FITC-UEA-I-positive area was significantly greater than the PAS- or and AB-positive area. There were significant positive correlations between the FITC-UEA-I-positive area and both the PAS-positive and AB-positive areas. TPN for 2 weeks promoted intestinal atrophy and decreased absolute quantity of mucus gel. We successfully introduced the FITC-UEA-I staining method to evaluate changes in mucus gel.

The activity of seven different types of biotinylated lectin were examined in normal and tumorous lacrimal gland tissue. In the normal lacrimal gland tissue, the glandular cells and the tubular epithelium were labeled by maclura pomifera agglutinin (MPA), soybean agglutinin (SBA), and bauhinia purpurea agglutinin (BPA). The myoepithelial cells were stained by griffonia simplicifolia agglutinin 1 (GS1). In the primary pleomorphic adenoma tissue, the epithelial components were labeled by MPA, ulex europaeus agglutinin, SBA, peanut agglutinin, and BPA. The mesenchymal components showed negative labeling. In contrast, the recurrent pleomorphic adenoma tissue showed a positive reaction in the mesenchymal components when GS1 and BPA were used. These results revealed differences in the glycoconjugate composition among normal and tumorous lacrimal gland tissues from patients with primary and recurrent pleomorphic adenomas.

The acidic glycoconjugates of mouse ileum Paneth cells were examined with the aid of light and electron microscopy, using cationic colloidal gold (CCG) as a probe. Specimens of mouse ilea were fixed in half-strength Karnovsky's fixative and embedded in Lowicryl K4M resin. Semithin and ultrathin sections were cut of examination with light and electron microscopy, respectively. Examination of the sections using light microscopy revealed the positive staining of CCG at pH 1.0 and pH 2.5, which was detected at the rim of secretory granules and at the supranuclear regions of the Paneth cells. At pH 4.0, in addition to staining of the secretory granule rim, weak staining was observed in the granule core. At pH 7.2, the cytoplasm other than secretory granules exhibited positive CCG staining. Examination of the sections using electron microscopy, at pH 1.0, the trans lamellae of the Golgi apparatus, the rim of the secretory granules, and lysosomes were labeled selectively by CCG. At pH 2.5, labeling was also discernible over the same structures in the cells. However, at this pH, the labeling intensity was stronger than that at pH 1.0, due to the dual labeling of sulfated and sialylated glycoconjugates in these structures. At pH 4.0, the Golgi apparatus, rims and cores of secretory granules and ribosomes were labeled. Lysosomes and nuclei were also positively stained. At pH 7.2, the rims of secretory granules were not stained. The present results indicate that the CCG method gives good resolution and contrast when applied to staining, and therefore is useful for the specific staining of glycoconjugates such as sulfated, sialylated and phosphated glycoconjugates for light and electron microscopy.

Lectins are polyvalent proteins of non-immune origin with exquisite carbohydrate binding specificity making them ideal for investigation of cell surface glycoprotein and glycolipid antigens. We examined the cell surface lectin binding phenotypes of 20 UM-SCC squamous cell carcinoma cell lines established from 17 patients with head and neck cancers using a panel of fluorescein-conjugated lectins and inhibition by the appropriate monosaccharide to confirm specificity of using a panel of fluorescein-conjugated lectins and inhibition by the appropriate monosaccharide to confirm specificity of binding. Conconavalin A (Con A) from Canavalia ensiformis and the peanut agglutinin (PNA) from Arachis hypogaea bound all SCC cell lines tested and wheat germ agglutinin (WGA) from Triticum vulgaris bound to 12 of 13 tumor cell lines. The blood group O specific lectin UEA 1 from Ulex europeus also bound to all cell lines regardless of the donor blood type. Lectins of Dolichos biflorus (DBA) and Griffonia simplicifolia (GS I-B4 or BSA I-B4) with binding specificity for glycoproteins associated with blood group A and B respectively, had reactivity that did not directly correlate with blood group antigen expression. In contrast to the other lectins in our panel which exhibited broad reactivity with SCC antigens, the BSA-II lectin from Griffonia simplicfolia,(GS II or BSA II) which has sugar binding specificity for terminal non-reducing GlcNAc, did not bind to any of the screened cell lines. Our results demonstrate a common pattern of lectin-defined carbohydrate expression on the cell surface of squamous cell carcinomas of head and neck that appears promising in defining the malignant cellular phenotype. Lectin binding profile may be useful in differentiating benign from malignant histopathology.

Hydrolysis of glucosylceramides (GlcCer) by beta-glucocerebrosidase generates ceramides, critical components of the epidermal permeability barrier. Ceramides also are involved in the regulation of cellular proliferation and differentiation in a variety of cell types. Whereas most studies have focused on ceramides and their sphingoid base metabolites as growth inhibitors, GlcCer apparently acts oppositely (i.e., as a mitogen). To determine whether enhancement of GlcCer content stimulates epidermal mitogenesis, we examined the response of hairless mouse epidermis to alterations in endogenous and/or exogenous GlcCer. Topical applications of conduritol B epoxide, a specific irreversible inhibitor of beta-glucocerebrosidase, increased epidermal GlcCer levels twofold, an alteration localized largely to the basal, proliferative cell layer (fourfold increase); and stimulated epidermal proliferation (2.3-fold elevation in [3H]thymidine incorporation; P < or = 0.001), localized autoradiographically again to the basal layer, and resulting in epidermal hyperplasia. Intracutaneous administration of GlcCer (2.0 mg) also stimulated epidermal DNA synthesis, while simultaneous treatment with conduritol B epoxide plus GlcCer resulted in an additive increase in DNA synthesis. These increases in epidermal proliferation could not be attributed either to altered epidermal permeability barrier function, or to nonspecific irritant effects, as determined by four separate criteria. These results strongly suggest that GlcCer directly stimulates epidermal mitogenesis.

Cholera toxin causes reversible epidermal hyperplasia. We observed maximal thickness of the epidermis on the fourth day after treatment and a return to pretreatment values by day 7. The increase in thickness occurred in the basal and intermediate layers, with these layers becoming two to three times thicker than those of normal epidermis. The time sequence of epidermal proliferation was studied using bromodeoxyuridine (BrdU) labelling. We observed a maximum number of labelled basal cells within the first 24 h. Only a few cells were labelled 7 days after toxin injection. Griffonia simplicifolia-IB4 (GSA-IB4), Ulex europaeus-I (UEA-I) and Griffonia simplicifolia-II (GSA-II) lectins were used for the analysis of epidermal cell differentiation in the tissue sections. To study keratinocyte differentiation, further immunological staining was performed using two anticytokeratin antibodies, PKK2 and PKK3 mouse monoclonal antibodies. From the immunocytochemical results, we conclude that synchronous differentiation of the epidermis occurs after cholera toxin administration.

Temporal changes have been noted previously in retinal glycoproteins that bind to wheat germ agglutinin by a technique in which the denatured glycoproteins are first separated according to size by polyacrylamide gel electrophoresis, and are then localized on the gel using [125I]lectin. As reported here this technique will also detect differences between dorsal and ventral halves of the neural retina from 8-day chick embryos, and using other lectins will detect temporal changes in the glycoprotein pattern of the optic tectum. Some of the glycoproteins detected by wheat germ agglutinin in the neural retina appear to be represented on the surface of the retinal cells since:(a) the temporal changes in retinal glycoproteins can also be observed in a plasma membrane enriched fraction prepared from neural retina cells; and (b) antibodies prepared in mice against various size categories of wheat germ lectin binding glycoproteins bind to intact retinal cells.

The presence of specific oligosaccharides on the surface of retinal cells was examined by incubating FITC-labeled lectins with cells dissociated from papain-treated turtle retinas. The pattern and intensity of binding was found to vary among the cells examined. With Con A, there was strong surface staining of both rods and cones, with an intense ring of fluorescence above the nucleus. The bipolar and ganglion cells also showed strong surface labeling. In Müller (glial) cells there was intense fluorescence in the apical, microvillous region. In contrast, the horizontal cells and their axons showed weak staining. When RCA-60, RCA-120, and WGA were incubated with photoreceptors, bipolar cells, or horizontal cells, little fluorescence was visible. However, all three lectins bound strongly to the Müller cells. In contrast, the Lotus lectin did not bind to any of the cells examined. In all the cases, lectin binding was inhibited by the appropriate haptene sugar. Further, prior treatment cells with neuraminidase did not alter lectin binding to any cell type. These results suggest differences in the distribution of lectin receptors among specific cell types, and particularly between neurons and glial cells in the vertebrate retina.

Regulation in epidermal differentiation can best be studied if molecular mechanism can be associated with structural and functional changes. Such recognized associations include the cessation of mitosis through inhibition of DNA replication by a G1-inhibitor present in the suprabasal cells, the biosynthesis of a tonofilament-protein as an early event in keratinization, the biosynthesis of HRP0 (histidine-rich protein) and its polymerization to HRPI during the formation of keratohyalin, the conversion of HRPI to HRPII coincident with the loss of the nucleus from the granular cell, and the aggregation of the stratum corneum basic protein and keratin filaments to form fibers in the cornified cell. To this list can now be added changes in specificity for lectin-binding to the cell surface as the keratinocyte progresses toward the cutaneous surface. This report presents data on a) the conversion of HRPI to HRPII and b) the differential lectin-binding in the epidermis of the newborn rat. HRPI (Mol. Wgt. greater than or equal to 10(6)) and HRPII (Mol. Wgt. 6 X 10(4)) have similar unique amino acid compositions and exhibit extensive-but not complete-homology in primary structures as determined by peptide mapping after exposure to trypsin. When labeled by exposure in vivo to radioactivity histidine, about 75 of the labeled histidine from both HRPI and HRPII appeared in one peptide fraction in the map, HRPI appears to have on histidine-containing fragment which is not present in HRPII. This peptide appears to contain phosphate and to account for the organically-bound phosphate which was found in HRPI but not defected in HRPII. Changes which occur in the lectin-binding specificity of the cell during differentiation may result from either movement or chemical change in carbohydrates at the cell surface. Immunofluorescent studies have shown that an isolectin from Bandieraea simplicifolia with specificity for alpha-D-galactose binds to the surface of basal and lower spinous cells, a lectin from Ulex europaeus with specificity for alpha-L-focus labels spinous cells, and a second lectin from B. simplicifolia with specificity for N-acetyl-D-glucosamine labels cornified cells. The relationship fo these alterations in the carbohydrates of the cell surface in intracellular structural and/or functional changes in unknown.

The distribution of binding sites for four rhodamine-conjugated lectins has been examined in paraffin-embedded tissue sections of the developing and mature avian neural retina. The method of fixation employed here (95% ethanol:glacial acetic acid) is shown to conserve substantially more in vivo labeled 3H-glycoprotein or 3H-ganglioside than fixation with either 3.7% formaldehyde or 2% glutaraldehyde. Each lectin was shown to be optimally active by direct hemagglutination and inhibitable by the appropriate hapten in the cytochemical assay. Staining with wheat germ agglutinin (leads to N-acetylglucosamine) occurs predominantly to each of the anuclear retinal layers and progressively disappears from each of the nuclear layers. By adulthood, the inner nuclear layer is stained in a gradient which is highest adjacent to the inner nuclear layer while the nuclear layers are virtually unstained. Although similar to wheat germ agglutinin, staining with concanavalin A (leads to mannose) is less intense and persists in the adult nuclear layers. Dolichos biflorus agglutinin (leads to N-acetylgalactosamine) predominantly stains the embryonic ganglion cell layer. With development, this lectin demonstrates profound differences between the major cell types of the inner nuclear layer and the inner (negative) and outer (positive) plexiform layers. Differences between the principal synaptic layers are further accentuated by Ulex europaeus agglutinin I (leads to fucose): Binding sites are virtually absent from the 12th day embryonic retina, but are abundant throughout the retina by the 18th day and persist after hatching. However, in the adult retina staining persists in the outer plexiform layer but is lost from the inner plexiform and nerve fiber layers. In contrast to Dolichos biflorus agglutinin, Ulex europaeus agglutinin I stains the inner nuclear layer uniformly. Temporal differences in the characteristic lectin binding patterns exhibited by each of the major nuclear and anuclear layers of the developing avian neural retina are thus documented.

The binding of concanavalin A to the plasmalemma of acinar carcinoma cells was characterized by electron microscopy utilizing horseradish peroxidase. Heavy labeling due to specific concanavalin A binding was detected on the plasmalemma of undifferentiated carcinoma cells lacking zymogen maturation, neoplastic cells of intermediate differentiation with only occasional zymogen granules, and highly differentiated acinar carcinoma cells containing numerous cytoplasmic zymogen granules. The plasmalemma of acinar carcinoma cells was also compared to the normal pancreatic acinar cell plasmalemma by measurement of specific 125I-labeled concanavalin A binding. Although only about one-third of pancreatic acinar carcinoma cells demonstrate mature zymogen differentiation, the acinar carcinoma had a full complement of normal plasmalemma receptors for 125I-labeled concanavalin A. It is concluded that, unlike normal pancreas, the presence of concanavalin A receptors on the plasmalemma of acinar carcinoma cells is not a specific membrane marker for differentiated cells containing zymogen granules.

The Concanavalin A reactive glycoproteins of epidermal cells were analyzed by the application of the iodinated lectin to molecules separated by SDS-PAGE. Normal epidermal cells were maintained as undifferentiated or differentiated by controlling the Ca++ concentration of the growth medium. Some 20 labeled bands could be resolved. Their relative intensities changed dramatically with the stage of differentiation. Fresh tissue gave a radioactive profile similar to that for cultured differentiated cells, except for evidence of damage from the techniques used to separate the epidermis from the dermis (the damage being progressively more severe going from heat to ammonium chloride to trypsin separation). The labeling patterns for three carcinogen-transformed cell lines were markedly different from those of the normal cells. The least tumorigenic cell line had a profile in many respects intermediate between those of the normal differentiated and undifferentiated cells, while the other 2 lines showed greater deviation.

The distribution of binding sites for two lectins with different specificities was studied in adult mice by staining paraffin sections with lectins labeled either with fluorescein isothiocyanate or horseradish peroxidase. Binding sites for Dolichos biflorus agglutinin, a lectin specific to terminal alpha-N-acetylgalactosamine residue, were detected only in several restricted regions, such as collecting tubules and Bowman's capsules of the kidney, bile ducts, pancreatic ducts, sperms, oocytes, some secreting cells, and the secreted mucin itself. Binding sites for peanut agglutinin (PNA), a lectin specific to terminal beta-galactosyl residue, were distributed more widely. However, differentiation-dependent alterations in the expression of PNA binding sites have been observed in two types of cell lineage. During the course of spermatogenesis, the binding sites were expressed at the stage of spermatocytes. In the epithelium of esophagus, the binding sites were present in cells of the superficial layer.

Cell surface proteins of normal human, mouse, and rat cells in primary culture, of human basal cell carcinoma, and of carcinogen-transformed cell lines were examined by lactoperoxidase-catalyzed iodination. Autoradiography was used to record the distribution of label in the polypeptide subunits separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis. There was no significant difference in the results for normal cells of human, mouse, and rat. On the other hand, carcinogen-transformed mouse cells had many more labeled polypeptide bands of widely distributed molecular weights. The iodination profiles from human basal cell carcinoma cells were much more akin to those from normal cells than to those from carcinogen-transformed cells. Treatment of iodinated cells with proteolytic enzymes visibly altered the polypeptide bands.