Immunohistochemical staining for chondroitin sulphate and keratan sulphate. An evaluation of two monoclonal antibodies

Immunohistochemical staining with commercially available antibodies against chondroitin sulphate (clone CS-56) and keratan sulphate (clone 1/20/5-D-4) was compared with two conventional histochemical methods for the demonstration of glycosaminoglycans, namely Alcian Blue with varying pH and critical electrolyte concentrations, and a modified PAS stain. The antibodies were tested on sections from both frozen and fixed, paraffin embedded human material from umbilical cord, skin, and bronchus. The results showed immunostaining to function equally well on frozen and routine sections, and to be superior to Alcian Blue and PAS with regard to morphological detail. Thus, reactivity with anti-chondroitin sulphate was demonstrated in vessel walls, in small nerves, in the basal membrane zone of the skin, in perichondrium, and in and around chondrocytes. Reactivity with anti-keratan sulphate occurred in chondroid matrix and in perichondrial tissue; however, some cells of the bronchial epithelium and mucous glands also exhibited positivity.     

Immunohistochemical staining for chondroitin sulphate and keratan sulphate. An evaluation of two monoclonal antibodies

Summary Immunohistochemical staining with commercially available antibodies against chondroitin sulphate (clone CS-56) and keratan sulphate (clone 1/20/5-D-4) was compared with two conventional histochemical methods for the demonstration of glycosaminoglycans, namely Alcian Blue with varying pH and critical electrolyte concentrations, and a modified PAS stain. The antibodies were tested on sections from both frozen and fixed, paraffin embedded human material from umbilical cord, skin, and bronchus. The results showed immunostaining to function equally well on frozen and routine sections, and to be superior to Alcian Blue and PAS with regard to morphological detail. Thus, reactivity with anti-chondroitin sulphate was demonstrated in vessel walls, in small nerves, in the basal membrane zone of the skin, in perichondrium, and in and around chondrocytes. Reactivity with anti-keratan sulphate occurred in chondroid matrix and in perichondrial tissue; however, some cells of the bronchial epithelium and mucous glands also exhibited positivity.     

Temporo-spatial distribution of matrix and microfilament components during odontoblast and ameloblast differentiation

Summary Several extracellular matrix components (procollagen type III, fibronectin, collagen type IV, laminin and nidogen) and microfilament constituents (actin, α-actinin and vinculin) were localized by indirect immunofluorescence microscopy in frozen sections of embryonic mouse molars. Nidogen was present at the epithelio-mesenchymal junction during polarization and initial steps of functional differentiation of odontoblasts. Nidogen disappeared at a stage where direct contacts between preameloblasts and predentin were required to allow the initiation of ameloblast polarization. Our observations concerning the distribution of procollagen type III and fibronectin during odontoblast differentiation add to current knowledge. Procollagen type III and fibronectin surrounding preodontoblasts accumulated at the apical part of polarizing and functional odontoblasts secreting “initial” predentin. Procollagen type III, but not fibronectin, disappeared in front of functional odontoblasts synthesizing “late” predentin and dentin. Fibronectin, present in “initial” predentin, was no longer detected in “late” predentin and dentin but was found between odontoblasts secreting “late” predentin and dentin. Actin, α-actinin and vinculin were concentrated in the peripheral cytoplasm of preameloblasts and accumulated at the apical and basal poles of functional ameloblasts. During differentiation of odontoblasts, the three proteins accumulated at the apical pole of these cells. Time and space correlations between matrix and microfilament modifications during odontoblast and ameloblast differentiation are documented. The possibility is discussed that there is transmembranous control of the cytoskeletal activities of odontoblasts and ameloblasts by the extracellular matrix.     

Effect of oxygen tension and lactate concentration on keratan sulphate and chondroitin sulphate biosynthesis in bovine cornea.

Calf cornea slices were incubated with [U-14C]glucose, in varying pO2 or lactate concentrations. Acid glycosaminoglycans were separated by ion-exchange chromatography after papain digestion. The percentage radioactivity incorporated into keratan sulphate increased markedly with decreased oxygen tension, whereas a concomitant relative decrease of the biosynthesis of glycosaminoglycuronans occurred. Similar results were obtained with increased lactate concentration. Our findings support the idea that keratan sulphate is a functional substitute for chondroitin sulphate in conditions of oxygen lack (Scott, J.E. and Haigh, M. (1988) J. Anat. 158, 95-108).     

The distribution of sulphate residues in the chondroitin sulphate chain

1. Electrophoresis of chondroitin sulphate, before and after partial degradation with testicular hyaluronidase, revealed charge heterogeneity of the degraded but not of the intact polymer. 2. Hyaluronidase-treated chondroitin sulphate was fractionated by gel chromatography. Two subfractions which were essentially monodisperse with regard to molecular weight (values of 8600 and 4800, respectively) were separated further by chromatography on Dowex 1. The resulting subfractions differed considerably with respect to their sulphate/disaccharide molar ratios. 3. Amino acid and neutral-sugar analyses of the Dowex 1 subfractions showed that the less sulphated fragments contained the carbohydrate-protein linkage region, whereas the high-sulphated fragments essentially lacked this constituent. It was concluded that chondroitin sulphate contains relatively less sulphate in the vicinity of the carbohydrate-protein linkage region than in the more peripheral portion of the polysaccharide chain.     

Conformation of keratan sulphate

X-ray diffraction patterns from stretched films of keratan sulphate, isolated from bovine cornea, indicate that the molecules are twofold helices with an axial rise per disaccharide residue of 0.945 nm. These helices are oriented with their twofold screw axes parallel and about equally spaced, but are not further organized into regular crystalline arrays. Computer methods were used to construct a molecular model with the observed symmetry and axial rise per disaccharide residue, with standard bond lengths, bond angles and pyranose ring conformations and with a hydrogen bond of length 0.270 nm between O(3) of N-acetylglucosamine and O(5) of galactose. This model has no unacceptably short non-bonded interatomic distances. The intensity distribution of the diffraction pattern calculated from the co-ordinates of the model is in reasonable agreement with the observed intensity distribution. This keratan sulphate model is an extended polysaccharide chain fringed with charged sulphate side groups, and is similar to those that have already been reported for chondroitin sulphates and dermatan sulphate, paralleling the similarities in covalent structure and biological occurrence among these substances.     

Nature and distribution of chondroitin sulphate and dermatan sulphate proteoglycans in rabbit alveolar bone

Summary The type and distribution of mineral binding and collagenous matrix-associated chondroitin sulphate and dermatan sulphate proteoglycans in rabbit alveolar bone were studied biochemically and immunocytochemically, using three monoclonal antibodies (mAb 2B6, 3B3, and 1B5). The antibodies specifically recognize oligosaccharide stubs that remain attached to the core protein after enzymatic digestion of proteoglycans and identify epitopes in chondroitin 4-sulphate and dermatan sulphate; chondroitin 6-sulphate and unsulphated chondroitin; and unsulphated chondroitin, respectively. In addition, mAb 2B6 detects chondroitin 4-sulphate with chondroitinase ACII pre-treatment, and dermatan sulphate with chondroitinase B pre-treatment. Bone proteins were extracted from fresh specimens with a three-step extraction procedure: 4m guanidine HCl (G-1 extract), 0.4m EDTA (E-extract), followed by guanidine HCl (G-2 extract), to characterize mineral binding and collagenous matrix associated proteoglycans in E- and G2-extracts, respectively. Biochemical results using Western blot analysis of SDS-polyacrylamide gel electrophoresis of E- and G2-extracts demonstrated that mineral binding proteoglycans contain chondroitin 4-sulphate, chondroitin 6-sulphate, and dermatan sulphate, whereas collagenous matrix associated proteoglycans showed a predominance of dermatan sulphate with a trace of chondroitin 4-sulphate and no detectable chondroitin 6-sulphate or unsulphated chondroitin. Immunocytochemistry showed that staining associated with the mineral phase was limited to the walls of osteocytic lacunae and bone canaliculi, whereas staining associated with the matrix phase was seen on and between collagen fibrils in the remainder of the bone matrix. These results indicate that mineral binding proteoglycans having chondroitin 4-sulphate, dermatan sulphate, and chondroitin 6-sulphate were localized preferentially in the walls of the lacunocanalicular system, whereas collagenous associated dermatan sulphate proteoglycans were distributed over the remainder of the bone matrix.     

The structure and composition of cartilage keratan sulphate

Keratan sulphate was isolated from bovine intervertebral disc and bovine nasal septum after hydrolysis with proteinases and treatment with dilute alkali. Each preparation was found to contain, per keratan sulphate chain: (a) 1 residue of mannose; (b) 3 residues of N-acetylneuraminic acid (2 residues after alkali treatment); (c) 1 residue of N-acetylgalactosamine (lost after alkali treatment); (d) 1 residue or less of fucose. N-Acetyl-neuraminic acid residues were at non-reducing termini and were bonded to keratan sulphate through galactose residues. Evidence is presented for two different types of linkage between skeletal keratan sulphate and protein. Consideration of molecular parameters and compositions leads to a proposed structure for keratan sulphate-protein as found in skeletal proteoglycans.     

The alkali-labile linkage between keratan sulphate and protein

Keratan sulphate was isolated from adult intervertebral disc in 90% yield by sequential digestion of the whole tissue with papain, Pronase and Proteus vulgaris chondroitin sulphate lyase. Treatment of this preparation with alkali cleaved a glycosidic bond between N-acetylgalactosamine and threonine and produced, by an alkali-catalysed ;peeling' reaction, an unsaturated derivative of N-acetylgalactosamine which reacted as a chromogen in the Morgan-Elson reaction, but remained covalently bonded to the keratan sulphate chain. This derivative was reduced and labelled by alkaline NaB(3)H(4). The substituent at position 3 of N-acetylgalactosamine in the keratan sulphate-protein linkage was identified as a disaccharide, N-acetylneuraminylgalactose, which was isolated from the reaction mixture after alkali treatment.     

Sequential degradation of a chondroitin sulphate trisaccharide by lysosomal enzymes from embryonic-chick epiphysial cartilage.

The disulphated trisaccharide D-N-acetylgalactosamine sulphate-beta-D-glucuronic acid-beta-D-N-acetylgalactosamine sulphate prepared from 35S- or 14C-labelled chondroitin sulphate was incubated with a preparation of lysosomal enzymes from embryonic-chick epiphysial cartilage. Degradation was demonstrated by analysis of the reaction products. By use of the appropriate intermediate products as substrates, in conjunction with specific enzyme inhibitors, it was shown that the degradation proceeded sequentially from the non-reducing end. It was initiated by sulphatase (preferentially hydrolysing sulphate ester groups at the 6-position), followed by beta-N-acetylgalactosaminidase and beta-glucuronidase, converting the substrate into monosaccharides and inorganic sulphate. The latter enzyme preferentially attacked disaccharides carrying their sulphate ester group at C-4 of the hexosamine residue. Generation of chondroitin sulphate oligosaccharides may occur by the action of an endoglycosidase, previously demonstrated in embryonic-chick cartilage. Endo- and exo-enzymes may thus form a functional unit in lysosomal degradation of chondroitin sulphate.     

Malaria during pregnancy: parasites, antibodies and chondroitin sulphate A

CSA-binding forms of P. falciparum appear uncommonly in non-pregnant hosts but are selected by the human placenta for growth. Parasites are presumably selected by adherence to CSA within the vascular compartment of the placenta, allowing IRBCs to sequester and multiply to high density. Chondroitin sulphate appears on the surface of placental syncytiotrophoblasts, and CSA is a component of PGs found in the placenta [42], but the identification of the CSA-containing PG(s) mediating IRBC adhesion in vivo requires further study. Anti-adhesion antibodies against CSA-binding parasites are associated with protection from maternal malaria, but these antibodies develop only over successive pregnancies, accounting for the susceptibility of primigravidas to infection. PfCSA-L, the parasite ligand mediating adhesion to CSA, has not yet been identified but is known to be antigenically conserved among isolates from around the world. An anti-adhesion vaccine delivered to women before first pregnancy could confer protection from maternal malaria and might be globally effective.     

Immunofluorescent localization of vimentin, prekeratin and actin during odontoblast and ameloblast differentiation

The localization of constitutive proteins of different types of cytoskeletal components (prekeratin, vimentin, and actin) was examined in embryonic mouse molars using specific antibodies and immunofluorescence microscopy on frozen sections. Prekeratin and actin were found in the enamel organ. Preameloblasts demonstrated uniform staining, whereas ameloblasts demonstrated an apical accumulation of both prekeratin and actin. Vimentin and actin were observed in the dental papilla. A redistribution of vimentin accompanied the polarization of odontoblasts. A possible transmembranous control of cytoskeletal activities by the extracellular matrix is discussed.     

Immunological studies of sheep brain keratan sulphate proteoglycans

Recently, we reported the isolation and partial characterization of keratan sulphate (KS) from sheep brain. In this study, a panel of monoclonal antibodies (Mab) recognizing epitopes within KS chains and core proteins of KS-containing proteoglycans were used to detect, by immunoblotting, antigenically related molecules extracted from cerebrum, cerebellum and brainstem, respectively. Although the intensity of labelling varied with each of the antibodies, the brain KSPGs were recognized by all the monoclonals used, confirming the presence of KS side chains, which react with the Mabs: 5-D-4, EFG-11, EFG-4, I22, as also the presence of KSPGs related to phosphacan-KS (3H1 proteoglycan). Extracts of all the three brain areas could bind both anti-KS and anti-core protein Mabs, as also anti-HNK-1 monoclonal antibody. Binding was sensitive to keratanases degradation in the cerebrum and brainstem except cerebellum where the presence of a large molecular size hybrid CS/KSPG bearing KS chains partially resistant to keratanases was identified. This population reacts only with 5-D-4, EFG-11 and EFG-4 antibodies. Furthermore, the presence of HNK-1 epitope in CSPGs was detected in the cerebellum and brainstem. In contrast, in the cerebrum the coexistence of HNK-1 epitope and KS in KSPGs was identified. These data suggest that the KSs of sheep brain are part of proteoglycans containing protein and KS antigenic sites related to those of corneal and cartilage KSPG, as also of the brain proteoglycan phosphacan-KS.     

Differential expression of the keratan sulphate proteoglycan,keratocan, during chick corneal embryogenesis

Keratan sulphate (KS) proteoglycans (PGs) are key molecules in the connective tissue matrix of the cornea of the eye, where they are believed to have functional roles in tissue organisation and transparency. Keratocan, is one of the three KS PGs expressed in cornea, and is the only one that is primarily cornea-specific. Work with the developing chick has shown that mRNA for keratocan is present in early corneal embryogenesis, but there is no evidence of protein synthesis and matrix deposition. Here, we investigate the tissue distribution of keratocan in the developing chick cornea as it becomes compacted and transparent in the later stages of development. Indirect immunofluorescence using a new monoclonal antibody (KER-1) which recognises a protein epitope on the keratocan core protein demonstrated that keratocan was present at all stages investigated (E10–E18), with distinct differences in localisation and organisation observed between early and later stages. Until E13, keratocan appeared both cell-associated and in the stromal extracellular matrix, and was particularly concentrated in superficial tissue regions. By E14 when the cornea begins to become transparent, keratocan was located in elongate arrays, presumably associated along collagen fibrils in the stroma. This fibrillar label was still concentrated in the anterior stroma, and persisted through E15–E18. Presumptive Bowman’s layer was evident as an unlabelled subepithelial zone at all stages. Thus, in embryonic chick cornea, keratocan, in common with sulphated KS chains in the E12–E14 developmental period, exhibits a preferential distribution in the anterior stroma. It undergoes a striking reorganisation of structure and distribution consistent with a role in relation to stromal compaction and corneal transparency. E. Claire Gealy and Briedgeen C. Kerr were joint first authors.     

Sulphate release from keratan sulphate and heparan sulphate by bovine N-acetylglucosamine-6-sulphate sulphatase

The functions of sulphated monosaccharides within glycosaminoglycans(GAGs) and glycoproteins are being studied intensely, but progressis hindered by an inability to selectively desulphate glycoconjugates.We recently identified an N-acetylglucosamine-6-sulphate sulphatase(NG6SS) from bovine kidney that can remove sulphate from N-acetylglucosamine-6-sulphate(GlcNAc-6-SO₄) within oligosaccharides and glycoproteins. However,the potential ‘endosulphatase’ activity of the NG6SStoward GAGs is not known. To test for this possibility, [³H]glucosamine-,[³H]galactose- and ³⁵SO_4- labelled keratan sulphate (KS) wereseparately prepared by metabolic radiolabelling of bovine cornea.NG6SS quantitatively removed sulphate from KS without releaseof sugar fragments. The enzyme had a K_m of 4.7 mM toward freeGlcNAc-6-SO₄, but its K_m for commercially available bovine cornealKS was found to be 9.1 µM. Analyses of both KS and heparansulphate after treatment with NG6SS demonstrated significantloss of sulphate from GlcNAc-6-SO₄ in both GAGs. These findingsmay be relevant for future studies aimed at defining the function(s)of GlcNAc-6-SO₄ residues in GAGs and understanding the catabolismof GAGs, especially in regard to sulphatidoses, such as SanfilippoD syndrome in humans, which involves a deficiency of NG6SS activity catabolism endosulphatase glycosaminoglycans sulphation