Distribution of proteoglycans and hyaluronic acid in transverse sections of bovine thoracic aorta

Preferential lectin binding to specific layers of rat oral epithelium and modification by enzyme pretreatment

Three fluorescein-labeled lectins were shown to bind differentially to cell surfaces in different epithelial layers of rat oral mucosa regardless of the age or the site of origin of the tissue. Griffonia simplicifolia (GS-1-B4), specific for alpha-D-galactosyl end groups, labeled basal cells only; Ulex europeus (Ulex 1) specific for alpha-L-fucosyl groups labeled spinous cells; and Bandeiraea simplicifolia (BSII), specific for N-acetyl-D-glucosamine, labeled cornified cells. Pretreatment of sections with alpha-galactosidase completely abolished the staining of basal cells by GS-1-B4, but had no effect on the staining of spinous cells by Ulex 1. In contrast, alpha-fucosidase abolished the staining of spinous cells by Ulex 1 and caused staining of both basal and spinous cells by GS-1-B4. Neuraminidase and chondroitinase ABC produced results similar to one another, with staining of basal cells by GS-1-B4 and labeling of both basal and spinous cells with Ulex 1. beta-galactosidase, beta-glucuronidase, and testicular hyaluronidase did not affect the staining pattern of GS-1-B4 or Ulex 1, whereas chymotrypsin completely abolished any staining with either lectin. The results demonstrate a complex arrangement of cell surface carbohydrates in the epithelium of rat oral mucosa. The findings indicate a possible simplification in the spatial arrangements of cell surface carbohydrates during the differentiation of basal to spinous cells.

Lectin binding to elastic fibres and associated components during development of the human aorta

A panel of peroxidase-conjugated lectins was used to stain frozen sections of human foetal, neonatal, infant and adult aortae. Two main distinctive staining patterns were observed at the light microscope level, depending on the lectin employed. Lectins from Concanavalin A, Triticum vulgaris, Arachis hypogaea and Glycine max resulted in staining of the surfaces of aortic elastic lamellae and the interlamellar areas. With lectins from Dolichos biflorus and Bandeiraea simplicifolia staining was seen predominantly in the interlamellar areas. The findings indicate the presence of several different glycoconjugates at various sites within the aorta. In addition, there were alterations in the lectin binding affinities of the aortae that were dependent upon age. The findings are interpreted as indicating sequential changes in the composition of glycoprotein or proteoglycan moieties in the development of the human aorta.

Investigation of relationships between collagens, elastin and proteoglycans in bovine thoracic aorta by immunofluorescence techniques

Types I, III and V collagens and proteoglycan were localized in the aorta by indirect immunofluorescence techniques. Type I collagen was more prominent in media and adventitia than in intima while type III collagen predominated in intima and media but appeared less significant in adventitia. Type V collagen was observed in intima and media only and was seen surrounding smooth muscle cells. Type I collagen was located between elastic fibres but type III collagen appeared to envelop the fibres, suggesting an interaction between elastic fibres and type III collagen. Pretreatment of sections with testicular hyaluronidase caused no changes in staining for type I collagen, but adventitial areas showed increased staining for type III collagen. After digestion with chondroitinase ABC, intimal and medial areas showed increased staining for type III collagen. Therefore, type III collagen forms stronger interactions with proteoglycans and hyaluronic acid than does type I collagen and type III collagen in adventitia is largely masked by hyaluronic acid, while type III collagen in intima and media is associated with proteoglycan. Thus, type III collagen is a more significant component of adventitia than previously recognized. Proteoglycan was also partly localized along elastic fibres. It is, therefore, suggested that elastic fibres are coated with type III collagen, which itself is coated with proteoglycan.