A specific fluorometric assay for hexosamines in glycosaminoglycans, based on deaminative cleavage with nitrous acid.

Glycosaminoglycan (GAG) hexosamines were measured after deacetylation (2 h acid hydrolysis), deaminative cleavage by nitrous acid, and coupling of the 2,5-anhydro sugars thus produced with 3,5-diaminobenzoic acid (DABA) to give a fluorescent product. Analyses were performed after the addition of an aliquot of potassium acetate solution to the acid hydrolysates, to adjust the pH. Results on a series of GAGs were compared with an Elson-Morgan (E-M) procedure. Our method is faster, more convenient, 10-20 times more sensitive, and always gave higher figures for hexosamine content. In particular it avoids long, destructive hydrolysis in concentrated strong acid and the complications of the Moggridge-Neuberger effect. Results agreed with calculations and titrimetric data. Using internal standards, our method is tolerant of cetylpyridinium chloride, peptides, and salts. A simple fluorometer easily handled less than 1 microgram GAG per sample in 1.0 ml volume. Results are available in 4-5 h. The method is suitable for automation. A strongly polycationic environment, as in chitosan, markedly slowed nitrous acid deamination, possibly because of Donnan-type exclusion from the domain of the polycation of the cationic nitrosonium species. Whereas all other alpha- and beta-hexosaminides gave yield-hydrolysis time profiles that peaked in approximately 1 h in the DABA method, the E-M profiles, particularly for 2-sulfamato-alpha-hexosaminides, took longer and/or achieved lower optimal yields. All the usually encountered forms of the 2-amino-2-deoxy group (free, acetylated, sulfamato) are readily assayed using the same reagents, with appropriate prefluorometric stages.

The chemical morphology of age-related changes in human intervertebral disc glycosaminoglycans from cervical, thoracic and lumbar nucleus pulposus and annulus fibrosus.

Hyaluronan (HA), chondroitin and keratan sulphates (CS, KS), collagen and dry weights were measured in the annulus fibrosus and nucleus pulposus of human cervical, thoracic and lumbar intervertebral discs aged 36-79 y. Alcian blue-critical electrolyte concentration (CEC) staining of sections extended the results. The collagen, total polyanion, HA, CS and KS contents of the nucleus pulposus and annulus fibrosus were plotted for all 3 regions against age. Regional differences and age-related trends were found. For regional differences, the collagen content of the nucleus pulposus was highest in cervical discs and lowest in lumbar discs. In contrast, the total polyanion content of the nucleus pulposus was highest in lumbar discs and lowest in cervical discs. These differences were seen in fetal and adult discs. With respect to age-related trends, the collagen content of the annulus fibrosus was higher in adults and children than in neonates and infants. The collagen content of the nucleus pulposus increased with age in thoracic and lumbar discs, but it was consistently high in cervical discs. There was generally a downward trend of total polyanion and CS with increase in age. This was quite consistent for the annulus fibrosus in all regions and there were dramatic decreases in the lumbar nucleus pulposus in all adults compared with infants and children. These trends were least evident in the cervical nucleus pulposus where infant values were low. CS changes correlated with water content. HA and KS increased in all discs with increasing maturity. Oversulphated KS, absent from fetal discs, reached mature levels by 10 y. Many of the changes occurred before maturity. Glycosaminoglycan (GAG) levels correlated with increasing compressive loads. Higher collagen levels in the cervical nucleus pulposus correlated with greater ranges of torsional and shearing strains in cervical discs. High GAG levels in cervical annulus fibrosus probably facilitate lamellar movements during torsional and flexional movements by lubrication and increase of tissue compressibility. Increased KS/CS ratios before maturity correlated with decreased disc blood supply. Ambient O2 tensions may determine KS/CS balance, the former consuming little O2 during biosynthesis.

The chemical morphology of extracellular matrix in experimental rat liver fibrosis resembles that of normal developing connective tissue.

The time course of development of extracellular matrix (ECM) in experimentally induced fibrosis (thioacetamide administration followed for 12 weeks or bile duct ligation for 8 weeks) in adult rats was examined by light and electron microscopy, using Alcian blue or Cupromeronic blue staining for sulphated proteoglycans (PGs) in critical electrolyte concentration techniques. Proteodermatan sulphate (PDS) was regularly observed at the gap zone of the collagen fibrils. Morphometry of uranyl acetate-stained collagen fibrils, polarity of their banding patterns (a-e), statistics of d/e band occupancies by PDS, and lengths and thicknesses of PG filaments were quantified. Biochemical analyses showed that the ECM components collagen, hyaluronan, chondroitin and dermatan sulphates increased by 5-10 fold, roughly in parallel, as did heparan sulphate and DNA. Water and lipid contents also increased sharply. Thioacetamide treatment was much slower than bile duct ligation in producing fibrotic changes of equal severity. Sulphation of anionic glycosaminoglycans (AGAGs) decreased with increasing severity of fibrosis. Biochemical and ultrastructural methods correlated well. The large increase in dermatan sulphate was quantitatively as expected, given that it is collagen fibril surface-associated, and there was an increase of collagen content together with a decrease in fibril thicknesses. The increase in DNA reflected the marked increase in cell numbers in fibrotic livers. The chemical morphology of the new connective tissue closely resembled that in e.g. developing young tendon, in that fibrils were thinner, and AGAG levels were higher. The collagen fibrils were often disarranged, rather than ordered and parallel as in normal ECM. No other indication of abnormality in the new ECM was obtained.

Human intervertebral disc acid glycosaminoglycans.

Alcian blue critical electrolyte concentration (CEC) staining of intervertebral discs (annulus and nucleus of cervical, thoracic and lumbar discs) distinguished 3 groups where CEC staining correlated with age (less than 3 months; from 3 months to 5 years; over 10 years). The CEC increased markedly (implying increased sulphation of the glycosaminoglycans) in the period of maturation (fetal life to 10 years) and then remained constant throughout adult life. This is at variance with accepted views which attribute such changes to degenerative changes in old age. The major part of the CEC increase occurred after the disappearance of blood vessels from the disc, which is almost complete by 4 years. Our results are compatible with the hypothesis that keratan sulphate replaces chondroitin sulphate, functionally, in conditions of oxygen lack.

A comparative biochemical and ultrastructural study of proteoglycan-collagen interactions in corneal stroma. Functional and metabolic implications.

1. Corneas of mouse, rat, guinea pig, rabbit, sheep, cat, dog, pig and cow were quantitatively analysed for water, hydroxyproline, nucleic acid, total sulphated polyanion, chondroitin sulphate/dermatan sulphate and keratan sulphate, several samples or pools of tissue from each species being used. Ferret cornea was similarly analysed for water and hydroxyproline on one pool of eight corneas. Pooled frog (38) and ferret (eight) corneas and a single sample of human cornea were qualitatively examined for keratan sulphate and chondroitin sulphate/dermatan sulphate by electrophoresis on cellulose acetate membranes. Nine species (mouse, frog, rat, guinea pig, rabbit, sheep, cat, pig and cow) were examined by light microscopy and six (mouse, frog, rat, guinea pig, rabbit and cow) by electron microscopy, with the use of Alcian Blue or Cupromeronic Blue in critical-electrolyte-concentration (CEC) methods to stain proteoglycans. 2. Water (% of wet weight), hydroxyproline (mg/g dry wt.) and chondroitin sulphate (mg/g of hydroxyproline) contents were approximately constant across the species, except for mouse. 3. Keratan sulphate contents (mg/g of hydroxyproline) increased with corneal thickness, whereas dermatan sulphate contents decreased. The oversulphated domain of keratan sulphate was absent from mouse and frog corneas, increasing as percentage of total keratan sulphate with increasing corneal thickness. Sulphation of dermatan sulphate was essentially complete (i.e. one sulphate group per disaccharide unit). 4. Chondroitin sulphate/dermatan sulphate proteoglycans were present at the d bands of the collagen fibrils of all species examined, orthogonally arrayed, with high frequency, and occasionally at the e bands. Keratan sulphate proteoglycans were present at the a and c bands of all species examined, but with far higher frequency in the thicker corneas, where keratan sulphate contents were high. 5. Alcian Blue CEC staining showed much higher sulphation of keratan sulphate in thick corneas, e.g. that of cow, than in thin corneas, e.g. that of mouse, in keeping with biochemical analyses. 6. It is suggested that the constancy of interfibrillar volumes is regulated via the swelling and osmotic pressure of the interfibrillar polyanions, by adjustment of the extent of sulphation in two independent proteoglycan populations, to achieve an 'average sulphation' of the total polyanion similar to that of fully sulphated chondroitin sulphate/dermatan sulphate. 7. The balance of synthesis of the two kinds of proteoglycans may be determined by the O2 supply to the avascular cornea. O2 supply may also determine the conversion of chondroitin sulphate into dermatan sulphate.

The comparative chemical morphology of the mammalian cornea.

A simple model of mammalian corneal stroma has been tested against biochemical and ultrastructural measurements performed on a number of species. Contents of water, collagen and total sulphated polyanion were constant, as predicted from the model. Alcian blue CEC results showed great variability between species, with a rise in CEC as corneal size and thickness increased. These variations were due to changes in keratan sulphate content, and particularly to its oversulphated terminal domain, which is absent from mouse cornea. The increase in keratan sulphate content with corneal thickness was balanced by an increase in dermatan sulphate in thin corneas, thus maintaining total sulphated GAG levels at a constant "average", in all the mammals investigated. This balance is probably decided by oxygen tension, which will vary with corneal thickness.