Comparisons between extracted and residual proteoglycans on the glycosaminoglycan level and changes with ageing

Plyometric exercise increases serum indices of muscle damage and collagen breakdown

The aim of the present study was to examine the effect of acute plyometric exercise on indices of muscle damage and collagen breakdown. Nine untrained men performed an intense bout of plyometric jumping exercises (experimental group) and nine men remained at rest (control group). Seven days before and 24, 48, and 72 hours after plyometric exercise or rest, several physiological and biochemical indices of muscle damage and two biochemical indices of collagen damage were determined. No significant changes in concentric and eccentric peak torque of knee extensors and flexors or flexion and extension range of motion were found after the plyometric exercise. Delayed-onset muscle soreness increased 48 hours after exercise. Creatine kinase increased 48 and 72 hours post exercise, whereas lactate dehydrogenase increased 24, 48, and 72 hours post exercise. Serum hydroxyproline increased 24 hours post exercise, peaked at 48 hours, and remained elevated up to 72 hours post exercise. Hydroxylysine (which was measured only before exercise and at 48 hours) was found increased 48 hours post exercise. No differences were found in any physiological or biochemical index in the control group. Intense plyometric exercise increased muscle damage, delayed-onset muscle soreness, and serum indices of collagen breakdown without a concomitant decrease in the functional capacity of muscles. Hydroxyproline and hydroxylysine levels in serum seem promising measures for describing exercise-induced collagen degradation. Coaches need to keep in mind that by using plyometric activities, despite the increased muscle damage and collagen turnover that follow, it is not necessarily accompanied by decreases in skeletal muscle capacity.

Detection, quantification, and glycotyping of prion protein in specifically activated enzyme-linked immunosorbent assay plates

The conversion of a normal glycoprotein, prion protein (PrP(C)), to its abnormal protease-resistant isoform (PrP(Sc)) seems to be one of the main factors underlying the pathogenesis of spongiform encephalopathies. There are many studies indicating that PrP interacts with glycosaminoglycans, and we exploited this interaction to develop a sensitive solid phase assay for detection of both PrP forms. Glycosaminoglycans, such as chondroitin sulfate and heparin, were immobilized by their negative charge to enzyme-linked immunosorbent assay (ELISA) plate wells activated by glutaraldehyde and spermine. PrP in the samples examined (recombinant PrP or tissue homogenate) was allowed to interact with glycans. The interaction of recombinant PrP was more efficient against immobilized chondroitin sulfate of type A, and a linear correlation with concentration was demonstrated. From this curve, the concentration of each one of the PrP isoforms in biological samples can be determined. In addition, and taking into account that glycosylation of prion protein is species specific, we used similarly activated ELISA plate wells to determine different PrP glycoforms. A monoclonal antibody against PrP was immobilized, and PrP present in the samples (brain homogenates) was bound and visualized by various lectins. The most interesting outcome of the study is the differential binding of ricinus communis agglutinin I to the normal and scrapie brain homogenates. Dattura stramonium lectin and wheat germ agglutinin seem to bind almost equally to both samples, and all three have an increased sensitivity to PrP(Sc) after proteinase K digestion.

A solid phase assay for the determination of heparan sulfate and its application to normal and cancerous human cartilage samples

A sensitive and accurate quantitative assay for the measurement of minor amounts of chondroitin/dermatan sulfate and heparan sulfate that does not require specific apparatus or reagents is described. The assay involves labeling of chondroitin sulfate A following reaction of carboxyl groups with biotin hydrazide in the presence of carbodiimide. ELISA plate wells were coated with glutaraldehyde and then spermine was coupled to it via a Schiff's base bond. In such activated wells, the biotinylated molecules were readily bound and detected after the interaction with avidin-peroxidase conjugates and the subsequent enzymic assay. Chondroitin/dermatan sulfate and heparan sulfate competed this interaction in a linear manner. Disaccharides derived from chondroitin sulfate A did not act as competitors, while heparan sulfate disaccharides showed significant competition. From the competition, before and after digestion with either chondroitinase ABC or heparitinases, the amounts of chondroitin sulfate and heparan sulfate in a sample could be calculated. The assay was applied for the determination of sulfated glycosaminoglycans in normal and cancerous human laryngeal cartilage samples. By using this procedure, the accurate determination, especially, of heparan sulfate in a mixture of glycosaminoglycans was achieved, which otherwise would require the use of very expensive technology.

High-performance capillary electrophoretic analysis of hyaluronan and galactosaminoglycan-disaccharides in gastrointestinal carcinomas. Differential disaccharide composition as a possible tool-indicator for malignancies

The glycosaminoglycans (GAGs) have documented implications for the growth and progression of malignant tumors. Gastrointestinal carcinomas (gastric, colon, rectum and pancreatic) are the most frequent malignancies occurring in human. GAGs, isolated from the tissues after digestion with papain, were analyzed by high-performance capillary electrophoresis (HPCE) following treatment with chondroitinase ABC. The composition of GAGs in disaccharides derived from the various gastrointestinal carcinomas was compared with those of normal tissues. We report that human gastrointestinal carcinomas are characterized by increased concentrations of GAGs, which have quite different disaccharide composition which, in turn, is associated with marked increase of non-sulfated (Delta(di)-nonS) and 6-sulfated (Delta(di)-mono6S) Delta-disaccharides. Particularly, a 12-51-fold increase in Delta(di)-nonS and a 3-42-fold increase in Delta(di)-mono6S content characterize these carcinomas, while the 4-sulfated units (Delta(di)-mono4S) showed a lower increase, about 0.5-1.5-fold. Moreover, the quantitation of hyaluronan (HA)-derived Delta-disaccharides (Delta(di)-nonS(HA)) also revealed a marked increase (1-12-fold) in the malignant tissues. On the other hand, the content of the chondroitinase ABC-resistant GAGs showed a low decrease, about 0.2-0.7-fold. The high amounts of hyaluronan (HA) produced by these carcinomas and the ectopic production of chondroitin sulphate (CS) proteoglycans, in which (Delta(di)-nonS) and (Delta(di)-mono6S) predominated, suggest a close relation between the content of these GAGs and the malignant phenotype, the metastatic ability and the survival time.

Isolation and characterization of matrix proteoglycans from human nasal cartilage. Compositional and structural comparison between normal and scoliotic tissues

The content, types and the fine structures of proteoglycans (PGs) present in human normal nasal cartilage (HNNC) were investigated and compared with those in human scoliotic nasal cartilage (HSNC). Three PG types were identified in both HNNC and HSNC; the large-sized high buoyant density aggrecan, which is the predominant PG population, and the small-sized low buoyant density biglycan and decorin. HSNC contained a significantly higher amount of keratan sulfate (KS)-rich aggrecan (30%) of smaller hydrodynamic size as compared to HNNC. The average molecular sizes (M(r)s) of aggecan-derived chondroitin sulfate (CS) chains in both HNNC and HSNC were identical (18 kDa), but they significantly differ in disaccharide composition, since CS isolated from HSNC contained higher proportions of 6-sulfated disaccharides as compared to those from HNNC. Scoliotic tissue contained also higher amounts (67%) of the small PGs, biglycan and decorin as compared to HNNC. It is worth noticing that both normal and scoliotic human nasal cartilage contain also non-glycanated forms of decorin and biglycan. Dermatan sulfate (DS) was the predominant glycosaminoglycan (GAG) present on biglycan and decorin in both tissues. The small PGs-derived CS chains in both normal and scoliotic cartilage had the same M(r) (20 kDa), whereas DS chains from scoliotic cartilage were of greater M(r) (32 kDa) than those from normal cartilage (24 kDa). Furthermore, scoliotic tissue-derived DS chains contained higher amounts of iduronate (20%) as compared to those of normal cartilage (12%). Disaccharide analysis of small PGs showed that both HNNC and HSNC were rich in 4-sulfated disaccharides and in each case, the small size PGs contained a considerably higher proportion of 4-sulfated disaccharides than the aggrecan of the same tissue. The higher amounts of matrix PGs identified in scoliotic tissue as well as the differences in fine chemical composition of their GAG chains may reflect the modified architecture and functional failure of scoliotic tissue.

Characterization of glycosaminoglycans from human normal and scoliotic nasal cartilage with particular reference to dermatan sulfate

The composition and the distribution of glycosaminoglycans (GAGs) present in normal human nasal cartilage (HNNC), were examined and compared with those in human scoliotic nasal cartilage (HSNC). In both tissues, hyaluronan (HA), keratan sulfate (KS) and the galactosaminoglycans (GalAGs)--chondroitin sulfate (CS) and dermatan sulfate (DS)--were identified. The overall GAG content in HSNC was approx. 30% higher than the HNNC. Particularly, a 114% increase in HA, and 46% and 86% in KS and DS, respectively, was recorded. CS was the main type of GAG in both tissues with no significant compositional difference. GalAG chains in HSNC exhibited an altered disaccharide composition which was associated with significant increases of non-sulfated and 6-sulfated disaccharides. DS, which was identified and quantitated for the first time in HNNC and HSNC, contained low amounts of iduronic acid (IdoA), 18% and 28% respectively. In contrast to other tissues, where IdoA residues are organized in long IdoA rich repeats, the IdoA residues of DS in human nasal cartilage seemed to be randomly distributed along the chain. DS chains in HSNC were of larger average molecular size than those from HNNC. These results clearly indicate the GAG content and pattern in both HNNC and HSNC and demonstrate that scoliosis of nasal septum cartilage is related to quantitative and structural modifications at the GAG level.

Pancreatic carcinoma is characterized by elevated content of hyaluronan and chondroitin sulfate with altered disaccharide composition

The amount and the types of glycosaminoglycans (GAGs) present in human pancreatic carcinoma were examined and compared with those in normal pancreas. Human pancreatic carcinoma contained increased levels (4-fold) of total GAGs. Particularly, this carcinoma is characterized by a 12-fold increase of hyaluronan (HA) and a 22-fold increase in chondroitin sulfate (CS) content. CS in pancreatic carcinoma exhibited an altered disaccharide composition which is associated with marked increase of non-sulfated and 6-sulfated disaccharides. Dermatan sulfate (DS) was also increased (1.5-fold) in carcinoma, whereas heparan sulfate (HS), the major GAG of normal pancreas, becomes the minor GAG in pancreatic carcinoma without significant changes in the content and in molecular size. In all cases, the galactosaminoglycans (GalGAGs, i.e. CS and DS) derived from pancreatic carcinomas were of lower molecular size compared to those from normal pancreas. The results in this study indicate, for the first time, that human pancreatic carcinoma is characterized by highly increased amounts of HA and of a structurally altered CS.

A solid-phase assay for quantitative analysis of sulfated glycosaminoglycans at the nanogram level. Application to tissue samples

A sensitive and accurate solid-phase methodology for the quantitative analysis of glycosaminoglycans is described. Chondroitin-4-sulfate (CSA) was labelled with biotin hydrazide after the reaction of its carboxyl groups with it in the presence of carbodiimide. Polystyrene plates modified with sequential reaction with glutaraldehyde (GH) and spermine to possess amino groups were used to immobilize electrostatically the biotin labelled CSA. Exogenously added sulfated glycosaminoglycans (GAGS) [variously sulfated chondroitin sulfates and heparan sulfate (HS)] were found to compete to this immobilization in a concentration dependent mode, within a concentration range from 10 up to 300 ng/ml. Glycosaminoglycan-derived oligosaccharides competed to a degree similar to that of intact molecules. Hyaluronan (HA) and keratan sulfate (KS) did not compete the immobilization. The procedure was applied for the rapid and reproducible determination of the sulfated glycosaminoglycans in proteinase digests of small tissue samples or cell cultures with high sensitivity and accuracy.

Aggrecan immobilization onto polystyrene plates through electrostatic interactions with spermine

A new procedure for the immobilization of proteoglycans and the core protein thereof via their carbohydrate chains onto enzyme-linked immunosorbent assay (ELISA) plate wells is presented. The aggrecan was immobilized via electrostatic interactions with spermine coupled to glutaraldehyde via Schiff's base, the latter being directly anchored onto ELISA wells. The amounts of aggrecan bound by this procedure measured immunochemically were 10-fold greater than those adsorbed by direct coating. The interaction of aggrecan and spermine may be inhibited by very small amounts of sulfated glycosaminoglycans or proteoglycans in a competitive manner, and therefore the system may be used for their quantitation. Bound aggrecan could react with link protein and therefore the system may be used for studying interactions of cartilage macromolecules. The method may also be used for direct quantitation of proteoglycans since the amounts adsorbed, in a given range of concentrations, are directly proportional to the amounts in solution.

Aging of the normal nose in adults

Like other organs, the nose changes as the body ages. A review of the literature reveals a basic understanding of the aging process in the nose but a paucity of documentation and few organized studies. This study was designed to identify systematically the agerelated changes in the normal, nondiseased adult nose. A nasal-sinus laboratory was created, and a computerized patient database was developed. Four separate investigations were conducted. First, 111 subjects ranging in age from 21 to 94 years of age were studied prospectively using 135 variables. The following data were collected: history, symptoms, physical examination, rhinomanometry, ciliary beat frequency, smell testing, and incentive spirometry. Second, photographs of a separate group of 105 subjects 20 to 86 years of age were studied to ascertain the facial cephalometric changes that occur with aging. Third, a histopathologic examination of the nasal septum was performed in 20 additional subjects to evaluate the cellular changes that accompany aging. Finally, an epidemiologic study analyzing the prevalence of various nasal complaints by age was conducted, based on a review of more than 11,000 patient charts from surgeries and office visits. A number of specific age-related changes in the nose were identified, including an increased likelihood of certain nasal complaints, a pattern of increasing airflow resistance, and a decrease in physical abnormalities in the nasopharynx. The appearance of the nose, as measured by the nasolabial angle and the height/length ratio, was also found to change with age.

Proteoglycan heterogeneity in the normal adult ovine intervertebral disc

Proteoglycans (PGs) were isolated from 4 M GuHCl extracts of young adult ovine Intervertebral disc (IVD) tissues using sequential CsCl density gradient centrifugation, and a combination of gel-permeation and hydrophobic chromatography. A total of six PG sub-populations were identified in both the Annulus fibrosus (AF) and Nucleus pulposus (NP), i.e. two high buoyant density aggregatable PGs, two high buoyant density non-aggregatable PGs and two small, low-intermediate buoyant density, non-aggregatable, DS-rich PG species. These latter PGs were identified as biglycan and decorin on the basis of analyses of their core protein native size, and glycosaminoglycan composition. Additional low-intermediate buoyant density PG species were also evident in the non-aggregatable PG pool, particularly in extracts of NP tissues. These PGs did not bind to the octyl affinity matrix under the experimental conditions employed and thus were readily separated from the DS-PGs by hydrophobic chromatography, their constituent glycosaminoglycans (CS and KS) also differed and were of a smaller size to the CS and KS chains isolated from the large high buoyant density PGs, the small PGs which did not bind to octyl-sepharose may therefore represent distinct PG species in their own right. Differences were evident in the absolute size, and in the distribution of individual PG species in the respective IVD tissues but the NP always contained a larger proportion of high buoyant density non-aggregatable PGs of somewhat smaller size than those isolated from the AF. Decorin and biglycan, however, were generally more abundant in AF tissues.

Kinetic studies on activation of peptide bond formation by hyaluronic acid

1. In this study, a cell-free system derived from Escherichia coli has been used in order to examine in detail the effect of hyaluronic acid on peptide bond formation with the aid of puromycin reaction. 2. This reaction is activated by hyaluronic acid. 3. The degree of activation of peptide bond formation depends on the molecular size of hyaluronic acid. 4. The kinetic analysis revealed that the hyaluronic acid acts as a mixed-type nonessential activator. 5. The presence of hyaluronic acid improves about 9-fold the activity status of ternary complex as it can be calculated by k3/k5 ratio.

Effect of glycosaminoglycans on peptide bond formation in bacterial ribosomes

1. A cell-free system derived from E. coli has been used in this study. The process of peptide bond formation was assessed with the aid of the puromycin reaction, which is catalyzed by peptidyltransferase. 2. This reaction is inhibited by heparin, in contrast, this reaction is activated by hyaluronic acid. 3. The presence of heparin decreases the percentage of formed initiation complex (complex C), but hyaluronic acid, chondroitin sulphate and keratan sulphate have no effect on the formation of complex C. 4. From other types of glycosaminoglycans, only hyaluronic acid increases the stability of active complex C.

Age-related changes in the composition of proteoglycans in sheep cartilages

Age-related changes in the proteoglycans of costal, tracheal, nasal and xiphoid cartilages of sheep, starting at 100 days in utero to 1 year postnatally and in scapular cartilages up to 13 years of age, have been assessed. The amino acid compositions of the core proteins in the proteoglycans from one-year-old cartilages are indistinguishable on the basis of kind of cartilage or of earlier stages of development. At 13 years of age, the core protein in the proteoglycans of scapular cartilages contains less glutamic acid/glutamine and glycine and more lysine, histidine, arginine, and threonine than at one year of age. Relative to the protein, the amount of chondroitin sulfates decreases with age but the amount of keratan sulfate increases. In part, this is a reflection of a decrease in the size of the chondroitin sulfate chains and an increase in the size of the keratan sulfate chains. Up to one year of age, the ratio of chondroitin-4-sulfate to chondroitin-6-sulfate increases in the scapular cartilages. From two to nine years of age, this ratio remains relatively constant at 1.7. At 100 days in utero, about 12% of the disaccharide repeats in the chondroitin sulfate are notsulfated, and this fraction progressively decreases to about 1% by two years postnatally. After one year of age, the size of the proteoglycan monomers decreases. As indicated by sedimentation velocity analysis, the proportion of monomers in aggregate form increases up to 1-2 years of age and then decreases. At 100 days of age the "immature" core protein does not react in vitro with hyaluronan and link proteins to form aggregates discernable in the ultracentrifuge.

Maturation of proteoglycan matrix in articular cartilage under increased and decreased joint loading. A study in young rabbits

The right knees of 4-month-old NZW rabbits were splinted in extension for 1 to 8 weeks. Biochemical changes of the knee articular cartilage were noted after decreased (splinted leg) and increased loading (created by the shift of body weight onto the left, contralateral limb). Increased loading accelerated changes associated with maturation of articular cartilage, which include accumulation of hyaluronic acid (HA) and keratan sulfate-rich proteoglycans (KS, PG) that are tightly bound to the tissue. After 8-weeks of splinting the content of extractable PGs in the tibial medial condyle decreased. The lost material was apparently replaced by PGs with a higher degree of sulfation of the chondroitin sulfate (Ch-S) chains. Reduced loading disturbed normal maturation as evidenced by inhibition of the accumulation of KS-rich, non-extractable PGs. Collagen content increased in all samples of different joint sites and groups during the 8-week experiment. The content of extractable PGs decreased slightly, while the content of non-extractable, especially KS-rich PGs increased. The greatest changes occurred in the tibial medial condyle, where the KS content was highest.

Age-related changes of proteoglycan subunits from sheep nasal cartilage

Proteoglycan subunits of sheep nasal cartilage from animals of five different ages were studied. There is a continuous reduction in the size and chondroitin sulphate content of the aggregable and non-aggregable subunits with ageing. For each age group, the non-aggregable are poorer in protein and keratan sulphate than the corresponding aggregable molecules. Irrespective of age, the amount of proteoglycan protein extracted from each gramme wet cartilage is the same. The amino acid composition and the proportion of the aggregable proteoglycans are also the same.