The effect of synovial fluid proteins in the degradation of hyaluronic acid induced by ascorbic acid

The degradation of hyaluronic acid induced by ascorbic acid and the effect of synovial fluid proteins, such as ceruloplasmin, transferrin, and albumin, were investigated on the basis of the elution volume and the molecular weight of hyaluronic acid using high-performance gel permeation chromatography. Hyaluronic acid was degraded to less than one-third of the original molecular weight in the range of the physiological concentrations of ascorbic acid. Synovial fluid proteins protected against the ascorbate-dependent degradation of hyaluronic acid at their physiological concentrations. It is suggested that the inhibitory activity of ceruloplasmin mainly depends on the ferroxidase activity and that of transferrin is probably due to iron binding property.     

Fractionation of a hyaluronic acid preparation in a density gradient: The isolation and identification of a chondroitin sulphate

1. Following the suggestion of Nichol, Ogston & Preston (1967) that hyaluronic acid, prepared by filtration from ox synovial fluid, contains a component of high density, such material has been detected and isolated by equilibrium sedimentation in a density gradient of caesium chloride. 2. This material (fraction III) has been characterized as a chondroitin sulphate-protein complex of average molecular weight about 250000. Its amino acid pattern is characteristic of such complexes present in cartilage. It contains a proportion of glucosamine (as well as galactosamine); this is not due to contamination with hyaluronic acid. 3. Preliminary findings on fraction I (low density) and fraction II (intermediate density) suggest that these consist chiefly of protein and hyaluronic acid respectively.     

Molecular weight dependence of hyaluronic acid produced during oncogenic transformation

Cultured chicken embryo fibroblasts synthesize two distinct molecular size classes of hyaluronic acid. The high molecular weight material (form I, 2.98 x 10(6) is the predominant species synthesized by transformed cells, whereas form II (1.42 x 10(5)) is the major product of non-transformed cells. A shift to synthesis of predominantly form I hyaluronic acid is an early transformation event in cells infected with LA24 Rous sarcoma virus and maintained at the permissive temperature for transformation (35 degrees C). Form I hyaluronic acid exhibits greater binding to preparations of cellular fibronectin and to both normal and transformed cells than does form II. Both forms bind more to transformed cells than to normal, uninfected cells. Hyaluronic acid (predominantly form I) isolated from transforming cells stimulates proliferation in growth-retarded, non-transformed cells.     

Biosynthesis of hyaluronic acid by Streptococcus.

Synthesis of hyaluronic acid was investigated in a cell-free system derived from a strain of Group A streptococci. Preparative procedures were improved so that an enzyme system 70 times more active than that previously reported was obtained. The hyaluronic acid synthesized could be separated into trichloroacetic acid-soluble and -insoluble fractions. On the basis of pulse-chase experiments, it was shown that the trichloroacetic acid-insoluble fraction is a precursor of the soluble fraction. The release of the trichloroacetic acid-insoluble hyaluronic acid is specifically blocked with p-chloromercuribenzoate, without inhibition of chain elongation. The addition of butanol to trichloroacetic acid resulted in solubilization of all of the hyaluronic acid. No detectable difference in molecular size was observed between the two hyaluronic acid fractions, both of which were estimated to be more than one million daltons in size. Testicular hyaluronidase digestion of either one of the two types of hyaluronic acid yielded no high molecular weight fragments, indicating that hyaluronic acid is not bound covalently to protein. However, following incubation of enzyme assay mixtures with UDP-[14C]GlcUA, even in the absence of UDP-GlcNAc, radioactive high molecular weight hyaluronic acid was obtained which suggests that the enzyme system elongates rather than initiates hyaluronic acid chains. Tunicamycin did not inhibit hyaluronic acid synthesis, indicating lack of participation of an intermediate of pyrophosphorylpolyisoprenol type. The results obtained are consistent with the hypothesis that chain elongation of hyaluronic acid proceeds by alternate addition of monosaccharides from UDP-sugars by a membrane-bound synthesizing system followed by release of completed hyaluronic acid chains.     

Plasma clearance, tissue distribution and metabolism of hyaluronic acid injected intravenously in the rabbit.

The plasma clearance, tissue distribution and metabolism of hyaluronic acid were studied with a high average molecular weight [3H]acetyl-labelled hyaluronic acid synthesized in synovial cell cultures. After intravenous injection in the rabbit the label disappeared from the plasma with a half-life of 2.5--4.5 min, which corresponds to a normal hyaluronic acid clearance of approx. 10 mg/day per kg body weight. Injection of unlabelled hyaluronic acid 15 min after the tracer failed to reverse its absorption. Clearance of labelled polymer was retarded by prior injection of excess unlabelled hyaluronic acid. The maximum clearance capacity was estimated in these circumstances to be about 30 mg/day per kg body wt. The injected material was concentrated in the liver and spleen. As much as 88% of the label was absorbed by the liver, where it was found almost entirely in non-parenchymal cells. Degradation was rapid and complete, since volatile material, presumably 3H2O, appeared in the plasma within 20 min. Undegraded [3H]hyaluronic acid, small labelled residues and 3H2O were detected in the liver, but there was little evidence of intermediate oligosaccharides. No metabolite except 3H2O was recognized in plasma or urine. Two-thirds of the radioactivity was retained in the body water 24 h later, and small amounts were found in liver lipids. Radioactivity did not decline in the spleen as rapidly as in the liver. The upper molecular weight limit for renal excretion was about 25 000. Renal excretion played a negligible part in clearance. It is concluded that hyaluronic acid is removed from the plasma and degraded quickly by an efficient extrarenal system with a high reserve capacity, sited mainly in the liver.     

Analysis of the streptococcal hyaluronic acid synthase complex using the photoaffinity probe 5-azido-UDP-glucuronic acid.

The mucopolysaccharide, hyaluronic acid, is an important component of both mammals and pathogenic streptococci. This high molecular weight polymer is synthesized by a membrane-associated, multisubunit hyaluronate synthase which utilizes UDP-glucuronic acid and UDP-N-acetylglucosamine as substrates. Using the photoaffinity probe, [beta-32P]5-azido-UDP-glucuronic acid, three streptococcal membrane proteins (42, 33, and 27 kDa) specifically photoincorporated this probe. Labeling of these proteins was enhanced in the presence of UDP-N-acetylglucosamine, whereas UDP-galactose or UDP-glucose had no effect on incorporation. UDP-glucuronic acid inhibited the labeling of the three proteins in a dose-dependent manner. Detergent-solubilized membrane proteins from transposon-inactivated hyaluronic acid capsule mutants no longer incorporated the probe. This was also the case when membranes from stationary phase organisms were tested. Finally, glucuronic acid no longer was incorporated into high molecular weight hyaluronic acid with either the mutant or stationary phase preparations. Further biochemical analysis will be required to demonstrate the exact role each of the proteins play in hyaluronic acid biosynthesis.     

Effect of oxygen and shear stress on molecular weight of hyaluronic acid

Dissolved oxygen (DO) and shear stress have pronounced effects on hyaluronic acid (HA) production, yet various views persist about their effect on the molecular weight of HA. Accordingly, this study investigated the effects of DO and shear stress during HA fermentation. The results showed that both cell growth and HA synthesis were suppressed under anaerobic conditions, and the HA molecular mass was only (1.22+/-0.02) x 106 Da. Under aerobic conditions, although the DO level produced no change in the biomass or HA yield, a high DO level favored the HA molecular mass, which reached a maximum value of (2.19+/- 0.05) x 106 Da at 50% DO. Furthermore, a high shear stress delayed the rate of HA synthesis and decreased the HA molecular weight, yet had no clear effect on the HA yield. Therefore, a high DO concentration and mild shear environment would appear to be essential to enhance the HA molecular weight.     

Elimination and subsequent metabolism of circulating hyaluronic acid in the fetus

Hyaluronic acid differs from other glycosaminoglycans in its lack of covalently linked peptide, absence of sulphate groups, and the exceptional size of its single-chain polymers. These differences can be related to its distinct physical and functional properties, and may be pertinent to its greater abundance in early tissue development. In mature animals, the turnover of hyaluronic acid in tissues is reflected at least partly in the blood stream. The metabolism of circulating hyaluronic acid was therefore studied in fetal sheep after intravenous injection of [3H]acetylhyaluronic acid. Between 95% and 99% was removed within 6 min. Plasma radioactivity decayed by first-order kinetics, with a half-life between 0.8 and 1.25 min. The rate of elimination did not vary materially with hyaluronic acid fractions of widely disparate average Mr or with fetal age between 70 and 120 days. 3H2O was detected in plasma within 8-10 min. Labelled material found in urine from 10 min onward included polymers greater than or equal to 70,000 Mr, which indicates that urine may be a source of hyaluronic acid in amniotic fluid. Elimination from the plasma took place mainly in the liver, where labelled material was largely recovered in small metabolic residues as early as 28 min after injection. These were shown by high pressure liquid chromatography (h.p.l.c.) to include water, acetate, N-acetylglucosamine and a fraction tentatively identified as N-acetylglucosamine 1-phosphate. Tritium radioactivity was detected in hepatic lipids but not those of the spleen. Estimated plasma turnover was in the order of 10 micrograms/min per kg body weight. This is about 3-10 times that in adult animals and is consistent with an increased inflow of hyaluronic acid generated during the maturation of developing tissues.     

High and low molecular weight hyaluronic acid differentially regulate human fibrocyte differentiation

Background

Following tissue injury, monocytes can enter the tissue and differentiate into fibroblast-like cells called fibrocytes, but little is known about what regulates this differentiation. Extracellular matrix contains high molecular weight hyaluronic acid (HMWHA; ∼2×10⁶ Da). During injury, HMWHA breaks down to low molecular weight hyaluronic acid (LMWHA; ∼0.8–8×10⁵ Da).

Methods and Findings

In this report, we show that HMWHA potentiates the differentiation of human monocytes into fibrocytes, while LMWHA inhibits fibrocyte differentiation. Digestion of HMWHA with hyaluronidase produces small hyaluronic acid fragments, and these fragments inhibit fibrocyte differentiation. Monocytes internalize HMWHA and LMWHA equally well, suggesting that the opposing effects on fibrocyte differentiation are not due to differential internalization of HMWHA or LMWHA. Adding HMWHA to PBMC does not appear to affect the levels of the hyaluronic acid receptor CD44, whereas adding LMWHA decreases CD44 levels. The addition of anti-CD44 antibodies potentiates fibrocyte differentiation, suggesting that CD44 mediates at least some of the effect of hyaluronic acid on fibrocyte differentiation. The fibrocyte differentiation-inhibiting factor serum amyloid P (SAP) inhibits HMWHA-induced fibrocyte differentiation and potentiates LMWHA-induced inhibition. Conversely, LMWHA inhibits the ability of HMWHA, interleukin-4 (IL-4), or interleukin-13 (IL-13) to promote fibrocyte differentiation.

Conclusions

We hypothesize that hyaluronic acid signals at least in part through CD44 to regulate fibrocyte differentiation, with a dominance hierarchy of SAP>LMWHA≥HMWHA>IL-4 or IL-13.     

Purification and characterization of hyaluronic acid from the mollusc bivalve Mytilus galloprovincialis

Hyaluronan (hyaluronic acid, HA) was for the first time extracted, purified and characterized from the species of mollusc bivalve Mytilus galloprovincialis. HA was characterized by agarose-gel electrophoresis, 13C-NMR, HPLC and normal polarity capillary electrophoresis by evaluating the unsaturated disaccharide, DeltaDiHA (Delta-hexuronic acid-N-acetyl-glucosamine) after treatment with chondroitin ABC lyase, and by separating Delta-tetrasaccharide and Delta-hexasaccharide generated by the specific action of hyaluronate lyase from Streptomyces hyalurolyticus. The weight average molecular weight (M(w)) was found to be about 200 kDa as determined by HPSEC. HA from M. galloprovincialis was not able to interact with aggrecan from bovine cartilage to form high molecular mass aggregate and also had a very low specific viscosity, but it showed the same capacity to inhibit cell proliferation (50 microg per 10(3) human fibroblasts inhibit cell proliferation by about 50%) than high molecular mass HA. HA of M. galloprovincialis could have a physiological role in the regulation of cell functions.     

A novel glycoprotein that binds to hyaluronic acid

Hyaluronic acid binding protein (HBP) has been purified to homogeneity from normal rat brain by using Hyaluronate-Sepharose affinity chromatography. It appears as a single band in non-dissociating gel electrophoresis. The molecular weight of native protein, as determined by gel filtration is found to be 68,000 daltons, and has a single subunit of molecular weight approximately 13,500 as determined under denaturing conditions in polyacrylamide gel electrophoresis, indicating that this protein is apparently composed of five identical subunits. Amino acid analysis shows the purified HBP to be rich in glycine and glutamic acid content, and is distinct from fibronectin, link proteins, and gelatin binding proteins which are known to bind to hyaluronic acid. This protein is further characterised as sialic acid containing glycoprotein.     

A serum factor capable of stimulating hyaluronic acid synthesis in cultured rat fibroblasts.

Calf serum as well as rat and mouse sera has a factor that stimulates hyaluronic acid synthesis in cultured rat fibroblasts. Such a factor was partially purified from calf serum and characterized. It has a molecular weight of approximately 150,000. The activity of the factor is lost by treatment with pronase and by periodate oxidation. It is suggested, therefore, that the factor is a glycoprotein. Its susceptibility to alpha-mannosidase and affinity for Con A-Sepharose may suggest that the factor contains a mannose residue(s) which is essential for the activity to induce hyaluronic acid synthesis.     

Streptococcal hyaluronic acid: proposed mechanisms of degradation and loss of synthesis during stationary phase.

Streptococcal hyaluronic acid was found to distribute into two discrete sizes. Cellular hyaluronic acid from strain D181 had an average molecular weight of 10 X 10(6), whereas the average molecular weight of extracellular hyaluronic acid from the same strain was 2 X 10(6). Cellular streptococcal hyaluronic acid was purified to homogeneity. Proteases were unable to cleave the purified cellular polymer, indicating that a peptide was not involved in cross-linking five extracellular hyaluronate polymers to form a cell-bound complex. Lipids apparently are not part of the cellular hyaluronic acid because phosphorus and glycerol were not detected by radioisotopic techniques, and denaturing conditions did not change the size of the polymer. Membranes obtained from various strains of group A and C streptococci cleaved the cellular form of the hyaluronate polymer demonstrating the presence of a membrane-bound hyaluronidase-like activity. By contrast, this activity was not found in the extracellular products of the strains studied. Furthermore, membranes derived from streptococci at the stationary phase of growth no longer had the capacity to synthesize hyaluronic acid. The loss of this property appeared to be due to changes in the structure of the membrane.     

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.     

Tissue structure and macromolecular diffusion in umbilical cord. Immobilization of endogenous hyaluronic acid

Diffusion of endogenous hyaluronic acid and 125I-labelled albumin, monitored by desorption from umbilical cord (Wharton's jelly) slices, was studied in relation to tissue structure. Diffusion of hyaluronic acid was Fickian and some two orders of magnitude slower than that in free solution. After treatment of tissue with trypsin which removes proteoglycan(s) and degrades glycoprotein microfibrils, hyaluronic acid mobility through the collagen fibril network that remains is increased by an order of magnitude. These findings indicate that the mobility of hyaluronic acid in tissue is reduced both by the collagen network and by the presence of proteoglycan(s) and/or microfibrils. Estimates of the reduction in mobility due to physical entanglements with the fibrillar networks show that these play a major role. The mobility of hyaluronic acid found for intact tissue is sufficient for it to permeate the extracellular space within its metabolic turnover time. Labelled albumin diffusion is intact tissue, on the other hand, is reduced by only some 30% relative to free solution. This is consistent with the approximate 10% reduction found for the polysaccharide-free tissue (given by the excluded volume fraction) and the approximate 20% reduction expected for the polysaccharides in the interstitial fluid. Similar effects appear to be involved in the mobility of endogenous diffusible proteins in tissue.     

The formation of a stable complex between dissociated proteoglycan and hyaluronic acid in the absence of a link protein.

A proteoglycan fraction prepared from bovine articular cartilage under dissociative conditions was shown to interact with three purified hyaluronic acid preparations to form stable complexes in the analytical ultracentrifuge. It is concluded from these experiments that, although link proteins are associated with hyaluronic acid and proteoglycans in complexes between these macromolecular constituents.     

Tissue structure and macromolecular diffusion in umbilical cord immobilization of endogenous hyaluronic acid

Diffusion of endogenous hyaluronic acid and ¹²⁵I-labelled albumin, monitored by desorption from umbilical cord (Wharton's jelly) slices, was studied in relation to tissue structure. Diffusion of hyaluronic acid was Fickian and some two orders of magnitude slower than that in free solution. After treatment of tissue with trypsin which removes proteoglycan(s) and degrades glycoprotein microfibrils, hyaluronic acid mobility through the collagen fibril network that remains is increased by an order of magnitude. These findings indicate that the mobility of hyaluronic acid in tissue is reduced both by the collagen network and by the presence of proteoglycan(s) and/or microfibrils. Estimates of the reduction in mobility due to physical entanglements with the fibrillar networks show that these play a major role The mobility of hyaluronic acid found for intact tissue is sufficient for it to permeate the extracellular space within its metabolic turnover. time. Labelled albumin diffusion is intact tissue, on the other hand, is reduced by only some 30% relative to free solution. This is consistent with the approximate 10% reduction found for the polysaccharide-free tissue (given by the excluded volume fraction) and the approximate 20% reduction expected for the polysaccharides in the interstitial fluid. Similar effects appear to be involved in the mobility of endogenous diffusible proteins in tissue.     

Induction of hyaluronic acid synthetase activity in rat fibroblasts by medium change of confluent cultures

Hyaluronic acid synthesis in cultured cells usually occurs during the growth phase. The relation between hyaluronic acid synthetase activity and cell proliferation is studied. The synthetase activity in rat fibroblasts is high during the growth phase, but low in the stationary phase. When the old medium of stationary cultures is renewed with fresh medium containing 20% calf serum, DNA synthesis occurs synchronously between 12 and 20 hours, followed by cell division. Under these conditions, the hyaluronic acid synthetase activity is significantly induced within two hours, reaching a maximum level at 5–8 hours, and then decreases gradually. This induction of the synthetase, which shows a high turnover rate, requires continued synthesis of both RNA and protein. Furthermore, the induction of both DNA and hyaluronic acid synthesis is found to be caused by calf serum added in the medium. However, dialysis and ultrafiltration of the serum permit us to concentrate an active fraction with a high molecular weight, which induces the synthetase activity, but not DNA synthesis.     

Photodegradation of hyaluronic acid: EPR and size exclusion chromatography study.

Photochemically induced radical reactions involving the lateral sequences and the end macromolecular chain groups of hyaluronic acid in aqueous solutions at 293K were studied by EPR spin trapping technique with DMPO (5,5-dimethylpyrroline-1-oxide). In the first 1-10 minutes of irradiation EPR indicates spin adducts of two carbon centered radicals with the splitting constants of aN = 1.60 mT, aH = 2.51 mT and aN = 1.56 mT, aH = 2.28 mT. After longer irradiation time (over 10 minutes) dominate two further DMPO adducts of radicals centered on hetero-atoms with splitting constants of aN = 1.44 mT, aH = 1.60 mT and of aN = 1.49 mT, aH = 1.49 mT. Simultaneously, molecular weight followed by SEC decreases, suggesting that UV irradiation leads to the breaking of interglycosidic bonds of hyaluronic acid main macromolecular chain.     

Viscosity and molecular weight of hyaluronic acids.

The intrinsic viscosity ([eta]) and the molecular weight (M) by sedimentation equilibrium were determined for hyaluronic acids of low (M=104--7.2X10(4)) and high (M=3.1X10(5)--1.5X10(6)) molecular weights. Double logarithmic plot of [eta] against M gave different lines for the two groups. The relationship between [eta] and M was [eta]=3.0X10(6)XM1,20 for the former and [eta]=5.7X10(-4)XM0.46 for the latter group. The molecular weight at the point of intersection of the two lines was about 1.5X10(5). The rheological behavior of the hyaluronic acids below M=2.1X10(4), for which the value of reduced viscosity was independent of concentration, was different from that of the hyaluronic acids above M=5.1X10(4), for which the value of reduced viscosity increased with concentration.