The application of the research work of James Clerk Maxwell in electromagnetics to industrial frequency problems.

Faraday's work inspired the development of electrical motors and generators. Until Maxwell pointed out the significance of Ampere's Law, there was no rigorous design method for magnetic devices. His interpretation strongly influenced the creation, by others, of the 'magnetic circuit' approach, which became the seminal design technique. This, utilizing the concept of reluctance, led to the design method for magnetic machines that is still widely in use today. The direct solution of the Maxwell equations (less the displacement current term) had to await the development of modern continuum methods to yield the field everywhere in, and around, the devices of interest, and this then permitted the application of the Maxwell stress tensor. This final refinement yielded forces and torques, and this resulted in the accurate prediction of electrical machine performance.

Polymorphonuclear neutrophils release 35S-labelled proteoglycans into cartilage during frustrated phagocytosis.

Rabbit peritoneal polymorphonuclear neutrophils (PMN), incubated in medium containing [35S]sulphate, incorporated 35S into proteoglycan and protein fractions. Approximately 46% of the 35S-labelled macromolecules associated with the PMN cells after 1 h of incubation were recovered in a cytoplasmic granule extract, the majority being present in azurophil granules. Analysis of the azurophil granule fraction showed that approximately 90% of the 35S-labelled macromolecules were proteoglycans. When challenged with heat-aggregated rabbit gamma-globulin in the presence of cytochalasin B and cGMP, PMN were induced to release granular enzymes but did not release 35S-labelled proteoglycans into the incubation medium. When incubated with articular cartilage slices, PMN released their granule 35S-labelled proteoglycan into the medium and into the cartilage matrix. Granule enzymes and 35S-labelled granule proteoglycan were extracted from the cartilage tissue after incubation and 35S-labelled macromolecules were detected in the cartilage tissue by autoradiography.

Synthesis of 35S-labelled macromolecules by polymorphonuclear neutrophils. Evidence for the production of [35S]sulphite which can modify both endogenous and exogenous proteins.

The incorporation of [35S]sulphate into macromolecules by rabbit peritoneal polymorphonuclear neutrophils (PMN) in vitro revealed that two major groups of 35S-labelled macromolecules were synthesized by these cells. The first group did not bind to anion-exchange columns at pH 6.0 and contained 60-80% of the total incorporated radiolabel. The second group did bind to anion-exchange columns at pH 6.0 and eluted as a single peak of radioactivity at an ionic strength characteristic of sulphated proteoglycans; it accounted for the remaining incorporated radiolabel. Analysis of this material on Sepharose CL-6B demonstrated that 35S-labelled macromolecules isolated from the cell extract migrated with Kav. of 0.36, while corresponding material isolated from the medium migrated with Kav. of 0.51. When subjected to electrophoresis on SDS/polyacrylamide gels the intact proteoglycan had a molecular mass of approx. 90 kDa and yielded two core proteins of molecular mass 31 kDa and 28 kDa after digestion with chondroitinase ABC. The peak of labelled macromolecules which did not bind to the anion-exchange column was found, by SDS/PAGE, to comprise 35S-labelled proteins of various molecular masses. The 35S label was displaced from this fraction by treatment with 0.1 M-sodium sulphite, suggesting that the radiolabel was in the form of an S-sulpho sulphite derivative. Using the sulphite-trapping agents N-2,4-dinitroanilinomaleimide and cyst(e)ine, [35S]sulphite was detected in the incubation medium of PMN, indicating that these cells were able to synthesize [35S]sulphite from [35S]sulphate. The release of [35S]sulphite from neutrophil cultures was calculated to be 78 pmol/h per 10(6) cells. When exogenous proteins were included in the incubation medium of cell cultures, the [35S]sulphite reacted with these proteins to form a stable 35S-labelled conjugate.

Oxidation of articular cartilage glyceraldehyde-3-phosphate dehydrogenase (G3PDH) occurs in vivo during carrageenin-induced arthritis.

Articular cartilage proteoglycan biosynthesis was substantially inhibited by the competitive glycolytic inhibitor 2-deoxyglucose (approximately 65% at 100 mM), but to a much lesser degree (approximately 10%) by the oxidative phosphorylation uncoupler, 2,4-dinitrophenol. These results confirm that articular cartilage proteoglycan synthesis mostly utilises ATP which is generated by glycolysis. In addition, we have utilised the loss of the relatively specific labelling of glyceraldehyde-3-phosphate dehydrogenase (G3PDH) by [3H]-iodoacetic acid to show that rabbit articular G3PDH is oxidised in vivo during the animal model of acute arthritis, carrageenin-induced arthritis, in the same way as we have previously shown that cartilage G3PDH is oxidised after in vitro exposure to sublethal doses of H2O2. The oxidation of rabbit G3PDH in vivo (18 hr post-injection) corresponds with the maximal influx of PMNL cells into the arthritic synovial fluid and with substantial inhibition of proteoglycan core protein synthesis. We propose that H2O2 released from "activated" PMNLs and macrophages is responsible for the "down-regulation" of biosynthetic processes found in cartilage during acute inflammation.

The oxidant hypochlorite (OCl-), a product of the myeloperoxidase system, degrades articular cartilage proteoglycan aggregate.

The myeloperoxidase-derived oxidant, hypochlorite (OCl-) was shown to be able to degrade proteoglycan aggregate prepared from bovine articular cartilage. Exposure of proteoglycan aggregate to OCl- concentrations less than 10(-4) M resulted in a decrease in the size of the constituent proteoglycan monomers, which were unable to reaggregate with hyaluronate due to the loss of the hyaluronic acid binding region as indicated by immunoblotting using the monoclonal 1-C-6 antibody. Analysis of the [35S]-labeled core proteins by SDS/polyacrylamide electrophoresis and fluorography indicated a decrease in the size of the core protein. These data suggest that concentrations of OCl- below 10(-3) M results in the cleavage of the proteoglycan core protein in or near the hyaluronic acid binding region. The physiological consequences of these data are discussed. Exposure to higher concentrations (greater than 10(-3)) of OCl- caused more extensive degradation of the core protein; however, there was no evidence to suggest that OCl- cleaves glycosaminoglycan (GAG) chains.

Depolymerization of synovial fluid hyaluronic acid (HA) by the complete myeloperoxidase (MPO) system may involve the formation of a HA-MPO ionic complex.

Gel filtration analysis (Sephacryl S-1000) indicated that the Mr of purified equine synovial cell culture 3H-hyaluronic acid (HA) (Mr greater than 1.67 x 10(7) Da) decreased in a concentration dependent manner after exposure to hypochlorite (OCl-). Both high (equine) and medium (human, Mr = 5.5 x 10(5) Da) molecular weight HA were cleaved by the complete myeloperoxidase system (MPO/H2O2/Cl-). Purified human neutrophil myeloperoxidase (MPO) bound tightly to HA-Sepharose and we suggest that this is due to a strong ionic interaction between HA and MPO. The formation of such a complex did not disturb MPO activity. The significance of these results in relation to our previous studies concerning the reduction in viscosity and potential cleavage of HA by the product of the MPO/H2O2/Cl- system is discussed.

Changes in the viscosity of hyaluronic acid after exposure to a myeloperoxidase-derived oxidant.

Both purified hyaluronic acid (HA) and bovine synovial fluid react with OCI-, the major oxidant produced by the myeloperoxidase (MPO)/H2O2/CI- system, resulting in a decrease in their specific viscosity. This reaction is inhibited in the presence of excess methionine. H2O2 alone decreases the viscosity of HA, presumably by the Fenton reaction, in the absence (but not in the presence) of the iron chelator, diethyltriaminepentacetic acid (DETAPAC). In the presence of DETAPAC, incubation of HA with the complete MPO/H2O2/CI- system lowered the viscosity of HA. Analysis of 3H-HA exposed to OCI- by gel filtration chromatography indicated that cleavage of HA occurred only at higher OCI- concentrations. We suggest that the reduction in viscosity of HA by the MPO/H2O2/CI- system may be due to a combination of oxidative cleavage and changes in the conformation of the molecule. We speculate that the changes in the molecular size of rheumatoid synovial fluid HA may be due to the action of the neutrophil MPO/H2O2/CI- system.

The mechanism of chondrocyte hydrogen peroxide damage. Depletion of intracellular ATP due to suppression of glycolysis caused by oxidation of glyceraldehyde-3-phosphate dehydrogenase.

Exposure of articular cartilage to H2O2 in vitro inhibits proteoglycan synthesis in a fashion which parallels the inhibition which occurs in cartilage in animal models of acute inflammation. Our study shows that exposure to H2O2 also inhibits other chondrocyte functions, including total protein and DNA synthesis. Since these intracellular biosynthetic processes require adenosine triphosphate (ATP), the effect of exposure of H2O2 on chondrocyte ATP was measured. Exposure to H2O2 caused an immediate (less than 2 min) dose dependent decrease in cartilage ATP levels--found to be due to the oxidative inactivation of glyceraldehyde-3-phosphate dehydrogenase (G-3-PDH). We suggest that intrachondrocyte oxidant damage occurs through oxidation of the sensitive thiol (-SH) residue at the active center of G-3-PDH, with subsequent reduction in the rate of glycolytic ATP synthesis and the intracellular concentration of ATP which is required for DNA, protein, proteoglycan and hyaluronic acid synthesis.

D-penicillamine reverses the inhibition of proteoglycan biosynthesis caused by exposure of cultured articular cartilage to hydrogen peroxide.

The sulphydryl containing anti-rheumatic drug D-penicillamine mildly inhibited proteoglycan synthesis in cartilage explant cultures by a mechanism not dependent upon H2O2 generation. More importantly, this drug alleviated the suppression of PG synthesis mediated by 10(-4) M H2O2 in a dose-dependent manner at concentrations of reduced drug similar to those plasma levels reported in vivo. The ability of D-penicillamine to reverse this effect was due solely to a reaction which resulted in scavenging of medium H2O2 and was not due to the "repair" of cellular lesions caused by prior exposure to H2O2.

Chondrocyte antioxidant defences: the roles of catalase and glutathione peroxidase in protection against H2O2 dependent inhibition of proteoglycan biosynthesis.

The production of hydrogen peroxide by polymorphonuclear cells is suspected as being a cause of cellular damage during acute inflammation. In our study, the kinetics by which hydrogen peroxide suppressed proteoglycan synthesis in cartilage explant culture suggested that the damage occurred at the level of core protein synthesis. Chondrocytes were also shown to contain both catalase and the glutathione peroxidase/reductase systems, which were both involved in the removal of 10(-4) M H2O2. Interruption of either of these peroxide metabolizing systems markedly sensitized cartilage to a greater inhibition of synthesis by H2O2. Inhibition of catalase (with 3-amino 1,2,4 triazole or azide) was found to depress synthesis further, possibly because of exposure to higher steady state levels of H2O2. Inhibition of glutathione reductase (with 1,3-bis-(choloroethyl)-1-nitrosurea) did not expose tissue to higher steady state levels of H2O2, but this treatment decreased the intrachondrocyte level of reduced glutathione which may explain the increased damage obtained in the presence of H2O2. These results support the concept that effective H2O2 metabolizing systems are important in the maintenance of normal biosynthetic rates in cartilage during inflammation.

The role of serine proteinase in cartilage damage.

Arthritic cartilage from experimental animals has been shown to have a decreased proteoglycan content, a decreased rate of proteoglycan synthesis, and a marked increase in an active serine proteinase when compared with normal articular cartilage. The serine proteinase is transferred from PMN cells into cartilage during the inflammatory response where it increased the rate of proteoglycan degradation and is eventually removed by interaction with the chondrocyte surface. The interaction also results in an inhibition of proteoglycan synthesis by the chondrocytes. Both these factors contribute to the loss of proteoglycan from arthritic cartilage.

Receptor-mediated binding of leukocyte elastase by chondrocytes.

Studies on the effect of leukocyte elastase on the metabolism of chondrocytes in culture have demonstrated that these cells possess a specific cell surface receptor for leukocyte-derived elastase. Purified elastase from rabbit and human leukocytes is capable of modulating the metabolism of the cell by causing a marked decrease in both proteoglycan and protein biosynthesis. Addition of 125I-labeled elastase to chondrocytes maintained in suspension culture has shown that binding occurs, and that it is saturable and is inhibited by the addition of unlabeled enzyme. We ascertained that the active site of the enzyme was necessary for binding to the chondrocyte, since phenylmethylsulfonyl fluoride-inactivated leukocyte elastase failed to bind. Pancreatic elastase had only a slight affinity for the receptor, whereas trypsin and bovine serum albumin failed to bind to any significant extent. Autoradiographic studies and the use of inhibitors of endocytosis, such as dansyl cadaverine, confirmed that endocytosis of elastase was the secondary event after cell binding.

Hyaluronic acid synthesis in articular cartilage: an inhibition by hydrogen peroxide.

The synthesis of hyaluronic acid by bovine articular cartilage in culture was inhibited after treatment with xanthine oxidase and hypoxanthine. Through the use of catalase, superoxide dismutase and the specific iron chelator diethylenetriaminepentaacetic acid, the active species responsible for inhibition was shown to be hydrogen peroxide. Hydrogen peroxide generated by glucose oxidase was also inhibitory. Some recovery of hyaluronic synthesis was evident after a further period of culturing. Proteoglycan synthesis was inhibited in parallel with hyaluronic acid synthesis.

The structure and synthesis of proteoglycans of articular cartilage.

The major proteoglycan of articular cartilage is a protein-polysaccharide of great complexity. The structure of this macromolecule is described in this article and is correlated to the function of proteoglycans within the extracellular matrix of cartilage. Chondrocytes, which comprise the cell population of cartilage, are responsible for the synthesis of proteoglycans. A description of the synthesis of proteoglycans reflects the complex nature of these macromolecules and involves a number of sites within various organelles of the chondrocyte. The pathway of proteoglycan synthesis is discussed in addition to the intracellular and extracellular events involved in the regulation of their biosynthesis.

Carrageenin-induced arthritis. VI. Alterations in amino acid transport by articular cartilage in acute inflammatory arthritis.

The mechanism of transport of alanine and aminoisobutyric acid into chondrocytes in rabbit articular cartilage was shown to be mediated by transport systems similar to that described for other eukaryotic cells namely the A, ASC, and L systems. Three days after the initiation of an acute inflammatory arthritis by the intra-articular injection of carrageenin into one knee joint the rate of transport of both these amino acids was decreased. Although all three transport systems were depressed, it appeared that the A and ASC systems were partially susceptible to damage by the induced inflammation. The rate of amino acid transport by the affected cartilage had recovered by 28 days after carrageenin treatment. This depression in amino acid transport is discussed in relation to a decrease in general metabolic processes in chondrocytes as a consequence of inflammation.

The effects of trypsin treatment on proteoglycan biosynthesis by bovine articular cartilage.

The effects of mild or severe trypsin treatment of bovine articular-cartilage slices in tissue culture were studied by monitoring the incorporation of [35S]sulphate into proteoglycans. Moderate trypsin treatment caused a subsequent marked inhibition of proteoglycan biosynthesis, which was reversible with time. Analysis on Sepharose CL-2B of the proteoglycan species synthesized showed that, directly after trypsin treatment, there was a 30% increase in the synthesis of the low-Mr proteoglycan (Kav. 0.71), and the total decrease in proteoglycan biosynthesis was reflected in a decrease in the synthesis of the high-Mr proteoglycan species (Kav. 0.31). The small proteoglycan was partially characterized and shown to be a true biosynthetic product and not a breakdown product. Trypsin treatment (20 micrograms/ml per 100 mg of tissue) of cartilage slices also resulted in an increase in the glycosaminoglycan chain size of the large proteoglycan, but not of the small proteoglycan.

Inhibition of proteoglycan synthesis by hydrogen peroxide in cultured bovine articular cartilage.

Oxygen-derived reactive species, generated enzymatically by the action of xanthine oxidase upon hypoxanthine, significantly inhibit proteoglycan synthesis by cultured bovine articular cartilage (Bates, E.J., Lowther, D.A. and Handley, C.J. (1984) Ann. Rheum. Dis. 43, 462-469). Here we extend these investigations and show, through the use of catalase and the specific iron chelator diethylenetriaminepentaacetic acid, that the active species involved is H2O2 and not the hydroxyl radical. Incubations of cartilage with H2O2 at concentrations of 1 X 10(-4) M and above are also inhibitory to proteoglycan synthesis. Subsequent recovery of the tissue is dependent upon the initial dose of xanthine oxidase or H2O2. Xanthine oxidase at 84 mU per incubation results in a prolonged inhibition of proteoglycan synthesis which is still apparent after 14 days in culture. Lower concentrations of xanthine oxidase (21-66 mU) are inhibitory to proteoglycan synthesis, but the tissue is able to synthesise proteoglycans at near normal rates after 3 days in culture. The inhibition of proteoglycan synthesis by 1 X 10(-4) M H2O2 is completely reversed after 5 days in culture, whereas 1 X 10(-3) M H2O2 results in a more prolonged inhibition. The synthesis of the proteoglycan core protein is inhibited, but the ability of the newly formed proteoglycans to aggregate with hyaluronic acid is unimpaired.

The relation of protein synthesis to chondroitin sulphate biosynthesis in cultured bovine cartilage.

The effect of cycloheximide on chondroitin sulphate biosynthesis was studied in bovine articular cartilage maintained in culture. Addition of 0.4 mM-cycloheximide to the culture medium was followed, over the next 4h, by a first-order decrease in the rate of incorporation of [35S]sulphate into glycosaminoglycan (half-life, t 1/2 = 32 min), which is consistent with the depletion of a pool of proteoglycan core protein. Addition of 1.0 mM-benzyl beta-D-xyloside increased the rate of incorporation of [35S]sulphate and [3H]acetate into glycosaminoglycan, but this elevated rate was also diminished by cycloheximide. It was concluded that cycloheximide exerted two effects on the tissue; not only did it inhibit the synthesis of the core protein, but it also lowered the tissue's capacity for chondroitin sulphate chain synthesis. Similar results were obtained with chick chondrocytes grown in high-density cultures. Although the exact mechanism of this secondary effect of cycloheximide is not known, it was shown that there was no detectable change in cellular ATP concentration or in the amount of three glycosyltransferases (galactosyltransferase-I, N-acetylgalactosaminyltransferase and glucuronosyltransferase-II) involved in chondroitin sulphate chain synthesis. The sizes of the glycosaminoglycan chains formed in the presence of cycloheximide were larger than those formed in control cultures, whereas those synthesized in the presence of benzyl beta-D-xyloside were consistently smaller, irrespective of the presence of cycloheximide. These results suggest that beta-D-xylosides must be used with caution to study chondroitin sulphate biosynthesis as an event entirely independent of proteoglycan core-protein synthesis, and they also indicate a possible involvement of the core protein in the activation of the enzymes of chondroitin sulphate synthesis.

Turnover of proteoglycans in cultures of bovine articular cartilage.

Proteoglycans in cultures of adult bovine articular cartilage labeled with [35S]sulfate after 5 days in culture and maintained in medium containing 20% fetal calf X serum had longer half-lives (average 11 days) compared with those of the same tissue maintained in medium alone (average 6 days). The half-lives of proteoglycans in cultures of calf cartilage labeled after 5 days in culture and maintained in medium with serum were considerably longer (average 21 days) compared to adult cartilage. If 0.5 mM cycloheximide was added to the medium of cultures of adult cartilage, or the tissue was maintained at 4 degrees C after labeling, the half-lives of the proteoglycans were greater, 24 and greater than 300 days, respectively. Analyses of the radiolabeled proteoglycans remaining in the matrix of the tissue immediately after labeling the tissue and at various times in culture revealed two main populations of proteoglycans; a large species eluting with Kav of 0.21-0.24 on Sepharose CL-2B, of high bouyant density and able to form aggregates with hyaluronate, and a small species eluting with a Kav of 0.63-0.70 on Sepharose CL-2B, of low buoyant density, containing only chondroitin sulfate chains, and unable to form aggregates with hyaluronate. The larger proteoglycan had shorter half-lives than the smaller proteoglycan; in cartilage maintained with serum, the half-lives were 9.8 and 14.5 days, respectively. Labeling cartilage with both [3H]leucine and [35S]sulfate showed the small proteoglycan to be a separate synthetic product. The size distribution of 35S-labeled proteoglycans lost into the medium was shown to be polydisperse on Sepharose CL-2B, the majority eluting with a Kav of 0.27 to 0.35, of high buoyant density, and unable to aggregate with hyaluronate. The size distribution of glycosaminoglycans from 35S-labeled proteoglycans appearing in the medium did not differ from that associated with labeled proteoglycans remaining in the matrix.

Changes in proteoglycan biosynthesis following leukocyte elastase treatment of bovine articular cartilage in culture.

Treatment of bovine articular cartilage in culture with a low molecular weight elastase purified from rabbit polymorphonuclear leukocytes resulted in degradation and release of proteoglycans from the tissue, coupled with a prolonged inhibition of proteoglycan biosynthesis. These observations are consistent with those seen in experimental arthritis induced in rabbits. Comparison of the size of the proteoglycan degradation products extracted from elastase-treated cartilage in culture with that from arthritic cartilage showed marked similarities. The results strongly suggest that leukocyte elastase is a contributing factor in proteoglycan degradation and inhibition of synthesis in inflammatory joint disease.