Nitric oxide (NO) produces rapid osteoclast detachment and contraction in vitro, and this effect is accompanied by a profound inhibition of bone resorption. Work by others has confirmed these findings in vivo: inhibition of NO synthase [NOS; L-arginine, NADPH: oxygen oxidoreductase (NO-forming), EC 1.14.13.39] in normal rats is followed by increased bone resorption reflected by a marked loss in bone mineral density. In our present study, immunocytochemistry and Northern blotting show the presence of the constitutive calcium-sensitive NOS isoform (cNOS) in normal rat osteoclasts and in the human preosteoclast cell line (FLG 29.1 by normal rat osteoclasts treated with LPS or IFN-'y. In contrast, the nonselective NOS inhibitor NG-monomethyl-Larginine inhibits resorption by untreated neonatal rat osteoclasts. Thus, osteoclast function may require intermittent calcium-stimulated increases in NO production by cNOS against a basal inhibitory background activity of the iNOS isoform. However, bone resorption depends on precursor replication and on the activity of the mature cells, and we found that the NO donor 3-morpholinosydnonimine (SIN-1) (50 ,uM) profoundly depressed replication in the human preosteoclast line. Taken together, these results strongly suggest that NO maintains a central control of bone resorption in both avian and mammalian species by exerting a powerful tonic restraint of osteoclast numbers and activity. The presence of NOS in human cells implies a similar function in man and that conventional views of calcium homoeostasis and skeletal metabolism will need substantial revision. Since NO also influences behavior of the osteoblast, the boneforming cell, in vitro, a similar effect in vivo might imply a general influence on bone remodeling.Nitric oxide, or NO, secreted by the endothelium exerts an overriding control of blood pressure and blood flow by producing a dominant tonic dilatation of arterial muscle. To this crucial physiological role is added a number of other important functions. In the central nervous system, NO potentiates long-term memory; in the periphery it is the transmitter in the nonadrenergic noncholinergic (NANC) inhibitory nerves of the gastrointestinal and urogenital tracts. In contrast, the macrophage uses NO to kill invading microorganisms. NO is produced by several NO-synthase [NOS; L-arginine, NADPH: oxygen oxidoreductase (NO-forming), EC. 1.14.13.39] isoforms that require the same cofactors but vary in their response to calcium, mode of regulation, and tissue specificity (1). Constitutive isoforms of NOS have been identified in brain (2) and endothelium (3), while in macrophages (4) and hepatocytes (5) NOS transcripts of inducible NOS (iNOS) isoforms are detected only after treatment with cytokines or lipopolysaccharide (LPS). However, this gas radical now appears to be involved in still another function-that of control of osteoclastic activity. The osteoclast is the only cell in the body that can resorb bone and, together with the kidney, this cell plays the major role...
The established model for the mechanism of action of aspirin is the inhibition of prostaglandin synthesis. However, this has never fully explained aspirin's repertoire of antiinflammatory properties. We found in acute pleuritis that aspirin, but not salicylate, indomethacin, or piroxicam, increased plasma nitric oxide (NO), which correlated with a reduction in inflammation. Inhibiting aspirin-elicited NO pharmacologically in this model nullified the antiinflammatory effects of aspirin. Moreover, aspirin was not antiinflammatory in either constitutive (eNOS) or inducible NO synthase (iNOS) knockout mice with IL-1β–induced peritonitis. It transpires that aspirin generates NO through its unique ability to trigger the synthesis of 15-epi-lipoxin A4. Aspirin and 15-epi-lipoxin A4 were shown to inhibit leukocyte trafficking in an NO-dependent manner using intravital microscopy on IL-1β–stimulated mouse mesentery. Not only did aspirin inhibit leukocyte–endothelial interaction in a manner similar to NO in wild-type mice but both aspirin and 15-epi-lipoxin A4 had markedly reduced effects on leukocyte–endothelial cell adherence in eNOS- and iNOS-deficient mice compared with wild type. Collectively, these data suggest that aspirin triggers the synthesis of 15-epi-lipoxin A4, which increases NO synthesis through eNOS and iNOS. This aspirin-elicited NO exerts antiinflammatory effects in the microcirculation by inhibiting leukocyte–endothelium interactions.
Osteoarthritis is a highly prevalent and disabling disease for which we do not have a cure. The identification of suitable molecular targets is hindered by the lack of standardized, reproducible and convenient screening assays. Following extensive comparisons of a number of chondrocytic cell lines, culture conditions, and readouts, we have optimized an assay utilizing C-28/I2, a chondrocytic cell line cultured in high-density micromasses. Utilizing molecules with known effects on cartilage (e.g. IL-1β, TGFβ1, BMP-2), we have exploited this improved protocol to (i) evoke responses characteristic of primary chondrocytes; (ii) assess the pharmacodynamics of gene over-expression using non-viral expression vectors; (iii) establish the response profiles of known pharmacological treatments; and (iv) investigate their mechanisms of action. These data indicate that we have established a medium-throughput methodology for studying chondrocyte-specific cellular and molecular responses (from gene expression to rapid quantitative measurement of sulfated glycosaminoglycans by Alcian blue staining) that may enable the discovery of novel therapeutics for pharmacological modulation of chondrocyte activation in osteoarthritis.
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