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Arachidonic acid metabolism during antigen and ionophore activation of the mouse bone marrow derived mast cell

Nakamura, T. ; Fonteh, A.N. ; Hubbard, W.C. ; [et al.]

Amsterdam : Elsevier

Biochimica et Biophysica Acta (BBA)/Lipids and Lipid Metabolism 1085 (1991), S. 191-200

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ISSN: 0005-2760

Keywords: (Mast cell) ; Antigen ; Arachidonic acid metabolism ; GC-MS ; Ionophore A23187 Immunological challenge

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Biology , Chemistry and Pharmacology , Medicine , Physics

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1016/0005-2760(91)90094-X

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Glycosylation enhances oxygen radical-induced modifications and decreases acetylhydrolase activity of human low density lipoprotein (1997)

Napoli, C. ; Triggiani, M. ; Palumbo, G. ; [et al.]

Springer

Basic research in cardiology 92 (1997), S. 96-105

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ISSN: 1435-1803

Keywords: LDL ; glycosylation ; oxygen radicals ; scavengers ; superoxide radical ; acetylhydrolase

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Background. Posttranslational nonenzymatic glycosylation of native low-density lipoprotein (n-LDL) occurs bothin vitro andin vivo in diabetic patients. Glycosylated LDL (glc-LDL) behave similarly to oxidized LDL in some respects. In fact, unlike n-LDL, uptake of glc-LDL can occur in part by the “scavenger” receptor(s), as also demonstrated for oxidized LDL. The enzyme acetylhydrolase, carried by LDL, catabolizes platelet activating factor (PAF). This enzymatic activity is inhibited in oxidized LDL. However, it is unknown whether glc-LDL have reduced acetylhydrolase activity.Objectives. The first aim of the study was to investigate whether glc-LDL were more susceptible than n-LDL to oxidative modification, and which different oxygen radical species were involved in the phenomenon. Moreover, in order to investigate whether glycosylation may affect acetylhydrolase, we also measured this enzymatic activity in both n- and glc-LDL.Methods. In vitro glc-LDL and n-LDL were exposed to the oxidants xanthine/xanthine oxidase (X/XO; 2 mM and 100 mU/ml, respectively), or CuSO4 (10 μM) for 18 hs at 37°C. Parallel experiments were done in the presence of the superoxide radical scavenger superoxide dismutase (SOD; 330 U/ml), the hydrogen peroxide scavenger catalase (1000 U/ml), or the hydroxyl radical scavenger dimethylthiourea (10 mM) or dimethylsulfoxide (1 mM). Standards of PAF and lyso-PAF were visualized with iodine vapors after separation by thin layer chromatography. The distribution of label was determined by an imaging scanner. Labeled products were then isolated from the chromatography plate, and the amount of3H-lyso-PAF formed was determined by liquid scintillation counting.Results. Glc-LDL were more susceptible than n-LDL to lipid peroxidation (n-LDL 22.9±3.4 vs 34.8±4.2* nmoles/MDA/mg of protein in glc-LDL oxidized by X/XO and n-LDL 28.9±4.2 vs 40.4±4.1* in glc-LDL oxidized by CuSO4,*p〈0.05 vs n-LDL). SOD, but not other scavengers, prevented peroxidation, indicating an obligatory role for superoxide radicals. Oxidation of glc-LDL also induced a higher degree of apolipoprotein-B100 modifications than n-LDL, with increased electrophoresis mobility and decreased TNBS reactivity. These effects were similarly prevented by SOD. Finally, acetylhydrolase activity was significantly lower in glc-LDL than in n-LDL.Conclusion. Glycosylation increases LDL oxidation due to superoxide radicals, and also reduces acetylhydrolase activity. These phenomenona may contribute to enhance and/or accelerate the progression of atherosclerosis in diabetic patients.