Silvia Bradamante

Carnosine is a quencher of 4-hydroxy-nonenal: through what mechanism of reaction?

The aim of this study was to understand the mechanism of action through which carnosine (beta-alanyl-L-histidine) acts as a quencher of cytotoxic alpha,beta-unsaturated aldehydes, using 4-hydroxy-trans-2,3-nonenal (HNE) as a model aldehyde. In phosphate buffer solution (pH 7.4), carnosine was 10 times more active as an HNE quencher than L-histidine and N-acetyl-carnosine while beta-alanine was totally inactive; this indicates that the two constitutive amino acids act synergistically when incorporated as a dipeptide and that the beta-alanyl residue catalyzes the addition reaction of the histidine moiety to HNE. Two reaction products of carnosine were identified, in a pH-dependent equilibrium: (a) the Michael adduct, stabilized as a 5-member cyclic hemi-acetal and (b) an imine macrocyclic derivative. The adduction chemistry of carnosine to HNE thus appears to start with the formation of a reversible alpha,beta-unsaturated imine, followed by ring closure through an intra-molecular Michael addition. The biological role of carnosine as a quencher of alpha,beta-unsaturated aldehydes was verified by detecting carnosine-HNE reaction adducts in oxidized rat skeletal muscle homogenate.

An alternative expeditious analysis of phospholipid composition in human blood plasma by 31P NMR spectroscopy

31P nuclear magnetic resonance spectroscopy has been applied to quantitate phospholipids in human blood plasma and in separate lipoprotein fractions. The addition of suitable detergents to samples produces an excellent chemical shift dispersion and allows the identification and integration of the peaks of the most important phospholipids. Results are in agreement with those obtained with enzymatic colorimetric and TLC methods: our method is characterized by good accuracy and reproducibility.

Free radicals promote modifications in plasma high-density lipoprotein: Nuclear magnetic resonance analysis

The behavior of high-density lipoprotein (HDL) after free-radical-mediated oxidation was studied by incubating plasma HDL with chemical oxidizing systems (Cu++) in conditions similar to those used for low-density lipoprotein (LDL) chemical oxidation. Nuclear magnetic resonance (NMR) spectroscopy (1H and 31P) was used to evaluate the degree of oxidation and to characterize the oxidized products. The almost complete loss of polyunsaturated systems together with an appreciable decrease in choline peak demonstrates large-scale HDL-lipid degradation. The appearance of epoxide systems on fatty chains and the identification of oxidized cholesterol derivatives as cholesterol 5 alpha,6 alpha-epoxide, 5 beta,6 beta-epoxide, 7-keto, and 25-hydroxy confirm this picture. Phospholipid analysis indicates an alteration of the phospholipid profile in lyso-phosphatidylcholine (Lyso-PC) production and the disappearance of phosphatidylethanolamine (PE). This study shows that HDL is extensively degraded although there are no large variations in the classical oxidative monitors, lipid hydroperoxide (LPO) and thiobarbituric acid reactive substance (TBARS). Our results suggest that HDL is significantly modified when submitted to an oxidative process.

Protective activity of the spin trap tert-bytyl-α-phenyl nitrone (PBN) in reperfused rat heart

Abstract The aim of this work was to ascettain whether free radicals play a causal role in the injury occurring in myocardial ischemia and reperfusion. To this purpose we observed whether spin-trapping compounds protect the heart when used at a concentration capable of reacting with free radicals. The lipophilic spin trap α-phenyl-t-butyl nitrone (PBN) was used because it is taken up by the myocites. Isolated Langendorff rat hearts were subjected to ischemia according to two schemes: “Model A” = 30 min zero-flow ischemia followed by 30 min reperfusion; “Model B” = 60 min of low-flow ischemia (10% of the individual value; N 2 saturated) followed by 30 min reperfusion. Treated groups received in addition 5.0 m m PBN which was supplied continuously. The following parameters were measured throughout the experiment: contractile performance (RPP); coronary flow (CF); CPK; phosphocreatine (PCr), ATP, inorganic phosphate ( P i ), intracellular pH (pH i ). The pathology obtained by “Model A” is more severe than that of Model B, and partly irreversible. During the ischemic phase in “Model A”, contractility, PCr and ATP dropped to near zero; during initial reflow CPK rose about 13-fold and P i rose 2.5-fold, while pH i decreased to 6.1. During reperfusion, a partial recovery of PCr, P i and pH i was observed, while RPP and ATP did not increase; PBN treatment improved significantly PCr and CPK, while the other parameters were unaffected. During ischemia, “Model B” hearts showed a drop of contractility to near zero, of PCr to 35%, of ATP to 50%; CPK rose 7-fold and P i 1.5-fold; pH i was not modified. During reperfusion, all parameters recovered in part, with exception of P i . PBN developed a marked protective activity on all tested parameters, which gained a nearly normal value. The results of the present investigations show that the lipophilic spin trap PBN partly protects the heart from the ischemia/reperfusion injury, thus confirming that free radicals play a causal role in this pathology; the continuous loading of the tissue with the drug can be an important factor for obtaining the protective effect.

Induction of human endothelial cell growth by mildly oxidized low density lipoprotein.

The aim of the present study was to examine whether endothelial growth could be modulated by mildly oxidized low density lipoprotein. When human endothelial cells were cultured in the presence of mildly oxidized low density lipoprotein (1 microgram/ml), a significant induction of endothelial cell growth was observed, whereas native low or high density lipoprotein were ineffective. Further, treatment of endothelial cells with mildly oxidized low density lipoprotein modulated the expression of cytokines and growth factors which may be relevant in atherogenesis. Endothelial cells chronically exposed to mildly oxidized low density lipoprotein underwent a more rapid onset of cellular senescence. Since senescence is associated with endothelial dysfunction, the novel finding showing that mildly oxidized low density lipoprotein induces endothelial cell growth may be relevant in the development and evolution of the atherosclerotic lesions.

Effects of the spin trap α-phenyl n-tert-butyl nitrone on myocardial function and flow: A dose-response study in the open-chest dog and in the isolated rat heart

Alpha-phenyl N-tert-butyl nitrone (PBN) is widely used in spin-trapping experiments, but its possible toxicity has not been systematically evaluated. The purpose of this study was to investigate the effects of different doses of PBN on cardiac function in vivo (open-chest dogs) and in vitro (isolated rat hearts). In open-chest dogs, PBN was infused intracoronarily to achieve coronary arterial concentrations ranging from 1.6 mM to 10.0 mM. At coronary arterial concentrations of 1.6 mM and 2.5 mM, PBN had no appreciable effect on regional myocardial function (assessed as systolic wall thickening). However, coronary arterial concentrations of PBN of 5.0 mM and 10.0 mM produced a marked reduction and, eventually, a complete loss of systolic wall thickening (53% of baseline values after 30 min at 5.0 mM and 14% after 30 min at 10.0 mM). Furthermore, PBN increased coronary blood flow by approximately 25% at 2.5 mM and by > 100% at 10.0 mM. In isolated rat hearts, perfusion with 2.5 and 5.0 mM PBN for 60 min did not significantly affect global myocardial function, assessed as developed pressure, rate-pressure product, and positive and negative dP/dt. At the 10.0 mM concentration, however, these variables were significantly decreased after 30 min (developed pressure: -77% vs. controls; rate-pressure product: -84%; +dP/dt: -60%; -dP/dt: -70%); two out of five hearts stopped beating within 30 min.(ABSTRACT TRUNCATED AT 250 WORDS)

Intermittent v continuous ischernia decelerates adenylate breakdown and prevents norepinephrine release in reperfused rabbit heart

Myocardium tolerates intermittent ischemia followed by short reperfusions better than continuous ischemia of the same duration. We attempted to delineate the differential mechanism(s) involved in intermittent v continuous ischemia. Isolated, paced rabbit hearts were perfused at 22 ml/min. Coronary flow was stopped intermittently 12 x for 2 or 4 min, with 3-min reperfusions (total reperfusion period: 36 min). In two other groups, flow was stopped continuously for 24 or 36 min followed by a flat 36-min reperfusion. Following the first intermittent 2-min ischemia, adenosine efflux increased ninefold; in all subsequent ischemia/reperfusion cycles, adenosine and total purine releases were substantially less despite identical heart rates, coronary flows and ischemic periods. The rate-pressure product prior to the intermittent ischemias exhibited exponential correlations with total purine efflux during the 3 min of reperfusion. When intermittent ischemia was extended to 4 min, the initial attenuation of ATP breakdown during the prior 2-min occlusions was overcome, but during subsequent 4-min ischemia/reperfusion cycles, ATP breakdown was again attenuated relative to the first 4-min ischemia. After the prolonged continuous ischemias, purine efflux was up to 6 x higher than with intermittent ischemias of the same total time of zero flow. Lactate release and hence cellular H+ export after intermittent ischemias remained consistently elevated, but following the continuous ischemia of 36 min, release of lactate, and thus H+, was subsequentially decreased. Glycogen mobilization occurred regardless of the ischemias nature, but it was markedly enhanced during continuous ischemias, where no fall in proglycogen levels occurred. Similarly, myocardial norepinephrine release increased substantially only during the prolonged continuous ischemias. Thus short intermittent ischemia attenuates cardiac adenylate degradation and glycogen mobilization; such ischemic insult also provides for better lactate and H+ washouts immediately upon reperfusion. Another beneficial effect of intermittent ischemia was the near-complete absence of free interstitial norepinephrine, which exacerbates myocardial ischemic insults. In addition, the exponential correlations between preischemic rate-pressure product and postischemic purine release suggest that preischemic energy demand may determine ATP breakdown in ischemic rabbit myocardium.

Role of adenosine and glycogen in ischemic preconditioning of rat hearts

We tested whether ischemic preconditioning of the rat heart is mediated by reduced glycogenolysis during ischemia, an event triggered by adenosine A1 receptor activation. Rat hearts (n=40) were studied with [31P] and [13C] nuclear magnetic resonance (NMR) spectroscopy, using the Langendorff perfusion technique (5.5 mM [1-13C]glucose, 10 U/l insulin). In parallel experiments, hearts (n=43) were freeze-clamped at different time-points throughout the protocol. They were subjected to either ischemic preconditioning (PC), PC in the presence of 50 microM adenosine receptor antagonist, 8-(p-sulfophenyl)-theophylline (SPT), or intermittent infusion of 0.25 microM adenosine A1 receptor agonist, 2-chloro-N6-cyclopentyladenosine (CCPA). After 30 min ischemia and reperfusion, recovery of heart ratexpressure product was improved in hearts treated with preconditioning (33+/-13%) or CCPA (58+/-14%) compared with the SPT and ischemic control (IC) groups, which both failed to recover (P<0.05). CCPA administration induced a 58% increase in pre-ischemic [13C]glycogen (P<0.05 vs. all groups). In the PC and SPT groups, [13C]glycogen decreased by 25 and 47%, respectively (P<0.05) due to the short bouts of ischemia, resulting in lower pre-ischemic glycogen compared to ischemic control and CCPA hearts (P<0.05). The rate of [13C]glycogen utilization during the first 15 min of ischemia (in micromol/min g wwt) was not statistically different between IC (0.42+/-0.03), PC (0.30+/-0.04), and CCPA (0.38+/-0.05) hearts, but was reduced in SPT hearts (0.24+/-0.05; P<0.05). Total glycogen depletion during 30-min ischemia was reduced in PC hearts (0.61 mg/g wwt) compared to IC (1.84 mg/g wwt) and CCPA (1.75 mg/g wwt) hearts; SPT did not block reduced glycogenolysis during ischemia in PC hearts (0.77 mg/g wwt vs. IC). This study adds further strong evidence that in rat hearts, adenosine is involved in ischemic preconditioning. However, protection is unrelated to pre-ischemic glycogen levels and glycogenolysis during ischemia.

NMR ANALYSIS OF LOW-DENSITY LIPOPROTEIN OXIDATIVELY -MODIFIED IN VZTRO

Human plasma low density lipoprotein has been oxidized at different stages in vitro and analysed by 1H. 13C, and 31P NMR spectroscopy and by biochemical methods. Information was obtained on: a) structure mobilities of lipids and on lipid-protein interactions: b) conjugated and oxo-dienes; c) polyunsaturated/ monounsaturated fatty acid chains; d) lysophosphatidylcholine production. The results show that the NMR approach is particularly useful for the assessment of structural modification in oxidized LDL.

NMR evaluation of changes in myocardial high energy metabolism produced by repeated short periods of ischemia.

Following our previous results which demonstrated that repeated short periods (2 min) of ischemia are capable of protecting the isolated rat heart from a subsequent global ischemia (30 min), in the present study we have concentrated on the metabolic changes occurring in rat hearts during six 2 min ischemia/3 min reperfusion cycles. Cardiac high-energy phosphates were monitored using 31P-NMR. Phosphocreatine levels fell (50-60%) during each ischemic period, and recovered to 70-80% of their initial values during reperfusion. P(i) rose by 59% during the first ischemic period, but increased less during subsequent ischemias (30% during the 6th occlusion, P < 0.05 vs. the first ischemic period) returning to baseline levels after each reperfusion. [ATP], pH, and [Mg2+] remained almost unaffected, but there was a decrease in HPLC-determined effluent ATP catabolites. The first occlusion led to a 95% drop in contractile function (P < 0.001 vs. baseline), but this recovered to 73% upon reperfusion (P < 0.02 vs. baseline), and was 65% at the end of the protocol. Phosphorylation potential (PP = [ATP]/([ADP].[P(i)]) correlated exponentially with total purine (r = 0.90) and with adenosine + inosine release (r = 0.81), and by the 6th ischemia/reperfusion cycle, exceeded that observed in controls by 21% (P < 0.05). We conclude that repeated short periods of ischemia do not lead to any significant alteration in the absolute myocardial ATP, but are associated with an enhanced cytosolic energy state in the heart, that enables the myocardium to reach a steady albeit lower functional state. Adenosine (+inosine) release may be involved in the regulation of the energy supply-demand balance.