Shuichiro Nagai

Leukotoxin, 9, 10-epoxy-12-octadecenoate, causes cardiac failure in dogs

An epoxy derivative of linoleate, 9, 10-epoxy-12-octadecenoate, was demonstrated to be biosynthesized by leukocytes, thus nominated as leukotoxin. Its chemical structure was determined by gas-chromatography/mass spectrometry and nuclear magnetic resonance measurements. When it was injected intravenously, 15 mg/kg, canine heart showed signs of a typical cardiac failure; viz. Aortic flow started to drop immediately after the injection, and fell to 22% of the original at 40 min after the injection. At that point, systolic aortic pressure dropped to 35%, diastolic aortic pressure to 23%, and electronically differentiated maximal rate of left ventricular pressure rise (LV dp/dt) to 29%. All of experimental dogs died 40 to 50 min after the injection. On the contrary, administration of linoleic acid (15 mg/kg) did not affect these hemodynamical parameters. Therefore, leukotoxin seems to be an important factor to the genesis of heart failure.

The effect of Coenzyme Q10 on reperfusion injury in canine myocardium.

The mechanism of mitochondrial damage during reperfusion injury of ischemic myocardium was studied using mongrel dogs in vivo and isolated mitochondria in vitro. Seventy-seven adult dogs were divided into three groups: the control group (n = 38), the Coenzyme Q10 (CoQ10)-5 mg group (n = 24), and the CoQ10-15 mg group (n = 15). In the control group, the left anterior descending coronary artery (LAD) of the dog was occluded for 15 min followed by 5 min of reperfusion after 40 min of premedication with physiological saline. In both CoQ10 groups, 5 mg/kg or 15 mg/kg of CoQ10 was infused intravenously for 20 min and then physiological saline was administered for 20 min before 15 min occlusion of the LAD. Subsequently, reperfusion was allowed for 5 min. Each group was further divided into two subgroups depending on the presence (arrhythmia group) or the absence (non-arrhythmia group) of ventricular arrhythmias. Immediately after 15 min occlusion, myocardial samples were taken from the normal and reperfused areas to measure CoQ10 content of myocardium. Heart mitochondria were prepared after 5 min of reperfusion from both areas. Arrhythmias appeared in 12 of 38 dogs in the control group (32%), two of 24 dogs in the CoQ10-5 mg group (8%) and none of 15 dogs in the CoQ10-15 mg group (0%). Premedication with CoQ10 increased tissue CoQ10 content in a dose-dependent manner. In the CoQ10-5 mg group, the increase in CoQ10 content of dogs with reperfusion arrhythmias was relatively less than that of dogs without reperfusion arrhythmias. In each group, mitochondrial function was decreased in the arrhythmia group compared to that of the non-arrhythmia group. The increase in free fatty acid (FFA) content and the decrease in phospholipid content were also observed in mitochondria from the reperfused area of each arrhythmia group. The increase in FFA and mitochondrial dysfunction were induced by the incubation of mitochondria in vitro with phospholipase (PLase) A2 or PLase C, and protected by the addition of CoQ10. These results suggest that PLase plays an important role in the development of mitochondrial damage associated with reperfusion.

The role of phospholipase in the genesis of reperfusion arrhythmia

To clarify the mechanism of reperfusion arrhythmia, the following experiments were performed. In vivo study: Using anesthetized mongrel dogs, the left anterior descending coronary artery was occluded for 15 min and the ligation was released. The dogs were divided into two groups depending on whether the pretreatment was with saline or coenzyme Q10 (CoQ10), 15 mg/kg, before the ligation, i.e., the control and the CoQ10 groups. Each group was further divided into two subgroups depending on the presence or the absence of reperfusion arrhythmia. Reperfusion arrhythmia was observed in 12 out of 38 dogs in the control, whereas in the CoQ10 group none developed arrhythmia. Nine species of free fatty acids (FFA) were detected in the plasma membrane in each group. In the dogs in the control group with arrhythmia, all species of detected FFA increased, and phospholipid content in plasma membrane decreased. These changes were not observed in the dogs without arrhythmia in both the control and the CoQ10 groups. In vitro study: Incubation of myocardial plasma membrane with phospholipase (PLase) A2 increased only unsaturated FFA, while PLase C increased all detected FFA. Premedication with CoQ10 prevented the increase in FFA caused by PLases. Perfusion with PLase A2 or C altered membrane action potential. Premedication with CoQ10 also prevented changes in membrane action potential. PLase liberates fatty acids from phospholipids, and CoQ10 is known to protect the membrane phospholipids from the attack of PLase. These facts and results suggest that activation of PLase associated with coronary reperfusion is closely related to the development of reperfusion arrhythmia.

Mechanism of antiarrhythmic action of β-blocking agents*†

Summary We investigated the antiarrhythmic effect of β-blocking agents. Using 35 anesthetized dogs, the chest was opened and the left anterior descending coronary artery (LAD) was ligated for 30 min and the ventricular multiple response threshold (VMRT) was observed in the time course. The dogs were divided into five groups premedicated intravenously ten min before LAD ligation with either isotonic saline (the control group), D,L-propranolol (0.5 mg/kg), D-propranolol (0.5 mg/kg), D,L-pindolol (0.1 mg/kg), or D,L-acebutolol (2.5 mg/kg). Thirty min after ligation, myocardial mitochondria were prepared from the ischemic and the non-ischemic areas, and then the content of mitochondrial long-chain acyl-CoA and Ca ++ -binding activity were measured. The value of VMRT 1.59±0.21 mA before ligation decreased to 0.99±0.13 mA 30 min after ligation. Content of acyl-CoA in mitochondria from the ischemic area increased significantly compared to those from the non-ischemic area. Mitochondrial Ca ++ -binding activity in the ischemic area decreased significantly compared to that in the non-ischemic area. Each administration of three β-blocking agents prevented the decreases in VMRT and Ca ++ -binding activity and excessive accumulation of acyl-CoA; D-propranolol had no effect. These results suggest that the antiarrhythmic action of β-blocking agents is based, at least in part, on the protection from decrease in Ca ++ -binding activity due to mitochondrial dysfunction induced by the excessive accumulation of long-chain acyl-CoA in mitochondria.