Cardiovascular kinin-generating capability in hypertensive fructose-fed rats.

OBJECTIVE: The hypertensive state is often associated with metabolic abnormalities, including glucose intolerance. Tissue kallikrein, a potent kinin-generating enzyme, is present in the vascular wall and heart tissue. High dietary fructose consumption is reported to induce hyperinsulinemia, hypertriglyceridemia and hypertension. The objective of the present study was to examine the status of kallikrein in vascular and cardiac tissue from highly fructose-fed rats and to delineate the effect of kinins and the angiotensin converting enzyme inhibitor ramipril in this animal model of glucose intolerance. DESIGN AND METHODS: Male Wistar rats (350 g body weight) were divided into four groups of 10 rats each: (1) controls; (2) oral ramipril at 500 microg/kg per day for the last 2 study weeks; (3) fructose in drinking water as a 10% (w/v) solution for 4 weeks; and (4) fructose + ramipril, with fructose administered as in group 3 plus the administration of ramipril for the last 2 study weeks. Systolic blood pressure (tail-cuff method), glucose tolerance (2 g/kg body weight intraperitoneally) and metabolic parameters were recorded. Kallikrein activity in tail artery and heart tissue homogenates was estimated at the end of the 4th study week from measurements of kininogenase activity and kinins generated by a radioimmunoassay. RESULTS: The area under the curve for the glucose tolerance test increased from 1265 +/- 103 mmol/l after 120 min in the control and 1152 +/- 36 mmol/l in the ramipril group (NS) to 2628 +/- 143 mmol/l in the fructose group (P<0.01). The administration of ramipril to fructose-treated rats in group 4 improved glucose tolerance (2160 +/- 100 mmol/l; P<0.05 versus group 3). Blood pressure increased significantly in fructose-fed rats but fell markedly in fructose-fed rats treated with ramipril (P<0.01). Kallikrein activity measured in the heart and vessels increased as a consequence of fructose administration (P<0.05), but the administration of ramipril increased this parameter to a much greater extent (P<0.01 versus control group), which correlated closely with the decrease in blood pressure and the improvement in glucose tolerance observed in the fructose + ramipril group. CONCLUSIONS: The administration of fructose as a solution in the drinking water induced glucose intolerance and increased blood pressure. Treatment with the angiotensin converting enzyme inhibitor ramipril improved glucose tolerance and significantly diminished blood pressure. Cardiovascular kinin-generating capability increased in treated animals and this increase was even higher when rats were treated with ramipril, suggesting that kinins, acting as a paracrine hormonal system, can exert cardiovascular protection and contribute to the beneficial effects of angiotensin converting enzyme inhibitor.

The kallikrein--kinin system in blood vessels.

We have previously reported that vascular tissue contains kallikrein and kallikrein mRNA. We can now show that kallikrein is present throughout the vascular tree and is released from arterial and venous rings incubated "in vitro". Using the isolated perfused rat hindquarters as a model, we found that kallikrein appeared in the perfusate in concentrations that increased linearly with time. Treatment with puromycin inhibited kallikrein release by 87% (p < 0.01), these data suggest that kallikrein is synthesized and released by the vascular wall. Local generation of kinins (autocrine/paracrine system) may contribute to the regulation of vascular homeostasis.

The kallikrein-kinin system in cardiac tissue.

Kallikrein and minute amounts of kininogen have been found in rat cardiac tissue. The mRNA for kallikrein was also determined by the polymerase chain reaction using KK-specific probe. The existence of an intrinsic kallikrein-kinin system in the heart raises the possibility that the enzyme-peptide system is involved in local regulation of cardiac function and metabolism.

Kallikrein-like activity in nonpregnant and pregnant rat uterus, fetal membranes, placenta and amniotic fluid.

SBTI-resistant kininogenase activity was found in nonpregnant and pregnant rat uterus, placenta, amniotic fluid and fetal membranes. After trypsin treatment the kininogenase activity increased 2-3 fold. Total kininogenase (active plus inactive) was completely blocked by kallikrein antibodies. The physiological role of these kallikrein-like enzymes is unknown. It is speculated that these enzymes play a local role, perhaps in the processing of polypeptide hormones of through the release of kinins in the regulation of uterine blood flow.

Half-life of circulating renin under different experimental conditions.

The half-life of circulating renin was studied in normal rats and in rats with a single kidney that was ischemic. The resulting disappearance curve represented the sum of two exponentials. The average half-life of the fast component was 11.5 minutes for normal rats, 11 minutes for rats with mild renal ischemia, and 8 minutes for rats with severe renal ischemia. The mean half-life of the slow component was 67 minutes in normality, 84 minutes in mild ischemia, and 121 minutes in severe ischemia. Also, the calculated proportion of the slower component was different for each group--60.3% in normality, 68.2% in mild ischemia, and 82.2% in severe iischemia. The results suggest that more than one kind of renin may be produced and released by the kidney, and also that renal ischemia may modify the normal metabolism of renin.