ABSTRACT
Phagocytosis is a receptor-mediated process by which specialized cell types engulf large extracellular particles. Phagosome maturation involves a series of intracellular membrane fusion and budding events resulting in the delivery of particles to compartments enriched in lysosomal hydrolases where they are digested. Substantial amounts of plasma membrane and many phagosomal proteins, such as receptors, rapidly recycle to the plasma membrane following phagosome formation. Despite the importance of this recycling pathway in phagosome maturation and in the retrieval of immunogenic peptides from phagosomes, the molecular machinery involved is largely unknown. To assess the participation of GTPases in phagocytosis and recycling from phagosomes we used aluminum fluoride (AIF(-)(4)), which activates the GDP-bound form of stimulatory and inhibitory trimeric G proteins. AlF(-)(4) inhibited both the uptake to and the recycling from the phagosomal compartment. Cholera toxin, which activates Galphas, and pertussis toxin, which uncouples Gi and Go from receptors, were effective inhibitors of phagocytosis. However, both toxins stimulated recycling from phagosomes. These results suggest that more than one GTP-binding protein participates either directly or indirectly not only in phagocytosis, but also in maturation and recycling from phagosomes, and thereby assign a role for heterotrimeric G proteins in controlling traffic through the phagocytic pathway.
Subject(s)
Aluminum Compounds/pharmacology , Fluorides/pharmacology , Heterotrimeric GTP-Binding Proteins/metabolism , Macrophages/physiology , Phagocytosis/physiology , Phagosomes/metabolism , Animals , Cell Line , Cholera Toxin/pharmacology , Macrophages/cytology , Macrophages/drug effects , Pertussis Toxin , Staphylococcus aureus/cytology , Staphylococcus aureus/drug effects , Staphylococcus aureus/metabolism , Virulence Factors, Bordetella/pharmacologyABSTRACT
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.
Subject(s)
Cardiovascular System/metabolism , Fructose/administration & dosage , Hypertension/metabolism , Kinins/biosynthesis , Animals , Antihypertensive Agents/pharmacology , Arteries/enzymology , Blood Pressure/physiology , Diet , Fructose/pharmacology , Glucose Tolerance Test , Hypertension/physiopathology , Kallikreins/metabolism , Male , Myocardium/metabolism , Ramipril/pharmacology , Rats , Rats, WistarABSTRACT
The main objective of this study was to determine if the components of the kallikrein-kinin system are released into the venous effluent from isolated perfused rat hearts. To assess the contribution of kinins and the vascular and cardioprotective effects of the ACE inhibitor ramipril, we determined the status of cardiac kallikrein (CKK), potent kinin-generating enzyme, in rats with right ventricular hypertrophy induced by chronic volume overload and left ventricular hypertrophy by aortic banding. CKK was measured as previously described (Nolly, H.L., Carbini, L., Carretero, O.A., Scicli, A.G., 1994). Kininogen by a modification of the technique of Dinitz and Carvalho (1963) and kinins were extracted with a Sep-Pak C18 cartridge and measured by RIA. CKK (169 +/- 9 pg Bk/30 min), kininogen (670 +/- 45 pg Bk/30 min) and immunoreactive kinins (62 +/- 10 pg Bk/30 min) were released into the perfusate. The release was almost constant over a 120 min period. Pretreatment with the protein synthesis inhibitor puromycin (10 mg i.p.) lowered the release of kallikrein (42 +/- 12 pg Bk/30 min, p < 0.001) and kininogen (128 +/- 56 pg Bk/30 min, p < 0.001). Addition of ramiprilat (10 micrograms/ml) increased kinin release from 54 +/- 18 to 204 +/- 76 pg Bk/30 min (p < 0.001). Aortic banding of rats increased their blood pressure (BP) (p < 0.001), relative heart weight (RHW) (p < 0.001) and CKK (p < 0.001). Ramipril treatment induced a reduction in BP (p < 0.05) and RHW (p < 0.005) while CKK remained elevated. Aortocaval shunts increased their ANF plasma levels (p < 0.05), RHW (p < 0.001) and CKK (p < 0.01). Ramipril treatment induced a reduction in RHW (p < 0.05), while CKK and ANF increased significantly (p < 0.05). The present data show that the components of the kallikrein-kinin system are continuously formed in the isolated rat heart and that ramipril reduces bradykinin breakdown with subsequent increase in bradykinin outflow. The experiments with aorta caval shunt and aortic banding show that cardiac tissues increase their kinin-generating activity and this was even higher in ramipril-treated animals. This may suggest that the actual level of kinins is finely tuned to the local metabolic demands. In this experimental model of cardiac hypertrophy. ACE inhibitors potentiate the actions of kinins and probably try to normalise endothelial cell function.
Subject(s)
Angiotensin-Converting Enzyme Inhibitors/pharmacology , Bradykinin/metabolism , Heart/drug effects , Kallikrein-Kinin System/drug effects , Ramipril/pharmacology , Angiotensin-Converting Enzyme Inhibitors/therapeutic use , Animals , Arteriovenous Shunt, Surgical , Atrial Natriuretic Factor/blood , Blood Pressure/drug effects , Disease Models, Animal , Heart Failure/drug therapy , Heart Failure/physiopathology , Hypertension/drug therapy , Hypertension/physiopathology , Hypertrophy, Left Ventricular/drug therapy , Hypertrophy, Left Ventricular/metabolism , Hypertrophy, Left Ventricular/physiopathology , Hypertrophy, Right Ventricular/drug therapy , Hypertrophy, Right Ventricular/metabolism , Hypertrophy, Right Ventricular/physiopathology , Kallikrein-Kinin System/physiology , Kallikreins/metabolism , Kininogens/isolation & purification , Kininogens/metabolism , Male , Myocardium/metabolism , Organ Size/drug effects , Protein Synthesis Inhibitors/pharmacology , Puromycin/pharmacology , Radioimmunoassay , Ramipril/therapeutic use , Rats , Rats, WistarABSTRACT
The vascular wall itself, through a complex interplay of endocrine, neurocrine and autoparacrine mechanisms, plays an active role in vascular homeostasis. The endothelial cell senses humoral and hemodynamic changes and responds by secreting a variety of metabolically active substances that act locally causing either vasodilatation or vasoconstriction. Kallikrein (KK) and the mRNA for KK are present in arteries and veins. Vascular KK releases kinins from kininogen which circulate in plasma and is also present in vascular tissue. Vascular-derived kinins induce vasodilatation through the release of endothelial compounds (prostacyclin, EDRFs and cytochrome P-450). Disturbance in the delicate balance between vasodilators and vasoconstrictors may play a role in the development of hypertension. Vascular kallikrein (VKK) was significantly (P < 0.05) elevated after 2 weeks of development of renovascular and mineralocorticoid hypertension, and blood pressure was only slightly elevated. However, VKK decreased in both experimental models when blood pressure was increased. It is possible that the increase in VKK in the early stages resulted in increased local vasodilatory activity, thus counteracting the rise in blood pressure. As hypertension developed, KK was significantly decreased in arteries. The decrease in arterial KK during established hypertension is most likely secondary to high blood pressure. When the endothelium is damaged by high blood pressure, diabetes, excessive LDL cholesterol or cigarette smoking, a net imbalance favoring vasoconstriction, proliferation and migration of cells and increased lipid deposition predisposes to specific vascular diseases. Converting enzyme inhibitors (CEI) blunt the proliferative response of vascular smooth muscle cells after endothelial injury. The cardiovascular protective effects of CEI are mediated in part by the antihypertrophic, antihyperplastic and antithrombotic effects of kinins. The vascular kallikrein-kinin system has a promising role in the regulation of vascular homeostasis and some of the CEI effects may be explained by potentiation of the vascular-derived kinins.
Subject(s)
Kinins/metabolism , Muscle Tonus/physiology , Muscle, Smooth, Vascular/metabolism , Angiotensin-Converting Enzyme Inhibitors/metabolism , Animals , Endothelium, Vascular/metabolism , Humans , Hypertension/metabolism , Kallikrein-Kinin System/physiology , RatsABSTRACT
The vascular itself, through a complex interplay of endocrine, neurocrine and autoparacrine mechanisms, plays an active role in vascular homeostasis. The endothelial cell senses humoral and hemodynamic changes and respondes by secreting a variety of metabolically active substances that act locally causing either vasodilatation or vasoconstriction. Kallikrein (KK) and the nRNA for KK are present in arteries and veins. Vascular KK releases Kinins from kininogen which circulate in plasma and is also present in vascular tissue. Vascular-derived kinins induce vasodilatation through the release of endothelial compounds ( prostacyclin, EDRFs and cytochrome P-450). Disturbance in the delicate balance between vasodilators and vasoconstrictiors may play a role in the development of hypertension. Vascular kallikrein (VKK) was significantly (P < 0.05) elevated after 2 weeks of development of renovascular and mineralocorticoid hypertension, and blood pressure was only slightly elevated. However, VKK decreased in both experimental models when blood pressure was incresed. It is possible that the increase in VKK in the early stages resulted in incresead local vasodilatory activity, thus counteracting the rise in blood pressure. As hypertension developed, KK was significantly decreased in arteries. The decrease in arterial KK during established hypertension is most likely secondary to high blood pressure....