M. Wicklmayr scite author profile

Bradykinin infusion has been shown to improve glucose metabolism in non-insulin-dependent diabetic subjects (NIDD). Therefore, we tested the following hypothesis: inhibition of Kininase II, the bradykinin (BK) degrading enzyme, by captopril may also improve glucose metabolism in NIDD. Immediate effects of captopril on total body and peripheral glucose disposal were examined in five normotensive, normal weight NIDD and compared with five NIDD control subjects, well matched for age, weight and degree of fasting hyperglycaemia. The euglycaemic insulin clamp technique was employed in combination with the forearm catheter technique. After 90 min of insulin infusion a single dose of 25 mg captopril was administered orally, whereas in the control group a placebo was given. Captopril lead to a significant rise in total body glucose disposal and forearm glucose uptake, while in the control group no change was observed. Simultaneously, captopril lead to reduction in muscular release of lactate and pyruvate. We conclude that these results demonstrate the stimulatory effect of captopril on insulin-induced glucose disposal of the whole body, which appears to be a result of increased glucose utilization by peripheral tissues. Because of the described insulin-like activity of bradykinin, the concomitant accumulation of local kinins by captopril-induced inhibition of kininase II may represent an attractive hypothesis to explain the generated data sufficiently.

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Insulin-Induced Glucose Transporter (GLUT1 and GLUT4) Translocation in Cardiac Muscle Tissue Is Mimicked by Bradykinin

Rett

Wicklmayr

Dietze

et al. 1996

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The effect of bradykinin on glucose transporter translocation in isolated rat heart was compared with the effect of insulin. Hearts from male obese (fa/fa) Zucker rats were perfused under normoxic conditions and constant pressure in a classic Langendorff preparation with 12 mmol/l glucose as substrate, and a set of functional parameters was measured simultaneously. Bradykinin was administered at a concentration (10(-11) mmol/l) that did not increase coronary flow. Insulin was used at a concentration (8 x 10(-8) mmol/l) known to maximally stimulate glucose transport in this model. After 15 min of perfusion with insulin or bradykinin, subcellular membrane fractions of the heart were prepared, and distribution of glucose transporter protein (GLUT1 and GLUT4) in fractions enriched with surface membranes (transverse tubules [TTs] and sarcolemmal membranes [PMs]) and with low-density microsomal membranes (LDMs) were determined by immunoblotting with the respective antibodies. Both glucose transporter isoforms were translocated after stimulation with insulin (increased transporter protein content in the PM+TT-enriched fraction with a concomitant decrease in the LDM-enriched fraction) and, to a smaller extent, also with bradykinin. These data suggest that in hearts of insulin-resistant obese (fa/fa) Zucker rats, bradykinin interacts with or facilitates the translocation process of both GLUT1 and GLUT4.

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Potential Role of Bradykinin in Forearm Muscle Metabolism in Humans

Dietze

Wicklmayr

Rett

et al. 1996

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Using the euglycemic-hyperinsulinemic glucose clamp and the human forearm technique, we have demonstrated that the improved glucose disposal rate observed after the administration of an angiotensin-converting enzyme (ACE) inhibitor such as captopril may be primarily due to increased muscle glucose uptake (MGU). These results are not surprising because ACE, which is identical to the bradykinin (BK)-degrading kininase II, is abundantly present in muscle tissue, and its inhibition has been observed to elicit the observed metabolic actions via elevated tissue concentrations of BK and through a BK B2 receptor site in muscle and/or endothelial tissue. These findings are supported by several previous studies. Exogenous BK applied into the brachial artery of the human forearm not only augmented muscle blood flow (MBF) but also enhanced the rate of MGU. In another investigation, during rhythmic voluntary contraction, both MBF and MGU increased in response to the higher energy expenditure, and the release of BK rose in the blood vessel, draining the working muscle tissue. Inhibition of the activity of the BK-generating protease in muscle tissue (kallikrein) with aprotinin significantly diminished these functional responses during contraction. Applying the same kallikrein inhibitor during the infusion of insulin into the brachial artery significantly reduced the effect of insulin on glucose uptake into forearm muscle. This is of interest, because in recent studies insulin has been suggested to elicit its actions on MBF and MGU via the accelerated release of endothelium-derived nitric oxide, the generation of which is also stimulated by BK in a concentration-dependent manner. This new evidence obtained from in vitro and in vivo studies sheds new light on the discussion of whether BK may play a role in energy metabolism of skeletal muscle tissue.

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M. Wicklmayr

Differential effect of chronic treatment with two beta-blocking agents on insulin sensitivity

Captopril enhances insulin responsiveness of forearm muscle tissue in non‐insulin‐dependent diabetes mellitus

Insulin-Induced Glucose Transporter (GLUT1 and GLUT4) Translocation in Cardiac Muscle Tissue Is Mimicked by Bradykinin

Potential Role of Bradykinin in Forearm Muscle Metabolism in Humans

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