Hyperosmolarity and cardiac function in chronic diabetic rat heart

Inhibition of hyperglycemia-induced angiogenesis and breast cancer tumor growth by systemic injection of microRNA-467 antagonist

Abnormal angiogenesis in multiple tissues is a key characteristic of the vascular complications of diabetes. However, angiogenesis may be increased in one tissue but decreased in another in the same patient at the same time point in the disease. The mechanisms of aberrant angiogenesis in diabetes are not understood. There are no selective therapeutic approaches to target increased neovascularization without affecting physiologic angiogenesis and angiogenesis in ischemic tissues. We recently reported a novel miRNA-dependent pathway that up-regulates angiogenesis in response to hyperglycemia in a cell- and tissue-specific manner. The goal of the work described herein was to test whether systemic administration of an antagonist of miR-467 would prevent hyperglycemia-induced local angiogenesis in a tissue-specific manner. We examined the effect of the antagonist on hyperglycemia-induced tumor growth and angiogenesis and on skin wound healing in mouse models of diabetes. Our data demonstrated that the systemic injection of the antagonist prevented hyperglycemia-induced angiogenesis and growth of mouse and human breast cancer tumors, where the miR-467 pathway was active in hyperglycemia. In tissues where the miR-467-dependent mechanism was not activated by hyperglycemia, there was no effect of the antagonist: the systemic injection did not affect skin wound healing or the growth of prostate tumors. The data show that systemic administration of the miR-467 antagonist could be a breakthrough approach in the treatment and prevention of diabetes-associated breast cancer in a tissue-specific manner without affecting physiologic angiogenesis and angiogenesis in ischemic tissues.

Novel tissue-specific mechanism of regulation of angiogenesis and cancer growth in response to hyperglycemia

Background

Hyperglycemia is an independent risk factor for the development of vascular diabetic complications, which are characterized by endothelial dysfunction and tissue‐specific aberrant angiogenesis. Tumor growth is also dependent on angiogenesis. Diabetes affects several cancers in a tissue‐specific way. For example, it positively correlates with the incidence of breast cancer but negatively correlates with the incidence of prostate cancer. The tissue‐specific molecular mechanisms activated by hyperglycemia that control angiogenesis are unknown. Here we describe a novel tissue‐ and cell‐specific molecular pathway that is activated by high glucose and regulates angiogenesis.

Methods and Results

We have identified microRNA 467 (miR‐467) as a translational suppressor of thrombospondin‐1 (TSP‐1), a potent antiangiogenic protein that is implicated in the pathogenesis of several diabetic complications. miR‐467 was upregulated by hyperglycemia in a tissue‐specific manner. It was induced by high glucose in microvascular endothelial cells and in breast cancer cells, where it suppressed the production of TSP‐1 by sequestering mRNA in the nonpolysomal fraction. Mutation of the miR‐467 binding site in TSP‐1 3′ UTR or miR‐467 inhibitor relieved the translational silencing and restored TSP‐1 production. In in vivo angiogenesis models, miR‐467 promoted the growth of blood vessels, and TSP‐1 was the main mediator of this effect. Breast cancer tumors showed increased growth in hyperglycemic mice and expressed higher levels of miR‐467. The antagonist of miR‐467 prevented the hyperglycemia‐induced tumor growth.

Conclusions

Our results demonstrate that miR‐467 is implicated in the control of angiogenesis in response to high glucose, which makes it an attractive tissue‐specific potential target for therapeutic regulation of aberrant angiogenesis and cancer growth in diabetes.

Coronary blood flow in chronic insulin-dependent diabetic dogs

Diabetic patients appear to be at an increased risk for perioperative morbidity and mortality following coronary artery bypass grafting. Many have suggested that microangiopathy is a primary cause. Using radionuclide labelled microspheres, we measured the perfusion of the subendocardium, midmyocardium, subepicardium, and the subendocardium/subepicardium ratio in alloxan-induced diabetic and normal dogs. We found no statistical difference in the myocardial perfusion of dogs made diabetic for five months when compared to normal dogs. By using repeated measures two-factor analysis of variance-regression model, changing blood glucose levels had no effect on coronary blood flow in either the diabetic or normal dogs.