Novel Leptin-Cardiac TRH pathway responsible for the cardiac alterations in the Hyperleptinemic obesity.

The association between hypertension and obesity-induced cardiac damage is usually accepted. However, no studies have been focused on cardiac alterations in obesity, independently of blood pressure increase. It is well known that Cardiac TRH induces Left Ventricular Hypertrophy (LVH) and fibrosis, and its inhibition prevents the development of hypertrophy. Also, it has been described that the adiponectin leptin induces TRH expression. Thus, we hypothesized that in obesity, the increase in TRH induced by hyperleptinemia is responsible for LVH, until now mostly attributed to pressure load. We studied obese Agouti mice suffering from hypertension with hyperleptinemia and found a significant LVH development with increased TRH gene expression. Consequently, we found higher fibrotic (collagens and TGF-ß) and hypertrophic markers (BNP and ß-MHC) expression vs lean black controls. As pressure could explain these results, we treated obese mice with diuretic (hydrochlorothiazide 20 mg/kg/day) since weaning. Diuretic treatment was successful as the diuretic group was normotensive in contrast to control obese mice. Nevertheless, both groups showed LVH development, higher cardiac precursor TRH gene and peptide expressions and elevated fibrotic and hypertrophic markers expression, pointing out that obesity-induced LVH is not due to hypertension. In addition, we performed Cardiac TRH inhibition by specific siRNA injection compared to control siRNA treatment and evaluated cardiac damage. As expected, expressions and protein increase in hypertrophic and fibrotic markers observed in the AG mouse with the native cTRH system were not seen in the AG mouse with the cTRH silencing. Indeed, the AG + TRH-siRNA group showed hypertrophic markers expression and fibrosis measurements similar to the lean BL mice. On the whole, these results point out that the novel Leptin-Cardiac TRH pathway is responsible for the cardiac alterations present in hyperleptinemic obesity, independent of blood pressure, and cTRH long-term silencing since early stages totally prevent LVH development and cardiac fibrosis.

Cardiovascular and body weight regulation changes in transgenic mice overexpressing thyrotropin-releasing hormone (TRH).

Thyrotropin-releasing hormone (TRH) plays several roles as a hormone/neuropeptide. Diencephalic TRH (dTRH) participates in the regulation of blood pressure in diverse animal models, independently of the thyroid status. The present study aimed to evaluate whether chronic overexpression of TRH in mice affects cardiovascular and metabolic variables. We developed a transgenic (TG) mouse model that overexpresses dTrh. Despite having higher food consumption and water intake, TG mice showed significantly lower body weight respect to controls. Also, TG mice presented higher blood pressure, heart rate, and locomotor activity independently of thyroid hormone levels. These results and the higher urine noradrenaline excretion observed in TG mice suggest a higher metabolic rate mediated by sympathetic overflow. Cardiovascular changes were impeded by siRNA inhibition of the diencephalic Trh overexpression. Also, the silencing of dTRH in the TG mice normalized urine noradrenaline excretion, supporting the view that the cardiovascular effects of TRH involve the sympathetic system. Overall, we show that congenital dTrh overexpression leads to an increase in blood pressure accompanied by changes in body weight and food consumption mediated by a higher sympathetic overflow. These results provide new evidence confirming the participation of TRH in cardiovascular and body weight regulation.

Short-term doxorubicin cardiotoxic effects: involvement of cardiac Thyrotropin Releasing Hormone system.

Doxorubicin is an antineoplastic in the anthracycline class widely used for the treatment of several solid tumors and blood cancers. Cardiotoxicity is the major dose-limiting adverse effect of the drug. Chronic and accumulated doxorubicin administration cause myocyte damage and myocardial fibrosis. Doxorubicin-associated cardiotoxicity can be also observed after a short-course drug treatment even without clinical evidence of cardiac disease. Nevertheless, acute underlying mechanisms involved in the initiation of drug-induced cardiotoxicity remain poorly explored despite their similarities with pathophysiological conditions where cardiac TRH (cTRH) plays a central role. We showed that cTRH mediates myocardial injury induced by hypertension, and angiotensin II. Further, cTRH overexpression induces cardiac apoptosis, hypertrophy and fibrosis. AIM: To demonstrate that cTRH could mediate acute doxorubicin cardiotoxicity. MAIN METHOD: A single injection of doxorubicin (10 mg kg/day i.p.) was used to evaluate acute cardiac damage in a short-term experimental model of doxorubicin-induced cardiotoxicity. While inhibiting cTRH by small interfering RNA (siRNA), we evaluated the progression of cardiotoxicity. KEY FINDINGS: We found a doxorubicin-induced TRH overexpression in the LV, which was associated with apoptosis, hypertrophy and fibrosis. siRNA-mediated cTRH suppression prevented the doxorubicin-associated cardiac histological lesions. SIGNIFICANCES: doxorubicin requires an active cardiac TRH system to promote heart injury.