BNP as a New Biomarker of Cardiac Thyroid Hormone Function.

BACKGROUND: Cardiac re-expression of fetal genes in patients with heart failure (HF) suggests the presence of low cardiac tissue thyroid hormone (TH) function. However, serum concentrations of T3 and T4 are often normal or subclinically low, necessitating an alternative serum biomarker for low cardiac TH function to guide treatment of these patients. The clinical literature suggests that serum Brain Natriuretic Peptide (BNP) levels are inversely associated with serum triiodo-L-thyronine (T3) levels. The objective of this study was to investigate BNP as a potential serum biomarker for TH function in the heart. METHODS: Two animal models of thyroid hormone deficiency: (1) 8-weeks of propyl thiouracil-induced hypothyroidism (Hypo) in adult female rats were subsequently treated with oral T3 (10 µg/kg/d) for 3, 6, or 14 days; (2) HF induced by coronary artery ligation (myocardial infarction, MI) in adult female rats was treated daily with low dose oral T3 (5 µg/kg/d) for 8 or 16 wks. RESULTS: Six days of T3 treatment of Hypo rats normalized most cardiac functional parameters. Serum levels of BNP increased 5-fold in Hypo rats, while T3 treatment normalized BNP by day 14, showing a significant inverse relationship between serum BNP and free or total T3 concentrations. Myocardial BNP mRNA was increased 2.5-fold in Hypo rats and its expression was decreased to normal values by 14 days of T3 treatment. Measurements of hemodynamic function showed significant dysfunction in MI rats after 16 weeks, with serum BNP increased by 4.5-fold and serum free and total T3 decreased significantly. Treatment with T3 decreased serum BNP while increasing total T3 indicating an inverse correlation between these two biologic factors (r 2 = 0.676, p < 0.001). Myocardial BNP mRNA was increased 5-fold in MI rats which was significantly decreased by T3 over 8 to 16 week treatment periods. CONCLUSIONS: Results from the two models of TH dysfunction confirmed an inverse relationship between tissue and serum T3 and BNP, such that the reduction in serum BNP could potentially be utilized to monitor efficacy and dosing of T3 treatment. Thus, serum BNP may serve as a reliable biomarker for cardiac TH function.

Thyroid Hormone and Cardioprotection.

The heart is a major target of thyroid hormones, with maintenance of euthyroid hormone balance critical for proper function. In particular, chronic low thyroid function can eventually lead to dilated heart failure with impaired coronary blood flow. New evidence also suggests that heart diseases trigger a reduction in cardiac tissue thyroid hormone levels, a condition that may not be detectible using serum hormone assays. Many animal and clinical studies have demonstrated a high prevalence of low thyroid function in heart diseases with worse outcomes from this condition. Animal and human studies have also demonstrated many benefits from thyroid hormone treatment of heart diseases, particularly heart failure. Nonetheless, this potential treatment has not yet translated to patients due to a number of important concerns. The most serious concern involves the potential of accidental overdose leading to increased arrhythmias and sudden death. Several important clinical studies, which actually used excessive doses of thyroid hormone analogs, have played a major role in convincing the medical community that thyroid hormones are simply too dangerous to be considered for treatment in cardiac patients. Nonetheless, this issue has not gone away due primarily to overwhelmingly positive evidence for treatment benefits and a new understanding of the cellular and molecular mechanisms underlying those benefits. This review will first discuss the clinical evidence for the use of thyroid hormones as a cardioprotective agent and then provide an overview of the cellular and molecular mechanisms underlying beneficial changes from thyroid hormone treatment of heart diseases. © 2016 American Physiological Society. Compr Physiol 6:1199-1219, 2016.

Improvement of left ventricular remodeling after myocardial infarction with eight weeks L-thyroxine treatment in rats.

BACKGROUND: Left ventricular (LV) remodeling following large transmural myocardial infarction (MI) remains a pivotal clinical issue despite the advance of medical treatment over the past few decades. Identification of new medications to improve the remodeling process and prevent progression to heart failure after MI is critical. Thyroid hormones (THs) have been shown to improve LV function and remodeling in animals post-MI and in the human setting. However, changes in underlying cellular remodeling resulting from TH treatment are not clear. METHODS: MI was produced in adult female Sprague-Dawley rats by ligation of the left descending coronary artery. L-thyroxine (T4) pellet (3.3 mg, 60 days sustained release) was used to treat MI rats for 8 weeks. Isolated myocyte shape, arterioles, and collagen deposition in the non-infarcted area were measured at terminal study. RESULTS: T4 treatment improved LV ±dp/dt, normalized TAU, and increased myocyte cross-sectional area without further increasing myocyte length in MI rats. T4 treatment increased the total LV tissue area by 34%, increased the non-infarcted tissue area by 41%, and increased the thickness of non-infarcted area by 36% in MI rats. However, myocyte volume accounted for only ~1/3 of the increase in myocyte mass in the non-infarct area, indicating the presence of more myocytes with treatment. T4 treatment tended to increase the total length of smaller arterioles (5 to 15 µm) proportional to LV weight increase and also decreased collagen deposition in the LV non-infarcted area. A tendency for increased metalloproteinase-2 (MMP-2) expression and tissue inhibitor of metalloproteinases (TIMPs) -1 to -4 expression was also observed in T4 treated MI rats. CONCLUSIONS: These results suggest that long-term T4 treatment after MI has beneficial effects on myocyte, arteriolar, and collagen matrix remodeling in the non-infarcted area. Most importantly, results suggest improved survival of myocytes in the peri-infarct area.

Acute myocardial infarction and thyroid function: new pathophysiological and therapeutic perspectives.

In the post-reperfusion era, molecular and genetic mechanisms of cardioprotection and regeneration represent new therapeutic challenges to limit infarct size and minimize post-ischemic remodeling after acute myocardial infarction (AMI). Activation of cell survival mechanisms can be promoted by the administration of external drugs, stimulation of internal mechanisms, and genetic manipulation to delete or replace pathological genes or enhance gene expression. Among internal cardiovascular regulatory mechanisms, thyroid hormones (THs) may play a fundamental role. TH has a critical role in cardiovascular development and homeostasis in both physiological and pathological conditions. In experimental AMI, TH has been shown to affect cardiac contractility, left ventricular (LV) function, and remodeling. Several experimental studies have clearly shown that THs participate in the regulation of molecular mechanisms of angiogenesis, cardioprotection, cardiac metabolism, and ultimately myocyte regeneration, changes that can reverse left ventricular remodeling by favorably improving myocyte shape and geometry of LV cavity, thus improving systolic and diastolic performance. This review is focused on the role of thyroid on AMI evolution and on the potential novel option of thyroid-related treatment of AMI.

Post-myocardial infarction left ventricular myocyte remodeling: are there gender differences in rats?

BACKGROUND: Previous studies have shown gender differences in left ventricular remodeling after myocardial infarction. Results are varied, however, and reliable, comprehensive data for changes in cardiac myocyte shape are not available. METHODS: Young adult female and male Sprague-Dawley rats were used in this study and randomly assigned to the myocardial infarction and sham myocardial infarction groups. Myocardial infarction was produced by ligation of the left descending coronary artery. Four weeks after surgery, left ventricular echocardiography and hemodynamics were performed before isolating myocytes for size determination. RESULTS: In general, left ventricular functional changes after myocardial infarction were comparable. Females developed slightly, but significantly, more left ventricular hypertrophy than males, and this was reflected by the relative increases in left ventricular myocyte volume. In both males and females, however, myocyte hypertrophy was due exclusively to lengthening of myocytes with no change in myocyte cross-sectional area. CONCLUSIONS: This study demonstrates that post-myocardial infarction changes in LV function and myocyte remodeling are remarkably similar in young adult male and female rats.

Alterations in G protein and MAP kinase signaling pathways during cardiac remodeling in hypertension and heart failure.

The present study was undertaken to elucidate the G-protein and mitogen-activated kinase (MAP kinase) coupled signaling profile in a genetic model of hypertension and congestive heart failure (CHF) that mimics similar disease in humans. At the receptor level, Ang II type 1 receptor (AT1R) increased in left ventricular hypertrophy (LVH) and reverted to normal in CHF, whereas there was a downregulation of the Ang II type 2 receptor (AT2R) in CHF. At the transducer level, Galphaq and Galpha12 protein levels were unchanged during LVH but decreased significantly in CHF. In contrast, Gbeta and Galpha13 protein content were markedly upregulated in CHF. Furthermore, using phospho-specific antibodies in Western blots and in vitro kinase assays, we found at the effector level an upregulation of the small G-protein Rac1 activity during LVH but a decrease during CHF. In parallel, small G-protein Rho activity was significantly increased during LVH but was unchanged in failure. We found at the downstream level that MAP kinase isoforms extracellular signal regulated-kinase (ERK1/2), big mitogen-activated kinase (BMK1/ERK5), C-jun N-terminal-activated kinase (JNKs/SAPKs), and stress-activated kinase (p38) bioactivities were increased during LVH. During CHF, ERK1/2 and JNK1/2 kinase activities were decreased, whereas BMK1/ERK5 kinase activity reverted to normal values. In conclusion, this study demonstrates, for the first time, multistep alterations of G-protein and MAP kinase signaling pathways in LVH and progression to failure in a genetic model of hypertension and failure.