Mohammad Reza Mehrabi

Measuring extracellular matrix turnover in the serum of patients with idiopathic or ischemic dilated cardiomyopathy and impact on diagnosis and prognosis

Circulating levels of extracellular matrix components were measured by radioimmunoassays and tested if they were useful for clinical staging in chronic heart failure. In 41 patients with dilated cardiomyopathy (33 idiopathic and 8 ischemic cases), the serum concentrations of procollagen type III aminoterminal peptide (PIIINP), type I collagen telopeptide (ICTP), and basement membrane laminin were significantly higher than in 30 healthy controls regardless of the underlying etiology. Patients with serum values of PIIINP, ICTP, and laminin > 7 micrograms/L, 7.6 micrograms/L, and 2.3 U/ml, respectively, were at higher relative risk for advanced clinical stage, poor hemodynamic condition, hyponatremia, heart transplantation, and death during follow-up than patients with low levels, with the exception that serum laminin > 2.3 U/ml was not significantly associated with hyponatremia and heart transplantation. Despite their interdependence on liver function, circulating levels of PIIINP and ICTP were independent predictors of mortality. In 17 of the 41 patients with cardiomyopathy whose explanted hearts were available for histologic evaluation, serum PIIINP, ICTP, and laminin significantly correlated with the myocardial area fractions of their tissue analogues (PIIINP vs myocardial collagen type III, r = 0.784, p = 0.0013; serum ICTP vs myocardial collagen type I, r = 0.603, p = 0.0527; and serum laminin vs myocardial laminin, r = 0.605, p = 0.0411). In conclusion, the increase in extracellular matrix turnover, which may partially be derived from fibrosis in the myocardium, can be measured in the serum of patients with dilated cardiomyopathy, and has an impact on risk stratification and prognosis.

The melatonin receptor subtype MT2 is present in the human cardiovascular system

Abstract: We showed that the melatonin receptor subtype, MT1, is expressed in healthy and diseased human coronary arteries. As studies in experimental animals suggest that the MT2 melatonin receptor subtype is also present in the vasculature, we investigated whether the MT2 is expressed in human aorta and coronary arteries. Additionally, MT2 expression in human ventricular specimens was analysed, as melatonin was shown to affect myocyte function. Expression of the MT2‐receptor was studied in sections of isolated coronary arteries, aorta and left ventricular specimens from healthy heart donors (control) and patients with dilated or ischemic cardiomyopathy. MT2 expression was found by reverse transcriptase (RT)‐nested‐polymerase chain reaction (PCR) in all of the specimens (aorta, left ventricle and coronary arteries) derived from controls. Also, visible evidence for receptor expression was found in 12 of 15 samples from cardiomyopathy patients and 10 of 15 of coronary heart disease patients. Additionally, the expression of MT2‐receptor between aorta, left ventricle and coronary arteries varied among the individuals, some of them showing highest expression in the aorta while in others principal expression sites were coronary arteries or left ventricles. In conclusion, the MT2‐receptor subtype is present in human arteries and left ventricles and it is suggested that in coronary heart disease MT2‐receptor expression is altered. Furthermore, there is evidence for heterogeneous MT2 expression patterns in individual patients.

The isoprostane, 8-epi-PGF2α, is accumulated in coronary arteries isolated from patients with coronary heart disease

OBJECTIVE In the present study we wanted to know whether 8-epi-PGF2 alpha, which belongs to the class of isoprostanes formed by free radical-mediated peroxidation of arachidonic acid and arachidonyl-containing phospholipids, is enriched in isolated coronary arteries of patients suffering from coronary heart disease (CHD, n = 23) who received allograft heart transplants as compared to vessels derived from patients with dilative cardiomyopathy (CMP, n = 19) or from healthy heart donors (controls, n = 6). METHODS Sections from the isolated coronary arteries were analysed by semiquantitative immunohistochemistry by determining the area and intensity of positive reaction for 8-epi-PGF2 alpha in the vascular intima and media. In addition, the 8-epi-PGF2 alpha content was determined using a specific immunoassay after extraction and purification. RESULTS The immunohistochemical results indicated that 8-epi-PGF2 alpha is significantly enriched in arteries from patients suffering from CHD as compared to CMP (P < 0.0001). In controls, significantly less immunostaining was observed. Furthermore, a significant positive correlation between semiquantitative immunohistochemistry and radioimmunological determination was observed too. CONCLUSIONS From our findings we conclude that 8-epi-PGF2 alpha is especially accumulated in coronary arteries from CHD patients and therefore is likely to be involved in atherogenesis.

Clinical and experimental evidence of prostaglandin E1-induced angiogenesis in the myocardium of patients with ischemic heart disease

OBJECTIVE Prostaglandin E1 (PGE-1) is a potent vasodilative agent which has been used to bridge patients with chronic heart failure listed for heart transplantation (HTX). In various experimental settings PGE-1 appears to stimulate angiogenesis by inducing vascular endothelial growth factor expression. This observational clinical study sought to investigate the angiogenic effects of PGE-1 in the failing human heart. METHODS Neovascularization was investigated in 14 explanted hearts from patients with ischemic cardiomyopathy (ICMP) who had been bridged to HTX with PGE-1 (8+/-1 mg/kg/min, 97+/-75.6 days) and compared with 14 hearts who did not receive PGE-1 prior to HTX. In three sectional areas obtained from the left ventricular wall CD34, von Willebrand factor (vWf), nuclear Ki67 (MIB-1), and VEGF were quantified by immunohistochemistry to estimate capillary density and endothelial cell proliferation. Additionally, to investigate a possible angiogenic effect of PGE-1 in vitro, cultured human coronary artery smooth muscle cells (HCASMCs) were treated with PGE-1. RESULTS PGE-1-treated patients had significantly more CD34- and vWf-positive cells in the subepicardium (both P<0.01), myocardium (both P<0.0001) and subendocardium (P<0.01 and P<0.001) as compared to the nonPGE-1 group. Proliferative endothelial activity expressed by the presence of MIB-1- and VEGF-positive cells (both P<0.0001 in all layers) was increased more than twofold. Addition of PGE-1 to HCASMCs in cell culture resulted in a significant increase in VEGF production (164.0+/-19.7 pg/10(5) cells/24 h, P<0.005) as compared to the control cell line (66.6+/-8.7 pg/10(5) cells/24 h, P<0.005). CONCLUSIONS Our data demonstrate that PGE-1 is a potent stimulator of angiogenesis via upregulation of VEGF expression. The induction of therapeutic angiogenesis in patients with severe ICMP might explain the favorable clinical outcome in PGE-1 treated patients until HTX.

Accumulation of oxidized LDL in human semilunar valves correlates with coronary atherosclerosis.

OBJECTIVE Recent data indicate that oxidized low-density lipoprotein (ox-LDL) has several proatherogenic effects, e.g. induction of macrophage chemoattractants, adhesion molecules, cytokines, type-1 plasminogen activator inhibitor and platelet-derived growth factor A-chain by smooth muscle cells. Therefore, ox-LDL has been utilized as a marker of oxidative modification of proteins in atherosclerosis. Because heart valves consist of smooth muscle cells, fibroblasts and endothelial cells, and because valvular disease and coronary atherosclerosis could result from similar biological processes, we investigated ox-LDL accumulation in isolated aortic and pulmonary valves and coronary arteries from patients with angiographically proven coronary heart disease (CHD, n = 19), patients with idiopathic congestive heart failure (IDCM = idiopathic dilated cardiomyopathy, n = 20), and transplant donors. METHODS Masson-Goldner staining and immunohistochemistry utilizing anti ox-LDL and CD68 were performed on paraffin sections of freshly isolated semilunar valves. Data were analyzed by digital image planimetry and by visual scoring of staining intensity. RESULTS Ox-LDL immunoreactivity was identified in the vascular aspect of the attachment line, in the deep valve stroma, and in the ventricular and vascular endothelium of the semilunar valves, colocalizing with macrophages. Valvular ox-LDL area was significantly increased in CHD-patients (P < 0.03) and IDCM-patients (P < 0.04) compared with controls. More ox-LDL was accumulating in the pulmonary valves than in the aortic valves (P = 0.04) as assessed by area and staining intensity. Valvular ox-LDL area in pulmonary valve and aortic valve was significantly correlated with ox-LDL accumulation in the intimal layer (P < 0.001) and medial layer (P < 0.001) of coronary arteries from the same patients. CONCLUSION The data suggest that the biological process leading to ox-LDL accumulation in coronary atherosclerosis also involves heart valves. Therefore, accumulation of the oxidative stress marker ox-LDL in heart valves illustrates atherosclerosis as an additional mechanisms accelerating valvular degeneration in these patients.

Angiogenesis stimulation in explanted hearts from patients pre-treated with intravenous prostaglandin E1

BACKGROUND Prostaglandin E(1) (PGE(1)) is a potent vasodilator and induces angiogenesis in animal tissues. Previous clinical studies demonstrated that PGE(1) improves hemodynamic parameters in patients with heart failure listed for heart transplantation (HTX). Therefore, we designed a retrospective immunohistochemistry study to investigate various markers of angiogenesis using hearts explanted from PGE(1)-treated patients with idiopathic dilated cardiomyopathy (IDCM). METHODS AND RESULTS We investigated neovascularization in 18 hearts explanted from patients with IDCM: 9 patients received treatment with chronic infusions of PGE(1) for end-stage heart failure before HTX, whereas the remaining patients with IDCM did not receive PGE(1) and served as controls. We used immunoreactivity against CD34, von Willebrand factor (vWf), vascular endothelial growth factor (VEGF), and MIB-1 (Ki-67) to quantify angiogenesis, and used sirius red staining to determine the degree of fibrosis. Compared with the control group, PGE(1)-treated patients had significantly more CD34-, vWf- and MIB-1-positive cells in the sub-endocardium, myocardium and sub-epicardium (p < 0.01). The degree of fibrosis in the hearts of PGE(1)-treated patients was significantly lower than in control patients (p < 0.05), but we did not see any difference in the percentage of muscle mass. Finally, throughout the ventricles, we found significantly more VEGF-positive capillaries in the PGE(1) group (p < 0.0001). CONCLUSIONS The data suggest that PGE(1) could be a potent inducer of angiogenesis and the angiogenic factor VEGF, and could cause reduced fibrosis in the failing human heart.

Quantitative analysis of peroxisome proliferator‐activated receptor gamma (PPARγ) expression in arteries and hearts of patients with ischaemic or dilated cardiomyopathy

PPARγ, a nuclear transcription factor, is expressed in various cells within the vasculature and in cardiomyocytes. It has been suggested that PPARγ is involved in atherogenesis and in cardiac hypertrophy. Therefore, we sought to quantify PPARγ mRNA in coronary arteries, the aorta and left ventricular specimens from patients with ischaemic (CHD) and dilated cardiomyopathy (CMP). Using real‐time PCR, we were able to demonstrate the expression of PPARγ in all of the human specimens. The lowest expression of PPARγ was detected in the aorta specimens of both groups (this was set to one). In comparison, the expression in coronary arteries was 2.32‐fold in CHD‐ and 3.78‐fold in CMP specimens and in the left ventricle specimens, 2.12‐fold in CHD‐ and 3.51‐fold in CMP. Samples from CHD patients showed a higher expression of PPARγ in all of the samples compared to those from CMP patients (aorta: 1.99‐fold; coronary arteries: 1.35; left ventricles: 1.23). PPARγ levels were not significantly correlated to CD 36 expression values in any group, suggesting that higher levels of PPARγ are not principally due to increased PPARγ expression in macrophages. This was confirmed by immunohistochemical analysis, which showed that PPARγ is also located in the smooth muscle layer and in cardiomyocytes. In conclusion, our observations of increased PPAR mRNA expression in the coronary arteries and left ventricles from CHD and CMP patients suggest an important function of this nuclear receptor in the pathogenesis of heart disease.

The peroxisome proliferator-activated receptor gamma (PPARγ) is highly expressed in human heart ventricles

Peroxisome proliferator-activated receptor gamma (PPARgamma) is a ligand activated transcription factor which regulates gene expression in various tissues. PPARgamma was primarily found to be associated with lipid and glucose metabolism. Recent experimental studies provided evidence that PPARgamma is also expressed in the arterial wall and in cardiomyocytes and described PPARgamma as a transducer of antihypertropic signaling in the heart. This comparative study sought to investigate whether PPARgamma is differently expressed in the aorta, coronary arteries and left ventricle specimens derived from healthy heart donors (n = 5). By using quantitative PCR, we found that PPARgamma is expressed in all of the human specimens with the by far highest expression (5.01-fold) in the left ventricles compared to aorta, whereas no significant difference was detected between coronary arteries (0.93-fold) vs. aorta. Furthermore, especially great interindividual variations were observed in PPARgamma expression in aorta, and to a lesser extent, in coronary arteries and left ventricle specimens. In conclusion, our data argue for the prominent role of PPARgamma in the human heart, particularly in the normal left ventricle.

The isoprostane 8-epi-PGF2α is a valuable indicator of oxidative injury in human heart valves

To date, little information is available concerning oxidative injury in human cardiac valves. Therefore, we sought to investigate whether the isoprostane, 8-epi-PGF(2alpha), a novel oxidative stress marker, is localized in aortic and pulmonary valves derived from explanted hearts of patients suffering from idiopathic dilative cardiomyopathy (IDC). By using semiquantitative immunohistochemistry, we demonstrated that 8-epi-PGF(2alpha) is localized in both valves with pulmonary valves accumulating more of this isoprostane compared to aortic valves (36.69+/-12.04% vs. 31.54+/-11.49%, P<.05). These results were confirmed by a radioimmunoassay (RIA) analysis showing a similar, but not significant, difference between the two valves (288.50+/-72.18 pg/mg protein in the pulmonary valves and 267.30+/-58.77 pg/mg protein in aortic valves, P=.09). Considering the data presented in this study, we suggest that 8-epi-PGF(2alpha) is a valuable indicator of oxidative injury in human semilunar valves.

Expression of fibrinolytic antigens in redistributed cardiac mast cells in auricular thrombosis

Recent data suggest that auricular thrombosis is associated with an increase and accumulation of mast cells (MC) in the subendothelial region of the upper endocardium. However, the molecular basis and the functional role of MC in this process are not known. In the current study, expression of fibrinolytic and antifibrinolytic antigens in human cardiac MC was analyzed by immunohistochemistry. MC were found to react with antibodies against tissue-type plasminogen activator (tPA) and urokinase receptor (uPAR/CD87), but not with antibodies against urokinase (uPA) or plasminogen activator inhibitors (PAI-1, PAI-2). Significant changes were observed when the phenotype of accumulated MC in the upper endocardium in patients with auricular thrombosis was compared with the phenotype of myocardial MC in the same patients or with MC in normal hearts. These redistributed MC stained less intensely with antibodies against tPA and chymase but retained their staining for tryptase and uPAR. Together, these data indicate that cardiac MC are a source of fibrinolytic antigens and that accumulation of MC in auricular thrombosis is associated with phenotypic changes of MC and loss of cellular tPA. It is hypothesized that MC and their products may play a role in endogenous fibrinolysis in auricular thrombosis.