Vascular Endothelial Dysfunction in β-Thalassemia Occurs Despite Increased eNOS Expression and Preserved Vascular Smooth Muscle Cell Reactivity to NO

The hereditary β-thalassemia major condition requires regular lifelong blood transfusions. Transfusion-related iron overloading has been associated with the onset of cardiovascular complications, including cardiac dysfunction and vascular anomalies. By using an untransfused murine model of β-thalassemia major, we tested the hypothesis that vascular endothelial dysfunction, alterations of arterial structure and of its mechanical properties would occur despite the absence of treatments.Vascular function and structure were evaluated ex vivo. Compared to the controls, endothelium-dependent vasodilation with acetylcholine was blunted in mesenteric resistance arteries of β-thalassemic mice while the endothelium-independent vasodilator (sodium nitroprusside) produced comparable vessel dilation, indicating endothelial cell impairment with preserved smooth muscle cell reactivity to nitric oxide (NO). While these findings suggest a decrease in NO bioavailability, Western blotting showed heightened expression of aortic endothelial NO synthase (eNOS) in β-thalassemia. Vascular remodeling of the common carotid arteries revealed increased medial elastin content. Under isobaric conditions, the carotid arteries of β-thalassemic mice exhibited decreased wall stress and softening due to structural changes of the vessel wall.A complex vasculopathy was identified in untransfused β-thalassemic mice characterized by altered carotid artery structure and endothelial dysfunction of resistance arterioles, likely attributable to reduced NO bioavailability despite enhanced vascular eNOS expression

Caractérisation des désordres microcirculatoires par techniques d'imagerie chez des souris transgéniques bêta-thalassémiques et drépanocytaires

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal

Évaluation des désordres cardiovasculaires chez des souris bêta-thalassémiques

L’hémoglobine est une protéine contenue dans les globules rouges dont la principale fonction est le transport de l’oxygène. Chaque molécule d’hémoglobine est un tétramère constitué de deux paires de globines identiques de type α et β. La β-thalassémie est une maladie génétique hématopoïétique provenant de mutations du gène encodant l'hémoglobine. Ce désordre se caractérise par une diminution ou une absence totale de la synthèse de la chaîne β-globine résultant principalement en une anémie hémolytique sévère ainsi que des complications multisystémiques, telles que la splénomégalie, des déformations osseuses et une dysfonction hépatique et rénale. Actuellement, les transfusions sanguines chroniques représentent le traitement standard des patients β-thalassémiques. Cette thérapie nécessite l’administration conjointe d’un traitement chélateur de fer puisqu’elle entraîne une accumulation pathologique du fer, considéré à ce jour comme la source principale des complications cardiovasculaires de la β-thalassémie. Néanmoins, malgré le traitement efficace de la surcharge de fer transfusionnelle, l’insuffisance cardiaque demeure encore la principale cause de mortalité chez les patients atteints de β-thalassémie. Cette observation indique possiblement la présence d’un mécanisme complémentaire dans le développement de la physiopathologie cardiaque β-thalassémique. L’objectif du présent projet consistait donc à étudier les altérations cardiovasculaires de la β-thalassémie indépendamment de la surcharge de fer transfusionnelle. En utilisant un modèle murin non-transfusé de la β-thalassémie majeure, nous avons d’abord évalué in vivo, par méthode d’imagerie novatrice échographique à haute fréquence, les propriétés hémodynamiques vasculaires. Nos résultats d’index de Pourcelot ainsi que de résistance vasculaire périphérique totale ont démontré une perturbation de l’écoulement microcirculatoire chez les souris β-thalassémiques non-transfusées. Subséquemment, nous avons étudié la fonction endothéliale de régulation du tonus vasculaire de vaisseaux mésentériques isolés. Nos résultats ont révélé un dysfonctionnement de la réponse vasodilatatrice dépendante de l’endothélium chez les souris β-thalassémiques malgré une augmentation de l’expression de l’enzyme de synthèse du monoxyde d’azote ainsi qu’un remodelage de la carotide commune caractérisé par un épaississement de la paroi vasculaire. Finalement, notre étude échocardiographique de la fonction et la morphologie cardiaque a montré, chez les souris β-thalassémiques, le développement d’une hypertrophie et une dysfonction ventriculaire gauche en l’absence de transfusions sanguines chroniques ou de dépôts directs de fer dans le myocarde. L’ensemble des résultats présentés dans le cadre de cette thèse indique la présence d’une pathologie cardiovasculaire chez les souris β-thalassémiques non-transfusés. Nos travaux permettent de proposer un mécanisme de la pathophysiologie cardiovasculaire β-thalassémique, indépendant de la charge de fer transfusionnelle, impliquant les effets compensatoires d’une anémie chronique combinés à une vasculopathie complexe initiée par les érythrocytes endommagés et l’hémolyse intravasculaire.Hemoglobin is the major protein in red blood cells and is responsible of the oxygen transport. Each hemoglobin molecule is a tetramer consisting of two identical α- and β-globin subunits. β-thalassemia is a genetic hematopoietic disease caused by mutations in hemoglobin genes. This disorder is characterized by a decrease or absence of production of β-globin chain leading mainly to a severe hemolytic anemia and several systemic manifestations, including splenomegaly, skeletal deformities as well as hepatic and renal dysfunctions. Chronic blood transfusions remain the standard treatment for β-thalassemic patients. This therapy requires iron chelating management since it leads to pathological iron accumulation which is currently considered the main cause of cardiovascular complications of β-thalassemia. However, despite adequate control of transfusional iron loading, heart failure remains the leading cause of mortality in β-thalassemia. This issue is possibly indicative of additional pathogenic mechanisms underlying the development of the β-thalassemic cardiac pathology. The objective of the present research project was to study cardiovascular alterations of β-thalassemia independently of transfusional iron overloading. Using an untransfused murine model of β-thalassemia major, we have evaluated in vivo, by non-invasive high-frequency ultrasound imaging, vascular hemodynamic properties. Our results of Pourcelot indices and total peripheral vascular resistance have shown microcirculatory flow disturbances in untransfused β-thalassemic mice. Consequently, we have studied ex vivo the endothelial vasomotor function in isolated mesenteric arterioles. Our findings have pointed out endothelium-dependent vasodilator dysfunction in β-thalassemic mice despite increased expression of nitric oxide synthase, as well as remodeling of the common carotid artery wall. Lastly, our echocardiography studies of heart morphology and function in β-thalassemic mice have demonstrated the development of left ventricle hypertrophy and dysfunction in the absence of chronic blood transfusions or direct myocardial iron deposits. In conclusion, findings presented in this thesis have demonstrated for the first time development of severe cardiovascular complications in untransfused β-thalassemic mice. Based on our results, we have proposed a novel mechanism, independent of direct myocardial iron deposition, responsible for the cardiovascular complications in β-thalassemia. This model combines compensatory effects of chronic anemia with a complex vasculopathy initiated by abnormal erythrocytes and intravascular hemolysis

Non-invasive high-frequency vascular ultrasound elastography.

International audienceNon-invasive vascular elastography (NIVE) was recently introduced to characterize mechanical properties of superficial arteries. In this paper, the feasibility of NIVE and its applicability in the context of high-frequency ultrasound imaging is investigated. First, experiments were performed in vitro on vessel-mimicking phantoms. Polyvinyl alcohol cryogel was used to create two double-layer vessels with different mechanical properties. In both cases, the stiffness of the inner layer was made softer. Radial stress was applied within the lumen of the phantoms by applying incremental static pressure steps with a column of a flowing mixture of water-glycerol. The vessel phantoms were insonified at 32 MHz with an ultrasound biomicroscope to provide cross-section sequences of radio-frequency (RF) ultrasound data. The Lagrangian speckle model estimator (LSME) was used to assess the two-dimensional-strain tensors, and the composite Von Mises elastograms were computed. A new implementation of the LSME based on the optical flow equations was introduced. Deformation parameters were estimated using an inversion algorithm. For each in vitro experiment, both layers of approximately 1 mm were distinguished. Second, the use of the method for the purpose of studying small vessels (MicroNIVE) in genetically engineered rodents was introduced. Longitudinal scans of the carotid artery were performed at 40 MHz. The in vivo results give confidence in the feasibility of MicroNIVE as a potential tool to non-invasively study the impact of targeted genes on vascular remodelling in rodents

Histological analysis of elastin content in media (A) and representative microscopy images of Verhoeff van Gieson-stained sections (B) of the left common carotid arteries in control (open bars) and homo-βthal mice (closed bars, <i>n</i> = 8 per group). Data are means ± SEM.

<p>^*<i>p</i><0.05. L, vascular lumen.</p

Comparison of structural characteristics in common carotid arteries from control (○; <i>n</i> = 13) and homo-βthal mice (•; <i>n</i> = 11).

<p>(A) Luminal diameter, (B) external diameter, (C) wall cross-sectional area (CSA), and (D) wall-to-lumen ratio versus intraluminal pressure. Data are means ± SEM. ^†<i>p</i><0.001.</p

Evidence for a Novel Mechanism Independent of Myocardial Iron in β-Thalassemia Cardiac Pathogenesis

<div><p>Human β-thalassemia major is one of the most prevalent genetic diseases characterized by decrease/absence of β-globin chain production with reduction of erythrocyte number. The main cause of death of treated β-thalassemia major patients with chronic blood transfusion is early cardiac complications that have been attributed to secondary iron overload despite optimal chelation. Herein, we investigated pathophysiological mechanisms of cardiovascular dysfunction in a severe murine model of β-thalassemia from 6 to 15-months of age in the absence of confounding effects related to transfusion. Our longitudinal echocardiography analysis showed that β-thalassemic mice first display a significant increase of cardiac output in response to limited oxygen-carrying erythrocytes that progressed rapidly to left ventricular hypertrophy and structural remodeling. Following this compensated hypertrophy, β-thalassemic mice developed age-dependent deterioration of left ventricular contractility and dysfunction that led toward decompensated heart failure. Consistently, murine β-thalassemic hearts histopathology revealed cardiac remodeling with increased interstitial fibrosis but virtual absence of myocardial iron deposits. Importantly, development of thalassemic cardiac hypertrophy and dysfunction independently of iron overload has uncoupled these cardiopathogenic processes. Altogether our study on β-thalassemia major hemoglobinopathy points to two successive phases resulting from severe chronic anemia and from secondarily induced mechanisms as pathophysiologic contributors to thalassemic cardiopathy.</p> </div

Endothelium-dependent vasodilatory responses of mesenteric resistance arterioles from control (<i>n</i> = 10) (A) and homo-βthal mice (<i>n</i> = 9) (B) to acetylcholine (ACh) in the absence (○) or presence (

<p>▴<b>) of L-NAME.</b> Relaxation responses are expressed as a percentage increase in lumen diameter after norepinephrine pre-contraction. Data are means ± SEM. ^*<i>p</i><0.05 and ^†<i>p</i><0.001.</p

Vasodilatory responses of mesenteric resistance arterioles to acetylcholine (ACh) (A) and sodium nitroprusside (SNP) (B), in control (○; <i>n</i> = 10) and homo-βthal (•; <i>n</i> = 9) mice.

<p>Relaxation responses are expressed as a percentage increase in lumen diameter after norepinephrine pre-contraction. Data are means ± SEM. ^*<i>p</i><0.05.</p