13 research outputs found

    Nanomechanics of cell membrane and cellular contacts in control and failing hearts

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    In recent years, a growing number of studies have shown that mechanical properties play an important role in both structure and function of cells. Heart is an extremely dynamic organ; therefore, cardiac myocytes are constantly subjected to a mechanical stress. To date, titin protein and collagen fibers were considered to be the main regulators of tissue Young’s modulus, one of the standard measures of mechanical properties. Recently, studying mechanical properties at cellular, tissue and organ level, demonstrated contribution of mechanical cues to the development of different diseases, including heart failure. During the progression of this pathology, cells undergo several changes in physiology and mechanobiology, where a significant increase in Young’s modulus is observed. Work presented in this thesis examines cardiomyocyte nanomechanical properties focusing specifically on measuring transverse cortical Young’s modulus by using high resolution Scanning Ion Conductance Microscopy in different mouse, rat and human disease models of heart failure. Further work investigates the role of different intracellular elements such as generic and cardiac-specific cytoskeleton, mitochondria and mechanical load that can affect cardiac mechanics. In order to determine their role RT-PCR, Western blot, Transmission Electron Microscopy and immunofluorescent staining techniques were used. To obtain a bigger picture on cardiac mechanics, co-cultures of myocytes alone and with fibroblasts were established where changes in Young’s modulus at the homo- and hetero-cellular cell-cell junction were studied. Using a novel Junctional Mapper software precise quantification of intercalated disc proteins population was attainable. Scanning Ion Conductance Microscope was adapted to measure cell Young’s modulus at a nanoscale resolution and used in an extensive study of cardiomyocytes mechanics. In normal myocytes, the contribution of individual cellular elements to cell mechanical properties was assessed via inhibitor analysis. Consequently, actin, microtubules and caveolae were found to have the biggest contribution to cardiomyocyte mechanics. In a rat model of heart failure (16 weeks after myocardial infarction), cardiac myocytes show a markedly increased Youngs modulus with a significantly higher value in surface crest areas than Z-grooves. This could be related to mitochondria rearrangement, actin-myosin incomplete relaxation and increased microtubular network densification. In fact, microtubule post translational modifications (acetylation and detyrosination) were found to be increased in failing cells and that will correlates with an increased Young’s modulus. Moreover, a cross-talk has been revealed between these two populations of microtubules, as increased level of acetylation results in reduced detyrosination. Removal of load from both control and failing heart markedly reduces Young’s modulus of myocytes; in fact, after unloading the hearts failing cardiomyocytes present a similar Young’s modulus value to healthy cells. Other changes can be observed after the removal of load, for example the level of acetylated and detyrosinated microtubules and the mitochondria numbers are also reduced. Long term exposure to Angiotensin II (Ang II) is known to exert a hypertrophic effect on cardiac myocytes, whereas little is known about acute, short-term action of Ang II. This work suggests a novel, beneficial role of acute treatment with Ang II in regulating cardiomyocyte mechanics. Reduced Young’s modulus is observed in Ang II treated myocytes, which is driven by changes in microtubular network, including acetylation and detyrosination modifications. More importantly, Ang II acts equally upon failing myocytes bringing Young’s modulus value to the normal level. Therefore, it can be potentially used to treat diseased heart muscle cells. Overall, this thesis describes a novel technique of measuring Young’s modulus in live cells. Using this method, a detailed study on changes in cardiomyocyte mechanics is presented. In line with other studies, we observe that understanding myocardial mechanobiology is imperative to fully disclose the mechanism of initiation and progression of heart failure.Open Acces

    Hypertensive pressure mechanosensing alone triggers lipid droplet accumulation and transdifferentiation of vascular smooth muscle cells to foam cells

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    Arterial Vascular smooth muscle cells (VSMCs) play a central role in the onset and progression of atherosclerosis. Upon exposure to pathological stimuli, they can take on alternative phenotypes that, among others, have been described as macrophage like, or foam cells. VSMC foam cells make up >50% of all arterial foam cells and have been suggested to retain an even higher proportion of the cell stored lipid droplets, further leading to apoptosis, secondary necrosis, and an inflammatory response. However, the mechanism of VSMC foam cell formation is still unclear. Here, it is identified that mechanical stimulation through hypertensive pressure alone is sufficient for the phenotypic switch. Hyperspectral stimulated Raman scattering imaging demonstrates rapid lipid droplet formation and changes to lipid metabolism and changes are confirmed in ABCA1, KLF4, LDLR, and CD68 expression, cell proliferation, and migration. Further, a mechanosignaling route is identified involving Piezo1, phospholipid, and arachidonic acid signaling, as well as epigenetic regulation, whereby CUT&Tag epigenomic analysis confirms changes in the cells (lipid) metabolism and atherosclerotic pathways. Overall, the results show for the first time that VSMC foam cell formation can be triggered by mechanical stimulation alone, suggesting modulation of mechanosignaling can be harnessed as potential therapeutic strategy

    Mediastinal Lymphadenopathy, Class-Switched Auto-Antibodies and Myocardial Immune-Complexes During Heart Failure in Rodents and Humans.

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    Mediastinal lymphadenopathy and auto-antibodies are clinical phenomena during ischemic heart failure pointing to an autoimmune response against the heart. T and B cells have been convincingly demonstrated to be activated after myocardial infarction, a prerequisite for the generation of mature auto-antibodies. Yet, little is known about the immunoglobulin isotype repertoire thus pathological potential of anti-heart auto-antibodies during heart failure. We obtained human myocardial tissue from ischemic heart failure patients and induced experimental MI in rats. We found that anti-heart autoimmunity persists during heart failure. Rat mediastinal lymph nodes are enlarged and contain active secondary follicles with mature isotype-switched IgG2a B cells. Mature IgG2a auto-antibodies specific for cardiac antigens are present in rat heart failure serum, and IgG and complement C3 deposits are evident in heart failure tissue of both rats and human patients. Previously established myocardial inflammation, and the herein provided proof of B cell maturation in lymph nodes and myocardial deposition of mature auto-antibodies, provide all the hallmark signs of an established autoimmune response in chronic heart failure

    Microtubule-mediated regulation of  β2AR translation and unction in failing hearts

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    Background: Beta-1 adrenergic receptor (β 1 AR)- and Beta-2 adrenergic receptor (β 2 AR)-mediated cyclic adenosine monophosphate signaling has distinct effects on cardiac function and heart failure progression. However, the mechanism regulating spatial localization and functional compartmentation of cardiac β-ARs remains elusive. Emerging evidence suggests that microtubule-dependent trafficking of mRNP (messenger ribonucleoprotein) and localized protein translation modulates protein compartmentation in cardiomyocytes. We hypothesized that β-AR compartmentation in cardiomyocytes is accomplished by selective trafficking of its mRNAs and localized translation. Methods: The localization pattern of β-AR mRNA was investigated using single molecule fluorescence in situ hybridization and subcellular nanobiopsy in rat cardiomyocytes. The role of microtubule on β-AR mRNA localization was studied using vinblastine, and its effect on receptor localization and function was evaluated with immunofluorescent and high-throughput Förster resonance energy transfer microscopy. An mRNA protein co-detection assay identified plausible β-AR translation sites in cardiomyocytes. The mechanism by which β-AR mRNA is redistributed post–heart failure was elucidated by single molecule fluorescence in situ hybridization, nanobiopsy, and high-throughput Förster resonance energy transfer microscopy on 16 weeks post–myocardial infarction and detubulated cardiomyocytes. Results: β 1 AR and β 2 AR mRNAs show differential localization in cardiomyocytes, with β 1 AR found in the perinuclear region and β 2 AR showing diffuse distribution throughout the cell. Disruption of microtubules induces a shift of β 2 AR transcripts toward the perinuclear region. The close proximity between β 2 AR transcripts and translated proteins suggests that the translation process occurs in specialized, precisely defined cellular compartments. Redistribution of β 2 AR transcripts is microtubule-dependent, as microtubule depolymerization markedly reduces the number of functional receptors on the membrane. In failing hearts, both β 1 AR and β 2 AR mRNAs are redistributed toward the cell periphery, similar to what is seen in cardiomyocytes undergoing drug-induced detubulation. This suggests that t-tubule remodeling contributes to β-AR mRNA redistribution and impaired β 2 AR function in failing hearts. Conclusions: Asymmetrical microtubule-dependent trafficking dictates differential β 1 AR and β 2 AR localization in healthy cardiomyocyte microtubules, underlying the distinctive compartmentation of the 2 β-ARs on the plasma membrane. The localization pattern is altered post–myocardial infarction, resulting from t-tubule remodeling, leading to distorted β 2 AR-mediated cyclic adenosine monophosphate signaling

    Cardiomyocyte-myofibroblast contact dynamism is modulated by connexin-43

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    Healthy cardiomyocytes are electrically coupled at the intercalated discs by gap junctions. In infarcted hearts, adverse gap-junctional remodeling occurs in the border zone, where cardiomyocytes are chemically and electrically influenced by myofibroblasts. The physical movement of these contacts remains unquantified. Using scanning ion conductance microscopy, we show that intercellular contacts between cardiomyocytes and myofibroblasts are highly dynamic, mainly owing to the edge dynamics (lamellipodia) of the myofibroblasts. Decreasing the amount of functional connexin-43 (Cx43) at the membrane through Cx43 silencing, suppression of Cx43 trafficking, or hypoxia-induced Cx43 internalization attenuates heterocellular contact dynamism. However, we found decreased dynamism and stabilized membrane contacts when cellular coupling was strengthened using 4-phenylbutyrate (4PB). Fluorescent-dye transfer between cells showed that the extent of functional coupling between the 2 cell types correlated with contact dynamism. Intercellular calcein transfer from myofibroblasts to cardiomyocytes is reduced after myofibroblast-specific Cx43 down-regulation. Conversely, 4PB-treated myofibroblasts increased their functional coupling to cardiomyocytes. Consistent with lamellipodia-mediated contacts, latrunculin-B decreases dynamism, lowers physical communication between heterocellular pairs, and reduces Cx43 intensity in contact regions. Our data show that heterocellular cardiomyocyte-myofibroblast contacts exhibit high dynamism. Therefore, Cx43 is a potential target for prevention of aberrant cardiomyocyte coupling and myofibroblast proliferation in the infarct border zone.-Schultz, F., Swiatlowska, P., Alvarez-Laviada, A., Sanchez-Alonso, J. L., Song, Q., de Vries, A. A. F., Pijnappels, D. A., Ongstad, E., Braga, V. M. M., Entcheva, E., Gourdie, R. G., Miragoli, M., Gorelik, J. Cardiomyocyte-myofibroblast contact dynamism is modulated by connexin-43

    Lem2 is essential for cardiac development by maintaining nuclear integrity

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    Aims: Nuclear envelope integrity is essential for the compartmentalization of the nucleus and cytoplasm. Importantly, mutations in genes encoding nuclear envelope (NE) and associated proteins are the second highest cause of familial dilated cardiomyopathy. One such NE protein that causes cardiomyopathy in humans and affects mouse heart development is Lem2. However, its role in the heart remains poorly understood. Methods and results: We generated mice in which Lem2 was specifically ablated either in embryonic cardiomyocytes (Lem2 cKO) or in adult cardiomyocytes (Lem2 iCKO) and carried out detailed physiological, tissue, and cellular analyses. High-resolution episcopic microscopy was used for three-dimensional reconstructions and detailed morphological analyses. RNA-sequencing and immunofluorescence identified altered pathways and cellular phenotypes, and cardiomyocytes were isolated to interrogate nuclear integrity in more detail. In addition, echocardiography provided a physiological assessment of Lem2 iCKO adult mice. We found that Lem2 was essential for cardiac development, and hearts from Lem2 cKO mice were morphologically and transcriptionally underdeveloped. Lem2 cKO hearts displayed high levels of DNA damage, nuclear rupture, and apoptosis. Crucially, we found that these defects were driven by muscle contraction as they were ameliorated by inhibiting myosin contraction and L-type calcium channels. Conversely, reducing Lem2 levels to ∼45% in adult cardiomyocytes did not lead to overt cardiac dysfunction up to 18 months of age. Conclusions: Our data suggest that Lem2 is critical for integrity at the nascent NE in foetal hearts, and protects the nucleus from the mechanical forces of muscle contraction. In contrast, the adult heart is not detectably affected by partial Lem2 depletion, perhaps owing to a more established NE and increased adaptation to mechanical stress. Taken together, these data provide insights into mechanisms underlying cardiomyopathy in patients with mutations in Lem2 and cardio-laminopathies in general
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