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McCain, Megan

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McCain

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Megan

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McCain, Megan
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    Cell-to-cell coupling in engineered pairs of rat ventricular cardiomyocytes: relation between Cx43 immunofluorescence and intercellular electrical conductance
    (American Physiological Society, 2012) McCain, Megan; Desplantez, Thomas; Geisse, Nicholas A.; Rothen-Rutishauser, Barbara; Oberer, Helene; Parker, Kevin; Kleber, Andre
    Gap junctions are composed of connexin (Cx) proteins, which mediate intercellular communication. Cx43 is the dominant Cx in ventricular myocardium, and Cx45 is present in trace amounts. Cx43 immunosignal has been associated with cell-to-cell coupling and electrical propagation, but no studies have directly correlated Cx43 immunosignal to electrical cell-to-cell conductance, \(g_j\), in ventricular cardiomyocyte pairs. To assess the correlation between Cx43 immunosignal and \(g_j\), we developed a method to determine both parameters from the same cell pair. Neonatal rat ventricular cardiomyocytes were seeded on micropatterned islands of fibronectin. This allowed formation of cell pairs with reproducible shapes and facilitated tracking of cell pair locations. Moreover, cell spreading was limited by the fibronectin pattern, which allowed us to increase cell height by reducing the surface area of the pattern. Whole cell dual voltage clamp was used to record \(g_j\) of cell pairs after 3–5 days in culture. Fixation of cell pairs before removal of patch electrodes enabled preservation of cell morphology and offline identification of patched pairs. Subsequently, pairs were immunostained, and the volume of junctional Cx43 was quantified using confocal microscopy, image deconvolution, and three-dimensional reconstruction. Our results show a linear correlation between gj and Cx43 immunosignal within a range of 8–50 nS.
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    From Womb to Doom: Mechanical Regulation of Cardiac Tissue Assembly in Morphogenesis and Pathogenesis
    (2013-02-14) McCain, Megan; Parker, Kevin Kit; Saffitz, Jeffrey; Weitz, David
    The assembly, form, and function of the heart is regulated by complex mechanical signals originating from intrinsic and extrinsic sources, such as the cytoskeleton and the extracellular matrix. During development, mechanical forces influence the self-assembly of highly organized ventricular myocardium. However, mechanical overload induces maladaptive remodeling of tissue structure and eventual failure. Thus, mechanical forces potentiate physiological or pathological remodeling, depending on factors such as frequency and magnitude. We hypothesized that mechanical stimuli in the form of microenvironmental stiffness, cytoskeletal architecture, or cyclic stretch regulate cell-cell junction formation and cytoskeletal remodeling during development and disease. To test this, we engineered cardiac tissues in vitro and quantified structural and functional remodeling over multiple spatial scales in response to diverse mechanical perturbations mimicking development and disease. We first asked if the mechanical microenvironment impacts tissue assembly. To investigate this, we cultured two-cell cardiac µtissues on flexible substrates with tunable stiffness and monitored cell-cell junction formation over time. As myocytes transitioned from isolated cells to interconnected µtissues, focal adhesions disassembled near cell-cell interfaces and mechanical forces were transmitted almost completely through cell-cell junctions. However, µtissues cultured on stiff substrates mimicking fibrotic microenvironments retained focal adhesions near the cell-cell interface, potentially to reinforce the cell-cell junction in response to excessive forces generated by myofibrils in stiff microenvironments. Intercellular electrical conductance between myocytes was measured as a function of connexin 43 immunosignal and the length-to-width ratio of cell pairs. We observed that conductance was correlated to connexin 43 immunosignal and cell pair length-to-width ratio, indicating that tissue architecture can affect electrical coupling. The impact of mechanical overload was also determined by applying chronic cyclic stretch to engineered cardiac tissues. Stretch activated gene expression patterns characteristic of pathological remodeling, including up-regulation of focal adhesion genes, and impacted sarcomere alignment and myocyte shape. Furthermore, chronic cyclic stretch altered intracellular calcium cycling in a manner similar to heart failure and decreased contractile stress generation, suggestive of maladaptive remodeling. In summary, we show that the assembly, form, and function of cardiac tissue is sensitive to a wide range of mechanical cues that emerge during physiological and pathological growth.