Coxsackievirus B (CVB) is an enterovirus that causes a self-limited febrile illness in infants, but can also cause myocarditis. Long-term consequences of mild CVB infection are unknown, although an association between heart failure and seropositive status has been previously described. We have shown that early postnatal exposure to doxorubicin depleted c-Kit+ cardiac stem cells (CSCs). Cardiac dysfunction in adult mice only developed after exercise challenge, or experimentally-induced myocardial infarction. We now report that CSCs from neonatal mouse hearts were susceptible to cytopathic CVB infection. To learn if mild CVB infection might deplete the CSC population in the heart, we inoculated newborn BALB/c mice with a recombinant CVB expressing eGFP. We observed CVB-infected CSCs 2 days post-inoculation and documented a reduction in the number of c-Kit+ cells in the hearts of animals at 4 and 11 weeks of age despite the absence of detectable virus. Moreover, CVB infection induced differentiation in the surviving CSCs. These results indicate that CVB can infect CSCs in the neonatal heart and trigger their destruction. Premature differentiation of surviving cells may also explain the reduced CSC population in adult mice. Despite normal histologic features in adult hearts, prolonged exercise challenge elicited cardiac hypertrophy and fibrosis in mice infected with CVB as pups. We suggest that the loss of CSCs after mild neonatal CVB infection may predispose to late-onset heart failure.
The requirement for atrial function in developing heart is unknown. To address this question, we have generated mice deficient in atrial myosin light chain 2 (MLC2a), a major structural component of the atrial myofibrillar apparatus. Inactivation of the Mlc2a gene resulted in severely diminished atrial contraction and consequent embryonic lethality at ED10.5-11.5, demonstrating that atrial function is essential for embryogenesis. Our data also address two longstanding questions in cardiovascular development: the connection between function and form during cardiac morphogenesis, and the requirement for cardiac function during vascular development. Diminished atrial function in MLC2a-null embryos resulted in a number of consistent secondary abnormalities in both cardiac morphogenesis and angiogenesis. Our results unequivocally demonstrate that normal cardiac function is directly linked to normal morphogenic development of heart and vasculature. These data have important implications for the etiology of congenital heart disease.
Background— The anthracycline doxorubicin is an effective chemotherapeutic agent used to treat pediatric cancers but is associated with cardiotoxicity that can manifest many years after the initial exposure. To date, very little is known about the mechanism of this late-onset cardiotoxicity. Methods and Results— To understand this problem, we developed a pediatric model of late-onset doxorubicin-induced cardiotoxicity in which juvenile mice were exposed to doxorubicin, using a cumulative dose that did not induce acute cardiotoxicity. These mice developed normally and had no obvious cardiac abnormalities as adults. However, evaluation of the vasculature revealed that juvenile doxorubicin exposure impaired vascular development, resulting in abnormal vascular architecture in the hearts with less branching and decreased capillary density. Both physiological and pathological stress induced late-onset cardiotoxicity in the adult doxorubicin-treated mice. Moreover, adult mice subjected to myocardial infarction developed rapid heart failure, which correlated with a failure to increase capillary density in the injured area. Progenitor cells participate in regeneration and blood vessel formation after a myocardial infarction, but doxorubicin-treated mice had fewer progenitor cells in the infarct border zone. Interestingly, doxorubicin treatment reduced proliferation and differentiation of the progenitor cells into cells of cardiac lineages. Conclusions— Our data suggest that anthracycline treatment impairs vascular development as well as progenitor cell function in the young heart, resulting in an adult heart that is more susceptible to stress.
Background: PARIS (Parkin Interacting Substrate) is a recently identified zinc finger protein acting as a transcriptional inhibitor for PGC-1α. Previous studies showed that Parkin ubiquitinates PAR...
Bcl-2/adenovirus E1B 19-kDa protein-interacting protein 3 (Bnip3) is a member of the Bcl-2 homology domain 3-only subfamily of proapoptotic Bcl-2 proteins and is associated with cell death in the myocardium. In this study, we investigated the potential mechanism(s) by which Bnip3 activity is regulated. We found that Bnip3 forms a DTT-sensitive homodimer that increased after myocardial ischemia-reperfusion (I/R). The presence of the antioxidant N-acetylcysteine reduced I/R-induced homodimerization of Bnip3. Overexpression of Bnip3 in cells revealed that most of exogenous Bnip3 exists as a DTT-sensitive homodimer that correlated with increased cell death. In contrast, endogenous Bnip3 existed mainly as a monomer under normal conditions in the heart. Screening of the Bnip3 protein sequence revealed a single conserved cysteine residue at position 64. Mutation of this cysteine to alanine (Bnip3C64A) or deletion of the NH2-terminus (amino acids 1-64) resulted in reduced cell death activity of Bnip3. Moreover, mutation of a histidine residue in the COOH-terminal transmembrane domain to alanine (Bnip3H173A) almost completely inhibited the cell death activity of Bnip3. Bnip3C64A had a reduced ability to interact with Bnip3, whereas Bnip3H173A was completely unable to interact with Bnip3, suggesting that homodimerization is important for Bnip3 function. A consequence of I/R is the production of reactive oxygen species and oxidation of proteins, which promotes the formation of disulfide bonds between proteins. Thus, these experiments suggest that Bnip3 functions as a redox sensor where increased oxidative stress induces homodimerization and activation of Bnip3 via cooperation of the NH2-terminal cysteine residue and the COOH-terminal transmembrane domain.
MicroRNAs (miRs) regulate post-transcriptional gene expression and protein translation. There is now increasing evidence that miRs regulate mitochondrial turnover. miR-33 regulates cholesterol metabolism and mitochondrial function in cardiac fibroblasts and macrophages and has been implicated in promoting fibrosis. Excessive fibrosis contributes to the development of adverse LV remodeling. Given our recent findings that a glucagon-like peptide-1 receptor agonist (GLP1Ra) [Sigma] induces mitophagy and mitigates post-MI LV remodeling, the purpose of this study was to determine its effects on miR-33 expression after MI. We analyzed miR-33 expression in the viable regions of hearts in lean mice after permanent coronary arterial ligation (PCAL) and subsequent treatment with GLP1Ra administered 2h and 48h after the infarction (total of 2 doses). PCAL was associated with a marked increase in miR-33 that peaked at day 3 (data not shown). In the presence of GLP1Ra, miR-33 expression was suppressed 3 days post-PCAL ( A ). Polysome profiling revealed that miR-33 was decreased in the translating fractions of GLP1Ra-treated mice and increased in the non-translating fraction (80S free ribosomes) compared to vehicle ( B and C ). Decreased association of miR-33 with polysomes in GLP1Ra-treated mice would allow for increased target translation. Given that suppression of miR-33 is implicated in promoting fibrosis, a suppression of this miR by acute GLP1Ra treatment could explain the beneficial effects of this drug in limiting adverse cardiac remodeling.
Almost 30% of survivors of myocardial infarction (MI) develop heart failure (HF), in part due to damage caused by the accumulation of dysfunctional mitochondria. Organelle quality control through Parkin-mediated mitochondrial autophagy (mitophagy) is known to play a role in mediating protection against HF damage post-ischaemic injury and remodelling of the subsequent deteriorated myocardium.
Bacterial endotoxin lipopolysaccharide (LPS) is responsible for the multiorgan dysfunction that characterizes septic shock and is causal in the myocardial depression that is a common feature of endotoxemia in patients. In this setting the myocardial dysfunction appears to be due, in part, to the production of proinflammatory cytokines. A line of evidence also indicates that LPS stimulates autophagy in cardiomyocytes. However, the signal transduction pathway leading to autophagy and its role in the heart are incompletely characterized. In this work, we wished to determine the effect of LPS on autophagy and the physiological significance of the autophagic response. Autophagy was monitored morphologically and biochemically in HL-1 cardiomyocytes, neonatal rat cardiomyocytes, and transgenic mouse hearts after the administration of bacterial LPS or TNF-alpha. We observed that autophagy was increased after exposure to LPS or TNF-alpha, which is induced by LPS. The inhibition of TNF-alpha production by AG126 significantly reduced the accumulation of autophagosomes both in cell culture and in vivo. The inhibition of p38 MAPK or nitric oxide synthase by pharmacological inhibitors also reduced autophagy. Nitric oxide or H(2)O(2) induced autophagy in cardiomyocytes, whereas N-acetyl-cysteine, a potent antioxidant, suppressed autophagy. LPS resulted in increased reactive oxygen species (ROS) production and decreased total glutathione. To test the hypothesis that autophagy might serve as a damage control mechanism to limit further ROS production, we induced autophagy with rapamycin before LPS exposure. The activation of autophagy by rapamycin suppressed LPS-mediated ROS production and protected cells against LPS toxicity. These findings support the notion that autophagy is a cytoprotective response to LPS-induced cardiomyocyte injury; additional studies are needed to determine the therapeutic implications.
