Despite current treatment regimens, heart failure remains the leading cause of morbidity and mortality in the developed world due to the limited capacity of adult mammalian ventricular cardiomyocytes to divide and replace ventricular myocardium lost from ischemia-induced infarct1,2. As a result, there is great interest to identify potential cellular sources and strategies to generate new ventricular myocardium3. Past studies have shown that lower vertebrate and early postnatal mammalian ventricular cardiomyocytes can proliferate to help regenerate injured ventricles4–6; however, recent studies have suggested that additional endogenous cellular sources may contribute to this overall ventricular regeneration3. Here, we have developed in the zebrafish a combination of fluorescent reporter transgenes, genetic fate-mapping strategies, and a ventricle-specific genetic ablation system to discover that differentiated atrial cardiomyocytes can transdifferentiate into ventricular cardiomyocytes to contribute to zebrafish cardiac ventricular regeneration. Using in vivo time-lapse and confocal imaging, we monitored the dynamic cellular events during atrial-to-ventricular cardiomyocyte transdifferentiation to define intermediate cardiac reprogramming stages. Importantly, we observed that Notch signaling becomes activated in the atrial endocardium following ventricular ablation, and discovered that inhibiting Notch signaling blocked the atrial-to-ventricular transdifferentiation and cardiac regeneration. Overall, these studies not only provide evidence for the plasticity of cardiac lineages during myocardial injury, but more importantly reveal an abundant new potential cardiac resident cellular source for cardiac ventricular regeneration.
Summary
In Caenorhabditis elegans, the programmed repression of
the heat shock response (HSR) accompanies the transition to reproductive
maturity, leaving cells vulnerable to environmental stress and protein
aggregation with age. To identify the factors driving this event, we performed
an unbiased genetic screen for suppressors of stress resistance, and identified
the mitochondrial electron transport chain (ETC) as a central regulator of the
age-related decline of the HSR and cytosolic proteostasis. Mild down-regulation
of ETC activity, either by genetic modulation or exposure to mitochondria
targeted xenobiotics, maintained the HSR in adulthood by increasing HSF-1
binding and RNA polymerase II recruitment at HSF-1 target genes. This resulted
in a robust restoration of cytoplasmic proteostasis and increased vitality later
in life, without detrimental effects on fecundity. We propose that low levels of
mitochondrial stress regulate cytoplasmic proteostasis and healthspan during
aging by coordinating the long-term activity of HSF-1 with conditions preclusive
to optimal fitness.
Conclusions: Our analysis found a sustained R c and prolonged incubation/ infectious periods, suggesting COVID-19 is highly infectious. Although interventions in China have been effective in controlling secondary transmission, sustained global efforts are needed to contain an emerging pandemic. Alternative interventions can be explored using modelling studies to better inform policymaking as the outbreak continues.
Melatonin protects cells against various types of oxidative stress-induced apoptosis due primarily to its ability to effectively scavenge pathological and disease condition-augmented generation of mitochondrial reactive oxygen species (mROS). Once produced, mROS indiscriminately damage mitochondrial components and more importantly they crucially activate directly the mitochondrial permeability transition (MPT), one of the critical mechanisms for initiating post mitochondrial apoptotic signaling. Whether or not melatonin targets directly the MPT, however, remains inconclusive, particularly during oxidative stress. This study, thus, investigated this possibility of an 'oxidation free Ca(2+) stress' in the presence of vitamin E after ionomycin exposure as a sole Ca(2+)-mediated MPT in order to exclude melatonin's primary antioxidative effects as well as Ca(2+)-mediated oxidative stress. The studies were carried out using cultured rat brain astrocytes RBA-1. With the application of laser scanning multiple fluorescence imaging microscopy, we visualized for the first time multiple mitochondrial protective effects provided by melatonin during Ca(2+) stress. First, melatonin, due to its primary antioxidative actions, completely prevented mCa(2+)-induced mROS formation during ionomycin exposure. Secondly, when melatonin(')s antioxidative effects were prevented due to the addition of vitamin E, melatonin significantly prevented mCa(2+)-mediated MPT and apoptosis suggesting its direct targeting of the MPT. Surprisingly, in the presence of cyclosporin A, a MPT inhibitor, melatonin reduced further mCa(2+)-mediated apoptosis during ionomycin exposure also suggesting its targeting beyond the MPT. As astrocytes are actively involve in regulating synaptic transmission and neurovascular coupling in the CNS, these multiple mitochondrial layers of protection provided by melatonin against mCa(2+)-and/or mROS-mediated apoptosis in astrocytes may be crucial for future therapeutic prevention and treatment of astrocyte-mediated neurodegenerative diseases in the CNS.
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