Background The current paradigm of Sinoatrial Node (SAN) impulse generation: (i) is that full-scale action potentials (APs) of a common frequency are initiated at one site and are conducted within the SAN along smooth isochrones; and (ii) does not feature fine details of Ca 2+ signalling present in isolated SAN cells, in which small subcellular, subthreshold local Ca 2+ releases (LCRs) self-organize to generate cell-wide APs.Objectives To study subcellular Ca 2+ signals within and among cells comprising the SAN tissue. MethodsWe combined immunolabeling with a novel technique to detect the occurrence of LCRs and AP-induced Ca 2+ transients (APCTs) in individual pixels (chonopix) across the entire mouse SAN images. ResultsAt high magnification, Ca 2+ signals appeared markedly heterogeneous in space, amplitude, frequency, and phase among cells comprising an HCN4 + /CX43cell meshwork.The signalling exhibited several distinguishable patterns of LCR/APCT interactions within and among cells. Apparently conducting rhythmic APCTs of the meshwork were transferred to a truly conducting HCN4 -/CX43 + network of straited cells via narrow functional interfaces where different cell types intertwine, i.e. the SAN anatomical/functional unit. At low magnification, the earliest APCT of each cycle occurred within a small area of the HCN4 meshwork and subsequent APCT appearance throughout SAN pixels was discontinuous. ConclusionsWe have discovered a novel, microscopic Ca 2+ signalling paradigm of SAN operation that has escaped detection using low-resolution, macroscopic tissue isochrones employed in prior studies: APs emerge from heterogeneous subcellular subthreshold Ca 2+ 105 and is also made available for use under a CC0 license.
Age-associated changes in gene expression in skeletal muscle of healthy individuals reflect accumulation of damage and compensatory adaptations to preserve tissue integrity. To characterize these changes, RNA was extracted and sequenced from muscle biopsies collected from 53 healthy individuals (22–83 years old) of the GESTALT study of the National Institute on Aging–NIH. Expression levels of 57,205 protein-coding and non-coding RNAs were studied as a function of aging by linear and negative binomial regression models. From both models, 1134 RNAs changed significantly with age. The most differentially abundant mRNAs encoded proteins implicated in several age-related processes, including cellular senescence, insulin signaling, and myogenesis. Specific mRNA isoforms that changed significantly with age in skeletal muscle were enriched for proteins involved in oxidative phosphorylation and adipogenesis. Our study establishes a detailed framework of the global transcriptome and mRNA isoforms that govern muscle damage and homeostasis with age.
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