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e., an increase in contractile function with increasing heart rate) by increasing heart rate (from 240 to 420 beats per minute) and sympathetic stimulation (dobutamine). Our data exhibited a clear loss of diastolic and systolic reserve in the AA mice with increasing heart rate and dobutamine. Since we observed a clear inability to increase systolic and diastolic function in AA mice, we performed speckle tracking echocardiography to quantitatively characterize function at resting heart rate. learn more We observed that AA mice demonstrated normal systolic function (radial strain rate) and impaired directional diastolic function (reverse radial strain rate) at resting heart rate. We conclude that TnI S23/S24 phosphorylation is essential for cardiac reserve by enhancing systolic and diastolic function. A blunted cardiac reserve leads to heart disease making TnI S23/S24 phosphorylation a potential therapeutic strategy.Septins are considered as the fourth component of the cytoskeleton, with septin-7 isoform playing a critical role in myogenic cell division and fusion. Skeletal muscle regeneration is a highly orchestrated process that requires many steps, including proper cell division to achieve functional recovery. Here, the role of septin-7 was investigated in this complex process. link2 To this end, muscle injury was induced in wild type BL6/C57 and septin-7-conditional (mer-Cre-mer) knock-down mice by in vivo BaCl2 injection to the left m. tibialis anterior muscle (TA) of the mice (the right m. tibialis anterior muscle was nontreated control). Mice were sacrificed 4 and 14 d later to reflect the early (monitored by PAX7 level) and late (monitored by myogenin level) phases of muscle regeneration. Western blotting was used to follow the changes of septin-7, PAX7, and myogenin expression at the protein level, while changes of mRNA were detected by qPCR. Morphological differences were visualized by HE staining. Levels of septin-7 protein increased 4 and 14 d after injury in BL6/C57 mice and mRNA expression of SEPT7 showed significant elevation both 4 and 14 d after injection in Cre+ mice only, considered to be a compensatory increase of mRNA expression of SEPT7 in order to ensure the appropriate regeneration process. Furthermore, up-regulation of septin-7 protein was more pronounced on day 14 in both Cre- and Cre+ mice, which may indicate its importance in the later phase of regeneration. Level of PAX7 and myogenin were also increased 4 and 14 d after injury in BL6/C57, Cre-, and Cre+ mice, respectively. Taken together, our data suggest the importance of septin-7 in skeletal muscle regeneration.The mechanisms that link the primary increase in SR Ca2+ leak of MH susceptibility and related conditions to their disease phenotypes are not well understood. We found that abnormal Ca2+ homeostasis in MHS individuals induces proteolysis of junctophilin1 (JPh1), an essential structural protein of EC coupling (Perni, in 2017). Guo (in 2018) and Lahiri (in 2020) reported similar fragmentation of JPh2 in stressed hearts. Western blot of patients' muscle with domain-specific antibodies showed a deficit of full-length JPh1 and excess of a 44-kD C-terminal fragment (JPh44) in MHS subjects. While JPh1 was located in T-SR junctions, JPh44 was found anywhere within the I band, and at high densities within nuclei-a location forbidden for JPh1. Expression and cleavage in mice of a JPh1 plasmid tagged at both ends showed that its N-terminal fragment remained in triads, and the C-terminal fragment, orthologue to JPh44, entered nuclei, which indicates that JPh44 is the C-terminal cleavage product. Endogenous calpain1 appeared in T-SR junctions, colocalized with JPh1. On muscle extracts and primary cultures, Ca2+-activated calpain1 cleaved a 44-kD JPh1 piece, consistent with the C-terminal fragment that starts at Ser241, the highest probability cleavage site found by calpain1 algorithms. Completing the identification of Ser241 as the likely start of JPh44, the tagged deletion plasmid GFP-JPh1_Δ1-240, expressed in mice, copied the location and migration of JPh44. Expression of GFP-JPh1_Δ1-240 in C2C12 myoblasts reduced by more than twofold the transcription of PI3K-Akt genes that inhibit muscle uptake and storage of glucose, including GSK3β, an inhibitor of glycogen synthase that is activated in MHS patients. In agreement with the genetic profile, GSK3β protein content decreased upon expression of GFP-JPh1_Δ1-240. In sum, the identified gene control roles of JPh44 oppose the deleterious effects of chronically elevated cytosolic [Ca2+], including late-onset hyperglycemia and type-2 diabetes (Tammineni, in 2020).Calmodulin (CaM) prevents proarrhythmic late sodium current (INa) by facilitating normal inactivation of sodium channels (NaV). Since dysfunction of NaV1.6 has been implicated in late INa-mediated arrhythmias, we investigated its role in arrhythmias promoted by CaM mutant D96V. Super-resolution STED microscopy revealed enlarged NaV1.6 clusters in NaV1.6-expressing Chinese hamster ovary cells transfected with D96V-CaM relative to those transfected with WT-CaM. Therefore, we examined NaV1.6 clustering in transgenic mice with cardiac-specific expression of D96V-CaM (cD96V) with a C-terminal FLAG tag. Confocal microscopy confirmed expression of NaV1.6 and FLAG-tagged D96V-CaM in a striated pattern along with RYR2 in cD96V hearts, consistent with T-tubular localization. In both WT and cD96V hearts, STORM single molecule localization microscopy revealed that ∼50% of NaV1.6 clusters localized less then 100 nm from RYR2. However, NaV1.6 density within these regions was 67% greater in cD96V relative to WT. Consistentodulin, offering novel mechanistic insight into calmodulinopathy.Early afterdepolarization (EAD) is an aberrant cardiac afterpotential that underlies the development of life-threatening ventricular arrhythmias. It is believed that the development of EAD is caused by the reactivation of L-type Ca2+ current during the period of the action potential plateau; however, the cellular mechanisms that underlie the development of EAD is still controversial. One favorable alternative is the depolarizing reverse-mode operation of the Na+/Ca2+ exchanger, which is activated by aberrant Ca2+ release from the sarcoplasmic reticulum in the process of reverse E-C coupling. Since EADs develop preferentially in damaged heart cells with abnormal Ca2+-signaling, here I studied the causal link between the development of EADs and aberrant intracellular Ca2+ level ([Ca2+]i) dynamics in mouse heart cells using the whole-cell clamp technique. My results show (1) the generation of EADs was preceded by the development of depolarizing membrane potential (Vm) fluctuation, (2) the depolarizing Vm fluctuation is associated with [Ca2+]i elevation, suggesting an involvement of reverse E-C coupling via the Na+/Ca2+ exchanger, and (3) that extending the T-tubules' length constant by decreasing the extracellular K+ level facilitated the development of the Vm fluctuation and EADs. Taken together, I conclude that EADs are caused by the depolarizing Vm fluctuation, which is induced locally in the T-tubule membrane by aberrant [Ca2+]i elevation and is conducted back electrotonically along the T-tubules.Ryanodine receptor type-1 (RYR1) and Calsequestrin-1 (CASQ1) proteins, located in the sarcoplasmic reticulum (SR), are two of the main players in skeletal excitation-contraction (EC) coupling. Mutations in the human RYR1 gene (encoding for the SR Ca2+ release channel) and ablation in mice of CASQ1 (a SR Ca2+ binding protein) cause hypersensitivity to halogenated anesthetics (malignant hyperthermia [MH] susceptibility) and to heat (heat stroke; HS). As both MH and HS are characterized by excessive cytosolic Ca2+ levels and hypermetabolic responses, we studied the metabolism of 4-mo-old mice from two different lines that are MH/HS susceptible knock-in mice carrying a human MH mutation (RYR1YS) and CASQ1-knockout (ko) mice. RYR1YS and, to a lesser degree, CASQ1-null mice show an increased volume of oxygen consumption (VO2) and a lower respiratory quotient (RQ) compared with WT mice (indicative of a metabolism that relies more on lipids). This finding is accompanied by a reduction in total body fat mass in both Y522S and CASQ1-null mice (again, compared with WT). In addition, we found that RYR1YS and CASQ1-null mice have an increased food consumption (+26.04% and +25.58% grams/day, respectively) and higher basal core temperature (+0.57°C and +0.54°C, respectively) compared with WT mice. Finally, Western blots and electron microscopy indicated that, in hyperthermic mice, (1) SERCA (used to remove myoplasmic Ca2+) and UCP3 (responsible for a thermogenic process that dissipates mitochondrial H+ gradient) are overexpressed, and (2) mitochondrial volume and percentage of damaged mitochondria are both increased. In conclusion, the MH/HS phenotype in RYR1YS and CASQ1-null mice is associated with an intrinsically increased basal metabolism.Cancer and cardiovascular diseases are the main causes of death in Uruguay and developed countries. In clinical practice, there is often the need to administrate chemotherapy with cisplatin (CTP) to patients with cardiovascular comorbidities. The aim of this work is to characterize the possible detrimental effects in cardiac function by the acute exposition to CPT using isolated heart and cardiomyocytes from guinea pigs (Cavia porcellus). All the procedures regarding animal experimentation were performed following approved protocols by the university ethics committee. Isolated hearts were placed in a Langendorff system and perfused with Tyrode 1.8 mM Ca2+ as control medium, or with extracellularly added CPT (0-100 µM). Tension was recorded with a gauge force transducer attached to the papillary muscle and electrical responses were measured with Ag-AgCl electrodes placed in surface extremes near the papillary muscle. Cardiomyocytes were isolated by enzymatic methods. Data were obtained by patch clamp and confocal microscopy with Rhodamine and Fluo dyes sensitive to Ca2+ binding. Non-parametric t tests were used for data comparison. The best fit of Hill's equation to dose-response curves was done using nonlinear regression methods. In isolated hearts, CPT showed a biphasic effect over the development of tension, increasing up to 5-10 µM to decrease at higher concentrations. In isolated cardiomyocytes, Ca2+ currents were stimulated and inhibited by CPT in a similar dose. Confocal microscopy showed an increment and a reduction of relative fluorescence of the calcium-sensitive dyes with CPT as well. Our results suggest that CPT may affect cardiac contraction and automatism upon acute exposure of the heart, presumably by blocking L-type (Cav1.2) calcium channels and interference with molecules involved in maintaining the homeostasis of intracellular Ca2+.Congenital myopathies (CM) are a group of early-onset, genetically diverse muscle disorders of variable severity with characteristic muscle biopsy findings. link3 Mutations in RYR1, the gene encoding the RYR1, are the most common genetic cause, responsible for ∼30% of all human CM. They are linked to the pharmacogenetic disorder malignant hyperthermia susceptibility and to various disease phenotypes, including central core disease (which is primarily dominantly inherited), multiminicore disease (which is predominantly recessively inherited), some forms of centronuclear myopathy and congenital fiber-type disproportion (which can be either dominantly or recessively inherited), and King-Denborough syndrome (a CM characterized by skeletal abnormalities, dysmorphic features, and malignant hyperthermia susceptibility). The recessive forms of RYR1-linked CM are more severe, affecting children at birth and, in addition to profound muscle weakness, may also affect facial and extraocular muscles and cause skeletal deformities and feeding difficulties.

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