Calcium Cycling Research Articles

Abstract 4136448: A Novel Cardiomyocyte Targeting Peptide Enhances Calcium Handling

Introduction: Intracellular calcium handling plays a central role in cardiac contractility and relaxation. Genes such as the Ca 2+ -ATPase pump (SERCA2a) and the Dihydropteridine reductase (DHPR) enzyme are especially important in the cycling of intracellular calcium. As prior research has established a link between treatment with our cardiac targeting peptide (CTP: a 12-amino acid, cardiomyocyte-specific cell penetrating peptide) and upregulation of calcium-handling genes such as SERCA2a and DHPR, we hypothesized that treatment with our novel hybrid cardiac targeting peptide (hCTP: positions #3 and 11 replaced with the D-enantiomer form of the amino acids) will improve intracellular calcium handling in human cardiomyocytes (CMCs) by increasing expression of key calcium handling genes instrumental in sequestering calcium in diastole and lowering cytosolic levels. Methods: To test hCTP’s calcium handling abilities, CMCs were plated on day 1 and allowed to settle for 24 hours, after which they received daily treatment with various concentrations of hCTP (1-25µM) for three days. On day 5, cells underwent either intracellular calcium measurements using the FLIPR 6 Calcium assay or were prepared for western blotting. Western blotting was performed to determine the protein concentrations of SERCA2a and DHPR, as compared to a GAPDH control. To test hCTP’s intrinsic calcium handling abilities, various concentrations of hCTP were mixed with a constant amount of elemental calcium dissolved in water. After 20 min at 37 o C, the concentration of free Ca 2+ was measured with an ABL90 Flex Plus radiometer. Results: In CMCs, treatment with hCTP led to a decrease in cytosolic calcium in a dose dependent fashion; concentrations as low as 1µM led to a significant decrease in cytosolic calcium (p< 0.0001 for all groups). Western blots performed on the treated CMCs revealed an increase in expression of both DHPR and SERCA2a, normalized to GAPDH control. Outside of the cellular environment, hCTP did not appear to display inherent calcium sequestring properties, suggesting that improvements in calcium handling are due to upregulation of gene expression. Conclusion: hCTP appears to lower cytosolic calcium and improve calcium handling through upregulation of SERCA2a and DHPR. Our data indicates that hCTP is worth pursuing as a stand-alone, cardio-selective therapy for cardiomyopathies involving calcium mishandling.

HuR-dependent expression of RyR2 contributes to calcium-mediated thermogenesis in brown adipocytes.

Several uncoupling protein 1 (UCP1)-independent thermogenic pathways have been described in thermogenic adipose tissue, including calcium-mediated thermogenesis in beige adipocytes via sarco/endoplasmic reticulum ATPase (SERCA). We have previously shown that adipocyte-specific deletion of the RNA binding protein human antigen R (HuR) results in thermogenic dysfunction independent of UCP1 expression. RNA sequencing revealed the downregulation of several genes involved in calcium ion transport upon HuR deletion. The goal of this work was to define the HuR-dependent mechanisms of calcium driven thermogenesis in brown adipocytes. We generated (BAT)-specific HuR-deletion (BAT-HuR -/- ) mice and show that their body weight, glucose tolerance, brown and white adipose tissue weights, and total lipid droplet size were not significantly different compared to wild-type. Similar to our initial findings in Adipo-HuR -/- mice, mice with BAT-specific HuR deletion are cold intolerant following acute thermal challenge at 4°C, demonstrating specificity of acute HuR-dependent thermogenesis to BAT. We also found decreased expression of ryanodine receptor 2 (RyR2), but no changes in RyR2, SERCA1, SERCA2, or UCP1 expression, in BAT from BAT-HuR -/- mice. Next, we used Fluo-4 calcium indicator dye to show that genetic deletion or pharmacological inhibition of HuR blunts the increase in cytosolic calcium concentration in SVF-derived primary brown adipocytes. Moreover, we saw a similar blunting in β-adrenergic-mediated heat generation, as assessed by ERtherm AC fluorescence, in SVF-derived brown adipocytes following HuR inhibition or deletion. Mechanistically, we show that HuR directly binds and reduces the decay rate of RyR2 mRNA in brown adipocytes, and stabilization of RyR2 via S107 rescues β-adrenergic-mediated cytosolic calcium increase and heat generation in HuR deficient brown adipocytes. In conclusion, our results suggest that HuR-dependent control of RyR2 expression plays a significant role in the thermogenic function of brown adipose tissue through modulation of SR calcium cycling.

New insights into the combined effect of steam and SO2 on CaCO3 decomposition: Experimental study and DFT calculation

Calcium cycling is a second-generation CO2 capture technology characterized by rapid development and high technical maturity. In practical applications, steam and SO2 are commonly present in the calcination reactor due to the oxygen-rich combustion of coal. Previous studies have shown that steam accelerates the decomposition of CaCO3 and shortens the calcination time. However, steam also significantly enhances sulfation in the presence of SO2, and there remains no consensus in the literature regarding the combined effects of steam and SO2 on the decomposition of CaCO3. This study investigates the decomposition characteristics of CaCO3 over time under various reaction atmospheres. The results indicate that while steam accelerates the decomposition of CaCO3, the presence of SO2 almost neutralizes the positive effect of steam. Notably, steam promotes rapid sulfation during the early stages of calcination, which subsequently inhibits the decomposition of CaCO3. Physicochemical characterization reveals that the simultaneous presence of steam and SO2 leads to the rapid formation of CaSO4 on the sorbent surface, with steam-induced pore expansion further enhancing sulfation in the internal pores of the grains. Additionally, this study elucidates the mechanism by which steam accelerates CaCO3 decomposition. It was found that the presence of steam increases the adsorption energy of the CaCO3 (1 0–1 4) surface for SO2 and that H2O molecules facilitate a lower activation energy for the formation of HSO3* compared to SO3*. These findings validate the experimental results and provide a deeper understanding of the combined effects of steam and SO2 during the calcination process from a microscopic perspective.

HDAC5 controls a hypothalamic STAT5b-TH axis, the sympathetic activation of ATP-consuming futile cycles and adult-onset obesity in male mice

With age, metabolic perturbations accumulate to elevate our obesity burden. While age-onset obesity is mostly driven by a sedentary lifestyle and high calorie intake, genetic and epigenetic factors also play a role. Among these, members of the large histone deacetylase (HDAC) family are of particular importance as key metabolic determinants for healthy ageing, or metabolic dysfunction. Here, we aimed to interrogate the role of class 2 family member HDAC5 in controlling systemic metabolism and age-related obesity under non-obesogenic conditions. Starting at 6 months of age, we observed adult-onset obesity in chow-fed male global HDAC5-KO mice, that was accompanied by marked reductions in adrenergic-stimulated ATP-consuming futile cycles, including BAT activity and UCP1 levels, WAT-lipolysis, skeletal muscle, WAT and liver futile creatine and calcium cycles, and ultimately energy expenditure. Female mice did not differ between genotypes. The lower peripheral sympathetic nervous system (SNS) activity in mature male KO mice was linked to higher dopaminergic neuronal activity within the dorsomedial arcuate nucleus (dmARC) and elevated hypothalamic dopamine levels. Mechanistically, we reveal that hypothalamic HDAC5 acts as co-repressor of STAT5b over the control of Tyrosine hydroxylase (TH) gene transactivation, which ultimately orchestrates the activity of dmARH dopaminergic neurons and energy metabolism in male mice under non-obesogenic conditions.

Carbon–sulfur–calcium isotopic variability of lower Cambrian shale-hosted carbonate concretions: Insights into growth mechanisms and calcium cycling

Marine calcium cycling is closely linked with carbon cycling in the ocean, in which authigenic carbonates precipitated in sediments play a non-negligible role. However, calcium cycling during authigenic carbonate precipitation in organic-rich, shaly sediments in geological history remains underexplored. This study focuses on carbonate concretions (aggregates of authigenic carbonates) in the lower Cambrian Niutitang Formation, South China, to provide insights into calcium cycling during their growth. Sedimentological and mineralogical observations suggest that these concretions were formed through concentric growth by authigenic calcite and pyrite precipitation during the early diagenetic stage. Geochemical analyses reveal internal variations in “M-shaped” δ13Ccarb trends (from −11.9 ‰ to −4.4 ‰) and diverse δ34Spyr trends (from 4.7 ‰ to 14.0 ‰) along core-to-rim transects. These findings suggest formation through microbial sulfate reduction by organic matter in a shallow depth beneath the sediment–water interface. In contrast to the dynamic δ13Ccarb and δ34Spyr variations and multi-stage concentric growth, these carbonate concretions display nearly uniform δ44/40Cacarb values (from 0.80 ‰ to 1.03 ‰, average 0.96 ± 0.06 ‰, 1SD) and consistent internal trends, which are further attributed to strongly seawater-buffered porewater calcium geochemistry and small calcium isotope fractionation due to calcite precipitation at slow rates. This study confirms that early diagenetic carbonate concretions in the lower Cambrian Niutitang Formation are characterized by much heavier δ44/40Ca values compared to coeval shallow platform carbonates. In light of abundant authigenic carbonates observed in the lower Cambrian successions, their roles in calcium isotope mass balance in the early Cambrian ocean warrant further investigation in the future. Therefore, early diagenetic carbonate concretions in black shales could provide valuable insights into porewater and seawater calcium isotope signals, as well as early diagenetic and marine calcium cycling in geological history.

Pressurized Regenerative Calcium Cycle for Utility-Scale Energy Storage: A Techno-Economic Assessment

Pressurized Regenerative Calcium Cycle for Utility-Scale Energy Storage: A Techno-Economic Assessment

Mild cold stress at ambient temperature elevates muscle calcium cycling and exercise adaptations in obese female mice.

Housing temperature is a critical regulator of mouse metabolism and thermoneutral housing can improve human translation. However, the impact of housing temperature on the ability of wheel running to rescue the detrimental effect of diet-induced obese mice is currently not fully understood. Lean or obese female mice were housed at standard ambient temperature (22℃) or thermoneutrality (30℃) with/without access to running wheels. The metabolic phenotype was investigated using glucose tolerance tests, indirect calorimetry, and body composition. Molecular muscle adaptations were measured using immunoblotting, qPCR, and spectrophotometric/fluorescent assays. Obese female mice housed at 22°C showed lower adiposity, lower circulating insulin levels, improved glucose tolerance, and elevated basal metabolic rate compared to 30°C housing. Mice exposed to voluntary wheel running exhibited a larger fat loss and higher metabolic rate at 22°C housing compared to thermoneutrality. In obese female mice, glucose tolerance improved after exercise training independent of housing temperature. Independent of diet and training, 22°C housing increased skeletal muscle sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA) activity. Additionally, 22°C-housing elevated the induction of training-responsive muscle proteins in obese mice. Our findings highlight that housing temperature significantly influences adiposity, insulin sensitivity, muscle physiology, and exercise adaptations in diet-induced obese female mice.

Abstract Mo119: PI3Kgamma regulates CamKII mediated phosphorylation of phospholamban and SR calcium cycling

Although phosphoinositide 3-kinase (PI3Kγ) null mice (PI3Kγ -/- ) show increased ventricular rate/contraction, it is unknown whether PI3Kγ regulates calcium recycling machinery underlying this phenotype. Primary adult cardiomyocytes from PI3Kγ -/- mice show altered sarcoendoplasmic reticulum (SR) calcium cycling following caffeine. Unexpectedly, PI3Kγ -/- cardiomyocytes showed significant reduction in phosphorylation of phospholamban (PLN) at Thr17, a key regulator of SR calcium re-uptake without changes in phosphorylation at Ser16. Furthermore, loss in PLN phosphorylation in PI3Kγ -/- cardiomyocytes was associated with augmented interaction with SR calcium ATPase (SERCA). Surprisingly, cardiomyocyte-specific overexpression of kinase-dead PI3Kγ (PI3Kγ inact ) in global PI3Kγ -/- mice (PI3Kγ inact /PI3Kγ -/- ) normalized caffeine-induced calcium re-uptake, PLN phosphorylation at Thr17 and decreased PLN-SERCA interaction. These data suggested kinase-independent function of PI3Kγ in regulation of SR calcium load and PLN phosphorylation. Since phosphorylation of Thr17 of PLN is carried out by Ca 2+ /Calmodulin dependent protein kinase (CamKII), we probed for the role of PI3Kγ in regulation of CamKII in PLN phosphorylation. Mechanistically, PI3Kγ exhibits scaffolding function in recruitment of CamKII to PLN at SR to mediate PLN phosphorylation. Furthermore, we showed that PI3Kγ directly interacts with CamKII. The study unravels a yet to be recognized kinase-independent role of PI3Kγ in regulating PLN with implications in cardiac function.

Abstract We143: MED12 Dysregulation Disrupts Transcriptional Programs Leading to Dilated Cardiomyopathy

The Mediator complex serves as a bridge to link transcriptional machinery and transcription factors (TFs) to control transcription, but detailed molecular mechanisms of transcriptional regulation by Mediator are not well-understood. Mediator is comprised of the head, middle, and tail submodules that make up the core Mediator, and the transiently associating kinase submodule. The CDK8 kinase submodule acts to regulate Mediator-RNA Polymerase II interaction. MED12 is an essential Mediator component within the kinase submodule and is required for CDK8 kinase activity. In aging models, dysregulated levels of Med12 mRNA are detected in both atria and ventricles by qRT-PCR. MED12 protein levels are also increased in human heart failure biopsies and in the mouse heart after transverse aortic constriction (TAC)-induced heart failure[KB1] . To test the hypothesis that increased levels of MED12 contribute to development of heart failure we generated cardiac-specific Med12 transgenic mice (cTg) by driving increased MED12 expression in cardiomyocytes using the αMHC promoter. Med12 overexpression leads to a progressive decrease in fractional shortening by serial echocardiography. Decreased cardiac function was accompanied by increased cardiac chamber size and dilation, without cardiac fibrosis. RNA sequencing of cardiomyocytes from cTg and control mice revealed that increased levels of MED12 leads to early changes in gene expression programs. Using ingenuity pathway analysis we identified MED12-regulated gene programs including those involved in calcium cycling. MED12 is a transcriptional regulator but does not directly bind DNA. To determine how MED12 regulates gene expression we screened for TFs that interact with MED12. We performed immunoprecipitation of MED12 and by mass spectrometry and determined that MED12 interacts with the TFs MEF2, CREB, and SRF. In follow-up experiments we demonstrated that MED12 interacts with the transcription factor (TF) MEF2 to regulate calcium handling genes. Current studies are focused on determining how MED12 binding coordinates gene expression through multiple TFs in cardiomyocytes. Collectively, our data demonstrate that increased MED12 expression leads to the development of heart failure, in part by dysregulation of gene expression. Therefore, precise regulation of MED12 levels is important to maintain normal cardiac function. [KB1]What about aging?

Abstract Mo096: High-Throughput Functional Determination of TNNI3 Variant Pathogenicity

Introduction: Mutations in the thin filament protein TNNI3 (cardiac troponin I) can perturb calcium cycling and cause hypertrophic, restrictive, and dilated cardiomyopathies. However, the majority of TNNI3 variants observed in patients have unknown functional significance and uncertain contribution to disease. Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) are a powerful system for studying the effect of genetic variants on human cardiomyocyte function. TNNI3 has been challenging to study in these cells as they predominantly express TNNI1. In this study, we combined a novel scalable in vitro gene replacement method with simultaneous measurement of contractility and calcium cycling to determine the functional effect of TNNI3 variants. Hypothesis: Using our gene replacement platform, we expect that TNNI3 variants causing Hypertrophic Cardiomyopathy (HCM) will increase force generation and calcium sensitivity relative to wild-type, whereas TNNI3 variants causing Dilated Cardiomyopathy (DCM) will decrease force generation and calcium sensitivity relative to wild-type. Methods: We generated double knockout TNNI1 -/- TNNI3 -/- hiPSCs. Cardiomyocytes differentiated from these hiPSCs were transduced with lentivirus carrying either wild-type or mutant TNNI3 during replating onto polyacrylamide gels with fluorescent beads. After a week of incubation, the cells were stained with a fluorescent calcium probe, and contractility, diastolic tension, and calcium sensitivity were measured by our high-throughput physiologic imaging and analysis platform. Results: hiPSC-CMs expressing the HCM-associated variant R192H show increased peak force, diastolic tension, and calcium sensitivity relative to wild-type TNNI3, whereas hiPSC-CMs expressing the DCM-associated variant K36Q show decreased peak force and calcium sensitivity relative to wild-type TNNI3. Conclusion: We validated our TNNI3 in vitro gene replacement and high-throughput physiologic imaging and analysis platform by comparing reference HCM and DCM variants to wild-type TNNI3. Ongoing scaled studies will evaluate the naturally occurring variants in ClinVar to characterize their functional effect on cardiac physiology.

Gene transfer of human cardiomyopathy β-MyHC mutant R403Q directly alters intact cardiac myocyte calcium homeostasis and causes hyper-contractility.

The R403Q mutation of human cardiac β-myosin heavy chain was the first missense mutation of a sarcomeric protein identified as being causal for hypertrophic cardiomyopathy (HCM), in humans. The direct effect of the R403Q mutant myosin on intracellular calcium homeostasis and contractility is not fully known. Here we have used in vitro gene transfer of the R403Q mutant human β-myosin to study its direct effects on single intact adult cardiac myocyte contractility and calcium homeostasis. In the first experiments, adult cardiac myocytes transduced with the R403Q mutant myosin recombinant viral vectors were compared to myocytes transduced with wild-type human β-myosin (wtMYH7). Efficiency of gene transfer was high in both groups (>98%) and the degree of stoichiometric myofilament incorporation of either the mutant or normal myosin was comparable at ∼40% in quiescent myocytes in primary culture. Sarcomere structure and cellular morphology were unaffected by R403Q myosin expression and myofilament incorporation. Functionally, in electrically paced cardiac myocytes, the R403Q mutant myosin caused a significant increase in intracellular calcium concentration and myocyte hyper-contractility. At the sub-cellular myofilament level, the mutant myosin increased the calcium sensitivity of steady state isometric tension development and increased isometric cross-bridge cycling kinetics. R403Q myocytes became arrhythmic after β-adrenergic stimulation with spontaneous calcium transients and contractions in between electrical stimuli. These results indicate that human R403Q mutant myosin directly alters myofilament function and intracellular calcium cycling. Elevated calcium levels may provide a trigger for the ensuing hypertrophy and susceptibility to arrhythmia that are characteristic of HCM.

Thermodynamic evaluation of decarbonized power production based on solar energy integration

This study aims to create an environmentally friendly system by utilizing solar and biomass energies as renewable sources, employing high temperature and pressure ranges for analysis. A new energy system is introduced, using biomass to produce hydrogen and other valuable commodities. The study evaluates power and hydrogen production technologies from a thermodynamic perspective, including conventional biomass gasification, calcium and iron thermochemical looping cycles, and gasification with supercritical water, incorporating carbon capture techniques. It assesses and compares the performance of locally available biomass material, such as cotton stalk, during gasification. Results show that employing the supercritical water gasification cycle yields the highest hydrogen production (8330 kg/h) and carbon capture rate (92.91 %), with potential for significant reduction in CO2 emissions. Supercritical water gasification also demonstrates electricity, heating, and CO2 production rates of 51.48 MW, 23.3 MW, and 16.6 MW, respectively. Integrating supercritical water gasification with solar energy enhances syngas productivity and system efficiency. Additionally, the highest performance is demonstrated in the SCWG case, which exhibits the lowest irreversibility at 320.32 MW. In conclusion, the system with supercritical water gasification emerges as the most efficient biomass conversion method, with higher energy and exergy efficiencies of 67.59 % and 49.74 %, respectively, under specific operating conditions. The developed model facilitates integration of solar energy into biomass gasification, enabling prediction and comparison of performance in terms of energy and exergy efficiencies.

Barley polysaccharides inhibit colorectal cancer by two relatively independent pathways

Colorectal cancer is one of the most common types of cancer worldwide that can lead to serious injury and death. Although polysaccharides are widely recognized as having antitumor activity, there has been little research on the role of barley polysaccharides (BP)11BP: barley polysaccharides. in colorectal cancer. The results of our research suggest that BP (300 mg/kg) had a significant inhibitory effect on colorectal cancer, and this effect was achieved through two pathways. First, BP can directly promote the secretion of protective metabolites like 5-(4-Hydroxyphenyl)-5-phenylimidazolidine-2,4-dione and 2,3-Bis(4-hydroxyphenyl)propionitrile thereby inhibiting the cancer pathways such as ERK, PI3K, WNT, JAK-STAT, Calcium, and Cell cycle cancer pathways to alleviate inflammation. Second, BP also can enrich beneficial intestinal bacteria such as Colidextribacter, Bilophila, and UCG-003 improve the intestinal barrier, promote the production of beneficial metabolites such as 5,8-Epoxy-5,8-dihydro-3-hydroxy-8′-apo-b,y-carotenal and L-Glutamic acid, and thus inhibit cancer pathways such as ERK, PI3K, Nuclear receptor, Cell cycle, Apoptosis and TGF-β. In conclusion, our findings suggest for the first time that BP can alleviate colorectal cancer by two relatively independent pathways: direct action and indirect action via the gut microbiota on both colon tumor cells and microbiota.

Hyperthermia Treatment Attenuates Diet-Induced Obesity and Insulin Resistance in Old Female and Ovariectomized Mice via TRPV1-Mediated Futile Calcium Cycling

Hyperthermia Treatment Attenuates Diet-Induced Obesity and Insulin Resistance in Old Female and Ovariectomized Mice via TRPV1-Mediated Futile Calcium Cycling

Glucagon-like peptide-1 increases heart rate by a direct action on the sinus node.

Glucagon-like peptide-1 receptor agonists (GLP-1 RAs) are increasingly used to treat type 2 diabetes and obesity. Albeit cardiovascular outcomes generally improve, treatment with GLP-1 RAs is associated with increased heart rate, the mechanism of which is unclear. We employed a large animal model, the female landrace pig, and used multiple in vivo and ex vivo approaches including pharmacological challenges, electrophysiology, and high-resolution mass spectrometry to explore how GLP-1 elicits an increase in heart rate. In anaesthetized pigs, neither cervical vagotomy, adrenergic blockers (alpha, beta, or combined alpha-beta blockade), ganglionic blockade (hexamethonium), nor inhibition of hyperpolarization-activated cyclic nucleotide-gated (HCN) channels (ivabradine) abolished the marked chronotropic effect of GLP-1. GLP-1 administration to isolated perfused pig hearts also increased heart rate, which was abolished by GLP-1 receptor blockade. Electrophysiological characterization of GLP-1 effects in vivo and in isolated perfused hearts localized electrical modulation to the atria and conduction system. In isolated sinus nodes, GLP-1 administration shortened the action potential cycle length of pacemaker cells and shifted the site of earliest activation. The effect was independent of HCN blockade. Collectively, these data support a direct effect of GLP-1 on GLP-1 receptors within the heart. Consistently, single nucleus RNA sequencing showed GLP-1 receptor expression in porcine pacemaker cells. Quantitative phosphoproteomics analyses of sinus node samples revealed that GLP-1 administration leads to phosphorylation changes of calcium cycling proteins of the sarcoplasmic reticulum, known to regulate heart rate. GLP-1 has direct chronotropic effects on the heart mediated by GLP-1 receptors in pacemaker cells of the sinus node, inducing changes in action potential morphology and the leading pacemaker site through a calcium signalling response characterized by PKA-dependent phosphorylation of Ca2+ cycling proteins involved in pacemaking. Targeting the pacemaker calcium clock may be a strategy to lower heart rate in people treated with GLP-1 RAs.

Leaky RyR2 channels as pro-arrhythmic trigger in the PKP2-deficient atrial myocardium

Abstract Funding Acknowledgements Type of funding sources: Public Institution(s). Main funding source(s): American Heart Association National Institutes of Health Introduction Atrial arrhythmias, like atrial fibrillation, occur in 20–40% of patients with Arrhythmogenic Right Ventricular Cardiomyopathy (ARVC). Atrial fibrillation in ARVC patients is often associated with an increased risk of sustained ventricular arrhythmias and inappropriate ICD shocks. However, the pathophysiology behind the development of atrial arrhythmias in ARVC is far from clear. A genome-wide association study, based on UK-biobank data, revealed a link between atrial fibrillation and variants in the desmosomal gene plakophilin-2 (PKP2). Previous studies show that PKP2 is necessary to maintain the transcription of genes that control intracellular calcium (Ca2+) cycling and that loss of PKP2 expression in adult mouse ventricular tissue leads to disruption of intracellular Ca2+ homeostasis. In this study, we test the hypothesis that loss of PKP2 expression leads to pro-arrhythmic changes in atrial myocytes. Methods Experiments were carried out using a cardiac-specific, tamoxifen (TAM)-activated PKP2 knockout murine model (PKP2-cKO). Cre-negative, flox-positive, TAM-injected littermates were used as controls. We used RNA sequencing, quantitative imaging modalities, as well as biochemical and electrophysiological methods to study the functional and structural properties of atrial PKP2cKO tissue. Studies were carried out 21 days post-tamoxifen injection, a time point at which an arrhythmogenic cardiomyopathy of right ventricular predominance is manifest. Results In contrast to the previously-reported observations in PKP2cKO ventricular myocytes, atrial PKP2cKO myocytes presented no significant differences in Ca2+ transient dynamics, SR load and action potential duration. However, PKP2cKO atrial myocytes showed an increased frequency and amplitude of Ca2+ sparks, in combination with increased diastolic Ca2+ levels as well as an increase in cellular ROS levels. RNAseq data showed an under-representation of mRNA for Integrinα7, a stabilizer of Ryr2 that reduces its phosphorylation. Separate studies showed that PKP2cKO atrial myocytes present impaired relaxation and enhanced sarcomere shortening, a finding consistent with a downregulation in the expression of Myosin Binding Protein C. Isoproterenol (ISO) exposure further increased the frequency of Ca2+ sparks and the levels of diastolic Ca2+, and these effects were reversed by acute (30 minute) in vivo treatment with Ryanodex (medical grade Dantrolene), a known RyR blocker. Conclusion Loss of PKP2 expression affects cellular Ca2+ handling and electrophysiology differently in the atrial versus ventricular myocardium. We speculate that an increased probability of opening of Ryr2 channels, caused by ROS-induced RyR2 oxidation and/or Integrinα7-induced RyR2 phosphorylation, serve as pro-arrhythmic trigger in the PKP2-deficient atrial myocardium, that these effects can be amplified by a catecholaminergic input and that RyR blockers can dampen these pro-arrhythmic effects.

Relative sarcolipin (SLN) and sarcoplasmic reticulum Ca2+ ATPase (SERCA1) transcripts levels in closely related endothermic and ectothermic scombrid fishes: Implications for molecular basis of futile calcium cycle non-shivering thermogenesis (NST)

Regional endothermy is the ability of an animal to elevate the temperature of specific regions of the body above that of the surrounding environment and has evolved independently among several fish lineages. Sarcolipin (SLN) is a small transmembrane protein that uncouples the sarcoplasmic reticulum calcium ATPase pump (SERCA1b) resulting in futile Ca2+ cycling and is thought to play a role in non-shivering thermogenesis (NST) in cold-challenged mammals and possibly some fishes. This study investigated the relative expression of sln and serca1 transcripts in three regionally-endothermic fishes (the skipjack, Katsuwonus pelamis, and yellowfin tuna, Thunnus albacares, both of which elevate the temperatures of their slow-twitch red skeletal muscle (RM) and extraocular muscles (EM), as well as the cranial endothermic swordfish, Xiphias gladius), and closely related ectothermic scombrids (the Eastern Pacific bonito, Sarda chiliensis, and Pacific chub mackerel, Scomber japonicus). Using Reverse Transcription quantitative PCR (RT-qPCR) and species-specific primers, relative sln expression trended higher in both the RM and EM for all four scombrid species compared to white muscle. In addition, relative serca1 expression was found to be higher in RM of skipjack and yellowfin tuna in comparison to white muscle. However, neither sln nor serca1 transcripts were higher in swordfish RM, EM or cranial heater tissue in comparison to white muscle. A key phosphorylation site in sarcolipin, threonine 5, is conserved in the swordfish, but is mutated to alanine or valine in tunas and the endothermic smalleye Pacific opah, Lampris incognitus, which should result in increased uncoupling of the SERCA pump. Our results support the role of potential SLN-NST in endothermic tunas and the lack thereof for swordfish.

Experimental Study on Ecological and Biogeochemical Role of Calcimycocavites in Understanding Carbon Fluxes in the Age of Global Warming and Climate Change

The present work reports the results of calcimycocavitological studies on the seashells from beaches of north Goa, India yielding distinct microfungal forms known as calcimycocavites which are important in global climate change studies. SEM studies of the calcareous shell fragments revealed the micro tunneling behavior of the fungi. Digital analysis of SEM images using Mountain Premium 7.2 software revealed the fine topography of calcimycocavites hyphae along with unidentified presumptive biomineral encrustations. The biodegradation of mycocavitogenic insoluble Calcium Oxalate by oxalotrophic members of bacterial communities may occur using bacterial Oxalate decarboxylase and formate dehydrogenase finally releasing Carbon Di Oxide and water and Calcium oxide to the local nutrient pool. Calcimycocavites may be thus involved in the biogeochemical cycling of Carbon and Calcium in the Ocean-Beach environment. The ecological, biological, and biogeochemical implications of the findings are presented concerning the possible role of calcimycocavites in Calcium and Carbon cycling by breakdown of the calcareous shells and release of inorganic and organic components in the ecosystem. The role of calcimycocavites is stressed in global climate studies.

B1AR regulation of the Cav1.2 via the SAP97 complex

Beta adrenergic (BAR) signaling is stimulated by the catecholamines norepinephrine (NE) and epinephrine (EPI) to control cardiac contractility. The beta-1-AR (B1AR) is the major cardiac subtype. B1AR signals canonically through the Gas subunit, leading to increases in cAMP and PKA; however, it can also signal via the Gai subunit, leading to increased NOS1, cGMP, and PKG levels. B1AR-NOS1 signaling leads to increased contractility and calcium cycling in cardiomyocytes. We found a novel complex within cardiomyocytes in which the B1AR, Cav1.2, and NOS1 proteins are held in proximity by the membrane scaffolding protein SAP97. In heart failure, there is a decrease in SAP97 expression and impaired B1AR signaling. Cardiac-specific deletion of SAP97 disrupts this complex. In the SAP97-cKO mice, there are minimal changes in B1AR-Gas; however, B1AR-Gai signaling is decreased, with a loss of B1AR-NOS1 signaling. Furthermore, we see a decrease in whole cell calcium currents and cardiac contractility. In mice lacking the NOS1, we see the same decrease in calcium currents. We hypothesize SAP97 is necessary to maintain B1AR modulation of Cav1.2 in cardiomyocytes. Using electrophysiology and biochemical techniques, we aim to elucidate the role of SAP97 in B1AR modulation of Cav1.2 and how this is impacted by the impairment of B1AR-Gai signaling. T32HL086350 RO1-HL147263. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Cardiac Complications and COVID-19: A Review of Life-threatening Co-morbidities.

The novel 2019 coronavirus disease (COVID-19) was first reported in the last days of December 2019 in Wuhan, China. The presence of certain co-morbidities, including cardiovascular diseases (CVDs), are the basis for worse outcomes in patients with COVID-19. Relevant English-language literature was searched and retrieved from the Google Scholar search engine and PubMed database up to 2023 using COVID-19, SARS-CoV-2, Heart failure, Myocardial infarction, and Arrhythmia and Cardiac complication as keywords. Increased hemodynamic load, ischemia-related dysfunction, ventricular remodeling, excessive neurohumoral stimulation, abnormal myocyte calcium cycling, and excessive or insufficient extracellular matrix proliferation are associated with heart failure (HF) in COVID-19 patients. Inflammatory reaction due to the excessive release of inflammatory cytokines, leads to myocardial infarction (MI) in these patients. The virus can induce heart arrhythmia through cardiac complications, hypoxia, decreased heart hemodynamics, and remarkable inflammatory markers. Moreover, studies have linked cardiac complications in COVID-19 with poor outcomes, extended hospitalization time, and increased mortality rate. Patients with COVID-19 and CVDs are at higher mortality risk and they should be given high priority when receiving the treatment and intensive care during hospitalization.