Basal Respiration Research Articles

A Mitochondrial Targeted Ubiquinol (MitoQ) Improves Immune Cell Bioenergetics in Patients with Heart Failure with Preserved Ejection Fraction

BACKGROUND: Heart failure with preserved ejection fraction (HFpEF) is a proinflammatory syndrome. Mitochondrial dysfunction that is characteristic of HFpEF could alter immunometabolism, attenuating the functional reserve of immune cells. In addition, immune cell mitochondrial respiration is a biomarker of systemic mitochondrial health. The aim of this study was to assess the impact of a chronic oral mitochondrial targeted ubiquinol (MitoQ) on the immune cell bioenergetic profile in patients with HFpEF. We hypothesized that MitoQ administration in patients with HFpEF, would improve mitochondrial respiration in peripheral blood mononuclear cells (PBMC’s). METHODS: In this double-blind, crossover trial 8 patients with a clinical diagnosis of HFpEF (6 female, 2 male; 6 African American/Black, 2 white; mean ± SEM, Age, 58±5 years; BMI, 37±1 kg/m2) received a 4 week oral dose of MitoQ (MTQ, 20 mg/day) and placebo (PLB) in random order separated by a 2 week wash out period. Following completion of each trial arm, a venous blood sample was obtained and PBMCs were isolated using density gradient centrifugation. High resolution respirometry coupled with modulators of cellular respiration was performed to obtain basal respiration, ATP-linked respiration, maximal respiration, and spare respiratory capacity of the immune cells. Paired samples t-tests were used to compare variables between conditions. RESULTS: MitoQ was safe, well tolerated, and compliance was high (MTQ, 99 ± 1%; PLB, 89±4%). Basal respiration (MTQ, 106.4 ± 11.5 pmol/min; PLB, 66.5±5.9 pmol/min; p=0.002), ATP-linked respiration (MTQ, 41.4± 16.9 pmol/min; PLB, 16.3±6.7 pmol/min; p=0.04), maximal respiration (MTQ, 323.9 ± 50.0 pmol/min; PLB, 65.4±23.1 pmol/min; p=0.01), spare respiratory capacity (MTQ, 217.5 ± 39.6 pmol/min; PLB, 149.6 ±18.2 pmol/min; p=0.02), were higher following MTQ compared to PLB. CONCLUSIONS: In patients with HFpEF, administration of a mitochondrial targeted ubiquinol improved the immune cell mitochondrial respiration capacity and effciency. An increase in spare respiratory capacity following MTQ reflects an improvement in functional reserve that would augment the ability to respond to an acute stressor. These findings have positive implications for the ability to target and improve mitochondrial function in patients with HFpEF. Future work should investigate if the observed improvements in immune cell mitochondrial function are mirrored in other tissues. Supported by AHA 19CDA3474002. 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.

Interactive effects of climate warming and management on grassland soil respiration partitioning

AbstractGrassland ecosystems are important for the provision of food, fuel and fibre. They represent globally important carbon (C) reservoirs that are under pressure from intensive management and ongoing climate change. How these drivers of change will interact to affect grassland soil C and nitrogen (N) cycling and heterotrophic and autotrophic respiration remains uncertain. Roots and mycelia in grassland soil are important regulators of ecosystem functioning and likely to be an influential determinant of CO2 fluxes responses to global change. The aim of this study was to investigate the interactive effect of climate warming and grassland management on soil respiration originating from roots rhizosphere, mycelia and free‐living microbes. The experiment used a block design to measure the interactive effects of warming, nitrogen addition, aboveground biomass (AGB) removal on belowground respiration in a temperate grassland ecosystem. An in‐growth core method using cores with different mesh sizes was used to partition belowground respiration due to its simplicity of design and efficacy. We found that basal respiration (free‐living microorganisms) was the highest (58.5% of the total emissions), followed by that from roots (22.8%) and mycelia (18.7%) across all treatments. Warming reduced basal respiration whilst AGB removal increased it. An antagonistic interaction between warming and nitrogen addition reduced root respiration, and a three‐way interaction between warming, nitrogen addition and AGB removal affected mycelial respiration. The results show different contributions of belowground biota to soil respiration, and how interactions between climate change and grassland management may influence effects on soil respiration.

High Salt Induced Alterations in Substrate Metabolism, Respiratory Activity, and Acidification in Isolated Proximal Tubules from Dahl Salt-Sensitive Rats

Rationale: The renal nephron actively reabsorbs nearly 99% of Na+ from the glomerular filtrate to maintain fluid and solute homeostasis, roughly 70% of which occurs in the proximal tubules (PT), where mitochondria consume a great amount of O2 for ATP production to meet the energy demand. However, the effect of a high salt diet upon the PT substrate metabolism and respiratory activity towards energy production and associated cellular acidification is not well-known. Method: To determine alterations in the PT substrate metabolism, respiratory activity, and acidification with a high salt diet, the PT of adult Dahl salt-sensitive (SS) rats were isolated by collagenase digestion and sieving with the rats fed either a 0.4% (LS) or a 4.0% (HS) NaCl diet for 7, 14 and 21 days (age-matched). Responses of the PT O2 consumption rate (OCR) and extracellular acidification rate (ECAR) were determined using a high-throughput Agilent Seahorse XF96 Extracellular Flux Analyzer and a modified mitochondrial stress test protocol, which combined a substrate addition step to the mitochondrial stress reagent addition steps. Basal OCR and ECAR were assessed with only amino acids (basic Seahorse medium) used as fuel for respiration. Subsequently, OCR and ECAR responses were determined by adding different circulating substrates followed by perturbations to the electron transport chain (ETC) in sequential order with oligomycin to inhibit ATP synthase, FCCP to uncouple oxidative phosphorylation, and rotenone + antimycin A to inhibit complexes I and III of the ETC. From these measurements, different OCR and ECAR parameters were derived for each substrate and each salt load condition. Results: The OCR data show that the PT of SS rats preferred to use lactate, glutamine, and palmitate for ATP production under the LS diet. However, the HS diet resulted in significantly reduced OCR when supplied with the same substrates. Interestingly, the basal OCR which occurred with amino acids as metabolic substrates was increased in the PT obtained from HS fed SS rats starting on day 7. These alterations in substrate metabolism were also apparent from the same parametric analysis of the ECAR data. An increased mitochondrial proton leak induced respiration was also deduced form both OCR and ECAR data under the HS diet. Since it is known that uncoupling proteins (UCP) and ADP/ATP translocase (ANT) enhance proton leak, gene expression was quantified from the isolated PT segments. Increased Ucp2 gene expression was found in response to the HS diet (days 7, 14, 21) compared to the LS fed SS rats but no changes were observed in the expression of Slc25A4 (ANT1) or Slc25A5 (ANT2). Summary: HS diet resulted in significant metabolic changes in the PT segments, including substrate metabolism, respiratory activity, and cellular acidification. HS diet also increased PT basal respiration and proton leak, which was associated with an increase of Ucp2 gene expression. Considering the increased ATP demand in the PT segments with a HS diet, these changes would result in increased O2 consumption and increased reactive oxygen species production. Together with the physiological changes on renal hemodynamics that we have observed, we propose that the observed metabolomic changes on the PT upon HS diet contribute to the onset of associated regional ischemia, tissue inflammation, and renal injury observed in hypertensive SS rats. NIH R01-HL151587. 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.

Carbon and nutrient cycling responses to repeated application of biochar and NPK fertilizers depend on microenvironmental differences among hierarchical aggregate fractions

The conversion of bambara groundnut seed residues into biochar facilitated the bioavailability and retention of more nutrients (C, N, P, K and Mg) after repeated application of biochar. However, the mechanisms of microbially mediated biochar-C degradation and nutrient cycling responses to repeated biochar application, particularly in different hierarchical soil aggregates, are largely unknown. A 20-day incubation experiment was conducted on Ultisols from a 4-year cucumber field trial in Nsukka, Nigeria. The effects of repeated application of bambara seed residue biochar with or without NPK fertilizer on soil aggregate associated electrical conductivity (EC), basal respiration, microbial biomass, and soil enzyme activities were determined. The results showed that the concentration of organic matter in the bulk soils increased with biochar and NPK+biochar treatments. These treatments also increased the soil EC, cumulative CO2 respiration, microbial biomass C and N concentrations, and the activities of tyrosine-aminopeptidase and sulfatase enzymes, compared to the biochar treatment and the control soil. The NPK+biochar treatment contributed 35 % more to β-cellobiosidase activity, but the biochar treatment resulted in 85 % reduction in N-Acetyl-β-glucosaminidase activity, indicating microbial N mining. The NPK and NPK+biochar treatments accounted for a higher percentage of N-, C and N-, and S- cycle enzyme activities, although their composition was relatively higher with the latter treatment. The overall soil biochemical responses were significantly higher in the micro-aggregates (< 0.25 mm) than in the macro-aggregates (≤ 4.75–0.25 mm); least of all in the small macro-aggregates (0.25–1.00 mm). Therefore, repeated application of biochar to N-deficient soils generally does not result in positive soil biochemical responses. However, repeated application of biochar together with NPK fertilizer modulates N limitation and optimizes microbial nutrient cycling processes, especially in micro-aggregates.

Mitochonic Acid 5 Improves Mitochondrial Respiration Following Alcohol-Induced Mitochondrial Dysfunction

Chronic alcohol exposure can lead to the development of Alcohol Induced Cardiomyopathy (ACM). The pathological changes in ACM have been suggested to be largely caused by mitochondrial damage, reduction of ATP, oxidative stress, and apoptosis of the cardiomyocytes. Cardiomyocytes, as cells with high energy demand, rely greatly on mitochondrial homeostasis and ATP production. Thus, therapeutic intervention to specifically target the mitochondria and ATP production can potentially alleviate ACM. Mitochonic acid 5 (MA-5) has been recently identified as a potential therapeutic compound that increases cellular ATP and improves mitochondrial function in several cardiac disorders. Given the potential role of MA-5 in improving mitochondrial function, I speculate that MA-5 could be an effective treatment for alcohol-induced cardiotoxicity. In the present study, I test the hypothesis that MA-5 can mitigate mitochondrial energetics in cultured cardiomyocytes exposed to alcohol. To investigate this, neonatal mouse cardiomyocytes (NMCMs) were isolated from mice at day 1-2 of age and cultured for 6 days with alcohol (50mM). The cells were treated with MA-5 (1μM, 5μM, or 10μM) for 4 hours with serum starvation and then cellular energetic changes were measured using the Mito Stress assay with the Seahorse Bioanalyzer (XF96pro, Agilent). To investigate the impacts of chronic alcohol exposure, rat embryonic myoblasts, H9C2 cells, were treated with 50mM alcohol for 3 weeks. Subsequently, cells were treated with MA-5 (1μM, 5μM, or 10μM) for 24 hours and then attached to the Resipher system (Lucid Lab) for continuous oxygen consumption monitoring and recording. NMCMs treated with 50mM alcohol showed a substantial reduction in basal respiration, maximal respiration, and spare respiratory capacity compared to controls. NMCMs treated with 10μM MA-5 showed a significant improvement in these parameters. Chronically exposed H9C2 cells showed a prolonged decline in OCR. MA-5 treatment improved and maintained oxygen consumption in these cells. In summary, these results demonstrated that alcohol exposed cardiomyocytes experience a decline in cellular energetics that could be corrected by MA-5 treatment. Future in vivo studies on preclinical ACM animal models are warranted to yield further insights into a potential novel therapy for ACM in patients. This research was supported by grant #T32AA007577 from the NIAAA at the National Institutes of Health. 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.

Abstract 3042: Oxidized Phospholipids Inhibit Glycolysis In Cardiomyocytes And Decrease Oxidative Phosphorylation By Activating The Mitogen-activated Protein Kinase Pathway

Oxidized phospholipids (oxPLs) were shown to be key players in the progression of numerous cardiovascular diseases including myocardial infarction, atherosclerosis, or cardiac ischemia reperfusion injury. However, the oxidized phospholipid-induced signaling mechanisms causing cardiac dysfunction remain elusive. We tested the hypothesis that oxPLs impact metabolism in cardiomyocytes and explored the involved signaling pathways. In vitro, treatment of h9c2 cardiomyocytes with a mixture of oxidized phosphatidylcholines (oxPAPC) led to activation of a mitogen-activated protein kinase (MAPK) pathway, namely phosphorylation of extracellular signal-regulated kinase 1/2 (ERK 1/2). Moreover, oxPAPC induced the expression of regulatory enzymes associated with the pentose phosphate pathway (PPP), such as PGD, G6PD, TALDO1, as well as genes connected to Nrf2-dependent oxidative stress, like HMOX-1. Metabolically, oxPAPC significantly reduced basal respiration and maximal oxygen consumption rate, as well as glycolytic capacity in h9c2 cardiomyocytes, as measured using a Seahorse extracellular flux analyzer. Treatment with a MEK inhibitor (PD98059, 10μM) resulted in a partial rescue of basal respiration and maximal oxygen consumption rate after incubation with oxPAPC. On the other hand, p38 inhibition (SB203580, 10μM) resulted in a change of oxPAPC-induced gene expression of PPP regulatory enzymes and HMOX-1. Ongoing studies including RNA-sequencing and pathway analysis will further explicate the scope of oxPL-induced gene expression and the involved mechanisms. In vivo , AAV8-mediated expression of the oxPL-recognizing scFv-E06 in albumin cre mice that had been fed a high fat high sucrose diet for 12 weeks, resulted in decreased expression of genes associated with GO Terms “glutathione metabolism” compared to AAV-GFP expressing counterparts, in their hearts. In summary, our study provides evidence that oxPLs significantly influence cardiomyocyte metabolism towards a redox-regulatory phenotype accompanied by the inhibited glycolysis and the decrease in oxidative phosphorylation by activating MAPK pathways. Future experiments will elucidate the relationship between MAPK signaling induced by oxPLs and cardiac dysfunction.

Activation of the Nrf-2 pathway improves the mitochondrial phenotype in skeletal muscle cells

Aging muscle displays a reduction in mitochondrial content, along with elevated reactive oxygen species (ROS) emission and reduced levels of antioxidant enzymes. These characteristics enhance tissue susceptibility to oxidative damage, facilitating sub-optimal cellular metabolism and subsequent muscle atrophy. While these perturbations to metabolic homeostasis are a natural course of the aging process, there has been ongoing research investigating how to implement interventions to reduce this decline in muscle health. Regular exercise is one possible treatment modality, however this may be unsuitable for some populations who are unable to participate due to their health status. The objective of this study was to examine the activation of the Nrf-2 pathway using the nutraceutical Sulforaphane (SFN) and evaluate its role as a potential exercise mimetic. We hypothesized that SFN would act through similar pathways activated with chronic exercise to improve mitochondrial content, respiration, and ROS emission. To address our objective, C2C12 myotubes were treated with SFN for various timepoints basally, and in the presence of the Complex-I inhibitor rotenone to induce oxidative stress. Western blotting revealed an 8-fold increase in Nrf-2 nuclear localization following 24hrs of SFN treatment, which subsequently led to the upregulation of antioxidant enzymes NQO1, Heme Oxygenase-1, catalase, glutathione reductase and Glucose-6-Phosphate Dehydrogenase by 2-to 3-fold. These protein changes, were accompanied by dramatic reductions in both total cellular and mitochondrial ROS emission with SFN, detected with CellROX Green and MitoSOX Red respectively. Interestingly, this led to an increase in mitochondrial membrane potential, detected via MitoTracker Red (MTR), despite rotenone-induced oxidative stress. Western blotting revealed TFAM upregulation at 24hrs, suggesting an increase in mitochondrial DNA (mtDNA) replication and transcription. This was corroborated by an increase in COX subunit I protein, a mitochondrially-encoded subunit of cytochrome c oxidase, as well as MitoTracker Green and MTR staining by 48hrs. Mitochondrial respiration was evaluated using Seahorse analysis, demonstrating a marked increase in ATP production as well as basal and maximal respiration. Together these data suggest that activation of the Nrf-2 pathway via SFN may lead to adaptations similar to chronic exercise. Additionally, SFN may have applications in disorders characterized by mitochondrial loss and high ROS emission. To fully elucidate the precise mechanisms underlying this agent, SFN will be combined with chronic contractile activity to determine if these two interventions operate through independent pathways. This work was supported by funds from the Natural Science and Engineering Research Council (NSERC). Sabrina Champsi is the recipient of the NSERC Alexander Graham Bell Canada Graduate Scholarship-Master’s (CGS-M). David A. Hood is the holder of a Canadian Research Chair in Cell Physiology. 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.

Characterization of Sex-Dependent Differences in Brain Microvascular Bioenergetics

Background: Women experience increased incidence of stroke-related deaths and lifetime risk of Alzheimer's disease (AD). Microvascular dysfunction has been implicated in the pathogenesis of ischemic stroke and AD. Our objective is to investigate the sex-dependent differences in bioenergetics of young mouse brain microvessels (BMVs). Methods: BMVs were isolated from young male and female mice (3-4 months), using a combination of gradient centrifugation and filtration (300μm and 40μm filters) methods. Extracellular acidification rate (ECAR) and oxygen consumption rate (OCR) of BMVs were measured utilizing the Agilent Seahorse XFe 24 analyzer. The levels of proteins and mRNAs of mitochondrial respiratory complexes were measured by western blot and RT-PCR, respectively. Citrate synthase (CS) enzyme activity and ATP levels were determined in lysates of BMVs. Results: Real-Time ATP Rate assay demonstrated a decreased total ATP production rate and ATP contribution from both glycolysis and oxidative phosphorylation (OxPhos) in BMVs from females compared to males. Mitochondrial stress test assay revealed significantly lower values of several mitochondrial respiratory parameters, including basal respiration, ATP production, maximal respiration, spare respiratory capacity, and proton leak in BMVs from females compared to males. Glycolytic Rate assay uncovered reduced basal glycolysis, proton efflux rate (PER) originating from basal glycolysis, and the mitoOCR/glycoPER ratio in BMVs from females compared to males. Interestingly, no sex-dependent differences were observed in basal PER and post-2-DG acidification rates in BMVs. Mito Fuel Flex Test assay showed no sex-dependent difference in the utilization of glucose, glutamine, and long-chain fatty acids as fuel substrates in BMVs. ATP measurements confirmed the reduced ATP levels in BMVs from females compared to males. Measurements of CS activity revealed no sex-dependent difference in the BMVs. Lastly, Western blot and RT-PCR experiments indicated no differences in either protein or mRNA levels of various mitochondrial complex protein levels.Conclusions: Female BMVs showed reduced mitochondrial respiratory and glycolytic parameters compared to male BMVs although relative contribution of various substrates for energy production were not different. These sex-dependent differences involving glycolysis and OxPhos make the microvasculature vulnerable to injury in females. Funding sources: NIH grants AG074489 and NS114286 (PVGK and RM). 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.

HSP47 complements cholesterol synthesis-independent HMGCoA-reductase pathway-mediated fibroblast bioenergetics

Fibrosis, characterized by excessive extracellular matrix (ECM) components deposition, is a common pathological process underlying numerous chronic diseases. Differentiating fibroblasts into myofibroblasts leads to the deposition of fibrous proteins like collagen in the ECM. Heat shock protein 47 (HSP47) is a molecular chaperone protein that assists in the folding of collagen. Recent studies show that inhibition of cholesterol synthesis-independent HMGCoA-reductase pathway enzyme geranylgeranyl pyrophosphate synthase 1 (GGPS1) decreases fibroblast differentiation and its bioenergetics. However, the role of HSP47 in this pathway is unknown, although recent observations show that HSP47 is decreased when GGPS1 is inhibited. Hence, we tested the hypothesis that HSP47 promotes cellular respiration in myofibroblasts. Seahorse assays were performed on different fibroblasts/myofibroblasts repeatedly and the oxygen consumption rate (OCR) and extracellular acidification rate (ECAR) were measured in the presence and absence of HSP47 inhibitor (HY124817). Complex V of the electron transport chain was measured by immunoblotting ATP-5A. HY124817 tends to decrease the OCR, basal respiration rate, ATP-linked, and spare respiratory capacity. Co-incubation with HY124817 and digeranyl bisphosphonate (DGBP), an inhibitor of GGPS1, significantly (P = 0.043) inhibited further the ATP-linked OCR compared to the TGF group. Immunoblotting showed that Complex V did not change significantly across treatments. These results suggest that HSP47 is involved in fibroblast bioenergetics related to ATP-linked OCR in both differentiated myofibroblasts and normal fibroblasts. Inhibition of HSP47 complements the decrease in myofibroblast cellular respiration caused by the GGPS1 inhibition. This finding is novel in that HSP47 plays a role in fibroblast bioenergetics regulated by the cholesterol synthesis-independent HMGCoA-reductase pathway. Further research is necessary to identify what HSP47 targets and regulatory elements involved in this process. This would provide more insight into the mechanisms that underlie critical fibrosis conditions like myocardial fibrosis and potential therapeutics. This experience was supported by the Medical College of Wisconsin's Advancing Student Potential for Inclusion with Research Experiences (ASPIRE) program. The program is funded by a federal grant from the National Heart, Lung, and Blood Institute. 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.

Cell-autonomous Action of the FGF19 Promotes UCP1 Expression and Function in Human Brown Adipocytes

Fibroblast growth factor 19 (FGF19) is an intestine-derived hormone that regulates glucose and energy metabolism. Central and systemic administration of human FGF19 in mice promotes increased energy expenditure and body weight loss through mechanisms that are not fully understood. In this study, we investigated whether FGF19 can activate thermogenesis in brown adipocytes (BA) in a cell-autonomous manner. We differentiated immortalized human brown preadipocytes into mature adipocytes with adipogenic induction media in the presence and absence of FGF19 for 18 days to evaluate the effects of FGF19 on adipogenesis and thermogenesis. Through qPCR and RNA-sequencing analyses, we observed that FGF19 receptors were expressed in both brown preadipocytes and mature BA. However, the obligatory FGF19 co-receptor, β-klotho, was not expressed in preadipocytes, suggesting that the effects of FGF19 must occur preferentially in mature BA. Lipid staining with Oil Red O as well as gene expression of the adipogenic markers fatty acid binding protein (FABP4) and peroxisome proliferator activated receptor-γ (PPAR-γ) showed that adipogenesis was not affected by FGF19. We then treated mature BA with FGF19 (100 ng/mL) acutely and chronically to evaluate FGF19-induced changes in signaling, gene transcription, and thermogenic function. FGF19 signaling was assessed by measuring ERK1/2 phosphorylation levels, which increased within 5 min and remained elevated for at least 30 min after treatment. Using Seahorse assays, we observed that 24-hour FGF19 treatment promoted increased basal respiration, ATP production, and proton leak in human BA, indictive of enhanced mitochondrial function. Since proton leak across the inner membrane through the uncoupling protein 1 (UCP1) generates heat, we assessed the expression of UCP1 and other thermogenic genes. Interestingly, FGF19 treatment specifically increased UCP1 gene expression without affecting other classical adrenergic-mediated thermogenic genes, such as deiodinase 2 (DIO2), peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC1-α), PR domain containing 16 (PRDM16), and cell death-inducing DNA fragmentation factor A (CIDEA). These findings suggest that FGF19 regulates UCP1 expression through non-canonical pathways. Future work will elucidate the mechanism by which FGF19 promotes UCP1 gene expression in mature BA. Taken together, FGF19 stimulates ERK1/2 phosphorylation and UCP1 expression in human BA, leading to enhanced mitochondrial respiration. These results provide new mechanistic insights into FGF19’s effects on metabolic regulation. Topic subcategories: Adipocyte biology. Funding sources: Sao Paulo Research Foundation (FAPESP): 2022/15148-2 and NIH R01 DK102898. 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.

Beta adrenergic agonist induces a shift in mitochondria metabolism in porcine skeletal muscle

During phases of skeletal muscle growth, the metabolic processes regulating muscle tissue exhibit remarkable adaptability. This metabolic flexibility is an essential component of maintaining the health and functionality of skeletal muscle, which allows the capacity to transition between oxidative and glycolytic metabolic pathways. Within the occurrence of these metabolic shifts, the exact underlying mechanisms that orchestrate these transitions within the context of mitochondrial function remain unresolved. Therefore, our objective is to determine the role of mitochondria during a shift in metabolism, through measuring functional capacity, gene expression, and protein abundance. To investigate this shift, we utilized β-adrenergic agonists (BAA) supplementation, due to its ability to increase the proportion of fast-twitch fibers in skeletal muscle. To assess the role of the mitochondria, we utilized a mutated pig, containing a constitutively active adenosine monophosphate activated protein kinase (AMPKγ3R200Q) that contains a greater oxidative capacity in a habitually glycolytic skeletal muscle. In this current study, mature pigs (wildtype and AMPKγ3R200Q) were fed BAA (0 and 9ppm) for 1 week, then euthanized and longissimus dorsi muscle samples were collected. Mitochondria of AMPK mutated pigs had a higher ( P = 0.08) oxygen consumption rate with pyruvate/malate substrates when stimulated with ADP when compared to their wildtype (WT) counterpart. When given succinate/rotenone substrates, there was an interaction ( P = 0.04) noted for basal respiration, where WT pigs fed control diets had lower oxygen consumption compared to that of AMPK mutated pigs and those fed BAA. These data suggest that BAA has more of an effect on WT pigs than AMPK mutated pigs, possibly due to the inherent increased oxidative metabolism in mutant pigs. In addition, skeletal muscle mitochondria of AMPK mutated pigs had higher ( P = 0.04) maximal respiration compared to that of their WT counterpart. After 1 week of feeding BAA, there were no differences in mitochondrial DNA content, but there was an increase in β1-adrenergic receptor gene expression in pigs fed BAA (Diet, P = 0.06; Interaction P = 0.08). Oxidative protein abundance increased for succinate dehydrogenase ( P &lt; 0.01) and citrate synthase ( P = 0.08) in the skeletal muscle of AMPK mutated pigs. Glycolytic proteins were increased for lactate dehydrogenase ( P &lt; 0.05) and glyceraldehyde 3-phosphate dehydrogenase ( P &lt; 0.01) in the muscle of WT pigs. No interactions between genotype and diet on the protein abundance level was noted. Together, these data show that mitochondria function is altered in porcine skeletal muscle when pigs are supplemented with 1 week of BAA; however, it is not detected in protein levels after 1 week. These data suggest part of the mechanism by which BAA supplementation augments muscle growth in pigs lies within the regulation of β1-adrenergic receptors and changes in mitochondrial function. 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 Sodium Channel Nav1.5 Arg222Gln Variant Induces a Sex-Specific Arrhythmia and Alters Mitochondrial Function

Introduction: Encoded by the SCN5A gene, cardiac Nav1.5 sodium channels initiate the action potential to trigger a heartbeat. As the predominant sodium channel in the heart, variants can have devastating consequences, leading to potentially lethal arrhythmias. With the gain of function arginine to glutamine (Arg222Gln) variant in Nav1.5, patients develop intermittent arrhythmias and dilated cardiomyopathy. The stress induced by chronic arrhythmias can trigger adverse metabolic reprogramming, exacerbating the underlying condition. We have generated a murine model harboring the human Arg222Gln variant where we observe that only males produce a clear observable arrhythmia. We hypothesize that the maladaptive metabolic response to the arrhythmia caused by the Arg222Gln variant maybe be a potential link to the sex differences. Methods: The human exon containing the Arg222Gln mutation was knocked into a murine model under the endogenous SCN5A promoter. Cellular metabolism (oxygen consumption) was measured using primary adult mouse cardiomyocytes (CMs) with the Seahorse XFe analyzer. Mitochondrial membrane potential was measured using ratiometric JC-1 dye and imaged on a scanning confocal microscope. Heart tissues were diced into 1mm3 cubes and fixed to perform serial block face electron microscopy to obtain 3D structure of mitochondria and mitochondrial morphology. Western blots were used to detect protein levels. Results: Basal respiration of CMs were unchanged, however the maximal respiratory capacity of Arg222Gln males was significantly lower (116.9±13.5pmol O2/min, p&lt;0.05) compared to WT males (407.3±16.4pmol O2/min). There were no differences between WT females (451.4±22.4pmol O2/min) and Arg222Gln females (463.2±33.7pmol O2/min). JC-1 dye revealed that the Arg222Gln males (0.6213±0.0172 red/green ratio, p&lt;0.001) have significantly lowered mitochondrial polarization compared to WT males (0.7550 ±0.0257). There were no differences between WT females (0.6236±0.0154) and Arg222Gln females (0.6466±0.0139). Arg222Gln males have reduced mitochondria area (1.155±0.052μm2, p&lt;0.05) compared to WT males (1.332±0.060μm2) and are more fragmented (p&lt;0.05). Electron transport chain complex protein levels and mitochondrial biomass measured by voltage dependent anion channel protein levels remain unchanged between WT males and Arg222Gln males (P&gt;0.05). The ratio of phosphorylated dynamin related (DRP) / total DRP protein levels were significantly higher in Arg222Gln males compared to WT males, indicative of mitochondrial fission (p&lt;0.05). Conclusion: We demonstrate evidence of a mitochondrial dysfunction in a murine model of arrhythmia caused by a gain of function Nav1.5 variant, adversely affecting overall cellular metabolism and mitochondrial quality. Our data suggests that the difference in metabolic reprogramming could play a role in the cardioprotection against arrhythmia in Arg222Gln females or explain why Arg222Gln males are severely affected by the arrhythmia. Future experiments will aim to elucidate how the difference in sex affects cardiac metabolism in the context of Arg222Gln Nav1.5 variant. This work was supported by a Canadian Institutes of Health Research Project Grant, the SickKids Foundation through the Curtis Joseph and Harold Groves Chair in Anesthesia and Pain Medicine (JTM) and the Department of Anesthesiology and Pain Medicine, University of Toronto through a Merit Award (JTM). TYTL is supported by the CIHR Canadian Graduate Scholarship — Doctoral Award. 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.

Analysis of Cellular Stress Assay Parameters and Intracellular ATP in Platelets: Comparison of Platelet Preparation Methods.

Platelets are metabolically active, anucleated and small circulating cells mainly responsible for the prevention of bleeding and maintenance of hemostasis. Previous studies showed that platelets mitochondrial content, function, and energy supply change during several diseases such as HIV/AIDS, COVID-19, pulmonary arterial hypertension, and in preeclampsia during pregnancy. These changes in platelets contributed to the severity of diseases and mortality. In our previous studies, we have shown that the seahorse-based cellular stress assay (CSA) parameters are crucial to the understanding of the mitochondrial performance in peripheral blood mononuclear cells (PBMCS). Moreover, the results of CSA parameters were significantly influenced by the PBMC preparation methods. In this study, we assessed the correlation of CSA parameters and intracellular ATP content in platelets and evaluated the effects of platelet preparation methods on the results of CSA parameters and intracellular ATP content. We compared the results of CSA parameters and intracellular ATP content in platelets isolated by density centrifugation with Optiprep and simple centrifugation of blood samples without Optiprep. Platelets isolated by centrifugation with Optiprep showed a higher spare capacity, basal respiration, and maximal respiration than those isolated without Optiprep. There was a clear correlation between basal respiration and maximal respiration, and the whole-ATP content in both isolation methods. Moreover, a positive correlation was observed between the relative spare capacity and whole-cell ATP content. In conclusion, the results of seahorse-based CSA parameters and intracellular ATP content in platelets are markedly influenced by the platelet isolation methods employed. The results of basal respiration and maximal respiration are hallmarks of cellular activity in platelets, and whole-cell ATP content is a potential hint for basic platelet viability. We recommend further studies to evaluate the role of CSA parameters and intracellular ATP content in platelets as biomarkers for the diagnosis and prediction of disease states.

Close-to-nature forest management effects on soil nematodes and microbial activity in pine plantations on aeolian sands

AbstractClose-to-nature forest management combines the economic use of forests with nature conservation in forest, aiming promote stability, productivity, diversity and continuity within forest ecosystems. While close-to-nature management is expected to positively impact the tree growth, its effect on the belowground micro-biota has been poorly investigated. Nematodes and microbes are species-rich and abundant soil microorganisms that have long been used as ecological indicators of soil health. In this study, was assessed the impact of close-to-nature forest management on soil nematode communities and microbial activity in the pine plantations on aeolian sands in Southern Slovakia, 10 years after the introduction of this management approach. Fifteen stands in close-to-nature forest managed and fifteen stands with applying standard forest management were chosen. Our findings revealed that close-to-nature forest management significantly increased the abundance of soil nematodes and nematode biomass in each of the plots. Moreover, close-to-nature forest management significantly increased the mean abundance of omnivores and predators as stress sensitive nematodes (c–p4, c–p5). Additionally, close-to-nature forest management reduces the proportion of stress tolerant nematodes (c–p1) and enrichment opportunists (c–p2), increased all maturity and structure indices as well as composite, structure, predator and omnivore footprints. Furthermore, close-to-nature forest management significantly increased soil moisture, soil carbon content, microbial biomass carbon, basal respiration and N-mineralization, and understory vegetation diversity. These findings suggest that close-to-nature management practice, resulting in forest of different ages, positively influenced nematode communities and microbial activity by changing the quantity and quality of resources associated with increased understory cover and diversity.

NLRX1: a key regulator in mitochondrial respiration and colorectal cancer progression.

Colorectal cancer (CRC) is a prevalent and aggressive malignancy with high mortality rates and significant risks to human well-being. Population-wide screening for tumor suppressor genes and oncogenes shows promise for reducing the incidence and fatality of CRC. Recent studies have suggested that NLRX1, an innate immunity suppressor, may play a role in regulating chronic inflammation and tumorigenesis. However, further investigation is needed to understand the specific role of NLRX1 in CRC. To evaluate the impact of NLRX1 on migration, invasion, and metastasis, two human colon cancer cell lines were studied in vitro. Additionally, a knockout mouse tumor-bearing model was used to validate the inhibitory effect of NLRX1 on tumor emergence and progression. The Seahorse XF96 technology was employed to assess mitochondrial function and glycolysis in colorectal cancer cells overexpressing NLRX1. Moreover, public databases were consulted to analyze gene and protein expression levels of NLRX1. Finally, the results were validated using a series of CRC patient samples. Our findings demonstrate that downregulation of NLRX1 enhances proliferation, colony formation, and tumor-forming capacity in HCT116 and LoVo cells. Conversely, overexpression of NLRX1 negatively impacts basal respiration and mitochondrial ATP-linked respiration in both cell lines, resulting in a notable decrease in maximal respiration during the standard mitochondrial stress test. Furthermore, analysis of data from the TCGA database reveals a significant reduction in NLRX1 expression in colon and rectal cancer tissues compared to normal tissues. This result was validated using clinical samples, where immunohistochemistry staining and western blotting demonstrated a notable reduction in NLRX1 protein levels in CRC compared to adjacent normal tissues. The decreased expression of NLRX1 may serve as a significant prognostic indicator and diagnostic biomarker for CRC patients.

Unequal impacts of unidirectional freeze-thaw on different soil layers and aggregate sizes: Evidenced by microbial communities and CO2 emissions

Currently available investigations often fail to adequately recognize that soil does not freeze or thaw instantly nor uniformly, but unidirectionally and progressively. Unidirectional freeze-thaw can re-organize soil physio-, chemical- and biological-properties across layers as well among aggregates, thus posing far-reaching yet undervalued impacts on soil carbon biogeochemical cycling, especially in eroding settings. In this study, a Mollisol was refilled into soil columns, and respectively experienced complete freeze-thaw (i.e., no layer distinguished), and progressive freeze-thaw (i.e., from outer layer T1, to inner core T3). After thawing, all soils were fractionated into six size classes, and each size class was then incubated at 10℃ over 7 days to measure daily CO2 emission rate. Our results show that: (1) The soil microbial biomass carbon (SMBC) was generally reduced by 25 % after freeze-thaw, but only the finest aggregates ≤ 32 μm maintained comparable CO2 emission rates. (2) The inner core T3 thawed last and survived with significantly more SMBC and CO2, but lower respiratory quotient (qCO2), than the outer layer T1 thawed first. (3) The fine aggregates survived with more SMBC and total CO2 emissions, but significantly lower qCO2 and smaller ratios of fungal to bacterial biomass carbon, than the coarse aggregates. The disproportionally less respiratory carbon losses (i.e., lower qCO2) in T3 was probably because the lagged freezing and thus weakened water-ice phase changes in the inner core helped to better preserve the soil microbes. The fungal-dominant coarse aggregates were very responsive to freezing and evidently more respiratory active, whereas the fine aggregates were more resilient as the enhanced freezing point depression and the thus prolonged unfrozen state, fostering a better microbial survival with bacteria-dominant communities and robust basal respiration. Although limited to controlled simulation, this study may help to disentangle the role of unidirectional freeze-thaw in perturbing slope-scale soil carbon biogeochemical cycling.

Flexibility underlies differences in mitochondrial respiratory performance between migratory and non-migratory White-crowned Sparrows (Zonotrichia leucophrys)

Migration is one of the most energy-demanding behaviors observed in birds. Mitochondria are the primary source of energy used to support these long-distance movements, yet how mitochondria meet the energetic demands of migration is scarcely studied. We quantified changes in mitochondrial respiratory performance in the White-crowned Sparrow (Zonotrichia leucophrys), which has a migratory and non-migratory subspecies. We hypothesized that the long-distance migratory Gambel’s subspecies (Z. l. gambelii) would show higher mitochondrial respiratory performance compared to the non-migratory Nuttall’s subspecies (Z. l. nuttalli). We sampled Gambel’s individuals during spring pre-migration, active fall migration, and a period with no migration or breeding (winter). We sampled Nuttall’s individuals during periods coinciding with fall migration and the winter period of Gambel’s annual cycle. Overall, Gambel’s individuals had higher citrate synthase, a proxy for mitochondrial volume, than Nuttall’s individuals. This was most pronounced prior to and during migration. We found that both OXPHOS capacity (state 3) and basal respiration (state 4) of mitochondria exhibit high seasonal flexibility within Gambel’s individuals, with values highest during active migration. These values in Nuttall’s individuals were most similar to Gambel’s individuals in winter. Our observations indicate that seasonal changes in mitochondrial respiration play a vital role in migration energetics.

Unique features of β-cell metabolism are lost in type 2 diabetes.

Pancreatic β cells play an essential role in the control of systemic glucose homeostasis as they sense blood glucose levels and respond by secreting insulin. Upon stimulating glucose uptake in insulin-sensitive tissues post-prandially, this anabolic hormone restores blood glucose levels to pre-prandial levels. Maintaining physiological glucose levels thus relies on proper β-cell function. To fulfill this highly specialized nutrient sensor role, β cells have evolved a unique genetic program that shapes its distinct cellular metabolism. In this review, the unique genetic and metabolic features of β cells will be outlined, including their alterations in type 2 diabetes (T2D). β cells selectively express a set of genes in a cell type-specific manner; for instance, the glucose activating hexokinase IV enzyme or Glucokinase (GCK), whereas other genes are selectively "disallowed", including lactate dehydrogenase A (LDHA) and monocarboxylate transporter 1 (MCT1). This selective gene program equips β cells with a unique metabolic apparatus to ensure that nutrient metabolism is coupled to appropriate insulin secretion, thereby avoiding hyperglycemia, as well as life-threatening hypoglycemia. Unlike most cell types, β cells exhibit specialized bioenergetic features, including supply-driven rather than demand-driven metabolism and a high basal mitochondrial proton leak respiration. The understanding of these unique genetically programmed metabolic features and their alterations that lead to β-cell dysfunction is crucial for a comprehensive understanding of T2D pathophysiology and the development of innovative therapeutic approaches for T2D patients.

Soil Organic Matter and Microbial Biomass Under Cultivation of Urochloa Brizantha Fertilized with Wood Ash in the Cerrado of Mato Grosso

ABSTRACT The use of waste such as wood ash as an alternative fertilizer in agricultural production can result in an improvement in the chemical and biological characteristics of the soil. The objective of this research was to evaluate the effect of doses and management of wood ash application in the organic matter content and biological attributes of the soil in a Cerrado area cultivated with Urochloa brizantha cv BRS paiaguás. The experiment was performed in randomized blocks, in a 5 × 2 striped scheme, with five doses of wood ash (0, 8, 16, 24 and 32 t ha−1) and two application managements (with and without incorporation to the soil) with four repetitions. The variables analyzed were: soil organic matter content, microbial biomass carbon, basal respiration, qCO2 and β-glucosidase activity. During the evaluations it was observed a reduction of 0.36 g kg−1 of organic matter for each ton of ash applied to the soil, regardless of management. This reduction also occurred in microbial biomass carbon and β-glucosidase activity. initially the ash doses elevated the soil respiration and the metabolic quotient, evidencing a small stress in the soil microbiota, however, in the last evaluation the rates of these two variables remained stable. The application of wood ash, in doses ranging from 16 to 24 t ha−1, can be used as soil conditioner and fertilizer in pastures, because it results in better conditions for the soil.

Ecotoxicological impact of butisanstar and clopyralid herbicides on soil microbial respiration and the enzymatic activities

The application of herbicides in soil has been noted for its detrimental effect on the soil microbial community, crucial for various biochemical processes. This study provides a comprehensive assessment of the impact of butisanstar and clopyralid herbicides, both individually and in combination at different dosage (recommended field dose (RFD), ½, 2 and 5-times RFD). The assessment focuses on soil basal respiration (SBR), cumulative microbial respiration (CMR), and the activities dehydrogenase (DH), catalase (CAT), urease, acid and alkaline phosphatases (Ac–P and Alk-P) enzymes, along with their variations on days 10, 30, 60, and 90 post-herbicide application. Results indicate that, although herbicides, even at lower doses of RFD, demonstrate inhibitory effects on DH, CAT, and microbial respiration, they paradoxically lead to a significant enhancement in urease and phosphatase activities, even at higher doses. The inhibitory/enhancing intensity varies based on herbicide type, incubation period, and dosage. Co-application of herbicides manifests synergistic effects compared to individual applications. The most notable inhibitory effects on DH, CAT, and SBR are observed on the 30th day, coinciding with the highest activities of urease and phosphatases on the same day. The persistent inability to restore respiration and enzyme activities to initial soil (control) levels emphasizes the lasting adverse and inhibitory effects of herbicides, especially clopyralid, over the long term. It becomes apparent that soil microorganisms require an extended duration to decompose and acclimate to the presence of herbicides. Consequently, these agrochemical compounds pose a potential risk to crucial biochemical processes, such as nutrient cycling, ultimately impacting crop production.