Deficiency In Skeletal Muscle Research Articles

Laminin-α2 chain deficiency in skeletal muscle causes dysregulation of multiple cellular mechanisms.

LAMA2, coding for the laminin-α2 chain, is a crucial ECM component, particularly abundant in skeletal muscle. Mutations in LAMA2 trigger the often-lethal LAMA2-congenital muscular dystrophy (LAMA2-CMD). Various phenotypes have been linked to LAMA2-CMD; nevertheless, the precise mechanisms that malfunction during disease onset in utero remain unknown. We generated Lama2-deficient C2C12 cells and found that Lama2-deficient myoblasts display proliferation, differentiation, and fusion defects, DNA damage, oxidative stress, and mitochondrial dysfunction. Moreover, fetal myoblasts isolated from the dy W mouse model of LAMA2-CMD display impaired differentiation and fusion in vitro. We also showed that disease onset during fetal development is characterized by a significant down-regulation of gene expression in muscle fibers, causing pronounced effects on cytoskeletal organization, muscle differentiation, and altered DNA repair and oxidative stress responses. Together, our findings provide unique insights into the critical importance of the laminin-α2 chain for muscle differentiation and muscle cell homeostasis.

Heme deficiency in skeletal muscle exacerbates sarcopenia and impairs autophagy by reducing AMPK signaling

Heme serves as a prosthetic group in hemoproteins, including subunits of the mammalian mitochondrial electron transfer chain. The first enzyme in vertebrate heme biosynthesis, 5-aminolevulinic acid synthase 1 (ALAS1), is ubiquitously expressed and essential for producing 5-aminolevulinic acid (ALA). We previously showed that Alas1 heterozygous mice at 20–35 weeks (aged-A1+/−s) manifested impaired glucose metabolism, mitochondrial malformation in skeletal muscle, and reduced exercise tolerance, potentially linked to autophagy dysfunction. In this study, we investigated autophagy in A1+/−s and a sarcopenic phenotype in A1+/−s at 75–95 weeks (senile-A1+/−s). Senile-A1+/−s exhibited significantly reduced body and gastrocnemius muscle weight, and muscle strength, indicating an accelerated sarcopenic phenotype. Decreases in total LC3 and LC3-II protein and Map1lc3a mRNA levels were observed in aged-A1+/−s under fasting conditions and in Alas1 knockdown myocyte-differentiated C2C12 cells (A1KD-C2C12s) cultured in high- or low-glucose medium. ALA treatment largely reversed these declines. Reduced AMP-activated protein kinase (AMPK) signaling was associated with decreased autophagy in aged-A1+/−s and A1KD-C2C12s. AMPK modulation using AICAR (activator) and dorsomorphin (inhibitor) affected LC3 protein levels in an AMPK-dependent manner. Our findings suggest that heme deficiency contributes to accelerated sarcopenia-like defects and reduced autophagy in skeletal muscle, primarily due to decreased AMPK signaling.

ATF4-dependent and independent mitokine secretion from OPA1 deficient skeletal muscle in mice is sexually dimorphic.

Reducing Optic Atrophy 1 (OPA1) expression in skeletal muscle in male mice induces Activation Transcription Factor 4 (ATF4) and the integrated stress response (ISR). Additionally, skeletal muscle secretion of Fibroblast Growth Factor 21 (FGF21) is increased, which mediates metabolic adaptations including resistance to diet-induced obesity (DIO) and glucose intolerance in these mice. Although FGF21 induction in this model can be reversed with pharmacological attenuation of ER stress, it remains to be determined if ATF4 is responsible for FGF21 induction and its metabolic benefits in this model. We generated mice with homozygous floxed Opa1 and Atf4 alleles and a tamoxifen-inducible Cre transgene controlled by the human skeletal actin promoter to enable simultaneous depletion of OPA1 and ATF4 in skeletal muscle (mAO DKO). Mice were fed high fat (HFD) or control diet and evaluated for ISR activation, body mass, fat mass, glucose tolerance, insulin tolerance and circulating concentrations of FGF21 and growth differentiation factor 15 (GDF15). In mAO DKO mice, ATF4 induction is absent. Other indices of ISR activation, including XBP1s, ATF6, and CHOP were induced in mAO DKO males, but not in mOPA1 or mAO DKO females. Resistance to diet-induced obesity was not reversed in mAO DKO mice of both sexes. Circulating FGF21 and GDF15 illustrated sexually dimorphic patterns. Loss of OPA1 in skeletal muscle increases circulating FGF21 in mOPA1 males, but not in mOPA1 females. Additional loss of ATF4 decreased circulating FGF21 in mAO DKO male mice, but increased circulating FGF21 in female mAO DKO mice. Conversely, circulating GDF15 was increased in mAO DKO males and mOPA1 females, but not in mAO DKO females. Sex differences exist in the transcriptional outputs of the ISR following OPA deletion in skeletal muscle. Deletion of ATF4 in male and female OPA1 KO mice does not reverse the resistance to DIO. Induction of circulating FGF21 is ATF4 dependent in males, whereas induction of circulating GDF15 is ATF4 dependent in females. Elevated GDF15 in males and FGF21 in females could reflect activation by other transcriptional outputs of the ISR, that maintain mitokine-dependent metabolic protection in an ATF4-independent manner.

Skeletal muscle cystathionine γ-lyase deficiency promotes obesity and insulin resistance and results in hyperglycemia and skeletal muscle injury upon HFD in mice

ABSTRACT Objectives The objective of this study was to investigate whether skeletal muscle cystathionine γ-lyase (CTH) contributes to high-fat diet (HFD)-induced metabolic disorders using skeletal muscle Cth knockout (CthΔskm ) mice. Methods The Cth Δskm mice and littermate Cth-floxed (Cthf/f ) mice were fed with either HFD or chow diet for 13 weeks. Metabolomics and transcriptome analysis were used to assess the impact of CTH deficiency in skeletal muscle. Results Metabolomics coupled with transcriptome showed that CthΔskm mice displayed impaired energy metabolism and some signaling pathways linked to insulin resistance (IR) in skeletal muscle although the mice had normal insulin sensitivity. HFD led to reduced CTH expression and impaired energy metabolism in skeletal muscle in Cthf/f mice. CTH deficiency and HFD had some common pathways enriched in the aspects of amino acid metabolism, carbon metabolism, and fatty acid metabolism. CthΔskm +HFD mice exhibited increased body weight gain, fasting blood glucose, plasma insulin, and IR, and reduced glucose transporter 4 and CD36 expression in skeletal muscle compared to Cthf/f +HFD mice. Impaired mitochondria and irregular arrangement in myofilament occurred in CthΔskm +HFD mice. Omics analysis showed differential pathways enriched between CthΔskm mice and Cthf/f mice upon HFD. More severity in impaired energy metabolism, reduced AMPK signaling, and increased oxidative stress and ferroptosis occurred in CthΔskm +HFD mice compared to Cthf/f +HFD mice. Discussion Our results indicate that skeletal muscle CTH expression dysregulation contributes to metabolism disorders upon HFD.

Not So Rare: Diseases Based on Mutant Proteins Controlling Endoplasmic Reticulum-Mitochondria Contact (MERC) Tethering.

Mitochondria-endoplasmic reticulum contacts (MERCs), also called endoplasmic reticulum (ER)-mitochondria contact sites (ERMCS), are the membrane domains, where these two organelles exchange lipids, Ca2+ ions, and reactive oxygen species. This crosstalk is a major determinant of cell metabolism, since it allows the ER to control mitochondrial oxidative phosphorylation and the Krebs cycle, while conversely, it allows the mitochondria to provide sufficient ATP to control ER proteostasis. MERC metabolic signaling is under the control of tethers and a multitude of regulatory proteins. Many of these proteins have recently been discovered to give rise to rare diseases if their genes are mutated. Surprisingly, these diseases share important hallmarks and cause neurological defects, sometimes paired with, or replaced by skeletal muscle deficiency. Typical symptoms include developmental delay, intellectual disability, facial dysmorphism and ophthalmologic defects. Seizures, epilepsy, deafness, ataxia, or peripheral neuropathy can also occur upon mutation of a MERC protein. Given that most MERC tethers and regulatory proteins have secondary functions, some MERC protein-based diseases do not fit into this categorization. Typically, however, the proteins affected in those diseases have dominant functions unrelated to their roles in MERCs tethering or their regulation. We are discussing avenues to pharmacologically target genetic diseases leading to MERC defects, based on our novel insight that MERC defects lead to common characteristics in rare diseases. These shared characteristics of MERCs disorders raise the hope that they may allow for similar treatment options.

Nutritional considerations for people living with a Fontan circulation: a narrative review.

The population of people living with a Fontan circulation are highly heterogenous, including both children and adults, who have complex health issues and comorbidities associated with their unique physiology throughout life. Research focused on nutritional considerations and interventions in the Fontan population is extremely limited beyond childhood. This review article discusses the current literature examining nutritional considerations in the setting of Fontan physiology and provides an overview of the available evidence to support nutritional management strategies and future research directions. Protein-losing enteropathy, growth deficits, bone mineral loss, and malabsorption are well-recognised nutritional concerns within this population, but increased adiposity, altered glucose metabolism, and skeletal muscle deficiency are also more recently identified issues. Emergencing evidence suggets that abnormal body composition is associated with poor circulatory function and health outcomes. Many nutrition-related issues, including the impact of congenital heart disease on nutritional status, factors contributing to altered body composition and comorbidities, as well as the role of the microbiome and metabolomics, remain poodly understood.

HDAC9 inhibition reduces skeletal muscle atrophy and enhances regeneration in mice with cigarette smoke-induced COPD

Cigarette smoke (CS) is the major risk factor for chronic obstructive pulmonary disease (COPD), and sarcopenia is one of the significant comorbidities of COPD. However, the pathogenesis of CS-related deficient skeletal muscle regeneration has yet to be clarified. The impact of CS on myoblast differentiation was examined, and then we determined which HDAC influenced the myogenic process and muscle atrophy in vitro and in vivo. Finally, we further investigated the potential mechanisms via RNA sequencing. Long-term CS exposure activated skeletal muscle primary SCs while inhibiting differentiation, and defective myogenesis was also observed in C2C12 cells treated with CS extract (CSE). The level of HDAC9 changed in vitro and in vivo in CS exposure models as well as COPD patients, as detected by bioinformatics analysis. Our data showed that CSE impaired myogenic capacity and myotube formation in C2C12 cells via HDAC9. Moreover, inhibition of HDAC9 in mice exposed to CS prevented skeletal muscle dysfunction and promoted SC differentiation. The results of RNA-Seq analysis and verification indicated that HDAC9 knockout improved muscle differentiation in CS-exposed mice, probably by acting on the AKT/mTOR pathway and inhibiting the P53/P21 pathway. More importantly, the serum of HDAC9 KO mice exposed to CS alleviated the differentiation impairment of C2C12 cells caused by serum intervention in CS-exposed mice, and this effect was inhibited by LY294002 (an AKT/mTOR pathway inhibitor). These results suggest that HDAC9 plays an essential role in the defective regeneration induced by chronic exposure to CS.

PIEZO1 loss-of-function compound heterozygous mutations in the rare congenital human disorder Prune Belly Syndrome

Prune belly syndrome (PBS), also known as Eagle-Barret syndrome, is a rare, multi-system congenital myopathy primarily affecting males. Phenotypically, PBS cases manifest three cardinal pathological features: urinary tract dilation with poorly contractile smooth muscle, wrinkled flaccid ventral abdominal wall with skeletal muscle deficiency, and intra-abdominal undescended testes. Genetically, PBS is poorly understood. After performing whole exome sequencing in PBS patients, we identify one compound heterozygous variant in the PIEZO1 gene. PIEZO1 is a cation-selective channel activated by various mechanical forces and widely expressed throughout the lower urinary tract. Here we conduct an extensive functional analysis of the PIEZO1 PBS variants that reveal loss-of-function characteristics in the pressure-induced normalized open probability (NPo) of the channel, while no change is observed in single-channel currents. Furthermore, Yoda1, a PIEZO1 activator, can rescue the NPo defect of the PBS mutant channels. Thus, PIEZO1 mutations may be causal for PBS and the in vitro cellular pathophysiological phenotype could be rescued by the small molecule, Yoda1. Activation of PIEZO1 might provide a promising means of treating PBS and other related bladder dysfunctional states.

Calorie Restriction Rescues Mitochondrial Dysfunction in Adck2-Deficient Skeletal Muscle.

ADCK2 haploinsufficiency-mediated mitochondrial coenzyme Q deficiency in skeletal muscle causes mitochondrial myopathy associated with defects in beta-oxidation of fatty acids, aged-matched metabolic reprogramming, and defective physical performance. Calorie restriction has proven to increase lifespan and delay the onset of chronic diseases associated to aging. To study the possible treatment by food deprivation, heterozygous Adck2 knockout mice were fed under 40% calorie restriction (CR) and the phenotype was followed for 7 months. The overall glucose and fatty acids metabolism in muscle was restored in mutant mice to WT levels after CR. CR modulated the skeletal muscle metabolic profile of mutant mice, partially rescuing the profile of WT animals. The analysis of mitochondria isolated from skeletal muscle demonstrated that CR increased both CoQ levels and oxygen consumption rate (OCR) based on both glucose and fatty acids substrates, along with mitochondrial mass. The elevated aerobic metabolism fits with an increase of type IIa fibers, and a reduction of type IIx in mutant muscles, reaching WT levels. To further explore the effect of CR over muscle stem cells, satellite cells were isolated and induced to differentiate in culture media containing serum from animals in either ad libitum or CR diets for 72 h. Mutant cells showed slower differentiation alongside with decreased oxygen consumption. In vitro differentiation of mutant cells was increased under CR serum reaching levels of WT isolated cells, recovering respiration measured by OCR and partially beta-oxidation of fatty acids. The overall increase of skeletal muscle bioenergetics following CR intervention is paralleled with a physical activity improvement, with some increases in two and four limbs strength tests, and weights strength test. Running wheel activity was also partially improved in mutant mice under CR. These results demonstrate that CR intervention, which has been shown to improve age-associated physical and metabolic decline in WT mice, also recovers the defective aerobic metabolism and differentiation of skeletal muscle in mice caused by ADCK2 haploinsufficiency.

Muscle mass change using linear measurement analysis after nephrectomy for pT3 and pT4 renal cell carcinoma is associated with mortality

AbstractBackgroundPreoperative skeletal muscle deficiency is an established risk factor for poor survival outcomes in patients with renal cell carcinoma (RCC). However, given the dynamic nature of skeletal muscle associated with malignancy, there is a need to evaluate the prognostic benefit of muscle area change from the preoperative to postoperative period. We hypothesize that an improvement in muscle area following nephrectomy, measured by linear segmentation of L3 psoas and paraspinal musculature, is associated with improvement in overall survival (OS) and cancer specific survival (CSS) for patients with pT3 and pT4 RCC.MethodsWe retrospectively analysed 270 pT3 and pT4 RCC patients who underwent nephrectomy from March 2004 to February 2020 with available preoperative and postoperative axial CT or MRI studies segmented at the L3 vertebrae. The majority were N0 (79%) and M0 (68%). Psoas and paraspinal muscles were measured bilaterally using a validated digital ruler tool. Total muscle area (TMA) was calculated by aggregating the area of all four muscles and total muscle area index (TMI) by dividing the TMA by height squared (m2). The prognostic value of postoperative muscle improvement, defined as any increase in muscle area index, was analysed using Kaplan–Meier and Cox proportional stepwise hazard models.ResultsMedian time between preoperative scans and surgery was approximately 22 days and between surgery and postoperative scans 172 days. One hundred twenty‐one patients (44.8%) had an increase in total muscle area index post‐nephrectomy (IQR = 33.4; P ≤ 0.0001). On Kaplan–Meier analysis, postoperative improvement in TMI was associated with decreased odds of mortality (P = 0.0024) with a median follow‐up of 38.6 months. In a multivariable Cox regression analysis, improvement of TMI was associated with increased OS (HR = 0.52, 95% CI 0.35–0.78, P < 0.001) and increased CSS (HR = 0.55, 95% CI 0.32–0.94, P = 0.030). A 5% or more improvement in TMI was also associated with increased OS (HR = 0.53, 95% CI 0.34–0.84, P = 0.006) and increased CSS (HR = 0.46, 95% CI 0.24–0.86, P = 0.015).ConclusionsAny improvement in TMI between preoperative and initial postoperative imaging after nephrectomy was associated with increased OS and CSS in patients with pT3 and pT4 RCC. Perioperative linear segmentation is an efficient tool that may improve current prognostication methods and can be performed on any imaging software platform.

A Piezo1/KLF15/IL-6 axis mediates immobilization-induced muscle atrophy.

Although immobility is a common cause of muscle atrophy, the mechanism underlying this causality is unclear. We here show that Krüppel-like factor 15 (KLF15) and IL-6 are upregulated in skeletal muscle of limb-immobilized mice and that mice with KLF15 deficiency in skeletal muscle or with systemic IL-6 deficiency are protected from immobility-induced muscle atrophy. A newly developed Ca2+ bioimaging revealed that the cytosolic Ca2+ concentration ([Ca2+]i) of skeletal muscle is reduced to below the basal level by immobilization, which is associated with the downregulation of Piezo1. Acute disruption of Piezo1 in skeletal muscle induced Klf15 and Il6 expression as well as muscle atrophy, which was prevented by antibodies against IL-6. A role for the Piezo1/KLF15/IL-6 axis in immobility-induced muscle atrophy was validated in human samples. Our results thus uncover a paradigm for Ca2+ signaling in that a decrease in [Ca2+]i from the basal level triggers a defined biological event.

Key Facilitator Proteins that Mediate Sarcolemma Membrane Repair have Potential as Therapeutics for Muscle Disease and Injury

A common aspect of many diseases and traumatic injuries affecting skeletal muscle is the necrotic death of muscle fibers. Necrotic death of muscle fibers involves the breakdown of the sarcolemmal membrane that can be exacerbated by increased fragility of the membrane or by compromised endogenous sarcolemmal membrane repair processes. Increasing the efficacy of these repair mechanisms could act as a therapeutic approach for several muscular diseases and injuries. Limb‐girdle muscular dystrophy 2B (LGMD2B), a subtype of LGMD, is an autosomal recessive neuromuscular disorder caused by mutations in the DYSF gene that encodes dysferlin, a protein that is vital in membrane repair. The dysferlin protein has been previously shown to facilitate membrane repair in skeletal muscle and knockout mice for dysferlin develop progressive muscular dystrophy. When dysferlin is absent or inactivated through mutation, membrane damage that cannot be repaired accumulates until muscle fibers undergo necrosis that eventually overwhelms the regenerative capacity of the muscle. This causes skeletal muscle deterioration in LGMD2B patients, particularly in the pelvic and shoulder girdle muscles. There is currently no cure for LGMD2B and treatments that stimulate the membrane repair process in muscle fibers have been greatly overlooked and underutilized as a potential therapeutic approach. This project investigates a novel membrane repair signaling cascade in skeletal cells by utilizing SC79, an Akt activator, to increase membrane repair capacity in skeletal muscle. We hypothesize that activation of the phosphoinositide‐3 kinase (PI3K)/Akt1 signaling axis regulates membrane repair in cultured muscle cells and mouse tissue. Based on our data, we find that SC79 injection leads to decreased sarcolemmal membrane injury during treadmill exercises where injection of SC79 decreases the entry of Evans blue dye into muscle fibers. We determined that various doses of SC79 can increase membrane repair in cultured muscle cells and Bla/J dysferlin deficient mice. In these studies, multi‐photon infrared laser microscopy was used to damage the cell membrane of myoblasts, transdifferentiated from skin fibroblasts isolated from LGMD2B patients, in the presence of FM4‐64 dye, a lipophilic dye that fluoresces when it enters the cells and binds to the phospholipids of the cell membrane and intracellular organelles. The extent of localized FM4‐64 dye fluorescence provides a measurement of how well the membrane is repaired. We found SC79 could increase membrane repair in these human patient myoblasts in a dose dependent fashion. This assay was also used on isolated complete muscles from the Bla/J dysferlin deficient mice, where SC79 also increased membrane repair responses. We conclude that activation of the PI3K/Akt1 signaling axis increases membrane repair in dysferlin deficient skeletal muscle. This project explores a novel signaling cascade controlling membrane repair that could be leveraged to develop new therapies for muscle disease and injury.

Traces of Bothrops snake venoms in necrotic muscle preclude myotube formation in vitro

Deficient skeletal muscle regeneration, which often leads to permanent sequelae, is a common clinical finding in envenomations caused by snakes of the family Viperidae, such as those of Bothrops alternatus and B. diporus in South America. The causes of such poor muscle regenerative outcome are still incompletely understood. Using a murine experimental model of envenomation by the venoms of these two species, we assessed whether traces of venom components that remain in muscle tissue days after envenomation affect myoblasts and myotube formation in culture. The kinetics of drop in venom concentration in the tissue was assessed by ELISA and Western blot, and by the quantification of venom phospholipase A2 activity. A rapid drop of venom components was observed in muscle, although a band of 58–63 kDa remained even 168 h after venom injection, and venom phospholipase A2 activity was detected in muscle tissue days after envenomation. Muscle homogenates from envenomated animals were cytotoxic to myoblasts in culture and inhibited the formation of myotubes even in conditions where homogenates were devoid of cytotoxicity. These deleterious effects were abrogated when homogenates were incubated with antivenom. Our findings agree with previous observations with the venom of Bothrops asper and provide further evidence that one of the causes of the poor skeletal muscle regeneration after Bothrops sp venom-induced myonecrosis is the deleterious action on myogenic cells of traces of venom components remaining in the tissue.

COX16 deficiency causes a novel mitochondrial disorder with lethal infantile presentation and complex IV deficiency

Objective: To investigate the underlying genetic aetiology in two unrelated Caucasian patients with lethal infantile presentation of hypertrophic cardiomyopathy, encephalopathy, severe lactic acidosis, and complex IV deficiency in skeletal muscle.

GRSF1 deficiency in skeletal muscle reduces endurance in aged mice.

GRSF1 is a mitochondrial RNA-binding protein important for maintaining mitochondrial function. We found that GRSF1 is highly expressed in cultured skeletal myoblasts differentiating into myotubes. To understand the physiological function of GRSF1 in vivo, we generated mice in which GRSF1 was specifically ablated in skeletal muscle. The conditional knockout mice (Grsf1cKO) appeared normal until 7-9 months of age. Importantly, however, a reduction of muscle endurance compared to wild-type controls was observed in 16- to 18-month old Grsf1cKO mice. Transcriptomic analysis revealed more than 200 mRNAs differentially expressed in Grsf1cKO muscle at this age. Notably, mRNAs encoding proteins involved in mitochondrial function, inflammation, and ion transport, including Mgarp, Cxcl10, Nfkb2, and Sln mRNAs, were significantly elevated in aged Grsf1cKO muscle. Our findings suggest that GRSF1 deficiency exacerbates the functional decline of aged skeletal muscle, likely through multiple downstream effector proteins.

Nutrition and nutritional status of underweight patients

Insufficient body weight is one of the manifestations of nutritional disorders. Diseases associated with malnutrition occur in 10-12% of the population. The aim of the work was to study indicators of nutritional status and actual nutrient intake in patients with insufficient body weight. Material and methods. The study included 48 women aged 31.4±11.8 years, with a body mass index below 18.5 kg/m2. The body composition was estimated by bioelectrical impedance analysis. Nutrient intake was assessed using food frequency questionnaire, physical activity was evaluated by the survey method, using the computer program "Evaluation of nutrition", also blood biochemical parameters were determined. Results. Body fat mass was below average values in 93.8% of patients, while only 50.0% of women had a skeletal muscle deficiency, and 10.4% surveyed had skeletal muscle mass above average values. The energy value of the daily diet was 1982± 282 kcal, and daily energy expenditure was 2158±255 kcal. In the structure of the diet, fats prevailed (42.0±10.5% of daily calorie intake) and there was a significant lack of total carbohydrates (39.9±10.4% of daily calorie intake) and dietary fiber. Fat intake was exceeded in 92.9% of patients. Insufficient carbohydrate intake was also observed in 92.9% of patients. In most patients, daily intake of potassium, calcium, magnesium, iron, B vitamins did not reach the recommended level, while sodium and phosphorus intake was excessive. The nutrient intake imbalance affected blood biochemical parameters in hypercholesterolemia (in 41.7% of patients) and hypertriglyceridemia (31.3%), and decreased calcium (30.0%), iron (12.8%) and vitamin D (52.2%) levels. Conclusion. Thus, for underweight patients, correction of the diet and dispensary observation is required to determine body composition and biochemical parameters, in particular, the fat and muscle components of the body weight, lipid metabolism indicators, the supply with macro- and micronutrients in order to develop treatment and prevention tactics of diet-related diseases, combined with reduced body weight.

Mitochondrial Quality Control in Sarcopenia: Updated Overview of Mechanisms and Interventions.

Sarcopenia is a common geriatric disorder characterized by decreased muscle strength, low muscle mass and poor physical performance. This aging-related skeletal muscle deterioration leads to adverse outcomes and severely impairs the quality of life of patients. The accumulation of dysfunctional mitochondria with aging is an important factor in the occurrence and progression of sarcopenia. Mitochondrial quality control (MQC) fundamentally ensures the normal mitochondrial functions and is comprised of four main parts: proteostasis, biogenesis, dynamics and autophagy. Therefore, any pathophysiologic factors compromising the quality control of homeostasis in the skeletal muscle may lead to sarcopenia. However, the specific theoretical aspects of these processes have not been fully elucidated. Current therapeutic interventions using nutritional and pharmaceutical treatments show a modest therapeutic efficacy; however, only physical exercise is recommended as the first-line therapy for sarcopenia, which can ameliorate skeletal muscle deficiency by maintaining the homeostatic MQC. In this review, we summarized the known mechanisms that contribute to the pathogenesis of sarcopenia by impairing normal mitochondrial functions and described potential interventions that mitigate sarcopenia through improving MQC.

Impact of adiposity on clinical outcomes in people living with a Fontan circulation

BackgroundTo assess the association between body composition and the risk of adverse outcomes in Fontan patients. MethodsParticipants from the Australian and New Zealand Fontan Registry with dual-energy X-ray absorptiometry scans were included. Appendicular lean mass (ALM), appendicular lean mass index (ALM divided by height squared; ALMI) and total body fat mass percentage (%BF) were calculated. ALMI and %BF z-scores were derived using age- and sex-matched reference ranges. The primary outcome was Fontan failure (death, transplantation, New York Heart Association functional class III/IV, protein-losing enteropathy, and plastic bronchitis) or moderate-or-severe ventricular dysfunction. Results144 patients were included. Mean %BF was 29% (SD 10) with 50% having increased adiposity. Mean ALMI z-score was −1.4 (SD 1.1); one third of patients had skeletal muscle deficiency (ALMI z-score < −1 and −2) and another third had Fontan-associated myopaenia (ALMI z-score < −2). Age and %BF were associated with the risk of the endpoint in univariable regression (age: HR 1.09 per year, 95% CI 1.02–1.17, p = 0.01; %BF: HR 1.08, 95% CI 1.01–1.17, p = 0.03). On multivariable regression, every 1% increase in %BF was associated with a 10% increased risk of reaching the clinical endpoint (HR 1.10, 95% CI 1.01–1.19; p = 0.03). ALM was not associated with the endpoint (HR 1.02 per kg, 95% CI 0.88–1.20, p = 0.77). ConclusionsIncreased adiposity is associated with higher risk for adverse outcomes. Prospective studies to assess lifestyle interventions to optimise body composition should be prioritised.

Abstract 13382: Increased Adiposity is Associated With Risk of Adverse Clinical Events in Fontan Patients

Introduction: Increased adiposity and reduced lean mass are prevalent in Fontan patients and could be impactful because of the reliance on the peripheral muscle pump and the importance of favourable pulmonary physiology in univentricular physiology. The current study aimed to determine the impact of body fat and lean mass on the risk of adverse outcomes in Fontan patients. Methods: Patients with dual-energy X-ray absorptiometry (DXA) scans from the Australian and New Zealand Fontan Registry were included; they had been consecutively recruited for 2 previous cohort studies. Regression analysis was used to characterize the association between body composition and the composite endpoint of Fontan failure (which included death, transplantation, New York Heart Association (NYHA) functional class III/IV, protein-losing enteropathy, and plastic bronchitis) and development of moderate or worse ventricular dysfunction. Results: 131 DXA scans were analyzed, with mean follow-up of 2.5 (SD 2.2) years after DXA. Mean body fat percentage (%BF) was 29% (SD 10) with 48% having increased adiposity compared with local reference data. Mean appendicular lean mass index (ALMI) z-score was -1.5 (SD 1.1); one third of patients had skeletal muscle deficiency (defined as ALMI z-score between -1 and -2) and another third had Fontan-associated myopenia (defined as ALMI z-score &amp;lt -2). Nine patients reached the composite endpoint during the follow-up period. Age and %BF were predictors of the endpoint in univariable regression (age: HR 1.09 per year, 95% CI 1.02-1.17, p = 0.01; %BF: HR 1.08, 95% CI 1.01-1.17, p = 0.03). On multivariable regression, %BF remained a significant predictor with every 1% increase conferring an 9% increased risk (HR 1.09, 95% CI 1.00-1.19; p = 0.045). ALMI was not a predictor of the endpoint (HR 1.40, 95% CI 0.71-2.76, p = 0.33). However, all patients who experienced a Fontan failure event (n=4) concurrently had increased adiposity and skeletal muscle deficiency. Conclusions: Increased adiposity is associated with increased risk for adverse clinical outcomes. Appropriate lifestyle interventions to optimise body composition should be an important aspect of routine care in this population.

Mitochondrial dysfunction in skeletal muscle of fukutin-deficient mice is resistant to exercise- and 5-aminoimidazole-4-carboxamide ribonucleotide-induced rescue.

What is the central question of this study? Does fukutin deficiency in skeletal muscle cause mitochondrial dysfunction, and if so, can AMP-activated protein kinase (AMPK) stimulation via 5-aminoimidazole-4-carboxamide ribonucleotide attenuate this through regulation of mitochondrial biogenesis and autophagy? What is the main finding and its importance? Mitochondrial dysfunction is associated with fukutin deficiency and AMPK stimulation may benefit muscle contractility to a greater extent than mitochondrial function. Disruptions in the dystrophin-glycoprotein complex (DGC) are clearly the primary basis underlying various forms of muscular dystrophies and dystroglycanopathies, but the cellular consequences of DGC disruption are still being investigated. Mitochondrial abnormalities are becoming an apparent consequence and contributor to dystrophy disease pathology. Herein, we demonstrate that muscle-specific deletion of the fukutin gene (Myf5/fktn-KO mice (Fktn KO)), a model of secondary dystroglycanopathy, results in ∼30% lower muscle strength (P<0.001) and 16% lower mitochondrial respiratory function (P=0.002) compared to healthy littermate controls (LM). We also observed ∼80% lower expression of the gene for peroxisome proliferator-activated receptor-γ coactivator 1α (PGC-1α) (P=0.004), a primary transcription factor for mitochondrial biogenesis, in Fktn KO mice that likely contributes to the mitochondrial defects. PGC-1α is post-translationally regulated via phosphorylation by AMP-activated protein kinase (AMPK). Treatment with the AMPK agonist 5-aminoimidazole-4-carboxamide ribonucleotide (AICAR) failed to rescue mitochondrial deficits in Fktn KO mice (P=0.458) but did have beneficial (∼30% greater) effects on recovery of muscle contractility following injury in both LM and Fktn KO mice compared to saline treatment (P=0.006). The beneficial effects of AMPK stimulation via AICAR on muscle contractile function may be partially explained by AMPK's other role of regulating skeletal muscle autophagy, a cellular process critical for clearance of damaged and/or dysfunctional organelles. Two primary conclusions can be drawn from this data: (1) fukutin deletion produces intrinsic muscular metabolic defects that likely contribute to dystroglycanopathy disease pathology, and (2) AICAR treatment accelerates recovery of muscle contractile function following injury suggesting AMPK signalling as a possible target for therapeutic strategies.