The effects of tributyrin and butyrate on equine skeletal muscle

Gonzalez, Madison Louise

02 September 2022

In the equine industry, there is a need for supplements that can improve performance and muscle recovery. Tributyrin and butyrate affect satellite cells and oxidative metabolism in other species. To assess the effects of tributyrin on equine muscle repair, Thoroughbred horses were supplemented tributyrin, and a submaximal exercise test was performed. RNA isolated from the gluteal muscle of horses supplemented with tributyrin had increased myogenin mRNA. Satellite cells isolated from supplemented horses had a higher percentage of proliferating cell nuclear antigen immunopositive cells, indicating tributyrin primed satellite cells to activate. Another experiment was performed to test the effects of tributyrin supplementation on equine muscle metabolism. Horses were fed tributyrin for 30 days while partaking in light exercise training. After the supplementation period, horses performed an exhaustive exercise test. Tributyrin supplementation did not affect performance or measures of oxidative metabolism in the muscle. To measure the effects of butyrate on equine muscle metabolism, Thoroughbred horses were supplemented butyrate for 30 days. At the end of supplementation gluteal muscle from butyrate fed horses had a higher percentage of type IIA fibers. Tributyrin supplementation demonstrated positive effects on satellite cell activation, but failed to increase oxidative metabolism measures. Butyrate did statistically increase the percentage of type IIA fibers, but not oxidative enzyme activity and the modest increase seen would likely not effect performance. Higher doses and longer supplementation of butyrate and tributyrin should be investigated to see if a metabolic shift beneficial to racehorses can be achieved. Furthermore, future research should focus on tributyrin's effects on satellite cells and how supplementation can improve muscle recovery in racehorses. / Doctor of Philosophy / Thoroughbred racehorses take part in strenuous races that result in exercise induced damage to the muscle. In turn, this resulting damage to the muscle must be properly repaired before the horse can successfully race again. My projects involved finding nutritional supplements to improve equine muscle repair or metabolism. A special cell in the muscle, called a satellite cell is responsible for repairing this muscle damage. Unlike other muscle nuclei, satellite cells have the ability to divide, providing more myonuclei, able to fuse into muscle fibers for repair. In an un-damaged state, satellite cells are lying dormant in the muscle. However, upon stimulus, satellite cells leave their dormant state and become activated. Along with muscle damage, a lot of energy is used during a race. There are two main ways that energy can be made, either without oxygen (anerobic) or with oxygen (aerobic). Aerobic metabolism is able to produce more energy and is fatigue resistant. I supplemented Thoroughbred horse's diet's with two products, butyrate or tributyrin to test their effects on equine satellite cells and muscle metabolism. Ultimately, my research found that tributyrin was able to stimulate equine satellite cells activate after exercise. I also found that butyrate supplementation increased the percentage of aerobic muscle fibers.

exercise

skeletal muscle

equine

satellite cell

AMP-activated protein kinase and muscle metabolism

Scheffler, Tracy L.

08 August 2012

AMP-activated protein kinase (AMPK) is a major regulator of skeletal muscle metabolism with relevance to agriculture and human health. During the conversion of muscle to meat, the rate and extent of postmortem metabolism and pH decline largely determine pork quality development. Pigs with the AMPKγ3 R200Q mutation generate pork with low ultimate pH (pHu); this is attributed to high glycogen content, and greater "potential" to produce lactate and H+. We hypothesized that decreasing muscle phosphocreatine and creatine would decrease ATP buffering capacity, resulting in earlier termination of glycolysis and pH decline. Dietary supplementation with the creatine analogue, β-GPA, decreased muscle total creatine but negatively affected performance. Another experiment was conducted using control or β-GPA diet and wild type and AMPKγ3R200Q pigs in a 2Ã 2 factorial design. The loss of muscle total creatine was important in maintenance of ATP levels in AMPKγ3R200Q muscle early postmortem. Moreover, elevated glycogen did not affect pHu, supporting that energetic modifications induced by feed restriction and β-GPA supplementation influence extent of pH decline. Next, we utilized a line of pigs selected for differences in pHu. Another AMPKγ3 mutation (V199I), which is associated with higher pHu and lower glycolytic potential, was prevalent. The 199II genotype increased pHu in castrated males only. The wild type VV genotype increased glycolytic potential, but neither glycolytic potential nor lactate predicted pHu. In humans, AMPK activation is at least partly responsible for the beneficial effects of exercise on glucose transport and increased oxidative capacity in skeletal muscle. An inverse relationship exists between skeletal muscle fiber cross-sectional area and oxidative capacity, which suggests muscle fibers hypertrophy at the expense of oxidative capacity. Therefore, we utilized pigs possessing mutations associated with increased oxidative capacity (AMP-activated protein kinase, AMPKγ3R200Q) or fiber hypertrophy (ryanodine receptor 1, RyR1R615C) to determine if these events occur in parallel. RyR1R615C increased muscle fiber size; AMPKγ3R200Q increased oxidative capacity, evidenced by enhanced enzyme activity, mitochondrial function, and expression of mitochondrial proteins. Thus, pigs with both AMPKγ3R200Q and RyR1R615C possess increased fiber size and oxidative capacity, suggesting hypertrophy and oxidative capacity can occur simultaneously in skeletal muscle. / Ph. D.

calcium

mitochondria

pork quality

skeletal muscle

The effects of fatigue on glycogen, glycogen phosphorylase, and calcium uptake associated with the sarcoplasmic reticulum of rat skeletal muscle

Lees, Simon J.

06 November 2000

Skeletal muscle fatigue can be defined as the inability to produce a desired amount of force. Fatigue can not only limit athletic performance and rehabilitation, but it can affect one's ability to perform every day activity as well. Despite extensive investigation of muscle fatigue, little is known about the exact mechanisms that result in decreased muscle performance. It likely involves several factors that are themselves dependent upon activation patterns and intensity. The process of excitation-contraction (EC) coupling is of particular importance with respect to regulation of force production. The release of calcium (Ca²⁺) from the sarcoplasmic reticulum (SR), which is stimulated by the depolarization of the sarcolemma, causes muscle contraction. The SR Ca²⁺-adenosine triphosphatase (ATPase) drives the translocation of two Ca²⁺ ions into the SR, utilizing the energy derived from the hydrolysis of one adenosine triphosphate (ATP) molecule. The process of SR Ca²⁺ uptake causes muscle relaxation. It has been proposed that both glycogen and glycolytic enzymes are associated with the SR membrane (SR-glycogenolytic complex). Interestingly, glycogen phosphorylase, an enzyme involved in glycogen breakdown, seems to be associated with the SR-glycogenolytic complex through its binding to glycogen. The presence of the SR-glycogenolytic system may serve to locally regenerate ATP utilized by the SR Ca²⁺-ATPase. The purpose of the present study was to investigate the effects of prolonged muscle contraction on glycogen concentration, glycogen phosphorylase content and activity, and maximum Ca²⁺ uptake rate associated with the SR. Tetanic contractions, elicited once per second for 15 minutes, significantly reduced glycogen associated with SR to 5.1% of control from 401.17 ± 79.81 to 20.46 ± 2.16 mg/mg SR protein (£ 0.05). The optical density of glycogen phosphorylase from SDS-PAGE was significantly reduced to 21.2% of control (£ 0.05). Activity of glycogen phosphorylase, in the direction of glycogen breakdown, was significantly reduced to 4.1% of control (£ 0.05). Pyridoxal 5'-phosphate (PLP) concentration, a quantitative indicator of glycogen phosphorylase content, was significantly reduced to 3.3% of control (£ 0.05). Maximum SR Ca²⁺ uptake rates were significantly reduced to 80.8% of control (£ 0.05). These data suggest reduced glycogen and glycogen phosphorylase may be involved, either directly or indirectly, in a mechanism that causes decreased SR Ca²⁺ uptake normally found in fatigue. / Master of Science

skeletal muscle

sarcoplasmic reticulum

Fatigue

calcium uptake

Creation and Characterization of Several Polymer/Conductive Element Composite Scaffolds for Skeletal Muscle Tissue Engineering

Fischer, Kristin Mckeon

20 April 2012

After skeletal muscle damage, satellite cells move towards the injured area to assist in regeneration. However, these cells are rare as their numbers depend on the age and composition of the injured muscle. This regeneration method often results in scar tissue formation along with loss of function. Although several treatment methods have been investigated, no muscle replacement treatment currently exists. Tissue engineering attempts to create, repair, and/or replace damaged tissue by combining cells, biomaterials, and tissue-inducing substances such as growth factors. Electrospinning produces a non-woven scaffold out of biomaterials with fiber diameters ranging from nanometers to microns to create an extracellular-like matrix on which cells attach and proliferate. Our focus is on synthetic polymers, specifically poly(D,L-lactide) (PDLA), poly(L-lactide) (PLLA), and poly(ε-caprolactone) (PCL). Skeletal muscle cells grown on electrospun scaffolds tend to elongate and fuse together thus, mimicking natural tissue. Electrical stimulation has been shown to increase the number of cells fused in culture and decreased the time needed in culture for cells to contract. Therefore, a conductive element was added to each scaffold, specifically polyaniline (PANi), gold nanoparticles (Au Nps), and multi-walled carbon nanotubes (MWCNT). Our project goal is to create a polymeric, conductive, and biocompatible scaffold for skeletal muscle regeneration. PANi and PDLA were mixed to form the following solutions 24% (83% PDLA/17% PANi), 24% (80% PDLA/20% PANi), 22% (75%PDLA/25% PANi), 29% (83% PDLA/17% PANi), and 29% (80% PDLA/20% PANi). Only the 75/25 electrospun scaffold was conductive and had a calculated conductivity of 0.0437 S/cm. Scaffolds with larger amounts of PANi were unable to be electrospun. PDLA/PANi scaffolds were biocompatible as primary rat skeletal muscle cells cultured in vitro did attach. However, the scaffolds shrunk, degraded easily, and became brittle. Although PDLA/PANi scaffolds were easily manufactured, our results indicate that this polymer mixture is not appropriate for skeletal muscle scaffolds. PLLA and Au Nps were electrospun together to form three composite scaffolds: 7% Au-PLLA, 13% Au-PLLA, and 21% Au-PLLA. These were compared to PLLA electrospun scaffolds. Measured scaffold conductivities were 0.008 ± 0.015 S/cm for PLLA, 0.053 ± 0.015 S/cm for 7% Au-PLLA, 0.076 ± 0.004 S/cm for 13% Au-PLLA, and 0.094 ± 0.037 S/cm for 21% Au-PLLA. It was determined via SEM with a Bruker energy dispersive x-ray spectrometer (EDS) that the Au Nps were not evenly distributed within the scaffolds as they had agglomerated. Rat primary muscle cells cultured on the three Au-PLLA scaffolds displayed low cellular activity. A second cell study was conducted to determine Au NPs toxicity. The results show that the Au Nps were not toxic to the cells and the low cellular activity may be a marker for myotube fusion. Elastic modulus and yield stress values for the three Au-PLLA scaffolds measured on days 0, 7, 14, 21, and 28 were much larger than skeletal muscle tissue. Due to the larger mechanical properties and Au Nps agglomeration, a third polymer and conductive element scaffold was investigated. PCL was chosen as the new synthetic polymer as it had a lower elastic modulus and high elongation. MWCNT were chosen as the conductive element as they disperse well within PCL when acid functionalized. A third component was added to the scaffold to help it move similar to skeletal muscle. Ionic polymer gels (IPG) are hydrogels that respond to an external stimulus such as temperature, pH, light, and electric field. A poly(acrylic acid)/poly(vinyl alcohol) (PAA/PVA) mixture is one type of IGP that responds to an electric field. The scaffolds were coaxially electrospun so that each fiber had a PCL-MWCNT interior with a PAA/PVA sheath. These scaffolds were compared to electrospun PCL and PCL-MWCNT ones. The addition of MWCNT to the PCL did increase scaffold conductivity. Actuation of the PCL-MWCNT-PAA/PVA scaffold occurred when 15V and 20V were applied. All three scaffolds had rat primary skeletal muscle cells attached but, more multinucleated cells with actin interaction were seen on PCL-MWCNT-PAA/PVA scaffolds. Once again the mechanical properties were greater than muscle, but because of its ability to actuate we believe the PCL-MWCNT-PAA/PVA scaffold has potential as a bioartificial muscle. Further characterization of the PCL-MWCNT-PAA/PVA included varying the ratios of PAA/PVA, smaller crosslinking times, and lower amounts of MWCNT. Four ratios, 83/17, 60/40, 50/50, and 40/60, were successfully coaxially electrospun with PCL and MWCNT. Overall, very few differences were seen between the four ratios in conductivity, cellular biocompatibility, actuation angular speed, and mechanical properties. The 83/17 and 40/60 ratios were chosen for additional investigation into mechanical properties and actuation. As the mechanical properties of the two types of scaffolds did not change significantly through degradation, lower PVA crosslinking times were tested. No significant effects were found and it was hypothesized that the evaporation of the solution played a role in the crosslinking process. The smaller MWCNT amount scaffolds also did not significantly affect the mechanical properties or the actuation angular speeds. More work into lowering the scaffold mechanical properties while increasing the actuation angular speed is necessary. Though the mechanical properties for the 83/17 and 40/60 scaffolds remained high compared to skeletal muscle, we also looked for differences in in vivo biocompatibility. Both scaffolds were implanted into the right vastus lateralis muscle of Sprague-Dawley rats. The left vastus lateralis muscle served as either the PBS injected sham surgery or an unoperated control. Biocompatibility was evaluated using enzymes, creatine kinase (CK) and lactate dehydrogenase (LDH), levels, fibrosis formation, inflammation, scaffold cellular infiltration, and neovascularization on days 7, 14, 21, and 28 post-implantation. Fibrotic tissue formation, inflammation, and elevated CK and LDH levels were observed initially but responses decreased during the four week study. Cells infiltrated the scaffolds and histological staining showed more fibroblasts than myogenic cells initially but over time, the fibroblasts decreased and myogenic cells increased. Neovascularization of both scaffolds was also recorded. PCL-MWCNT-PAA/PVA scaffolds were determined to be biocompatible, but some differences between the two types were noted. The 83/17 scaffolds caused less of a response from the body compared to the 40/60 scaffolds and had more myogenic cells attached. However, the 40/60 scaffolds had a larger number of blood vessels running through the scaffold. In conclusion, we have successfully fabricated a polymeric, conductive, and biocompatible scaffold that can actuate for skeletal muscle tissue engineering. Although our results are promising, more work is necessary to continue developing and refining the scaffold. / Ph. D.

Biocompatibility

Actuation

Conductive

Scaffolds

Skeletal Muscle

The Effects of a 5-Day High-Fat Diet on Skeletal Muscle O-GlcNAcylation

Nealon, Lily Irene

06 July 2016

Continual intake of high-fat foods, coupled with limited physical activity, can lead to metabolic inflexibility. Eventually, this may lead to significant health issues such as obesity, insulin resistance, cardiovascular disease, and other chronic diseases. Metabolic flexibility of human skeletal muscles is influenced by changes to mitochondrial, nuclear, and cytosolic proteins, in part as a result of posttranslational modifications (PTMs). O-linked B-D-N-acetylglucosamine, known as O-GlcNAc, has recently been identified as an important posttranslational modification that responds to nutrient sensing and cellular stress. Unlike other PTMs, O-GlcNAc has only two cycling enzymes. Because of its novelty, little research has been performed on the role of O-GlcNAc in human skeletal muscle and metabolic flexibility. The purpose of the current study was to establish the effects of a 5-day high-fat diet on skeletal muscle O-GlcNAcylation. In the proposed study, 13 non-obese, sedentary, college-aged males consumed a controlled diet for two weeks followed by a high-fat diet composed of 55% fat, 30% carbohydrate, and 15% protein. Muscle biopsies were taken from the vastus lateralis both fasted and four hours after a high-fat meal, following both the control diet and the high-fat diet. Western blot analysis was used to assess global O-GlcNAc and protein concentrations of O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA) in whole-homogenates and isolated mitochondria from skeletal muscle. Results were analyzed using independent, two-tailed t-tests and 2-way ANOVA analysis with repeated measures and Bonferroni corrections; a p-value was set to α less than or equal to 0.05. It was found that O-GlcNAc and OGT levels remained stable, although fasting levels of OGA significantly decreased after the 5-day high-fat diet. It is possible that healthy individuals are capable of maintaining normal levels of O-GlcNAc and its cycling enzymes, but there is still more to learn about O-GlcNAc and its role in metabolic flexibility. / Master of Science

O-GlcNAc

skeletal muscle metabolism

Nutrition

physiology

The Effects of Resistance Wheel Running on Skeletal Muscle Function and Adaptation in C57BL/10SnJ Mice

Rodden, Gregory Robert

21 July 2015

Background: Resistance wheel running (RWR) can promote resistance-like training adaptations in mouse skeletal muscle (SkM), but its endurance-training effects are lesser known. Methods: Voluntary RWR was modulated as an exercise model to increase mouse hind-limb plantar-flexor torque and to promote endurance-training adaptations. Thirty male mice (cohort 1, n= 16; cohort 2, n= 14), were trained on a prototype RWR system that applied resistance relative to body mass (BM). Mice were sequentially, (1) screened for running ability (screening; 3-days); (2) trained with incremental adjustments to wheel loads (pre-training; 8-weeks); (3) grouped into cage-activity only (CA), and constant Low-0%, Med-15%, or High-25% BM resistance conditions (static training; 5-weeks); (4) trained with resistance adjusted in real-time (dynamic training; cohort 1, 7-weeks; cohort 2, 10-weeks); and (5) sacrificed for various assays. Plantar-flexor torque was determined during each training phase. After dynamic training, resistance runners in each cohort were sub-grouped post-hoc by work tertiles. Results: Wheel running distance varied between cohorts (cohort 2 > 1). During dynamic training, wheel running (±added-resistance) improved plantar flexor torque normalized to BM by 19% only in cohort 2 (p= 0.007). Muscle mass and cross-sectional area were unchanged. Runners in both cohorts (±added-resistance) improved maximal running capacity vs. CA-controls (+69% and +115%; both p < 0.05), but metabolic training adaptations were less evident. Conclusions: Wheel running promoted SkM strength and endurance, but there was a greater increase in endurance capacity than strength. This outcome may be due to adaptive signaling interference. / Master of Science

Exercise

Resistance Wheel Running

Skeletal Muscle

Hypertrophy

The Role of Angiotensin II in Skeletal Muscle Metabolism

Wahlberg, Kristin

13 June 2011

Hypertension and diabetes have long been closely linked. As such, the major player in the renin, angiotensin system, angiotensin II, has recently been investigated for its effects on metabolism and diabetes. Since skeletal muscle is one of the most metabolically active tissues, this study investigates the effects of angiotensin II specifically on skeletal muscle. In this study, L6 skeletal muscle cells were treated with angiotensin II for either 3 or 24 hours and a number of effects were investigated. Fatty acid oxidation and lipid synthesis was measured using [1-14C]-palmitate, glucose oxidation and glycogen synthesis were measured using 14C-glucose. In addition,mitochondrial oxidative capacity was measured using an XF 24 Flux Analyzer (Seahorse Bioscience) and reactive oxygen species measured using confocal microscopy. The clinical study involving the drug Benicar ® investigated the metabolic effects of blocking angiotensin II on skeletal muscle fatty acid oxidation, glucose oxidation, and oxidative and glycolytic enzyme activity. In L6 cells, angiotensin II significantly reduced fatty acid oxidation after 24 hours (p<0.01) and 3 hours (p<0.001) if angiotensin II was present during oxidation experiments. It also significantly reduced mitochondrial oxidative capacity (p<0.05) after 24 hours and significantly increased reactive oxygen species production (p<0.05) over 3 hours. The clinical study showed no significant effects of Benicar® on fatty acid or glucose oxidation or any enzyme activities. / Master of Science

ROS

Oxidation

skeletal muscle

angiotensin II

The Metabolic Effects of Low Grade Inflammation on Postprandial Metabolism Following a High Fat Meal

Pittman, Joshua Taylor

28 August 2013

Inflammation is a central feature of various metabolic diseases including obesity and type-II diabetes. For this study, we hypothesized postprandial metabolism following an acute, high fat (HF) meal to be impaired in mice pre-injected with an inflammatory agonist. To this end, C57BL/6J mice were injected with saline or lipopolysaccharide (LPS, 1μg/kgbw) following an overnight fast and gavaged 2hr post-injection with water or a HF meal in liquid form (5kcal; 21.4%SF, 40.8%UF, 27.1%CHO, 10.7%PRO). Blood and muscle samples taken 3hr post-gavage underwent ex vivo analysis. Overall, results demonstrated a metabolic response to a HF meal that was blocked in the presence of LPS. Metabolic flexibility, though unchanged following the HF meal alone, was reduced following the HF meal in the presence of LPS. Additionally, state-4 uncoupled mitochondrial respiration, which was increased following the HF meal, was also reduced following the HF meal in the presence of LPS. Similar near-significant trends were also observed with total palmitate oxidation. Although no independent response to a HF meal or LPS exposure was observed, a unique interaction between treatments significantly diminished ADP dependent, state-3 and maximal respiration. These effects do not appear to be dependent on the production of reactive oxygen species (ROS) since neither the HF meal nor LPS exposure resulted in increased production of ROS. In conclusion, these results demonstrate that acute activation of inflammatory pathways results in alterations in metabolic response to a HF meal in skeletal muscle from mice, although the mechanism underlying these effects is not yet understood. / Master of Science

Metabolic flexibility

inflammation

skeletal muscle

mitochondria

Skeletal Muscle Adaption to 5 days of High-Fat Feeding in Humans

Hayes, Jasmine Marie

20 September 2018

Skeletal muscle is highly involved in macronutrient metabolism. To maintain proper energy metabolism and physiology, skeletal muscle must adapt to nutrient supply. Thus, diet macronutrient composition is an important modulator of skeletal muscle metabolism. Evidence from rodent and human models show high-fat diets contribute to impaired insulin signaling, as well as decreased fatty acid and glucose oxidation. Utilizing proteomic analysis of metabolic proteins in humans may lead to the mechanism behind skeletal muscle adaption to macronutrient composition, potentially providing the groundwork for characterizing the etiology of high-fat feeding induced metabolic disease. The objective of this study was to compare the substrate oxidation patterns and the levels of metabolic proteins in the fasted skeletal muscle of lean, healthy males that either increased fatty acid oxidation in response to the high-fat diet, termed responders, or males that decreased fatty acid oxidation, termed non-responders. We employed a controlled feeding study design, where the participants served as their own controls. Following a 2-week control diet (30% fat, 55% carbohydrate and 15% protein), participants came to the lab fasted overnight and a muscle biopsy was taken from their vastus lateralis muscle. Participants were then placed on a 5-day high-fat diet (50% fat [45% saturated fat], 35% carbohydrate, and 15% protein). Following this diet, participants again came to the lab fasted overnight and another muscle biopsy was taken from their vastus lateralis muscle. Both the control and the high-fat diets were isocaloric to habitual diets. Muscle from the biopsies were utilized for substrate metabolism measures and mass spectrometry. We did not observe any significant differences in glucose oxidation between responders and non-responders, prior to or following the high-fat diet. Our proteomic analysis identified 81 proteins and protein subunits involved in substrate metabolism but only 6 were differentially regulated by the high-fat diet. Independent of the high-fat diet, compared to non-responders, responders contained an overall higher content of protein subunits belonging to Complex I and ATP synthase. The findings from this study suggest that adaption to high-fat feeding is individual specific and proteomic changes alone cannot explain high-fat feeding induced metabolic changes. / Ph. D. / Skeletal muscle is highly involved in macronutrient metabolism, which consist of the breakdown and utilization of glucose and fatty acids, thus making the foods we ingest a major modulator of skeletal muscle metabolism. Over the last few decades, Americans have increased their ingestion of foods high in saturated fats, which has coincided with the increased prevalence of obesity and type 2 diabetes. Further, evidence suggests these metabolic diseases are associated with the skeletal muscle’s inability to switch between the utilization of glucose and fatty acid in response to nutrient supply. Analyzing metabolic protein content in humans may lead to the mechanism behind skeletal muscle adaption to macronutrient composition, potentially leading to the cause behind the development of high-fat feeding induced metabolic disease. The objective of our controlled feeding study was to compare the macronutrient metabolism and the content of metabolic proteins in the fasted skeletal muscle of healthy males that either increased fatty acid utilization in response to a high-fat diet, termed responders, or males that decreased fatty acid utilization, termed non-responders. Following a 2-week control diet (30% fat, 55% carbohydrate and 15% protein), participants came to the lab fasted overnight and a biopsy was taken from their thigh muscle called the vastus lateralis. Participants then began a 5-day high-fat diet (50% fat [45% saturated fat], 35% carbohydrate, and 15% protein). Following this diet, participants came to the lab fasted overnight and another biopsy was taken from their vastus lateralis muscle. Both the control and the high-fat diets were isocaloric to habitual diets. The muscle samples were used to analyze macronutrient metabolism and identify metabolic protein content. We did not observe differences in glucose utilization between responders and non-responders, prior to or following the high-fat diet. We identified 81 metabolic proteins and protein subunits but only 6 were differentially regulated by the high-fat diet. Independent of diet, responders contained higher levels of subunits from 2 proteins involved in cell energy production, Complex I and ATP synthase. Our findings suggest that adaption to high-fat feeding is individual specific and protein content changes alone cannot explain high-fat feeding induced metabolic changes.

High-fat diet

metabolism

skeletal muscle

The role of Lynx1, an endogenous modulator of cholinergic transmission, in NMJ development, maintenance, and repair

Vaughan, Sydney Katherine

08 May 2019

The cholinergic system drives muscle contraction and plays a central role in the formation, maintenance, and repair of mammalian neuromuscular junctions (NMJs) and skeletal muscles. Because of these essential actions, much effort has been devoted to identifying primary and auxiliary modulatory components of the cholinergic system at NMJs and throughout skeletal muscles. Here, I asked if Lynx1, a GPI-anchored protein shown to modulate nAChRs in the brain, is present and affects the activity of nAChRs at NMJs. Molecular and cellular analysis revealed that Lynx1 levels increase in skeletal muscles, specifically at NMJs, during development. Its expression pattern also closely mirrors changes in cholinergic transmission in vivo and in vitro. As expected, I found by co-immunoprecipitation that Lynx1 interacts with muscle nAChRs and using electrophysiology, I show that Lynx1 desensitizes nAChRs to ACh at NMJs. These findings demonstrate that Lynx1 regulates the cholinergic system at NMJs, suggesting roles for this gene in developing and adult NMJs. To determine the role of Lynx1 at NMJs, I examined Lynx1 knockout mice at different ages. While deletion of Lynx1 has no discernable effect on developing NMJs, its absence increases the incidence of NMJs with age-related morphological features, such as fragmentation and denervation, in young adult and middle-aged mice. Loss of Lynx1 also increases the number of slow-type muscle fibers in young and middle-aged mice, another hallmark of aging. Along with these morphological changes, deletion of Lynx1 affects expression of genes associated with NMJ stability, myogenesis, and muscle atrophy in young adult and middle-aged mice. Not surprisingly, the loss of Lynx1 reduces the density and stability of nAChRs at NMJs. Because of these findings, I surmised that loss of Lynx1 would adversely affect NMJs under other physiological stressors. However, I found the opposite as the loss of Lynx1 augments the capacity of NMJs to repair damages during exercise, following injury to motor axons, and during the initial symptomatic stage of amyotrophic lateral sclerosis (ALS). Since Lynx1 modulates the activity of nAChRs, these contrasting findings likely represent the positive and negative effects of heightened cholinergic transmission on aging compared to injury and disease-afflicted NMJs. / Doctor of Philosophy / During normal aging and in neuromuscular diseases, such as amyotrophic lateral sclerosis (ALS), voluntary movement becomes compromised. This is largely due to deterioration of the synapse between motor neurons and skeletal muscles, called the neuromuscular junction (NMJ), which is responsible for voluntary movement. Signaling at the NMJ is driven by cholinergic transmission, which when dysregulated can directly result in degeneration of the NMJ, similar to that seen in both aging and ALS. Thus, it is critical to maintain proper cholinergic transmission for preservation of the NMJ. For the first time, I have characterized the role of an endogenous protein, Lynx1, in modulating cholinergic transmission at the NMJ. Lynx1 functions to dampen cholinergic activity to prevent muscles from becoming overwhelmed and fatigued. The work outlined in this dissertation proposes Lynx1 as a novel therapeutic candidate for preventing neuromuscular degeneration in conditions associated with dysregulated cholinergic transmission, such as ALS.

skeletal muscle

acetylcholine

plasticity

Aging

ALS