Zebrafish embryos exposed to alcohol undergo abnormal development of motor neurons and muscle fibers

Sylvain, Nicole J.

11 1900

Children with Fetal Alcohol Spectrum Disorder have significantly delayed motor skills, and deficiencies in reflex development. The reasons underlying these motor deficits are not fully understood. The purpose of this thesis was to investigate the effect of embryonic exposure to ethanol (EtOH) on motor neuron and muscle fiber morphology and physiology in zebrafish. We observed that EtOH-exposed fish took longer to hatch and exhibited fewer swimming bouts in response to touch. Immunolabelling of motor neurons indicated that EtOH-exposed fish had significantly higher rates of motor neuron axon defects. Examination of muscle fiber morphology revealed that EtOH exposure resulted in significantly smaller muscle fibers. Miniature endplate current (mEPC) recordings from muscle fibers revealed that event amplitudes, rise times, half widths, frequencies and decay times were affected by EtOH exposure. These findings indicate that motor neurons and muscle fibers of zebrafish are affected by embryonic EtOH exposure, which may be related to deficits in locomotion. / Physiology, Cell and Developmental biology

ethanol

zebrafish

Fetal Alcohol Syndrome

motor neurons

skeletal muscle

mEPC recordings

alcohol

Muscle Thixotropy : Implications for Human Motor Control

Axelson, Hans

January 2005

Human skeletal muscles possess thixotropic, i.e. history-dependent mechanical properties. This means that the degree of passive muscle stiffness and resting tension is dependent on the immediately preceding history of contractions and length changes. Athletes, for instance, reduce passive muscle stiffness by various types of ‘limbering-up’ procedures, whereas muscle stiffness gradually increases during inactivity. Passive resistance of antagonistic muscles may significantly add to the total load during voluntary muscle contractions. This resistance may vary from one moment to another, depending on immediately preceding events. This research was conducted to determine whether history-dependent variations in passive muscular forces influence motor control of voluntary joint movements and steady maintenance of joint positions in healthy subjects. In study I, the EMG signal revealed motor compensations for history-dependent variations in passive stiffness of the antagonists during slow voluntary wrist joint movements. Studies II and III demonstrated that the voluntary muscle activity required to maintain a certain wrist joint position was highly influenced by previous changes in forearm muscle length and contractions. Study IV showed that rapid voluntary movements varied in speed and onset time depending on the prevailing degree of muscle resistance, and in addition that the central nervous reaction time required to execute rapid movements was highly influenced by immediately preceding muscle-conditioning procedures. History-dependent variations in passive muscular forces seem to be effectively compensated by the motor control system. Presumably, voluntary motor commands to the muscles are automatically adjusted in strength to history-dependent changes in passive muscular forces. Such adjustments occur within the central nervous system, which receives information about the mechanical state of the muscles. Several issues in connection with muscle thixotropy remain unaddressed. For instance, do alterations in the normal thixotropic mechanical behaviour of the muscles impose a particular problem in patients with certain neuromuscular diseases?

Neurosciences

Motor control

Skeletal muscle

Thixotropy

History-dependent

EMG

Voluntary contractions

Neurovetenskap

Neurology

Neurologi

Ultrasonic Quantification of Skeletal Muscle Dynamics : Feasibility and Limitations

Lindberg, Frida

January 2013

Pain and disorders of the human skeletal muscles are one of the most common reasons for medical consultations in the western countries today and there is a great need to improve both the understanding and treatment of several different muscular conditions. Techniques describing the muscle function in vivo are often limited by either their invasiveness or lack of spatial resolution. Electromyography (EMG) is the most common approach to assess the skeletal muscle function in vivo, providing information on the neurological input. However, the spatial resolution is in general limited and there are difficulties reaching deep musculature without using invasive needles. Moreover, it does not provide any information about muscle structure or mechanical aspects. Quantitative ultrasound techniques have gained interest in the area of skeletal muscles and enables non-invasive and in-vivo insight to the intramuscular activity, through the mechanical response of the activation. However, these techniques are developed and evaluated for cardiovascular applications and there are important considerations to be made when applying these methods in the musculoskeletal field.  This thesis is based on the work from four papers with the main focus to investigate and describe some of these considerations in combination with the development of processing and analyzing methods that can be used to describe the physiological characteristics of active muscle tissue. In the first paper the accuracy of the Doppler based technique Tissue Velocity Imaging (TVI) was evaluated in a phantom study for very low tissue velocities and the effect of the pulse repetition frequency was considered. The second paper presents a biomechanical model to describe the TVI strain’s dependency on the muscle fiber pennation angle. In the third and fourth papers the intramuscular activity pattern was assessed through the regional tissue deformation by motion mode (M-mode) strain imaging. The activity patterns were analyzed during force regulation and for the effects of fatigue. The work of this thesis show promising results for the application of these methods on skeletal muscles and indicate high clinical potential where quantitative ultrasound may be a valuable tool to reach a more multifaceted and comprehensive insight in the musculoskeletal function. However, the methodological considerations are highly important for the optimized application and further evaluation and development of analyzing strategies are needed. / <p>QC 20130516</p>

ultrasound

skeletal muscle

intramuscular

dynamics

Tissue Doppler Imaging

Speckle Tracking

strain

quantification

The Role of XRCC1 in the Repair of DNA Strand Breaks in Skeletal Muscle Differentiation

Burns, Leanne E.

22 September 2011

Caspase-3 has demonstrated a non-apoptotic function in several developmental programs including skeletal muscle differentiation, yet the mechanism of action has not been fully elucidated. Under apoptotic conditions Caspase-3 induces DNA fragmentation through activation of CAD. Recent observations have demonstrated CAD activity and the resulting DNA strand breaks are also vital for skeletal muscle differentiation. These breaks are transient in nature, suggesting an active DNA repair program to maintain genomic integrity. The aim of this study was to delineate the DNA repair mechanism coordinated with caspase/CAD mediated DNA damage. It was found that XRCC1 formed punctate nuclear foci early in myoblast differentiation concurrent to the induction of DNA damage. Caspase-3 inhibition caused attenuation of the formation of DNA lesions and XRCC1 foci in differentiating myoblasts. Targeted reduction in XRCC1 expression impaired myoblast differentiation. These results suggest that XRCC1 may play a role in repairing the DNA damage associated with myoblast differentiation.

XRCC1

Caspase 3

Caspase activated DNase

differentiation

Skeletal muscle

DNA repair

Myocyte Androgen Receptor Modulates Body Composition and Metabolic Parameters

Fernando, Shannon M.

31 December 2010

Androgens (such as testosterone) have been shown to increase lean body mass and reduce fat body mass in men through activation of androgen receptors (AR). While this suggests a potential clinical use for androgens, attempts at utilization of this class of hormones as a therapeutic are limited by side effects due to indiscriminate AR activation in various tissues. Thus, a greater understanding of the tissues and cells involved in promoting these changes would be beneficial. Here we show that selective overexpression of AR in muscle cells of transgenic (HSA-AR) rodents both increases lean muscle mass and significantly reduces fat mass in males. Similar effects can be induced in HSA-AR females treated with testosterone. Metabolic analyses of HSA-AR males show that these animals demonstrate increased O2 consumption and hypermetabolism. Thus, targeted activation of AR in muscle regulates body composition and metabolism, suggesting a novel target for drug development.

endocrinology

metabolism

androgens

skeletal muscle

adipose tissue

transgenic

androgen receptor

testosterone

0719

0369

Myocyte Androgen Receptor Modulates Body Composition and Metabolic Parameters

Fernando, Shannon M.

31 December 2010

Androgens (such as testosterone) have been shown to increase lean body mass and reduce fat body mass in men through activation of androgen receptors (AR). While this suggests a potential clinical use for androgens, attempts at utilization of this class of hormones as a therapeutic are limited by side effects due to indiscriminate AR activation in various tissues. Thus, a greater understanding of the tissues and cells involved in promoting these changes would be beneficial. Here we show that selective overexpression of AR in muscle cells of transgenic (HSA-AR) rodents both increases lean muscle mass and significantly reduces fat mass in males. Similar effects can be induced in HSA-AR females treated with testosterone. Metabolic analyses of HSA-AR males show that these animals demonstrate increased O2 consumption and hypermetabolism. Thus, targeted activation of AR in muscle regulates body composition and metabolism, suggesting a novel target for drug development.

endocrinology

metabolism

androgens

skeletal muscle

adipose tissue

transgenic

androgen receptor

testosterone

0719

0369

Contribution of sarcoplasmic reticulum calcium pumping to resting mouse muscle metabolism

Norris, Sarah

January 2009

Few studies have quantified resting mouse muscle metabolism and even fewer studies have separated the contribution of sarcoplasmic reticulum (SR) Ca2+ pumping to resting metabolic rate. Furthermore, the studies that have attempted to quantify the contribution of Ca2+ pumping have used indirect methods to inhibit SR Ca2+ ATPase activity. The purpose of this study is to directly quantify resting muscle oxygen consumption and the contribution of SR Ca2+ pumping to resting oxygen consumption in mouse hindlimb muscles by using CPA to specifically inhibit Ca2+ pump activity in intact muscles at rest. The TIOX system was used to measure resting muscle VO2 of extensor digitorum longus (EDL) and soleus (SOL) muscles at 30oC and 20oC. C57BL mice aged 8-12 weeks were used with an average whole body mass of 23.8 g and EDL and SOL dry weights averaging 1.88 mg and 1.8 mg, respectively. All muscle VO2 measurements are expressed per gram dry weight. There were no differences (P>0.1) in resting muscle VO2 between EDL and SOL muscles at either 30oC (EDL, 2.05 µL/g/s; SOL, 2.27 µL/g/s) or 20oC (EDL, 0.62 µL/g/s; SOL, 0.71 µL/g/s). The average Q10 (3.1) was determined from EDL and SOL VO2 measures at 20oC and 30oC. The contribution of Ca2+ pumping by the sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA) was measured at 30oC using a range of CPA concentrations (1-15 µM) . There was a concentration-dependent effect of CPA on oxygen consumption with increasing CPA concentrations up to 10 µM resulting in progressively greater reductions in muscle oxygen consumption. Specifically, 1, 5, 10, and 15 µM CPA caused an 11, 35.4, 49.5, and 50.3% reduction in VO2. There were no differences (P>0.1) between 10 and 15 µM CPA indicating that 10 µM CPA induces maximal inhibition of SERCA in isolated muscle preparations. The results indicate that the Ca2+ pumping by SERCA is responsible for ~50% of oxygen consumption in resting mouse EDL and SOL muscle. This is the first study to use a direct inhibitor of SERCA to quantify the contribution of Ca2+ cycling to resting oxygen consumption and therefore is a more accurate reflection of the actual contribution of SERCA to resting muscle oxygen consumption compared to previous findings. These results suggest that SERCA energy consumption accounts for a large portion of resting muscle metabolism and may represent a potential therapeutic target for metabolic alterations to oppose obesity.

sarco(endo)plasmic reticulum Ca2+ ATPase

skeletal muscle oxygen consumption

Kinesiology

Methods and models for 2D and 3D image analysis in microscopy, in particular for the study of muscle cells / Metoder och modeller för två- och tredimensionell bildanalys inom mikroskopi, speciellt med inrikting mot muskelceller

Karlsson Edlund, Patrick

January 2008

Many research questions in biological research lead to numerous microscope images that need to be evaluated. Here digital image cytometry, i.e., quantitative, automated or semi-automated analysis of the images is an important rapidly growing discipline. This thesis presents contributions to that field. The work has been carried out in close cooperation with biomedical research partners, successfully solving real world problems. The world is 3D and modern imaging methods such as confocal microscopy provide 3D images. Hence, a large part of the work has dealt with the development of new and improved methods for quantitative analysis of 3D images, in particular fluorescently labeled skeletal muscle cells. A geometrical model for robust segmentation of skeletal muscle fibers was developed. Images of the multinucleated muscle cells were pre-processed using a novel spatially modulated transform, producing images with reduced complexity and facilitating easy nuclei segmentation. Fibers from several mammalian species were modeled and features were computed based on cell nuclei positions. Features such as myonuclear domain size and nearest neighbor distance, were shown to correlate with body mass, and femur length. Human muscle fibers from young and old males, and females, were related to fiber type and extracted features, where myonuclear domain size variations were shown to increase with age irrespectively of fiber type and gender. A segmentation method for severely clustered point-like signals was developed and applied to images of fluorescent probes, quantifying the amount and location of mitochondrial DNA within cells. A synthetic cell model was developed, to provide a controllable golden standard for performance evaluation of both expert manual and fully automated segmentations. The proposed method matches the correctness achieved by manual quantification. An interactive segmentation procedure was successfully applied to treated testicle sections of boar, showing how a common industrial plastic softener significantly affects testosterone concentrations.

medical image analysis

image segmentation

fluorescence microscopy

cytometry

human skeletal muscle

Persistent deep mechanical hyperalgesia induced by repeated cold stress in rats

Nasu, Teruaki, Taguchi, Toru, Mizumura, Kazue

03 1900

No description available.

Muscular mechanical hyperalgesia

Skeletal muscle

Repeated cold stress

Chronic muscle pain

Effects of high-fat feeding on skeletal muscle insulin signalling in sarcolipin knockout mice

Sayer, Ryan

18 August 2010

Type II diabetes mellitus (T2DM) has been associated with the onset of diet-induced obesity, which is currently on the rise worldwide. T2DM is typically characterized by insulin resistance in peripheral tissues such as adipose tissue, liver, and skeletal muscle. In skeletal muscle it is widely accepted that the defective insulin action is due to the inability of the cell to sufficiently activate the insulin signalling pathway and promote systemic glucose uptake. The sarcolipin-null (KO) mouse is a potential novel model for diet-induced obesity and diabetes. KO mice become significantly more obese and display a greater glucose intolerance than wildtype (WT) mice following an 8-week high-fat diet (HFD; 42% calories from fat) but the underlying mechanisms are still unknown. In this study the role of defective skeletal muscle insulin signalling in the development of the impaired glucose tolerance in KO mice was investigated. It was hypothesized that the HFD fed KO mice would exhibit greater reductions in IRS1 tyr628 and Akt ser473 phosphorylation (i.e. decreased activation of the insulin signalling pathway) than controls. Furthermore, it was believed that KO mice would display increased phosphorylation of IRS1 ser307, which is commonly associated with insulin resistance. At 16-weeks of age KO mice and littermates were subdivided into two groups and placed on either a HFD (n=30) or chow diet (n=24) for an 8-week period. Changes in body weight, glucose tolerance, and insulin tolerance were assessed pre- and post-diet period. Following the completion of the diet intervention mice were treated with an intraperitoneal injection of insulin (0.75U/kg) or vehicle solution and sacrificed for tissue collection. Epididymal/inguinal and retroperitoneal fat pads were removed for assessment of whole body adiposity. Whole gastrocnemius muscle was excised and homogenized for Western blot analysis of several key proteins of the insulin signalling cascade. Following completion of the HFD KO mice (48.6 ± 1.6 g) weighed significantly more than HFD fed wildtype (WT) mice (41.5 ± 1.6 g), and all chow fed mice (KO: 36.8 ± 1.5 g; WT: 35.2 ± 1.2 g; p<0.001). Glucose tolerance testing showed that KO mice exhibited significantly greater glucose intolerance compared to control mice post-HFD (p<0.001). Insulin tolerance testing, however, revealed no change in insulin sensitivity in KO or WT mice post-HFD (p>0.05). The HFD fed KO mice (0.73 ± 0.06 g) had an elevated retroperitoneal fat pad weight than HFD fed WT (0.49 ± 0.05 g) and all chow fed mice (KO: 0.28 ± 0.04 g; WT: 0.24 ± 0.04 g; p<0.01). Western blot analysis revealed a similar reduction in insulin receptor substrate-1 (IRS1) tyr628 phosphorylation in both KO and WT mice following the HFD (Con WT: 2.82 ± 0.69; Con KO: 3.06 ± 0.73; HFD WT: 1.71 ± 0.28; HFD KO: 1.28 ± 0.11 fold increase over non-insulin stimulated mice; p<0.02). IRS1 ser307 phosphorylation was elevated in both genotypes post-HFD (HFD WT: 2.97 ± 1.19; HFD KO: 2.17 ± 0.59 fold increase over standard chow fed control mice; p<0.03). Insulin treatment did not stimulate phosphorylation of Akt ser473 in KO or WT mice regardless of diet (p>0.05). In summary there was no difference between KO and WT mice in skeletal muscle insulin sensitivity as assessed by the phosphorylation of insulin signalling intermediates. An increase in IRS1 ser307 phosphorylation appears to be the primary mechanism for the reduced activation of IRS1 following the HFD in both KO and WT mice. However, the results from the current investigation did not support the notion that impaired skeletal muscle insulin signalling is responsible for the more pronounced diet-induced glucose intolerance observed in KO mice. Future studies investigating the viability of skeletal muscle GLUT4 translocation and glucose uptake as well as the glucose-induced insulin secretion of pancreatic β-cells following consumption of a HFD would help elucidate the mechanism of glucose intolerance in KO mice.

obesity

diabetes

sarcolipin

insulin signalling

high-fat diet

skeletal muscle

Kinesiology