A common nonsense polymorphism (R577X) in the ACTN3 gene results in complete deficiency of the fast skeletal muscle fiber protein alpha-actinin-3 in an estimated one billion humans worldwide. The XX null genotype is under-represented in elite sprint athletes, associated with reduced muscle strength and sprint performance in non-athletes, and is over-represented in endurance athletes, suggesting that alpha-actinin-3 deficiency increases muscle endurance at the cost of power generation. Here we report that muscle from Actn3 knockout mice displays reduced force generation, consistent with results from human association studies. Detailed analysis of knockout mouse muscle reveals reduced fast fiber diameter, increased activity of multiple enzymes in the aerobic metabolic pathway, altered contractile properties, and enhanced recovery from fatigue, suggesting a shift in the properties of fast fibers towards those characteristic of slow fibers. These findings provide the first mechanistic explanation for the reported associations between R577X and human athletic performance and muscle function.
Duchenne muscular dystrophy (DMD) is the second most commonly occurring genetically inherited disease in humans. It is an X-linked condition that affects approximately one in 3300 live male births. It is caused by the absence or disruption of the protein dystrophin, which is found in a variety of tissues, most notably skeletal muscle and neurones in particular regions of the CNS. Clinically DMD is characterized by a severe pathology of the skeletal musculature that results in the premature death of the individual. An important aspect of DMD that has received less attention is the role played by the absence or disruption of dystrophin on CNS function. In this review we concentrate on insights into this role gained from investigation of boys with DMD and the genetically most relevant animal model of DMD, the dystrophin-deficient mdx mouse. Behavioural studies have shown that DMD boys have a cognitive impairment and a lower IQ (average 85), whilst the mdx mice display an impairment in passive avoidance reflex and in short-term memory. In DMD boys, there is evidence of disordered CNS architecture, abnormalities in dendrites and loss of neurones, all associated with neurones that normally express dystrophin. In the mdx mouse, there have been reports of a 50% decrease in neurone number and neural shrinkage in regions of the cerebral cortex and brainstem. Histological evidence shows that the density of GABA(A) channel clusters is reduced in mdx Purkinje cells and hippocampal CA1 neurones. At the biochemical level, in DMD boys the bioenergetics of the CNS is abnormal and there is an increase in the levels of choline-containing compounds, indicative of CNS pathology. The mdx mice also display abnormal bioenergetics, with an increased level of inorganic phosphate and increased levels of choline-containing compounds. Functionally, DMD boys have EEG abnormalities and there is some preliminary evidence that synaptic function is affected adversely by the absence of dystrophin. Electrophysiological studies of mdx mice have shown that hippocampal neurones have an increased susceptibility to hypoxia. These recent findings on the role of dystrophin in the CNS have implications for the clinical management of boys with DMD.
Right (RVFW) and left (LVFW) ventricular free wall cardiac myocytes were collected from 25 fetal sheep aged 77-146 days gestation (term ϭ 150 days gestation), six salineinfused catheterized fetal sheep (129 GD), and five lambs to measure gestational changes in uni-and binucleated cardiac myocyte numbers and cell volumes by confocal microscopy. At 77 days gestation, 2% of the myocytes were binucleated, which increased to 50% at 135 days gestation and 90% at 4 -6 weeks after birth. RVFW uni-and binucleated myocytes were larger than those in the LVFW, and cell volumes of RVFW uni-and binucleated and LVFW binucleated myocytes (but not LVFW uninucleated myocytes) increased with gestation. Before birth, the approximate number of myocytes was greater in the LVFW than in the RVFW (P Ͻ 0.001). Before 110 GD, cardiac growth appeared to be due to myocyte hyperplasia, as approximate myocyte numbers and VFW weight increased at the same rate. After 110 days gestation, the approximate myocyte number/g VFW weight decreased, which suggests that myocyte hypertrophy, as well as hyperplasia, was occurring in association with the appearance of a greater proportion of binucleated cells after that time. By 4 -6 weeks of age, there was marked hypertrophy of myocytes and an apparent reduction in myocyte number. Anat Rec Part A 274A: 952-961, 2003.
We demonstrated that the susceptibility of skeletal muscle to injury from lengthening contractions in the dystrophin-deficient mdx mouse is directly linked with the extent of fiber branching within the muscles and that both parameters increase as the mdx animal ages. We subjected isolated extensor digitorum longus muscles to a lengthening contraction protocol of 15% strain and measured the resulting drop in force production (force deficit). We also examined the morphology of individual muscle fibers. In mdx mice 1-2 mo of age, 17% of muscle fibers were branched, and the force deficit of 7% was not significantly different from that of age-matched littermate controls. In mdx mice 6-7 mo of age, 89% of muscle fibers were branched, and the force deficit of 58% was significantly higher than the 25% force deficit of age-matched littermate controls. These data demonstrated an association between the extent of branching and the greater vulnerability to contraction-induced injury in the older fast-twitch dystrophic muscle. Our findings demonstrate that fiber branching may play a role in the pathogenesis of muscular dystrophy in mdx mice, and this could affect the interpretation of previous studies involving lengthening contractions in this animal.
In the dystrophinopathies, skeletal muscle fibres undergo cycles of degeneration and regeneration, with regenerated fibres displaying a branched morphology. This study tests the hypothesis that regenerated branched fibres are mechanically weakened by the presence of branches and are damaged by contractions which do not affect unbranched dystrophin-negative fibres. Experiments were carried out on single fast-twitch fibres and whole muscle from the dystrophin-negative mdx mouse. 2+ homeostasis, and break at branch points when submaximally activated in skinned fibre experiments. When old intact isolated mdx muscles, with >90% branched fibres, are eccentrically activated with a moderate eccentric protocol there is a 40 ± 8% reduction in maximal force. Isolated single fibres from these muscles show areas of damage at fibre branch points. This same eccentric protocol causes no force loss in either littermate control muscles or mdx muscles with <10% branched fibres. I present a two-stage hypothesis for muscle damage in the dystrophinopathies, as follows: stage 1, the absence of dystrophin disrupts ion channel function, causing an activation of necrotizing Ca 2+ -activated proteases, which results in regenerated branched fibres; and stage 2, branched fibres are mechanically damaged during contraction. These results may have implications when considering therapies for boys with Duchenne muscular dystrophy. In particular, any therapy aimed at rescuing the defective gene will presumably have to do so before the number of branched fibres has increased to a level where the muscle is mechanically compromised.
Sarcomeric α-actinins (α-actinin-2 and -3) are a major component of the Z-disk in skeletal muscle, where they crosslink actin and other structural proteins to maintain an ordered myofibrillar array. Homozygosity for the common null polymorphism (R577X) in ACTN3 results in the absence of fast fiber-specific α-actinin-3 in ∼20% of the general population. α-Actinin-3 deficiency is associated with decreased force generation and is detrimental to sprint and power performance in elite athletes, suggesting that α-actinin-3 is necessary for optimal forceful repetitive muscle contractions. Since Z-disks are the structures most vulnerable to eccentric damage, we sought to examine the effects of α-actinin-3 deficiency on sarcomeric integrity. Actn3 knockout mouse muscle showed significantly increased force deficits following eccentric contraction at 30% stretch, suggesting that α-actinin-3 deficiency results in an increased susceptibility to muscle damage at the extremes of muscle performance. Microarray analyses demonstrated an increase in muscle remodeling genes, which we confirmed at the protein level. The loss of α-actinin-3 and up-regulation of α-actinin-2 resulted in no significant changes to the total pool of sarcomeric α-actinins, suggesting that alterations in fast fiber Z-disk properties may be related to differences in functional protein interactions between α-actinin-2 and α-actinin-3. In support of this, we demonstrated that the Z-disk proteins, ZASP, titin and vinculin preferentially bind to α-actinin-2. Thus, the loss of α-actinin-3 changes the overall protein composition of fast fiber Z-disks and alters their elastic properties, providing a mechanistic explanation for the loss of force generation and increased susceptibility to eccentric damage in α-actinin-3-deficient individuals.
Branched fibres are a well-documented phenomenon of regenerating skeletal muscle. They are found in the muscles of boys with Duchenne muscular dystrophy (DMD), a severe condition of progressive muscle wasting caused by an absence of the sarcolemmal protein dystrophin, and in the muscles of the mdx mouse, an animal model of DMD. However, only a handful of studies have investigated how the physiological properties of these morphologically deformed fibres differ from those of normal fibres. These studies have found an association between the extent of fibre branching in mdx muscles and the susceptibility of these muscles to damage from eccentric contractions. They have also found that branched mdx muscle fibres cannot sustain maximal contractions in buffered Ca 2+ solutions, that branch points are sites of increased mechanical stress and that myofibrillar stucture is greatly disturbed at branch points. These findings have important implications for understanding the function of dystrophin. It is commonly thought that the role of dystrophin is mechanical stabilization of the sarcolemma, as numerous studies have shown that eccentric contractions damage mdx muscle more than normal muscle. However, the finding that branched mdx fibres are mechanically weakened raises the question, is it the lack of dystrophin or is it the fibre branching that leads to the vulnerability of mdx muscle to contractile damage? The importance of this question to our understanding of the function of dystrophin warrants further research into the physiological properties of branched fibres and how they differ from morphologically normal fibres.
Properties of enzymatically isolated skeletal fibres from mice with muscular dystrophy.
SUMMARY1. Single intact muscle fibres were enzymatically isolated from the skeletal muscles of the dystrophic mouse 129/ReJ dy/dy and were subjected to a range of physiological interventions.2. Electrophysiological measurements, diffusion of injected dyes (Lucifer Yellow), microdissection and general appearance in the light microscope have shown that the majority of skeletal fibres isolated from the soleus and extensor digitorum longus (EDL) of adult dystrophic mice (10-14 weeks old) had gross morphological abnormalities. These abnormalities ranged from simple branching of the fibre to interconnections of many fibre branches which form a complex syncitium.3. Segments from fibres of normal appearance and from fibres with morphological deformities were chemically skinned with Triton X-100 and activated in Ca2+-and Sr2+-buffered solutions. The different characteristics of the Ca2+-and Sr2+-activation curves were also used to identify the fibre type.4. Gross morphological abnormalities were observed both in fibres which had predominantly slow-twitch and fast-twitch characteristics. 5. A new group of fibres was found to exist in the soleus mnuscle of dystrophic animals and represented about 18 % of the entire soleus fibre population. This group of fibres had predominantly fast-twitch characteristics and some of these fibres were also grossly malformed.6. The activation characteristics of individual branches from the same complex syncitium were similar, indicating that the contractile and regulatory proteins were of one type in one syncitium.7. Chemically skinned segments from malformed fibres which included a major deformity between the points of attachment were generally unable to sustain nearmaximal forces. 8. The proportion of malformed fibres which remained intact decreased markedly after prolonged tetanical stimulation of the intact muscle. This strongly suggests that malformed fibres are also functionally weak and prone to progressive damage when stimulated within the intact muscle. 9. The presence in large proportions of fibres with gross morphological ab-MS 7621
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