Resistance training preserves high-intensity interval training induced improvements in skeletal muscle capillarization of healthy old men: a randomized controlled trial.

Skeletal muscle capillarization is a determining factor in gas and metabolite exchange, while its impairments may contribute to the development of sarcopenia. Studies on the potential of resistance training (RT) to induce angiogenesis in older muscles have been inconclusive, and effects of sequential endurance training (ET) and RT on capillarization are unknown. Healthy older men (66.5 ± 3.8 years) were engaged in either 12 weeks of habitual course observation (HC) followed by 12 weeks of RT (n = 8), or 12 weeks of high-intensity interval training (HIIT) followed by 12 weeks of RT (n = 9). At baseline, following 12 and 24 weeks, m. vastus lateralis biopsies were obtained. (Immuno-)histochemistry was used to assess indices of muscle fiber capillarization, muscle fiber morphology and succinate dehydrogenase (SDH) activity. Single periods of RT and HIIT resulted in similar improvements in capillarization and SDH activity. During RT following HIIT, improved capillarization and SDH activity, as well as muscle fiber morphology remained unchanged. The applied RT and HIIT protocols were thus similarly effective in enhancing capillarization and oxidative enzyme activity and RT effectively preserved HIIT-induced adaptations of these parameters. Hence, both, RT and HIIT, are valid training modalities for older men to improve skeletal muscle vascularization.

Satellite cell content in Huntington's disease patients in response to endurance training.

BACKGROUND: Skeletal muscle wasting is a hallmark of Huntington's disease (HD). However, data on myocellular characteristics and myofiber remodeling in HD patients are scarce. We aimed at gaining insights into myocellular characteristics of HD patients as compared to healthy controls at rest and after a period of increased skeletal muscle turnover. METHODS: Myosin heavy chain (MyHC)-specific cross-sectional area, satellite cell content, myonuclear number, myonuclear domain, and muscle fiber type distribution were determined from vastus lateralis muscle biopsies at rest and after 26 weeks of endurance training in HD patients and healthy controls. RESULTS: At the beginning of the study, there were no differences in myocellular characteristics between HD patients and healthy controls. Satellite cell content per MyHC-1 fiber (P = 0.014) and per MyHC-1 myonucleus (P = 0.006) increased significantly in healthy controls during the endurance training intervention, whereas it remained constant in HD patients (P = 0.804 and P = 0.975 for satellite cell content per MyHC-1 fiber and myonucleus, respectively). All further variables were not altered during the training intervention in HD patients and healthy controls. CONCLUSIONS: Similar skeletal muscle characteristics between HD patients and healthy controls at baseline suggested similar potential for myofiber remodeling in response to exercise. However, the missing satellite cell response in MyHC-1 myofibers following endurance training in HD patients points to a potential dysregulation in the exercise-induced activation and/or proliferation of satellite cells. In the longer-term, impaired myonuclear turnover might be associated with the clinical observation of skeletal muscle wasting.

Effects of endurance training on skeletal muscle mitochondrial function in Huntington disease patients.

BACKGROUND: Mitochondrial dysfunction may represent a pathogenic factor in Huntington disease (HD). Physical exercise leads to enhanced mitochondrial function in healthy participants. However, data on effects of physical exercise on HD skeletal muscle remains scarce. We aimed at investigating adaptations of the skeletal muscle mitochondria to endurance training in HD patients. METHODS: Thirteen HD patients and 11 healthy controls completed 26 weeks of endurance training. Before and after the training phase muscle biopsies were obtained from M. vastus lateralis. Mitochondrial respiratory chain complex activities, mitochondrial respiratory capacity, capillarization, and muscle fiber type distribution were determined from muscle samples. RESULTS: Citrate synthase activity increased during the training intervention in the whole cohort (P = 0.006). There was no group x time interaction for citrate synthase activity during the training intervention (P = 0.522). Complex III (P = 0.008), Complex V (P = 0.043), and succinate cytochrome c reductase (P = 0.008) activities increased in HD patients and controls by endurance training. An increase in mass-specific mitochondrial respiratory capacity was present in HD patients during the endurance training intervention. Overall capillary-to-fiber ratio increased in HD patients by 8.4% and in healthy controls by 6.4% during the endurance training intervention. CONCLUSIONS: Skeletal muscle mitochondria of HD patients are equally responsive to an endurance-training stimulus as in healthy controls. Endurance training is a safe and feasible option to enhance indices of energy metabolism in skeletal muscle of HD patients and may represent a potential therapeutic approach to delay the onset and/or progression of muscular dysfunction. TRIAL REGISTRATION: ClinicalTrials.gov NCT01879267 . Registered May 24, 2012.

Exercise effects in Huntington disease.

Huntington disease (HD) is a relentlessly progressive neurodegenerative disorder with symptoms across a wide range of neurological domains, including cognitive and motor dysfunction. There is still no causative treatment for HD but environmental factors such as passive lifestyle may modulate disease onset and progression. In humans, multidisciplinary rehabilitation has a positive impact on cognitive functions. However, a specific role for exercise as a component of an environmental enrichment effect has been difficult to demonstrate. We aimed at investigating whether endurance training (ET) stabilizes the progression of motor and cognitive dysfunction and ameliorates cardiovascular function in HD patients. Twelve male HD patients (mean ± SD, 54.8 ± 7.1 years) and twelve male controls (49.1 ± 6.8 years) completed 26 weeks of endurance training. Before and after the training intervention, clinical assessments, exercise physiological tests, and a body composition measurement were conducted and a muscle biopsy was taken from M. vastus lateralis. To examine the natural course of the disease, HD patients were additionally assessed 6 months prior to ET. During the ET period, there was a motor deficit stabilization as indicated by the Unified Huntington's Disease Rating Scale motor section score in HD patients (baseline: 18.6 ± 9.2, pre-training: 26.0 ± 13.7, post-training: 26.8 ± 16.4). Peak oxygen uptake ([Formula: see text]) significantly increased in HD patients (∆[Formula: see text] = +0.33 ± 0.28 l) and controls (∆[Formula: see text] = +0.29 ± 0.41 l). No adverse effects of the training intervention were reported. Our results confirm that HD patients are amenable to a specific exercise-induced therapeutic strategy indicated by an increased cardiovascular function and a stabilization of motor function.

Altered skeletal muscle (mitochondrial) properties in patients with mitochondrial DNA single deletion myopathy.

BACKGROUND: Mitochondrial myopathy severely affects skeletal muscle structure and function resulting in defective oxidative phosphorylation. However, the major pathomechanisms and therewith effective treatment approaches remain elusive. Therefore, the aim of the present study was to investigate disease-related impairments in skeletal muscle properties in patients with mitochondrial myopathy. Accordingly, skeletal muscle biopsies were obtained from six patients with moleculargenetically diagnosed mitochondrial myopathy (one male and five females, 53 ± 9 years) and eight age- and gender-matched healthy controls (two males and six females, 58 ± 14 years) to determine mitochondrial respiratory capacity of complex I-V, mitochondrial volume density and fiber type distribution. RESULTS: Mitochondrial volume density (4.0 ± 0.5 vs. 5.1 ± 0.8 %) as well as respiratory capacity of complex I-V were lower (P < 0.05) in mitochondrial myopathy and associated with a higher (P < 0.001) proportion of type II fibers (65.2 ± 3.6 vs. 44.3 ± 5.9 %). Additionally, mitochondrial volume density and maximal oxidative phosphorylation capacity correlated positively (P < 0.05) to peak oxygen uptake. CONCLUSION: Mitochondrial myopathy leads to impaired mitochondrial quantity and quality and a shift towards a more glycolytic skeletal muscle phenotype.

One bout of vibration exercise with vascular occlusion activates satellite cells.

NEW FINDINGS: What is the central question of this study? Acute skeletal muscle satellite cell (SC) activation is associated with skeletal muscle hypertrophy. Although the quantity of SCs has been reported to increase following a single bout of resistance exercise, data on muscle fibre type-specific SC quantity and/or activation status after a single bout of vibration is presently lacking. What is the main finding and its importance? By determining SCs from muscle biopsies of the vastus lateralis using immunohistochemistry, we conclude that modification of vibration exercise by superimposition of occlusion induced activation and differentiation of SCs in young men, which had not been observed with whole-body vibration or blood flow restriction alone. We tested the hypothesis that whole-body vibration (WBV) is insufficient to expand satellite cell numbers 24 h postexercise, whereas WBV in combination with blood flow restriction (BFR) is sufficient. Twenty-five young men were randomly assigned to one of the following three groups: WBV, BFR exercise or WBVBFR. Satellite cell numbers were determined from muscle biopsies of the vastus lateralis muscle using immunohistochemistry. Satellite cell quantity and frequency (+99.4%, P = 0.012 and +77.1%, P = 0.010, respectively) increased only in the WBVBFR group. Similar results were obtained for the quantity and frequency of myogenin-positive myonuclei (+139.0%, P < 0.001 and +148.4%, P < 0.001, respectively). We conclude that modification of WBV by superimposition of BFR induced activation and differentiation of satellite cells in young men, which had not been observed with WBV or BFR alone. These data suggest that WBVBFR might represent a novel viable anabolic stimulus.

High-intensity interval training with vibration as rest intervals attenuates fiber atrophy and prevents decreases in anaerobic performance.

UNLABELLED: Aerobic high-intensity interval training (HIT) improves cardiovascular capacity but may reduce the finite work capacity above critical power (W') and lead to atrophy of myosin heavy chain (MyHC)-2 fibers. Since whole-body vibration may enhance indices of anaerobic performance, we examined whether side-alternating whole-body vibration as a replacement for the active rest intervals during a 4 x 4 min HIT prevents decreases in anaerobic performance and capacity without compromising gains in aerobic function. Thirty-three young recreationally active men were randomly assigned to conduct either conventional 4 x 4 min HIT, HIT with 3 min of WBV at 18 Hz (HIT+VIB18) or 30 Hz (HIT+VIB30) in lieu of conventional rest intervals, or WBV at 30 Hz (VIB30). Pre and post training, critical power (CP), W', cellular muscle characteristics, as well as cardiovascular and neuromuscular variables were determined. W' (-14.3%, P = 0.013), maximal voluntary torque (-8.6%, P = 0.001), rate of force development (-10.5%, P = 0.018), maximal jumping power (-6.3%, P = 0.007) and cross-sectional areas of MyHC-2A fibers (-6.4%, P = 0.044) were reduced only after conventional HIT. CP, V̇O2peak, peak cardiac output, and overall capillary-to-fiber ratio were increased after HIT, HIT+VIB18, and HIT+VIB30 without differences between groups. HIT-specific reductions in anaerobic performance and capacity were prevented by replacing active rest intervals with side-alternating whole-body vibration, notably without compromising aerobic adaptations. Therefore, competitive cyclists (and potentially other endurance-oriented athletes) may benefit from replacing the active rest intervals during aerobic HIT with side-alternating whole-body vibration. TRIAL REGISTRATION: ClinicalTrials.gov Identifier: NCT01875146.

A novel DRAK inhibitor, SC82510, promotes axon branching of adult sensory neurons in vitro.

Recently, a new potent protein kinase inhibitor, SC82510, was identified acting on DRAK2 and stimulating axon outgrowth at low concentrations. DRAK is the Drosophila homologue of death-associated protein kinase that phosphorylates myosin-II regulatory light chain in a similar fashion as ROCK, the downstream target of RhoA mediating axon outgrowth inhibition. While higher concentrations of this novel compound exhibited toxic effects, significant promotion of process outgrowth of PC12 cells and of adult primary neurons was observed at 1 nM which could be further enhanced by addition of a neuronal growth factor (FGF-2). Unlike the effects of ROCK inhibitors on axon outgrowth that stimulate both, elongation and branching, SC82510 primarily promoted axon branching, whereas axon elongation was not increased in this cell culture model of peripheral axon regeneration.

C3 exoenzyme lacks effects on peripheral axon regeneration in vivo.

Peripheral nerve injury triggers the activation of the small GTPase RhoA in spinal motor and peripheral sensory neurons. C3 transferase, an exoenzyme produced by Clostridium botulinum that inactivates RhoA by ADP-ribosylation, has been successfully applied in central nervous system (CNS) lesion models to facilitate regeneration functionally and morphologically. Until now it has not been demonstrated if C3bot exerts positive effects on peripheral axon regeneration as well. In organotypic spinal cord preparations, C3bot reduced axonal growth of motoneurons, while no effect on sensory axon outgrowth from dorsal root ganglia (DRG) explants was observed. Enzymatically inactive C3E174Q was ineffective in both culture models. Spinal cord slices exhibited a significant increase in microglia/macrophages after treatment with C3bot suggesting an inflammatory component in the inhibition of axon growth. C3bot or C3E174Q were then applied into conduits implanted after transection of the sciatic nerve in rats. Functional evaluation by electrophysiology, nociception, and walking track tests did not show any significant difference between groups with active or mutant C3E174Q . Transmission electron microscopy of the regenerated nerves revealed no significant differences in the number of myelinated and unmyelinated axons 6 weeks after surgery. Compared to the CNS, the functional significance of RhoA may be limited during nerve regeneration in a growth-promoting environment.

Sorting of the FGF receptor 1 in a human glioma cell line.

Fibroblast growth factor receptor 1 (FGFR1) is a receptor tyrosine kinase promoting tumor growth in a variety of cancers, including glioblastoma. Binding of FGFs triggers the intracellular Ras/Raf/ERK signaling pathway leading to cell proliferation. Down-regulation of FGFR1 and, consequently, inactivation of its signaling pathways represent novel treatment strategies for glioblastoma. In this study, we investigated the internalization and endocytic trafficking of FGFR1 in the human glioma cell line U373. Stimulation with FGF-2 induced cell rounding accompanied by increased BrdU and pERK labeling. The overexpression of FGFR1 (without FGF treatment) resulted in enhanced phosphorylated FGFR1 suggesting receptor autoactivation. Labeled ligand (FGF-2-Cy5.5) was endocytosed in a clathrin- and caveolin-dependent manner. About 25 % of vesicles carrying fluorescently tagged FGFR1 represented early endosomes, 15 % transferrin-positive recycling endosomes and 40 % Lamp1-positive late endosomal/lysosomal vesicles. Stimulation with FGF-2 increased the colocalization rate in each of these vesicle populations. The treatment with the lysosomal inhibitor leupeptin resulted in FGFR1 accumulation in lysosomes, but did not enhance receptor recycling as observed in neurons. Analysis of vesicle distributions revealed an accumulation of recycling endosomes in the perinuclear region. In conclusion, the shuttling of receptor tyrosine kinases can be directly visualized by overexpression of fluorescently tagged receptors which respond to ligand stimulation and follow the recycling and degradation pathways similarly to their endogenous counterparts.

Rho-independent stimulation of axon outgrowth and activation of the ERK and Akt signaling pathways by C3 transferase in sensory neurons.

Peripheral nerve injury triggers the activation of RhoA in spinal motor and peripheral sensory neurons. RhoA activates a number of effector proteins including the Rho-associated kinase, ROCK, which targets the cytoskeleton and leads to inhibition of neurite outgrowth. Blockade of the Rho/ROCK pathway by pharmacological means improves axon regeneration after experimental injury. C3(bot) transferase, an exoenzyme produced by Clostridium botulinum, inactivates RhoA by ADP-ribosylation. It has been successfully applied in experimental CNS lesions to facilitate axon regeneration. Up to now it was not investigated thoroughly whether C3(bot) exerts positive effects on peripheral axon regeneration as well. In the present study, recombinant membrane permeable C3(bot) produced a small, but significant, axon outgrowth effect on peripheral sensory neurons dissociated from adult dorsal root ganglia (DRG) of the rat. Neuronal overexpression of C3, however, did not enhance axonal growth. Moreover, transfection of plasmids encoding dominant negative RhoA or RhoA specific shRNAs failed to increase axonal growth. Furthermore, we show that the C3(bot) mutant, C3(E174Q), which lacks RhoA inhibitory activity, still stimulates axonal growth. When analyzing possible signaling mechanisms we found that extracellular signal-regulated kinase (ERK) and Akt are activated by C3(bot) and ERK is induced by the C3(E174Q) mutant. Upregulation of kinase activities by C3(bot) occurs significantly faster than inactivation of RhoA indicating a RhoA-independent pathway of action by C3(bot). The induction of ERK signaling by C3(bot) was detected in embryonic hippocampal neurons, too. Taken together, although RhoA plays a central role for inhibition of axon outgrowth by myelin-derived inhibitors, it does not interfere with axonal growth of sensory neurons on a permissive substrate in vitro. C3(bot) blocks neuronal RhoA activity, but its positive effects on axon elongation and branching appear to be mediated by Rho independent mechanisms involving activation of axon growth promoting ERK and Akt kinases.

Sprouty2 and -4 regulate axon outgrowth by hippocampal neurons.

Sprouty proteins act as negative feedback inhibitors of fibroblast growth factor (FGF) signaling. FGFs belong to the neurotrophic factors and are involved in axonal growth during development and repair. We investigated the expression of Sprouty isoforms in hippocampal neurons as well as the regulation of Sprouty2 and -4 during development and their role in axon growth. Sprouty2 and -4 were located in the nucleus, the cytoplasm, in dendrites, and axons of hippocampal neurons concentrated in growth cones. During development in vivo and differentiation in vitro, expression of Sprouty2 and -4 was gradually downregulated in hippocampal neurons. Between 5 and 24 days in culture expression of both Sprouty isoforms was reduced by 70%. In vivo expression of Sprouty2 was reduced by 79% and of Sprouty4 by 93% on postnatal day 14 compared to embryonic day 16.5. Downregulation of Sprouty2 and -4 by shRNAs strongly promoted elongative axon growth by cultured hippocampal neurons, which was further increased by FGF-2 treatment. In addition, FGF-2 reduced expression of Sprouty2 by 33% and of Sprouty4 by 44%. Together, our results imply that Sprouty2 and -4 are downregulated in the hippocampus during postnatal brain development and that they can act as regulators of developmental axon growth.

Rho GTPases as regulators of morphological neuroplasticity.

GTPases function as intracellular, bimolecular switches by adopting different conformational states in response to binding GDP or GTP. Their activation is mediated through cell-surface receptors. Rho GTPases act on several downstream effectors involved in cellular morphogenesis, cell polarity, migration and cell division. In neurons, Rho GTPases regulate various features of dendritic and axonal outgrowth during development and regeneration mainly through their effects on the cytoskeleton. This review summarizes the main functions of Rho, Rac and Cdc42 GTPases as key regulators of morphological neuroplasticity under normal and pathological conditions.

C3 peptide enhances recovery from spinal cord injury by improved regenerative growth of descending fiber tracts.

Functional recovery and regeneration of corticospinal tract (CST) fibers following spinal cord injury by compression or dorsal hemisection in mice was monitored after application of the enzyme-deficient Clostridium botulinum C3-protein-derived 29-amino-acid fragment C3bot(154-182). This peptide significantly improved locomotor restoration in both injury models as assessed by the open-field Basso Mouse Scale for locomotion test and Rotarod treadmill experiments. These data were supported by tracing studies showing an enhanced regenerative growth of CST fibers in treated animals as visualized by anterograde tracing. Additionally, C3bot(154-182) stimulated regenerative growth of raphespinal fibers and improved serotonergic input to lumbar alpha-motoneurons. These in vivo data were confirmed by in vitro data, showing an enhanced axon outgrowth of alpha-motoneurons and hippocampal neurons cultivated on normal or growth-inhibitory substrates after application of C3bot(154-182). The observed effects were probably caused by a non-enzymatic downregulation of active RhoA by the C3 peptide as indicated by pull-down experiments. By contrast, C3bot(154-182) did not induce neurite outgrowth in primary cultures of dorsal root ganglion cells. In conclusion, C3bot(154-182) represents a novel, promising tool to foster axonal protection and/or repair, as well as functional recovery after traumatic CNS injury.

Sprouty2 down-regulation promotes axon growth by adult sensory neurons.

Fibroblast growth factors (FGFs) play a prominent role in axonal growth during development and repair. Treatment with FGF-2 or overexpression of FGF receptors promotes peripheral axon regeneration mainly by activation of extracellular signal-regulated kinase (ERK). The Ras/Raf/ERK pathway is under the control of Sprouty proteins acting as negative feedback inhibitors. We investigated the expression of Sprouty isoforms in adult sensory neurons of dorsal root ganglia (DRG) as well as the effects of Sprouty inhibition on axon growth by small interfering RNAs (siRNAs). Sprouty2 revealed the highest expression level in DRG neurons. Down-regulation of Sprouty2 promoted elongative axon growth by adult sensory neurons accompanied by enhanced FGF-2-induced activation of ERK and Ras, whereas Sprouty2 overexpression inhibited axon growth. Sprouty2 was not regulated in vivo in response to a sciatic nerve lesion. Together, our results imply that Sprouty2 is highly expressed in adult peripheral neurons and its down-regulation strongly promotes elongative axon growth by activation of the Ras/Raf/ERK pathway.

Dextromethorphan is protective against sensitized N-methyl-D-aspartate receptor-mediated excitotoxic brain damage in the developing mouse brain.

Enhanced glutamate release and inflammation play an important role in the pathogenesis of developmental brain injury. Although N-methyl-d-aspartate receptor (NMDAR) antagonists potently attenuate neonatal brain damage in several animal models, they can also impact trophic functions in the developing brain. As a consequence, high-affinity NMDAR antagonists have been shown to trigger widespread apoptotic neurodegeneration in the newborn brain. Dextromethorphan (DM), a low-affinity NMDAR antagonist with anti-inflammatory properties, may be neuroprotective against excitotoxic and inflammation-enhanced excitotoxic brain injury, without the associated stimulation of apoptotic degeneration. Using an established newborn mouse model of excitotoxic brain damage, we determined whether systemic injection of DM significantly attenuates excitotoxic lesion size. We investigated several doses and time regimens; a dose of 5 microg/g DM given in a combination of both pre-injury and repetitive post-injury treatment proved most effective. DM treatment significantly reduced lesion size in gray and white matter by reducing cell death as shown by a decreased Fluoro-Jade B staining and caspase-3 activation. Pre-treatment with interleukin-1beta and lipopolysaccharide enhanced NMDAR-mediated excitotoxic brain injury and microglial cell activation. This sensitizing effect was abolished by DM treatment, as the effectiveness of DM in reducing lesion size and microglial cell activation was similar to phosphate-buffered saline-pre-treated controls. In all cases, no gender-specific differences were detected. DM treatment did not trigger any apoptotic neurodegeneration (caspase-3 cleavage, terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling, Fluoro-Jade B staining). Although functional parameters were not measured, our data corroborate reports that DM is neuroprotective and that it may therefore improve functional outcome following perinatal brain injury.