Differential expression of nitric oxide synthases (NOS 1-3) in human skeletal muscle following exercise countermeasure during 12 weeks of bed rest.

Adaptive changes of major body systems in astronauts during spaceflight can be simulated by strict anti-orthostatic head-down tilt (HDT) bed rest (BR), a ground-based microgravity (microG) model that provides a meaningful opportunity to study atrophy mechanisms and possible countermeasures under controlled experimental conditions. As nitric oxide (NO) signaling is linked to muscle activity, we investigated altered expression of the three major isoforms of nitric oxide synthase (NOS 1-3) at cellular compartments during prolonged HDT BR without (control group) and with resistance exercise interventions (exercise group) using a flywheel ergometer (FWE). Atrophy detected in mixed (fast-slow) m. vastus lateralis (VL) and slow-type m. soleus (SOL) myofiber Types I and II (minus 35-40% of myofiber cross-sectional area) was prevented by FWE training. Concomitant to muscle atrophy, reduced NOS 1 protein and immunostaining was found in VL not in SOL biopsies. In trained VL, NOS 1 protein and immunostaining at myofibers II were significantly increased at the end of BR. Exercise altered NOS 2/caveolin 3 co-immunostaining patterns of subsarcolemmal focal accumulations in VL or SOL myofibers, which suggests reorganization of sarcolemmal microdomains. In trained VL, increased capillary-to-fiber (C/F) ratio and NOS 3 protein content were documented. Activity-linked NO signaling may be widespread in skeletal muscle cellular compartments that may be directly or indirectly impacted by adequate exercise countermeasure protocols to offset the negative effects induced by disuse, immobilization, or extended exposure to microgravity.

Human skeletal muscle structure and function preserved by vibration muscle exercise following 55 days of bed rest.

Prolonged immobilization of the human body results in functional impairments and musculoskeletal system deconditioning that may be attenuated by adequate muscle exercise. In a 56-day horizontal bed rest campaign involving voluntary males we investigated the effects of vibration muscle exercise (RVE, 2x6 min daily) on the lower limb skeletal muscles using a newly designed foot plantar trainer (Galileo Space) for use at supine position during bed rest. The maximally voluntary isometric plantar flexion force was maintained following regular RVE bouts during bed rest (controls -18.6 %, P<0.05). At the start (BR2) and end of bed rest (BR55) muscle biopsies were taken from both mixed fast/slow-type vastus lateralis (VL) and mainly slow-type soleus muscle (SOL), each having n=10. RVE group: the size of myofiber types I and II was largely unchanged in VL, and increased in SOL. Ctrl group: the SOL depicted a disrupted pattern of myofibers I/II profiles (i.e., type II>140 % vs. preBR) suggesting a slow-to-fast muscle phenotype shift. In RVE-trained SOL, however, an overall conserved myofiber I/II pattern was documented. RVE training increased the activity-dependent expression of nitric oxide synthase type 1 immunofluorescence at SOL and VL myofiber membranes. These data provide evidence for the beneficial effects of RVE training on the deconditioned structure and function of the lower limb skeletal muscle. Daily short RVE should be employed as an effective atrophy countermeasure co-protocol preferentially addressing postural calf muscles during prolonged clinical immobilization or long-term human space missions.

Neuromuscular contacts induce nitric oxide signals in skeletal myotubes in vitro.

It has previously been shown that skeletal myotubes express nitric oxide synthase (NOS) and produce and release NO signals. NOS is also part of agrin-induced acetylcholine receptor aggregations on myotubes. As nerve-muscle interactions underlie reciprocal signaling mechanisms, we hypothesized that NO signals in target myotubes may be induced by neuromuscular contacts in development. Chimeric neuron-myotube co-cultures were prepared using p75-selected spinal cord neurons from embryonic chicken. Confocal imaging revealed robust 1,2-diaminoanthraquinone red fluorescence indicative of de novo formation of NO only in those myotubes which were contacted by neurites, also verified by pre- and postsynaptic marker costaining (anti-synaptotagmin and alpha-bungarotoxin). Neither soluble agrin nor sensory dorsal root ganglionic neurons showed comparable effects in this model. We concluded that in target skeletal muscle cells the NOS/NO system is controlled by motoneuron contacts by as yet incompletely understood signaling mechanisms. Endogenous NO signaling in myotubes may be essential during synapse formation and plasticity of the neuromuscular system.

Effects of support stimulation on human soleus fiber characteristics during exposure to "dry" immersion.

In this study the model of 7-day dry immersion (DI) was used. 17 male volunteers (23-29 years old) were divided in 2 groups: (i) 7-day DI without support (DI, n=9), (ii) 7-day DI using support stimulation (DIS, n=8). Support stimulator device exerted pressure of 0.2 +/- 0.15 kg/cm2 upon the plantar support zones simulating the walking pattern 6 times a day for 20 minutes of every hour: 10 minutes at a speed of 75 steps/min and 10 minutes at a speed of 120 steps/min. M. soleus biopsy was performed before and immediately after DI. The m. soleus fiber myosin heavy chain (MHC) profile, myofiber cross-sectional area (CSA) and total protein concentration were analyzed in frozen serial sections. In addition, NO-synthase 1 (NOS1) levels indicative of normal muscle cell signaling were analyzed by western blotting in 4 persons in each group. After dry immersion, percentage of muscle fibers containing type I MHC decreased by 6% (p<0.05) in group DI, but was not changed significantly in group DIS. Percentage of the type IIa fibers was significantly altered in none of the groups. Type I fiber CSA decreased by 24.4% (p<0.05) in group DI. No significant changes of type I fiber CSA were found in group DIS. CSA of the type IIa fibers significantly altered in none of the groups. The total protein concentration was found increased by 17.6% in group DI and by 21% in group DIS. The increased total protein content in group DI suggests a diminution of fiber CSA attributed to the loss of non-protein component of fibers. NOS1 decreased by 35.6% in group DI and increased by 58.1% in group DIS. We conclude that 7 days in dry immersion lead to reduction in the type I muscle fiber percentage, loss of the non-protein component and decline in NOS1. These changes were clearly prevented by the support stimulation protocol applied during the DI period.