Induction of neuronal type nitric oxide synthase in skeletal muscle by chronic electrical stimulation in vivo

Regulation of nitric oxide production in response to skeletal muscle activation

Nitric oxide (NO) is synthesized in normal muscle fibers by the neuronal (nNOS) and the endothelial (ecNOS) isoforms of nitric oxide synthase (NOS). NO contributes to the regulation of several processes such as excitation-contraction coupling and mitochondrial respiration. We assessed in this study whether NO production is regulated in response to an acute increase in muscle activation. Three groups of anesthetized, tracheostomized, spontaneously breathing rats were examined after an experimental period of 3 h. Group 1 served as a control (no loading), whereas groups 2 and 3 were exposed to moderate and severe inspiratory resistive loads, respectively, which elicited tracheal pressures of 30 and 70% of maximum, respectively. Ventilatory (diaphragm, intercostal, and transverse abdominis) and limb (gastrocnemius) muscles were excised at the end of the experimental period and examined for NOS activity and NOS protein expression. Neither submaximal nor maximum tracheal pressures were altered after 3 h of resistive loading. Diaphragmatic and intercostal muscle NOS activities declined significantly in response to moderate and severe loading, whereas those of transverse abdominis and gastrocnemius muscles remained unchanged. On the other hand, resistive loading had no significant effect on ventilatory and limb muscle NOS isoform expression. We propose that a contraction-induced decline in muscle NOS activity represents a compensatory mechanism through which muscle contractility and mitochondrial function are protected from the inhibitory influence of NO.

Role of nitric oxide in contraction induced glucose transport

Nitric oxide (NO) is a vasoactive substance, which was first described as endothelium derived relaxing factor (EDRF). Subsequently, NO has been found to be a messenger molecule abundantly present in the nervous system. Functioning as a neurotransmitter in the peripheral nervous system, NO mediates an array of physiological functions such as gastrointestinal motility, regional blood flow, smooth muscle contraction, neuroendocrine activity and immune function. Recently NO biosynthesis has been found in skeletal muscle, where NO exerts an effect on both the metabolic and contractile processes. This review will focus on the actions of NO in skeletal muscle metabolism. NO donors have been shown to increase glucose transport in skeletal muscle. Inhibition of NOS activity blunts contraction-stimulated glucose transport but has no effect on insulin-stimulated glucose transport. NOS protein expression is enhanced by chronic exercise suggesting that NO may play a role in the improved glucose tolerance and increased insulin sensitivity characteristic of the trained state.

Increased caveolin-3 levels in mdx mouse muscles

The density of skeletal muscle caveolae is increased in Duchenne muscular dystrophy and its genetic homologue, the mdx mouse. This structural change is significant as it may indicate muscle regeneration. We identified in mdx mouse tibialis anterior muscles significantly increased levels of caveolin-3, the chief protein in muscle caveolae, and reduced levels of neuronal nitric oxide synthase, an enzyme regulated by caveolin-3. Similar changes occurred in the corresponding mRNA levels. These data suggest that induction of caveolin-3 occurs and this may at least partly be responsible for increased number of caveolae, altered nNOS-caveolin cycle, and regeneration of dystrophic muscles.

Mechanical loading regulates NOS expression and activity in developing and adult skeletal muscle

The hypothesis that changes in muscle activation and loading regulate the expression and activity of neuronal nitric oxide (NO) synthase (nNOS) was tested using in vitro and in vivo approaches. Removal of weight bearing from rat hindlimb muscles for 10 days resulted in a significant decrease in nNOS protein and mRNA concentration in soleus muscles, which returned to control concentrations after return to weight bearing. Similarly, the concentration of nNOS in cultured myotubes increased by application of cyclic loading for 2 days. NO release from excised soleus muscles was increased significantly by a single passive stretch of 20% or by submaximal activation at 2 Hz, although the increases were not additive when both stimuli were applied simultaneously. Increased NO release resulting from passive stretch or activation was dependent on the presence of extracellular calcium. Cyclic loading of cultured myotubes also resulted in a significant increase in NO release. Together, these findings show that activity of muscle influences NO production in the short term, by regulating NOS activity, and in the long term, by regulating nNOS expression.

Electrophoretic separation and quantitation of cardiac myosin heavy chain isoforms in eight mammalian species

A protocol for sample preparation and gel electrophoresis is described that reliably results in the separation of the alpha- and beta-isoforms of cardiac myosin heavy chain (MHC-alpha and MHC-beta) in eight mammalian species. The protocol is based on a simple, nongradient denaturing gel. The magnitude of separation of MHC-alpha and MHC-beta achieved with this protocol is sufficient for quantitative determination of the relative amounts of these two isoforms in mouse, rat, guinea pig, rabbit, canine, pig, baboon, and human myocardial samples. The sensitivity of the protocol is sufficient for the detection of MHC isoforms in samples at least as small as 1 microgram. The glycerol concentration in the separating gel is an important factor for successfully separating MHC-alpha and MHC-beta in myocardial samples from different species. The effect of sample load on MHC-alpha and MHC-beta band resolution is illustrated. The results also indicate that inclusion of a homogenization step during sample preparation increases the amount of MHC detected on the gel for cardiac samples to a much greater extent than for skeletal muscle samples. Although the protocol described in this study is excellent for analyzing cardiac samples, it should be noted that the same protocol is not optimal for separating MHC isoforms expressed in skeletal muscle, as is illustrated.