It is generally accepted that inhibition of nitric oxide synthase (NOS) facilitates, and thus nitric oxide (NO) inhibits, contractility of skeletal muscle. However, standard assessments of contractility are carried out at a nonphysiological oxygen tension [partial pressure of oxygen (pO₂)] that can interfere with NO signaling (95% O₂). We therefore examined, in normal and neuronal NOS (nNOS)-deficient mice, the influence of pO₂ on whole-muscle contractility and on myocyte calcium flux and sarcomere shortening. Here, we demonstrate a significant enhancement of these measures of muscle performance at low physiological pO₂ and an inhibitory influence at higher physiological pO₂, which depend on endogenous nNOS. At 95% O₂ (which produces oxidative stress; muscle core pO₂ ≈400 mmHg), force production is enhanced but control of contractility by NO/nitrosylation is greatly attenuated. In addition, responsivity to pO₂ is altered significantly in nNOS mutant muscle. These results reveal a fundamental role for the concerted action of NO and O₂ in physiological regulation of skeletal muscle contractility, and suggest novel molecular aspects of myopathic disease. They suggest further that the role of NO in some cellular systems may require reexamination.