There is some controversy regarding whether insulin or contractile activity alters the affinity of skeletal muscle glucose transporters for glucose and its analogues. The effects of insulin and contractions on the kinetics of glucose transport were therefore reexamined in isolated rat skeletal muscles. Concentration-dependent rates of 2-deoxyglucose (2-DG) transport were measured in the absence or presence of insulin (2 mU/ml) in the epitrochlearis and split soleus muscles. The apparent half-maximal saturating substrate concentration (Km) for basal 2-DG transport (approximately 12 mM) was similar for the split soleus and epitrochlearis, and the apparent Km was not changed by insulin in either muscle type. The presence of 2 mU/ml insulin increased the maximal transport velocity (Vmax) approximately fourfold in the epitrochlearis and approximately eightfold in the split soleus. In the epitrochlearis, in vitro muscle contractions also resulted in an approximately fourfold increases in Vmax with no change in apparent Km. The combined effects of insulin and contractions on Vmax were completely additive, but the apparent Km was not different from insulin alone. The apparent Km values for basal and insulin-stimulated glucose transport were further characterized in the epitrochlearis isolated from transgenic mice overexpressing the GLUT-1 isoform in the sarcolemma and their nontransgenic littermates. The apparent Km for basal 2-DG transport in the transgenic muscle (9 mM) was not significantly different from the apparent Km for insulin-stimulated transport in the control muscle (10 mM). The present study provides evidence that insulin and contractions, either alone or in combination, increase glucose transport activity in skeletal muscle by increasing Vmax, with no significant change in Km. Our results also suggest that, in intact skeletal muscle, the Km for basal glucose transport (a process mediated primarily by GLUT-1) is similar to the Km values for stimulated transport, mediated predominantly by GLUT-4.