It has been suggested that the slower V_O2 kinetics observed when exercise is initiated from an elevated baseline metabolic rate is linked to an impairment of muscle O₂ delivery. We hypothesized that 'priming' exercise would significantly reduce the phase II time constant () during subsequent severe-intensity cycle exercise initiated from an elevated baseline metabolic rate. Seven healthy men completed exercise transitions to 70% of the difference between gas exchange threshold (GET) and peak V_O2 from a moderate-intensity baseline (90% GET) on three occasions in each of the 'unprimed' and 'primed' conditions. Pulmonary gas exchange, heart rate and the electromyogram of m. vastus lateralis were measured during all tests. The phase II V_O2 kinetics were slower when severe exercise was initiated from a baseline of moderate exercise compared to unloaded pedaling (mean ± SD , 42 ± 15 vs. 33 ± 8 s; P<0.05) but were not accelerated by priming exercise (42 ± 17 s; P>0.05). The amplitude of the V_O2 slow component and the change in electromyogram from min 2 to 6 were both significantly reduced following priming exercise (V_O2 slow component: from 0.47 ± 0.09 to 0.27 ± 0.13 L•min^-1; iEMG_6-2: from 51 ± 35 to 21 ± 42 % of baseline; P<0.05 for both comparisons). These results indicate that the slower phase II V_O2 kinetics observed during transitions to severe exercise from an elevated baseline are not altered by priming exercise but that the reduced V_O2 slow component may be linked to changes in muscle fiber activation.