Incubation of [1-3H1]geraniol with stem disks of Douglas fir (Pseudotsuga menziesii) and incubation of [1-3H1]geranyl pyrophosphate with both a soluble enzyme extract from Douglas fir and a partially purified preparation of (+)-3-carene synthase from lodgepole pine (Pinus contorta) resulted in the production of (+)-3-[3H] carene. Subsequent conversion of the product to car-3-en-5-one and to 4-isocaranone followed by base-catalyzed exchange of the alpha-hydrogens established that the 3H located at C1 in the geranyl substrate resided at C5 of (+)-3-carene. Incubation of the (+)-3-carene synthase preparation with (S)-[5-3H1, 4-14C]geranyl pyrophosphate resulted in the production of (+)-3-carene without loss of tritium, indicating that the 5-proR hydrogen is eliminated during cyclopropyl ring closure. Analysis of the conformational requirements for this 1,3 elimination involving the 5-proR hydrogen suggested that cyclopropyl ring formation occurs via a (4S)-alpha-terpinyl cation derived from the anti-endo cyclization of a (3S)-linalyl pyrophosphate intermediate. Kinetic analyses of the conversion of (1Z,3R)-[1-3H1]linalyl pyrophosphate, (1Z, 3S)-[1-3H1]linalyl pyrophosphate and [1-3H1]geranyl pyrophosphate by (+)-3-carene synthase revealed that the velocity of the reaction with the (3S)-linalyl enantiomer was 25-fold greater than the velocity with the (3R)-enantiomer and twice that of the natural substrate, geranyl pyrophosphate, thereby confirming this stereochemical prediction and also indicating that the cyclization of the linalyl intermediate is faster than the coupled isomerization and cyclization of the geranyl substrate. From these results, a model that details the regio- and stereochemistry of the enzymatic conversion of geranyl pyrophosphate to (+)-3-carene is proposed.