Direct and indirect impacts of fire on isoprenoid emissions from Mediterranean vegetation

TitleDirect and indirect impacts of fire on isoprenoid emissions from Mediterranean vegetation
Publication TypeJournal Article
Year of Publication2004
AuthorsAlessio, G. A., De Lillis M., & Fanelli M.
JournalFunctional Ecology
Volume18
Pagination357-364
Keywordsisoprene, Mediterranean plant species, Monoterpenes, Ozone, photosynthesis, Stomatal conductance, fire ecology
Abstract

1. Fire is often associated with episodes of air pollution, possibly involving the release of biogenic isoprenoids (isoprene and monoterpenes). The direct and indirect impacts of fire on isoprenoid emission by plants of the Mediterranean vegetation were studied. Leaves of Arbutus unedo, Phillyrea latifolia, Cistus incanus, Cistus mospeliensis, Pistacia lentiscus, Quercus ilex, Quercus suber, Quercus pubescens, Myrtus communis and Pinus halepensis were exposed to direct fire or to the fire-consequent wave of elevated temperature. 2. Half the tested plant species did not emit isoprenoids and the treatments did not induce isoprenoid emission. In contrast, isoprene was emitted by intact leaves of Q. pubescens and M. communis, while monoterpenes were emitted by intact leaves of Q. ilex, Q. suber and P. halepensis. 3. The two treatments rapidly reduced isoprene emission by isoprene-emitting species and monoterpene emission by Quercus spp. This inhibition was associated with photosynthetic inhibition, and recovery was seen in Quercus spp. within days of treatment. Recovery was also associated with the recovery of photosynthesis, suggesting that emitted isoprenoids continue to be formed predominantly from photosynthetic intermediates after a fire episode. 4. In Q. pubescens leaves, however, recovery from the elevated-temperature treatment caused a sustained increase of isoprene emission which was not mirrored by a similar increase in photosynthesis. Whether this represents the induction of alternative metabolic pathways or an increase of the flux of photosynthetic carbon in the isoprene pathway is not known. Isoprene-emitting species in areas surrounding fire may emit a substantially larger hydrocarbon flux for several days after fire. 5. The elevated-temperature treatment induced the emission of α-pinene from Myrtus leaves, and the fire treatment stimulated the emission of several monoterpenes from Pinus needles. The emission began to decrease within minutes in Myrtus, while it increased within the first 100 min in Pinus, where it was detectable the day after the event although the flux was smaller than in prestressed needles. 6. Exposure to fire and to the associated elevated temperature may induce bursts of monoterpenes from plants that regularly do not emit these compounds and temporarily increase the load of monoterpenes in the atmosphere by pine species. These emissions may contribute to photochemical reactions involved in smog and ozone formation