Please use this identifier to cite or link to this item: https://repositorio.inpa.gov.br/handle/1/17161
Title: Monoterpene ‘thermometer’ of tropical forest-atmosphere response to climate warming
Authors: Jardine, Kolby J.
Jardine, Angela B.
Holm, Jennifer A.
Lombardozzi, Danica L.
Negrón-Juárez, Robinson I.
Martin, Scot T.
Beller, Harry R.
Gimenez, Bruno Oliva
Higuchi, Niro
Chambers, Jeffrey Quintin
Keywords: Aerosol
Biogenic Emission
Carbon Dioxide
Climate Change
Drought
El Nino
Enzyme Activity
Heating
Leaf
Monoterpene
Oxidative Stress
Photosynthesis
Temperature Effect
Thermometry
Tropical Forest
Volatile Substance
Amazonia
Carbon
Carbon Dioxide
Terpene
Volatile Organic Compound
Atmosphere
Circadian Rhythm
Climate Change
El Nino
Forest
Metabolism
Physiology
Plant Leaf
Season
Temperature
Tropic Climate
Atmosphere
Carbon
Carbon Dioxide
Carbon Isotopes
Circadian Rhythm
Climate Change
El Nino-southern Oscillation
Forests
Monoterpenes
Plant Leaves
Seasons
Temperature
Tropical Climate
Volatile Organic Compounds
Issue Date: 2017
metadata.dc.publisher.journal: Plant, Cell and Environment
metadata.dc.relation.ispartof: Volume 40, Número 3, Pags. 441-452
Abstract: Tropical forests absorb large amounts of atmospheric CO2 through photosynthesis but elevated temperatures suppress this absorption and promote monoterpene emissions. Using 13CO2 labeling, here we show that monoterpene emissions from tropical leaves derive from recent photosynthesis and demonstrate distinct temperature optima for five groups (Groups 1–5), potentially corresponding to different enzymatic temperature-dependent reaction mechanisms within β-ocimene synthases. As diurnal and seasonal leaf temperatures increased during the Amazonian 2015 El Niño event, leaf and landscape monoterpene emissions showed strong linear enrichments of β-ocimenes (+4.4% °C−1) at the expense of other monoterpene isomers. The observed inverse temperature response of α-pinene (−0.8% °C−1), typically assumed to be the dominant monoterpene with moderate reactivity, was not accurately simulated by current global emission models. Given that β-ocimenes are highly reactive with respect to both atmospheric and biological oxidants, the results suggest that highly reactive β-ocimenes may play important roles in the thermotolerance of photosynthesis by functioning as effective antioxidants within plants and as efficient atmospheric precursors of secondary organic aerosols. Thus, monoterpene composition may represent a new sensitive ‘thermometer’ of leaf oxidative stress and atmospheric reactivity, and therefore a new tool in future studies of warming impacts on tropical biosphere-atmosphere carbon-cycle feedbacks. © 2016 John Wiley & Sons Ltd
metadata.dc.identifier.doi: 10.1111/pce.12879
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