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C. Vickers, M. Possell, C. Cojocariu, V. Velikova, J. Laothawornkitkul, Annette Ryan, P. Mullineaux, C. Hewitt (2009)
Isoprene synthesis protects transgenic tobacco plants from oxidative stress.Plant, cell & environment, 32 5
D. Tapiolas, Jean-Baptiste Raina, Adrian Lutz, B. Willis, C. Motti (2013)
Direct measurement of dimethylsulfoniopropionate (DMSP) in reef-building corals using quantitative nuclear magnetic resonance (qNMR) spectroscopyJournal of Experimental Marine Biology and Ecology, 443
(1983)
The biological production of dimethylsulphide in the ocean and its role in the global atmospheric sulphur budget
D. Suggett, David Smith (2011)
Interpreting the sign of coral bleaching as friend vs. foeGlobal Change Biology, 17
M. Possell, C. Hewitt (2011)
Isoprene emissions from plants are mediated by atmospheric CO2 concentrationsGlobal Change Biology, 17
G. Jones, Anne Trevena (2005)
The influence of coral reefs on atmospheric dimethylsulphide over the Great Barrier Reef, Coral Sea, Gulf of Papua and Solomon and Bismarck SeasMarine and Freshwater Research, 56
H. Burdett, P. Donohue, A. Hatton, M. Alwany, N. Kamenos (2013)
Spatiotemporal Variability of Dimethylsulphoniopropionate on a Fringing Coral Reef: The Role of Reefal Carbonate Chemistry and Environmental VariabilityPLoS ONE, 8
J. Schnitzler, S. Louis, K. Behnke, M. Loivamäki (2009)
Poplar volatiles - biosynthesis, regulation and (eco)physiology of isoprene and stress-induced isoprenoids.Plant biology, 12 2
A. Curson, J. Todd, M. Sullivan, A. Johnston (2011)
Catabolism of dimethylsulphoniopropionate: microorganisms, enzymes and genesNature Reviews Microbiology, 9
M. Garren, K. Son, Jean-Baptiste Raina, R. Rusconi, F. Menolascina, O. Shapiro, Jessica Tout, D. Bourne, J. Seymour, R. Stocker (2013)
A bacterial pathogen uses dimethylsulfoniopropionate as a cue to target heat-stressed coralsThe ISME Journal, 8
W. Sunda, D. Kieber, R. Kiene, S. Huntsman (2002)
An antioxidant function for DMSP and DMS in marine algaeNature, 418
S. Shaw, S. Chisholm, R. Prinn (2003)
Isoprene production by Prochlorococcus, a marine cyanobacterium, and other phytoplanktonMarine Chemistry, 80
J. Stefels (2000)
Physiological aspects of the production and conversion of DMSP in marine algae and higher plantsJournal of Sea Research, 43
S. Ban, N. Graham, S. Connolly (2014)
Evidence for multiple stressor interactions and effects on coral reefsGlobal Change Biology, 20
T. Hughes, A. Baird, D. Bellwood, M. Card, S. Connolly, C. Folke, R. Grosberg, O. Hoegh‐Guldberg, J. Jackson, J. Jackson, J. Kleypas, J. Lough, P. Marshall, M. Nyström, S. Palumbi, J. Pandolfi, B. Rosen, J. Roughgarden (2003)
Climate Change, Human Impacts, and the Resilience of Coral ReefsScience, 301
A. Baker, A. Baker, P. Glynn, Bernhard Riegl (2008)
Climate change and coral reef bleaching: An ecological assessment of long-term impacts, recovery trends and future outlookEstuarine Coastal and Shelf Science, 80
D. Suggett, M. Warner, David Smith, P. Davey, S. Hennige, N. Baker (2008)
PHOTOSYNTHESIS AND PRODUCTION OF HYDROGEN PEROXIDE BY SYMBIODINIUM (PYRRHOPHYTA) PHYLOTYPES WITH DIFFERENT THERMAL TOLERANCES 1Journal of Phycology, 44
T. Sharkey, Sansun Yeh (2003)
ISOPRENE EMISSION FROM PLANTS.Annual review of plant physiology and plant molecular biology, 52
Rebecca Thurber, D. Burkepile, Corinne Fuchs, A. Shantz, Ryan McMinds, Jesse Zaneveld (2014)
Chronic nutrient enrichment increases prevalence and severity of coral disease and bleachingGlobal Change Biology, 20
Gregory Cunningham, V. Strauss, P. Ryan (2008)
African penguins (Spheniscus demersus) can detect dimethyl sulphide, a prey-related odourJournal of Experimental Biology, 211
M. Steinke, Patrick Brading, P. Kerrison, M. Warner, D. Suggett (2011)
CONCENTRATIONS OF DIMETHYLSULFONIOPROPIONATE AND DIMETHYL SULFIDE ARE STRAIN‐SPECIFIC IN SYMBIOTIC DINOFLAGELLATES (SYMBIODINIUM SP., DINOPHYCEAE) 1Journal of Phycology, 47
Jean-Baptiste Raina, E. Dinsdale, B. Willis, D. Bourne (2010)
Do the organic sulfur compounds DMSP and DMS drive coral microbial associations?Trends in microbiology, 18 3
T. Sharkey (2013)
Is it useful to ask why plants emit isoprene?Plant, cell & environment, 36 3
R. Simó (2001)
Production of atmospheric sulfur by oceanic plankton: biogeochemical, ecological and evolutionary links.Trends in ecology & evolution, 16 6
D. Rasher, E. Stout, S. Engel, J. Kubanek, M. Hay (2011)
Macroalgal terpenes function as allelopathic agents against reef coralsProceedings of the National Academy of Sciences, 108
D. Exton, D. Suggett, T. McGenity, M. Steinke (2013)
Chlorophyll‐normalized isoprene production in laboratory cultures of marine microalgae and implications for global modelsLimnology and Oceanography, 58
D. Bourne, P. Dennis, S. Uthicke, R. Soo, G. Tyson, N. Webster (2013)
Coral reef invertebrate microbiomes correlate with the presence of photosymbiontsThe ISME Journal, 7
T. Sharkey, E. Singsaas (1995)
Why plants emit isopreneNature, 374
B. Hatcher (1988)
Coral reef primary productivity: A beggar's banquet.Trends in ecology & evolution, 3 5
Katharina Fabricius, G. De’ath, M. Puotinen, T. Done, Timothy Cooper, Scott Burgess (2008)
Disturbance gradients on inshore and offshore coral reefs caused by a severe tropical cycloneLimnology and Oceanography, 53
E. Borell, M. Steinke, M. Fine (2013)
Direct and indirect effects of high pCO2 on algal grazing by coral reef herbivores from the Gulf of Aqaba (Red Sea)Coral Reefs, 32
S. Arnold, D. Spracklen, Jonathan Williams, N. Yassaa, J. Sciare, B. Bonsang, V. Gros, I. Peeken, A. Lewis, S. Alvain, C. Moulin (2008)
Evaluation of the global oceanic isoprene source and its impacts on marine organic carbon aerosolAtmospheric Chemistry and Physics, 9
J. Stefels, M. Steinke, S. Turner, G. Malin, S. Belviso (2007)
Environmental constraints on the production and removal of the climatically active gas dimethylsulphide (DMS) and implications for ecosystem modellingBiogeochemistry, 83
R. Charlson, J. Lovelock, M. Andreae, S. Warren (1987)
Oceanic phytoplankton, atmospheric sulphur, cloud albedo and climateNature, 326
G. Jones, M. Curran, A. Broadbent, Stacey King, Esther Fischer, Rosemary Jones (2007)
Factors affecting the cycling of dimethylsulfide and dimethylsulfoniopropionate in coral reef waters of the Great Barrier ReefEnvironmental Chemistry, 4
W. Bandaranayake (2002)
Bioactivities, bioactive compounds and chemical constituents of mangrove plantsWetlands Ecology and Management, 10
J. Kubanek, Kristen Whalen, S. Engel, Sarah Kelly, Timothy Henkel, W. Fenical, J. Pawlik (2002)
Multiple defensive roles for triterpene glycosides from two Caribbean spongesOecologia, 131
S. Shaw, B. Gantt, N. Meskhidze (2010)
Production and Emissions of Marine Isoprene and Monoterpenes: A ReviewAdvances in Meteorology, 2010
G. Jones, Esther Fischer, E. Deschaseaux, P. Harrison (2014)
The effect of coral bleaching on the cellular concentration of dimethylsulphoniopropionate in reef coralsJournal of Experimental Marine Biology and Ecology, 460
Frances Hopkins, S. Archer (2014)
Consistent increase in dimethyl sulfide (DMS) in response to high CO2 in five shipboard bioassays from contrasting NW European watersBiogeosciences, 11
H. Burdett, Victoria Keddie, N. MacArthur, Laurin McDowall, J. McLeish, Eva Spielvogel, A. Hatton, N. Kamenos (2014)
Dynamic photoinhibition exhibited by red coralline algae in the red seaBMC Plant Biology, 14
G. Nevitt (2011)
The neuroecology of dimethyl sulfide: a global-climate regulator turned marine infochemical.Integrative and comparative biology, 51 5
H. Swan, G. Jones, E. Deschaseaux (2012)
Dimethylsulfide, climate and coral reef ecosystems
A. Arneth, Ü. Niinemets, S. Pressley, J. Bäck, P. Hari, T. Karl, S. Noè, I. Prentice, D. Serça, T. Hickler, A. Wolf, B. Smith (2007)
Process-based estimates of terrestrial ecosystem isoprene emissions: incorporating the effects of a direct CO2-isoprene interaction
M. Loivamäki, R. Mumm, M. Dicke, J. Schnitzler (2008)
Isoprene interferes with the attraction of bodyguards by herbaceous plantsProceedings of the National Academy of Sciences, 105
J. Mcmanus, L. Meñez, Kathleen Kesner-Reyes, S. Vergara, M. Ablan (2000)
Coral reef fishing and coral-algal phase shifts: implications for global reef statusJournal of Materials Science, 57
H. Sweatman (1988)
Field evidence that settling coral reef fish larvae detect resident fishes using dissolved chemical cuesJournal of Experimental Marine Biology and Ecology, 124
B. Gantt, N. Meskhidze, A. Carlton (2010)
The contribution of marine organics to the air quality of the western United StatesAtmospheric Chemistry and Physics, 10
J. Seymour, R. Simó, T. Ahmed, R. Stocker (2010)
Chemoattraction to Dimethylsulfoniopropionate Throughout the Marine Microbial Food WebScience, 329
G. Wolfe, M. Steinke (1996)
Grazing‐activated production of dimethyl sulfide (DMS) by two clones of Emiliania huxleyiLimnology and Oceanography, 41
S. Kowalewsky, M. Dambach, B. Mauck, G. Dehnhardt (2006)
High olfactory sensitivity for dimethyl sulphide in harbour sealsBiology Letters, 2
M. Andreae (1990)
Ocean-atmosphere interactions in the global biogeochemical sulfur cycle*Marine Chemistry, 30
Graham Jones, M. Curran, A. Broadbent (1994)
Dimethylsulphide in the South Pacific
K. Alstyne, P. Schupp, M. Slattery (2006)
The distribution of dimethylsulfoniopropionate in tropical Pacific coral reef invertebratesCoral Reefs, 25
M. Siwko, S. Marrink, A. Vries, A. Kozubek, Anton Uiterkamp, A. Mark (2007)
Does isoprene protect plant membranes from thermal shock? A molecular dynamics study.Biochimica et biophysica acta, 1768 2
A. Kettle, M. Andreae (2000)
Flux of dimethylsulfide from the oceans: A comparison of updated data sets and flux modelsJournal of Geophysical Research, 105
Jean-Baptiste Raina, D. Tapiolas, S. Forêt, Adrian Lutz, D. Abrego, Janja Ceh, F. Seneca, P. Clode, D. Bourne, B. Willis, C. Motti (2013)
DMSP biosynthesis by an animal and its role in coral thermal stress responseNature, 502
D. Suggett, Liang Dong, Tracy Lawson, Evelyn Lawrenz, Leigh Torres, David Smith (2012)
Light availability determines susceptibility of reef building corals to ocean acidificationCoral Reefs, 32
Esther Fischer, G. Jones (2012)
Atmospheric dimethysulphide production from corals in the Great Barrier Reef and links to solar radiation, climate and coral bleachingBiogeochemistry, 110
N. Meskhidze, A. Nenes (2006)
Phytoplankton and Cloudiness in the Southern OceanScience, 314
J. Debose, G. Nevitt, A. Dittman (2010)
Rapid Communication: Experimental Evidence that Juvenile Pelagic Jacks (Carangidae) Respond Behaviorally to DMSPJournal of Chemical Ecology, 36
J. Uller, T. Stavrakou, S. Wallens, I. Smedt, M. Roozendael, M. Potosnak, J. Rinne, B. Munger, A. Goldstein, A. Guenther
Atmospheric Chemistry and Physics Global Isoprene Emissions Estimated Using Megan, Ecmwf Analyses and a Detailed Canopy Environment Model
I. Nagelkerken, G. Velde, M. Gorissen, G. Meijer, T. Hof, C. Hartog (2000)
Importance of Mangroves, Seagrass Beds and the Shallow Coral Reef as a Nursery for Important Coral Reef Fishes, Using a Visual Census TechniqueEstuarine Coastal and Shelf Science, 51
Müller Müller, Stavrakou Stavrakou, Wallens Wallens (2008)
Global isoprene emissions estimated using MEGAN, ECMWF analyses and a detailed canopy environment modelAtmospheric Chemistry and Physics, 8
P. Mumby (2006)
Connectivity of reef fish between mangroves and coral reefs: Algorithms for the design of marine reserves at seascape scalesBiological Conservation, 128
David Taylor, D. Schiel (2010)
Algal populations controlled by fish herbivory across a wave exposure gradient on southern temperate shores.Ecology, 91 1
J. Gershenzon (2008)
Insects turn up their noses at sweating plantsProceedings of the National Academy of Sciences, 105
B. Gantt, N. Meskhidze, D. Kamykowski (2009)
A new physically-based quantification of marine isoprene and primary organic aerosol emissionsAtmospheric Chemistry and Physics, 9
C. Vickers, J. Gershenzon, M. Lerdau, F. Loreto (2009)
A unified mechanism of action for volatile isoprenoids in plant abiotic stress.Nature chemical biology, 5 5
J. Todd, Rachel Rogers, Y. Li, M. Wexler, P. Bond, Lei Sun, A. Curson, G. Malin, M. Steinke, A. Johnston (2007)
Structural and Regulatory Genes Required to Make the Gas Dimethyl Sulfide in BacteriaScience, 315
G. Nevitt, R. Veit, P. Kareiva (1995)
Dimethyl sulphide as a foraging cue for Antarctic Procellariiform seabirdsNature, 376
A. Broadbent, G. Jones (2004)
DMS and DMSP in mucus ropes, coral mucus, surface films and sediment pore waters from coral reefs in the Great Barrier ReefMarine and Freshwater Research, 55
M. Rudd (2014)
Scientists' perspectives on global ocean research prioritiesFrontiers in Marine Science, 1
R. Fall, S. Copley (2000)
Bacterial sources and sinks of isoprene, a reactive atmospheric hydrocarbon.Environmental microbiology, 2 2
K. Six, S. Kloster, T. Ilyina, S. Archer, Kai Zhang, E. Maier‐Reimer (2013)
Global warming amplified by reduced sulphur fluxes as a result of ocean acidificationNature Climate Change, 3
K. Fabricius, Szilvia Cséke, C. Humphrey, G. De’ath (2013)
Does Trophic Status Enhance or Reduce the Thermal Tolerance of Scleractinian Corals? A Review, Experiment and Conceptual FrameworkPLoS ONE, 8
Benjamin Green, D. Suggett, A. Hills, M. Steinke (2011)
Optimisation of a fast DMS sensor (FDS) for real time quantification of dimethyl sulfide production by algaeBiogeochemistry, 110
A. Broadbent, G. Jones, Rosemary Jones (2002)
DMSP in Corals and Benthic Algae from the Great Barrier ReefEstuarine Coastal and Shelf Science, 55
O. Hoegh‐Guldberg, P. Mumby, A. Hooten, R. Steneck, P. Greenfield, E. Gomez, C. Harvell, P. Sale, A. Edwards, K. Caldeira, N. Knowlton, C. Eakin, R. Iglesias-Prieto, N. Muthiga, R. Bradbury, A. Dubi, M. Hatziolos (2007)
Coral Reefs Under Rapid Climate Change and Ocean AcidificationScience, 318
J. Laothawornkitkul, NIGEL Paul, Claudia Vickers, M. Possell, Jane Taylor, Philip Mullineaux, C. Hewitt (2008)
Isoprene emissions influence herbivore feeding decisions.Plant, cell & environment, 31 10
David Smith, D. Suggett, N. Baker (2005)
Is photoinhibition of zooxanthellae photosynthesis the primary cause of thermal bleaching in corals?Global Change Biology, 11
M. Alcaraz, R. Almeda, C. Duarte, B. Horstkotte, S. Lasternas, S. Agustí (2014)
Changes in the C, N, and P cycles by the predicted salps-krill shift in the southern oceanFrontiers in Marine Science, 1
D. Exton, David Smith, T. McGenity, M. Steinke, A. Hills, D. Suggett (2010)
Application of a Fast Isoprene Sensor (FIS) for measuring isoprene production from marine samplesLimnology and Oceanography: Methods, 8
M. Steinke, C. Evans, Gareth Lee, G. Malin (2007)
Substrate kinetics of DMSP-lyases in axenic cultures and mesocosm populations of Emiliania huxleyiAquatic Sciences, 69
S. Vallina, R. Simó (2007)
Re-visiting the CLAW hypothesisEnvironmental Chemistry, 4
V. Johnson, B. Russell, K. Fabricius, C. Brownlee, J. Hall‐Spencer (2012)
Temperate and tropical brown macroalgae thrive, despite decalcification, along natural CO2 gradientsGlobal Change Biology, 18
K. Fabricius, C. Langdon, S. Uthicke, C. Humphrey, S. Noonan, G. De’ath, R. Okazaki, N. Muehllehner, M. Glas, J. Lough (2011)
Losers and winners in coral reefs acclimatized to elevated carbon dioxide concentrationsNature Climate Change, 1
M. Breckels, E. Roberts, S. Archer, G. Malin, Michael Steinke (2011)
The role of dissolved infochemicals in mediating predator–prey interactions in the heterotrophic dinoflagellate Oxyrrhis marinaJournal of Plankton Research, 33
P. Mumby, A. Hastings, H. Edwards (2007)
Thresholds and the resilience of Caribbean coral reefsNature, 450
J. Pawlik, G. McFall, S. Zea (2002)
Does the Odor from Sponges of the Genus Ircinia Protect Them from Fish Predators?Journal of Chemical Ecology, 28
J. Barr, J. Fuentes, Daniel Wang, Yolanda Edmonds, J. Zieman, B. Hayden, D. Childers (2003)
RED MANGROVES EMIT HYDROCARBONS, 2
D. Exton, D. Suggett, M. Steinke, T. McGenity (2012)
Spatial and temporal variability of biogenic isoprene emissions from a temperate estuaryGlobal Biogeochemical Cycles, 26
T. Sharkey, F. Loreto (1993)
Water stress, temperature, and light effects on the capacity for isoprene emission and photosynthesis of kudzu leavesOecologia, 95
J. Debose, G. Nevitt (2008)
Dimethylsulfoniopropionate is linked to coral spawning, fish abundance and squid aggregations over a coral reef
E. Deschaseaux, G. Jones, M. Deseo, K. Shepherd, R. Kiene, H. Swan, P. Harrison, B. Eyre (2014)
Effects of environmental factors on dimethylated sulfur compounds and their potential role in the antioxidant system of the coral holobiontLimnology and Oceanography, 59
D. Tchernov, M. Gorbunov, C. Vargas, Swati Yadav, A. Milligan, M. Häggblom, P. Falkowski (2004)
Membrane lipids of symbiotic algae are diagnostic of sensitivity to thermal bleaching in corals.Proceedings of the National Academy of Sciences of the United States of America, 101 37
Susannah Leahy, M. Kingsford, C. Steinberg (2013)
Do Clouds Save the Great Barrier Reef? Satellite Imagery Elucidates the Cloud-SST Relationship at the Local ScalePLoS ONE, 8
G. Luo, F. Yu (2009)
A numerical evaluation of global oceanic emissions of α-pinene and isopreneAtmospheric Chemistry and Physics, 10
A. Guenther, T. Karl, P. Harley, C. Wiedinmyer, P. Palmer, C. Geron (2006)
Estimates of global terrestrial isoprene emissions using MEGAN (Model of Emissions of Gases and Aerosols from Nature)Atmospheric Chemistry and Physics, 6
DeBose DeBose, Nevitt Nevitt, Dittman Dittman (2010)
Experimental evidence that juvenile pelagic jacks (Carangidae) respond behaviourally to DMSPJournal of Chemical Ecology, 36
L. Alvarez, D. Exton, K. Timmis, D. Suggett, T. McGenity (2009)
Characterization of marine isoprene-degrading communities.Environmental microbiology, 11 12
O. Wingenter, K. Haase, P. Strutton, G. Friederich, S. Meinardi, D. Blake, F. Rowland (2004)
Changing concentrations of CO, CH(4), C(5)H(8), CH(3)Br, CH(3)I, and dimethyl sulfide during the Southern Ocean Iron Enrichment Experiments.Proceedings of the National Academy of Sciences of the United States of America, 101 23
M. Hay, W. Fenical, K. Gustafson (1987)
Chemical Defense Against Diverse Coral-Reef Herbivores.Ecology, 68 6
(1997)
Eco-ethological analysis of the interaction between isoprene and the behaviour of Collembola
Frances Hopkins, S. Turner, P. Nightingale, M. Steinke, D. Bakker, P. Liss (2009)
Ocean acidification and marine trace gas emissionsProceedings of the National Academy of Sciences, 107
L. Carpenter, S. Archer, R. Beale (2012)
Ocean-atmosphere trace gas exchange.Chemical Society reviews, 41 19
J. Dacey, G. King, P. Lobel (1994)
Herbivory by reef fishes and the production of dimethyl sulfide and acrylic acidMarine Ecology Progress Series, 112
P. Palmer, S. Shaw (2005)
Quantifying global marine isoprene fluxes using MODIS chlorophyll observationsGeophysical Research Letters, 32
K. Alstyne, V. Dominique, G. Muller-parker (2009)
Is dimethylsulfoniopropionate (DMSP) produced by the symbionts or the host in an anemone–zooxanthella symbiosis?Coral Reefs, 28
R. Woesik, K. Sakai, A. Ganase, Y. Loya (2011)
Revisiting the winners and the losers a decade after coral bleachingMarine Ecology Progress Series, 434
V. Weis (2008)
Cellular mechanisms of Cnidarian bleaching: stress causes the collapse of symbiosisJournal of Experimental Biology, 211
Jean-Baptiste Raina, D. Tapiolas, B. Willis, D. Bourne (2009)
Coral-Associated Bacteria and Their Role in the Biogeochemical Cycling of SulfurApplied and Environmental Microbiology, 75
P. Nightingale, P. Liss (2003)
Gases in SeawaterTreatise on Geochemistry, 6
B. Rost, I. Zondervan, D. Wolf-Gladrow (2008)
Sensitivity of phytoplankton to future changes in ocean carbonate chemistry: current knowledge, contradictions and research directionsMarine Ecology Progress Series, 373
N. Duke, J. Meynecke, S. Dittmann, A. Ellison, K. Anger, Uta Berger, S. Cannicci, K. Diele, K. Ewel, C. Field, N. Koedam, Shing Lee, C. Marchand, I. Nordhaus, F. Dahdouh-Guebas (2007)
A World Without Mangroves?Science, 317
M. Ball, M. Cochrane, H. Rawson (1997)
Growth and water use of the mangroves Rhizophora apiculata and R. stylosa in response to salinity and humidity under ambient and elevated concentrations of atmospheric CO2Plant Cell and Environment, 20
Courtney Endres, K. Lohmann (2012)
Perception of dimethyl sulfide (DMS) by loggerhead sea turtles: a possible mechanism for locating high-productivity oceanic regions for foragingJournal of Experimental Biology, 215
A. Hoey, D. Bellwood (2011)
Suppression of herbivory by macroalgal density: a critical feedback on coral reefs?Ecology letters, 14 3
Hayley Arnold, P. Kerrison, M. Steinke (2013)
Interacting effects of ocean acidification and warming on growth and DMS‐production in the haptophyte coccolithophore Emiliania huxleyiGlobal Change Biology, 19
F. Loreto, V. Velikova (2001)
Isoprene produced by leaves protects the photosynthetic apparatus against ozone damage, quenches ozone products, and reduces lipid peroxidation of cellular membranes.Plant physiology, 127 4
J. Debose, S. Lema, G. Nevitt (2008)
Dimethylsulfoniopropionate as a Foraging Cue for Reef FishesScience, 319
J. Kleypas, G. Danabasoglu, J. Lough (2008)
Potential role of the ocean thermostat in determining regional differences in coral reef bleaching eventsGeophysical Research Letters, 35
Biogenic volatile organic compounds (BVOCs), in particular dimethyl sulphide (DMS) and isoprene, have fundamental ecological, physiological and climatic roles. Our current understanding of these roles is almost exclusively established from terrestrial or oceanic environments but signifies a potentially major, but largely unknown, role for BVOCs in tropical coastal marine ecosystems. The tropical coast is a transition zone between the land and ocean, characterized by highly productive and biodiverse coral reefs, seagrass beds and mangroves, which house primary producers that are amongst the greatest emitters of BVOCs on the planet. Here, we synthesize our existing understanding of BVOC emissions to produce a novel conceptual framework of the tropical marine coast as a continuum from DMS‐dominated reef producers to isoprene‐dominated mangroves. We use existing and previously unpublished data to consider how current environmental conditions shape BVOC production across the tropical coastal continuum, and in turn how BVOCs can regulate environmental stress tolerance or species interactions via infochemical networks. We use this as a framework to discuss how existing predictions of future tropical coastal BVOC emissions, and the roles they play, are effectively restricted to present day ‘baseline’ trends of BVOC production across species and environmental conditions; as such, there remains a critical need to focus research efforts on BVOC responses to rapidly accelerating anthropogenic impacts at local and regional scales. We highlight the complete lack of current knowledge required to understand the future ecological functioning of these important systems, and to predict whether feedback mechanisms are likely to regulate or exacerbate current climate change scenarios through environmentally and ecologically mediated changes to BVOC budgets at the ecosystem level.
Global Change Biology – Wiley
Published: Apr 1, 2015
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