Chemoreception of the Seagrass Posidonia Oceanica by Benthic Invertebrates is Altered by Seawater Acidification

Several plants and invertebrates interact and communicate by means of volatile organic compounds (VOCs). These compounds may play the role of infochemicals, being able to carry complex information to selected species, thus mediating inter- or intra-specific communications. Volatile organic compounds...

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Veröffentlicht in:	Journal of chemical ecology 2015-08, Vol.41 (8), p.766-779
Hauptverfasser:	Zupo, Valerio, Maibam, Chingoileima, Buia, Maria Cristina, Gambi, Maria Cristina, Patti, Francesco Paolo, Scipione, Maria Beatrice, Lorenti, Maurizio, Fink, Patrick
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Sprache:	eng
Schlagworte:	Acidification Agriculture Alismatales - chemistry Animals Bacillariophyceae behavior change Benthic communities Benthic fauna benthic organisms Biochemistry Biological Microscopy Biomedical and Life Sciences Chemical ecology Chemosensory perception Chemotaxis Climate Change Ecology Entomology Hydrogen-Ion Concentration Invertebrata Invertebrates Invertebrates - physiology Italy Leaves Life Sciences microalgae Ocean acidification Oceans Odors Organic compounds Plant Leaves - chemistry Posidonia oceanica seagrasses Seawater Seawater - chemistry VOCs Volatile organic compounds Volatile Organic Compounds - metabolism
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container_title	Journal of chemical ecology
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creator	Zupo, Valerio Maibam, Chingoileima Buia, Maria Cristina Gambi, Maria Cristina Patti, Francesco Paolo Scipione, Maria Beatrice Lorenti, Maurizio Fink, Patrick
description	Several plants and invertebrates interact and communicate by means of volatile organic compounds (VOCs). These compounds may play the role of infochemicals, being able to carry complex information to selected species, thus mediating inter- or intra-specific communications. Volatile organic compounds derived from the wounding of marine diatoms, for example, carry information for several benthic and planktonic invertebrates. Although the ecological importance of VOCs has been demonstrated, both in terrestrial plants and in marine microalgae, their role as infochemicals has not been demonstrated in seagrasses. In addition, benthic communities, even the most complex and resilient, as those associated to seagrass meadows, are affected by ocean acidification at various levels. Therefore, the acidification of oceans could produce interference in the way seagrass-associated invertebrates recognize and choose their specific environments. We simulated the wounding of Posidonia oceanica leaves collected at two sites (a control site at normal pH, and a naturally acidified site) off the Island of Ischia (Gulf of Naples, Italy). We extracted the VOCs and tested a set of 13 species of associated invertebrates for their specific chemotactic responses in order to determine if: a) seagrasses produce VOCs playing the role of infochemicals, and b) their effects can be altered by seawater pH. Our results indicate that several invertebrates recognize the odor of wounded P. oceanica leaves, especially those strictly associated to the leaf stratum of the seagrass. Their chemotactic reactions may be modulated by the seawater pH, thus impairing the chemical communications in seagrass-associated communities in acidified conditions. In fact, 54 % of the tested species exhibited a changed behavioral response in acidified waters (pH 7.7). Furthermore, the differences observed in the abundance of invertebrates, in natural vs. acidified field conditions, are in agreement with these behavioral changes. Therefore, leaf-produced infochemicals may influence the structure of P. oceanica epifaunal communities, and their effects can be regulated by seawater acidification.
doi_str_mv	10.1007/s10886-015-0610-x
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These compounds may play the role of infochemicals, being able to carry complex information to selected species, thus mediating inter- or intra-specific communications. Volatile organic compounds derived from the wounding of marine diatoms, for example, carry information for several benthic and planktonic invertebrates. Although the ecological importance of VOCs has been demonstrated, both in terrestrial plants and in marine microalgae, their role as infochemicals has not been demonstrated in seagrasses. In addition, benthic communities, even the most complex and resilient, as those associated to seagrass meadows, are affected by ocean acidification at various levels. Therefore, the acidification of oceans could produce interference in the way seagrass-associated invertebrates recognize and choose their specific environments. We simulated the wounding of Posidonia oceanica leaves collected at two sites (a control site at normal pH, and a naturally acidified site) off the Island of Ischia (Gulf of Naples, Italy). We extracted the VOCs and tested a set of 13 species of associated invertebrates for their specific chemotactic responses in order to determine if: a) seagrasses produce VOCs playing the role of infochemicals, and b) their effects can be altered by seawater pH. Our results indicate that several invertebrates recognize the odor of wounded P. oceanica leaves, especially those strictly associated to the leaf stratum of the seagrass. Their chemotactic reactions may be modulated by the seawater pH, thus impairing the chemical communications in seagrass-associated communities in acidified conditions. In fact, 54 % of the tested species exhibited a changed behavioral response in acidified waters (pH 7.7). Furthermore, the differences observed in the abundance of invertebrates, in natural vs. acidified field conditions, are in agreement with these behavioral changes. 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These compounds may play the role of infochemicals, being able to carry complex information to selected species, thus mediating inter- or intra-specific communications. Volatile organic compounds derived from the wounding of marine diatoms, for example, carry information for several benthic and planktonic invertebrates. Although the ecological importance of VOCs has been demonstrated, both in terrestrial plants and in marine microalgae, their role as infochemicals has not been demonstrated in seagrasses. In addition, benthic communities, even the most complex and resilient, as those associated to seagrass meadows, are affected by ocean acidification at various levels. Therefore, the acidification of oceans could produce interference in the way seagrass-associated invertebrates recognize and choose their specific environments. 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Furthermore, the differences observed in the abundance of invertebrates, in natural vs. acidified field conditions, are in agreement with these behavioral changes. Therefore, leaf-produced infochemicals may influence the structure of P. oceanica epifaunal communities, and their effects can be regulated by seawater acidification.</description><subject>Acidification</subject><subject>Agriculture</subject><subject>Alismatales - chemistry</subject><subject>Animals</subject><subject>Bacillariophyceae</subject><subject>behavior change</subject><subject>Benthic communities</subject><subject>Benthic fauna</subject><subject>benthic organisms</subject><subject>Biochemistry</subject><subject>Biological Microscopy</subject><subject>Biomedical and Life Sciences</subject><subject>Chemical ecology</subject><subject>Chemosensory perception</subject><subject>Chemotaxis</subject><subject>Climate Change</subject><subject>Ecology</subject><subject>Entomology</subject><subject>Hydrogen-Ion Concentration</subject><subject>Invertebrata</subject><subject>Invertebrates</subject><subject>Invertebrates - physiology</subject><subject>Italy</subject><subject>Leaves</subject><subject>Life Sciences</subject><subject>microalgae</subject><subject>Ocean acidification</subject><subject>Oceans</subject><subject>Odors</subject><subject>Organic compounds</subject><subject>Plant Leaves - 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These compounds may play the role of infochemicals, being able to carry complex information to selected species, thus mediating inter- or intra-specific communications. Volatile organic compounds derived from the wounding of marine diatoms, for example, carry information for several benthic and planktonic invertebrates. Although the ecological importance of VOCs has been demonstrated, both in terrestrial plants and in marine microalgae, their role as infochemicals has not been demonstrated in seagrasses. In addition, benthic communities, even the most complex and resilient, as those associated to seagrass meadows, are affected by ocean acidification at various levels. Therefore, the acidification of oceans could produce interference in the way seagrass-associated invertebrates recognize and choose their specific environments. 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Furthermore, the differences observed in the abundance of invertebrates, in natural vs. acidified field conditions, are in agreement with these behavioral changes. Therefore, leaf-produced infochemicals may influence the structure of P. oceanica epifaunal communities, and their effects can be regulated by seawater acidification.</abstract><cop>New York</cop><pub>Springer US</pub><pmid>26318440</pmid><doi>10.1007/s10886-015-0610-x</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0001-9766-8784</orcidid></addata></record>
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subjects	Acidification Agriculture Alismatales - chemistry Animals Bacillariophyceae behavior change Benthic communities Benthic fauna benthic organisms Biochemistry Biological Microscopy Biomedical and Life Sciences Chemical ecology Chemosensory perception Chemotaxis Climate Change Ecology Entomology Hydrogen-Ion Concentration Invertebrata Invertebrates Invertebrates - physiology Italy Leaves Life Sciences microalgae Ocean acidification Oceans Odors Organic compounds Plant Leaves - chemistry Posidonia oceanica seagrasses Seawater Seawater - chemistry VOCs Volatile organic compounds Volatile Organic Compounds - metabolism
title	Chemoreception of the Seagrass Posidonia Oceanica by Benthic Invertebrates is Altered by Seawater Acidification
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