The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges

Caulerpa is a widely distributed genus of chlorophytes (green macroalgae) that is important for its dietary, social, and coastal ecosystem value. Ocean acidification (OA) and ocean warming (OW) both threaten to change the distribution of macroalgae in New Zealand and globally. Two of the most common...

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Main Author: aleluia taise
Format: Thesis
Language:unknown
Published: 2024
Subjects:
Community ecology (excl. invasive species ecology)
Ecological physiology
Plant physiology
Ecological impacts of climate change and ecological adaptation
Climate change impacts and adaptation not elsewhere classified
Caulerpa
carbon physiology
dissolved inorganic carbon
ocean acidification
ocean warming
irradiance
macroalgae
CO2 concentrating mechanism
School: School of Biological Sciences
310806 Plant physiology
310303 Ecological physiology
410102 Ecological impacts of climate change and ecological adaptation
410199 Climate change impacts and adaptation not elsewhere classified
310302 Community ecology (excl. invasive species ecology)
280102 Expanding knowledge in the biological sciences
280111 Expanding knowledge in the environmental sciences
Degree Discipline: Marine Biology
Degree Name: Doctor of Philosophy
Degree Level: Doctoral
New Zealand
Ocean acidification
Online Access:https://doi.org/10.26686/wgtn.25567215
https://figshare.com/articles/thesis/The_combined_effects_of_ocean_acidification_warming_and_light_on_Caulerpa_spp_The_role_of_inorganic_carbon_physiology_and_species_ranges/25567215
id ftvictoriauwfig:oai:figshare.com:article/25567215
record_format openpolar
spelling ftvictoriauwfig:oai:figshare.com:article/25567215 2024-05-12T08:09:19+00:00 The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges aleluia taise 2024-04-09T00:00:00Z https://doi.org/10.26686/wgtn.25567215 https://figshare.com/articles/thesis/The_combined_effects_of_ocean_acidification_warming_and_light_on_Caulerpa_spp_The_role_of_inorganic_carbon_physiology_and_species_ranges/25567215 unknown doi:10.26686/wgtn.25567215 https://figshare.com/articles/thesis/The_combined_effects_of_ocean_acidification_warming_and_light_on_Caulerpa_spp_The_role_of_inorganic_carbon_physiology_and_species_ranges/25567215 CC BY-NC-ND 4.0 Community ecology (excl. invasive species ecology) Ecological physiology Plant physiology Ecological impacts of climate change and ecological adaptation Climate change impacts and adaptation not elsewhere classified Caulerpa carbon physiology dissolved inorganic carbon ocean acidification ocean warming irradiance macroalgae CO2 concentrating mechanism School: School of Biological Sciences 310806 Plant physiology 310303 Ecological physiology 410102 Ecological impacts of climate change and ecological adaptation 410199 Climate change impacts and adaptation not elsewhere classified 310302 Community ecology (excl. invasive species ecology) 280102 Expanding knowledge in the biological sciences 280111 Expanding knowledge in the environmental sciences Degree Discipline: Marine Biology Degree Name: Doctor of Philosophy Degree Level: Doctoral Text Thesis 2024 ftvictoriauwfig https://doi.org/10.26686/wgtn.25567215 2024-04-15T16:55:20Z Caulerpa is a widely distributed genus of chlorophytes (green macroalgae) that is important for its dietary, social, and coastal ecosystem value. Ocean acidification (OA) and ocean warming (OW) both threaten to change the distribution of macroalgae in New Zealand and globally. Two of the most common Caulerpa species in Te Whanganui a Tara Wellington, Aotearoa New Zealand, Caulerpa brownii and C. geminata, could have vastly different responses to both OA and OW because of their divergent dissolved inorganic carbon (DIC) uptake strategies and distance from range edge. However, responses to both stressors of OA and OW could be heavily mediated by light. To address these concerns, I conducted four manipulative laboratory experiments to test the effects of OA, OW and marine heatwaves (MHWs), and light and interactive effects of two or more stressors on Caulerpa species. Responses in physiology and photo-physiology of both Caulerpa species to OA suggest that those macroalgae without a CO2 concentrating mechanism (CCM) and relying solely on diffusive CO2 for DIC will benefit more from OA due to the benefits of alleviation of current DIC limitation than those species which possess a CCM that are not currently DIC limited. Physiological and photo-physiological responses to OA were significantly impacted by irradiance, demonstrating the role of irradiance in mediating DIC physiology in Caulerpa species tested. I found that any benefits received from elevated CO2 under OA may be dependent on energy limitations which in turn affects photo-physiology differentially depending on the DIC uptake strategy operating. Growth and photosynthesis responses of Caulerpa spp., demonstrated that the species with a warm edge distribution in Wellington was more negatively impacted by OW than the species with a cold edge in Wellington, which was more tolerant to OW and MHWs. Exposure to multiple stressors (OA, OW, reduced irradiance) of a future ocean exhibited less severe responses to a combined stressors effect than the singular stressor ... Thesis Ocean acidification Open Access Victoria University of Wellington / Te Herenga Waka New Zealand
institution Open Polar
collection Open Access Victoria University of Wellington / Te Herenga Waka
op_collection_id ftvictoriauwfig
language unknown
topic Community ecology (excl. invasive species ecology)
Ecological physiology
Plant physiology
Ecological impacts of climate change and ecological adaptation
Climate change impacts and adaptation not elsewhere classified
Caulerpa
carbon physiology
dissolved inorganic carbon
ocean acidification
ocean warming
irradiance
macroalgae
CO2 concentrating mechanism
School: School of Biological Sciences
310806 Plant physiology
310303 Ecological physiology
410102 Ecological impacts of climate change and ecological adaptation
410199 Climate change impacts and adaptation not elsewhere classified
310302 Community ecology (excl. invasive species ecology)
280102 Expanding knowledge in the biological sciences
280111 Expanding knowledge in the environmental sciences
Degree Discipline: Marine Biology
Degree Name: Doctor of Philosophy
Degree Level: Doctoral
spellingShingle Community ecology (excl. invasive species ecology)
Ecological physiology
Plant physiology
Ecological impacts of climate change and ecological adaptation
Climate change impacts and adaptation not elsewhere classified
Caulerpa
carbon physiology
dissolved inorganic carbon
ocean acidification
ocean warming
irradiance
macroalgae
CO2 concentrating mechanism
School: School of Biological Sciences
310806 Plant physiology
310303 Ecological physiology
410102 Ecological impacts of climate change and ecological adaptation
410199 Climate change impacts and adaptation not elsewhere classified
310302 Community ecology (excl. invasive species ecology)
280102 Expanding knowledge in the biological sciences
280111 Expanding knowledge in the environmental sciences
Degree Discipline: Marine Biology
Degree Name: Doctor of Philosophy
Degree Level: Doctoral
aleluia taise
The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
topic_facet Community ecology (excl. invasive species ecology)
Ecological physiology
Plant physiology
Ecological impacts of climate change and ecological adaptation
Climate change impacts and adaptation not elsewhere classified
Caulerpa
carbon physiology
dissolved inorganic carbon
ocean acidification
ocean warming
irradiance
macroalgae
CO2 concentrating mechanism
School: School of Biological Sciences
310806 Plant physiology
310303 Ecological physiology
410102 Ecological impacts of climate change and ecological adaptation
410199 Climate change impacts and adaptation not elsewhere classified
310302 Community ecology (excl. invasive species ecology)
280102 Expanding knowledge in the biological sciences
280111 Expanding knowledge in the environmental sciences
Degree Discipline: Marine Biology
Degree Name: Doctor of Philosophy
Degree Level: Doctoral
description Caulerpa is a widely distributed genus of chlorophytes (green macroalgae) that is important for its dietary, social, and coastal ecosystem value. Ocean acidification (OA) and ocean warming (OW) both threaten to change the distribution of macroalgae in New Zealand and globally. Two of the most common Caulerpa species in Te Whanganui a Tara Wellington, Aotearoa New Zealand, Caulerpa brownii and C. geminata, could have vastly different responses to both OA and OW because of their divergent dissolved inorganic carbon (DIC) uptake strategies and distance from range edge. However, responses to both stressors of OA and OW could be heavily mediated by light. To address these concerns, I conducted four manipulative laboratory experiments to test the effects of OA, OW and marine heatwaves (MHWs), and light and interactive effects of two or more stressors on Caulerpa species. Responses in physiology and photo-physiology of both Caulerpa species to OA suggest that those macroalgae without a CO2 concentrating mechanism (CCM) and relying solely on diffusive CO2 for DIC will benefit more from OA due to the benefits of alleviation of current DIC limitation than those species which possess a CCM that are not currently DIC limited. Physiological and photo-physiological responses to OA were significantly impacted by irradiance, demonstrating the role of irradiance in mediating DIC physiology in Caulerpa species tested. I found that any benefits received from elevated CO2 under OA may be dependent on energy limitations which in turn affects photo-physiology differentially depending on the DIC uptake strategy operating. Growth and photosynthesis responses of Caulerpa spp., demonstrated that the species with a warm edge distribution in Wellington was more negatively impacted by OW than the species with a cold edge in Wellington, which was more tolerant to OW and MHWs. Exposure to multiple stressors (OA, OW, reduced irradiance) of a future ocean exhibited less severe responses to a combined stressors effect than the singular stressor ...
format Thesis
author aleluia taise
author_facet aleluia taise
author_sort aleluia taise
title The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
title_short The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
title_full The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
title_fullStr The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
title_full_unstemmed The combined effects of ocean acidification, warming and light on Caulerpa spp.: The role of inorganic carbon physiology and species’ ranges
title_sort combined effects of ocean acidification, warming and light on caulerpa spp.: the role of inorganic carbon physiology and species’ ranges
publishDate 2024
url https://doi.org/10.26686/wgtn.25567215
https://figshare.com/articles/thesis/The_combined_effects_of_ocean_acidification_warming_and_light_on_Caulerpa_spp_The_role_of_inorganic_carbon_physiology_and_species_ranges/25567215
geographic New Zealand
geographic_facet New Zealand
genre Ocean acidification
genre_facet Ocean acidification
op_relation doi:10.26686/wgtn.25567215
https://figshare.com/articles/thesis/The_combined_effects_of_ocean_acidification_warming_and_light_on_Caulerpa_spp_The_role_of_inorganic_carbon_physiology_and_species_ranges/25567215
op_rights CC BY-NC-ND 4.0
op_doi https://doi.org/10.26686/wgtn.25567215
_version_ 1798852551793180672

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