AUTHOR=Kim Seung Hyeon , Kim Hyegwang , Suonan Zhaxi , Zhang Fei , Lee Kun-Seop 

TITLE=Photosynthesis and whole-plant carbon balances of warm affinity Halophila nipponica and cold affinity Zostera marina in relation to water temperature rise: implication for future geographic distribution

JOURNAL=Frontiers in Marine Science

VOLUME=10

YEAR=2023

URL=https://www.frontiersin.org/journals/marine-science/articles/10.3389/fmars.2023.1203809

DOI=10.3389/fmars.2023.1203809

ISSN=2296-7745

ABSTRACT=<p>Climate change associated sea surface temperature rise could significantly affect the physiology, and consequently geographic distribution of seagrasses. Photosynthetic and respiratory responses of warm affinity <italic>Halophila nipponica</italic> and cold affinity <italic>Zostera marina</italic> to a change in water temperature (7–26°C) were investigated to estimate whole-plant carbon balance for prediction of the future geographic distributions of these seagrasses in the northwestern Pacific region. It was hypothesized that <italic>H. nipponica</italic> and <italic>Z. marina</italic> showed distinctly different patterns of carbon balance with changes in water temperature. Photosynthetic and respiratory rates of <italic>H. nipponica</italic> and <italic>Z. marina</italic> generally increased with increasing water temperature, except for <italic>I</italic><sub>c</sub> and <italic>I</italic><sub>k</sub> of <italic>H. nipponica</italic> and <italic>α</italic> of <italic>Z. marina</italic>. <italic>H. nipponica</italic> showed high <italic>P</italic><sub>max</sub> and <italic>α</italic> values, which could support a greater respiratory demand related to the higher proportion of non-photosynthetic tissues (~67%), compared with <italic>Z. marina</italic> (~34%). The whole-plant carbon balance of <italic>Z. marina</italic> remained positive throughout the experiment, although it decreased to nearly zero during the high water-temperature period. <italic>H. nipponica</italic> exhibited a negative carbon balance during winter and early spring, which corresponded with severely limited growth at water temperatures&lt; 15°C. These results suggest that increases in water temperature, particularly during winter, in relation to continuous climate change, could induce substantial changes in the seagrass ecosystem structure and corresponding changes in coastal ecosystem services in the temperate coastal waters of the northwestern Pacific region. The results of this study will provide valuable information on the effective management and conservation of coastal and estuarine ecosystems under ongoing climate change.</p>