Low pH enhances germination of eelgrass (Zostera marina L.) seeds despite ubiquitous presence of Phytophthora gemini

Seagrasses are foundation species in coastal ecosystems promoting biodiversity and community structure. Future marine carbonate chemistry under ocean acidification may enhance seagrass physiology, but little is known about how reproductive ecology and disease will integrate into future ocean conditi...

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Bibliographic Details
Published in:Aquatic botany 2024-11, Vol.195, p.103805, Article 103805
Main Authors: Lowell, Alyson, Hill, Claudia E.L., Dupont, Sam, Infantes, Eduardo, Ramesh, Kirti, Peterson, Bradley, Govers, Laura L., Cox, T. Erin
Format: Article
Language:English
Subjects:
Botanik
Botany
Copper sulfate
Ocean acidification
Phytophthora gemini
Seagrass
Seeds
Zostera marina
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Summary:Seagrasses are foundation species in coastal ecosystems promoting biodiversity and community structure. Future marine carbonate chemistry under ocean acidification may enhance seagrass physiology, but little is known about how reproductive ecology and disease will integrate into future ocean conditions. A novel pathogen, Phytophthora gemini, infects >90 % of eelgrass, Zostera marina, surveyed in Northern Atlantic and Mediterranean populations reducing annual germination 6-fold. Our study investigated the combined effects of ocean acidification and P. gemini infection on germination of eelgrass seeds. We conducted a two-level factorial experiment crossing four pH levels (∆0, - ∆0.3, - ∆0.6, -∆0.9; relative to the average pH at the sampling site) with three infection levels (infected, non-infected, exposed) to determine germination rate and infection response. Prior to experimentation, flowering shoots were collected and held in flow-through seawater tanks where seeds ripened naturally. Once collected, seeds were held in copper sulfate solution (27.37 ± 1.57 ppt) and stored in darkness to mimic winter dormancy (4 °C). Before the start of the experiment, viable seeds were cultured on oomycete selective growth media to determine infection status. By the end of the experiment, 100 % of tested seeds, regardless of treatment, contained P. gemini. Germination rate significantly increased with decreased pH. Our findings indicate that P. gemini is not inhibited by ecologically relevant changes to carbonate chemistry and standard handling practices can result in effective and highly virulent disease transmission. These results confirm perennial populations of eelgrass are susceptible to infection and alerts conservationists to additional considerations necessary for successful eelgrass restoration. •Lowered pH levels positively influence eelgrass seed germination indicating a positive response to ocean acidification.•Phytophthora gemini is uninhibited by low pH and will continue to infect eelgrass meadows in future carbonate conditions.•P. gemini will remain a threat to eelgrass restoration emphasizing the need for innovative disease management strategies
ISSN:0304-3770
1879-1522
DOI:10.1016/j.aquabot.2024.103805