The combined effect of seawater salinity and duration on the survival and growth of eelgrass Zostera marina

• Published in: Aquatic botany Vol. 187; p. 103652
• Main Authors: Zhang, Yan-Hao, Li, Jian-Du, Yan, Wen-Jie, Luo, Fan-Shu, Wang, Li, Zuo, Li-Ming, Xu, Jun-Ge, Li, Wen-Tao, Zhang, Pei-Dong
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2023
• Subjects: Leaf soluble sugar content; Morphology; Productivity; Salinity; Survival; Zostera marina; Productivity; Zostera marina; Leaf soluble sugar content; Survival; Morphology; Salinity
• ISSN: 0304-3770; 1879-1522
• DOI: 10.1016/j.aquabot.2023.103652

Abrupt changes in salinity are considered a key cause of seagrass bed degradation. In the study, we first quantified the effects of different combinations of salinity and duration on the responses of Zostera marina shoots in terms of survivorship, morphology, growth and physiology. The recovery potential (recovery of shoots from salinity stress to be returned to original salinity level) of Z. marina shoots was assessed. The LT50 (lethal time that caused an increase in mortality to 50 % of that of the control) and EC50 (effect concentration, i.e., salinity level that caused a decrease in growth to 50 % of that of the control) were calculated to reveal the quantitative relationship between salinity and duration that resulted in limiting effects on the survival and growth of Z. marina shoots. Z. marina shoots were exposed to different combinations of water salinity [20, 25, 30 (control), 35, 40, and 45 PSU] and duration (5, 10, 15 and 20 days), and then the shoots were transferred to the control condition for 30 days under laboratory conditions. The results showed that the survival rate of shoots at the end of recovery was significantly lower than those of shoots at the end of direct salinity stress at the hypersalinity levels of 40 and 45 PSU, indicating that short-term periods of increase in water salinity would lead to long-term effects on the survival of Z. marina shoots. The total leaf area of shoots at the end of recovery was significantly higher than those of shoots at the end of direct salinity stress at salinity levels of 25–35 PSU, indicating a significant recovery potential following the salinity stress. However, a poor recovery potential was found under combinations of hypersalinity (40–45 PSU) and duration of 20 days. Regression analysis revealed that the relationship between salinity and duration was a strong power function that could limit the growth of Z. marina. Pearson correlation analysis showed that the survival and growth of Z. marina shoots exposed to different salinity levels were significantly correlated with leaf soluble sugar contents when the duration was higher than 5 days. This study will further enhance our understanding of seagrass bed degeneration induced by abrupt changes in salinity. •We investigate the effect of seawater salinity and duration on Z. marina.•Increased seawater salinity display a significant effect on Z. marina shoots.•LT50 values of shoots range from 4.0 days to 15.6 days under the salinities of 35–45 PSU.•Leaf soluble sugar contents are significantly correlated with the survival and growth.