Rhizophora mangle, one of the main neotropic mangrove species, has wide phenological variability associated with soil salinity. Since global warming is one of the main drivers of changes in salinity,… Click to show full abstract
Rhizophora mangle, one of the main neotropic mangrove species, has wide phenological variability associated with soil salinity. Since global warming is one of the main drivers of changes in salinity, understanding the influence of this variable at the species level would help improve the prediction of climate change in the ecological services provided by mangroves. To understand the physiological and/or anatomical responses to water stress generated by edaphic salinity and its relationship with phenological and structural diversity, we quantified the functional traits of leaf tissue subjected to a cross-seeding experiment between two forests with different ranges of natural salinity (0–18 PSU1 and 20 to 70 PSU). A total of 180 propagules, 90 native and 90 from the other forest, were planted in each forest. Every three months for a year, soil salinity and growth, adaptability, and survival of propagules that were transformed into seedlings were measured. The traits evaluated between the two saline regimes presented significant differences, as stated in the working hypothesis. Likewise, there were modifications in the hypodermis and the xylem vessels in the exchanged seedlings, tissues related to water storage, and conduction. These responses allowed native euhaline forest seedlings to grow in oligohaline. The opposite occurred with seedlings originating in low salinities that did not survive in high salinities. Differences in adaptability between populations of R. mangle subjected to ranges of contrasting salinity may imply changes at the structural level, zoning, and abundance of the species front to the climate change processes.
               
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