Effects of flooding stress on the saltmarsh halophyte Salicornia fruticosa (L.) L. upscaling perspectives
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One of the major aftermaths of global warming is the ongoing global sea level rise, which is expected to
seriously treat the worldwide coasts. Among coastal environments, saltmarshes are particularly sensitive to
the increase of flooding and frequency of storm surges. Indeed, although saltmarshes respond with a
sediment accretion and coastal niche shifting, sea rise rates and the coastal squeeze phenomenon jeopardize
the acclimation capacity of saltmarsh species and plant communities. For these reasons, monitoring and
studying the response of saltmarshes to flooding is crucial to understand the fate of these fragile ecosystems.
For a comprehensive understanding of these processes, it is necessary to link different ecological scales
using an ecological upscaling approach. We analyzed main traits of plant community and the growth of the
key species Salicornia fruticosa (L.) L. in 9 saltmarshes along the flooding gradient (Marano and Grado
lagoon, northern Adriatic Sea). In particular, we considered community (i.e. species richness, dry biomass,
dry matter content) and individual traits (i.e. shoot annual growth, dry biomass, dry matter content, plant
height) analyzing the effect of flooding. Simultaneously we carried out a UAV (Unnamed Aerial Vehicle)
multispectral survey, in order to obtain remote sensing-derived vegetation indices (e.g. NDVI Normalized
Difference Vegetation Index) for the upscaling of plant responses. We found that the flooding gradient
produced a significant decrease of plant biomass and growth, affecting both plant traits and plant community
features. We also found NDVI effective to predict flooding effect only on the dry biomass of the community.
In contrast, flooding intensity shaped the relationship between NDVI and the individual plant growth. In
particular, the annual growth was satisfactorily explained by NDVI in the areas less subjected to flooding,
whereas lack of correlation between these two parameters was observed for sites frequently flooded. Our
findings shed new light on the potential use of the remote sensing tool for the understanding of the response
of saltmarshes vegetation to the future increase of the sea level. Further attention should be paid to species
morphological traits and additional ecophysiological responses (e.g. secondary metabolites, soil redox status)
in order to fully understand such crucial processes at the plant community scale
seriously treat the worldwide coasts. Among coastal environments, saltmarshes are particularly sensitive to
the increase of flooding and frequency of storm surges. Indeed, although saltmarshes respond with a
sediment accretion and coastal niche shifting, sea rise rates and the coastal squeeze phenomenon jeopardize
the acclimation capacity of saltmarsh species and plant communities. For these reasons, monitoring and
studying the response of saltmarshes to flooding is crucial to understand the fate of these fragile ecosystems.
For a comprehensive understanding of these processes, it is necessary to link different ecological scales
using an ecological upscaling approach. We analyzed main traits of plant community and the growth of the
key species Salicornia fruticosa (L.) L. in 9 saltmarshes along the flooding gradient (Marano and Grado
lagoon, northern Adriatic Sea). In particular, we considered community (i.e. species richness, dry biomass,
dry matter content) and individual traits (i.e. shoot annual growth, dry biomass, dry matter content, plant
height) analyzing the effect of flooding. Simultaneously we carried out a UAV (Unnamed Aerial Vehicle)
multispectral survey, in order to obtain remote sensing-derived vegetation indices (e.g. NDVI Normalized
Difference Vegetation Index) for the upscaling of plant responses. We found that the flooding gradient
produced a significant decrease of plant biomass and growth, affecting both plant traits and plant community
features. We also found NDVI effective to predict flooding effect only on the dry biomass of the community.
In contrast, flooding intensity shaped the relationship between NDVI and the individual plant growth. In
particular, the annual growth was satisfactorily explained by NDVI in the areas less subjected to flooding,
whereas lack of correlation between these two parameters was observed for sites frequently flooded. Our
findings shed new light on the potential use of the remote sensing tool for the understanding of the response
of saltmarshes vegetation to the future increase of the sea level. Further attention should be paid to species
morphological traits and additional ecophysiological responses (e.g. secondary metabolites, soil redox status)
in order to fully understand such crucial processes at the plant community scale
| Original language | English |
|---|---|
| Publication date | 2021 |
| Number of pages | 1 |
| Publication status | Published - 2021 |
ID: 328529765