Your search keyword '"POSIDONIA"' showing total 66 results

1. Different thermal regimes and susceptibility to herbivory do not constrain seagrass seedling restoration.

Author

Pansini, Arianna, Stipcich, Patrizia, Frasca, Sara, Migliore, Luciana, and Ceccherelli, Giulia

Subjects

*SEAGRASS restoration, *MARINE parks & reserves, *POSIDONIA oceanica, *LEAF development, *FIELD research, *POSIDONIA

Abstract

Recovering seagrass ecosystems through restoration has become impellent to re-establish their functionality and services. Although the use of seedlings may represent an appropriate solution, little information is provided on the seedling-based restoration effectiveness with influence of biotic and abiotic interactions. Survival, morphological development and leaf total phenol content of transplanted Posidonia oceanica seedlings were evaluated under different origin, thermal regimes and herbivore pressure through a five-months field experiment in two MPAs, located on the west (cold) and east (warm) Sardinia coast to explore the effectiveness of seedling-based restoration. Seedlings originated from the two coasts responded differently to thermal regime site and herbivory pressure, as the warm-adapted ones survived less but developed more (and vice-versa) and resisted to the herbivory pressure increasing their phenol content, thus showing compensating responses. This study provided information on the P. oceanica seedling-based restoration by investigating abiotic and biotic interactions with the transplanted plants. It promotes the collection of beach-cast fruits from different coasts and their transplantation, regardless their origin, with no need of protecting seedlings from predators. [Display omitted] • Seedlings may represent a suitable plant material for seagrass restoration. • Posidonia oceanica seedlings were tested under thermic and herbivory interactions. • Warm-adapted seedlings survived less but developed more respect to cold ones. • Their compensating responses suggest seedling restoration effectiveness. [ABSTRACT FROM AUTHOR]

Published

2025

2. Quantifying organic carbon burial rates and stocks in seagrass meadow sediments influenced by sargassum-brown tides.

Author

Sánchez-Rojas, Melisa Aranza, Ruiz-Fernández, Ana Carolina, van Tussenbroek, Brigitta I., Sanchez-Cabeza, Joan-Albert, Pérez-Bernal, Libia Hascibe, and Cardoso-Mohedano, José Gilberto

Subjects

*NATURE reserves, *SEAGRASSES, *SARGASSUM, *SEDIMENTS, *LAGOONS, *POSIDONIA

Abstract

Seagrass meadow sediments are efficient organic carbon (C org) sinks and can store C org for hundreds of years. The temporal variation of C org burial rates and stocks over recent decades at nearshore seagrass meadows in the Puerto Morelos Reef Lagoon, Mexico, was evaluated in 210Pb-dated sediment cores from nearshore meadows dominated by Thalassia testudinum. The sediments were predominantly sandy (>52% sand) rich in carbonate grains (11.8–12.5% C inorg) with minor C org (0.24–1.12%) and N org (0.02–0.13%) concentrations. The C:N ratio (9.4–13.0) indicated that marine-derived C org was prevalent. C org stocks in the upper 30 cm sediment were 15.9 ± 3.0–24.8 ± 4.6 Mg ha−1. Sedimentary mass accumulation rates (MAR) (0.7–1.5 g cm−2 yr−1) were higher than those previously recorded in seagrass sediments from the reef lagoon and other parts of the world. The highest MAR values, recorded in 2015 (±0.13) and 2018 (±0.03), coincided with the peak sargassum influx years. MAR and C org burial rates (11.4–133 g m−2 yr−1) were correlated (r2 = 0.76), indicating that the massive influxes of sargassum have accelerated C org burial rates in the region since 2015. This study marks the initial evaluation of the interaction between the massive influx of sargassum, MAR, and C org burial rates in seagrass sediments, potentially laying the groundwork for future extended monitoring initiatives. • Organic carbon (C org) stock and burial rates were measured in seagrass sediment cores. • The 210Pb-dated cores were from a natural protected area in the Mexican Caribbean. • Sargassum influx since 2015 accelerated C org burial rates in the region. • Sargassum tides seemed to influence C org dynamics, guiding future monitoring. [ABSTRACT FROM AUTHOR]

Published

2025

3. N2O emission in temperate seagrass meadows: Fluxes, pathway and molecular mechanism.

Author

He, Qianling, Qin, Huawei, Yang, Lin, Tan, Wenwen, Ji, Daode, Zhang, Jianbai, and Zhang, Xiaoli

Subjects

*SEAGRASSES, *POSIDONIA, *ZOSTERA marina, *NITRITE reductase, *NITROUS oxide, *COASTS, *CLIMATE change

Abstract

Seagrass meadows act as filters for nitrogen in coastal areas, but whether they are a source or sink for N 2 O has been still controversy. Additionally, the production pathways of N 2 O as well as the microbial driving mechanism in seagrass meadows are seldom reported. In this study, the air-sea fluxes, sediment release potential, and production pathway of N 2 O in a temperate Zostera marina and Z. japonica mixed meadow were investigated by using gas chromatography and 15N isotopic tracing methods. The qPCR and metagenome sequencing were used to compare the difference in functional gene abundance and expression between seagrass vegetated and non-grass sediments. The results showed that the N 2 O air-sea fluxes in the meadow ranged from −1.97 to −1.77 nmol m⁻2 h⁻1, which was slightly lower in the seagrass region than in the adjacent bare region. Seagrass sediment N 2 O release potential dramatically increased after warming and nitrogen enrichment treatments. Heterotrophic nitrification was firstly investigated in seagrass meadows, and the process (26.80%–62.41%) and denitrification (37.55%–72.83%) contributed significantly to N 2 O production in the meadow, affected deeply by sediment organic content, while the contribution of autotrophic nitrification can be neglected. Compared with the bare sediments, the ammonia monooxygenase genes amoA , amoB and amoC , and nitrite oxidoreductase genes nxrA and nxrB , as well as nitrite reductase gene nirS and nitric oxide reductase gene norB were down-regulated, while the nitrous oxide reductase gene nosZ was up-regulated in the seagrass sediments, explaining less N 2 O emission in seagrass regions from the perspective of molecular. The nosZII -bearing bacteria like Bacteroidia , Polyangia , Anaerolineae , and Verrucomicrobiae could play important roles in N 2 O reduction in the seagrass meadow. The result is of great significance for highlighting the ability of seagrass meadows to mitigate climate changes. • Seagrass meadows could be N 2 O sink in coastal zones. • Warming and nitrogen enrichment enhanced N 2 O emission in seagrass sediments. • Heterotrophic nitrification contributed to N 2 O production in seagrass meadows. • Metagenomic data supported lower N 2 O emission in seagrass regions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Spatial signatures of an approaching regime shift in Posidonia oceanica meadows.

Author

Rindi, Luca, Mintrone, Caterina, Ravaglioli, Chiara, and Benedetti-Cecchi, Lisandro

Subjects

*POSIDONIA oceanica, *POSIDONIA, *ECOLOGICAL integrity, *EFFECT of human beings on climate change, *MARINE ecology, *UNCERTAIN systems

Abstract

Determining the proximity of ecosystems to tipping points is a critical yet complex task, heightened by the growing severity of climate change and local anthropogenic stressors on ecosystem integrity. Spatial Early Warning Signals (EWS) have been recognized for their potential in preemptively signaling regime shifts to degraded states, but their performance in natural systems remains uncertain. In this study, we investigated the performance of 'recovery length' — the spatial extent of recovery from a perturbation — and spatial EWS as early warnings of regime shifts in Posidonia oceanica meadows. Our experimental approach involved progressively thinning the P. oceanica canopy, from 0 to 100%, at the edge of a dead- matte area — a structure formed by dead P. oceanica rhizomes and colonized by algal turfs — to promote the propagation of algal turfs. We calculated recovery length as the distance from the dead- matte edge to the point where algal turfs colonized the canopy-thinned region. Our results showed a linear increase in recovery length with canopy thinning, successfully anticipated the degradation of P. oceanica. While spatial skewness decline with increased canopy degradation, other spatial EWS, such as Moran correlation at lag-1, low-frequency spatial spectra, and spatial variance, were ineffective in signaling this degradation. These findings underscore the potential of recovery length as a reliable early warning indicator of regime shifts in marine coastal ecosystems. • Testing the performance of recovery length and spatial early warnings in detecting regime shifts in P. oceanica meadows. • Recovery length provided an early signal of the impending degradation of P. oceanica. • Unlike other spatial EWS, spatial skewness preemptively signaled canopy degradation. • Recovery length a versatile tool for signaling regime shifts across various coastal ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

5. Multiple scale assessment of habitat, landscape, and geographic-specific attributes driving decapod assemblages in Posidonia oceanica seagrass meadows.

Author

Baud, Marine, Macpherson, Enrique, Pérez, Marta, Romero, Javier, and Ricart, Aurora M.

Subjects

*POSIDONIA, *POSIDONIA oceanica, *SEAGRASSES, *HABITATS, *LANDSCAPES, *BIOMASS

Abstract

Seagrass meadows are biodiversity hotspots for invertebrate species including decapods. Understanding the drivers of species abundance, richness and diversity of decapod assemblages is crucial for the conservation of such hotspots, but how drivers act across multiple spatial scales remains unexplored. Here we describe the decapod assemblages of Posidonia oceanica seagrass meadows and assess the influence of attributes from three increasing spatial scales (habitat, landscape, and geographical levels) on the assemblages' structure and composition, as well as the variability partitioning among each one of these levels. Overall, geographical level attributes (i.e., inlet aperture, confinement) affected the most the decapod assemblages, while we only found a modest contribution from habitat (e.g., detritus biomass, sediment organic matter) and landscape attributes (e.g., fragmentation). We suggest that decapod assemblages are driven by the interaction of multiple processes occurring at different scales and other highly stochastic phenomena such as larval dispersion and recruitment. • We study habitat, landscape, and geographical drivers for seagrass-associated decapods. • We found 47 decapod species and 187 individuals per m2 in Posidonia oceanica meadows. • Geographical attributes explain most of the variation in the decapod assemblages. • At the habitat level, fine detritus biomass is the most relevant driver for decapods. [ABSTRACT FROM AUTHOR]

Published

2024

6. Patch age alters seagrass response mechanisms to herbivory damage.

Author

Jiménez-Ramos, Rocío, Egea, Luis G., Pérez-Estrada, Claudia J., Balart, Eduardo F., Vergara, Juan J., and Brun, Fernando G.

Subjects

*SEAGRASSES, *PHENOLS, *METABOLISM, *PLANT performance, *POSIDONIA, *ECOLOGICAL disturbances

Abstract

Natural disturbances can produce a mosaic of seagrass patches of different ages, which may affect the response to herbivory. These pressures can have consequences for plant performance. To assess how seagrass patch age affects the response to herbivory, we simulated the effect of herbivory by clipping leaves of Halodule wrightii in patches of 2, 4 and 6 years. All clipped plants showed ability to compensate herbivory by increasing leaf growth rate (on average 4.5-fold). The oldest patches showed resistance response by increasing phenolic compounds (1.2-fold). Contrastingly, the concentration of phenolics decreased in the youngest patches (0.26-fold), although they had a similar leaf carbon content to controls. These results suggest that younger plants facing herbivory pressure reallocate their phenolic compounds towards primary metabolism. Results confirm the H. wrightii tolerance to herbivory damage and provides evidence of age-dependent compensatory responses, which may have consequences for seagrass colonization and growth in perturbed habitats. • Effects of seagrass patch age on the response of Halodule wrightii to herbivory. • Evidences of age-dependent compensatory responses to herbivory were found. • Youngest patches presented the highest tolerance responses by increasing leaf growth. • Oldest patches showed resistance response increasing phenolic compounds. • Reallocation of phenolic compounds towards primary metabolism in youngest patches. [ABSTRACT FROM AUTHOR]

Published

2024

7. Plant and sediment properties in seagrass meadows from two Mediterranean CO2 vents: Implications for carbon storage capacity of acidified oceans.

Author

Vizzini, Salvatrice, Apostolaki, Eugenia T., Ricevuto, Elena, Polymenakou, Paraskevi, and Mazzola, Antonio

Subjects

*POSIDONIA, *OCEAN acidification, *SEAGRASSES, *CLIMATE change mitigation, *CARBON cycle, *OCEAN, *CARBON, *LEAF area

Abstract

Abstract Assessing the status of important carbon sinks such as seagrass meadows is of primary importance when dealing with potential climate change mitigation strategies. This study examined plant and sediment properties in seagrass meadows (Cymodocea nodosa (Ucria) Asch.) from two high p CO 2 –low pH Mediterranean vent systems, located at Milos (Greece) and Vulcano (Italy) Islands, providing insights on carbon storage potential in future acidified oceans. Contrary to what has been suggested, carbon content (both inorganic and organic) and its surficial accumulation decreased at high p CO 2 –low pH in comparison with controls. The decrease in inorganic carbon may result from the higher solubility of carbonates due to the more acidic conditions. At Vulcano, the seagrass properties (e.g. , leaf area, biomass) appeared negatively affected by environmental conditions at high p CO 2 –low pH conditions and this may have had a detrimental effect on the organic carbon content and accumulation. At Milos, organic carbon decreased at high p CO 2 –low pH conditions, despite the increase in seagrass aboveground biomass, leaf length and area, probably as a consequence of site-specific features, which need further investigation and may include both biotic and abiotic factors (e.g., oligotrophic conditions, decreased sedimentation rate and input of allochthonous material). Results suggest that, in contrast to previous predictions based exclusively on the expected positive response of seagrasses to ocean acidification, carbon storage capacity of the seagrass C. nodosa may not increase at high p CO 2 -low pH conditions. This study emphasizes the need to investigate further the potential alteration in the climate mitigation service delivered by seagrass meadows in acidified oceans. Highlights • Seagrass features differed between control and low pH stations inconsistently in the two vents. • Carbon content and its surficial accumulation decreased at high p CO 2 –low pH conditions. • Carbon storage capacity of the seagrass may not increase at high p CO 2 -low pH conditions. [ABSTRACT FROM AUTHOR]

Published

2019

8. Sediment carbon storage differs in native and non-native Caribbean seagrass beds.

Author

Brenner, Catherine L., Valdez, Stephanie R., Zhang, Y. Stacy, Shaver, Elizabeth C., Hughes, Brent B., Silliman, Brian R., and Morton, Joseph P.

Subjects

*SEAGRASSES, *POSIDONIA, *CLIMATE change mitigation, *CARBON sequestration, *SEDIMENTS, *CARBON cycle, *CARBON

Abstract

Non-native species are expanding globally and can alter ecosystem functions, including food web dynamics, community structure and carbon storage. Seagrass are foundation species that contribute a variety of ecosystem services in near-shore coastal ecosystems, including a significant sink of carbon. In the Caribbean, the rapidly expanding non-native Halophila stipulacea has unknown impacts on carbon storage. To investigate the impacts on carbon storage, we quantified organic carbon (C org) content in sediment and seagrass tissues from monotypic H. stipulacea beds, mixed native seagrass beds dominated by Thalassia testudinum and Syringodium filiforme, and unvegetated substrate in St. John, USVI. We found native seagrass-vegetated sediment contained 1.3 times more C org than sediment covered by H. stipulacea , and 1.6 times more C org than unvegetated areas on average. Whereas, H. stipulacea -dominated substrate stored 1.2 times more C org than unvegetated substrate. Likewise, native species contained 2.2 times more aboveground biomass and 6.0 times more belowground biomass than H. stipulacea. Since seagrasses are critical sources of carbon sequestration, our results suggest that invading H. stipulacea is associated with lower carbon stocks which has potential implications for conservation activities and climate change mitigation. [Display omitted] • Non-native species are expanding globally and can alter ecosystem functions. • Our results suggest that invading H. stipulacea is associated with lower carbon stocks. • In the Caribbean, rapidly expanding Halophila stipulacea may reduce carbon storage. [ABSTRACT FROM AUTHOR]

Published

2024

9. Effects of seagrass (Cymodocea nodosa) restoration on nematode biodiversity.

Author

Gambi, Cristina, Corinaldesi, Cinzia, Dell'Anno, Antonio, and Danovaro, Roberto

Subjects

*POSIDONIA, *SEAGRASSES, *SEAGRASS restoration, *COASTAL biodiversity, *RESTORATION ecology, *NUMBERS of species, *ANTHROPOGENIC effects on nature, *BIODIVERSITY, *ECOSYSTEMS

Abstract

Seagrass meadows are hot spots of biodiversity and play a key role in the provisioning of ecosystem goods and services but are often subjected to a regression due to a combination of multiple anthropogenic and climate-induced impacts. The ecological restoration of these habitat-forming species is a priority to reverse biodiversity loss and for the recovery of key ecosystem functions. Here we investigated the effects of seagrass (Cymodocea nodosa) restoration action on benthic biodiversity recovery assessed by a time-series analysis carried out for one year. We used nematode assemblages, the most widespread metazoan on global sediments, as a proxy of benthic biodiversity and compared the species richness, expected species number (ES51) and composition in donor and in restored seagrasses and in the adjacent unvegetated sediments. One year after the intervention, nematode biodiversity in restored seagrasses was more similar to that of the donor site than in unvegetated sediments, suggesting a progressive recovery. Overall, the nematode biodiversity of the restored seagrasses resulted in an intermediate level between unvegetated and pristine seagrass meadows, providing evidence that restoration intervention contributed to biodiversity recovery. Pristine and restored seagrass meadows hosted a high number of exclusive species, which resulted in an increase in the overall biodiversity in the investigated location. Our results indicate that the restoration of seagrass meadows has positive effects on benthic biodiversity and contributes to enhance the local biodiversity. • Nematode biodiversity in restored seagrasses recovers to values similar to the donor sites. • Pristine and restored seagrass meadows host a high number of exclusive species. • Seagrass restoration promotes high levels of benthic biodiversity. • Pristine and restored seagrasses enhance the local biodiversity of the coastal area. [ABSTRACT FROM AUTHOR]

Published

2024

10. Inoculation with plant growth-promoting rhizobacteria improves seagrass Thalassia hemprichii photosynthesis performance and shifts rhizosphere microbiome.

Author

Zhou, Weiguo, Ling, Juan, Shen, Xiaomei, Xu, Zhimeng, Yang, Qingsong, Yue, Weizhong, Liu, Hongbin, Suo, Anning, and Dong, Junde

Subjects

*PLANT growth-promoting rhizobacteria, *PLANT inoculation, *POSIDONIA, *RHIZOSPHERE, *SEAGRASSES, *ZOSTERA marina, *SEAGRASS restoration, *NITROGEN cycle, *ECOSYSTEMS

Abstract

Plant growth-promoting rhizobacteria (PGPR) inoculation is a crucial strategy for maintaining the sustainability of agriculture and presents a promising solution for seagrass ecological restoration in the face of disturbances. However, the possible roles and functions of PGPRs in the seagrass rhizosphere remain unclear. Here, we isolated rhizosphere bacterial strains from both reef and coastal regions and screened two PGPR isolates regarding their in vivo functional traits. Subsequently, we conducted microcosm experiments to elucidate how PGPR inoculation affected seagrass photosynthesis and shape within each rhizosphere microbiome. Both screened PGPR strains, Raoultella terrigena NXT28 and Bacillus aryabhattai XT37, excelled at expressing a specific subset of plant-beneficial functions and increased the photosynthetic rates of the seagrass host. PGPR inoculation not only decreased the abundance of sulfur-cycling bacteria, it also improved the abundance of putative iron-cycling bacteria in the seagrass rhizosphere. Strain XT37 successfully colonized the seagrass rhizosphere and displayed a leading role in microbial network structure. As a nitrogen-fixing bacteria, NXT28 showed potential to change the microbial nitrogen cycle with denitrification in the rhizosphere and alter dissimilatory and assimilatory nitrate reduction in bulk sediment. These findings have implications for the development of eco-friendly strategies aimed at exploiting microbial communities to confer sulfide tolerance in coastal seagrass ecosystem. • Two PGPR strains were screened from different seagrass species in both reef and coastal regions. • PGPR strains increased the photosynthetic rates of seagrass host. • PGPR inoculation inhibited and enriched the abundance of iron- and sulfur-cycling bacterial taxa, respectively. • The colonization of the seagrass rhizosphere by Bacillus aryabhattai XT37 played a leading role in the microbial network. [ABSTRACT FROM AUTHOR]

Published

2024

11. Interactive effects of global warming and eutrophication on a fast-growing Mediterranean seagrass.

Author

Ontoria, Yaiza, Gonzalez-Guedes, Eva, Sanmartí, Neus, Bernardeau-Esteller, Jaime, Ruiz, Juan M., Romero, Javier, and Pérez, Marta

Subjects

*POSIDONIA, *GLOBAL warming, *EUTROPHICATION

Abstract

Abstract Coastal ecosystems, such as seagrasses, are subjected to local (e.g. eutrophication) and global (e.g. warming) stressors. While the separate effects of warming and eutrophication on seagrasses are relatively well known, their joint effects remain largely unstudied. In order to fill this gap, and using Cymodocea nodosa as a model species, we assessed the joint effects of warming (three temperatures, 20 °C, 30 °C and 35 °C) with two potential outcomes of eutrophication: (i) increase in nutrients concentration in the water column (30 and 300 μM), and (ii) organic enrichment in the sediment). Our results confirm that temperature in isolation clearly affects plant performance; while plants exposed to 30 °C performed better than control plants, plants exposed to 35 °C showed clear symptoms of deterioration (e.g. decline of photosynthetic capacity, increase of incidence of necrotic tissue). Plants were unaffected by high ammonium concentrations; however, organic enrichment of sediment had deleterious effects on plant function (photosynthesis, growth, demographic balance). Interestingly, these negative effects were exacerbated by increased temperature. Our findings indicate that in addition to the possibility of the persistence of C. nodosa being directly jeopardized by temperature increase, the joint effects of warming and eutrophication may further curtail its survival. This should be taken into consideration in both predictions of climate change consequences and in local planning. Highlights • Temperature increase (up to 30 °C) favors Cymodocea nodosa performances. • Ammonium addition (up to 300 μM) has no negative effects on plants. • C. nodosa is severely altered by organically enriched sediments. • The joint effects of warming and organic C addition may curtail plant survival. [ABSTRACT FROM AUTHOR]

Published

2019

12. The role epiphytes play in particle capture of seagrass canopies.

Author

Barcelona, Aina, Colomer, Jordi, Serra, Teresa, Cossa, Damboia, and Infantes, Eduardo

Subjects

*POSIDONIA, *SUSPENDED sediments, *ZOSTERA marina, *SEDIMENTATION & deposition, *SEAGRASSES, *BIOINDICATORS, *LEAF area

Abstract

Seagrass epiphytic communities act as ecological indicators of the quality status of vegetated coastal environments. This study aims to determine the effect leaf epiphytes has on the sediment capture and distribution from outside sources. Thirteen laboratory experiments were conducted under a wave frequency of 0.5 Hz. Three epiphyte models were attached to a Zostera marina canopy of 100 plants/m2 density. The sediment deposited to the seabed, captured by the epiphytic leaf surface, and remaining in suspension within the canopy were quantified. This study demonstrated that the amount of epiphytes impacts on the sediment stocks. Zostera marina canopies with high epiphytic areas and long effective leaf heights may increase the sediment captured on the epiphyte surfaces. Also, reducing suspended sediment and increasing the deposition to the seabed, therefore enhancing the clarity of the water column. For largest epiphytic areas, a 34.5% increase of captured sediment mass is observed. The sediment trapped on the leaves can be 10 times greater for canopies with the highest epiphytic areas than those without epiphytes. Therefore, both the effective leaf length and the level of epiphytic colonization are found to determine the seagrass canopy ability at distributing sediment. • Epiphytes modify the sediment capture by eelgrass canopies. • Sediment trapped on leaves increases as epiphytic areas and leaf lengths increase. • High epiphyed canopies decrease the sediment settled to the seabed. • High epiphytic areas and long leaf lengths decrease the suspended sediment. [ABSTRACT FROM AUTHOR]

Published

2023

13. Effects of heatwave events on the seagrass-dwelling crustacean Pandalus latirostris in a subarctic lagoon.

Author

Matsumoto, Hiroyuki, Azuma, Noriko, and Chiba, Susumu

Subjects

*HEAT waves (Meteorology), *LAGOONS, *WATER temperature, *SEAGRASSES, *POSIDONIA, *WATER depth, *OCEAN zoning, *CRUSTACEA

Abstract

Heatwaves often cause mass mortality of organisms in seagrass areas, and they eventually alter some ecological functions of seagrass ecosystems. In subarctic regions, however, the effects of heatwaves on seagrass areas are still unclear. In a subarctic lagoon of northern Japan, we examined the effects of heatwaves on the Hokkai shrimp, Pandalus latirostris , a commercially exploited species distributed in seagrass areas of northern Japan and eastern Russia. A long-term survey of the surface water temperature in the lagoon clarified a gradual increase in the frequency and intensity of heatwave events since 1999. Surveys of the water temperature at a seagrass area in the lagoon during summer have also demonstrated that the maximum water temperature had been exceeding 25 °C, unusually high for this location, regardless of water depth. These results indicate that the effects of heatwaves in seagrass areas in a subarctic region had become as severe as those in tropical and temperate regions. We also experimentally evaluated the effects of this unusually high water temperature (25 °C) on the survival of P. latirostris by changing the length of exposure time. Some individuals suffered damage to their intestinal mucosal structure after exposure for 12 h or longer, and all individuals died after exposure for 120 h. Our results suggest that heatwaves possibly cause mass mortality in P. latirostris in the following sequence: heat stress, damage to the intestinal epithelial mucosal structure, degradation of nutrient absorption and immunological function of the intestine, energy deficiency and disease infection, and finally mortality. This study, conducted in subarctic closed waters, concludes that it is essential to become familiar with not only trends in heatwaves but also the intermittent occurrence of unusually high water temperature in seagrass areas in order to better understand the process of mortality of organisms that inhabit these ecosystems. • Frequency and intensity of heatwave events have increased in subarctic lagoons as well as tropical and temperate zones of oceans. • High water temperature affects the survival rate and physiological condition of shrimp. • Heatwaves can cause mass mortality in shrimp through gut damage, reduced nutrient absorption, weakened immunity, energy depletion, and increased disease vulnerability. [ABSTRACT FROM AUTHOR]

Published

2023

14. Cultivable mycoflora on bleached, decaying and healthy Posidonia oceanica leaves in a warm-edge Mediterranean location.

Author

Stipcich, Patrizia, Balmas, Virgilio, Jimenez, Carlos E., Oufensou, Safa, and Ceccherelli, Giulia

Subjects

*POSIDONIA oceanica, *POSIDONIA, *MARINE fungi, *PHYTOPATHOGENIC microorganisms, *SEAGRASSES, *FUNGI

Abstract

Marine fungi are widely distributed in the ocean, playing an important role in the ecosystems, but only little information is available about their occurrence and activity. Seagrass bleaching is also a neglected phenomenon that seems to be linked to warm environments, even though the causes are still to be defined. In this study, the cultivable mycoflora associated to the leaf conditions (bleached, necrotic and live) and section (from the base to the tip) in the seagrass Posidonia oceanica was investigated in a Mediterranean warm-edge location (Cyprus). A total of 17 Ascomycota species/taxon were identified and results highlighted that mycoflora composition changed significantly in relation to both the leaf condition and section. A few known pathogens of terrestrial plants were detected only on bleached leaves, but it remains unknown whether they have any direct connections with P. oceanica bleaching phenomenon. • Warming affects the condition of seagrass leaves and mycobiota distribution. • The mycoflora in live, necrotic and bleached P. oceanica leaves was investigated. • The fungal taxa may reflect a fungal succession linked to the leaf decomposition. • A few pathogens of terrestrial plants were detected only on bleached leaves. • A connection within the pathogens and seagrass bleaching remains unknown. [ABSTRACT FROM AUTHOR]

Published

2023

15. Vegetative fragment production as a means of propagule dispersal for tropical seagrass meadows.

Author

Tol, S.J., Carter, A.B., York, P.H., Jarvis, J.C., Grech, A., Congdon, B.C., and Coles, R.G.

Subjects

*SEAGRASSES, *POSIDONIA, *WORLD Heritage Sites, *ECOSYSTEM management, *ZOSTERA, *WIND speed, *GROWING season

Abstract

Long distance dispersal (LDD) contributes to the replenishment and recovery of tropical seagrass habitats exposed to disturbance, such as cyclones and infrastructure development. However, our current knowledge regarding the physical attributes of seagrass fragments that influence LDD predominantly stems from temperate species and regions. The goal of this paper is to measure seagrass fragment density and viability in two tropical species, assessing various factors influencing their distribution. We measured the density and viability of floating seagrass fragments for two tropical seagrass species (Zostera muelleri and Halodule uninervis) in two coastal seagrass meadows in the central Great Barrier Reef World Heritage Area, Australia. We assessed the effect of wind speed, wind direction, seagrass growing/senescent season, seagrass meadow density, meadow location and dugong foraging intensity on fragment density. We also measured seagrass fragment structure and fragment viability; i.e., potential to establish into a new plant. We found that seagrass meadow density, season, wind direction and wind speed influenced total fragment density, while season and wind speed influenced the density of viable fragments. Dugong foraging intensity did not influence fragment density. Our results indicate that wave action from winds combined with high seagrass meadow density increases seagrass fragment creation, and that more fragments are produced during the growing than the senescent season. Seagrass fragments classified as viable for Z. muelleri and H. uninervis had significantly more shoots and leaves than non-viable fragments. We collected 0.63 (±0.08 SE) floating viable fragments 100 m−2 in the growing season, and 0.13 (±0.03 SE) viable fragments 100 m−2 in the senescent season. Over a third (38%) of all fragments collected were viable. There is likely to be a large number of viable seagrass fragments available for long distance dispersal. This study's outputs can inform dispersal and connectivity models that are used to direct seagrass ecosystem management and conservation strategies. • There are large numbers of viable seagrass fragments available for dispersal. • Moderate winds with high seagrass density increases seagrass fragment creation. • More seagrass fragments are produced during the growing than the senescent season. • Seagrass fragments have more shoots and leaves than non-viable fragments. • Over a third (38%) of all floating fragments are viable. [ABSTRACT FROM AUTHOR]

Published

2023

16. Tolerance to aerial exposure influences distributional patterns in multi-species intertidal seagrass meadows.

Author

Rao, Rachana, Alcoverro, Teresa, Kongari, Phoolmani, Yoayela, Saw, Arthur, Rohan, and D'Souza, Elrika

Subjects

*POSIDONIA, *SEAGRASSES, *INTERTIDAL zonation, *SPECIES distribution, *COMPLEX matrices, *STRESS concentration, *SPECIES diversity

Abstract

Multi-specific seagrass meadow assemblages dominate most tropical intertidal regions but the relative role of environmental stress in determining distribution patterns is still uncertain. Here we combine observational and experimental approaches to examine aerial exposure as a factor driving species occurrence patterns in intertidal meadows of the Andaman archipelago, where up to 6 seagrass species co-occur. In the studied meadow, patterns of exposure did not map onto distance from the coast, instead creating a patchy matrix of exposure, based on fine-scale bathymetric differences. Distributional surveys showed that seagrass species were similarly patchy, often tracking the degree of aerial exposure during low tide. While some species (Halophila ovalis, Halophila minor, and Thalassia hemprichii) frequently occurred in submerged or subtidal areas and were rarely found in completely exposed areas, other species (Cymodocea rotundata , Halophila beccarii, and Halodule uninervis) also occupied areas that were subject to partial or complete aerial exposure during low tide. To confirm this pattern, we used field-based transplant experiments, employing a natural gradient of tidal exposure to subject six seagrass species to different desiccation exposure times. After a month, H. beccarii and H. uninervis transplants survived in areas that sustained more than 3 h of aerial tidal exposure without significant mortality, compared with other species (H. ovalis, H. minor, T. hemprichii, C. rotundata) that showed dramatic shoot mortality at the same exposure regimes. For all species, 4 h represented the upper limit of exposure, in both experimental and distributional studies. However, despite their wider tolerance of exposure to air, H. beccarii and H. uninervis did not dominate the entire meadow. This could be a result either of their poor tolerance to other environmental factors or their lower competitive abilities among other mechanisms. This suggests that in tropical multi-specific meadows, strong environmental filters could override clear intertidal zonation to create patchy matrices based on species tolerances. Key findings of the research showing seagrass species distribution in the intertidal region that can be explained based on individual species tolerance to aerial exposure. Seagrass symbol source: https://vecta.io/symbols/304/flora-seagrass-sav. [Display omitted] • Intertidal seagrass meadows get exposed to air as water recedes during low tide. • Small-scale bathymetric variation creates a complex matrix of aerial exposure. • Seagrass species distributions are similarly patchy, tracking aerial exposure. • Transplant experiments showed strong species-wise differences in exposure tolerance. • Strong environmental filters drive the assembly of multispecies intertidal meadows. Synthesis : Our work shows that in shallow intertidal seagrass meadows, the fine-scale distribution of exposure acts as a strong environmental filter determining distributional patterns and likely mediating species diversity. [ABSTRACT FROM AUTHOR]

Published

2023

17. Effects of herbivore on seagrass, epiphyte and sediment carbon sequestration in tropical seagrass bed.

Author

Jiang, Zhijian, He, Jialu, Fang, Yang, Lin, jizhen, Liu, Songlin, Wu, Yunchao, and Huang, Xiaoping

Subjects

*POSIDONIA, *CARBON sequestration, *SEAGRASSES, *SEAGRASS restoration, *POLYPHENOL oxidase, *COMPETITION (Biology), *CARBON cycle

Abstract

Herbivores strongly affect the ecological structure and functioning in seagrass bed ecosystems, but may exhibit density-dependent effects on primary producers and carbon sequestration. This study examined the effects of herbivorous snail (Cerithidea rhizophorarum) density on snail intraspecific competition and diet, dominant seagrass (Thalassia hemprichii) and epiphyte growth metrics, and sediment organic carbon (SOC). The growth rates of the herbivorous snail under low density (421 ind m−2) and mid density (842 ind m−2) were almost two times of those at extremely high density (1684 ind m−2), indicating strong intraspecific competition at high density. Herbivorous snails markedly reduced the epiphyte biomass on seagrass leaves. Additionally, the seagrass contribution to herbivorous snail as food source under high density was about 1.5 times of that under low density, while the epiphyte contribution under low density was 3 times of that under high density. A moderate density of herbivorous snails enhanced leaf length, carbon, nitrogen, total phenol and flavonoid contents of seagrasses, as well as surface SOC content and activities of polyphenol oxidase and β-glucosidase. However, high density of herbivorous snails decreased leaf glucose, fructose, detritus carbon, and total phenols contents of seagrasses, as well as surface SOC content and activities of polyphenol oxidase and β-glucosidase. Therefore, the effects of herbivorous snail on seagrass, epiphyte and SOC were density-dependent, and moderate density of herbivorous snail could be beneficial for seagrasses to increase productivity. This provided theoretical guidance for enhancing carbon sink in seagrass bed and its better conservation. [Display omitted] • Intraspecific competition inhibited herbivorous snail growth. • The presence of herbivorous snail markedly reduced the epiphyte biomass. • Moderate snail density facilitated seagrass by removing epiphyte and enhanced SOC. • High snail density adversely affected seagrass and sediment carbon sequestration. • Cultivate herbivore in moderate density benefits seagrass conservation. [ABSTRACT FROM AUTHOR]

Published

2023

18. Effects of anthropogenic pressures on the seagrass Halophila stipulacea and its associated macrozoobenthic communities in the northern Gulf of Aqaba.

Author

Nguyen, Hung Manh, Andolina, Cristina, Vizzini, Salvatrice, Gambi, Maria Cristina, and Winters, Gidon

Subjects

*COMMUNITIES, *POSIDONIA, *SEAGRASSES, *STABLE isotope analysis, *HABITATS, *BENTHIC animals, *BIOTIC communities

Abstract

Halophila stipulacea is a tropical seagrass species, native to the Red Sea, Persian Gulf, and Indian Ocean, while invasive to the Mediterranean and Caribbean Seas. The benthic fauna assemblages associated with H. stipulacea in its native habitats and the potential effects of anthropogenic stressors on these assemblages remain unknown. We compared meadow characteristics, associated fauna assemblages and trophic niche structures of H. stipulacea from an impacted and a pristine site in the northern Red Sea. Seagrass cover and biomass were higher in the impacted site, however, the associated fauna community was more abundant and diverse in the pristine site. Both meadows showed comparable trophic niches based on stable isotope analysis. This study provides first insights into the macrozoobenthos associated with H. stipulacea in its native habitat and highlights the importance of better understanding the relationship between seagrasses and their associated biota and the potential effects of urbanization on this relationship. [Display omitted] • Meadow characteristics of Halophila stipulacea and its associated fauna assemblages in the northern Gulf of Aqaba. • Meadows were denser in the anthropogenic impacted site than in the pristine site. • The associated fauna community was more abundant and diverse in the pristine site. • Comparable trophic diversity and redundancy were found in both sites. [ABSTRACT FROM AUTHOR]

Published

2023

19. Unexpected slow recovery of seagrass leaf epiphytes after the impact of a summer heat wave and concomitant mucilage bloom.

Author

Gallo, Elena, Oprandi, Alice, Bianchi, Carlo Nike, Morri, Carla, Azzola, Annalisa, and Montefalcone, Monica

Subjects

*POSIDONIA, *HEAT waves (Meteorology), *EPIPHYTES, *MUCILAGE, *SEAGRASSES, *POSIDONIA oceanica

Abstract

The epiphytes of seagrass leaves constitute a peculiar community, comprised of a number of species specialized for this living substrate. Several studies report on the response of epiphytes to different pressures but no information exists about the effects of summer heatwaves, which have become frequent events in the last decades. This paper represents the first attempt to investigate the change in the leaf epiphyte community of the Mediterranean seagrass Posidonia oceanica due to the heatwave occurred in summer 2003. Thanks to a series of data collected seasonally between 2002 and 2006, and punctual data in the summers of 2014 and 2019, we assessed the change over time in the leaf epiphyte community. Temperature data trends were analysed through linear regression, while multivariate analyses (i.e., nMDS and SIMPER) were applied to cover data in order to assess changes over time in the epiphyte community. As a whole, the two most abundant taxa were the crustose coralline alga Hydrolithon and the encrusting bryozoan Electra posidoniae , which displayed the highest average cover values in summer (around 19%) and spring (around 9%), respectively. Epiphytes proved to be sensitive to temperature highs, displaying different effects on cover, biomass, diversity and community composition. Cover and biomass exhibited a dramatic reduction (more than 60%) after the disturbance. In particular, Hydrolithon more than halved, while E. posidoniae dropped sevenfold during summer 2003. While the former recovered comparatively quickly, the latter, as well as the whole community composition, apparently required 16 years to return to a condition similar to that of 2002. • Seagrass leaf epiphytes constitute a specialized community. • Epiphytes of Posidonia oceanica have been impacted by summer heatwave in 2003. • Epiphytic cover and biomass exhibited a dramatic reduction. • Epiphyte community composition required 16 years to recover. [ABSTRACT FROM AUTHOR]

Published

2023

20. Spatial sedimentation and plant captured sediment within seagrass patches.

Author

Barcelona, Aina, Colomer, Jordi, and Serra, Teresa

Subjects

*SUSPENDED sediments, *POSIDONIA, *SEDIMENTS, *SEAGRASSES, *SEA level, *SEDIMENTATION & deposition, *CLIMATE change, *FOLIAGE plants

Abstract

Habitat degradation in coastal ecosystems has resulted in the fragmentation of coastal aquatic vegetation and compromised their role in supplying essential ecological services such as trapping sediment or sequestering carbon. Fragmentation has changed seagrass architecture by decreasing the density of the canopy or engendering small patches of vegetated areas. This study aims to quantify the role different patch sizes of vegetation with different canopy densities have in the spatial distribution of sediment within a patch. To this aim, two canopy densities, four different patch lengths, and two wave frequencies were considered. The amounts of sediment deposited onto the bed, captured by plant leaves, remaining in suspension within the canopy, and remaining in suspension above the canopy were used to understand the impact hydrodynamics has on sediment distribution patterns within seagrass patches. In all the cases studied, patches reduced the suspended sediment concentrations, increased the capture of particles in the leaves, and increased the sedimentation rates to the bed. For the lowest wave frequency studied (0.5 Hz), the sediment deposited to the bottom was enhanced at canopy edges, resulting in spatial heterogeneous sedimentation patterns. Therefore, restoration and preservation of coastal aquatic vegetation landscapes can help face future climate change scenarios where an increase in sedimentation can help mitigate predicted sea level rise in coastal areas. • Larger and denser seagrass patches increase the sedimentation within the patch. • Larger and denser seagrass patches increase the leaves particle capture. • Suspended sediment concentration decreases as the patch length and density increases. • Heterogeneous sedimentation patterns hold within patches under low wave frequencies. [ABSTRACT FROM AUTHOR]

Published

2023

21. Insights into autotrophic carbon fixation strategies through metagonomics in the sediments of seagrass beds.

Author

Chi, Xiangqun, Zhao, Zhiyi, Han, Qiuxia, Yan, Huaxiao, Ji, Bei, Chai, Yating, Li, Shengying, and Liu, Kun

Subjects

*CARBON fixation, *CARBON cycle, *SEAGRASSES, *SEDIMENTS, *TRICARBOXYLIC acids, *POSIDONIA, *SEDIMENT sampling

Abstract

Seagrass beds contributes up to 10% ocean carbon storage. Carbon fixation in seagrass bed greatly affect global carbon cycle. Currently, six carbon fixation pathways are widely studied: Calvin, reductive tricarboxylic acid (rTCA), Wood-Ljungdahl (WL), 3-hydroxypropionate (3HP), 3-hydroxypropionate/4-hydroxybutyrate (3HP/4HB) and dicarboxylate/4-hydroxybutyrate (DC/4-HB). Despite the knowledges about carbon fixation increase, the carbon fixation strategies in seagrass bed sediment remain unexplored. We collected seagrass bed sediment samples from three sites with different characteristics in Weihai, a city in Shandong, China. The carbon fixation strategies were investigated through metagenomics. The results exhibited that five pathways were present, of which Calvin and WL were the most dominant. The community structure of microorganisms containing the key genes of these pathways were further analyzed, and those dominant microorganisms with carbon fixing potential were revealed. Phosphorus significantly negatively corelated with those microorganisms. This study provides an insight into the strategies of carbon fixation in seagrass bed sediments. [Display omitted] • Metagenomics of key enzymes in fixation pathways indicate the pathway's niche. • Calvin and Wood-Ljungdahl pathways play important roles in carbon fixation. • The nutrients of nitrogen and phosphorus can affect the carbon fixation strategies. • Wood-Ljungdahl pathways negatively correalted with high phosphorus concentration. • Oxygen may be a critical factor determining the niches of carbon fixation pathways. [ABSTRACT FROM AUTHOR]

Published

2023

22. Effect of shading imposed by the algae Chaeotomorpha linum loads on structure, morphology and physiology of the seagrass Cymodocea nodosa.

Author

Zribi, Imen, Ellouzi, H., Mnasri, I., Abdelkader, N., Ben Hmida, A., Dorai, S., Debez, A., Charfi-Cheikhrouha, F., and Zakhama-Sraieb, R.

Subjects

*POSIDONIA, *SEAGRASSES, *ALGAE, *TERRITORIAL waters, *PHOTOSYNTHETIC pigments, *SHOOTING (Sports), *PHYSIOLOGY

Abstract

In shallow coastal waters, seagrass and macroalgae occur together but under eutrophic conditions, bloom-forming algae can take over seagrasses causing an irreversible regime shift. Understanding the effect of macroalgae loads on seagrass meadows at an early stage can help prevent the loss of these ecosystems and the services they provide. In the present study, in situ experiments were conducted for 90 days in Bekalta (eastern coast of Tunisia) to assess the response of the seagrass Cymodocea nodosa when challenged with shading induced by filamentous macroalgae Chaetomorpha linum. Structural, morphological and physiological variables were regularly measured during the experiment. Shaded plants showed a sharp decline in shoot density, growth rate, and above-ground biomass, the impact being more pronounced on the physiological traits. Besides, shading by C. linum induced a significant increase in the contents of leaf photosynthetic pigments and phenolic compounds, whereas causing a decrease in soluble protein and sugar concentrations. Thus, shading imposed by C. linum loads appeared to induce a phoadpatative response in C. nodosa concomitant with carbon mobilization. [Display omitted] • Cymodocea nodosa' s physiological traits may indicate stress from Cymodocea nodosa' s physiological traits may indicate stress from chaetomorpha linum. • Morphology changes and photoadaptation help Cymodocea nodosa cope with C haetomorpha linum 's shading. • The harmful impact of Chaetomorpha linum on Cymodocea nodosa is mainly due to light limitation. [ABSTRACT FROM AUTHOR]

Published

2023

23. Reconstructed life history metrics of the iconic seagrass Posidonia oceanica (L.) detect localized anthropogenic disturbance signatures.

Author

McDonald, Ashley M., McDonald, Rachel B., Cebrian, Just, and Sánchez Lizaso, José Luis

Subjects

*POSIDONIA, *POSIDONIA oceanica, *LIFE history theory, *SEAGRASSES, *AGE distribution, *TRAWLING

Abstract

Substantial losses of the seagrass Posidonia oceanica have initiated investigations into localized resilience declines related to anthropogenic disturbances. In this study, we determined reconstructed shoot age and interannual growth metrics can detect anthropogenic impact effects on P. oceanica production. Interannual rhizome vertical growth, leaf production, and demographics of shoots collected from sewage and trawling impacted areas were examined using mixed effects modeling. Detected impact effects were specific to the type of impact, manifesting as an older-skewed age distribution of sewage outfall shoots and reduced vertical growth and reduced leaf production of trawling site shoots. A stress event period was also detected for all shoots >5 years old, with trawling impacted shoots indicating little recovery. Reconstructed age and growth metrics are simple to measure, incorporate multiple years of in situ shoot development, and are advantageous for identification of declining P. oceanica resilience prior to catastrophic losses. • Localized stressors lower Posidonia oceanica resilience to larger-scale disturbances. • We examined stress impacts through reconstruction of P. oceanica life history. • Sewage and trawling impacts were elucidated using reconstruction methods. • The way P. oceanica life history was influenced differed by stressor type. • Trawl impacted seagrass showed evidence of low recovery from large-scale stressor. [ABSTRACT FROM AUTHOR]

Published

2023

24. Field development of Posidonia oceanica seedlings changes under predicted acidification conditions.

Author

Pansini, Arianna, Beca-Carretero, Pedro, Berlino, Manuel, Sarà, Gianluca, Stengel, Dagmar B., Stipcich, Patrizia, and Ceccherelli, Giulia

Subjects

*POSIDONIA, *POSIDONIA oceanica, *OCEAN acidification, *SEEDLINGS, *ACIDIFICATION, *CARBON dioxide

Abstract

Ocean acidification has been consistently evidenced to have profound and lasting impacts on marine species. Observations have shown seagrasses to be highly susceptible to future increased p CO 2 conditions, but the responses of early life stages as seedlings are poorly understood. This study aimed at evaluating how projected Mediterranean Sea acidification affects the survival, morphological and biochemical development of Posidonia oceanica seedlings through a long-term field experiment along a natural low pH gradient. Future ocean conditions seem to constrain the morphological development of seedlings. However, high p CO 2 exposures caused an initial increase in the degree of saturation of fatty acids in leaves and then improved the fatty acid adjustment increasing unsaturation levels in leaves (but not in seeds), suggesting a nutritional compound translocation. Results also suggested a P. oceanica structural components remodelling which may counteract the effects of ocean acidification but would not enhance seagrass seedling productivity. • Development of Posidonia oceanica seedlings was investigated in field predicted OA. • OA limits the stimulation of P. oceanica early life stage morphological development. • FA remodelling improves the seedling resilience to prolonged exposures of low sea pH. • Increased CO 2 availability would not enhance seagrass seedling productivity. [ABSTRACT FROM AUTHOR]

Published

2023

25. Drivers of variation in seagrass-associated amphipods across biogeographical areas.

Author

Navarro-Mayoral, Sandra, Tuya, Fernando, Prado, Patricia, Marco-Méndez, Candela, Fernandez-Gonzalez, Victoria, Fernández-Torquemada, Yolanda, Espino, Fernando, Antonio de la Ossa, Jose, Vilella, David Mateu, Machado, Margarida, and Martínez-Crego, Begoña

Subjects

*POSIDONIA, *AMPHIPODA, *LEAF area, *SPECIES diversity, *SEAGRASSES, *BIOMASS

Abstract

Amphipods are one of the dominant epifaunal groups in seagrass meadows. However, our understanding of the biogeographical patterns in the distribution of these small crustaceans is limited. In this study, we investigated such patterns and the potential drivers in twelve Cymodocea nodosa meadows within four distinctive biogeographical areas across 2000 Km and 13° of latitude in two ocean basins (Mediterranean Sea and Atlantic Ocean). We found that species abundances in the assemblage of seagrass-associated amphipods differed among areas following a pattern largely explained by seagrass leaf area and epiphyte biomass, while the variation pattern in species presence/absence was determined by seagrass density and epiphyte biomass. Seagrass leaf area was also the most important determinant of greater amphipod total density and species richness, while amphipod density also increased with algal cover. Overall, our results evidenced that biogeographical patterns of variation in amphipod assemblages are mainly influenced by components of the habitat structure, which covary with environmental conditions, finding that structurally more complex meadows harboring higher abundance and richness of amphipods associated. • We examine drivers of variation in seagrass-associated amphipods across 2000 Km in two ocean basins. • Structurally more complex meadows host greater density and richness of amphipods. • Seagrass leaf area drives higher amphipod total density and species richness, and the former also increase with algal cover. • Seagrass density and epiphyte biomass drive variation in species identity, while leaf area and epiphyte biomass explain abundances. • Attributes of habitat structural complexity selected as predictors covary with environmental factors. [ABSTRACT FROM AUTHOR]

Published

2023

26. Are clam-seagrass interactions affected by heatwaves during emersion?

Author

Román, Marta, Gilbert, Franck, Viejo, Rosa M., Román, Salvador, Troncoso, Jesús S., Vázquez, Elsa, and Olabarria, Celia

Subjects

*SEAGRASSES, *HEAT waves (Meteorology), *MANILA clam, *POSIDONIA, *SEAGRASS restoration, *GLOBAL warming, *PORE water, *CLAMS

Abstract

The increased frequency of heatwaves expected in the context of global warming will affect socio-ecological systems such as shellfish beds at intertidal seagrass meadows. A mesocosm experiment was performed to assess the effects of a simulated atmospheric heatwave during low tide on the bioturbation indicators and growth of the commercial juvenile native Ruditapes decussatus and the introduced clam R. philippinarum, and on their interactions with the seagrass Zostera noltei. Under the heatwave, heat dissipation at 5 cm depth was significantly greater in the sediments below Z. noltei than below bare sand, the photosynthetic efficiency (F v /F m) of Z. noltei decreased and the clams tended to grow less. Furthermore, after the heatwave clams below bare sand tended to burrow deeper than those below Z. noltei, indicating that seagrass provided a refuge for clams. Ruditapes philippinarum grew less, and did not burrow as deeply as R. decussatus , which may imply greater vulnerability to desiccation and heat at low tide. The particle displacement coefficient (PDC) of R. philippinarum indicated lower bioturbation values in Z. noltei than in bare sand and was a suitable bioturbation indicator for juvenile Ruditapes spp. clams. In Z. noltei coexisting with R. philippinarum , the F v /F m values were higher than without clams after a recovery period, which may be linked to the assimilation of phosphate excreted by the clams and suggests a facilitative interaction. No such interaction was observed with R. deccusatus , probably because of its deeper burrowing depth. The findings suggest reciprocal facilitative interactions between R. philippinarum and Z. noltei and the potential contribution of Z. noltei to the sustainability of clams under global warming scenarios, which may support management actions aimed at enhancing the coexistence between shellfishing activities and seagrass conservation. [Display omitted] • The effect of a heatwave during low tide on clam - seagrass interactions was tested. • Clam bioturbation and growth, seagrass photosynthetic efficiency (F v /F m) and pore water nutrients were measured. • Heat dissipation in the sediment was greater below Z. noltei than below bare sand. • The particle displacement coefficient was a good bioturbation indicator for venerids • F v /F m in Z. noltei and PO 4 3− in pore water increased with R. philippinarum. [ABSTRACT FROM AUTHOR]

Published

2023

27. Mapping seagrasses on the basis of Sentinel-2 images under tidal change.

Author

Li, Yiqiong, Bai, Junwu, Chen, Shiquan, Chen, Bowei, and Zhang, Li

Subjects

*SEAGRASSES, *POSIDONIA, *COASTAL zone management, *TIDE-waters, *TIDAL flats, *REMOTE sensing, *BODIES of water

Abstract

Tidal variations make the water bodies in satellite remote sensing images on different shooting dates have different inundation ranges and depths. Although the underwater substrates do not change, the spectral properties differ due to attenuation effects. These differences have an impact on the results when multi-temporal remote sensing images are used to analyze seagrasses. This paper proposes a remote sensing mapping method for seagrasses taking the tidal influence, using the seagrasses growth area in Xincun Bay, Hainan Province, China as a case study. a) The seagrasses growth area was determined from remote sensing images. The seagrasses were divided into two types: the seagrasses exposed to water surface or tidal flats (non-submerged seagrasses) and the seagrasses submerged in water (submerged seagrasses). b) The spectral features of seagrasses in Sentienl-2 image were analyzed. We found that the spectral characteristics of non-submerged seagrasses were similar to terrestrial vegetation and these seagrasses could be extracted by using NDVI. The submerged seagrasses spectral was different, forming a reflection peak at the first vegetation red edge band (i.e.705 nm) in Sentinel-2 images. This reflection peak was used to design the Submerged Seagrasses Identification Index (SSII) for extracting underwater seagrass. c) The extraction results of non-submerged seagrasses and submerged seagrasses were merged to map the seagrasses in the study area. The experimental results show that the mapping method proposed in this study can fully consider the influence of tidal changes in remote sensing images on seagrasses identification. The SSII constructed based on Sentinel-2 images extracted submerged seagrasses effectively. This study will provide references to remote sensing mapping of seagrasses and integrated ecological management in coastal zones. [Display omitted] • Tides can interfere with the extraction of information in the seagrasses remote sensing mapping process. • A seagrasses remote sensing mapping process considering the tidal water change is proposed. • The spectral of submerged seagrasses have a special reflection peak at 705 nm on Sentinel-2 images. • A Submerged Seagrasses Identification Index based on Sentinel-2 images was constructed. [ABSTRACT FROM AUTHOR]

Published

2023

28. Effects of high temperature and marine heat waves on seagrasses: Is warming affecting the nutritional value of Posidonia oceanica?

Author

Stipcich, Patrizia, Beca-Carretero, Pedro, Álvarez-Salgado, Xosé Antón, Apostolaki, Eugenia T., Chartosia, Niki, Efthymiadis, Pavlos Theofilos, Jimenez, Carlos E., La Manna, Gabriella, Pansini, Arianna, Principato, Elena, Resaikos, Vasilis, Stengel, Dagmar B., and Ceccherelli, Giulia

Subjects

*MARINE heatwaves, *POSIDONIA, *NUTRITIONAL value, *POSIDONIA oceanica, *HIGH temperatures, *TEMPERATURE effect

Abstract

Primary producers nutritional content affects the entire food web. Here, changes in nutritional value associated with temperature rise and the occurrence of marine heat waves (MHWs) were explored in the endemic Mediterranean seagrass Posidonia oceanica. The variability of fatty acids (FAs) composition and carbon (C) and nitrogen (N) content were examined during summer 2021 from five Mediterranean sites located at the same latitude but under different thermal environments. The results highlighted a decrease in unsaturated FAs and C/N ratio and an increase of monounsaturated FA (MUFA) and N content when a MHW occurred. By contrast, the leaf biochemical composition seems to be adapted to local water temperature since only few significant changes in MUFA were found and N and C/N had an opposite pattern compared to when a MHW occurs. The projected increase in temperature and frequency of MHW suggest future changes in the nutritional value and palatability of leaves. • Primary producer nutritional content may affect the functionality of the food web. • Changes in nutritional value related to temperature in P.oceanica were explored. • Marine heat waves increased MUFA and N content and decreased PUFA and C/N ratio. • Higher local temperature stimulates higher MUFA values and C/N content, but lower N. • The projected change in climate suggests a change in the nutritional value of P. oceanica. [ABSTRACT FROM AUTHOR]

Published

2023

29. A multi-approach inventory of the blue carbon stocks of Posidonia oceanica seagrass meadows: Large scale application in Calvi Bay (Corsica, NW Mediterranean).

Author

Leduc, Michèle, Abadie, Arnaud, Viala, Christophe, Bouchard, Alban, Iborra, Laura, Fontaine, Quentin, Lepoint, Gilles, Marengo, Michel, Pergent, Gérard, Gobert, Sylvie, Lejeune, Pierre, and Monnier, Briac

Subjects

*POSIDONIA, *POSIDONIA oceanica, *SEAGRASSES, *MARINE habitats, *SEDIMENT analysis, *SEDIMENT sampling

Abstract

In Mediterranean, Posidonia oceanica develops a belowground complex structure ('matte') able to store large amounts of carbon over thousands of years. The inventory of blue carbon stocks requires the coupling of mapping techniques and in situ sediment sampling to assess the size and the variability of these stocks. This study aims to quantify the organic (C org) and inorganic (C inorg) carbon stocks in the P. oceanica matte of the Calvi Bay (Corsica) using sub-bottom profiler imagery and biogeochemical analysis of sediment cores. The matte thicknesses map (average ± SD: 2.2 m ± 0.4 m) coupled with marine benthic habitat cartography allows to estimate matte volume at 12 473 352 m3. The cumulative stocks were assessed at 20.2–50.3 kg C org m−2 and 26.6–58.7 kg C inorg m−2 within the first meter of depth on matte (3632 ± 486 cal yr BP). The data contributed to estimate the overall carbon stocks at 389 994 t C org and 615 558 t C inorg , offering a new insight of the heterogeneity of blue carbon stocks in seagrass meadows. Variability of carbon storage capacity of matte influenced by substrate is discussed. [ABSTRACT FROM AUTHOR]

Published

2023

30. Advances in understanding multilevel responses of seagrasses to hypersalinity.

Author

Sandoval-Gil, Jose Miguel, Ruiz, Juan M., and Marín-Guirao, Lázaro

Subjects

*ZOSTERA marina, *POSIDONIA, *MARINE plants, *SEAGRASSES, *PHENOTYPIC plasticity, *POSIDONIA oceanica, *CARBON metabolism

Abstract

Human- and nature-induced hypersaline conditions in coastal systems can lead to profound alterations of the structure and vitality of seagrass meadows and their socio-ecological benefits. In the last two decades, recent research efforts (>50 publications) have contributed significantly to unravel the physiological basis underlying the seagrass–hypersalinity interactions, although most (∼70%) are limited to few species (e.g. Posidonia oceanica , Zostera marina, Thalassia testudinum, Cymodocea nodosa). Variables related to photosynthesis and carbon metabolism are among the most prevalent in the literature, although other key metabolic processes such as plant water relations and responses at molecular (i.e. gene expression) and ultrastructure level are attracting attention. This review emphasises all these latest insights, offering an integrative perspective on the interplay among biological responses across different functional levels (from molecular to clonal structure), and their interaction with biotic/abiotic factors including those related to climate change. Other issues such as the role of salinity in driving the evolutionary trajectory of seagrasses, their acclimation mechanisms to withstand salinity increases or even the adaptive properties of populations that have historically lived under hypersaline conditions are also included. The pivotal role of the costs and limits of phenotypic plasticity in the successful acclimation of marine plants to hypersalinity is also discussed. Finally, some lines of research are proposed to fill the remaining knowledge gaps. • This review synthetizes the seagrass–hypersalinity interactions. • Multilevel responses of seagrasses under hypersalinity are integrated. • Interactive effects of hypersalinity with biotic/abiotic factors are examined. [ABSTRACT FROM AUTHOR]

Published

2023

31. Understanding the depth limit of the seagrass Cymodocea nodosa as a critical transition: Field and modeling evidence.

Author

Mayol, Elvira, Boada, Jordi, Pérez, Marta, Sanmartí, Neus, Minguito-Frutos, Mario, Arthur, Rohan, Alcoverro, Teresa, Alonso, David, and Romero, Javier

Subjects

*POSIDONIA, *SEAGRASSES, *SHOOTING (Sports), *MEADOWS, *WATER quality

Abstract

Changes in light and sediment conditions can sometimes trigger abrupt regime shifts in seagrass meadows resulting in dramatic and unexpected die-offs of seagrass. Light attenuates rapidly with depth, and in seagrass systems with non-linear behaviours, can serve as a sharp boundary beyond which the meadow transitions to bare sand. Determining system behaviour is therefore essential to ensuring resilience is maintained and to prevent stubborn critical ecosystem transitions caused by declines in water quality. Here we combined field and modelling studies to explore the transition from meadow to bare sand in the seagrass Cymodocea nodosa at the limit of its depth distribution in a shallow, light-limited bay. We first describe the relationship between light availability and seagrass density along a depth gradient in an extensive unfragmented meadow (Alfacs bay, NE Spain). We then develop a simple mechanistic model to characterise system behaviour. In the field, we identified sharp decline in shoot density beyond a threshold of ∼1.9 m depth, shifting from a vegetated state to bare sand. The dynamic population model we developed assumes light-dependent growth and an inverse density-dependent mortality due to facilitation between shoots (mortality rate decreases as shoot density increases). The model closely tracked our empirical observations, and both the model and the field data showed signs of bistability. This strongly suggests that the depth limit of C. nodosa is a critical transition driven by photosynthetic light requirements. While the mechanisms still need to be confirmed with experimental evidence, recognizing the non-linear behaviour of C. nodosa meadows is vital not only in improving our understanding of light effects on seagrass dynamics, but also in managing shallow-water meadows. Given the shallow threshold (<2m), light-limited systems may experience significant and recalcitrant meadow retractions with even small changes in sediment and light conditions. Understanding the processes underlying meadow resilience can inform the maintenance and restoration of meadows worldwide. • Cymodocea nodosa meadow shows an abrupt decline in shoot density beyond a threshold of available light at the depth limit. • Bi-stability trends, at the depth limit, suggest alternative stable state dynamics in the seagrass meadow. • We propose a general mechanistic model based on light-dependent growth and density-dependent mortality in the meadow. • The advantages of mixing modeling and observational studies are evident in the following results. [ABSTRACT FROM AUTHOR]

Published

2022

32. Identifying conservation priorities for a widespread dugong population in the Red Sea: Megaherbivore grazing patterns inform management planning.

Author

Khamis, Abdulqader, Alcoverro, Teresa, D'Souza, Elrika, Arthur, Rohan, Pagès, Jordi F., Shah, Junid, Al-Qahtani, Tareq, and Eweida, Ameer Abdulla

Subjects

*DUGONG, *SEAGRASSES, *LATITUDE, *ENDANGERED species, *GRAZING, *COASTAL development, *POSIDONIA

Abstract

Extensive home ranges of marine megafauna present a challenge for systematic conservation planning because they exceed spatial scales of conventional management. For elusive species like dugongs, their management is additionally hampered by a paucity of basic distributional information across much of their range. The Red Sea is home to a wide-spread, globally important but data-poor population of dugongs. We surveyed the north-eastern Red Sea in the waters of NEOM, Kingdom of Saudi Arabia, to locate feeding sites and determine priority areas for dugong conservation. We conducted large-scale in-water surveys of dugong feeding trails across 27 seagrass meadows that span 0.7 degree of latitude and recorded nine seagrass species and 13 dugong feeding sites. Spread over ∼4‚061 km2 of nearshore and offshore waters, many of these sites clustered around five main core feeding areas. Dugong feeding trails were mostly recorded at sites dominated by the fast-growing pioneer seagrasses Halodule uninervis , Halophila ovalis and/or H. stipulacea. Multispecific meadows with pioneer seagrasses tended to be sheltered and shallow, reflecting a similar spatial pattern to the identified dugong feeding sites. Often close to hotels and fishing harbours, these high-use dugong areas are subject to high boat traffic, fishing, and coastal development which places considerable pressures on this vulnerable mammal and its seagrass habitat. The rapidly accelerating coastal development in the northern Red Sea directly threatens the future of its dugong population. Although our sampling focuses on feeding signs in early successional seagrasses, the results are valuable to spatial conservation planning as they will trigger overdue conservation interventions for a globally threatened species in a data-poor area. Urgent dugong conservation management actions in the northern Red Sea should focus on shallow waters sheltered by coastal lagoons, bays and the lee of large islands. • Pioneer seagrasses are important forage for dugongs in north-eastern Red Sea. • Feeding sites excavated by dugongs are found in shallow sheltered waters. • Dugong feeding sites are vulnerable to anthropogenic stressors. • Timely interventions are needed to conserve the dugong population of Red Sea. [ABSTRACT FROM AUTHOR]

Published

2022

33. Functional traits of polychaetes change between different types of Posidonia oceanica habitats.

Author

Katsiaras, N., Evagelopoulos, A., Simboura, N., Atsalaki, A., and Koutsoubas, D.

Subjects

*POSIDONIA, *POSIDONIA oceanica, *HABITAT modification, *POLYCHAETA, *HABITATS, *FRAGMENTED landscapes

Abstract

Meadows of Posidonia oceanica harbor rich biodiversity and ecosystem functions, yet Biological Traits Analysis on the resident benthic communities are lacking. This study aims to provide insight on the functional diversity of polychaetes communities, a dominant benthic group, between the different habitat types of P. oceanica (plain meadow, strips/patches and dead matte), as well as pilot indicators of habitat modification. The results showed how specific traits relate to the different habitat types. Plain meadow was different to strips/patches and dead matte in functional composition, diversity and thus, the ecosystem functions involved. However, an overlap was observed in functional composition between dead matte and living P. oceanica , due to the remaining matte structure. This highlights the importance of the former on ecosystem functioning and the serious consequences of its current exclusion from conservational legislation. In addition, the classification of species to ecosystem engineering types showed interesting potential as an indicator. • Different Posidonia oceanica habitats were analyzed using Biological Traits Analysis. • Specific trait modalities were found to relate to different layers of P. oceanica structure and habitat types. • Plain meadow differed to Strips/Patches and Dead Matte in functional composition, diversity and possibly ecosystem functions. • Dead Mattes highly contribute to ecosystem functioning but are threatened by lack of a conservational framework. • Types of ecosystem engineering showed potential as an indicator of habitat structure modification. [ABSTRACT FROM AUTHOR]

Published

2022

34. Simulated megaherbivore grazing as a driver of seagrass flowering.

Author

Lekammudiyanse, Manuja U., Saunders, Megan I., Flint, Nicole, Irving, Andrew D., and Jackson, Emma L.

Subjects

*GRAZING, *SEA turtles, *POSIDONIA, *FLOWERS, *FLORAL morphology, *FLOWERING time, *SEAGRASSES

Abstract

Seagrass meadows are an important habitat for Testudines (sea turtles) and Sirenia (dugong and manatee) megaherbivores. Megaherbivores can influence the structuring of seagrass meadows; for example, foraging patterns have been found to relate to seagrass phenological strategy. However, as these observations are derived from uncontrolled field studies, it is unclear whether grazing drives such changes or if the changes are related to other factors (e.g., temperature, tidal depth, light). In the present study, a mesocosm experiment was designed to test the impacts of grazing on metrics of flowering of Zostera muelleri over two consecutive flowering seasons. Prior to each flowering season, plants were cropped to 3 cm and 1 cm lengths to represent turtle and dugong grazing, respectively. This study measured the timing of flowering, the number of flowering shoots, the height of the flowering shoot, and the number of spathes (sheathing bracts containing seeds) per flowering shoot in each replicate (n = 5) weekly. Cropping had no significant influence on the timing of flowering (i.e., number of days to first and peak flowering) indicating that it is not a trigger for flowering. However, cropping significantly reduced the maximum density of flowering shoots and spathes, which was proposed to be due to resource allocation differences between clonal growth and flower production. A reduction in the flowering ratio was observed in both cropped plant groups and the relatively high density and the ratio of flowering observed in the 1 cm group indicate that the plant was adapting to cope with stress. Morphology of flowering (i.e., the maximum height of flowering shoot and the maximum number of spathes per flowering shoot) was not significantly affected by cropping and these two variables were strongly correlated. The results suggest that cropping can influence the overall flowering densities in a season but not the timing of flowering. This study demonstrated that cropping prior to the flowering season can reduce the expected production of spathes in seed nurseries and suggests it may be beneficial to consider megaherbivores in seed-based restoration activities. The graphical abstract is created by using the dugong, turtle, and Zostera capricornii images provided by Diana Kleine, University of Queensland (Kleine, 1999a , 1999b , 1999c). [Display omitted] • Cropping before a flowering season significantly reduces the abundance of flowering, compared to no cropping. • Effect of cropping treatment was consistent across two flowering seasons. • Cropping is not influenced on the timing and the morphology of flowering. [ABSTRACT FROM AUTHOR]

Published

2022

35. Simulated response of St. Joseph Bay, Florida, seagrass meadows and their belowground carbon to anthropogenic and climate impacts.

Author

Lebrasse, Marie Cindy, Schaeffer, Blake A., Zimmerman, Richard C., Hill, Victoria J., Coffer, Megan M., Whitman, Peter J., Salls, Wilson B., Graybill, David D., and Osburn, Christopher L.

Subjects

*SEAGRASSES, *POSIDONIA, *TURBIDITY, *DISSOLVED organic matter, *LEAF area index, *EFFECT of human beings on climate change, *OCEAN temperature, *OCEAN acidification

Abstract

Seagrass meadows are degraded globally and continue to decline in areal extent due to human pressures and climate change. This study used the bio-optical model GrassLight to explore the impact of climate change and anthropogenic stressors on seagrass extent, leaf area index (LAI) and belowground organic carbon (BGC) in St. Joseph Bay, Florida, using water quality data and remotely-sensed sea surface temperature (SST) from 2002 to 2020. Model predictions were compared with satellite-derived measurements of seagrass extent and shoot density from the Landsat images for the same period. The GrassLight -derived area of potential seagrass habitat ranged from 36.2 km2 to 39.2 km2, averaging 38.0 ± 0.8 km2 compared to an observed seagrass extent of 23.0 ± 3.0 km2 derived from Landsat (range = 17.9–27.4 km2). GrassLight predicted a mean seagrass LAI of 2.7 m2 leaf m−2 seabed, compared to a mean LAI of 1.9 m2 m−2 estimated from Landsat, indicating that seagrass density in St. Joseph Bay may have been below its light-limited ecological potential. Climate and anthropogenic change simulations using GrassLight predicted the impact of changes in temperature, pH, chlorophyll a , chromophoric dissolved organic matter and turbidity on seagrass meadows. Simulations predicted a 2–8% decline in seagrass extent with rising temperatures that was offset by a 3–11% expansion in seagrass extent in response to ocean acidification when compared to present conditions. Simulations of water quality impacts showed that a doubling of turbidity would reduce seagrass extent by 18% and total leaf area by 21%. Combining climate and water quality scenarios showed that ocean acidification may increase seagrass productivity to offset the negative effects of both thermal stress and declining water quality on the seagrasses growing in St. Joseph Bay. This research highlights the importance of considering multiple limiting factors in understanding the effects of environmental change on seagrass ecosystems. • The GrassLight model simulated future climate and anthropogenic effects on the seagrasses of St. Joseph Bay, Florida. • A predicted 8% seagrass decline with rising temperatures was offset by an 11% seagrass expansion with ocean acidification. • Anthropogenic changes in water quality were a bigger stressor than temperature and pH, predicting a 21% seagrass decline. • Ocean acidification may boost seagrass productivity enough to offset thermal stress and declining water quality effects on seagrasses. [ABSTRACT FROM AUTHOR]

Published

2022

36. Impacts of land-use change and urban development on carbon sequestration in tropical seagrass meadow sediments.

Author

Dahl, Martin, Ismail, Rashid, Braun, Sara, Masqué, Pere, Lavery, Paul S., Gullström, Martin, Arias-Ortiz, Ariane, Asplund, Maria E., Garbaras, Andrius, Lyimo, Liberatus D., Mtolera, Matern S.P., Serrano, Oscar, Webster, Chanelle, and Björk, Mats

Subjects

*SEAGRASSES, *SEAGRASS restoration, *POSIDONIA, *CARBON sequestration, *URBAN growth, *CARBON cycle, *ISOTOPIC signatures, *WASTE management

Abstract

Seagrass meadows store significant carbon stocks at a global scale, but land-use change and other anthropogenic activities can alter the natural process of organic carbon (C org) accumulation. Here, we assessed the carbon accumulation history of two seagrass meadows in Zanzibar (Tanzania) that have experienced different degrees of disturbance. The meadow at Stone Town has been highly exposed to urban development during the 20th century, while the Mbweni meadow is located in an area with relatively low impacts but historical clearing of adjacent mangroves. The results showed that the two sites had similar sedimentary C org accumulation rates (22–25 g m−2 yr−1) since the 1940s, while during the last two decades (∼1998 until 2018) they exhibited 24–30% higher accumulation of C org , which was linked to shifts in C org sources. The increase in the δ13C isotopic signature of sedimentary C org (towards a higher seagrass contribution) at the Stone Town site since 1998 points to improved seagrass meadow conditions and C org accumulation capacity of the meadow after the relocation of a major sewage outlet in the mid–1990s. In contrast, the decrease in the δ13C signatures of sedimentary C org in the Mbweni meadow since the early 2010s was likely linked to increased C org run-off of mangrove/terrestrial material following mangrove deforestation. This study exemplifies two different pathways by which land-based human activities can alter the carbon storage capacity of seagrass meadows (i.e. sewage waste management and mangrove deforestation) and showcases opportunities for management of vegetated coastal C org sinks. [Display omitted] • The seagrass carbon accumulation rate was 22–25 g C org m−2 yr−1. • The rate of carbon accumulation had increased by 24–30% during the last ∼20 years. • The increase in carbon storage was likely due to land-use change. • This study highlights the importance of land-sea connectivity for blue carbon sinks. [ABSTRACT FROM AUTHOR]

Published

2022

37. Responses of the Mediterranean seagrass Cymodocea nodosa to combined temperature and salinity stress at the ionomic, transcriptomic, ultrastructural and photosynthetic levels.

Author

Tsioli, Soultana, Koutalianou, Maria, Gkafas, Georgios A., Exadactylos, Athanasios, Papathanasiou, Vasilis, Katsaros, Christos I., Orfanidis, Sotiris, and Küpper, Frithjof C.

Subjects

*TRANSCRIPTOMES, *SEAGRASSES, *SALINITY, *TEMPERATURE, *POSIDONIA, *CHLOROPHYLL

Published

2022

38. Posidonia oceanica L. (Delile) meadows regression: Long-term affection may be induced by multiple impacts.

Author

Blanco-Murillo, Fabio, Fernández-Torquemada, Yolanda, Garrote-Moreno, Aurora, Sáez, Claudio A., and Sánchez-Lizaso, Jose Luis

Subjects

*POSIDONIA, *POSIDONIA oceanica, *MEADOWS, *SONAR imaging, *COASTAL development, *SCUBA diving, *ECOSYSTEMS

Abstract

Coastal development has an undeniable impact on marine ecosystems resulting in the detriment of the more sensible communities. Posidonia oceanica meadows are climax communities which offer a wide variety of ecosystem services both ecological and socio-economic. Human-derived impact on these habitats has been widely assessed although conclusions may vary depending on the area. P. oceanica meadow regression next to the city of Alicante (SE Spain) was analyzed on the long term (1984–2014) using bionomic cartographies and side-scan sonar images and, during the last two decades (2003–2021), using cover percentage and shoot density descriptors in the remaining meadow. Results showed a 25% colonized area reduction since 1984, this process being more rapid during the 1984–1994 period and decreasing with time. Cover and density have suffered a significant decrease in the last 20 years, mainly in the upper limit of the meadow. Dead matte cover was also assessed and have shown a significant increase in the same period following an inverse trend with the other metrics. There are several coastal impacts which have co-occurred in the area in the last few decades (port enlargement, brine and sewage discharges, industrial activity) thus resulting in the regression of the meadow. The existing negative trend of the measured descriptors indicate the necessity of implementing management actions which focus on the present sources of impact and actively reduce their effect on P. oceanica beds. • Cartography and SCUBA diving sampling revealed a long-term regression of Posidonia oceanica meadow. • Between 1984 and 2014 the meadow lost 25% of its surface, being this decline faster during the 1984–1994 period. • P. oceanica cover and density declined in the remaining meadow, especially in its upper limit, while dead matte increased. • Co-occurrence of multiple stressors in a coastal area resulted in a significant detriment of P. oceanica meadows. [ABSTRACT FROM AUTHOR]

Published

2022

39. "Contribution of Posidonia oceanica meadows in the context of climate change mitigation in the Mediterranean Sea" [Mar. Environ. Res. 165 (2021)].

Author

Pergent-Martini, Christine, Pergent, Gérard, Monnier, Briac, Boudouresque, Charles-François, Mori, Christophe, and Valette-Sansevin, Audrey

Subjects

*POSIDONIA oceanica, *POSIDONIA, *MEADOWS

Published

2021

40. What does measuring species diversity in estuarine seagrass systems actually assess?

Author

Barnes, R.S.K.

Subjects

*SPECIES diversity, *SEAGRASSES, *POSIDONIA, *PLANT species diversity, *SPECIES, *BIODIVERSITY

Abstract

Relationships between species diversity and other species-density and species-richness metrics were investigated in the seagrass macrobenthos of Knysna estuarine bay, South Africa. Although a wide range of species density occurred across sites, neither Hill-Shannon nor Hill-Simpson diversity showed any significant relationship with it, although they did with species richness. Instead species diversity was very closely related to relative evenness, and (negatively) to overall assemblage abundance. No significant relationship was found between species density and evenness. Whilst there was a clear and marked decrease in species density upstream along the main estuarine channel, only one of the species-diversity indices (the Hill-Shannon) showed a significant equivalent decrease. Relationships depended on how 'species richness' was assessed, and were very strongly influenced by the superabundant local occurrence of a few individual faunal components (three gastropod and one tanaid species). Species-diversity analysis contributes nothing new in such estuarine seagrass meadows and seems best avoided. [Display omitted] • Relations between biodiversity metrics studied in seagrass macrobenthos. • Species density was unrelated to either species diversity or evenness. • Evenness was by far the most important component of species diversity. • Diversity responded differently to variation in species density and in richness. • These patterns resulted from local superabundance of a few faunal components. [ABSTRACT FROM AUTHOR]

Published

2021

41. Impact of seagrass establishment, industrialization and coastal infrastructure on seagrass biogeochemical sinks

Author

James Bongiovanni, Carlos M. Duarte, Oscar Serrano, and Paul S. Lavery

Subjects

0106 biological sciences, Geologic Sediments, Biogeochemical cycle, Posidonia, Environmental change, Aquatic Science, Oceanography, 010603 evolutionary biology, 01 natural sciences, Soil, Blue carbon, Industrial Development, Organic matter, Ecosystem, 14. Life underwater, chemistry.chemical_classification, biology, 010604 marine biology & hydrobiology, General Medicine, Soil carbon, 15. Life on land, biology.organism_classification, Pollution, Carbon, Seagrass, chemistry, 13. Climate action, Environmental science

Abstract

The study of a Posidonia sinuosa sedimentary archive has delivered a millenary record of environmental change in Cockburn Sound (Western Australia). Ecosystem change is a major environmental problem challenging sustainable coastal development worldwide, and this study shows baseline trends and shifts in ecological processes in coastal ecosystems under environmental stress. The concentrations and fluxes of biogeochemical elements over the last 3,500 years indicate that important changes in ecosystem dynamics occurred over the last 1,000 years, in particular after ~1900's, probably related to establishment of seagrass meadows in the area and to local and regional human activities (industry and coastal development), respectively. The establishment of seagrasses ~1,000 years ago in the area of study is supported by the appearance of Posidonia fibres from ~40 cm soil depth until the core top, higher δ13C values indicating a larger contribution of seagrass-matter to the soil organic carbon pool, and increased concentration of fine sediments driven by the effect of seagrass canopy in enhancing sedimentation. The comparison of organic carbon, nutrients and metal concentrations and fluxes between pre- and post-establishment of seagrasses shows that seagrass establishment resulted in up to 9-fold increase in the soil biogeochemical sink. In ~1900's, shifts in the concentrations of metals, carbonates, organic carbon, sediment grain size, and δ13C and δ15N values of the organic matter were detected, demonstrating an alteration in seagrass ecosystem functioning following the onset of European settlement. Anthropogenic activities, and in particular the construction of a causeway in 1970's, enhanced seagrass soil organic carbon and metal accumulation rates by 36- and 39-fold, respectively, showing that human-made structures can enhance the biogeochemical sink capacity of seagrasses. Here we reconstruct the impact of human activities on seagrass ecosystem dynamics and blue carbon, which can inform local management of Cockburn Sound and seagrass conservation for climate change mitigation and adaptation.

Published

2020

42. Sizing the carbon sink associated with Posidonia oceanica seagrass meadows using very high-resolution seismic reflection imaging.

Author

Monnier, Briac, Pergent, Gérard, Mateo, Miguel Ángel, Carbonell, Ramon, Clabaut, Philippe, and Pergent-Martini, Christine

Subjects

*POSIDONIA, *CARBON cycle, *SEAGRASSES, *POSIDONIA oceanica, *SEAGRASS restoration, *IMAGING systems in seismology, *SEISMIC reflection method

Abstract

Among blue carbon ecosystems, seagrass meadows have been highlighted for their contribution to the ocean carbon cycle and climate change mitigation derived from their capacity to store large amounts of carbon over long periods of time in their sediments. Most of the available estimates of carbon stocks beneath seagrass meadows are based on the analysis of short sediment cores in very limited numbers. In this study, high-resolution seismic reflection techniques were applied to obtain an accurate estimate of the potential size of the organic deposit underlying the meadows of the Mediterranean seagrass Posidonia oceanica (known as 'matte'). Seismic profiles were collected over 1380 km of the eastern continental shelf of Corsica (France, Mediterranean Sea) to perform a large-scale inventory of the carbon stock stored in sediments. The seismic data were ground-truthed by sampling sediment cores and using calibrated seismo-acoustic surveys. The data interpolation map highlighted a strong spatial heterogeneity of the matte thickness. The height of the matte at the site was estimated at 251.9 cm, being maximum in shallow waters (10–20 m depth), near river mouths and lagoon outlets, where the thickness reached up to 867 cm. Radiocarbon dates revealed the presence of seagrass meadows since the mid-Holocene (7000–9000 cal yr BP). Through the top meter of soil, the matte age was estimated at 1656 ± 528 cal yr BP. The accretion rate showed a high variability resulting from the interplay of multiple factors. Based on the surface area occupied by the meadows, the average matte thickness underneath them and the carbon content, the matte volume and total C org stock were estimated at 403.5 ± 49.4 million m3 and 15.6 ± 2.2 million t C org , respectively. These results confirm the need for the application of large-scale methods to estimate the size of the carbon sink associated with seagrass meadows worldwide. [Display omitted] • Thickness of P. oceanica carbon sink was estimated over more 20,424 ha in Corsica. • This study is based on the use of an extensive HR seismic reflection dataset. • Matte height and volume were assessed on average at 2.5 m and 404 ± 49 million m3. • Seismic reflection method has proved valuable for large-scale carbon sink estimates. [ABSTRACT FROM AUTHOR]

Published

2021

43. Poor success of seagrass Posidonia oceanica transplanting in a meadow disturbed by power line burial.

Author

Castejón-Silvo, Inés and Terrados, Jorge

Subjects

*POSIDONIA, *POSIDONIA oceanica, *ELECTRIC lines, *MEADOWS, *SURVIVAL rate

Abstract

Local disturbances drive the decrease of the area covered by Posidonia oceanica in the Mediterranean. Mechanical impacts during the development of coastal infrastructures alter sea floor and the recolonization of benthic community will depend on the recovery of pre-disturbance environmental conditions and on the intrinsic characteristics of the local community that was disturbed. We transplanted 468 rhizome fragments and 450 seedlings of P. oceanica in a meadow disturbed by the trenching and deployment of a power line to evaluate the suitability of the disturbed sea floor for rehabilitating P. oceanica meadows. We quantify and compare the survivorship and vegetative development of the transplanted/planted (i.e. fragments/seedlings) material in the two types of the unconsolidated substrata left after infrastructure deployment works finished: sand and burlap bags filled with coarse gravel. The latter was used as a corrective measure for topographic restoration. Three experimental plots with sixteen transplanted fragments or twenty-five seedlings were placed at each substratum type at three different depths (i.e. 15, 20 and 25 m). Our results show that the transplanting of P. oceanica rhizome fragments in the disturbed substrata had low survival rates (0–31%) after 40–48 months. The survivorship of seedlings was lower than that of fragments. Our results highlight the importance of substratum for P. oceanica recovery after mechanical impact; disturbed, non-consolidated substrata will preclude P. oceanica rehabilitation through planting. Preservation of meadow substratum (i.e. dead matte) is a critical element that coastal infrastructure projects should consider to enable future recovery of P. oceanica meadows. • Survivorship of rhizome fragments 2 years after transplanting is not representative of longer (4-y) transplant success. • Substrata disturbed by the burial of power line are not suitable for P. oceanica transplanting. • Preservation, or creation, of substrata prone to P. oceanica colonization is essential for the recovery of meadows lost after mechanical impacts. [ABSTRACT FROM AUTHOR]

Published

2021

44. Spatial patterns of Posidonia oceanica structural and functional features in the Eastern Mediterranean (Aegean and E. Ionian Seas) in relation to large-scale environmental factors.

Author

Gerakaris, Vasilis, Papathanasiou, Vasillis, Salomidi, Maria, Issaris, Yiannis, and Panayotidis, Panayotis

Subjects

*POSIDONIA, *POSIDONIA oceanica, *COASTS, *SEAGRASSES, *SPATIAL variation, *MEADOWS

Abstract

In the context of general ecosystem monitoring of the Greek coastal marine environment, a total of 22 descriptors of Posidonia oceanica meadows were studied in 69 study sites. Spatial variation of P. oceanica meadows' features in relation to specific environmental factors (i.e., light, physical exposure, temperature, and nutrients) controlling their dynamics was assessed in three sub-ecoregions of the Hellenic seas (Eastern Ionian, North Aegean, and South Aegean). The studied meadows differentiated by exhibiting varying growth patterns at both the local and sub-ecoregional scale. Significant differences in morphological and demographic descriptors were observed for meadows of the N. Aegean Sea as compared to those of the S. Aegean and the Eastern Ionian Seas. Light limitation was determined as the main driver differentiating the P. oceanica meadows' distribution (i.e., lower limit depth), demography (i.e., shoot density, meadow cover) and shoots' biometry (i.e., shoot length, shoot leaf surface and leaf biomass) along the mainland coastal zone of the N. Aegean Sea. Considering the projected decline of P. oceanica in the face of increasing natural and human impacts, this study offers a crucial ecological baseline that can enhance our understanding of P. oceanica meadows' trends, against which the efficiency of conservation plans and management actions may be monitored. • Seagrass meadows exhibit varying growth patterns in the Aegean and Ionian Seas. • Posidonia meadows' features are different along the mainland coastal zone of the North Aegean Sea. • Light limitation is the main driver differentiating Posidonia meadows at local and sub-ecoregional level. • No massive regression phenomena were detected in the studied Posidonia meadows. • This study offers an ecological baseline for the key features of Posidonia meadows in the Eastern Mediterranean. [ABSTRACT FROM AUTHOR]

Published

2021

45. Warming intensifies the interaction between the temperate seagrass Posidonia oceanica and its dominant fish herbivore Sarpa salpa.

Author

Buñuel, Xavier, Alcoverro, Teresa, Romero, Javier, Arthur, Rohan, Ruiz, Juan M., Pérez, Marta, Ontoria, Yaiza, Raventós, Núria, Macpherson, Enrique, Torrado, Héctor, and Pagès, Jordi F.

Subjects

*POSIDONIA, *POSIDONIA oceanica, *GLOBAL environmental change, *SEAGRASSES, *OCEAN temperature, *ENDANGERED ecosystems

Abstract

Apart from directly influencing individual life histories of species, climate change is altering key biotic interactions as well, causing community processes to unravel. With rising temperatures, disruptions to producer-consumer relationships can have major knock-on effects, particularly when the producer is a habitat-forming species. We studied how sea surface temperature (SST) modifies multiple pathways influencing the interaction between the foundational seagrass species, Posidonia oceanica , and its main consumer, the fish Sarpa salpa in the Mediterranean Sea. We used a combination of a field-based temperature gradient approaches and experimental manipulations to assess the effect of temperature on seagrass performance (growth) and fish early life history (larval development) as well as on the interaction itself (seagrass palatability and fish foraging activity). Within the range of temperatures assessed, S. salpa larvae grew slightly faster at warmer conditions but maintained their settlement size, resulting in a relatively small reduction in pelagic larval duration (PLD) and potentially reducing dispersion. Under warmer conditions (>24 °C), P. oceanica reduced its growth rate considerably and seemed to display fewer deterring mechanisms as indicated by a disproportionate consumption in choice experiments. However, our field-based observations along the temperature gradient showed no change in fish foraging time, or in other aspects of feeding behaviour. As oceans warm, our results indicate that, while S. salpa may show little change in early life history, its preference towards P. oceanica might increase, which, together with reduced seagrass growth , could considerably intensify the strength of herbivory. It is unclear if P. oceanica meadows can sustain such an intensification, but it will clearly add to the raft of pressures this threatened ecosystem already faces from global and local environmental change. • Warming can cause disruptions to plant-herbivore interactions with major knock-on effects. • High temperature had no effect on S. salpa foraging activity but increased larval growth rate. • Warming negatively affected P. oceanica by reducing its growth rate and making it more palatable for fish. • Increased herbivory and decreased plant growth will intensify herbivory pressure in warming seas. [ABSTRACT FROM AUTHOR]

Published

2021

46. Impacts of habitat and predation on epifaunal communities from seagrass beds and artificial structures.

Author

Janiak, Dean S. and Branson, David

Subjects

*SEAGRASSES, *ARTIFICIAL habitats, *HABITATS, *COEXISTENCE of species, *SPECIES diversity, *POSIDONIA

Abstract

Within the coastal marine environment, the increased presence of artificial habitat can have negative impacts on the functioning of marine communities. Artificial structures provide a novel, hard surface for the colonization and growth of a variety of marine species and disproportionally favor introduced species. With the global rise in hardened shorelines, it is imperative to examine the ecological processes that occur within these habitats to those occurring in natural habitats. Here, we compared habitat differences in fouling community composition of different successional ages as well as the impact of predation on those communities. Specifically, we investigated how communities differed with respect to natural (seagrass beds) and artificial (docks) habitats and then exposed previously caged communities to predators to examine prey-specific effects within each habitat and on different aged communities. We found that habitat was a good predictor of community structure including both total species richness and introduced species richness higher in artificial habitats. We expected predators to increase available space allowing increased species co-existence, however, this was not the case. Predators in both habitats reduced richness despite having a strong impact on the percent cover of dominant groups. Predators also reduced introduced species richness, particularly in artificial habitats. Artificial structures are an important pathway of success for introduced species and results here show the importance of biotic resistance within these habitats, potentially limiting the spread of introduced species into natural habitat. Overall, species found within the different habitats could be predicted based on life history traits and predators did not increase the similarity of communities between habitats though still acted in a comparable way, reducing the dominant groups. • Caged communities were exposed to predators to examine consumption in artificial and natural habitats. • Communities differed by habitat, diversity increased in artificial habitats and predictedby life history characteristics. • Predator exclusion increased total species richness and introduced species richness. • Despite differences in communities between habitats, predators acted in a similar way, reducing cover of dominant species. • Biotic resistance was important in artificial habitats, where introduced species are more often found. [ABSTRACT FROM AUTHOR]

Published

2021

47. Differential effects of nutrient enrichment on carbon metabolism and dissolved organic carbon (DOC) fluxes in macrophytic benthic communities.

Author

Egea, Luis G., Jiménez-Ramos, Rocío, Hernández, Ignacio, and Brun, Fernando G.

Subjects

*CARBON metabolism, *BIOTIC communities, *COMMUNITIES, *BIOMASS, *FLUX (Energy), *POSIDONIA

Abstract

Nutrient enrichment can alter negatively benthic communities and reduce their ecological services. This study explores in two contrasting seasons (winter and summer), the effects of in situ nutrient enrichment at the community level on carbon metabolism and dissolved organic carbon (DOC) fluxes in two benthic communities dominated by the seagrass Cymodocea nodosa and by the macroalga Caulerpa prolifera. Under nutrient enrichment, C. nodosa increased total community biomass and diversity in summer, while net community production shifted from net autotrophic to net heterotrophic in winter. In contrast, C. prolifera became heterotrophic in summer, while no significant effects were found in winter. Regarding DOC fluxes, nutrient enrichment shifted C. nodosa from net DOC consumer in winter to a strong net DOC producer in summer, while C. prolifera seemed unaffected. Therefore, nutrient enrichment can promote conditional effects (positive, negative or neutral) in coastal areas depending both on macrophyte assemblages and season. Image 1 • First in situ study testing nutrient effects in the metabolism of benthic communities. • The increase in opportunistic macroalgae and epiphytes did not harm C. nodosa biomass. • Enhanced canopy complexity and proliferation of epiphytes boosted biodiversity. • Nutrient enrichment can shift benthic communities from autotrophic to heterotrophic. • Nutrient enrichment enhanced community behaviour as a net DOC producer or consumer. [ABSTRACT FROM AUTHOR]

Published

2020

48. Coralline macroalgae contribution to ecological services of carbon storage in a disturbed seagrass meadow.

Author

Arina, Natasha, Raynusha, Chandran, Hidayah, Nur, Zainee, Nur Farah Ain, Prathep, Anchana, and Rozaimi, Mohammad

Subjects

*SEAGRASSES, *POSIDONIA, *LOCAL budgets, *OCEAN acidification, *BIOGEOCHEMICAL cycles, *CALCIUM carbonate, *CARBON

Abstract

Coralline macroalgae are globally distributed rhodopyhtes that remove carbon from their immediate environment and transform it into carbonate sediments through the senescence of their calcified tissues. In this study, the calcium carbonate (CaCO 3) stocks in the tissue of Jania adhaerens and sediments in Tanjung Adang Shoal, Johor were quantified for a 13-month study period. The detailed maps of the geographical distribution based on the spatial and temporal variations of biomass and CaCO 3 were also assessed. The highest amount of biomass, CaCO 3 and organic carbon (OC) stocks in the tissues showed the highest in May 2018 and May 2019. The biomass values ranged from 65 to 143 g DW m−2, which contained 53–147 g CaCO 3 m−2 and 3–11 g OC m−2. These findings provided insights into the biogeochemical cycling of these inputs, which can be used to estimate the overall carbon budget of the macrophyte meadow. • Monsoon events affect the variability of Jania adhaerens distribution. • Drift accumulation of J. adhaerens was highest during the inter-monsoon season. • Senescence of J. adhaerens contributes to carbonate deposition. • The calcified tissues of J. adhaerens are susceptible to ocean acidification. • Measuring CaCO 3 stocks of J. adhaerens helps in understanding local carbon budgets. [ABSTRACT FROM AUTHOR]

Published

2020

49. Influence of biotic and abiotic factors of seagrass Posidonia oceanica recruitment: Identifying suitable microsites.

Author

Pereda-Briones, L., Terrados, J., Agulles, M., and Tomas, F.

Subjects

*POSIDONIA, *POSIDONIA oceanica, *FLUX (Energy), *PLANT growing media, *GERMINATION, *PLANT communities

Abstract

The period between seed germination and successful seedling establishment is considered the most vulnerable phase for plant development. To better predict recruitment patterns within plant communities, it is essential to identify the abiotic constrains and biotic interactions that allow for the colonization of substrates by plant species. We evaluated which combination of factors are associated with successful survival and development of seedlings of the seagrass Posidonia oceanica in order to identify the most important microsite features acting together on recruitment success. Our results show that P. oceanica seedlings are rather specific in their environmental requirements during their first 18 months of life, when their development and survival are favored in microsites of consolidated substratum (solid rock, and to a lesser extent P. oceanica matte) covered by macroalgae (mainly crustose algae) and located in sheltered locations (with energy flux values not exceeding 7 × 105 kg s−2 m s−1). After this phase, their probability of surviving becomes more independent from external conditions. • Recruitment success of Posidonia oceanica seedling is limited to safe microsites. • Seedling survivorship decreases significantly under high energy hydrodynamic fluxes. • Seedling survivorship and size are higher at hard substrates than at soft sediments. • All seedlings with seed volumes of 0.7 cm3 or larger survive. • Seedling survivorship and size are high in the presence of macroalgae. [ABSTRACT FROM AUTHOR]

Published

2020

50. Green turtle (Chelonia mydas) grazing plot formation creates structural changes in a multi-species Great Barrier Reef seagrass meadow.

Author

Scott, Abigail L., York, Paul H., and Rasheed, Michael A.

Subjects

*GREEN turtle, *POSIDONIA, *SEAGRASSES, *ENDANGERED species, *REEFS, *GRAZING

Abstract

The Great Barrier Reef (GBR) contains extensive seagrass meadows with abundant and diverse herbivore populations. Typically, meadows in the region are multi-species and dominated by fast growing opportunistic seagrass species. However, we know little about how herbivores modify these types of seagrass meadows by grazing. We conducted the first megaherbivore exclusion study in the GBR at Green Island (Queensland) to understand how green turtle grazing structures these multi-species tropical seagrass meadows. After excluding green turtles for three months, we found that grazing only impacted seagrasses at one site, where green turtles created a grazing plot by actively feeding on both above and below ground seagrass structures, a rare observation for the species. Within this grazing plot at the end of the experiment, the un-caged control treatments open to grazing had a 60% reduction in both above and below ground biomass, and shoot height was reduced by 75%, but there was no impact of grazing on the seagrass species mix. Our study shows that grazing plot formation by green turtles occurs in GBR fast growing seagrass communities and reduces both above and below ground seagrass biomass, this behaviour may be targeting elevated leaf nutrients, or nutritional content of rhizomes. This study is the first documented case of grazing plot formation by green turtles in the GBR and suggests that grazing pressure has a major influence on seagrass meadow structure. Image 1 • Green turtles form grazing plots in Great Barrier Reef seagrass meadows. • Grazing plot formation impacts above and below ground seagrass structure. • Green turtles were observed feeding on rhizomes. • Grazing by green turtles can have a major impact on seagrass meadow structure. [ABSTRACT FROM AUTHOR]

Published

2020