The constraint of ignoring the subtidal water climatology in evaluating the changes of coralligenous reefs due to heating events

Ceccherelli, Giulia; Pinna, Federico; Pansini, Arianna; Piazzi, Luigi; Manna, Gianfranco La

doi:10.1038/s41598-020-74249-9

Cited by 15 publications

(7 citation statements)

References 74 publications

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“…In coralligenous reefs, CCA constitute a secondary substrate which hosts highly diverse assemblages (Ballesteros, 2006). Spatial analyses of assemblages associated to CCA have evidenced biogeographical patterns (Piazzi et al, 2021), supporting the hypothesis that temperature is a key driver affecting the horizontal and vertical distribution of these communities (Ceccherelli et al, 2020;Pinna et al, 2021). On the contrary, little is known about the influence of temperature on CCA presence and distribution in the Mediterranean Sea, although several diseases referable to thermal effects have been reported (Hereu and Kersting, 2016) and a time-integrated thermogeographic model has been proposed by Adey and Steneck (2001) to demonstrate conditions under which CCA assemblages evolve biogeographic patterns in their distribution and abundance.…”

Section: Introductionsupporting

confidence: 53%

“…Both sites are far from any anthropogenic sources of disturbance and are characterized by a high oligotrophy (Barisiello et al, 2002;Regione Autonoma della Sardegna, 2016). However, large differences in sea water temperature were evidenced between sites in the Sea Surface Temperature (SST) climatology, water stratification during the hot season in terms of duration, temperature intensity and variability, and MHWs occurrence (Ceccherelli et al, 2020). Probably due also to such differences, the coralligenous assemblages of the two sites have different geomorphological structures (Piazzi et al, 2021): in particular, CP, which is on average colder than CC, is characterized by massive bioconstructions from 15 m of depth, while in CC the same type of constructions is found only deeper than 30 m (Pinna et al, 2021).…”

Section: Methodsmentioning

confidence: 99%

“…23 and 34 m). Based on temperature variations measured by Ceccherelli et al (2020), CC has considerably warmer water than CP, and the rationale of the BSE relies on the fact that, at the same depth, the algae of the two sites can experience different temperatures for several months, at least from May to November (Ceccherelli et al, 2020). At each combination of site and depth, eight L. stictiforme thalli were fixed on an exposed horizontal substratum next to the coralligenous cliff: four transplanted from the other site (same depth) and four translocated (same site and same depth, sensu Chapman, 1986).…”

Section: Sampling Designs and Experiments Set Upmentioning

confidence: 99%

“…Nowadays, there is a growing need of field experiments which may serve as a useful bridge between laboratory results and natural environmental processes (Chave, 2013). Taking advantage of natural differences in temperature conditions between coastal areas in Sardinia (Italy, Western Mediterranean, Pansini et al, 2021) and along depth gradients (Ceccherelli et al, 2020), we performed crossed transplants of L. stictiforme to examine the temperature effects in terms of mortality, growth, and reproductive structures for the first time in the field. Two experiments were conducted: in the first (between sites experiment), to evaluate the adaptability of the alga to a different thermal regime, we transplanted algae from a cold to a warmer site at two depths; in the second (between depths experiment), transplants were done within the same site from a deeper to a shallower depth under different light irradiance manipulations to evaluate the influence of the thermocline, which could be increasingly deeper and persistent due to global climate change effects (Cerrano et al, 2000;Collins et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

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The Mediterranean bioconstructor Lithophyllum stictiforme shows adaptability to future warming

Pinna

Caragnano²,

Piazzi³

et al. 2022

Front. Mar. Sci.

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Understanding how coralline algae may acclimatize to ocean warming is important to understand their survival over the coming century. Taking advantage of natural differences in temperature conditions between coastal areas in Sardinia (Italy) and between depths, the responses in terms of biological traits to warming of the crustose coralline alga Lithophyllum stictiforme, a key bioconstructor of coralligenous reefs in the Mediterranean, were evaluated in the field by two innovative transplant experiments where translocated specimens were used as controls. Results of the first experiment (algae cross transplanted between a cold and a warm site at two depths, 23 and 34 m) showed that the marginal growth of the alga and production of conceptacles were higher in the cold site, regardless of the treatment (transplant and translocation) and depth. However, growth in thickness in algae transferred from the cold to the warm site was higher at 34 m of depth, where they had a better performance than the local (translocated) algae. Results of the second experiment (algae transplanted from 34 m to 15 m of depth under different light irradiance manipulations) evidenced that the increase in temperature of +4°C was tolerated by thalli transplanted at 15 m, but that thallus growth and conceptacles production was negatively affected by the higher light irradiance. These results suggest an overall good adaptability of L. stictiforme under warmer conditions, even those due to thermocline deepening. Overall, these results encourage consideration of the use of transplants of this bioconstructor in future restoration actions of coralligenous habitats.

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Section: Introductionsupporting

confidence: 53%

Section: Methodsmentioning

confidence: 99%

Section: Sampling Designs and Experiments Set Upmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The Mediterranean bioconstructor Lithophyllum stictiforme shows adaptability to future warming

Pinna

Caragnano²,

Piazzi³

et al. 2022

Front. Mar. Sci.

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“…The temperature change projected in the Mediterranean Sea ranges between 0.81 and 3.71 • C in the upper layer (0-150 m) by the end of the 21st century, depending on the greenhouse gas emissions scenario (Soto-Navarro et al, 2020). The rising SST has accelerated MHWs occurrence and effects on Mediterranean benthic communities have already been described (Garrabou et al, 2009;Marbà and Duarte, 2010;Rubio-Portillo et al, 2016), even though their effects on subtidal water conditions are anything but obvious: SST is undoubtedly a useful proxy for very shallow water temperature, but using loggers remains recommended to have more accurate and precise temperature estimates as deep water temperature can be scarcely predicted from SST (Ceccherelli et al, 2020). The most severe impacts of MHWs on benthic communities are expected in summer when the intensity of these extreme events can easily exceed the maximum tolerance limit of the species (e.g., those in 2003(e.g., those in , 2012(e.g., those in , 2015(e.g., those in , Darmaraki et al, 2019b.…”

Section: Introductionmentioning

confidence: 99%

Effects of Current and Future Summer Marine Heat Waves on Posidonia oceanica: Plant Origin Matters?

Stipcich¹,

Marín-Guirao²,

Pansini³

et al. 2022

Front. Clim.

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Marine heat waves (MHWs), prolonged discrete anomalously warm water events, have been increasing significantly in duration, intensity and frequency all over the world, and have been associated with a variety of impacts including alteration of ecosystem structure and function. This study assessed the effects of current and future MHWs on the Mediterranean seagrass Posidonia oceanica performance, also testing the importance of the thermal environment where the plant lives. The effects of current MHWs were studied through a mensurative experiment in a cold and in a warm site (West and North-West Sardinia, Italy, respectively). Future MHWs effects were tested through a manipulative experiment using P. oceanica shoots collected from the cold and warm sites and transplanted in a common garden in front of a power plant (North-West Sardinia): here plants were exposed to heat longer in duration and stronger in intensity than the natural MHWs of the last 20 years, resembling the future scenario. Morphological (total # of leaves, maximum leaf length, and percentage of total necrotic leaf length per shoot) and biochemical variables (leaf proteins, carbohydrates, and lipids) were considered. Plants had similar sublethal responses in both the experiments for most of the variables, revealing that current and future MHWs had similar effect types, but different in magnitude depending on the intensity of the waves: in general, the number of leaves, the maximum leaf length and lipid content decreased, while the leaf necrosis and carbohydrates increased. However, also the origin of the plants affected the results, corroborating the hypothesis that the thermal context the plants live affects their tolerance to the heat. Overall, this study provided evidence about the importance of biochemical variations, such as carbohydrate and lipid levels, as potentially good indicators of seagrass heat stress.

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Coralligenous assemblages of continental shelf: Multiple spatial scale variability in the western Sardinia

Piazzi

Falco

Luca

et al. 2022

Continental Shelf Research

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The constraint of ignoring the subtidal water climatology in evaluating the changes of coralligenous reefs due to heating events

Cited by 15 publications

References 74 publications

The Mediterranean bioconstructor Lithophyllum stictiforme shows adaptability to future warming

The Mediterranean bioconstructor Lithophyllum stictiforme shows adaptability to future warming

Effects of Current and Future Summer Marine Heat Waves on Posidonia oceanica: Plant Origin Matters?

Coralligenous assemblages of continental shelf: Multiple spatial scale variability in the western Sardinia

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