Your search keyword '"Perna, Gabriela"' showing total 11 results

1. The Coral Bleaching Automated Stress System (CBASS): A low‐cost, portable system for standardized empirical assessments of coral thermal limits.

Author

Evensen, Nicolas R., Parker, Katherine E., Oliver, Thomas A., Palumbi, Stephen R., Logan, Cheryl A., Ryan, James S., Klepac, Courtney N., Perna, Gabriela, Warner, Mark E., Voolstra, Christian R., and Barshis, Daniel J.

Subjects

CORAL bleaching, CORALS, CORAL reefs & islands, MARINE ecology, TEMPERATURE control, WATER masses

Abstract

Ocean warming is increasingly affecting marine ecosystems across the globe. Reef‐building corals are particularly affected by warming, with mass bleaching events increasing in frequency and leading to widespread coral mortality. Yet, some corals can resist or recover from bleaching better than others. Such variability in thermal resilience could be critical to reef persistence; however, the scientific community lacks standardized diagnostic approaches to rapidly and comparatively assess coral thermal vulnerability prior to bleaching events. We present the Coral Bleaching Automated Stress System (CBASS) as a low‐cost, open‐source, field‐portable experimental system for rapid empirical assessment of coral thermal thresholds using standardized temperature stress profiles and diagnostics. The CBASS consists of four or eight flow‐through experimental aquaria with independent water masses, lighting, and individual automated temperature controls capable of delivering custom modulating thermal profiles. The CBASS is used to conduct daily thermal stress exposures that typically include 3‐h temperature ramps to multiple target temperatures, a 3‐h hold period at the target temperatures, and a 1‐h ramp back down to ambient temperature, followed by an overnight recovery period. This mimics shallow water temperature profiles observed in coral reefs and prompts a rapid acute heat stress response that can serve as a diagnostic tool to identify putative thermotolerant corals for in‐depth assessments of adaptation mechanisms, targeted conservation, and possible use in restoration efforts. The CBASS is deployable within hours and can assay up to 40 coral fragments/aquaria/day, enabling high‐throughput, rapid determination of thermal thresholds for individual genotypes, populations, species, and sites using a standardized experimental framework. [ABSTRACT FROM AUTHOR]

Published

2023

2. Urbanization comprehensively impairs biological rhythms in coral holobionts.

Author

Rosenberg, Yaeli, Simon‐Blecher, Noa, Lalzar, Maya, Yam, Ruth, Shemesh, Aldo, Alon, Shahar, Perna, Gabriela, Cárdenas, Anny, Voolstra, Christian R., Miller, David J., and Levy, Oren

Subjects

CORALS, BIOLOGICAL rhythms, CORAL reefs & islands, CONSERVATION biology, EFFECT of human beings on climate change, URBANIZATION

Abstract

Coral reefs are in global decline due to climate change and anthropogenic influences (Hughes et al., Conservation Biology, 27: 261–269, 2013). Near coastal cities or other densely populated areas, coral reefs face a range of additional challenges. While considerable progress has been made in understanding coral responses to acute individual stressors (Dominoni et al., Nature Ecology & Evolution, 4: 502–511, 2020), the impacts of chronic exposure to varying combinations of sensory pollutants are largely unknown. To investigate the impacts of urban proximity on corals, we conducted a year‐long in‐natura study—incorporating sampling at diel, monthly, and seasonal time points—in which we compared corals from an urban area to corals from a proximal non‐urban area. Here we reveal that despite appearing relatively healthy, natural biorhythms and environmental sensory systems were extensively disturbed in corals from the urban environment. Transcriptomic data indicated poor symbiont performance, disturbance to gametogenic cycles, and loss or shifted seasonality of vital biological processes. Altered seasonality patterns were also observed in the microbiomes of the urban coral population, signifying the impact of urbanization on the holobiont, rather than the coral host alone. These results should raise alarm regarding the largely unknown long‐term impacts of sensory pollution on the resilience and survival of coral reefs close to coastal communities. [ABSTRACT FROM AUTHOR]

Published

2022

3. Empirically derived thermal thresholds of four coral species along the Red Sea using a portable and standardized experimental approach.

Author

Evensen, Nicolas R., Voolstra, Christian R., Fine, Maoz, Perna, Gabriela, Buitrago-López, Carol, Cárdenas, Anny, Banc-Prandi, Guilhem, Rowe, Katherine, and Barshis, Daniel J.

Subjects

CORAL bleaching, CORALS, CORAL reefs & islands, BIOLOGICAL extinction, ACROPORA, THERMAL stresses, PORITES

Abstract

Global warming is causing an unprecedented loss of species and habitats worldwide. This is particularly apparent for tropical coral reefs, with an increasing number of reefs experiencing mass bleaching and mortality on an annual basis. As such, there is a growing need for a standardized experimental approach to rapidly assess the thermal limits of corals and predict the survival of coral species across reefs and regions. Using a portable experimental system, the Coral Bleaching Automated Stress System (CBASS), we conducted standardized 18 h acute thermal stress assays to quantitively determine the upper thermal limits of four coral species across the length of the Red Sea coastline, from the Gulf of Aqaba (GoA) to Djibouti (~ 2100 km). We measured dark-acclimated photosynthetic efficiency (Fv/Fm), algal symbiont density, chlorophyll a, and visual bleaching intensity following heat stress. Fv/Fm was the most precise response variable assessed, advancing the Fv/Fm effective dose 50 (ED50, i.e., the temperature at which 50% of the initial Fv/Fm is measured) as an empirically derived proxy for thermal tolerance. ED50 thermal thresholds from the central/southern Red Sea and Djibouti populations were consistently higher for Acropora hemprichii, Pocillopora verrucosa, and Stylophora pistillata (0.1–1.8 °C above GoA corals, respectively), in line with prevailing warmer maximum monthly means (MMMs), though were lower than GoA corals relative to site MMMs (1.5–3.0 °C). P. verrucosa had the lowest thresholds overall. Despite coming from the hottest site, thresholds were lowest for Porites lobata in the southern Red Sea, suggesting long-term physiological damage or ongoing recovery from a severe, prior bleaching event. Altogether, the CBASS resolved historical, taxonomic, and possibly recent environmental drivers of variation in coral thermal thresholds, highlighting the potential for a standardized, short-term thermal assay as a universal approach for assessing ecological and evolutionary variation in the upper thermal limits of corals. [ABSTRACT FROM AUTHOR]

Published

2022

4. Assessment of temperature optimum signatures of corals at both latitudinal extremes of the Red Sea.

Author

Banc-Prandi, Guilhem, Evensen, Nicolas R, Barshis, Daniel J, Perna, Gabriela, Omar, Youssouf Moussa, and Fine, Maoz

Subjects

CORAL bleaching, CORALS, THERMAL resistance, CHLOROPHYLL spectra, OCEAN temperature, ACROPORA, PORITES

Abstract

Rising ocean temperatures are pushing reef-building corals beyond their temperature optima (Topt), resulting in reduced physiological performances and increased risk of bleaching. Identifying refugia with thermally resistant corals and understanding their thermal adaptation strategy is therefore urgent to guide conservation actions. The Gulf of Aqaba (GoA, northern Red Sea) is considered a climate refuge, hosting corals that may originate from populations selected for thermal resistance in the warmer waters of the Gulf of Tadjoura (GoT, entrance to the Red Sea and 2000 km south of the GoA). To better understand the thermal adaptation strategy of GoA corals, we compared the temperature optima (Topt) of six common reef-building coral species from the GoA and the GoT by measuring oxygen production and consumption rates as well as photophysiological performance (i.e. chlorophyll fluorescence) in response to a short heat stress. Most species displayed similar Topt between the two locations, highlighting an exceptional continuity in their respective physiological performances across such a large latitudinal range, supporting the GoA refuge theory. Stylophora pistillata showed a significantly lower Topt in the GoA, which may suggest an ongoing population-level selection (i.e. adaptation) to the cooler waters of the GoA and subsequent loss of thermal resistance. Interestingly, all Topt were significantly above the local maximum monthly mean seawater temperatures in the GoA (27.1°C) and close or below in the GoT (30.9°C), indicating that GoA corals, unlike those in the GoT, may survive ocean warming in the next few decades. Finally, Acropora muricata and Porites lobata displayed higher photophysiological performance than most species, which may translate to dominance in local reef communities under future thermal scenarios. Overall, this study is the first to compare the Topt of common reef-building coral species over such a latitudinal range and provides insights into their thermal adaptation in the Red Sea. [ABSTRACT FROM AUTHOR]

Published

2022

5. Microbes support enhanced nitrogen requirements of coral holobionts in a high CO2 environment.

Author

Meunier, Valentine, Geissler, Laura, Bonnet, Sophie, Rädecker, Nils, Perna, Gabriela, Grosso, Olivier, Lambert, Christophe, Rodolfo‐Metalpa, Riccardo, Voolstra, Christian R., and Houlbrèque, Fanny

Subjects

SCLERACTINIA, CORAL reefs & islands, OCEAN acidification, MICROORGANISMS, CARBON cycle, CORALS, SYMBIODINIUM, NITROGEN

Abstract

Ocean acidification is posing a threat to calcifying organisms due to the increased energy requirements of calcification under high CO2 conditions. The ability of scleractinian corals to cope with future ocean conditions will thus depend on their ability to fulfil their carbon requirement. However, the primary productivity of coral holobionts is limited by low nitrogen (N) availability in coral reef waters. Here, we employed CO2 seeps of Tutum Bay (Papua New Guinea) as a natural laboratory to understand how coral holobionts offset their increased energy requirements under high CO2 conditions. Our results demonstrate for the first time that under high pCO2 conditions, N assimilation pathways of Pocillopora damicornis are jointly modified. We found that diazotroph‐derived N assimilation rates in the Symbiodiniaceae were significantly higher in comparison to an ambient CO2 control site, concomitant with a restructured diazotroph community and the specific prevalence of an alpha‐proteobacterium. Further, corals at the high CO2 site also had increased feeding rates on picoplankton and in particular exhibited selective feeding on Synechococcus sp., known to be rich in N. Given the high abundance of picoplankton in oligotrophic waters at large, our results suggest that corals exhibiting flexible diazotrophic communities and capable of exploiting N‐rich picoplankton sources to offset their increased N requirements may be able to cope better in a high pCO2 world. [ABSTRACT FROM AUTHOR]

Published

2021

6. Contrasting heat stress response patterns of coral holobionts across the Red Sea suggest distinct mechanisms of thermal tolerance.

Author

Voolstra, Christian R., Valenzuela, Jacob J., Turkarslan, Serdar, Cárdenas, Anny, Hume, Benjamin C. C., Perna, Gabriela, Buitrago‐López, Carol, Rowe, Katherine, Orellana, Monica V., Baliga, Nitin S., Paranjape, Suman, Banc‐Prandi, Guilhem, Bellworthy, Jessica, Fine, Maoz, Frias‐Torres, Sarah, and Barshis, Daniel J.

Subjects

CORALS, THERMAL resistance, TRANSCRIPTOMES, BACTERIAL communities, CORAL bleaching, GENE expression

Abstract

Corals from the northern Red Sea, in particular the Gulf of Aqaba (GoA), have exceptionally high bleaching thresholds approaching >5℃ above their maximum monthly mean (MMM) temperatures. These elevated thresholds are thought to be due to historical selection, as corals passed through the warmer Southern Red Sea during recolonization from the Arabian Sea. To test this hypothesis, we determined thermal tolerance thresholds of GoA versus central Red Sea (CRS) Stylophora pistillata corals using multi‐temperature acute thermal stress assays to determine thermal thresholds. Relative thermal thresholds of GoA and CRS corals were indeed similar and exceptionally high (~7℃ above MMM). However, absolute thermal thresholds of CRS corals were on average 3℃ above those of GoA corals. To explore the molecular underpinnings, we determined gene expression and microbiome response of the coral holobiont. Transcriptomic responses differed markedly, with a strong response to the thermal stress in GoA corals and their symbiotic algae versus a remarkably muted response in CRS colonies. Concomitant to this, coral and algal genes showed temperature‐induced expression in GoA corals, while exhibiting fixed high expression (front‐loading) in CRS corals. Bacterial community composition of GoA corals changed dramatically under heat stress, whereas CRS corals displayed stable assemblages. We interpret the response of GoA corals as that of a resilient population approaching a tipping point in contrast to a pattern of consistently elevated thermal resistance in CRS corals that cannot further attune. Such response differences suggest distinct thermal tolerance mechanisms that may affect the response of coral populations to ocean warming. [ABSTRACT FROM AUTHOR]

Published

2021

7. Remarkably high and consistent tolerance of a Red Sea coral to acute and chronic thermal stress exposures.

Author

Evensen, Nicolas R., Fine, Maoz, Perna, Gabriela, Voolstra, Christian R., and Barshis, Daniel J.

Subjects

PSYCHOLOGICAL stress, CORAL bleaching, HEAT waves (Meteorology), SCLERACTINIA, CORALS, OCEAN temperature, THERMAL stresses, GLOBAL warming

Abstract

Global warming is resulting in unprecedented levels of coral mortality due to mass bleaching events and, more recently, marine heatwaves, where rapid increases in seawater temperature cause mortality within days. Here, we compare the response of a ubiquitous scleractinian coral, Stylophora pistillata, from the northern Red Sea to acute (7 h) and chronic (7–11 d) thermal stress events that include temperature treatments of 27°C (i.e., the local maximum monthly mean), 29.5°C, 32°C, and 34.5°C, and assess recovery of the corals following exposure. Overall, S. pistillata exhibited remarkably similar responses to acute and chronic thermal stress, responding primarily to the temperature treatment rather than duration or heating rate. Additionally, corals displayed an exceptionally high thermal tolerance, maintaining their physiological performance and suffering little to no loss of algal symbionts or chlorophyll a up to 32°C, before the host suffered from rapid tissue necrosis and mortality at 34.5°C. While there was some variability in physiological response metrics, photosynthetic efficiency measurements (i.e., maximum quantum yield Fv/Fm) accurately reflected the overall physiological response patterns, with these measurements used to produce the Fv/Fm effective dose (ED50) metric as a proxy for the thermal tolerance of corals. This approach produced similar ED50 values for the acute and chronic experiments (34.47°C vs. 33.81°C), highlighting the potential for acute thermal assays with measurements of Fv/Fm as a systematic and standardized approach to quantitively compare the upper thermal limits of reef‐building corals using a portable experimental system. [ABSTRACT FROM AUTHOR]

Published

2021

8. Flexibility in Red Sea Tridacna maxima‐Symbiodiniaceae associations supports environmental niche adaptation.

Author

Rossbach, Susann, Hume, Benjamin C. C., Cárdenas, Anny, Perna, Gabriela, Voolstra, Christian R., and Duarte, Carlos M.

Subjects

CORAL reefs & islands, ALGAL communities, SYMBIODINIUM, GENES, HOST specificity (Biology), CORALS, CLAMS

Abstract

Giant clams (Tridacninae) are important members of Indo‐Pacific coral reefs and among the few bivalve groups that live in symbiosis with unicellular algae (Symbiodiniaceae). Despite the importance of these endosymbiotic dinoflagellates for clam ecology, the diversity and specificity of these associations remain relatively poorly studied, especially in the Red Sea. Here, we used the internal transcribed spacer 2 (ITS2) rDNA gene region to investigate Symbiodiniaceae communities associated with Red Sea Tridacna maxima clams. We sampled five sites spanning 1,300 km (10° of latitude, from the Gulf of Aqaba, 29°N, to the Farasan Banks, 18°N) along the Red Sea's North‐South environmental gradient. We detected a diverse and structured assembly of host‐associated algae with communities demonstrating region and site‐specificity. Specimens from the Gulf of Aqaba harbored three genera of Symbiodiniaceae, Cladocopium, Durusdinium, and Symbiodinium, while at all other sites clams associated exclusively with algae from the Symbiodinium genus. Of these exclusively Symbiodinium‐associating sites, the more northern (27° and 22°) and more southern sites (20° and 18°) formed two separate groupings despite site‐specific algal genotypes being resolved at each site. These groupings were congruent with the genetic break seen across multiple marine taxa in the Red Sea at approximately 19°, and along with our documented site‐specificity of algal communities, contrasted the panmictic distribution of the T. maxima host. As such, our findings indicate flexibility in T. maxima‐Symbiodiniaceae associations that may explain its relatively high environmental plasticity and offers a mechanism for environmental niche adaptation. [ABSTRACT FROM AUTHOR]

Published

2021

9. Standardized short‐term acute heat stress assays resolve historical differences in coral thermotolerance across microhabitat reef sites.

Author

Voolstra, Christian R., Buitrago‐López, Carol, Perna, Gabriela, Cárdenas, Anny, Hume, Benjamin C. C., Rädecker, Nils, and Barshis, Daniel J.

Subjects

CORAL bleaching, CORAL reef ecology, ACCLIMATIZATION, REEFS, CORAL reefs & islands, CORALS, ECOLOGICAL niche, HEAT

Abstract

Coral bleaching is one of the main drivers of reef degradation. Most corals bleach and suffer mortality at just 1–2°C above their maximum monthly mean temperatures, but some species and genotypes resist or recover better than others. Here, we conducted a series of 18‐hr short‐term acute heat stress assays side‐by‐side with a 21‐day long‐term heat stress experiment to assess the ability of both approaches to resolve coral thermotolerance differences reflective of in situ reef temperature thresholds. Using a suite of physiological parameters (photosynthetic efficiency, coral whitening, chlorophyll a, host protein, algal symbiont counts, and algal type association), we assessed bleaching susceptibility of Stylophora pistillata colonies from the windward/exposed and leeward/protected sites of a nearshore coral reef in the central Red Sea, which had previously shown differential mortality during a natural bleaching event. Photosynthetic efficiency was most indicative of the expected higher thermal tolerance in corals from the protected reef site, denoted by an increased retention of dark‐adapted maximum quantum yields at higher temperatures. These differences were resolved using both experimental setups, as corroborated by a positive linear relationship, not observed for the other parameters. Notably, short‐term acute heat stress assays resolved per‐colony (genotype) differences that may have been masked by acclimation effects in the long‐term experiment. Using our newly developed portable experimental system termed the Coral Bleaching Automated Stress System (CBASS), we thus highlight the potential of mobile, standardized short‐term acute heat stress assays to resolve fine‐scale differences in coral thermotolerance. Accordingly, such a system may be suitable for large‐scale determination and complement existing approaches to identify resilient genotypes/reefs for downstream experimental examination and prioritization of reef sites for conservation/restoration. Development of such a framework is consistent with the recommendations of the National Academy of Sciences and the Reef Restoration and Adaptation Program committees for new intervention and restoration strategies. [ABSTRACT FROM AUTHOR]

Published

2020

10. Assessing the effects of iron enrichment across holobiont compartments reveals reduced microbial nitrogen fixation in the Red Sea coral Pocillopora verrucosa.

Author

Rädecker, Nils, Pogoreutz, Claudia, Ziegler, Maren, Ashok, Ananya, Barreto, Marcelle M., Chaidez, Veronica, Grupstra, Carsten G. B., Ng, Yi Mei, Perna, Gabriela, Aranda, Manuel, and Voolstra, Christian R.

Subjects

CORALS, NITROGEN fixation, PHYSIOLOGICAL effects of iron, DINOFLAGELLATES, PHOTOSYNTHESIS

Abstract

The productivity of coral reefs in oligotrophic tropical waters is sustained by an efficient uptake and recycling of nutrients. In reef-building corals, the engineers of these ecosystems, this nutrient recycling is facilitated by a constant exchange of nutrients between the animal host and endosymbiotic photosynthetic dinoflagellates (zooxanthellae), bacteria, and other microbes. Due to the complex interactions in this so-called coral holobiont, it has proven difficult to understand the environmental limitations of productivity in corals. Among others, the micronutrient iron has been proposed to limit primary productivity due to its essential role in photosynthesis and bacterial processes. Here, we tested the effect of iron enrichment on the physiology of the coral Pocillopora verrucosa from the central Red Sea during a 12-day experiment. Contrary to previous reports, we did not see an increase in zooxanthellae population density or gross photosynthesis. Conversely, respiration rates were significantly increased, and microbial nitrogen fixation was significantly decreased. Taken together, our data suggest that iron is not a limiting factor of primary productivity in Red Sea corals. Rather, increased metabolic demands in response to iron enrichment, as evidenced by increased respiration rates, may reduce carbon (i.e., energy) availability in the coral holobiont, resulting in reduced microbial nitrogen fixation. This decrease in nitrogen supply in turn may exacerbate the limitation of other nutrients, creating a negative feedback loop. Thereby, our results highlight that the effects of iron enrichment appear to be strongly dependent on local environmental conditions and ultimately may depend on the availability of other nutrients. [ABSTRACT FROM AUTHOR]

Published

2017

11. Coral microbiome manipulation elicits metabolic and genetic restructuring to mitigate heat stress and evade mortality.

Author

Santoro, Erika P., Borges, Ricardo M., Espinoza, Josh L., Freire, Marcelo, Messias, Camila S. M. A., Villela, Helena D. M., Pereira, Leandro M., Vilela, Caren L. S., Rosado, João G., Cardoso, Pedro M., Rosado, Phillipe M., Assis, Juliana M., Duarte, Gustavo A. S., Perna, Gabriela, Rosado, Alexandre S., Macrae, Andrew, Dupont, Christopher L., Nelson, Karen E., Sweet, Michael J., and Voolstra, Christian R.

Subjects

*CORAL bleaching, *CHLOROPHYLL spectra, *CORALS, *COLONIZATION (Ecology), *RNA sequencing, *SCLERACTINIA, *CORAL reefs & islands

Published

2021