Your search keyword '"Assis, Jorge"' showing total 9 results

1. Vulnerability of Marine Species to Low Oxygen Under Climate Change

Author

Shi, Zhiyuan, primary, Assis, Jorge, additional, and Costello, Mark John, additional

Published

2022

2. Discovering marine biodiversity in the 21st century

Author

Rogers, Alex D., primary, Appeltans, Ward, additional, Assis, Jorge, additional, Ballance, Lisa T., additional, Cury, Philippe, additional, Duarte, Carlos, additional, Favoretto, Fabio, additional, Hynes, Lisa A., additional, Kumagai, Joy A., additional, Lovelock, Catherine E., additional, Miloslavich, Patricia, additional, Niamir, Aidin, additional, Obura, David, additional, O’Leary, Bethan C., additional, Ramirez-Llodra, Eva, additional, Reygondeau, Gabriel, additional, Roberts, Callum, additional, Sadovy, Yvonne, additional, Steeds, Oliver, additional, Sutton, Tracey, additional, Tittensor, Derek P., additional, Velarde, Enriqueta, additional, Woodall, Lucy, additional, and Aburto-Oropeza, Octavio, additional

Published

2022

3. Discovering marine biodiversity in the 21st century

Author

Sheppard, Charles, Rogers, Alex D., Appeltans, Ward, Assis, Jorge, Ballance, Lisa T., Cury, Philippe, Duarte, Carlos, Favoretto, Fabio, Hynes, Lisa A., Kumagai, Joy A., Lovelock, Catherine E., Miloslavich, Patricia, Niamir, Aidin, Obura, David, O’Leary, Bethan C., Ramirez-Llodra, Eva, Reygondeau, Gabriel, Roberts, Callum, Sadovy, Yvonne, Steeds, Oliver, Sutton, Tracey, Tittensor, Derek P., Velarde, Enriqueta, Woodall, Lucy, Aburto-Oropeza, Octavio, Sheppard, Charles, Rogers, Alex D., Appeltans, Ward, Assis, Jorge, Ballance, Lisa T., Cury, Philippe, Duarte, Carlos, Favoretto, Fabio, Hynes, Lisa A., Kumagai, Joy A., Lovelock, Catherine E., Miloslavich, Patricia, Niamir, Aidin, Obura, David, O’Leary, Bethan C., Ramirez-Llodra, Eva, Reygondeau, Gabriel, Roberts, Callum, Sadovy, Yvonne, Steeds, Oliver, Sutton, Tracey, Tittensor, Derek P., Velarde, Enriqueta, Woodall, Lucy, and Aburto-Oropeza, Octavio

Abstract

We review the current knowledge of the biodiversity of the ocean as well as the levels of decline and threat for species and habitats. The lack of understanding of the distribution of life in the ocean is identified as a significant barrier to restoring its biodiversity and health. We explore why the science of taxonomy has failed to deliver knowledge of what species are present in the ocean, how they are distributed and how they are responding to global and regional to local anthropogenic pressures. This failure prevents nations from meeting their international commitments to conserve marine biodiversity with the results that investment in taxonomy has declined in many countries. We explore a range of new technologies and approaches for discovery of marine species and their detection and monitoring. These include: imaging methods, molecular approaches, active and passive acoustics, the use of interconnected databases and citizen science. Whilst no one method is suitable for discovering or detecting all groups of organisms many are complementary and have been combined to give a more complete picture of biodiversity in marine ecosystems. We conclude that integrated approaches represent the best way forwards for accelerating species discovery, description and biodiversity assessment. Examples of integrated taxonomic approaches are identified from terrestrial ecosystems. Such integrated taxonomic approaches require the adoption of cybertaxonomy approaches and will be boosted by new autonomous sampling platforms and development of machine-speed exchange of digital information between databases.

Published

2022

4. Golden carbon of Sargassum forests revealed as an opportunity for climate change mitigation

Author

Gouvêa, Lidiane P., Assis, Jorge, Gurgel, Carlos F.D., Serrão, Ester A., Silveira, Thiago C.L., Santos, Rui, Duarte, Carlos M., Peres, Leticia M.C., Carvalho, Vanessa F., Batista, Manuela, Bastos, Eduardo, Sissini, Marina N., Horta, Paulo A., Gouvêa, Lidiane P., Assis, Jorge, Gurgel, Carlos F.D., Serrão, Ester A., Silveira, Thiago C.L., Santos, Rui, Duarte, Carlos M., Peres, Leticia M.C., Carvalho, Vanessa F., Batista, Manuela, Bastos, Eduardo, Sissini, Marina N., and Horta, Paulo A.

Abstract

Marine climate change mitigation initiatives have recently attracted a great deal of interest in the role of natural carbon sinks, particularly on coastal systems. Brown seaweeds of the genus Sargassum are the largest canopy-forming algae in tropical and subtropical environments, with a wide global distribution on rocky reefs and as floating stands. Because these algae present high amounts of biomass, we suggest their contribution is relevant for global carbon stocks and consequently for mitigating climate change as CO2 remover. We modelled global distributions and quantified carbon stocks as above-ground biomass (AGB) with machine learning algorithms and climate data. Sargassum AGB totaled 13.1 Pg C at the global scale, which is a significant amount of carbon, comparable to other key marine ecosystems, such as mangrove forests, salt marshes and seagrass meadows. However, specific techniques related to bloom production and management, or the utilization of biomass for biomaterials, should be fostered.

Published

2020

5. Corrigendum to "Golden carbon of Sargassum forests revealed as an opportunity for climate change mitigation" [Sci. Total Environ., 729 (2020) Start page - End page/ 138745].

Author

Gouvêa LP, Assis J, Gurgel CFD, Serrão EA, Silveira TCL, Santos R, Duarte CM, Peres LMC, Carvalho VF, Batista M, Bastos E, Sissini MN, and Horta PA

Published

2021

6. Golden carbon of Sargassum forests revealed as an opportunity for climate change mitigation.

Author

Gouvêa LP, Assis J, Gurgel CFD, Serrão EA, Silveira TCL, Santos R, Duarte CM, Peres LMC, Carvalho VF, Batista M, Bastos E, Sissini MN, and Horta PA

Subjects

Biomass, Carbon, Carbon Sequestration, Forests, Trees, Tropical Climate, Climate Change, Sargassum

Abstract

Marine climate change mitigation initiatives have recently attracted a great deal of interest in the role of natural carbon sinks, particularly on coastal systems. Brown seaweeds of the genus Sargassum are the largest canopy-forming algae in tropical and subtropical environments, with a wide global distribution on rocky reefs and as floating stands. Because these algae present high amounts of biomass, we suggest their contribution is relevant for global carbon stocks and consequently for mitigating climate change as CO 2 remover. We modelled global distributions and quantified carbon stocks as above-ground biomass (AGB) with machine learning algorithms and climate data. Sargassum AGB totaled 13.1 Pg C at the global scale, which is a significant amount of carbon, comparable to other key marine ecosystems, such as mangrove forests, salt marshes and seagrass meadows. However, specific techniques related to bloom production and management, or the utilization of biomass for biomaterials, should be fostered., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

7. Environmental drivers of rhodolith beds and epiphytes community along the South Western Atlantic coast.

Author

Carvalho VF, Assis J, Serrão EA, Nunes JM, Anderson AB, Batista MB, Barufi JB, Silva J, Pereira SMB, and Horta PA

Subjects

Atlantic Ocean, Biodiversity, Climate Change, Demography, Temperature, Aquatic Organisms physiology, Ecosystem, Rhodophyta physiology

Abstract

Environmental conditions shape the occurrence and abundance of habitat-building organisms at global scales. Rhodolith beds structure important hard substrate habitats for a large number of marine benthic organisms. These organisms can benefit local biodiversity levels, but also compete with rhodoliths for essential resources. Therefore, understanding the factors shaping the distribution of rhodoliths and their associated communities along entire distributional ranges is of much relevance for conservational biology, particularly in the scope of future environmental changes. Here we predict suitable habitat areas and identify the main environmental drivers of rhodoliths' variability and of associated epiphytes along a large-scale latitudinal gradient. Occurrence and abundance data were collected throughout the South-western Atlantic coast (SWA) and modelled against high resolution environmental predictors extracted from Bio-Oracle. The main drivers for rhodolith occurrence were light availability and temperature at the bottom of the ocean, while abundance was explained by nitrate, temperature and current velocity. Tropical regions showed the highest abundance of rhodoliths. No latitudinal pattern was detected in the variability of epiphytes abundance. However, significant differences were found between sampled sites regarding the composition of predominant taxa. The predictors influencing such differences were temperature and nitrate. The Tropical region is abundant in species with warm-water affinities, decreasing toward warm temperate region. The expressive occurrence of tropical species not referred before for warm temperate beds indicate a plausible tropicalization event., Competing Interests: Declaration of competing interest None., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2020

8. How experimental physiology and ecological niche modelling can inform the management of marine bioinvasions?

Author

Koerich G, Assis J, Costa GB, Sissini MN, Serrão EA, Rörig LR, Hall-Spencer JM, Barufi JB, and Horta PA

Subjects

Models, Theoretical, Biodiversity, Climate Change, Ecosystem, Introduced Species

Abstract

Marine bioinvasions are increasing worldwide by a number of factors related to the anthroposphere, such as higher ship traffic, climate change and biotic communities' alterations. Generating information about species with high invasive potential is necessary to inform management decisions aiming to prevent their arrival and spread. Grateloupia turuturu, one of the most harmful invasive macroalgae, is capable of damaging ecosystem functions and services, and causing biodiversity loss. Here we developed an ecological niche model using occurrence and environmental data to infer the potential global distribution of G. turuturu. In addition, ecophysiological experiments were performed with G. turuturu populations from different climatic regions to test predictions regarding invasion risk. Our model results show high suitability in temperate and warm temperate regions around the world, with special highlight to some areas where this species still doesn't occur. Thalli representing a potential temperate region origin, were held at 10, 13, 16, 20 and 24 °C, and measurements of optimal quantum field (Fv/Fm) demonstrated a decrease of photosynthetic yield in the higher temperature. Thalli from the population already established in warm temperate South Atlantic were held at 18, 24 and 30 °C with high and low nutrient conditions. This material exposed to the higher temperature demonstrated a drop in photosynthetic yield and significant reduction of growth rate. The congregation of modelling and physiological approach corroborate the invasive potential of G. turuturu and indicate higher invasion risk in temperate zones. Further discussions regarding management initiatives must be fostered to mitigate anthropogenic transport and eventually promote eradication initiatives in source areas, with special focus in the South America. We propose that this combined approach can be used to assess the potential distribution and establishment of other marine invasive species., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

9. Future climate change is predicted to shift long-term persistence zones in the cold-temperate kelp Laminaria hyperborea.

Author

Assis J, Lucas AV, Bárbara I, and Serrão EÁ

Subjects

Demography, Ecosystem, Europe, Oceans and Seas, Phylogeography, Climate Change, Cold Temperature, Laminaria physiology

Abstract

Global climate change is shifting species distributions worldwide. At rear edges (warmer, low latitude range margins), the consequences of small variations in environmental conditions can be magnified, producing large negative effects on species ranges. A major outcome of shifts in distributions that only recently received attention is the potential to reduce the levels of intra-specific diversity and consequently the global evolutionary and adaptive capacity of species to face novel disturbances. This is particularly important for low dispersal marine species, such as kelps, that generally retain high and unique genetic diversity at rear ranges resulting from long-term persistence, while ranges shifts during climatic glacial/interglacial cycles. Using ecological niche modelling, we (1) infer the major environmental forces shaping the distribution of a cold-temperate kelp, Laminaria hyperborea (Gunnerus) Foslie, and we (2) predict the effect of past climate changes in shaping regions of long-term persistence (i.e., climatic refugia), where this species might hypothetically harbour higher genetic diversity given the absence of bottlenecks and local extinctions over the long term. We further (3) assessed the consequences of future climate for the fate of L. hyperborea using different scenarios of greenhouse gas emissions (RCP 2.6 and RCP 8.5). Results show NW Iberia, SW Ireland and W English Channel, Faroe Islands and S Iceland, as regions where L. hyperborea may have persisted during past climate extremes until present day. All predictions for the future showed expansions to northern territories coupled with the significant loss of suitable habitats at low latitude range margins, where long-term persistence was inferred (e.g., NW Iberia). This pattern was particularly evident in the most agressive scenario of climate change (RCP 8.5), likely driving major biodiversity loss, changes in ecosystem functioning and the impoverishment of the global gene pool of L. hyperborea. Because no genetic baseline is currently available for this species, our results may represent a first step in informing conservation and mitigation strategies., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2016