Your search keyword '"Jesús M. Arrieta"' showing total 3 results

1. Uneven response of microbial communities to intense dust deposition across the coastal transition zone off Mauritania

Author

Clàudia Pérez-Barrancos, María D. Gelado-Caballero, Nauzet Hernández-Hernández, Isabel Baños, Markel Gómez-Letona, María F. Montero, Jesús M. Arrieta, and Javier Arístegui

Subjects

Global and Planetary Change, Ocean Engineering, Aquatic Science, Oceanography, Water Science and Technology

Abstract

The eastern North Atlantic region receives large Saharan dust deposition inputs, providing nutrients and trace metals to the surface waters. We assessed the effects of intense dust deposition on phytoplankton and bacteria cell abundances, metabolic activity, and community structure, along a surface productivity gradient in the Mauritanian-Senegalese upwelling system. Dust concentrations above 4 mg L-1 were added to triplicate microcosms in four bioassay experiments, each lasting three days, increasing nitrate, phosphate and, to a lesser extent, silicate seawater concentrations. Even though dust deposition enhanced both heterotrophic and photosynthetic activity, bacterial production responded faster and stronger than primary production, especially as oligotrophic conditions increased. Bacterial production rates in oligotrophic waters almost tripled one day after the enrichment. However, such favorable response could not be observed on the total organic carbon production until a lag phase of 2 days and whilst under moderate eutrophic conditions. Dust enrichment benefited the presence of certain planktonic groups over others according to their nutrient requirements. Indicator species analysis revealed that our dust-treated microcosms were consistently characterized by Raphid-pennate diatoms, as well as by Hyphomonas genus of Alphaproteobacteria and several species of Alteromonas Gammaproteobacteria. Yet, changes in microbial community structure and composition were primarily shaped by the starting conditions of each experiment. These findings indicate that increasing dust deposition events and the weakening of the Mauritanian-Senegalese upwelling system under climate change may result in a more heterotrophic system, particularly in oligotrophic waters, reducing its potential to function as an atmospheric carbon sink.

Published

2022

2. Abundance and Structure of the Zooplankton Community During a Post-eruptive Process: The Case of the Submarine Volcano Tagoro (El Hierro; Canary Islands), 2013-2018

Author

Alba González-Vega, Jesús M. Arrieta, Inma Herrera, Carmen Presas-Navarro, Eugenio Fraile-Nuez, Miguel Cabanellas-Reboredo, M. Gazá, and María Luz Fernández de Puelles

Subjects

zooplankton, 0106 biological sciences, Science, copepod assemblages, El Hierro Island, Canary Islands, Ocean Engineering, QH1-199.5, Aquatic Science, Oncaea, Plankton diversity, Oceanography, 01 natural sciences, Zooplankton, 03 medical and health sciences, Water column, Abundance (ecology), Post-eruptive, Centro Oceanográfico de Canarias, Medio Marino, Tagoro submarine volcano, North Atlantic Subtropical, Submarine volcano, 030304 developmental biology, Water Science and Technology, fish, abundance, 0303 health sciences, Global and Planetary Change, geography, research, geography.geographical_feature_category, biology, 010604 marine biology & hydrobiology, General. Including nature conservation, geographical distribution, biology.organism_classification, Volcano, post-eruptive stage, Archipelago, Environmental science, ecology, Copepod

Abstract

The mesozooplankton community was analyzed over a 6-year period (2013-2018) during the post-eruptive stage of the submarine volcano Tagoro, located south of the island of El Hierro (Canary Archipelago, Spain). Nine cruises from March 2013 to March 2018 were carried out in two different seasons, spring (March-April) and autumn (October). A high-resolution study was carried out across the main cones of Tagoro volcano, as well as a large number of reference stations surrounding El Hierro (unaffected by the volcano). The zooplankton community at the reference stations showed a high similarity with more than 85% of the variation in abundance and composition attributable to seasonal differences. Moreover, our data showed an increase in zooplankton abundance in waters affected by the volcano with a higher presence of non-calanoid copepods and a decline in the diversity of the copepod community, indicating that volcanic inputs have a significant effect on these organisms. Fourteen different zooplankton groups were found but copepods were dominant (79%) with 59 genera and 170 species identified. Despite the high species number, less than 30 presented a larger abundance than 1%. Oncaea and Clausocalanus were the most abundant genera followed by Oithona and Paracalanus (60%). Nine species dominated (>2%): O. media, O. plumifera, and O. setigera among the non-calanoids and M. clausi, P. nanus, P. parvus, C. furcatus, C. arcuicornis, and N. minor among the calanoids. After the initial low abundance of the copepods as a consequence of the eruption, an increase was observed in the last years of the study, where besides the small Paracalanus and Clausocalanus, the Cyclopoids seem to have a good adaptive strategy to the new water conditions. The increase in zooplankton abundance and the decline in the copepod diversity in the area affected by the volcano indicate that important changes in the composition of the zooplankton community have occurred. The effect of the volcanic emissions on the different copepods was more evident in spring when the water was cooler and the mixing layer was deeper. Further and longer research is recommended to monitor the zooplankton community in the natural laboratory of the Tagoro submarine volcano., SI

Published

2021

3. Resolving the abundance and air-sea fluxes of airborne microorganisms in the North Atlantic Ocean

Author

Gerhard J. Herndl, Maria A. Jiménez, Eva Mayol, Carlos M. Duarte, and Jesús M. Arrieta

Subjects

Microbiology (medical), 010504 meteorology & atmospheric sciences, Planetary boundary layer, Microorganism, lcsh:QR1-502, Biology, 01 natural sciences, Microbiology, lcsh:Microbiology, Latitude, Atmospheric dry deposition associated microbes, Atmosphere, 03 medical and health sciences, microbial dispersal, Abundance (ecology), 14. Life underwater, Original Research Article, Transect, Airborne microorganisms, Atlantic Ocean, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, Ecology, Aquatic ecosystem, Air-sea exchanges, air-sea exchange, 3. Good health, airborne microorganisms, Oceanography, bioaerosols, 13. Climate action, Biological dispersal, Bioaerosols, Microbial dispersal

Abstract

© 2014 Mayol, Jiménez, Herndl, Duarte and Arrieta. Airborne transport of microbes may play a central role in microbial dispersal, the maintenance of diversity in aquatic systems and in meteorological processes such as cloud formation. Yet, there is almost no information about the abundance and fate of microbes over the oceans, which cover >70% of the Earth's surface and are the likely source and final destination of a large fraction of airborne microbes. We measured the abundance of microbes in the lower atmosphere over a transect covering 17° of latitude in the North Atlantic Ocean and derived estimates of air-sea exchange of microorganisms from meteorological data. The estimated load of microorganisms in the atmospheric boundary layer ranged between 6×104 and 1.6×107 microbes per m2 of ocean, indicating a very dynamic air-sea exchange with millions of microbes leaving and entering the ocean per m2 every day. Our results show that about 10% of the microbes detected in the boundary layer were still airborne 4 days later and that they could travel up to 11,000 km before they entered the ocean again. The size of the microbial pool hovering over the North Atlantic indicates that it could play a central role in the maintenance of microbial diversity in the surface ocean and contribute significantly to atmospheric processes., This is a contribution to the Malaspina Expedition 2010, funded by the INGENIO 2010 CONSOLIDER program (ref. CDS2008-00077) of the Spanish Ministry of Economy and Competitiveness, and projects from the Austrian Science Fund (FWF, I486-B09 and P23234-B11) and project MEDEA from the European Research Council under the European Community's Seventh Framework Programme (FP7/2007-2013, ERC grant agreement No. 268595). Eva Mayol and María A. Jiménez acknowledge the “Junta para la Ampliación de Estudios” program (JAE-predoc and JAE-doc contracts, respectively) from CSIC, supplied by the European Social Fund. Jesús M. Arrieta was supported by a “Ramón y Cajal” fellowship by the former Ministry of Science and Innovation of the Spanish Government

Published

2014