Your search keyword '"S. Sánchez-Carrillo"' showing total 16 results

1. La información a largo plazo como herramienta clave para la evaluación de los cambios ambientales en las tablas de Daimiel: LTER-Daimiel

Author

S. Sánchez-Carrillo, M. Álvarez-Cobelas, S. Cirujano, M. Carrasco-Redondo, and A. Díaz-Cambronero

Subjects

Environmental sciences, GE1-350

Abstract

La mayor parte de los procesos ecológicos sólo pueden entenderse desde una perspectiva temporal larga. Los ecosistemas están cambiando de un modo tan complejo que todavía estamos intentando detectar cómo lo hacen y a qué ritmo ante la compleja red de estresores a que están sometidos. Las observaciones a largo plazo existentes en el nodo LTER-Daimiel nos permiten evaluar las causas y los efectos de los principales cambios ambientales ocurridos en Las Tablas de Daimiel durante los últimos 70 años. En este trabajo presentamos tres ejemplos que ponen de manifiesto la validez de las observaciones a largo plazo en la interpretación de diversos fenómenos ambientales ocurridos en el humedal, en contraposición a lo que proporcionan registros temporales limitados.

Published

2016

2. Morphological and physiological changes exhibited by a Cd-resistant Dictyosphaerium chlorelloides strain and its cadmium removal capacity

Author

A. Sánchez-Fortún, María Carmen Bartolomé, S. Sánchez-Carrillo, S. Sánchez-Fortún, A. A. Cortés, and M. G. Garnica-Romo

Subjects

0106 biological sciences, chemistry.chemical_element, Plant Science, Chlorophyta, 010501 environmental sciences, Cell morphology, Photosynthesis, Waste Disposal, Fluid, 01 natural sciences, Microbiology, Respiration, Microalgae, Environmental Chemistry, 0105 earth and related environmental sciences, Cadmium, biology, Strain (chemistry), Cell growth, 010604 marine biology & hydrobiology, biology.organism_classification, Pollution, chemistry, Biophysics, Dictyosphaerium, Water Pollutants, Chemical

Abstract

Changes induced on freshwater microalga Dictyosphaerium chlorelloides (Dc(wt)) acclimated in the laboratory until their survival in culture media enriched with cadmium 100 µM have been studied. Cadmium removal by living cells of this Cd-resistant (Dc(CdR100)) strain was tested in cultures exposed to 100 µM Cd during 30 days. Cell dimensions were measured under light microscopy, and cell growth was studied. Photosynthetic yield (ΦPSII) was analyzed and the photosynthetic oxygen development and respiration response was obtained. Results show that Dc(CdR100) strain exhibited significant cell morphology changes in comparison to Dc(wt) cells, which affected both surface area and cell biovolume. Malthusian fitness analysis showed that Dc(CdR100) strain living in Cd-enriched culture had developed a lower capacity of nearly 50% growth, and its photosynthetic oxygen development and respiration response were significantly reduced in both light and dark photosynthetic phases. Dc(CdR100) strain showed a very high capacity to remove cadmium from the aquatic environment (over 90%), although most of the removed heavy metal (≈70%) is adhered to the cell wall. These specific characteristics of Dc(CdR100) cells suggest the possibility of using this strain in conjunction with Dc(wt) strain as bioelements into a dual-head biosensor, and in bioremediation processes on freshwater polluted with Cd.

Published

2016

3. The Effects of Anthropogenic Stressors on Wetland Loss and Habitat Quality Deterioration in the Upper Guadiana River Basin: A Long-Term Assessment (1970–2000)

Author

M. O. Viedma, R. Sánchez-Andrés, and S. Sánchez-Carrillo

Subjects

Hydrology, geography, education.field_of_study, geography.geographical_feature_category, Soil salinity, Ecology, Population, Drainage basin, Wetland, Structural basin, Overexploitation, Habitat destruction, Habitat, Environmental science, education

Abstract

During the last four decades, around 1,500 km2 of dry croplands have been transformed, and are now irrigated in the Upper Guadiana river basin, causing hydrologic overexploitation and wetland desiccation. However, there are no estimations on how anthropogenic stressors have been changing the wetland landscape in the recent past. This chapter focuses on the understanding of how the changes on land-use land-cover (LULC), economic activities and population have driven wetland losses and habitat degradation in the basin from the 1970s. Our results show that 40.5% (2,041.6 ha) of the 5,321 ha of wetlands existing in the early 1970s had disappeared in the last 30 years (1970–2000). Most wetland losses occurred through the period 1978–1990, which registered a rate 127 ha of wetland lost per year. Most affected were floodplain wetlands (47% of total loss) and rain-fed temporary ponds (24%). During the entire period 1978–1999, the loss of wetlands could be significantly related to the loss of natural vegetation, as well as to the reduction of agricultural employment. Habitat quality of wetlands showed a clear pattern of nutrient over-enrichment, as well as a trend towards salinization, the later related to the greater disappearance of most freshwater wetlands (0–2,500 µS cm−1). LULC, economic activities and demography explained around 50% of wetland loss and habitat quality deterioration. Until 1990, the pressure of population growth, combined with the agricultural sector, explained the disappearance of most wetland area. From then on, habitat quality has been more impacted in areas where industry and building sectors had more weight in the socioeconomic development (also densely populated watersheds).

Published

2010

4. Climate and Hydrologic Trends: Climate Change Versus Hydrologic Overexploitation as Determinants of the Fluctuating Wetland Hydrology

Author

S. Sánchez-Carrillo and M. Álvarez-Cobelas

Subjects

Hydrology, geography, geography.geographical_feature_category, Water flow, business.industry, Water storage, Climate change, Water supply, Wetland, Hydrology (agriculture), Evapotranspiration, Environmental science, business, Groundwater

Abstract

Hydrology is the key to wetland persistence and conservation. Las Tablas de Daimiel National Park is among the many freshwater wetlands around the world that experienced strong hydrological alterations since the 1970s. Wetland hydrological functioning changed from a groundwater-dependent system to one that is maintained by artificial external water diversions. Throughout this chapter, using available data from 1904 to 2008, we analyze climate trends and hydrology of the wetland in order to quantify the changes occurred in the water budget components as well as to assess the main causes of its hydrological disturbance. Finally, through a hydrological model, developed to simulate the current wetland hydrologic functioning, the hydroperiod restoration is evaluated using multiple scenarios. Both rainfall and water flow variability are the main hydrological patterns in the wetland area, whilst evapotranspiration appeared as the main hydrologic variable controlling the TDNP annual water storage. The historical analysis of the annual inundation patterns at TNDN has discriminating between four distinctive hydroperiods, showing the importance of groundwater discharges to sustain the pristine hydroperiod. While drought frequency – as measured by the Standard Precipitation Index (SPI) – did not increase in the region, groundwater pumping for irrigation appeared as the main cause of groundwater overexploitation and wetland hydrological degradation. Through a hydrological model developed to simulate wetland hydrology, it was possible to test the restoration of the wetland hydroperiod, using scenarios which promote cut-sedge recovery and open water areas. Hydrological restoration could be achieved by means of an external annual water supply of close to 54 Mm3. Future stream and groundwater flows at the Upper Guadiana basin will depend on the land use management, while climate change effects will be secondary, considering the actual hydrological situation.

Published

2010

5. [Untitled]

Author

S. Sánchez Carrillo, M. Alvarez Cobelas, David G. Angeler, and C. Vizcayno Muñoz

Subjects

Geology

Abstract

Las tasas de acrecion registradas en el Parque Nacional Las Tablas de Daimiel son muy elevadas (2,38 ± 1,93 cm ano-1) comparadas con las de la mayoria de los humedales. La distribucion espacial de la acrecion depende de las caracteristicas topograficas del lecho, de la profundidad y del desarrollo de la vegetacion, y es mayor a la entrada reduciendose de manera significativa hacia la zona terminal del Parque. Se aprecian diferencias en el deposito en funcion de las caracteristicas hidrodinamicas y bioticas existentes en cada zona del humedal, dominando los limos en las zonas de canal y las arenas en las zonas estancadas (someras o profundas) con o sin vegetacion. Existe una marcada tendencia estacional de la sedimentacion con valores maximos durante los meses de otono e invierno, cuando son mayores los aportes procedentes de la descomposicion de los macrofitos emergentes. Los sedimentos acumulados presentan un alto contenido en materia mineral autoctona (31-57 %). La mayor parte de la materia organica depositada se genera dentro del humedal (45-65 %) y procede principalmente de la vegetacion emergente. La materia mineral autoctona puede proceder de una rapida mineralizacion de los restos organicos depositados y/o de la precipitacion endogena de calcita, que se presenta como la fase mineral mas abundante. Una simulacion de la evolucion sedimentarla del humedal indica su posible desaparicion, de continuar las condiciones actuales, en los proximos 100 anos

Published

2000

6. Climate Effects on Belowground Tea Litter Decomposition Depend on Ecosystem and Organic Matter Types in Global Wetlands.

Author

Trevathan-Tackett SM, Kepfer-Rojas S, Malerba M, Macreadie PI, Djukic I, Zhao J, Young EB, York PH, Yeh SC, Xiong Y, Winters G, Whitlock D, Weaver CA, Watson A, Visby I, Tylkowski J, Trethowan A, Tiegs S, Taylor B, Szpikowski J, Szpikowska G, Strickland VL, Stivrins N, Sousa AI, Sinutok S, Scheffel WA, Santos R, Sanderman J, Sánchez-Carrillo S, Sanchez-Cabeza JA, Rymer KG, Ruiz-Fernandez AC, Robroek BJM, Roberts T, Ricart AM, Reynolds LK, Rachlewicz G, Prathep A, Pinsonneault AJ, Pendall E, Payne R, Ozola I, Onufrock C, Ola A, Oberbauer SF, Numbere AO, Novak AB, Norkko J, Norkko A, Mozdzer TJ, Morgan P, Montemayor DI, Martin CW, Malone SL, Major M, Majewski M, Lundquist CJ, Lovelock CE, Liu S, Lin HJ, Lillebo A, Li J, Kominoski JS, Khuroo AA, Kelleway JJ, Jinks KI, Jerónimo D, Janousek C, Jackson EL, Iribarne O, Hanley T, Hamid M, Gupta A, Guariento RD, Grudzinska I, da Rocha Gripp A, González Sagrario MA, Garrison LM, Gagnon K, Gacia E, Fusi M, Farrington L, Farmer J, de Assis Esteves F, Escapa M, Domańska M, Dias ATC, de Los Santos CB, Daffonchio D, Czyryca PM, Connolly RM, Cobb A, Chudzińska M, Christiaen B, Chifflard P, Castelar S, Carneiro LS, Cardoso-Mohedano JG, Camden M, Caliman A, Bulmer RH, Bowen J, Boström C, Bernal S, Berges JA, Benavides JC, Barry SC, Alatalo JM, Al-Haj AN, and Adame MF

Subjects

Tea, Climate, Ecosystem, Carbon, Temperature, Wetlands

Abstract

Patchy global data on belowground litter decomposition dynamics limit our capacity to discern the drivers of carbon preservation and storage across inland and coastal wetlands. We performed a global, multiyear study in over 180 wetlands across 28 countries and 8 macroclimates using standardized litter as measures of "recalcitrant" (rooibos tea) and "labile" (green tea) organic matter (OM) decomposition. Freshwater wetlands and tidal marshes had the highest tea mass remaining, indicating a greater potential for carbon preservation in these ecosystems. Recalcitrant OM decomposition increased with elevated temperatures throughout the decay period, e.g., increase from 10 to 20 °C corresponded to a 1.46-fold increase in the recalcitrant OM decay rate constant. The effect of elevated temperature on labile OM breakdown was ecosystem-dependent, with tidally influenced wetlands showing limited effects of temperature compared with freshwater wetlands. Based on climatic projections, by 2050 wetland decay constants will increase by 1.8% for labile and 3.1% for recalcitrant OM. Our study highlights the potential for reduction in belowground OM in coastal and inland wetlands under increased warming, but the extent and direction of this effect at a large scale is dependent on ecosystem and OM characteristics. Understanding local versus global drivers is necessary to resolve ecosystem influences on carbon preservation in wetlands.

Published

2024

7. Organic matter processing by heterotrophic bacterioplankton in a large tropical river: Relating elemental composition and potential carbon mineralization.

Author

Cuevas-Lara D, García-Oliva F, Sánchez-Carrillo S, and Alcocer J

Subjects

Nitrogen analysis, Nitrogen metabolism, Mexico, Plankton metabolism, Phosphorus analysis, Phosphorus metabolism, Seasons, Carbon Dioxide metabolism, Carbon Dioxide analysis, Tropical Climate, Bacteria metabolism, Heterotrophic Processes, Rivers chemistry, Rivers microbiology, Carbon metabolism, Carbon analysis

Abstract

River hydrology shapes the sources, concentration, and stoichiometry of organic matter within drainage basins. However, our understanding of how the microbes process dissolved organic matter (DOM) and recycle nutrients in tropical rivers needs to be improved. This study explores the relationships between elemental DOM composition (carbon/nitrogen/phosphorus: C/N/P), C and N uptake, and C mineralization by autochthonous bacterioplankton in the Usumacinta River, one of the most important fluvial systems in Mexico. Our study investigated changes in the composition and concentration of DOM and evaluated carbon dioxide (CO2)production rates (C-CO2) through laboratory experiments. We compared three sites representing the middle and lower river basins, including their transitional zones, during the rainy and dry seasons. After incubation (120 h at 25°C), the DOM decreased between 25% and 89% of C content. Notably, the initial high proportion of C in DOM in samples from the middle-forested zone and the transition led to elevated C-CO2 rates (>10 mg l-1 day-1), in contrast to the lower initial C proportion and subsequent C-CO2 rates (<7 mg l-1 day-1) in the lower river basin. We also found that dissolved organic carbon uptake and NO3- and NH4+ production were higher during the dry season than in the rainy season. The low water flow in the river during the dry season accentuated the differences in elemental composition and microbial processing of DOM among the sites, while the high water flow of the rainy season homogenized these factors. Our findings indicate that microbial metabolism operates with reduced efficiency in C-rich environments like forests, particularly when faced with high C/N and C/P ratios in DOM. This study highlights the influence of the tropical hydrological regime (rainy and dry seasons) and the longitudinal changes in the river basin (middle and lower) topography and land cover on microbial metabolism by constraining DOM characteristics, emphasizing the crucial role of elemental ratios in river DOM processing., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Cuevas-Lara et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

8. Anoxic nitrification with carbon-based materials as terminal electron acceptors.

Author

Ponce-Jahen SJ, Valenzuela EI, Rangel-Mendez JR, Sánchez-Carrillo S, and Cervantes FJ

Subjects

Electrons, Graphite chemistry, Phylogeny, Oxidation-Reduction, Ammonium Compounds metabolism, Anaerobiosis, Nitrates metabolism, Bacteria metabolism, Nitrification, Carbon chemistry

Abstract

This study investigates the potential of humic substances (HS) and graphene oxide (GO), as extracellular electron acceptors (EEA) for nitrification, aiming to explore alternatives to sustain this process in wastewater treatment systems. Experimental results demonstrate the conversion of ammonium to nitrate (up to 87 % of conversion) coupled to the reduction of either HS or GO by anaerobic consortia. Electron balance confirmed the contribution of HS and GO to ammonium oxidation. Tracer analysis in incubations performed with 15 NH 4 + demonstrated 15 NO 3 - as the main product with a minor fraction ending as 29 N 2 . Phylogenetic analysis identified Firmicutes, Euryarchaeota, and Chloroflexi as the microbial lineages potentially involved in anoxic nitrification linked to HS reduction. This study introduces a new avenue for research in which carbon-based materials with electron-accepting capacity may support the anoxic oxidation of ammonium, for instance in bioelectrochemical systems in which carbon-based anodes could support this novel process., 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 © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

9. Abiotic processes control carbon dioxide dynamics in temperate karst lakes.

Author

Vargas-Sánchez M, Alcocer J, Puche E, and Sánchez-Carrillo S

Subjects

Spain, Environmental Monitoring methods, Carbon Cycle, Phytoplankton metabolism, Lakes chemistry, Carbon Dioxide analysis, Carbon Dioxide metabolism, Seasons

Abstract

Inland waters are crucial in the carbon cycle, contributing significantly to the global CO 2 fluxes. Carbonate lakes may act as both sources and sinks of CO 2 depending on the interactions between the amount of dissolved inorganic carbon (DIC) inputs, lake metabolisms, and geochemical processes. It is often difficult to distinguish the dominant mechanisms driving CO 2 dynamics and their effects on CO 2 emissions. This study was undertaken in three groundwater-fed carbonate-rich lakes in central Spain (Ruidera Lakes), severely polluted with nitrates from agricultural overfertilization. Diel and seasonal (summer and winter) changes in CO 2 concentration (C CO2 ) DIC, and CO 2 emissions-(F CO2 )-, as well as physical and chemical variables, including primary production and phytoplanktonic chlorophyll- a were measured. In addition, δ 13 C-DIC, δ 13 C-CO 2 in lake waters, and δ 13 C of the sedimentary organic matter were measured seasonally to identify the primary CO 2 sources and processes. While the lakes were consistently C CO2 supersaturated and F CO2 was released to the atmosphere during both seasons, the highest C CO2 and DIC were in summer (0.36-2.26 µmol L -1 ). Our results support a strong phosphorus limitation for primary production in these lakes, which impinges on CO 2 dynamics. External DIC inputs to the lake waters primarily drive the C CO2 and, therefore, the F CO2 . The δ 13 C-DIC signatures below -12‰  confirmed the primary geogenic influence on DIC. As also suggested by the high values on the calcite saturation index, the Miller-Tans plot revealed that the CO 2 source in the lakes was close to the signature provided by the fractionation of δ ions drive lake co-precipitation dynamics. Carbonate regions extend over 15% of the Earth's surface but seem essential in the CO 13 C-CO 2 from calcite precipitation. Therefore, the main contribution behind the C CO2 values found in these karst lakes should be attributed to the calcite precipitation process, which is temperature-dependent according to the seasonal change observed in δ 13 C-DIC values. Finally, co-precipitation of phosphate with calcite could partly explain the observed low phytoplankton production in these lakes and the impact on the contribution to increasing greenhouse gas emissions. However, as eutrophication increases and the soluble reactive phosphorus (SRP) content increases, the co-precipitation of phosphate is expected to be progressively inhibited. These thresholds must be assessed to understand how the CO 3 2- ions drive lake co-precipitation dynamics. Carbonate regions extend over 15% of the Earth's surface but seem essential in the CO 2 dynamics at a global scale., Competing Interests: The authors declare there are no competing interests., (©2024 Vargas-Sánchez et al.)

Published

2024

10. Fecal Metabolome and Bacterial Composition in Severe Obesity: Impact of Diet and Bariatric Surgery.

Author

Salazar N, Ponce-Alonso M, Garriga M, Sánchez-Carrillo S, Hernández-Barranco AM, Redruello B, Fernández M, Botella-Carretero JI, Vega-Piñero B, Galeano J, Zamora J, Ferrer M, de Los Reyes-Gavilán CG, and Del Campo R

Subjects

Bacteria genetics, Diet, Feces microbiology, Humans, Metabolome, Weight Loss, Ammonium Compounds, Bariatric Surgery methods, Gastrointestinal Microbiome, Obesity, Morbid microbiology, Obesity, Morbid surgery

Abstract

The aim of this study was to monitor the impact of a preoperative low-calorie diet and bariatric surgery on the bacterial gut microbiota composition and functionality in severe obesity and to compare sleeve gastrectomy (SG) versus Roux-en-Y gastric bypass (RYGB). The study also aimed to incorporate big data analysis for the omics results and machine learning by a Lasso-based analysis to detect the potential markers for excess weight loss. Forty patients who underwent bariatric surgery were recruited (14 underwent SG, and 26 underwent RYGB). Each participant contributed 4 fecal samples (baseline, post-diet, 1 month after surgery and 3 months after surgery). The bacterial composition was determined by 16S rDNA massive sequencing using MiSeq (Illumina). Metabolic signatures associated to fecal concentrations of short-chain fatty acids, amino acids, biogenic amines, gamma-aminobutyric acid and ammonium were determined by gas and liquid chromatography. Orange 3 software was employed to correlate the variables, and a Lasso analysis was employed to predict the weight loss at the baseline samples. A correlation between Bacillota (formerly Firmicutes) abundance and excess weight was observed only for the highest body mass indexes. The low-calorie diet had little impact on composition and targeted metabolic activity. RYGB had a deeper impact on bacterial composition and putrefactive metabolism than SG, although the excess weight loss was comparable in the two groups. Significantly higher ammonium concentrations were detected in the feces of the RYGB group. We detected individual signatures of composition and functionality, rather than a gut microbiota characteristic of severe obesity, with opposing tendencies for almost all measured variables in the two surgical approaches. The gut microbiota of the baseline samples was not useful for predicting excess weight loss after the bariatric process.

Published

2022

11. Anaerobic ammonium oxidation linked to sulfate and ferric iron reduction fuels nitrogen loss in marine sediments.

Author

Rios-Del Toro EE, Valenzuela EI, López-Lozano NE, Cortés-Martínez MG, Sánchez-Rodríguez MA, Calvario-Martínez O, Sánchez-Carrillo S, and Cervantes FJ

Subjects

Anaerobiosis, Bacteria metabolism, Biodegradation, Environmental, Electrons, Iron analysis, Oxidation-Reduction, Sulfur metabolism, Ammonium Compounds metabolism, Ferric Compounds metabolism, Geologic Sediments chemistry, Nitrogen analysis, Seawater microbiology, Sulfates metabolism

Abstract

Availability of fixed nitrogen is a pivotal driver on primary productivity in the oceans, thus the identification of key processes triggering nitrogen losses from these ecosystems is of major importance as they affect ecosystems function and consequently global biogeochemical cycles. Denitrification and anaerobic ammonium oxidation coupled to nitrite reduction (Anammox) are the only identified marine sinks for fixed nitrogen. The present study provides evidence indicating that anaerobic ammonium oxidation coupled to the reduction of sulfate, the most abundant electron acceptor present in the oceans, prevails in marine sediments. Tracer analysis with 15 N-ammonium revealed that this microbial process, here introduced as Sulfammox, accounts for up to 5 μg 15 N 2 produced g -1 day -1 in sediments collected from the eastern tropical North Pacific coast. Raman and X-ray diffraction spectroscopies revealed that elemental sulfur and sphalerite (ZnFeS) were produced, besides free sulfide, during the course of Sulfammox. Anaerobic ammonium oxidation linked to Fe(III) reduction (Feammox) was also observed in the same marine sediments accounting for up to 2 μg 15 N 2 produced g -1 day -1 . Taxonomic characterization, based on 16S rRNA gene sequencing, of marine sediments performing the Sulfammox and Feammox processes revealed the microbial members potentially involved. These novel nitrogen sinks may significantly fuel nitrogen loss in marine environments. These findings suggest that the interconnections among the oceanic biogeochemical cycles of N, S and Fe are much more complex than previously considered.

Published

2018

12. Inferring the relative resilience of alternative states.

Author

Angeler DG, Allen CR, Rojo C, Alvarez-Cobelas M, Rodrigo MA, and Sánchez-Carrillo S

Subjects

Floods, Geography, Models, Theoretical, Seasons, Spain, Biodiversity, Ecosystem, Phytoplankton

Abstract

Ecological systems may occur in alternative states that differ in ecological structures, functions and processes. Resilience is the measure of disturbance an ecological system can absorb before changing states. However, how the intrinsic structures and processes of systems that characterize their states affects their resilience remains unclear. We analyzed time series of phytoplankton communities at three sites in a floodplain in central Spain to assess the dominant frequencies or "temporal scales" in community dynamics and compared the patterns between a wet and a dry alternative state. The identified frequencies and cross-scale structures are expected to arise from positive feedbacks that are thought to reinforce processes in alternative states of ecological systems and regulate emergent phenomena such as resilience. Our analyses show a higher species richness and diversity but lower evenness in the dry state. Time series modeling revealed a decrease in the importance of short-term variability in the communities, suggesting that community dynamics slowed down in the dry relative to the wet state. The number of temporal scales at which community dynamics manifested, and the explanatory power of time series models, was lower in the dry state. The higher diversity, reduced number of temporal scales and the lower explanatory power of time series models suggest that species dynamics tended to be more stochastic in the dry state. From a resilience perspective our results highlight a paradox: increasing species richness may not necessarily enhance resilience. The loss of cross-scale structure (i.e. the lower number of temporal scales) in community dynamics across sites suggests that resilience erodes during drought. Phytoplankton communities in the dry state are therefore likely less resilient than in the wet state. Our case study demonstrates the potential of time series modeling to assess attributes that mediate resilience. The approach is useful for assessing resilience of alternative states across ecological and other complex systems.

Published

2013

13. Export of nitrogen from catchments: a worldwide analysis.

Author

Alvarez-Cobelas M, Angeler DG, and Sánchez-Carrillo S

Subjects

Agriculture, Ammonia analysis, Climate, Databases, Factual, Ecosystem, Forestry, Nitrates analysis, Rain, Rivers, Time, Environmental Pollution analysis, Fertilizers analysis, Internationality, Nitrogen analysis, Water Pollutants, Chemical analysis

Abstract

This study reviews nitrogen export rates from 946 rivers of the world to determine the influence of quantitative (runoff, rainfall, inhabitant density, catchment area, percentage of land use cover, airborne deposition, fertilizer input) and qualitative (dominant type of forest, occurrence of stagnant waterbodies, dominant land use, occurrence of point sources, runoff type) environmental factors on nitrogen fluxes. All fractions (total, nitrate, ammonia, dissolved organic and particulate organic) of nitrogen export showed a left-skewed distribution, which suggests a relatively pristine condition for most systems. Total nitrogen export showed the highest variability whereas total organic nitrogen export comprised the dominant fraction of export. Nitrogen export rates were only weakly explained by our qualitative and quantitative environmental variables. Our study suggests that the consideration of spatial and temporal scales is important for predicting nitrogen export rates using simple and easy-to-get environmental variables. Regionally based modelling approaches prove more useful than global-scale analyses.

Published

2008

14. Eutrophication and sedimentation patterns in complete exploitation of water resources scenarios: an example from Northwestern semi-arid Mexico.

Author

Sánchez-Carrillo S, Alatorre LC, Sánchez-Andrés R, and Garatuza-Payán J

Subjects

Chlorophyll analysis, Chlorophyll A, Mexico, Nitrogen analysis, Phosphorus analysis, Rivers chemistry, Water Movements, Desert Climate, Eutrophication, Geologic Sediments, Water Pollutants, Chemical analysis, Water Supply standards

Abstract

Water requirements to supply human needs lead water stakeholders to store more water during surplus periods to fulfil the demand during--not only--scarcity periods. At the reservoirs, mostly those in semi-arid regions, water level then fluctuates extremely between rises and downward during one single year. Besides of water management implications, changes on physical, chemical and biological dynamics of these drawdown and refilling are little known yet. This paper shows the results, throughout a year, on solids, nutrients (N and P), chlorophyll-a, and sedimentation changes on the dynamics, when the former policy was applied in a reservoir from the semi-arid Northwestern Mexico. Water level sinusoidal trend impinged changes on thermal stratification and mixing, modifying nutrient cycling and primary producer responses. According to nitrogen and phosphorus concentration as well as chlorophyll-a, reservoir was mesotrophic, becoming hypertrophic during drawdown. Nutrient concentrations were high (1.22 +/- 0.70 and 0.14 +/- 0.12 mg P l(-1)), increasing phosphorus and lowering N:P significantly throughout the study period, although no intensive agricultural, no urban development, neither industrial activities take place in the watershed. This suggests nutrient recycling complex mechanisms, including nutrient release from the sediment-water interface as the main nutrient pathway when shallowness, at the same time as mineralization, increases. Outflows controlled nitrogen and phosphorus availability on the ecosystem while organic matter depended on river inflows. As on other subtropical aquatic ecosystems, nitrogen limited primary productivity (Spearman correlation R = 0.75) but chlorophyll-a seasonal pattern showed an irregular trend, prompting other no-nutrient related limitants. Shallowness induced a homogeneous temporal pattern on water quality. This observed temporal variability was mainly explained statistically by changes on solids (mineral and organic), chlorophyll-a and flows (62.3%). Annual sedimentation rates of total solids ranged from 11.73 to 16.29 kg m(-2) year(-1) with organic matter comprising around 30%. N:P ratio on sedimentation rates were as high as could be expected in a resuspension dominated ecosystem, and spatially inverse related with N:P ratio on bottom sediments. Distance from river inlet into the reservoir reveals a marked spatial heterogeneity on solid and nitrogen sedimentation, showing the system dependence on river inflows and supporting resuspension as the main phosphorus pathway. Accretion rates (2.19 +/- 0.40 cm year(-1)) were not related to hydrological variability but decreased with the distance to the river input. Total sediment accumulation (9,895 tons km(-2) year(-1)) denotes siltation as other serious environmental problem in reservoirs but possibly not related with operational procedures.

Published

2007

15. Does seston size structure reflect fish-mediated effects on water quality in a degraded semiarid wetland?

Author

Angeler DG, Sánchez-Carrillo S, Rodrigo MA, Alvarez-Cobelas M, and Rojo C

Subjects

Animals, Evaluation Studies as Topic, Models, Theoretical, Particle Size, Species Specificity, Zooplankton metabolism, Carps metabolism, Cyprinodontiformes metabolism, Water Pollutants, Chemical analysis, Wetlands

Abstract

This study evaluates whether the size structure of seston (the sum of living and nonliving particles in the water column) reflects the effects of fish on wetland water quality. Using enclosures, we measured water quality and zooplankton community structure in the presence and absence of two fish species with distinct foraging strategies [benthivorous carp (Cyprinus carpio) and planktivorous mosquitofish (Gambusia holbrooki)]. Seston collected from the enclosures was counted and sized automatically with a Coulter counter, and the size structure in the range of 1-60 microm was modelled using the underlying Pareto distribution of particles. Only Cyprinus contributed to a loss of water quality (increased nutrient levels, algal and non-algal turbidity, hypoxia), while both fish species changed zooplankton community composition compared to fishless controls. However, these changes were not reflected in parameters [goodness of fit (r (2)) and parameter c (slopes)] of Pareto models. Multivariate statistics suggest that seston size structure responded more to environmental gradients related to water depth but the relationships were also weak. Our overall result contrasts with the regulation of size spectra constructed from living organisms. Although seston integrates many structural and functional features of the water column, the lack of strong relationships between Pareto model parameters and water quality suggests that a size-based approach to characterise seston structure has a limited potential for assessing biota-mediated effects in wetlands in a straightforward manner.

Published

2007

16. Characterization of the membrane binding mode of the C2 domain of PKC epsilon.

Author

Corbalán-Garcia S, Sánchez-Carrillo S, García-García J, and Gómez-Fernández JC

Subjects

Animals, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Models, Molecular, Mutagenesis, Site-Directed, Peptide Fragments chemistry, Peptide Fragments genetics, Peptide Fragments metabolism, Phosphatidic Acids chemistry, Phosphatidylserines chemistry, Phospholipids chemistry, Protein Binding genetics, Protein Kinase C genetics, Protein Kinase C metabolism, Protein Kinase C-epsilon, Protein Structure, Secondary genetics, Protein Structure, Tertiary genetics, Rats, Membrane Proteins chemistry, Protein Kinase C chemistry

Abstract

PKCepsilon is a member of the group of novel PKCs that contain a C2 domain located in their N-terminal region. On the basis of recent structural studies, a series of mutants were prepared to increase our knowledge of the mechanism of the phospholipid binding site of this domain. The results revealed that this domain preferentially binds to phosphatidic acid- and phosphatidylserine-containing vesicles. Although the increase in affinity was linear in the case of phosphatidic acid, it became exponential when the vesicles contained increasing concentrations of phosphatidylserine. Site-directed mutagenesis studies showed that residues W23, R26, and R32 located in loop 1 and I89 and Y91 located in loop 3 are of critical importance when the binding is performed with phosphatidic acid-containing vesicles. Furthermore, when the same mutants were assayed with phosphatidylserine-containing vesicles, no binding was observed in any case, reflecting the smaller affinity of the C2 domain for phosphatidylserine-containing vesicles. A study of the ionic nature of the membrane interaction suggested that it is mainly driven by electrostatic interactions that are disrupted by very low salt concentrations. Differential scanning calorimetry experiments performed to ascertain whether this interaction affected the transition phase of the phosphatidic acid demonstrated that increasing concentrations of the protein lead to changes in the transition, with more than one peak appearing at lower temperatures, which suggests a weak interaction focused on the polar headgroup of the phospholids. In conclusion, a different membrane-binding mode from those previously described in other C2 domains has been found and is seemingly based on electrostatic, interfacial, and hydrophobic interactions without the participation of Ca(2+) ions.

Published

2003