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J. Marques, P. Maranhão, M. Pardal (1993)
Human Impact Assessment on the Subtidal Macrobenthic Community Structure in the Mondego Estuary (Western Portugal)Estuarine Coastal and Shelf Science, 37
(2016)
Variation in leaf litter decomposition rate according to salinity and water regime in Juglans regia L
C. Townsend, S. Dolédec, M. Scarsbrook (1997)
Species traits in relation to temporal and spatial heterogeneity in streams: a test of habitat templet theoryFreshwater Biology, 37
C. Elias, A. Calapez, S. Almeida, M. Feio (2015)
Determining useful benchmarks for the bioassessment of highly disturbed areas based on diatomsLimnologica, 51
M. Feio, S. Almeida, F. Aguiar (2017)
Functional associations between microalgae, macrophytes and invertebrates distinguish river typesAquatic Sciences, 79
R. Naiman, J. Melillo, M. Lock, T. Ford, S. Reice (1987)
Longitudinal patterns of ecosystem processes and community structure in a subarctic river continuumEcology, 68
C. Hawkins, J. Sedell (1981)
Longitudinal and Seasonal Changes in Functional Organization of Macroinvertebrate Communities in Four Oregon StreamsEcology, 62
A. Fuentes-Cid, É. Chauvet, H. Etcheber, E. De-Oliveira, A. Sottolichio, S. Schmidt (2015)
Leaf litter degradation in highly turbid transitional waters: preliminary results from litter-bag experiments in the Gironde EstuaryGeodinamica Acta, 27
J. Culp, R. Davies (1982)
Analysis of Longitudinal Zonation and the River Continuum Concept in the Oldman–South Saskatchewan River SystemCanadian Journal of Fisheries and Aquatic Sciences, 39
J. Marques, P. Maranhão, M. Pardal (2014)
Characterisation of the macroinvertebrate benthic communities in the Mondego Estuary
M. Hemminga, J. Leeuw, W. Munek, B. Koutstaal (1991)
Decomposition in estuarine salt marshes: the effect of soil salinity and soil water contentVegetatio, 94
FRANçOIS Chevene, Sylvain Doléadec, D. Chessel (1994)
A fuzzy coding approach for the analysis of long‐term ecological dataFreshwater Biology, 31
F. Altermatt, C. Little, E. Mächler, Shaopeng Wang, Xiaowei Zhang, Rosetta Blackman (2020)
Uncovering the complete biodiversity structure in spatial networks: the example of riverine systemsOikos
Erin Peterson, J. Hoef, Dan Isaak, Jeffrey Falke, Marie-Josée Fortin, Chris Jordan, K. McNyset, P. Monestiez, A. Ruesch, Aritra Sengupta, Nicholas Som, E. Steel, David Theobald, C. Torgersen, Seth Wenger (2013)
Modelling dendritic ecological networks in space: an integrated network perspective.Ecology letters, 16 5
E. Berger, O. Frör, R. Schäfer (2018)
Salinity impacts on river ecosystem processes: a critical mini-reviewPhilosophical Transactions of the Royal Society B, 374
F. Sangiorgio, A. Basset, Maurizio Pinna, L. Sabetta, M. Abbiati, M. Ponti, M. Minocci, S. Orfanidis, A. Nicolaidou, S. Moncheva, A. Trayanova, L. Georgescu, S. Dragan, S. Beqiraj, D. Koutsoubas, A. Evagelopoulos, S. Reizopoulou (2007)
Ecosystem processes: litter breakdown patterns in Mediterranean and Black Sea transitional watersTransitional Waters Bulletin, 1
A. Sabatino, G. Cristiano, Maurizio Pinna, P. Lombardo, F. Miccoli, Gabriele Marini, P. Vignini, B. Cicolani (2014)
Structure, functional organization and biological traits of macroinvertebrate assemblages from leaf-bags and benthic samples in a third-order stream of Central Apennines (Italy)Ecological Indicators, 46
G. Winkler, J. Dodson, N. Bertrand, Denis Thivierge, W. Vincent (2003)
Trophic coupling across the St. Lawrence River estuarine transition zoneMarine Ecology Progress Series, 251
M. Feio, S. Dolédec, M. Graça (2015)
Human disturbance affects the long-term spatial synchrony of freshwater invertebrate communities.Environmental pollution, 196
J. McArthur, J. Aho, R. Rader, G. Mills (1994)
Interspecific Leaf Interactions during Decomposition in Aquatic and Floodplain EcosystemsJournal of the North American Benthological Society, 13
Tamara Rodríguez-Castillo, Edurne Estévez, A. González-Ferreras, J. Barquín (2018)
Estimating Ecosystem Metabolism to Entire River NetworksEcosystems, 22
R. Nicholls, A. Cazenave (2010)
Sea-Level Rise and Its Impact on Coastal ZonesScience, 328
(1986)
Aproveitamento hidráulico do vale do Mondego
Verónica Ferreira, É. Chauvet (2011)
Synergistic effects of water temperature and dissolved nutrients on litter decomposition and associated fungiGlobal Change Biology, 17
J. Thorp, M. Thoms, Michael Delong (2006)
The riverine ecosystem synthesis: biocomplexity in river networks across space and timeRiver Research and Applications, 22
B. Statzner, B. Higler (1986)
Stream hydraulics as a major determinant of benthic invertebrate zonation patternsFreshwater Biology, 16
M. Lopes, Patrícia Martins, Fernando Ricardo, A. Rodrigues, V. Quintino (2011)
In situ experimental decomposition studies in estuaries: A comparison of Phragmites australis and Fucus vesiculosusEstuarine Coastal and Shelf Science, 92
P. Bady, S. Dolédec, B. Dumont, J. Fruget (2004)
Multiple co-inertia analysis: a tool for assessing synchrony in the temporal variability of aquatic communities.Comptes rendus biologies, 327 1
R. Walters, M. Hassall (2006)
The Temperature‐Size Rule in Ectotherms: May a General Explanation Exist after All?The American Naturalist, 167
Dirk Zeuss, S. Brunzel, R. Brandl (2017)
Environmental drivers of voltinism and body size in insect assemblages across EuropeGlobal Ecology and Biogeography, 26
C. Connolly, W. Sobczak, S. Findlay (2014)
Salinity Effects on Phragmites Decomposition Dynamics Among the Hudson River’s Freshwater Tidal WetlandsWetlands, 34
R. Vannote, G. Minshall, Kenneth Cummins, J. Sedell, Colbert Gushing (1980)
The River Continuum ConceptCanadian Journal of Fisheries and Aquatic Sciences, 37
Stefano Larsen, M. Bruno, I. Vaughan, G. Zolezzi (2019)
Testing the River Continuum Concept with geostatistical stream-network modelsEcological Complexity
Paula Sardiña, J. Beardall, J. Beringer, M. Grace, R. Thompson (2017)
Consequences of altered temperature regimes for emerging freshwater invertebratesAquatic Sciences, 79
C. Townsend, A. Hildrew (1994)
Species traits in relation to a habitat templet for river systemsFreshwater Biology, 31
R. Naiman, H. Décamps (1997)
The Ecology of Interfaces: Riparian ZonesAnnual Review of Ecology, Evolution, and Systematics, 28
Matthew Yarrow, V. Marín (2007)
Toward Conceptual Cohesiveness: a Historical Analysis of the Theory and Utility of Ecological Boundaries and Transition ZonesEcosystems, 10
(1996)
Crayfish, Procambarus clarkii, effects on initial stages of rice growth in lower Mondego River valley (Portugal)
Tiago Múria, J. Cabral, R. Lopes, J. Marques (1997)
Low-water use of the Mondego estuary (West Portugal) by waders (Charadrii).
S. Domisch, S. Jähnig, P. Haase (2011)
Climate‐change winners and losers: stream macroinvertebrates of a submontane region in Central EuropeFreshwater Biology, 56
W. Junk, K. Wantzen (2004)
The flood pulse concept: new aspects, approaches and applications - an update
E. Piano, F. Bona, E. Falasco, V. Morgia, G. Badino, M. Isaia (2015)
Environmental drivers of phototrophic biofilms in an Alpine show cave (SW-Italian Alps).The Science of the total environment, 536
M. Graça, M. Pardal, J. Marques (2002)
Aquatic ecology of the Mondego River basin global importance of local experience
S. Dray, D. Chessel, J. Thioulouse (2003)
CO‐INERTIA ANALYSIS AND THE LINKING OF ECOLOGICAL DATA TABLESEcology, 84
D. Sutcliffe (2010)
Reproduction in Gammarus (Crustacea, Amphipoda): female strategies, 3
M. Feio, T. Reynoldson, Verónica Ferreira, M. Graça (2007)
A predictive model for freshwater bioassessment (Mondego River, Portugal)Hydrobiologia, 589
S. Dolédec, D. Chessel (1994)
Co‐inertia analysis: an alternative method for studying species–environment relationshipsFreshwater Biology, 31
B. Southwood (1977)
HABITAT, THE TEMPLET FOR ECOLOGICAL STRATEGIES?Journal of Animal Ecology, 46
P. Gomes, Verónica Ferreira, A. Tonin, A. Medeiros, J. Júnior (2017)
Combined Effects of Dissolved Nutrients and Oxygen on Plant Litter Decomposition and Associated Fungal CommunitiesMicrobial Ecology, 75
V. Villanueva, J. Font, T. Schwartz, A. Romani (2011)
Biofilm formation at warming temperature: acceleration of microbial colonization and microbial interactive effectsBiofouling, 27
M. Menéndez, O. Hernández, N. Sanmartí, F. Comín (2004)
Variability of Organic Matter Processing in a Mediterranean Coastal LagoonInternational Review of Hydrobiology, 89
(1987)
Longitudinal zonation of the benthic invertebrate fauna in the river Glomma
J. Neto, M. Flindt, J. Marques, M. Pardal (2008)
Modelling nutrient mass balance in a temperate meso-tidal estuary: Implications for managementEstuarine Coastal and Shelf Science, 76
F. Sangiorgio, Maurizio Pinna, A. Basset (2004)
Inter- and intra-habitat variability of plant detritus decomposition in a transitional environment (Lake Alimini, Adriatic Sea)Chemistry and Ecology, 20
M. Feio, T. Alves, M. Boavida, A. Medeiros, M. Graça (2010)
Functional indicators of stream health: a river-basin approachFreshwater Biology, 55
M. Duran (2007)
Life Cycle of Gammarus pulex (L.) in the River YeşilırmakTurkish Journal of Zoology, 31
É. Chauvet (1997)
Leaf litter decomposition in large rivers: the case of the River GaronneLimnetica
J. Neto, H. Teixeira, J. Patrício, A. Baeta, H. Veríssimo, Rute Pinto, J. Marques (2010)
The Response of Estuarine Macrobenthic Communities to Natural- and Human-Induced Changes: Dynamics and Ecological QualityEstuaries and Coasts, 33
Verónica Ferreira, V. Gulis, M. Graça (2006)
Whole-stream nitrate addition affects litter decomposition and associated fungi but not invertebratesOecologia, 149
J. Grubaugh, J. Wallace, E. Houston (1996)
Longitudinal changes of macroinvertebrate communities along an Appalachian stream continuumCanadian Journal of Fisheries and Aquatic Sciences, 53
M. Graça, Verónica Ferreira, C. Canhoto, A. Encalada, Francisco Guerrero‐Bolaño, K. Wantzen, L. Boyero (2015)
A conceptual model of litter breakdown in low order streamsInternational Review of Hydrobiology, 100
J. Thorp, Michael Delong (2002)
Dominance of autochthonous autotrophic carbon in food webs of heterotrophic riversOikos, 96
J. Neto, M. Feio, H. Teixeira, J. Patrício, S. Serra, João Franco, A. Calapez, E. Constantino (2014)
Transitional and freshwater bioassessments: one site, two perspectives?Marine pollution bulletin, 78 1-2
P. Haase, F. Pilotto, Fengqing Li, A. Sundermann, A. Lorenz, J. Tonkin, S. Stoll (2019)
Moderate warming over the past 25 years has already reorganized stream invertebrate communities.The Science of the total environment, 658
V. Baldy, É. Chauvet, J. Charcosset, M. Gessner (2002)
Microbial dynamics associated with leaves decomposing in the mainstem and floodplain pond of a large riverAquatic Microbial Ecology, 28
S. Rundle, M. Attrill, A. Arshad (1998)
Seasonality in macroinvertebrate community composition across a neglected ecological boundary, the freshwater-estuarine transition zoneAquatic Ecology, 32
(2013)
2013)Modelling dendritic ecological networks
(2002)
Introducing the Montego river basin
H. Guasch, E. Martí, S. Sabater (1995)
Nutrient enrichment effects on biofilm metabolism in a Mediterranean streamFreshwater Biology, 33
M. Bayo, J. Casas, L. Cruz‐Pizarro (2005)
Decomposition of submerged Phragmites australis leaf litter in two highly eutrophic mediterranean coastal lagoons : relative contribution of microbial respiration and macroinvertebrate feedingArchiv Fur Hydrobiologie, 163
M. Angilletta, Todd Steury, M. Sears (2004)
Temperature, Growth Rate, and Body Size in Ectotherms: Fitting Pieces of a Life-History Puzzle1, 44
(2010)
Romanı́ A (2010) Biofilm
We analysed the relationship between functional and structural variables (leaf litter decomposition, biofilms growth, primary productivity, invertebrate communities’ taxonomic structure, and biological traits) and environmental conditions from headwaters into the estuary, which remains under-investigated. Six river sections (headwaters, middle reach, and four large river sections with increasing salinity) and 18 sites were selected in the Mondego river (Central Portugal). Hypotheses of the expected variations were drawn, based on theory (e.g. River Continuum Concept—RCC) and previous studies. Abiotic conditions were strongly associated with macroinvertebrate communities’ taxonomic composition, but the relationship with functional parameters was different than the predicted one. Decomposition rates were similar from headwaters to the first large river sections (not expected) but increased in the estuarine sections. The high rates of decomposition were associated with the low salinity and especially with the high densities of the shredder Gammarus sp. Biofilm growth rate peaked in intermediate sections and was lower in the headwaters and in the estuary (not expected). The lower algae productivity in the estuary was not compensated by the heterotrophic component of the biofilm. The use of multiple biological traits indicated an unexpected higher functional similarity among the upper river sections, and differences within large river sections (not evident with taxonomic composition). These results show contradictions to widely accepted river concepts, such as the RCC, and highlight the importance of management practices adjusted to each river section to keep the ecosystem functioning. They also increased the knowledge on the transition zone between fresh and estuarine water which is important in the context of mitigation of climate change effects, considering the expected intrusion of saline water upstream.
Aquatic Ecology – Springer Journals
Published: Jan 11, 2021
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