Fungal richness does not buffer the effects of streams salinization on litter decomposition

Free Access

Issue		Ann. Limnol. - Int. J. Lim. Volume 57, 2021


Article Number		5
Number of page(s)		6
DOI		https://doi.org/10.1051/limn/2021003
Published online		08 February 2021

Abelho M. 2009. ATP and ergosterol as indicators of fungal biomass during leaf decomposition in streams: a comparative study. Int Rev Hydrobiol 94: 3–15. [Google Scholar]
Almeida Júnior ES, Martínez A, Gonçalves AL, Canhoto C. 2020. Combined effects of freshwater salinization and leaf traits on litter decomposition. Hydrobiologia 847: 3427–3435. [Google Scholar]
Bärlocher F. 2016. Aquatic hyphomycetes in a changing environment. Fungal Ecol 19: 14–27. [Google Scholar]
Bärlocher F, Kebede YK, Gonçalves AL, Canhoto C. 2013. Incubation temperature and substrate quality modulate sporulation by aquatic hyphomycetes. Microb Ecol 66: 30–39. [Google Scholar]
Cañedo-Argüelles M, Grantham TE, Perrée I, Rieradevall M, Céspedes-Sánchez R, Prat N. 2012. Response of stream invertebrates to short-term salinization: a mesocosm approach. Environ Pollut 166: 144–151. [Google Scholar]
Cañedo-Argüelles M, Hawkins CP, Kefford BJ, Schäfer RB, Dyack BJ, Brucet S, Buchwalter D, Dunlop J, Frör O, Lazorchak J, Coring E, Fernández HR, Goodfellow W, González Achem AL, Hatfield-Dodds S, Karimov BK, Mensah P, Olson JR, Piscart C, Prat N, Ponsá S, Schulz CJ, Timpano AJ. 2016. Saving freshwater from salts. Science 351: 914–916. [Google Scholar]
Canhoto C, Gonçalves AL, Bärlocher F. 2016. Biology and ecological functions of aquatic hyphomycetes in a warming climate. Fungal Ecol 19: 201–218. [Google Scholar]
Canhoto C, Simões S, Gonçalves AL, Guilhermino L, Bärlocher F. 2017. Stream salinization and fungal-mediated leaf decomposition: a microcosm study. Sci Total Environ 599: 1638–1645. [PubMed] [Google Scholar]
Chauvet E, Ferreira V, Giller PS, McKie BG, Tiegs SD, Woodward G, Elosegi A, Dobson M, Fleituch T, Graça MAS, Gulis V, Hladyz S, Lacoursière JO, Lecerf A, Pozo J, Preda E, Riipinen M, Rîşnoveanu G, Vadineanu A, Vought LBM, Gessner MO. 2016. Litter decomposition as an indicator of stream ecosystem functioning at local-to-continental scales: insights from the European RivFunction project. In: Kordas R, Dumbrell A. and Woodward G. (eds.), Advances in Ecological Research, Elsevier, 99–182. [Google Scholar]
Cochero J, Licursi M, Gómez N. 2017. Effects of pulse and press additions of salt on biofilms of nutrient-rich streams. Sci Total Environ 579: 1496–1503. [PubMed] [Google Scholar]
Connolly CT, Sobczak WV, Findlay SEG. 2014. Salinity effects on Phragmites decomposition dynamics among the Hudson River's freshwater tidal wetlands. Wetlands 34: 575–582. [Google Scholar]
Cooper CA, Mayer PM, Faulkner BR. 2014. Effects of road salts on groundwater and surface water dynamics of sodium and chloride in an urban restored stream. Biogeochemistry 121: 149–166. [Google Scholar]
Corsi SR, Graczyk DJ, Geis SW, Booth NL, Richards KD. 2010. A fresh look at road salt: aquatic toxicity and water-quality impacts on local, regional, and national scales. Environ Sci Technol 44: 7376–7382. [Google Scholar]
Costantini ML, Rossi L. 2010. Species diversity and decomposition in laboratory aquatic systems: the role of species interactions. Freshw Biol 55: 2281–2295. [Google Scholar]
Dang CK, Chauvet E, Gessner MO. 2005. Magnitude and variability of process rates in fungal diversity-litter decomposition relationships. Ecol Lett 8: 1129–1137. [Google Scholar]
Duarte S, Pascoal C, Cássio F. 2008. High diversity of fungi may mitigate the impact of pollution on plant litter decomposition in streams. Microb Ecol 56: 688–695. [Google Scholar]
Duarte S, Pascoal C, Cássio F, Bärlocher F. 2006. Aquatic hyphomycete diversity and identity affect leaf litter decomposition in microcosms. Oecologia 147: 658–666. [PubMed] [Google Scholar]
Fernandes I, Pascoal C, Cássio F. 2011. Intraspecific traits change biodiversity effects on ecosystem functioning under metal stress. Oecologia 166: 1019–1028. [PubMed] [Google Scholar]
Fernandes I, Pascoal C, Guimaraes H, Pinto R, Sousa I, Cassio F. 2012. Higher temperature reduces the effects of litter quality on decomposition by aquatic fungi. Freshw Biol 57: 2306–2317. [Google Scholar]
France RL. 2011. Leaves as “crackers”, biofilm as “peanut butter”: Exploratory use of stable isotopes as evidence for microbial pathways in detrital food webs. Oceanol Hydrobiol Stud 40: 110–115. [Google Scholar]
Geraldes P, Pascoal C, Cássio F. 2012. Effects of increased temperature and aquatic fungal diversity on litter decomposition. Fungal Ecol 5: 734–740. [Google Scholar]
Gessner MO. 2003. Qualitative and quantitative analyses of aquatic hyphomycetes in streams. Fungal Divers Res Ser 10: 127–157. [Google Scholar]
Gessner MO, Chauvet E. 2002. A case for using litter breakdown to assess functional stream integrity. Ecol Appl 12: 498–510. [Google Scholar]
Gessner MO, Chauvet E. 1994. Importance of stream microfungi in controlling breakdown rates of leaf litter. Ecology 75: 1807–1817. [Google Scholar]
Gessner MO, Chauvet E. 1993. Ergosterol-to-biomass conversion factors for aquatic hyphomycetes. Appl Environ Microbiol 59: 502–507. [Google Scholar]
Gessner MO, Swan CM, Dang CK McKie BG, Bardgett RD, Wall DH, Hättenschwiler S. 2010. Diversity meets decomposition. Trends Ecol Evol 25: 372–380. [CrossRef] [PubMed] [Google Scholar]
Gómez R, Asencio AD, Picón JM, Del Campo R, Arce MI, Sánchez-Montoya MM, Suárez ML, Vidal-Abarca MR. 2016. The effect of water salinity on wood breakdown in semiarid Mediterranean streams. Sci Total Environ 541: 491–501. [PubMed] [Google Scholar]
Gonçalves AL, Carvalho A, Bärlocher F, Canhoto C. 2019a. Are fungal strains from salinized streams adapted to salt-rich conditions? Philos Trans R Soc B 374: 20180018. [Google Scholar]
Gonçalves AL, Chauvet E, Bärlocher F, Graça MAS, Canhoto C. 2014. Top-down and bottom-up control of litter decomposers in streams. Freshw Biol 59: 2172–2182. [Google Scholar]
Gonçalves AL, Graça MAS, Canhoto C. 2015. Is diversity a buffer against environmental temperature fluctuations? A decomposition experiment with aquatic fungi. Fungal Ecol 17: 96–102. [Google Scholar]
Gonçalves AL, Lírio A.V, Graça MAS, Canhoto C. 2016. Fungal species diversity affects leaf decomposition after drought. Int Rev Hydrobiol 101: 78–86. [Google Scholar]
Gonçalves AL, Simões S, Bärlocher F, Canhoto C. 2019b. Leaf litter microbial decomposition in salinized streams under intermittency. Sci Total Environ 653: 1204–1212. [PubMed] [Google Scholar]
Gulis V, Suberkropp K. 2003. Leaf litter decomposition and microbial activity in nutrient-enriched and unaltered reaches of a headwater stream. Freshw Biol 48: 123–134. [Google Scholar]
Hintz WD, Relyea RA. 2019. A review of the species, community, and ecosystem impacts of road salt salinisation in fresh waters. Freshw Biol 64: 1081–1097. [Google Scholar]
Kaushal SS, Likens GE, Pace ML, Utz RM, Haq S, Gorman J, Grese M. 2018. Freshwater salinization syndrome on a continental scale. Proc Natl Acad Sci 115: E574–E583. [Google Scholar]
Martínez A, Barros J, Gonçalves AL, Canhoto C. 2020. Salinisation effects on leaf litter decomposition in fresh waters: Does the ionic composition of salt matter? Freshw Biol DOI: 10.1111/fwb.13514. [Google Scholar]
Pascoal C, Cássio F, Nikolcheva L, Bärlocher F. 2010. Realized fungal diversity increases functional stability of leaf litter decomposition under zinc stress. Microb Ecol 59: 84–93. [Google Scholar]
R Development Core Team. 2016. R: A language and environment for statistical computing. Vienna: R Foundation for Statistical Computing. [Google Scholar]
Reis F, Nascimento E, Castro H, Canhoto C, Gonçalves AL, Simões S, García-Palacios P, Milla R, Sousa JP, da Silva PM. 2018. Land management impacts on the feeding preferences of the woodlouse Porcellio dilatatus (Isopoda: Oniscidea) via changes in plant litter quality. Appl Soil Ecol 132: 45–52. [Google Scholar]
Sauer FG, Bundschuh M, Zubrod JP, Schäfer RB, Thompson K, Kefford BJ. 2016. Effects of salinity on leaf breakdown: dryland salinity versus salinity from a coalmine. Aquat Toxicol 177: 425–432. [PubMed] [Google Scholar]
Schäfer RB, Bundschuh M, Rouch DA, Szöcs E, von der Ohe PC, Pettigrove V, Schulz R, Nugegoda D, Kefford BJ. 2012. Effects of pesticide toxicity, salinity and other environmental variables on selected ecosystem functions in streams and the relevance for ecosystem services. Sci Total Environ 415: 69–78. [PubMed] [Google Scholar]
Snronan K, Kavr K. 1988. Occurrence and survival of aquatic hyphomycetes in brackish and sea water. Arch Hydrobiol 113: 153–160. [Google Scholar]
Tyree M, Clay N, Polaskey S, Entrekin S. 2016. Salt in our streams: even small sodium additions can have negative effects on detritivores. Hydrobiologia 775: 109–122. [Google Scholar]
Vineis P, Chan Q, Khan A. 2011. Climate change impacts on water salinity and health. J Epidemiol Glob Health 1: 5–10. [PubMed] [Google Scholar]
Webster JR, Benfield EF. 1986. Vascular plant breakdown in freshwater ecosystems. Annu Rev Ecol Syst 17: 567–594. [Google Scholar]
Yachi S, Loreau M. 1999. Biodiversity and ecosystem productivity in a fluctuating environment: the insurance hypothesis. Proc Natl Acad Sci 96: 1463–1468. [Google Scholar]
Young JC. 1995. Microwave-assisted extraction of the fungal metabolite ergosterol and total fatty acids. J Agric Food Chem 43: 2904–2910. [Google Scholar]
Young RG, Matthaei CD, Townsend CR. 2008. Organic matter breakdown and ecosystem metabolism: functional indicators for assessing river ecosystem health. J North Am Benthol Soc 27: 605–625. [Google Scholar]

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