Abstract
Climate change is causing prolonged drying in many seasonal wetlands, including urban wetlands, potentially affecting aquatic invertebrates that take refuge in wetland sediment during dry periods and thereby threatening wetland biodiversity. We collected sediment from two habitats: open water (OW) and fringing trees (FT), in eight urban wetlands after seasonal inundation had ended. Both habitats are inundated during winter–spring and dry in summer–autumn. Each sediment sample was divided into subsamples. One set of subsamples were inundated in the laboratory to test the hypothesis that emerging invertebrate assemblages would differ between OW and FT sediments. Another set of subsamples was dried, stored for a year, and inundated to test the hypothesis that prolonged drying would reduce the abundance and taxa richness of emerging invertebrates. The composition of emerging invertebrate assemblages differed between habitats, with more amphibious species found in FT sediment. Invertebrate responses to prolonged drying and storage varied among species: for some, effects depended on habitat type, while others delayed emergence or showed no response. Microcrustacean abundance was unaffected by drying, suggesting that their productivity during refilling may resist drier water regimes. Surface temperatures of dry sediment are cooler beneath FT, and this sediment has higher organic matter, holds more water and is less dense than OW sediment; and FT sediment remained cooler than OW sediment in the laboratory, despite the absence of shading. Fringing trees may therefore provide a refuge for some freshwater invertebrates relying on dormant stages in the sediment to survive drying in urban wetlands.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Balla SA, Davis JA (1995) Seasonal variation in the macroinvertebrate fauna of wetlands of differing water regime and nutrient status on the Swan Coastal Plain, Western Australia. Hydrobiologia 299:147–161
Bayley M, Holmstrup M (1999) Water vapor absorption in arthropods by accumulation of myoinositol and glucose. Science 285:1909–1911
Bernhardt ES, Palmer MA (2007) Restoring streams in an urbanizing world. Freshw Biol 52:738–751
Boulton AJ, Lloyd LN (1992) Flooding frequency and invertebrate emergence from dry floodplain sediments of the river Murray, Australia. Regul Rivers 7:137–151
Boulton AJ, Brock MA, Robson BJ, Ryder DS, Chambers JC, Davis JA (2014) Australian freshwater ecology: processes and management. Wiley-Blackwell, Chichester
Brendonck L, De Meester L (2003) Egg banks in freshwater zooplankton: evolutionary and ecological archives in the sediment. Hydrobiologia 491:63–54
Brock MA, Nielsen DL, Shiel RJ, Green JD, Langley JD (2003) Drought and aquatic community resilience: the role of eggs and seeds in sediments of temporary wetlands. Freshw Biol 48:1207–1218
Brock MA, Nielsen DL, Crossle K (2005) Changes in biotic communities developing from freshwater wetland sediments under experimental salinity and water regimes. Freshw Biol 50:1376–1390
Chester ET, Robson BJ (2011) Drought refuges, spatial scale and the recolonization of invertebrates in non- perennial streams. Freshw Biol 56:2094–2104
Chester ET, Robson BJ (2013) Anthropogenic refuges for freshwater biodiversity: their ecological characteristics and management. Biol Conserv 166:64–75
Clarke KR, Warwick RM (2001) Change in marine communities: an approach to statistical analysis and interpretation. PRIMER-E, Plymouth
CSIRO (2011) Science and solutions for Australia. In: Cleugh H, Smith MS, Battaglia M, Graham P (eds) Climate change. CSIRO, Collingwood
Datry T, Corti R, Philippe M (2012) Spatial and temporal aquatic-terrestrial transitions in the temporary Albarine River, France: responses of invertebrates to experimental rewetting. Freshw Biol 57:716–727
Davies PM (2010) Climate change implications for river restoration in global biodiversity hotspots. Restor Ecol 18:261–268
Davis JA, Christidis F (1999) A guide to wetland invertebrates of Southwestern Australia. Western Australian Museum, Perth
Davis JA, Froend R (1999) Loss and degradation of wetlands in southwestern Australia: underlying causes and consequences and solutions. Wetl Ecol Manag 7:13–23
Gordon ND, McMahon TA, Finlayson BL (1992) Stream hydrology an introduction for ecologists. Wiley, Chichester
Horwitz P, Rogan R, Halse S, Davis J, Sommer B (2009) Wetland invertebrate richness and endemism on the Swan Coastal Plain, Western Australia. Mar Freshw Res 60:1006–1020
Jenkins KM, Boulton AJ (2007) Detecting impacts and setting restoration targets in arid-zone rivers: aquatic micro-invertebrate responses to reduced floodplain inundation. J Appl Ecol 44:823–832
Lake PS (2000) Disturbance, patchiness, and diversity in streams. J N Am Benthol Soc 19:573–592
Larned ST, Datry T, Robinson CT (2007) Invertebrate and microbial responses to inundation in an ephemeral river reach in New Zealand: effects of preceding dry periods. Aquat Sci 69:554–567
Mackintosh TJ, Davis JA, Thompson RM (2015) The influence of urbanisation on macroinvertebrate biodiversity in constructed stormwater wetlands. Sci Total Environ 536:527–537
Pinder AM, Halse SA, Shiel RJ, McRae JM (2000) Granite outcrop pools in south-western Australia: foci of diversification and refugia for aquatic invertebrates. J R Soc West Aust 83:149–161
Rawls WJ, Pachepsky YA, Ritchie JC, Sobecki TM, Bloodworth H (2003) Effect of soil organic carbon on soil water retention. Geoderma 116:61–76
Ricci C, Pagani M (1997) Desiccation of Panagrolaimus rigidus (Nematoda): survival, reproduction and the influence on the internal clock. Hydrobiologia 347:1–13
Schon I, Shearn R, Martens K, Koenders A, Halse S (2015) Age and origin of Australian Bennelongia (Crustacea, Ostracoda). Hydrobiologia 750:125–146
Sharitz RR (2003) Carolina Bay wetlands: unique habitats of the southeastern United States. Wetlands 23:550–562
Sim LL, Davis JA, Strehlow K, McGuire M, Trayler KM, Wild S, Papas PJ, O’Connor J (2013) The influence of changing hydroregime on the invertebrate communities of temporary seasonal wetlands. Freshw Sci 32:327–342
Steward AL, Marshall JC, Sheldon F, Harch B, Choy S, Bunn SE, Tockner K (2011) Terrestrial invertebrates of dry river beds are not simply subsets of riparian assemblages. Aquat Sci 73:551–566
Stewart BA, Close PG, Cook PA, Davies PM (2013) Upper thermal tolerances of key taxonomic groups of stream invertebrates. Hydrobiologia 718:131–140
Strachan SR, Chester ET, Robson BJ (2014) Microrefuges from drying for invertebrates in a seasonal wetland. Freshw Biol 59:2528–2538
Strachan SR, Chester ET, Robson BJ (2015) Freshwater invertebrate life history strategies for surviving desiccation. Springer Sci Rev 3:57–75
Strachan SR, Chester ET, Robson BJ (2016) Habitat alters the effect of false starts on seasonal-wetland invertebrates. Freshwater Biol. doi:10.1111/fwb.12738
Stubbington R, Datry T (2013) The macroinvertebrate seedbank promotes community persistence in temporary rivers across climate zones. Freshw Biol 58:1202–1220
Tronstad LM, Tronstad BP, Benke AC (2005) Invertebrate responses to decreasing water levels in a subtropical river floodplain wetland. Wetlands 25:583–593
Waterkeyn A, Grillas P, Vanschoenwinkel B, Brendonck L (2008) Invertebrate community patterns in Mediterranean temporary wetlands along hydroperiod and salinity gradients. Freshw Biol 53:1808–1822
Wickson SJ, Chester ET, Robson BJ (2012) Aestivation provides flexible mechanisms for survival of stream drying in a larval trichopteran (Leptoceridae). Mar Freshw Res 63:821–826
Zhang Y, Wang X, Pan Y, Hu R (2012) Diurnal relationship between the surface albedo and surface temperature in revegetated desert ecosystems, north-west China. Arid Land Res Manag 26:32–43
Acknowledgments
The authors would like to thank Murdoch University for its support and for providing a PhD scholarship to SRS. Thanks to Peter O’Toole for his help in the field. Sampling was carried out with permits from the Department of Environment and Conservation and the Department of Fisheries, Western Australia.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Strachan, S.R., Chester, E.T. & Robson, B.J. Fringing trees may provide a refuge from prolonged drying for urban wetland invertebrates. Urban Ecosyst 19, 1213–1230 (2016). https://doi.org/10.1007/s11252-016-0548-y
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11252-016-0548-y