Abstract
Riparian vegetation is known to provide environmental benefits for aquatic ecosystems and is commonly used in the restoration of agricultural catchments. However, little information exists on the influence of riparian vegetation on the fauna of intermittent or humic (coloured) streams. We examined the ecological condition of riparian vegetation and its influence on stream fauna amongst humic and non-humic intermittent and perennial stream reaches in the Ellen Brook catchment, south west Western Australia. Permutation-tests showed that flow regime (Global R = 0.444, P < 0.001) and the presence/absence of riparian vegetation (Global R = 0.407, P < 0.001) were the most influential factors associated with invertebrate assemblage composition. Riparian vegetation influenced invertebrate assemblages through the provision of organic matter for food and habitat, and by shading stream channels, thereby limiting light and algal growth. This was illustrated by a higher proportion of algal grazers (Chironominae and Physidae) in unvegetated streams and more detritivores (Leptoceridae, Gripopterygidae, Ceinidae) in vegetated streams. Humic intermittent streams showed different invertebrate assemblages to non-humic intermittent streams; having fewer Cladocera and Chironomidae and more grazing gastropods (Physidae and Lynceidae). A significant proportion of the variation in invertebrate assemblages was associated with stream width, salinity and NO x -N concentrations because intermittent streams were narrower, more brackish and less enriched than with nitrogen than perennial streams. Riparian vegetation benefited invertebrate assemblages in all stream types, showing that revegetation is as effective a restoration action in intermittent and humic streams as it is in perennial streams.
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References
ANZECC and ARMCANZ (2000) National Water Quality Management Strategy: Australia and New Zealand Water Quality Guidelines for Fresh and Marine Water Quality. Australian and New Zealand Conservation Council, Agriculture and Resource Management Council of Australia and New Zealand
APHA (1995) Phosphorus sample preparation. In: Eaton AD, Clesceri LS, Greenberg AE (eds) Standard methods for the examination of water and wastewater. American Public Health Association, Washington DC
Arnaiz O, Wilson A, Watts R, Stevens M (2011) Influence of riparian condition on aquatic macroinvertebrate communities in an agricultural catchment in south-eastern Australia. Ecol Res 26(1):123–131
Bayly IAE, Williams WD (1973) Inland waters and their ecology. Longman, Melbourne
Bêche LA, McElravy EP, Resh VH (2006) Long-term seasonal variation in the biological traits of benthic-macroinvertebrates in two Mediterranean-climate streams in California, U.S.A. Freshw Biol 51(1):56–75
Becker A, Robson BJ (2009) Riverine macroinvertebrate assemblages up to 8 years after riparian restoration in a semi-rural catchment in Victoria, Australia. Mar Freshw Res 60(12):1309–1316
BOM (Bureau of Meteorology) (2015) Climate data online: monthly rainfall. http://www.bom.gov.au/climate/data. Accessed 10 Nov 2015
Boulton AJ, Lake PS (1992) The ecology of two intermittent streams in Victoria, Australia. Freshw Biol 27(1):99–121
Brian M, Hickey C, Doran B (2004) A review of the efficiency of buffer strips for the maintenance and enhancement of riparian ecosystems. Water Qual Res J Can 39(3):311–317
Bunn SE, Edward DH, Loneragan NR (1986) Spatial and temporal variation in the macroinvertebrate fauna of streams of the northern jarrah forest, Western Australia: community structure. Freshw Biol 16(1):67–91
Bunn SE, Davies PM, Kellaway DM, Prosser IP (1998) Influence of invasive macrophytes on channel morphology and hydrology in an open tropical lowland stream, and potential control by riparian shading. Freshw Biol 39:171–178
Bunn SE, Davies PM, Mosisch TD (1999) Ecosystem measures of river health and their response to riparian and catchment degradation. Freshw Biol 41(2):333–345
Burcher CL, Valett HM, Benfield EF (2007) The land-cover cascade: relationships coupling land and water. Ecology 88(1):228–242
Chester ET, Robson BJ (2011) Drought refuges, spatial scale and recolonisation by invertebrates in non-perennial streams. Freshw Biol 56(10):2094–2104
Chester ET, Miller AD, Valenzuela I, Wickson SJ, Robson BJ (2015) Drought survival strategies, dispersal potential and persistence of invertebrate species in an intermittent stream landscape. Freshw Biol 60(10):2066–2083
Connolly NM, Pearson RG, Loong D, Maughan M, Brodie J (2015) Water quality variation along streams with similar agricultural development but contrasting riparian vegetation. Agric Ecosyst Environ 213:11–20
Danger A, Robson B (2004) The effects of land use on leaf-litter processing by macroinvertebrates in an Australian temperate coastal stream. Aquat Sci 66(3):296–304
Datry T, Larned ST, Tockner K (2014) Intermittent rivers: a challenge for freshwater ecology. Bioscience 64(3):229–235
Davey AJH, Kelly DJ (2007) Fish community responses to drying disturbances in an intermittent stream: a landscape perspective. Freshw Biol 52(9):1719–1733
Davies PM (2010) Climate change implications for river restoration in global biodiversity hotspots. Restoration Ecol 18(3):261–268
Davis JA, Rosich RS, Bradley JS, Growns JE, Schmidt LG, Cheal F (1993) Wetlands of the Swan Coastal Plain, vol 6. Wetland classification on the basis of water quality and invertebrate community data. Water Authority of Western Australia and the Environmental Protection Authority, Perth
Gooderham J, Tsyrlin E (2002) The waterbug book. CSIRO Publishing, Collingwood
Graça MAS, Prozo J, Canhoto C, Elosegi A (2002) Effects of eucalyptus plantations on detritus, decomposers and detritivores in streams. Sci World J 2:1173–1185
Harding J, Claassen K, Evers N (2006) Can forest fragments reset physical and water quality conditions in agricultural catchments and act as refugia for forest stream invertebrates? Hydrobiologia 568(1):391–402
Hart B, Bailey P, Edwards R, Hortle K, James K, McMahon A, Meredith C, Swadling K (1991) A review of the salt sensitivity of the Australian freshwater biota. Hydrobiologia 210(1–2):105–144
Hessen D, Tranvik L (eds) (1998) Aquatic humic substances: ecology and biogeochemistry. Springer, Berlin
Hladyz S, Åbjörnsson K, Chauvet E, Dobson M et al (2011a) Stream ecosystem functioning in an agricultural landscape: the importance of terrestrial–aquatic linkages, chapter 4. In: Guy W (ed) Advances in ecological research. Academic Press, New York, pp 211–276
Hladyz S, Åbjörnsson K, Giller PS, Woodward G (2011b) Impacts of an aggressive riparian invader on community structure and ecosystem functioning in stream food webs. J Appl Ecol 48(2):443–452
Holland A, Duivenvoorden LJ, Kinnear SHW (2015) Effect of key water quality variables on macroinvertebrate and fish communities within naturally acidic wallum streams. Mar Freshw Res 66(1):50–59
Hughes FMR, Colston A, Mountford JO (2005) Restoring riparian ecosystems: the challenge of accommodating variability and designing restoration trajectories. Ecol Soc 10(1):1–12
Johnson KS (1982) Determination of phosphate in seawater by flow injection analysis with injection of reagent. Anal Chem 54(7):1185–1187
Johnson KS (1983) Determination of nitrate and nitrite in seawater by flow injection analysis with injection of reagent. Limnol Oceanogr 28(6):1260–1266
Kefford BJ, Marchant R, Schäfer RB, Metzeling L, Dunlop JE, Choy SC, Goonan P (2011) The definition of species richness used by species sensitivity distributions approximates observed effects of salinity on stream macroinvertebrates. Environ Pollut 159(1):302–310
Keighery BJ (1994) Bushland plant survey: a guide to plant community survey for the community. Wildflower Society of WA Inc, Nedlands
Kirk JTO (1994) Light and photosynthesis in aquatic ecosystems, 2nd edn. Cambridge University Press, Cambridge
Klunzinger MW, Beatty SJ, Morgan DL, Pinder AM, Lymbery AJ (2015) Range decline and conservation status of Westralunio carteri Iredale, 1934 (Bivalvia: Hyriidae) from south-western Australia. Aust J Zool 63(2):127–135
Kullberg A (1992) Benthic macroinvertebrate community structure in 20 streams of varying pH and humic content. Environ Pollut 78(1–3):103–106
Labbe TR, Fausch KD (2000) Dynamics of intermittent stream habitat regulate persistence of a threatened fish at multiple scales. Ecol Appl 10(6):1774–1791
Larned ST, Datry D, Arscott DB, Tockner K (2010) Emerging concepts in temporary river ecology. Freshw Biol 55(4):717–738
Lemly AD, Hilderbrand R (2000) Influence of large woody debris on stream insect communities and benthic detritus. Hydrobiologia 421(1):179–185
March TS, Robson BJ (2006) Association between burrow densities of two Australian freshwater crayfish (Engaeus sericatus and Geocharax gracilis: Parastacidae) and four riparian land uses. Aquat Conserv 16(2):181–191
McPharlin I, Delroy N, Jeffery B, Dellar G, Eales M (1990) Phosphorus retention of sandy horticultural soils on the Swan Coastal Plain. J Agric WA 31(1):28–32
Merritt R, Lawson D (1992) The role of leaf litter macroinvertebrates in stream-floodplain dynamics. Hydrobiologia 248(1):65–77
Meyer JL (1990) A blackwater perspective on riverine ecosystems. BioScience 40(9):643–651
Mosisch TD, Bunn SE, Davies PM (2001) The relative importance of shading and nutrients on algal production in subtropical streams. Freshw Biol 46(9):1269–1278
Naiman RJ, Decamps H, McLain ME (2005) Riparia: ecology, conservation and management of streamside communities. Elsevier Academic, Amsterdam
O’Toole PM (2014) The functionality of riparian zones in flat sandy catchments. PhD Thesis, Murdoch University, Western Australia
Poquet JM, Mezquita F, Rueda J, Miracle MR (2008) Loss of Ostracoda biodiversity in Western Mediterranean wetlands. Aquat Conserv 18(3):280–296
Pusey BJ, Arthington AH (2003) Importance of the riparian zone to the conservation and management of freshwater fish: a review. Mar Freshw Res 54(1):1–16
Reid DJ, Lake PS, Quinn GP, Reich P (2008a) Association of reduced riparian vegetation cover in agricultural landscapes with coarse detritus dynamics in lowland streams. Mar Freshw Res 59(11):998–1014
Reid DJ, Lake PS, Quinn GP, Reich P (2008b) Terrestrial detritus supports the food webs in lowland intermittent streams of south-eastern Australia: a stable isotope study. Freshw Biol 53(10):2036–2050
Reid DJ, Lake PS, Quinn GP (2013) Influences of agricultural landuse and seasonal changes in abiotic conditions on invertebrate colonisation of riparian leaf detritus in intermittent streams. Aquat Sci 75(2):285–297
Rutherford JC, Marsh NA, Davies PM, Bunn SE (2004) Effects of patchy shade on stream water temperature: how quickly do small streams heat and cool? Mar Freshw Res 55(8):737–748
Sabater S, Acuña V, Giorgi A, Guerra E, Muñoz I, Romaní AM (2005) Effects of nutrient inputs in a forested Mediterranean stream under moderate light availability. Arc Hydrobiol 163(4):479–496
Sharma ML, Herne DE, Byrne JD (1996) Land use effects on water quality in the Ellen Brook catchment: experimental/modelling—annual report July 1992–June 1993. Department of Water, Floreat Park
Smock LA, Gilinsky E, Stoneburner DL (1985) Macroinvertebrate production in a southeastern United States blackwater stream. Ecology 66(5):1491–1503
Sponseller RA, Benfield EF, Valett HM (2001) Relationships between land use, spatial scale and stream macroinvertebrate communities. Freshw Biol 46(10):1409–1424
Stanley EH, Powers SM, Lottig NR, Buffam I, Crawford JT (2012) Contemporary changes in dissolved organic carbon (DOC) in human-dominated rivers: is there a role for DOC management? Freshw Biol 57:26–42
Stewart B, Close P, Cook P, Davies P (2013) Upper thermal tolerances of key taxonomic groups of stream invertebrates. Hydrobiologia 718(1):131–140
Storey RG, Quinn JM (2013) Survival of aquatic invertebrates in dry bed sediments of intermittent streams: temperature tolerances and implications for riparian management. Freshw Sci 32(1):250–266
Strachan SR, Chester ET, Robson BJ (2015) Freshwater invertebrate life history strategies for surviving desiccation. Springer Sci Rev 3(1):57–75
Switala K (1993) Determination of ammonia by flow injection analysis colorimetry (dialysis). Latchet Instruments, Milwaukee
Valderrama J (1981) The simultaneous analysis of total nitrogen and total phosphorus in natural waters. Mar Chem 10:109–122
Vondracek B, Blann KL, Cox CB, Nerbonne JF, Mumford KG, Nerbonne BA, Sovell LA, Zimmerman JKH (2005) Land use, spatial scale, and stream systems: lessons from an agricultural region. J Environ Manag 36(6):775–791
Walker K, Jones H, Klunzinger M (2014) Bivalves in a bottleneck: taxonomy, phylogeography and conservation of freshwater mussels (Bivalvia: Unionoida) in Australasia. Hydrobiologia 735(1):61–79
Watson M, Dallas HF (2013) Bioassessment in ephemeral rivers: constraints and challenges in applying macroinvertebrate sampling protocols. Afr J Aquat Sci 38(1):35–51
Webb AA, Erskine WD (2003) A practical scientific approach to riparian vegetation rehabilitation in Australia. J Environ Manag 68(4):329–341
Wrigley TJ, Chambers JM, McComb AJ (1988) Nutrient and Gilvin levels in waters of coastal-plain wetlands in an agricultural area of Western Australia, Australia. Mar Freshw Res 39:685–694
Zampella R, Bunnell J, Procopio N, Bryson D (2008) Macroinvertebrate assemblages in blackwater streams draining forest land and active and abandoned cranberry bogs. Wetlands 28(2):390–400
Acknowledgments
Funding for this research was from the Australian Government Caring for our Country program coordinated through the Swan River Trust. Murdoch University provided a PhD scholarship to Peter O’Toole. Sampling was carried out with permits from the Department of Environment and Conservation and the Department of Fisheries, Western Australia. Belinda Cale provided the base artwork for Fig. 1.
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O’Toole, P., Robson, B.J. & Chambers, J.M. Riparian vegetation condition is associated with invertebrate assemblage composition in intermittent and humic streams. Aquat Sci 79, 277–289 (2017). https://doi.org/10.1007/s00027-016-0496-x
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DOI: https://doi.org/10.1007/s00027-016-0496-x