Aquatic invertebrate assemblages of wetlands and rivers in the wheatbelt region of Western Australia

Pinder, Adrian; Halse, Stuart; McRae, J. M.; Shiel, Russell J.

doi:10.18195/issn.0313-122x.67.2004.007-037

Cited by 62 publications

(86 citation statements)

References 79 publications

(42 reference statements)

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“…However, many Coleoptera in inland southwest WA appear to be relatively salt tolerant, and the same correlation was not found in this study (over 0-8 or 0-20 gl -1 TDS) or in other studies in the same region (Kay et al, 2001;Bailey et al, 2002;Pinder et al, 2004Pinder et al, , 2005. It is also possible that salinity differences in abundances of Coleoptera, between mesocosm and field samples, may partially be due to some field Coleoptera having developed from eggs within water bodies, whereas all Coleoptera colonised mesocosms as adults.…”

Section: Salinity Colonisation Behaviour and Insects In The Fieldsupporting

confidence: 79%

“…Ephemeral water bodies are characteristic of the Wheatbelt, where they show a range of salinities, especially in areas affected by secondary salinisation, making them ideal to investigate how salinity affects the colonisation and oviposition behaviour of insects. Numerous studies have investigated how salinity influences the distribution of aquatic organisms by examining patterns in species occurrence (Halse, 1981;Bunn & Davies, 1992;Kay et al, 2001;Williams, 2003;Halse et al, 2004;Marshall & Bailey, 2004;Pinder et al, 2004;Piscart et al, 2005a) and salt sensitivity (Roberts, 1996;Blasius & Merritt, 2002;Kefford et al 2003;Jeffery et al 2005;Hassell et al, 2006;Zalizniak et al, 2006). Studies have found a range of invertebrate fauna, such as the disease vector Ae.…”

Section: Introductionmentioning

confidence: 99%

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Salinity as a driver of aquatic invertebrate colonisation behaviour and distribution in the wheatbelt of Western Australia

et al. 2008

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To understand how environmental change will modify community assembly and the distribution of organisms it is valuable to understand mechanisms that drive the occurrence of organisms across the landscape. Salinisation of agricultural land in southwest Western Australia, as a result of land clearing, is a widespread environmental change, which threatens numerous taxa, but provides an opportunity to elucidate such mechanisms. Although salinisation affects terrestrial fauna and flora, the greatest impacts are seen in wetlands and waterways. Many aquatic insect taxa colonise ephemeral water bodies directly as adults or by oviposition. Few empirical studies, however, evaluate the influence of abiotic factors, such as water body salinity, on the colonisation behaviour of aquatic fauna. We conducted a manipulative experiment using mesocosms to test whether colonising insect fauna select aquatic habitats based upon salinity. We found that halosensitive fauna selected less saline mesocosms for oviposition and colonisation, demonstrating that behaviour can influence the distribution of aquatic organisms. Additionally, we utilised field surveys of insects from ephemeral water bodies across a broad region of southwest Western Australia to determine if mesocosm results reflected field observation. The abundance of the same insect taxa and taxonomic groups in the field were highly variable and, with the exceptions of Culex australicus Dobrotworksy and Drummond and Anopheles annulipes Giles (Diptera: Culicidae), did not show similar patterns of distribution to those observed in the mesocosm experiment. Both mesocosm and field assemblages exhibited similar and significant trajectories associated with the salinity gradient, even though there were differences in assemblage structure between the two. Our findings give empirical support to the importance of behaviour in the spatial distribution and assembly of some aquatic insects.

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Section: Salinity Colonisation Behaviour and Insects In The Fieldsupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Salinity as a driver of aquatic invertebrate colonisation behaviour and distribution in the wheatbelt of Western Australia

et al. 2008

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“…These water quality conditions were tolerated by only very hardy species, as increased salinity and acidity of sites impacted by deep drainage led to a sharp decline in species richness, and significant changes in macro-invertebrate community composition downstream of the drain. Kay et al (2001) showed a general tendency for family richness in Wheatbelt streams to decrease with increasing salinity, whilst Pinder et al (2004Pinder et al ( , 2005 further demonstrated that salinity has a major influence on the distribution of aquatic invertebrates in the Wheatbelt. They showed that the salinity range of 10-20 ppt (g l −1…”

Section: Impacts Of High Salinity and Acidity On Biodiversitymentioning

confidence: 95%

“…The conversion between conductivity and salinity was performed using a conversion factor of 0.64. Following Pinder et al (2004), water was considered 'fresh' when salinity was <3 ppt, 'subsaline' when 3-10 ppt, and saline when >10 ppt. Values greater than 100 ppt signify hypersaline conditions.…”

Section: Measurement Of Water Quality Variablesmentioning

confidence: 99%

Impacts of deep open drains on water quality and biodiversity of receiving waterways in the Wheatbelt of Western Australia

2008

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On each occasion, water quality parameters were measured and the macroinvertebrate fauna was sampled. Significant differences in water quality and macro-invertebrates were observed between the untreated sites and those affected by the drain discharge. Surface water at untreated sites was always fresh (<3 ppt), alkaline (pH 7.6-8.9) and turbid (49-600 NTU), whereas treatment sites were always saline (28-147 ppt), acidic (pH 1.9-3.8) and mostly clear (0-100 NTU).No recovery of water quality was observed with distance from discharge point (20 km). Invertebrates reflected differences in water quality, with drain discharge resulting in a sharp decline in species richness, and significant changes in macro-invertebrate community composition. Sites affected by drain discharge were dominated by fly larvae such as Orthocladiinae and Ceratopogonidae.Microcrustaceans were far more abundant at sites unaffected by drainage. The ecological values of Wheatbelt streams are likely to be further compromised by discharge of poor water quality from deep drainage.

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“…In Australia, secondary salinisation is principally caused by rising watertables as a consequence of reduced evapotranspiration following changes in land use, typically land clearing for agriculture. The south-west corner of Australia, where~80-90% of the land has been cleared, is a hot spot in terms of secondary salinisation (NLWRA 2001;Halse et al 2003;Pinder et al 2004). As a result, most of the freshwater ecosystems in south-western Australia are affected by increasing salinity, with 56% having become brackish (1.0-2.0 g L -1 ) or saline (>2.0 g L -1 ) (see Mayer et al 2005).…”

Section: Salinity As a Threatening Processmentioning

confidence: 99%

Range decline and conservation status of Westralunio carteri Iredale, 1934 (Bivalvia:Hyriidae) from south-western Australia

et al. 2015

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Abstract.Westralunio carteri is the only species of freshwater mussel found in south-western Australia and, owing to a lack of comprehensive information on its ecology, its conservation status has been speculative. To more accurately predict the true conservation status of this species, the historical and contemporary distributional records were modelled with environmental data that identified salinity, perenniality and total nitrogen as variables responsible for limiting the species' current extent of occurrence, inferring threatening processes. The species was found to have undergone a 49% reduction in extent of occurrence in less than three generations, due primarily to secondary salinisation. Current distribution is bounded by Gingin Brook in the north to the Kent, Goodga and Waychinicup Rivers in the South, within 50-100 km of coastal south-western Australia. Field observations indicated that W. carteri was almost never found at sites where mean salinity was >1.6 g L -1 . This was corroborated by laboratory tolerance trials that showed that W. carteri has an acute salinity tolerance (LD 50 ) of 1.6-3.0 g L -1 . Application of IUCN Red List criteria indicates that W. carteri qualifies for listing as vulnerable. Conservation management measures should focus on maintaining existing populations.

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Aquatic invertebrate assemblages of wetlands and rivers in the wheatbelt region of Western Australia

Cited by 62 publications

References 79 publications

Salinity as a driver of aquatic invertebrate colonisation behaviour and distribution in the wheatbelt of Western Australia

Salinity as a driver of aquatic invertebrate colonisation behaviour and distribution in the wheatbelt of Western Australia

Impacts of deep open drains on water quality and biodiversity of receiving waterways in the Wheatbelt of Western Australia

Range decline and conservation status of Westralunio carteri Iredale, 1934 (Bivalvia:Hyriidae) from south-western Australia

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