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RESEARCH ARTICLE
Contents Vol 67(2)

Historical water-plant occurrence and environmental change in two contrasting catchments

Michelle T. Casanova
+ Author Affiliations
- Author Affiliations

A Water Research Network, Federation University, Mount Helen, Vic. 3350, Australia

B Royal Botanic Gardens Melbourne, Birdwood Avenue, South Yarra, Vic. 3141, Australia.

C Present address: 273 Casanova Road, Westmere, Vic. 3351, Australia. Email: amcnova@netconnect.com.au

Marine and Freshwater Research 67(2) 210-223 https://doi.org/10.1071/MF14189
Submitted: 1 July 2014  Accepted: 16 January 2015   Published: 27 May 2015

Abstract

Historical conditions in riparian systems can be derived from the recorded distribution of water plants and their ecological requirements. Herbarium and literature records were used to assess historical species occurrence, and a field survey and a seed-bank study were used to assess present-day occurrence in two adjacent, southern Australian catchments: the Angas River and the Tookayerta Creek. There was an increase in the proportion of salinity- and drought-tolerant species detected in the Angas River catchment since European settlement. Field-survey data and the seed-bank study data were similar for that catchment, indicating that the submerged flora of the Angas River catchment is resilient to drought. In contrast, the dissimilarity of the seed-bank study data and the survey data from the Tookayerta Creek catchment indicated that the submerged flora in that catchment is not tolerant of drought. Although submerged species in the Tookayerta Creek catchment are dependent on the presence of permanent fresh water, there were more salinity-tolerant species in the lower Tookayerta catchment in the present study than were detected in the past. Comparison of the historical plant distribution and present-day distribution in catchments can provide interpretation of environmental conditions and ecological filters now, and since European settlement.

Additional keywords: Angas River, charophytes, Lake Alexandrina, macrophytes, Murray–Darling Basin, Tookayerta Creek.


References

Auderset Joye, D., Castella, E., and Lachavanne, J.-B. (2002). Occurrence of Characeae in Switzerland over the last two centuries (1800–2000). Aquatic Botany 72, 369–385.
Occurrence of Characeae in Switzerland over the last two centuries (1800–2000).Crossref | GoogleScholarGoogle Scholar |

Ayres, K. R., Sayer, C. D., Skeare, E. R., and Perrow, M. R. (2008). Palaeolimnology as a tool to inform shallow lake management: an example from Upton Great Broad, Norfolk, UK. Biodiversity and Conservation 17, 2153–2168.
Palaeolimnology as a tool to inform shallow lake management: an example from Upton Great Broad, Norfolk, UK.Crossref | GoogleScholarGoogle Scholar |

Barko, J. W., and James, W. F. (1998). Effects of submerged aquatic macrophytes on nutrient dynamics, sedimentation and resuspension. In ‘The Structuring Role of Submerged Macrophytes in Lakes’. (Eds E. Jeppesen, M. A. Søndergaard, M. O. Søndergaard and K. Christoffersen.) pp. 197–226. (Springer-Verlag: New York.)

Beechie, T. J., and Imaki, H. (2009). Multi-scale geomorphic and climatic controls on riparian vegetation pattern in the Columbia River basin, USA. In ‘AGU 2009 Fall Meeting’, 14–18 December 2009, San Francisco, CA, USA. Abstract #H51D-0780. (American Geophysical Union: Washington, DC.)

Belbin, L., and Collins, A. (2009) PATN version 3.12. (Blatant Fabrications Pty Ltd.)

Bickford, S., and Gell, P. A. (2005). Holocene vegetation change, Aboriginal wetland use and the impact of European settlement on the Fleurieu Peninsula, South Australia. The Holocene 15, 200–215.
Holocene vegetation change, Aboriginal wetland use and the impact of European settlement on the Fleurieu Peninsula, South Australia.Crossref | GoogleScholarGoogle Scholar |

Bickford, S., Gell, P. A., and Hancock, G. I. (2008). Wetland and terrestrial vegetation change since European settlement on the Fleurieu Peninsula. The Holocene 18, 425–436.
Wetland and terrestrial vegetation change since European settlement on the Fleurieu Peninsula.Crossref | GoogleScholarGoogle Scholar |

Black, J. M. (1943). ‘Flora of South Australia. Part I.’ (South Australia Government Printers: Adelaide.)

Black, J. M. (1948). ‘Flora of South Australia. Part II.’ (South Australia Government Printers: Adelaide.)

Black, J. M. (1952). ‘Flora of South Australia. Part III.’ (South Australia Government Printers: Adelaide.)

Black, J. M. (1957). ‘Flora of South Australia. Part IV.’ (South Australia Government Printers: Adelaide.)

Black, J. M., and Cleland, J. B. (1951). Plants of the Encounter Bay district. The South Australian Naturalist 26, 24–27.

Brock, M. A., and Casanova, M. T. (1997). Plant life at the edge of wetlands: ecological responses to wetting and drying patterns. In ‘Frontiers in Ecology: Building the Links’. (Eds N. Klomp and I. Lunt.) pp. 181–192. (Elsevier Science: Oxford, UK.)

Brock, M. A., and Lane, J. A. K. (1983). The aquatic macrophyte flora of saline wetlands in Western Australia in relation to salinity and permanence. Hydrobiologia 105, 63–76.
The aquatic macrophyte flora of saline wetlands in Western Australia in relation to salinity and permanence.Crossref | GoogleScholarGoogle Scholar |

Brock, M. A., Theodore, K. A., and O’Donnell, L. (1994). Seed bank methods for Australian wetlands. Australian Journal of Marine and Freshwater Research 45, 483–493.
Seed bank methods for Australian wetlands.Crossref | GoogleScholarGoogle Scholar |

Brock, M. A., Nielsen, D. L., Shiel, R. J., Green, J. D., and Langley, J. D. (2003). Drought and aquatic community resilience: the role of eggs and seeds in sediments of temporary wetlands. Freshwater Biology 48, 1207–1218.
Drought and aquatic community resilience: the role of eggs and seeds in sediments of temporary wetlands.Crossref | GoogleScholarGoogle Scholar |

Brock, M. A., Nielsen, D. L., and Crosslé, K. (2005). Changes in biotic communities developing from freshwater wetland sediments under experimental salinity and water regimes. Freshwater Biology 50, 1376–1390.
Changes in biotic communities developing from freshwater wetland sediments under experimental salinity and water regimes.Crossref | GoogleScholarGoogle Scholar |

Buckman, S., Brownlie, K. C., Bourman, R. P., Murray-Wallace, C. V., Morris, R. H., Lachlan, T. J., Roberts, R. G., Arnold, L. J., and Cann, J. H. (2009). Holocene palaeofire records in a high-level, proximal valley-fill (Wilson Bog), Mount Lofty Ranges, South Australia. The Holocene 19, 1017–1029.
Holocene palaeofire records in a high-level, proximal valley-fill (Wilson Bog), Mount Lofty Ranges, South Australia.Crossref | GoogleScholarGoogle Scholar |

Bunn, S., Davies, P. M., and Mosisch, T. D. (1999). Ecosystem measures of river health and their response to riparian and catchment degradation. Freshwater Biology 41, 333–345.
Ecosystem measures of river health and their response to riparian and catchment degradation.Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T. (1993). The ecology of charophytes in temporary and permanent wetlands: an Australian perspective. Ph.D. Thesis, University of New England, Armidale, NSW.

Casanova, M. T. (2005). An overview of Chara in Australia (Characeae, Charophyta). Australian Systematic Botany 18, 25–39.
An overview of Chara in Australia (Characeae, Charophyta).Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T. (2009). An overview of Nitella in Australia (Characeae, Charophyta). Australian Systematic Botany 22, 193–218.
An overview of Nitella in Australia (Characeae, Charophyta).Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T. (2011). Using water plant functional groups to investigate environmental water requirements. Freshwater Biology 56, 2637–2652.
Using water plant functional groups to investigate environmental water requirements.Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T. (2013). Lamprothamnium in Australia (Characeae, Charophyceae). Australian Systematic Botany 26, 268–290.
Lamprothamnium in Australia (Characeae, Charophyceae).Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., and Brock, M. A. (1996). Can oospore germination patterns explain charophyte distribution in permanent and temporary wetlands? Aquatic Botany 54, 297–312.
Can oospore germination patterns explain charophyte distribution in permanent and temporary wetlands?Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., and Brock, M. A. (1999). Life histories of charophytes from permanent and temporary wetlands in eastern Australia. Australian Journal of Botany 47, 383–397.
Life histories of charophytes from permanent and temporary wetlands in eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., and Brock, M. A. (2000). How do depth, duration and frequency of flooding influence establishment of wetland plant communities? Plant Ecology 147, 237–250.
How do depth, duration and frequency of flooding influence establishment of wetland plant communities?Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., and Karol, K. G. (2008). Monoecious Nitella (Characeae, Charophyceae) species from south-eastern mainland Australia, including N. paludigena sp. nov. Australian Systematic Botany 21, 201–216.
Monoecious Nitella (Characeae, Charophyceae) species from south-eastern mainland Australia, including N. paludigena sp. nov.Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., and Karol, K. G. (2014). A revision of ecorticate species of Chara in Australia (subgenus Charopsis, section Protochara sect. nov.) (Characeae, Charophyceae). Australian Systematic Botany 27, 23–27.
A revision of ecorticate species of Chara in Australia (subgenus Charopsis, section Protochara sect. nov.) (Characeae, Charophyceae).Crossref | GoogleScholarGoogle Scholar |

Casanova, M. T., de Winton, M. D., Clayton, J. S., and Karol, K. G. (2007). Nitella hookeri A.Braun (Characeae, Charophyceae) in New Zealand and Australia: implications for endemism, speciation and biogeography. Charophytes 1, 2–18.

Cleland, J. B. (1926). Plants of the Encounter Bay district. The South Australian Naturalist 7, 51.

Cleland, J. B. (1927a). Plants of the Encounter Bay district. The South Australian Naturalist 8, 7.

Cleland, J. B. (1927b). Plants of the Encounter Bay district. The South Australian Naturalist 8, 53.

Cleland, J. B. (1928a). Plants of the Encounter Bay district. The South Australian Naturalist 9, 27.

Cleland, J. B. (1928b). Plants of the Encounter Bay district. The South Australian Naturalist 9, 45–48.

Cleland, J. B. (1928c). Plants of the Encounter Bay district. The South Australian Naturalist 9, 57–60.

Cleland, J. B. (1928d). Plants of the Encounter Bay district. The South Australian Naturalist 10, 16–20.

Cleland, J. B. (1929). Plants of the Encounter Bay district. The South Australian Naturalist 10, 37–40.

Cleland, J. B. (1954). Excursion to Mt Compass: additions to its flora. The South Australian Naturalist 28, 51–52.

Cleland, J. B. (1959). Plants of the Encounter Bay district: 7th list of additional records. The South Australian Naturalist 43, 22–24.

Cleland, J. B., and Black, J. M. (1927). Plants of the Encounter Bay district: additional records. The South Australian Naturalist 8, 39–45.

Cleland, J. B., and Black, J. M. (1937). Plants of the Encounter Bay district: fourth list of additional records. The South Australian Naturalist 16, 52–57.

de Winton, M. D., Casanova, M. T., and Clayton, J. S. (2004). Charophyte germination and establishment under low irradiance. Aquatic Botany 79, 175–187.
Charophyte germination and establishment under low irradiance.Crossref | GoogleScholarGoogle Scholar |

Dixon, M. D., and Johnson, W. C. (1999). Riparian vegetation along the middle Snake River, Idaho: zonation, geographical trends and historical changes. The Great Basin Naturalist 59, 18–34.

Dunstone, K. (1952). Secrets of the swamps. The South Australian Naturalist 26, 41–42.

Eardley, C. M. (1956). Some South Australian water plants. The South Australian Naturalist 30, 6–9.

García, A. (1999). Charophyte flora of south-east South Australia and south-west Victoria, Australia; systematics, distribution and ecology. Australian Journal of Botany 47, 407–435.
Charophyte flora of south-east South Australia and south-west Victoria, Australia; systematics, distribution and ecology.Crossref | GoogleScholarGoogle Scholar |

Gell, P. A. (1997). The development of a diatom data base for inferring lake salinity: towards a quantitative approach for reconstructing past climates. Australian Journal of Botany 45, 389–423.
The development of a diatom data base for inferring lake salinity: towards a quantitative approach for reconstructing past climates.Crossref | GoogleScholarGoogle Scholar |

Gemmel, N. (1975). Some notes on Ferdinand von Mueller and the early settlement of the Bugle Ranges. The South Australian Naturalist 49, 51–63.

Hammer M (2004). ‘The Eastern Mount Lofty Ranges Fish Inventory: Distribution and Conservation of Freshwater Fishes of Tributaries to the Lower River Murray, South Australia.’ (Native Fish Australia (SA) Inc & River Murray Catchment Water Management Board: Berri, SA.)

Harden, G. J. (1990). ‘Flora of New South Wales. Vol. I.’ (University of New South Wales Press. Sydney, NSW.)

Harden, G. J. (1991). ‘Flora of New South Wales. Vol. 2.’ (University of New South Wales Press. Sydney, NSW.)

Harden, G. J. (1992). ‘Flora of New South Wales. Vol. 3.’ (University of New South Wales Press. Sydney, NSW.)

Harden, G. J. (1993). ‘Flora of New South Wales. Vol. 4.’ (University of New South Wales Press. Sydney, NSW.)

Harris, W. K. (1963). Observations on water plants on the River Murray. The South Australian Naturalist 37, 43–44.

Huisman, J. M., and Millar, A. J. K. (2013). Australian seaweed collections: use and misuse. Phycologia 52, 2–5.
Australian seaweed collections: use and misuse.Crossref | GoogleScholarGoogle Scholar |

Jessop, J. P., and Toelken, H. R. (1986). ‘Flora of South Australia. Vols I–IV’, 4th edn. (South Australian Government Printing Division: Adelaide, SA.)

Linke, S., Pressey, R. L., Bailey, R. C., and Norris, R. H. (2007). Management options for river conservation planning: condition and conservation revisited. Freshwater Biology 52, 918–938.
Management options for river conservation planning: condition and conservation revisited.Crossref | GoogleScholarGoogle Scholar |

Lunt, I. D., Jansen, A., Binns, D. L., and Kenny, S. A. (2007). Long-term effects of exclusion of grazing stock on herbaceous communities in a riparian Eucalyptus camaldulensis forest in south-eastern Australia. Austral Ecology 32, 937–949.
Long-term effects of exclusion of grazing stock on herbaceous communities in a riparian Eucalyptus camaldulensis forest in south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Moore, J. A. (1986). ‘Charophytes of Great Britain and Ireland. BSBI Handbook 5.’ (Botanical Society of the British Isles: London.)

Murfet, D., and Taplin, R. (Eds) (2000). Vegetation. In ‘Natural History of Strathalbyn and Goolwa Districts’. pp. 108–220. (Strathalbyn Naturalists Club; and Douglas Press: Adelaide, SA.)

Nordstedt, C. F. O. (1918). Australasian Characeae. Proceedings of the Royal Society of Victoria 31, 1–6.

Orchard, A. E. (1985). Myriophyllum in Australasia II. The Australian species. Brunonia 8, 173–291.
Myriophyllum in Australasia II. The Australian species.Crossref | GoogleScholarGoogle Scholar |

Patino, J. L., Buckman, S., Bourman, R. P., Morris, R., and Brownlie, K. C. (2009). Using LiDAR to assess the effect of fire and floods on upland peat bogs, waterfall gully, Mount Lofty Ranges, South Australia. In ‘Proceedings of the Surveying & Spatial Sciences Institute, Biennial International Conference’. pp. 733–743. (Surveying & Spatial Sciences Institute: Adelaide, SA.)

Poff, N. L. (1997). Landscape filters and species traits: towards mechanistic understanding and prediction in stream ecology. Journal of the North American Benthological Society 16, 391–409.
Landscape filters and species traits: towards mechanistic understanding and prediction in stream ecology.Crossref | GoogleScholarGoogle Scholar |

Roberts, J., and Marston, F. (2000). Water regime and wetland and floodplain plants in the Murray–Darling Basin: a sourcebook of ecological knowledge. Technical Report 30/00, CSIRO Land and Water, Canberra, ACT.

Robinson, R. W., James, E. A., and Boon, P. I. (2012). Population structure in the clonal, woody wetland plant Melaleuca ericifolia (Myrtaceae): an analysis using historical aerial photographs and molecular techniques. Australian Journal of Botany 60, 9–19.
Population structure in the clonal, woody wetland plant Melaleuca ericifolia (Myrtaceae): an analysis using historical aerial photographs and molecular techniques.Crossref | GoogleScholarGoogle Scholar |

Romanowski, N. (1998). ‘Aquatic and Wetland Plants: a Field Guide for Non-tropical Australia.’ (University of New South Wales Press: Sydney, NSW.)

Sainty, G., and Jacobs, S. (2003). ‘Waterplants in Australia.’ (Sainty and Associates: Sydney, NSW.)

Salgado, J., Sayer, C., Carvalho, L., Davidson, T., and Gunn, I. (2010). Assessing aquatic macrophyte community change through the integration of palaeolimnological and historical data at Loch Leven, Scotland. Journal of Paleolimnology 43, 191–204.
Assessing aquatic macrophyte community change through the integration of palaeolimnological and historical data at Loch Leven, Scotland.Crossref | GoogleScholarGoogle Scholar |

Scott, G. M. (1985). ‘Southern Australian Liverworts. Australian Flora and Fauna Series 2.’ (Australian Government Publishing Service: Canberra, ACT.)

Sim, T. (2005). History of the Angas Bremer Catchments. Available at http://www.angasbremerwater.org.au/documents/Bremer_history.pdf [Verified 12 April 2015]

Sim, T., and Muller, K. (2004). ‘A Fresh History of the Lake: Wellington to the Murray Mouth, 1800s to 1935.’ (River Murray Catchment Water Management Board: Strathalbyn, SA.)

Sokol, R. C., and Stross, R. G. (1986). Annual germination window in oospores of Nitella furcata (Charophyceae). Journal of Phycology 22, 403–406.
Annual germination window in oospores of Nitella furcata (Charophyceae).Crossref | GoogleScholarGoogle Scholar |

Spencer, J. C. (2011) Eastern Mount Lofty Ranges Conservation action planning summary 2010–11. Report to the SA Murray Darling Basin Natural Resources Management Board, Greening Australia, Berri, SA.

Steinhardt, T., and Selig, U. (2011). Influence of salinity and sediment resuspension on macrophyte germination in coastal lakes. Journal of Limnology 70, 11–20.
Influence of salinity and sediment resuspension on macrophyte germination in coastal lakes.Crossref | GoogleScholarGoogle Scholar |

van der Valk, A. G., Toth, L. A., Gibney, E. B., Mason, D. H., and Wetzel, P. R. (2009). Potential propagule sources for reestablishing vegetation on the floodplain of the Kissimmee River, Florida, USA. Wetlands 29, 976–987.
Potential propagule sources for reestablishing vegetation on the floodplain of the Kissimmee River, Florida, USA.Crossref | GoogleScholarGoogle Scholar |

Vestergaard, O., and Sand-Jensen, K. (2000). Aquatic macrophyte richness in Danish lakes in relation to alkalinity, transparency, and lake area. Canadian Journal of Fisheries and Aquatic Sciences 57, 2022–2031.
Aquatic macrophyte richness in Danish lakes in relation to alkalinity, transparency, and lake area.Crossref | GoogleScholarGoogle Scholar |

Walsh, N. G., and Entwisle, T. J. (1994). ‘Flora of Victoria. Vol. 2.’ (Inkata Press: Melbourne.)

Walsh, N. G., and Entwisle, T. J. (1996). ‘Flora of Victoria. Vol. 3.’ (Inkata Press: Melbourne.)

Walsh, N. G., and Entwisle, T. J. (1999). ‘Flora of Victoria. Vol. 4.’ (Inkata Press: Melbourne.)

Wiens, J. A. (2002). Riverine landscapes: taking landscape ecology into the water. Freshwater Biology 47, 501–515.
Riverine landscapes: taking landscape ecology into the water.Crossref | GoogleScholarGoogle Scholar |

Williams, L. D., and Cleland, J. B. (1960). Plants south of Lake Alexandrina. The South Australian Naturalist 35, 21–26.

Wood, R. D. (1972). ‘Characeae of Australia.’ (J. Cramer: Lehre, Germany.)

Wood, R. D., and Imahori, K. I. (Eds) (1965). Monograph of the Characeae. In ‘A Revision of the Characeae. Vol. 1’. (Eds RD Wood, KI Imahori.) pp. 1–904. (Cramer: Weinheim, Germany.)

Wood, R. D., and Mason, R. (1977). Characeae of New Zealand. New Zealand Journal of Botany 15, 87–180.
Characeae of New Zealand.Crossref | GoogleScholarGoogle Scholar |

Zulfic, D., and Barnett, S. (2003). Eastern Mount Lofty Ranges groundwater assessment. Report to the Department of Water, Land and Biodiversity Conservation, South Australia, 20033/25, Adelaide.