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Advances in the aquatic sciences
RESEARCH ARTICLE

Catadromous migrations by female tupong (Pseudaphritis urvillii) in coastal streams in Victoria, Australia

David A. Crook A E , Wayne M. Koster A , Jed I. Macdonald A , Simon J. Nicol B , Chris A. Belcher C , David R. Dawson A , Damien J. O'Mahony A , Danny Lovett D , Adam Walker D and Lucas Bannam D
+ Author Affiliations
- Author Affiliations

A Arthur Rylah Institute for Environmental Research, Department of Sustainability and Environment, 123 Brown Street, Heidelberg, Vic. 3084, Australia.

B Oceanic Fisheries Program, Secretariat of the Pacific Community, BP D5, 98848 Noumea Cedex, New Caledonia.

C Ecosystems Environmental Consultants, 397 Brumbys Road, Peterborough, Vic. 3270, Australia.

D Winda Mara Aboriginal Corporation, 21 Scott Street, Heywood, Vic. 3304, Australia.

E Corresponding author. Email: david.crook@dse.vic.gov.au

Marine and Freshwater Research 61(4) 474-483 https://doi.org/10.1071/MF09170
Submitted: 8 July 2009  Accepted: 20 September 2009   Published: 27 April 2010

Abstract

Understanding migratory requirements is critical for the conservation of diadromous fishes. Tupong (Pseudaphritis urvillii) are diadromous fishes found in freshwater and estuarine regions of south-eastern Australia. Previous studies have hypothesised that mature female tupong undertake downstream spawning migrations from freshwater to the estuary or sea, with a compensatory return of juveniles, and possibly spent fish, back upstream. We applied acoustic telemetry to test this hypothesis. We tagged 55 female tupong in two river systems in Victoria, Australia, and tracked movements for 4- to 6-month periods over 2 years. Thirty-one fish undertook rapid downstream migrations and then appeared to move through the estuary and out to sea between May and August in each year. Migration was associated with relatively high river discharges, and movement from the estuary to the sea tended to occur most frequently during intermediate moon phases. Low rates of movement between September and April suggested that tupong inhabited restricted home ranges outside of the spawning season. The apparently disparate migratory patterns of female (catadromous) and male (non-diadromous) tupong are rare amongst fishes globally. Differential exertion of a range of selective pressures may have resulted in the evolution of sexual differences in migratory modes in this species.

Additional keywords: catadromy, congolli, diadromy, downstream migration, Pseudaphritidae, sexual dimorphism.


Acknowledgements

The authors acknowledge and pay respects to the traditional custodians of the Koo Wee Rup region and the Budj Bim landscape at Lake Condah and Darlots Creek. The authors thank Matthew O'Brien (Glenelg-Hopkins Catchment Management Authority), Andrew Govanstone (Department of Sustainability and Environment), Matthew Butt, Damein Bell and Dennis Rose (Winda-Mara Aboriginal Corporation), Lucy Rose and Rhys Coleman (Melbourne Water) for their critical roles in the co-ordination, management and planning of this work. Jeremy Hindell (Arthur Rylah Institute) provided helpful advice and assistance with the application of acoustic tracking technology. Heather Builth, Lachlan McKinnon, Chris Gippel and Lance Lloyd provided valuable discussions about the ecology and history of the Lake Condah area. Jeremy Hindell, Frank Amtstaetter, John Morrongiello, and Lauren Dodd assisted with the field work. The authors thank Justin O’Connor, Brendan Ebner and Isabel Thibault for their constructive reviews of this manuscript. Financial support was provided by the Natural Heritage Trust, the Glenelg–Hopkins Catchment Management Authority, Melbourne Water and the Victorian Department of Sustainability and Environment. This research was conducted under Victorian Fisheries permit RP827 and animal ethics permits ARI AEC 07/02 and ARI AEC 08/04.


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