Murray–Darling Basin Authority Native Fish Strategy Strategies to improve post release survival of hatchery-reared threatened fish species Michael Hutchison, Danielle Stewart, Keith Chilcott, Adam Butcher, Angela Henderson

Variances relating to use of cover and open areas were homogenous between groups and no significant differences were detected between treatment groups by general ANOVA in mean use of cover (Figure 34) after introduction of a predator. Use of cover was similar both before and after introduction of a predator across most treatments, with the tendency being for a greater use of cover than open areas. Figure 34 suggests a trend for increased use of cover and a corresponding decrease in use of open areas by 72 hour trained catfish, but this was not significant at the 5% level. Figure 35 suggests an initial upward trajectory in use of cover after introduction of the predator, followed by a gradual decline towards pre-introduction levels. Mean use of cover by 72 hours trained fish is consistently higher than that of control fish (Figure 35) in the first 10 minutes after introduction of a predator.

Movements of catfish decreased after the introduction of a predator, but there were no significant differences between any of the treatment groups. Movement behaviour by catfish consisted of roaming and loose schooling behaviour with no evidence for territorial interactions. After introduction of the predator, most movements occurred in cells external to the predator cell.

Bartlett's test of homogeneity of variances showed no significant differences between treatment variances in each of catfish, silver perch and Murray cod fingerling groups. Analyses of fingerling data by ANOVA shows that although the fingerlings in each species group responded to the presence of a simulated bird, the response of trained fish was not significantly different at the 5% level to that of control fish in all cases. i.e., both trained and untrained fish responded in the same way.

Trained and untrained sub-adult silver perch showed no significant difference in the use of predator, near or far cells (p>0.1). However there was a significant difference in the use of cover between trained and untrained silver perch both before (p <0.01) and after (p=0.015) simulated bird attack (Figure 37). Trained sub-adult silver perch tended to use cover more than the untrained sub-adult silver perch before simulated predatory bird attack. Simulated predatory bird attack also increased cover use by trained silver perch marginally. Use of cover did not change in untrained fish but became slightly more variable.

Small adult silver perch pairs in 1000 L tanks did not behave normally, refusing to feed during live feeding trials. In contrast, during training in 7000 L tanks, silver perch readily took live shrimp, even on the first day. Given the behaviour of silver perch in the 1000 L tanks this experiment was abandoned. It was clear during the training that silver perch readily accepted live shrimp. Within an hour of being returned to a 7000 L tank silver perch were readily feeding again. Unfortunately 7000 L tanks could not be used for the validation experiments as the larger tank size made accurate observations of predation more difficult and there were also insufficient large tanks available for simultaneous replication due to the requirement to use the large tanks for housing other species at the research centre.