Arjan Palstra, Chantal Roozeboom, John Bastiaansen, Xiaofei Yu, Farid Aththar, Priadi Setyawan and Pauline Jehannet presented their research on selective breeding with genomics tools, interaction of genes with the environment, swimming physiology and eel reproduction.
Selective breeding in tilapia
Priadi Setyawan presented his results about the potential for combined production of salinity tolerant tilapia and shrimp in brackish water pond culture in Indonesia. Small scale farmers dominate brackish water farming, and the majority of them apply shrimp and tilapia farming in polyculture, with or without rotation during rainy and dry season. He showed that such systems can be economically very profitable to the farmers but to successfully produce tilapia in brackish water, a tilapia strain with good growth over a range of fluctuating salinities is needed.
A breeding programme for salinity tolerant tilapia based on selection for own performance of harvest weight has been conducted by Research Institute of Fish breeding (RIFB) in Indonesia for four generations. Xiaofei Yu presented a detailed whole-genome analysis on the origins of Sukamandi strain which was used as base population for the breeding programme. The Sukamandi strain represents an interesting, inter-species fish hybrid produced for aquaculture, but with very asymmetrical contributions from its parent populations, the Nile tilapia and the blue tilapia. Breeding with four generations under high salinity environment resulted in strong selection on salinity- adaptive regulatory pathways.
The reproductive performance of tilapia in brackish water is also considered important. Farid Aththar presented his results about the reproductive performance and the genetic parameters of the Sukamandi strain in brackish water and freshwater. Surprisingly, all reproductive traits showed higher values in brackish water compared to freshwater. To reduce the potential threat of tilapia invading the brackish water ecosystem, selection for reduced maturation in brackish water environment is urgently needed.
Selective breeding in rainbow trout
Chantal Roozeboom simulated a rainbow trout breeding programme and investigated whether genomic selection would result in better performance. Using genomic selection, the rate of inbreeding was reduced and therefore a higher selection intensity could be applied in order to increase the genetic gain. Genotyping cost could be reduced by genotyping fish with lower density SNP panels or genotyping only half of the selection candidates.
Sea bream breeding for the east and west Mediterranean
Sea bream are a major aquaculture species produced all around the Mediterranean. John Bastiaansen showed that sea bream of different families were ranking differently for harvest weight, fillet weight and growth rate when raised in either the eastern and western Mediterranean. Because of this genotype by environment interaction breeding programmes for these environments need to be optimised, or separate breeding programmes may be needed for each environment. Producers will benefit if they stock their farms with fish from breeding programmes that target their environment. The main difference between the test sites was the water temperature, indicating that future temperature changes will need to be considered in breeding programmes of sea bream.
The production cycle of the European eel is still not closed. The Eel Reproduction Innovation Centre (EELRIC) of Wageningen University & Research can produce eel larvae three times per week but egg and larval quality is not yet optimal. This is at least partly due to the crudeness of injecting carp hormones which consists of a hormone mixture that might vary between batches and is not eel-specific. Pauline Jehannet presented results showing that larvae were produced for the first time with newly developed recombinant gonadotropins that are eel-specific. The protocol needs further improvements but could potentially improve egg equality and lead to the production of more robust larvae.
Arjan Palstra presented results from the EU MedAID project showing that an optimal flow regime, stimulating sea bream to swim, enhanced growth (by 15 percent), improved uniformity of growth (25 percent less variation), and lowered stress levels. Following these fish for six weeks with accelerometer sensors in a sea cage revealed the activity patterns over the day and over the weeks, which can be extremely useful for timing feeding events at the start of active periods.