The issue of animal welfare in aquaculture is growing of interest and there is an increasing consumer demand for documentation of safe and ethically defendable food production. In this context, we have looked for molecular markers among those genes whose expression results modified by the different farming conditions. We have compared gene expression of seabass farmed at different population densities by differential display. We have obtained six bands differentially expressed whose sequences we have deposited in the public databases; two of them resulted suppressed by high population density, while four were induced by the treatment. Population density has, therefore, an effect at gene level by repressing or enhancing the expression of different genes. These genes can be used as biomarkers to rapidly detect, by polymerase chain reaction (PCR), the occurred exposure of the fish to the stressor. We are certain that the new molecular techniques will find their place in the everyday management of fish farming; on the other hand, we are also aware that the scarcity of the genomic resources for some fish species, in spite of their economical interest, will retard the beneficial effects that modern biotechnology could bring to aquaculture industry. Therefore, an effort should be made to reduce, as far as it concerns genomics resources, the gap that separates farming species from ‘‘model organisms’’.
Effects of population density on seabass (Dicentrarchus labrax, L.) gene expression
GORNATI, ROSALBA;TEROVA, GENCIANA;VIGETTI, DAVIDE;PRATI, MARIANGELA;SAROGLIA, MARCO;BERNARDINI, GIOVANNI BATTISTA
2004-01-01
Abstract
The issue of animal welfare in aquaculture is growing of interest and there is an increasing consumer demand for documentation of safe and ethically defendable food production. In this context, we have looked for molecular markers among those genes whose expression results modified by the different farming conditions. We have compared gene expression of seabass farmed at different population densities by differential display. We have obtained six bands differentially expressed whose sequences we have deposited in the public databases; two of them resulted suppressed by high population density, while four were induced by the treatment. Population density has, therefore, an effect at gene level by repressing or enhancing the expression of different genes. These genes can be used as biomarkers to rapidly detect, by polymerase chain reaction (PCR), the occurred exposure of the fish to the stressor. We are certain that the new molecular techniques will find their place in the everyday management of fish farming; on the other hand, we are also aware that the scarcity of the genomic resources for some fish species, in spite of their economical interest, will retard the beneficial effects that modern biotechnology could bring to aquaculture industry. Therefore, an effort should be made to reduce, as far as it concerns genomics resources, the gap that separates farming species from ‘‘model organisms’’.
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