Chem. Senses 29: 93-100,
2004
© Oxford University Press 2004
Behavioral Responses of Newly Hatched Zebrafish (Danio rerio) to Amino Acid Chemostimulants
1 Department of Biological Sciences, University of South Carolina, Columbia, SC 29208, USA
2 Present address: School of Marine Sciences, University of Maine, Orono, ME 04469, USA
Correspondence to be sent to: Richard G. Vogt, Department of Biological Sciences, University of South Carolina, Columbia, SC 29208, USA. e-mail: vogt{at}biol.sc.edu
The zebrafish chemosensory systems of olfaction, taste and solitary chemosensory cells (SCCs) are established during the first week after fertilization (a.f.). These systems presumably support the early development of feeding behaviors required as yolk supplies diminish over the same period. Yet there is no previous data reporting early chemosensory responses in zebrafish. We therefore assayed the chemosensory behavior of newly hatched zebrafish on days 3, 4 and 5 a.f. Responses were compared between fish exposed to water alone versus water containing a mixture of 12 amino acids (100 µM each) flowing through a 50 ml test chamber at 4 ml/min; computer-assisted motion analysis was used to quantify responses. Behavioral responses were first observed at day 4 a.f.; the number of fish swimming, their swimming speeds, and their net-to-gross displacement (NGDR) all increased significantly in response to amino acid stimulation. Because taste buds first appear 4–5 days a.f. and the SCCs may not respond to amino acids, these initial chemosensory responses of day 4 fish may be mediated by already established olfactory neurons. The onset of chemosensitivity in day 4 fish corresponded with an easily recognizable developmental phenotype of inactive floating; day 3 fish were inactive and resting on the bottom while day 5 fish were active and moving through the water column. The ease of identifying responsive day 4 fish suggests these animals may be useful for characterizing odorant sensitivity or developmental plasticity or for screening for chemosensory mutations.
Key words: chemoreception, chemosensory behavior, development, fish, odor, olfactory receptor
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