Pigmentation and/or immunity? - Sandmansandman.net/files/Betta.pdf · Pigmentation and/or immunity?...
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Pigmentation and/or immunity? Carotenoid pigments are responsible for many examples of sexual attractive red, orange and yellow coloration in animals and play an important role in antioxidant and immune defences. In this study an experimental approach has been used to test the carotenoid trade-off hypothesis between maintaining coloration and health. Methodology Experimental approach on Betta splendens; Female - for male color: A dichotomus mate choice test was conducted in the laboratory Carotenoid supplementation A Carotenoiddiet was given number of Betta splendens in each color (red/blue). The reflectation was measured using a Ocean Optics USN2000 spectrometer connected to a PX-2 pulsed xenon light. Immune response Tested by using PHA. Pigmentation analysis Analysis of dermis and epidermis with spectrophotometer. Statistic analysis To conduct statistical analyses SAS 9.1.3, ANOVA and t-test was used. Trade-offs between pigmentation and immunity in Betta Splendens Red fish, blue fish: trade-offs between pigmentation and immunity in Betta splendens By Ethan D. Clotfelter, Daniel R. Ardia and Kevin J. McGraw Department of Biology, Amherst College, Amherst, MA 01002, USA and School of Life Science, Arizona State University, Tempe, AZ 85287, USA. Publication; Behavioral Ecology doi:10.1093/beheco/arm090, Advance Access publication 10 October 2007. 0 50 100 150 200 Blue male Neutral Zone Red Male 0 0,05 0,10 0,15 0,20 Control Carotenoid supplemented 0 0,075 0,150 0,225 0,300 -10,0 -7,5 -5,0 -2,5 0 2,5 5,0 7,5 10,0 Blue Red Female Betta splendens spent more time (Mixed model ANOVA: F1.44= 9.36, P = 0.004) associated with red males (149.0912.12 s) than with blue males, (96.4812.21 s ). Fish feed with dietary carotenoids (N=33) did have a significantly greater immune respons to the PHA injection than the controls (N=28). (Mean postinjection swelling in mm SE: control = 0.087 0.01 mm, N = 28; supplemented = 0.17 0.02 mm, N = 33; carotenoid supplemented group: F1.58 = 12.68, P = 0.001) Fishes with low PC2 values (more blue) showed a larger increase in immune activity than redder fish supplemented with carotenoids. (Overall modell: F4.56=7.83 P<0.0001; initial redness: F1.56= 7.59, P<0.01; supplementation: F1.56 = 15.5 P= 0.0002). Conclusion The carotenoid trade-off hypothesis is supported in Betta splendens. The carotenoid pigments are both used for coloration, prefered by females in sexual selection and boost both immunity and coloration when abundance. Female Betta splendens preferred to associate with red males over blue males, which suggest a sexual selection to being red. Carotenoid-supplemented fish became redder and a natural redder fish had higher caroteonid concentration in their skin. In contrast, blue males of Betta splendens did not change in coloration but instead benefited immunological more than both redder males and controls. This gives an understanding of carotenoid mobilization and utilization pathways in animals. Anna Lydig vt. 2008
Transcript of Pigmentation and/or immunity? - Sandmansandman.net/files/Betta.pdf · Pigmentation and/or immunity?...
Pigmentation and/or immunity?
Carotenoid pigments are responsible for many examples of sexual attractive red, orange and yellow coloration in animals and play an important role in antioxidant and immune defences. In this study an experimental approach has been used to test the carotenoid trade-off hypothesis between maintaining coloration and health.
MethodologyExperimental approach on Betta splendens;
Female - for male color:A dichotomus mate choice test was conducted in the laboratory
Carotenoid supplementationA Carotenoiddiet was given number of Betta splendens in each color (red/blue). The reflectation was measured using a Ocean
Optics USN2000 spectrometer connected to a PX-2 pulsed xenon light.
Immune responseTested by using PHA.
Pigmentation analysisAnalysis of dermis and epidermis with spectrophotometer.
Statistic analysis To conduct statistical analyses SAS 9.1.3, ANOVA and t-test was used.
Trade-offs between pigmentation and immunity in Betta Splendens
Red fish, blue fish: trade-offs between pigmentation and immunity in Betta splendensBy Ethan D. Clotfelter, Daniel R. Ardia and Kevin J. McGraw
Department of Biology, Amherst College, Amherst, MA 01002, USA and School of Life Science, Arizona State University, Tempe, AZ 85287, USA. Publication; Behavioral Ecology doi:10.1093/beheco/arm090, Advance Access publication 10 October 2007.
0
50
100
150
200
Blue maleNeutral Zone
Red Male0
0,05
0,10
0,15
0,20
ControlCarotenoid supplemented
0
0,075
0,150
0,225
0,300
-10,0 -7,5 -5,0 -2,5 0 2,5 5,0 7,5 10,0
Blue Red
Female Betta splendens spent more time (Mixed model ANOVA: F1.44= 9.36, P = 0.004) associated with red males (149.0912.12 s) than with blue males, (96.4812.21 s ).
Fish feed with dietary carotenoids (N=33) did have a significantly greater immune respons to the PHA injection than the controls (N=28). (Mean postinjection swelling in mm SE: control = 0.087 0.01 mm, N = 28; supplemented = 0.17 0.02 mm, N = 33; carotenoid supplemented group: F1.58 = 12.68, P = 0.001)
Fishes with low PC2 values (more blue) showed a larger increase in immune activity than redder fish supplemented with carotenoids. (Overall modell: F4.56=7.83 P<0.0001; initial redness: F1.56= 7.59, P<0.01; supplementation: F1.56 = 15.5 P= 0.0002).
ConclusionThe carotenoid trade-off hypothesis is supported in Betta splendens. The carotenoid pigments are both used for coloration, prefered by females in sexual selection and boost both immunity and coloration when abundance. Female Betta splendens preferred to associate with red males over blue males, which suggest a sexual selection to being red. Carotenoid-supplemented fish became redder and a natural redder fish had higher caroteonid concentration in their skin. In contrast, blue males of Betta splendens did not change in coloration but instead benefited immunological more than both redder males and controls. This gives an understanding of carotenoid mobilization and utilization pathways in animals.
Anna Lydigvt. 2008
