Combined blue light and daily thermocycles enhance zebrafish growth and development

In the wild, the light/temperature environment cyclically oscillates insofar as the temperature rises after dawn and drops after dusk. In the underwater photo-environment, light is filtered through the water column so that blue photons reach greater depths. This paper investigates the combined effects of both factors with two temperature regimes (constant temperature = 26 degrees C, CTE vs. daily thermocycle = 28 degrees C day:24 degrees C night, TC) and three light wavelengths (white-W, blue-B, red-R) on Danio rerio embryos and larvae from fertilization to 30 days post-fertilization (dpf). It studied hatching rate, larval survival, growth, and food intake (gut content). It analyzed the expression of the genes involved in stress (crh), somatic growth (gh, ifg1a, igf2a), and food intake control (npy, agrp, ghrelin, orexin, mch1, mch2, grp, cck8) at 10 and 30 dpf. The results revealed that the lowest hatching rate was in R regardless of the temperature regime. The highest growth rate was for the larvae reared with B + TC, which was consistent with the highest expression values of the growth factors. The highest feeding and expression levels of the genes involved in food intake were for the larvae in B (regardless of the temperature regime) and W + TC. Conversely, the R + CTE combination obtained the worst growth and feeding results. These findings indicate that the best larval performance can be achieved with combinations of blue wavelengths and cyclic temperature regimes that come closer to those in the natural environment. These results should be considered when optimizing rearing protocols to improve the growth and welfare of the fish larvae.

Automated summary

This study investigates the combined effects of temperature and light wavelength on Danio rerio embryos and larvae. It finds that blue light wavelength and cyclic temperature regimes closer to the natural environment result in the best performance of the fish larvae.