Evidence for species-specific clock gene expression patterns in hamster peripheral tissues

- We examined daily clock gene expression patterns via qPCR in three hamster species.
- Six clock genes were analyzed in the kidney, liver, spleen, heart, and testis.
- Clock gene expression pattern was rhythmic in all investigated peripheral organs.
- Complex cosinor analysis revealed species differences, most obvious in the testis.
- Organ- and species-specific patterns suggest clock-unrelated clock gene functions.

Rhythmic oscillations that repeat every 24 h can be found in numerous behavioral and physiological functions. Beside the endogenous master clock in the suprachiasmatic nucleus (SCN), peripheral oscillators exist that can disengage from the master clock rhythm by different mechanisms. The fact that core clock genes in peripheral tissues do not always have the same characteristics as in the SCN suggests that their function may vary in different organs. Additionally, suggestions about species-specific variation in expression peak and nadir times, especially in the testis, led to the need for systematical investigations on clock gene expression patterns in different organs and species under standardized methodological conditions. Therefore, daily gene expression patterns of the clock genes Bmal1, Period1, Period2, Clock, Cryptochrome1 and Cryptochrome2 were recorded at each of eight time points during a 24 hour period in the testis, kidney, liver, spleen and heart of three hamster species (Phodopus sungorus, Phodopus roborovskii and Cricetulus griseus; family: Cricetidae). Clock gene expression was found to be rhythmic in all investigated organs, however with inconsistent results in the testis. Complex cosinor analysis revealed species differences in temporal gene expression patterns regarding their orthophase, number of peaks, and amplitude for all genes and organs with most pronounced differences in the testis. The results of this study strongly indicate that clock gene expression in peripheral tissues is species-specific and that their functions might be at least partly connected to clock-unrelated traits that vary between the investigated species. Further studies should aim at clarifying the specific roles of clock genes in the testis.