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Starling circannual systems: are they arrested in long photoperiods?

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Summary

In the European starling,Sturnus vulgaris, circannual rhythms in gonadal size, molt and other related functions persist only in photoperiods close to 12 h, but are absent in longer or shorter daylengths. To find out whether the arrhythmia seen in long photoperiods results from an arrest of the underlying clock system, three groups of male starlings were held for 10, 14, or 20 months in a 13 h photoperiod and then transferred to a 12 h photoperiod. A control group was held in the 13 h photoperiod throughout the experiment for 28 months. During the initial exposure to the 13 h photoperiod, all birds went through a gonadal cycle, followed by a complete molt. Subsequently, the control birds retained small testes to the end of the experiment and there was no further molt. In contrast, most of the experimental birds re-initiated a testicular cycle, following transfer to the 12 h photoperiod and molted after its completion. The latency between the transfer to the 12 h photoperiod and the onset of testicular growth was not significantly different among the three groups, indicating that the underlying circannual clock had been arrested in the 13 h photoperiod and restarted in the 12 h photoperiod. The pattern of the second testicular cycle did, however, differ among groups. Particularly its amplitude decreased from group 1 to group 3, suggesting that the capacity of the birds to respond to a 12 h photoperiod decreased with increasing duration of exposure to the 13 h photoperiod.

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Authors and Affiliations

  1. Max-Planck-Institut für Verhaltensphysiologie, D-8138, Vogelwarte, Andechs, Germany

    E. Gwinner, G. Gänshirt & J. Dittami

Authors
  1. E. Gwinner
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  2. G. Gänshirt
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  3. J. Dittami
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Dedicated to Prof. Dr. C.S. Pittendrigh on the occasion of his seventieth birthday.

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Gwinner, E., Gänshirt, G. & Dittami, J. Starling circannual systems: are they arrested in long photoperiods?. J. Comp. Physiol. 165, 35–39 (1989). https://doi.org/10.1007/BF00613797

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  • DOI: https://doi.org/10.1007/BF00613797

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