Shin G. Goto scite author profile

BackgroundMost organisms have evolved a circadian clock in order to anticipate daily environmental changes and many of these organisms are also capable of sophisticated measurement of daylength (photoperiodism) that is used to regulate seasonal events such as diapause, migration and polymorphism. It has been generally accepted that the same elements are involved in both circadian (daily) and seasonal (annual) rhythms because both rely upon daily light-dark cycles. However, as reasonable as this sounds, there remains no conclusive evidence of such a molecular machinery in insects. We have approached this issue by using RNA interference (RNAi) in Riptortus pedestris.ResultsThe cuticle deposition rhythm exhibited the major properties of circadian rhythms, indicating that the rhythm is regulated by a circadian clock. RNAi directed against the circadian clock genes of period and cycle, which are negative and positive regulators in the circadian clock, respectively, disrupted the cuticle deposition rhythm and distinct cuticle layers were produced by these RNAi. Simultaneously, period RNAi caused the insect to avert diapause under a diapause-inducing photoperiod whereas cycle RNAi induced diapause under a diapause-averting photoperiod. The expression patterns of juvenile hormone-regulated genes and the application of juvenile hormone analogue suggested that neither ovarian development itself nor a downstream cascade of juvenile hormone secretion, were disturbed by period and cycle RNAi.ConclusionsThis study revealed that the circadian clock genes are crucial not only for daily rhythms but also for photoperiodic diapause. RNAi directed against period and cycle had opposite effects not only in the circadian cuticle deposition rhythm but also in the photoperiodic diapause. These RNAi also had opposite effects on juvenile hormone-regulated gene expression. It is still possible that the circadian clock genes pleiotropically affect ovarian development but, based on these results, we suggest that the circadian clock operated by the circadian clock genes, period and cycle, governs seasonal timing as well as the daily rhythms.See Commentary: http://www.biomedcentral.com/1741-7007/8/115

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Gene expression of heat-shock proteins (Hsp23, Hsp70 and Hsp90) during and after larval diapause in the blow fly Lucilia sericata

Tachibana

Numata

Goto

2005

Journal of Insect Physiology

120

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Heat- and cold-shock responses and temperature adaptations in subtropical and temperate species of Drosophila

Goto

Kimura

1998

Journal of Insect Physiology

123

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Roles of circadian clock genes in insect photoperiodism

Goto

2012

Entomological Science

115

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Functional involvement of a circadian clock in photoperiodism for measuring the length of day or night had been proposed more than 70 years ago, and various physiological experiments have supported the idea. However, the molecular basis of a circadian clock has remained veiled in insects. Nevertheless, our knowledge of the functional elements of a circadian clock governing circadian rhythmicity has advanced rapidly. Since both circadian rhythms and photoperiodism depend on the daily cycles of environmental changes, it is easy to assume that the same clock elements are involved in both processes. Recently, the RNA interference (RNAi) technique clarified that the molecular machinery of a circadian clock governing photoperiodism is identical to that governing circadian rhythmicity. Here, I review the theoretical background of photoperiodic responses incorporating a circadian clock(s) and recent progress on the molecular clockwork involved in photoperiodism in the bean bug Riptortus pedestris and other insect species. I have focused on the intense controversy regarding the involvement of a circadian clock in insect photoperiodism.

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Expression of Drosophila homologue of senescence marker protein-30 during cold acclimation

Goto

2000

Journal of Insect Physiology

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Shin G. Goto

Photoperiodic diapause under the control of circadian clock genes in an insect

Gene expression of heat-shock proteins (Hsp23, Hsp70 and Hsp90) during and after larval diapause in the blow fly Lucilia sericata

Heat- and cold-shock responses and temperature adaptations in subtropical and temperate species of Drosophila

Roles of circadian clock genes in insect photoperiodism

Expression of Drosophila homologue of senescence marker protein-30 during cold acclimation

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