Photoperiodic control of development in the New Zealand leafroller moth Planotortrix octo Dugdale (Lepidoptera, Tortricidae)

Abstract

The aim of this study is to test for photoperiodic control of larval and pupal development in the New Zealand moth Planotortrix octo Dugdale. The photoperiodic response curves for larval and pupal development and especially for instar number at 17°C and 21°C indicate that a photoperiodic mechanism is involved. Superimposed on this response is the suggestion that daylength affects development rate directly, with larvae and pupae developing faster under longer photophases. This effect is especially strong for pupal development (Chapter 3). The effects of thermophotoperiods (Chapter 4), night interruption and resonance experiments (Chapter 6) provide further evidence for photoperiodic involvement. The response to resonance experiments suggests the involvement of an hourglass rather than a circadian mechanism. Larvae reared under short days accumulate significantly more lipids in the 5th and 6th instars than larvae reared under long days (Chapter 4). This finding, combined with the suppressed development rate and higher instar number under short days, suggests that a weak form of diapause may be present in this insect. This is significant in being the first recorded incidence of a photoperiodically induced diapause in a phyllophagous New Zealand insect for which a year round food supply is available (Chapter 1). By transferring insects from long to short days I found that long days have more influence than short days on larval development (Chapter 7). An attempt was made to measure juvenile hormone titres under long and short days using a Galleria bioassay. The test used was not sensitive enough however to measure any significant amounts of juvenile hormone (Chapter 8). Simulations of the experimental results were performed using a damped circadian oscillator model (Chapter 9). This model was considered the most appropriate to use, based on the experimental results and on a review of the literature (Chapter 2). Simulations showed good similarities with experimental results in most cases, but could not account for resonance responses.