Thermal effect on the fecundity and longevity of Bactrocera dorsalis adults and their improved oviposition model

Abstract

The oriental fruit fly, Bactrocera dorsalis, is a destructive polyphagous pest that causes damage to various fruit crops, and their distribution is currently expanding worldwide. Temperature is an important abiotic factor that influences insect population dynamics and distribution by affecting their survival, development, and reproduction. We examined the fecundity, pre-oviposition and oviposition periods, and longevity of adult B. dorsalis at various constant temperatures ranging from 13 degrees C to 35 degrees C. The longevity of female B. dorsalis ranged from 116.8 days (18.8 degrees C) to 22.4 days (34.9 degrees C), and the maximum fecundity per female was 1,684 eggs at 28.1 degrees C. Females were only able to lay eggs at 16.7 degrees C to 34.9 degrees C, and both the pre-oviposition and oviposition periods were different depending on the temperature. We modeled female reproduction in two oviposition models (OMs): 1) the current model developed by Kim and Lee, an OM composed of a fecundity model, age-specific survival model, and age-specific cumulative oviposition rate model, and 2) a two-phase OM modified the logic structure of the current model by separating pre-oviposition, so that oviposition was estimated with the female in oviposition phase who had complete pre-oviposition phase. The results of the two-phase OM provided more realistic outputs at lower and higher temperatures than those of the current model. We discussed the usefulness of the twophase OM for the reproduction of insects with long pre-oviposition periods.