Karami, Amene, Talebi, Ali Asghar, Fathipour, Yaghoub, Mehrabadi, Mohammad (2025). Temperature-Dependent Development of Exorista larvarum (Diptera: Tachinidae): An Efficient Candidate for Biological Pest Control. , (), -.
Amene Karami; Ali Asghar Talebi; Yaghoub Fathipour; Mohammad Mehrabadi. "Temperature-Dependent Development of Exorista larvarum (Diptera: Tachinidae): An Efficient Candidate for Biological Pest Control". , , , 2025, -.
Karami, Amene, Talebi, Ali Asghar, Fathipour, Yaghoub, Mehrabadi, Mohammad (2025). 'Temperature-Dependent Development of Exorista larvarum (Diptera: Tachinidae): An Efficient Candidate for Biological Pest Control', , (), pp. -.
Karami, Amene, Talebi, Ali Asghar, Fathipour, Yaghoub, Mehrabadi, Mohammad Temperature-Dependent Development of Exorista larvarum (Diptera: Tachinidae): An Efficient Candidate for Biological Pest Control. , 2025; (): -.

Temperature-Dependent Development of Exorista larvarum (Diptera: Tachinidae): An Efficient Candidate for Biological Pest Control

Journal of Agricultural Science and Technology
Articles in Press, Accepted Manuscript, Available Online from 16 September 2025    PDF (620.75 K)
Authors
Amene Karami; Ali Asghar Talebi* ; Yaghoub Fathipour; Mohammad Mehrabadi
Department of Entomology, Faculty of Agriculture, Tarbiat Modares University, Tehran, Iran
Abstract
Climatic conditions are the most important factor in the distribution and abundance of living organisms, with temperature serving as a critical factor influencing the development of insect pests and their natural enemies. Thermal models are a key component of modern integrated pest management (IPM) systems. The Exorista larvarum (Linnaeus, 1758) (Diptera: Tachinidae), a gregarious larval endoparasitoid, serves as a biocontrol agent against several lepidopteran pests affecting both forest and agricultural ecosystems. To optimize the mass rearing of E. larvarum and improve its application in IPM programs, the developmental times of this parasitoid were investigated under seven constant temperatures (15-35 °C) in laboratory conditions. We applied two linear and 26 nonlinear models to describe the temperature-dependent development rate of E. larvarum. The lower temperature threshold (T0) and thermal constant (K) were estimated to be 5.09 °C and 389.41 DD using the ordinary linear model and 9.73 °C and 292.74 DD using the Ikemoto model, respectively. Among the nonlinear models, Performance-2, Beta, Janisch/Kontodimas, Analytis-1, and Analytis-3/Kontodimas were the best models to describe the temperature-dependent development rate of the parasitoid. The estimated Tfast values by Performance-2 and Janisch/Kontodimas models were 33.2 and 31.4 °C, respectively, closely were the closest to Tfast observed (32.5 °C). Our findings can help to gain new and valuable insights into the biology of E. larvarum and provide essential information that can be incorporated into forecasting models of this parasitoid.
Keywords
Biocontrol; degree day; Developmental rate; temperature thresholds; tachinid fly
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