%20fruits.JPG "Infested watermelon (Citrullus lanatus) fruits collected from the sampling sites")
Madeleine Ivonne Mendy,
Toffène Diome, Mamecor Faye, and Mbacké
Sembène, from the institute of Sénégal. wrote a Research article about, Temperature
Effects on Melon Fly Development in Senegal Watermelon Crops. entitled, Effect
of temperature on the development of immature stages of Zeugodacus cucurbitae
(Diptera: Tephritidae), Coquillett, 1899, A major watermelon pest in Senegal. This
research paper published by the International Journal of Biosciences | IJB. an
open access scholarly research journal Biosciences. under the affiliation of
the International Network For Natural Sciences| INNSpub. an open
access multidisciplinary research journal publisher.
Abstract
Global warming strongly
influences the development of Zeugodacus cucurbitae, a major pest of
cucurbit crops; however, the effects of certain intermediate and high
temperatures, as well as natural conditions particularly on watermelon remain
insufficiently documented. The present study assessed the effect of a thermal
gradient, including ambient temperature and constant temperatures of 25, 27,
30, and 33°C, on the development of the immature stages (egg-larva-pupa)
of Z. cucurbitae. The results indicate that preimaginal development time
exhibits a non-linear thermal response. The duration of the pupal stage
decreases with increasing temperature, whereas pupal survival and total
developmental time follow a unimodal pattern, characterized by accelerated
development up to a thermal optimum (27°C), beyond which biological performance
declines and variability increases. These findings confirm the existence of an
optimal thermal window (25-27°C) for the development of Z. cucurbitae and
reveal stage-specific thermal plasticity. This sensitivity to temperature
fluctuations has important implication for phenological modeling, population dynamics
forecasting, and the adaptation of integrated pest management strategies under
climate change scenarios.
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Introduction
Climate warming is now
an unequivocal scientific reality. According to Legg (2021), the global mean
temperature has increased by approximately 1.1°C relative to pre-industrial
levels, primarily due to anthropogenic activities, with a marked
intensification of heatwaves and thermal extremes. Recent years rank among the
warmest ever recorded, reflecting a persistent upward temperature trend (WMO,
2026). Beyond physical alterations, these changes directly affect biological
systems by modifying the distribution, phenology, physiology, and population
dynamics of living organisms (Trisos et al., 2022). Temperature is a
fundamental abiotic factor governing the distribution and functioning of
organisms within ecosystems (Odum, 1971; Ricklefs, 2008). Teder et al. (2022)
reported that it strongly influences the growth and development of ectothermic
animals. Insects are typical ectotherms, characterized by high taxonomic
diversity, large population sizes, and rapid reproductive rates (Chapman, 1998;
Grimaldi and Engel, 2005). Their small body size, thin cuticle, rapid heat
exchange with the surrounding environment, and limited capacity to maintain a
stable body temperature make them particularly sensitive to environmental
fluctuations (Zeng et al., 2022). In agroecosystems, climate change regulates
the geographic distribution of pests, the number of generations per year,
survival rates, and synchronization with host plants (Britannica, 2026).
Zeugodacus cucurbitae (Coquillett, 1899) (Diptera : Tephritidae), commonly
known as the melon fly, is a major pest of tropical and subtropical cucurbit
crops, causing substantial agricultural losses when populations reach high
densities (Dhillon et al., 2005; Meyer et al., 2015; Zeng et al., 2022). Like
other poikilothermic insects, its development is strongly influenced by ambient
temperature, which affects both the duration of the immature stages (egg,
larva, and pupa) and their survival (Vayssières et al., 2008; Mkiga and
Mwatawala, 2015). Although several studies (Vayssières et al., 2008; Mkiga and
Mwatawala, 2015; Ahn et al., 2022; Zeng et al., 2022) have examined the effects
of temperature on the development of Z. cucurbitae, they rarely include
watermelon-one of the fly’s principal host plants-and are generally restricted to
a limited range of constant temperatures (20, 25, and 30°C). Moreover, these
studies predominantly focus on populations from East Africa or Asia. According
to Mwatawala et al. (2016), watermelon is the preferred host of Z. cucurbitae.
In addition, intermediate temperatures (27°C) and those approaching the upper
thermal tolerance limit (≈33°C) remain poorly documented in the scientific
literature. The effects of natural ambient conditions, incorporating daily
thermal fluctuations, have also not been directly compared with controlled
constant temperatures.
Therefore, evaluating
the development of Z. cucurbitae under a thermal gradient including ambient
temperature and constant temperatures of 25, 27, 30, and 33°C an approach not
previously implemented in Senegal helps fill a critical knowledge gap. This
framework enables a more precise determination of the thermal optimum and
sublethal thresholds, improves understanding of the species’ thermal
plasticity, and strengthens predictive tools for population management. The
objective of this study is to compare the thermal responses of the different
immature stages and to identify the optimal temperature ranges for their
development.
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