SIT 2.0: 21(st) Century genetic technology for the screwworm sterile-insect program

Establishment of pupal color as a screening marker and activity analysis of six U6 promoters in Zeugodacus cucurbitae using the white pupae gene

BACKGROUND

The genetic control method, which is environmentally friendly and species-specific, has effectively reduced or eliminated pests in many areas. One essential requirement to control a species is the identification of its genetic and molecular elements. Such elements, however, are rarely available in Zeugodacus cucurbitae, a very destructive insect pest worldwide.

RESULTS

In this study, we knocked out the white pupae (wp) gene in Z. cucurbitae and generated a wp(-) strain, which has a white pupae phenotype. The white puparium color was successfully restored to brown by inserting the wp gene rescue allele into the genome of the wp(-) strain using piggyBac transgenic technology. The potential wp promoter was then truncated to drive the expression of the wp gene and the puparium color was rescued even by the 605 bp sequence upstream of its transcription initiation site. Further fertility tests showed that knocking out or rescuing the wp gene had no effect on the reproduction of adult flies. In addition, we identified six U6 promoters and tested their promoter activities in the embryos of Z. cucurbitae. The ZcU6-2 and ZcU6-1 promoters exhibited significantly higher activity than the others and are suitable for use in CRISPR technology-based genetic control methods.

CONCLUSION

Our work first shows the success of applying piggyBac transgenic technology in Z. cucurbitae. Our results demonstrate a highly efficient transgenic screening marker by puparium color and the promoter activity of multiple ZcU6 promoters, facilitating the construction of transgenic strains that are used for genetic control of tephritid species. © 2025 Society of Chemical Industry.

Gene drives: an alternative approach to malaria control?

Genetic modification for the control of mosquitoes is frequently touted as a solution for a variety of vector-borne diseases. There has been some success using non-insecticidal methods like sterile or incompatible insect techniques to control arbovirus diseases. However, control by genetic modifications to reduce mosquito populations or create mosquitoes that are refractory to infection with pathogens are less developed. The advent of CRISPR-Cas9-mediated gene drives may advance this mechanism of control. In this review, use and progress of gene drives for vector control, particularly for malaria, is discussed. A brief history of population suppression and replacement gene drives in mosquitoes, rapid advancement of the field over the last decade and how genetic modification fits into the current scope of vector control are described. Mechanisms of alternative vector control by genetic modification to modulate mosquitoes' immune responses and anti-parasite effector molecules as part of a combinational strategy to combat malaria are considered. Finally, the limitations and ethics of using gene drives for mosquito control are discussed.

Genetic control of Plutella xylostella in omics era

Diamondback moth, Plutella xylostella (L.), is a specialist pest on cruciferous crops of economic importance. The large-scale use of chemical insecticides for the control of this insect pest has caused a number of challenges to agro-ecosystems. With the advent of the omics era, genetic pest management strategies are becoming increasingly feasible and show a powerful potential for pest control. Here, we review strategies for using transgenic plants and sterile insect techniques for genetic pest management and introduce the major advances in the control of P. xylostella using a female-specific RIDL (release of insects carrying a dominant lethal gene) strategy. Further, the advantages of gene drive developed in combination with sex determination and CRISPR/Cas9 systems are addressed, and the corresponding prospects and implementation issues are discussed. It is predictable that under the policy and regulation of professional committees, the genetic pest control strategy, especially for gene drive, will open a new avenue to sustainable pest management not only for P. xylostella but also for other insect pests.

Analyses of density-dependent effects are needed to understand how and when Wolbachia can control dengue vectors

Releases of Wolbachia-infected mosquitoes have been shown to be an effective method of controlling Aedes aegypti, the main vector of dengue fever, in Australia. A study in BMC Biology from Penelope Hancock and others shows that incorporation of density-dependent effects into population models can provide major improvements in understanding how and when the infected populations can become established.

See research article: https://bmcbiol.biomedcentral.com/articles/10.1186/s12915-016-0319-5.