# Genetic Surveillance Reveals Differential Evolutionary Dynamic of Anopheles gambiae Under Contrasting Insecticidal Tools Used in Malaria Control

**Authors:** Harun N. Njoroge, Lilian Namuli, Sanjay C. Nagi, Anastasia Hernandez‐Koutoucheva, Daniel P. McDermott, Erin Knight, Samuel Gonahasa, Amy Lynd, Ambrose Oruni, Catherine Maiteki‐Sebuguzi, Jimmy Opigo, Adoke Yeka, Agaba Katureebe, Mary Kyohere, Moses R. Kamya, Grant Dorsey, Janet Hemingway, Sarah G. Staedke, Chris Clarkson, Alistair Miles, Eric R. Lucas, Martin J. Donnelly

PMC · DOI: 10.1111/mec.70284 · Molecular Ecology · 2026-03-03

## TL;DR

This study uses genetic data to track how malaria mosquitoes evolve in response to different insecticide-treated nets, showing distinct resistance patterns.

## Contribution

The study reveals distinct evolutionary dynamics of Anopheles gambiae under pyrethroid-only and pyrethroid-PBO nets, highlighting resistance mechanisms.

## Key findings

- Mosquito populations exposed to pyrethroid-only nets showed increased frequency of the Cyp9k1 gene duplication.
- PBO-treated nets selected for a chromosomal variant near the UDP-glucose 6-dehydrogenase gene.
- Pyrethroid-only nets selected a novel X chromosome locus linked to neurotransmission modulation.

## Abstract

Malaria, a febrile disease caused by the Plasmodium parasites and transmitted by mosquitoes, is a leading cause of mortality in children under 5 in endemic countries. The widespread deployment of insecticide‐treated bed nets (ITNs) has significantly reduced malaria transmission, but rising levels of insecticide resistance threaten to halt the progress. Monitoring insecticide resistance is vital for effective vector control, particularly when deploying new tools. Understanding mosquito population responses to these interventions is crucial for guiding control programmes in making informed decisions about the selection, timing and geographic deployment of tools. This genomic study investigates the demographic and evolutionary consequences on the malaria vector 
Anopheles gambiae
 of deploying standard ITNs (containing only pyrethroids) and pyrethroid‐PBO nets (containing pyrethroids plus the synergist piperonyl butoxide) during a clinical trial in Uganda. Despite substantial reductions in indoor mosquito densities in the clinical trial, estimates of nucleotide diversity (π) and linkage disequilibrium revealed no significant decline in effective population size, reflecting continued large population size even after effective control. Marked allele frequency shifts at resistance‐associated loci indicated strong selection pressures driven by the interventions, with distinct selective dynamics between the two net types, highlighting alternative pyrethroid detoxification pathways in the presence of PBO. A duplication in the Cyp9k1 gene significantly increased in frequency in populations exposed to pyrethroid‐only nets but decreased in populations exposed to PBO‐treated nets, suggesting that selection for over‐expression of this gene is removed when this resistance mechanism is impacted by PBO. An alternative potential detoxification mechanism was selected within a region of the 2La chromosomal inversion on chromosome 2 L, which encompasses the UDP‐glucose 6‐dehydrogenase gene. This variant consistently increased in frequency when exposed to PBO‐treated nets. Additionally, pyrethroid‐only nets selected for a novel locus on the X chromosome containing the diacylglycerol kinase gene, which is potentially linked to behavioural adaptations through its role in neurotransmission modulation. Our findings underscore the importance of genomic surveillance in vector control, revealing distinct evolutionary dynamics of insecticide resistance mechanisms in the presence of PBO. While ITNs remain effective, the persistence and evolution of resistance‐associated alleles highlight the need for adaptive and dynamic resistance management strategies. By integrating high‐resolution genomic data with epidemiological and entomological monitoring, this study offers actionable insights to sustain malaria control efforts amid the ongoing challenge of insecticide resistance.

## Linked entities

- **Genes:** LOC1277432 (cytochrome P450 9e2) [NCBI Gene 1277432]
- **Chemicals:** pyrethroids (PubChem CID 162381), piperonyl butoxide (PubChem CID 5794)
- **Diseases:** malaria (MONDO:0005136)
- **Species:** Anopheles gambiae (taxon 7165)

## Full-text entities

- **Genes:** DGKQ (diacylglycerol kinase theta) [NCBI Gene 1609] {aka DAGK, DAGK4, DAGK7}, DGKB (diacylglycerol kinase beta) [NCBI Gene 1607] {aka DAGK2, DGK, DGK-BETA}
- **Diseases:** Infectious Diseases (MESH:D003141), Malaria (MESH:D008288), anaemia (MESH:D000743), deaths (MESH:D003643), metabolic (MESH:D008659), febrile disease (MESH:D004194)
- **Chemicals:** dieldrin (MESH:D004026), DAG (MESH:D004075), lipid (MESH:D008055), PBO (MESH:D010882), UDP-glucose (MESH:D014532), amino acids (MESH:D000596), silica (MESH:D012822), sodium (MESH:D012964), DONNELLY (-), PA (MESH:D010712), Pyrethroids (MESH:D011722), fipronil (MESH:C082360), UDP-glucuronic acid (MESH:D014535)
- **Species:** Plasmodium (subgenus) [taxon 418103], Anopheles gambiae (African malaria mosquito, species) [taxon 7165], Culex quinquefasciatus (southern house mosquito, species) [taxon 7176], Aedes aegypti (yellow fever mosquito, species) [taxon 7159]
- **Mutations:** L1014F, 995S, 296G/S, L995S/F, 296G, Q467R, I236M, 236 M, A>C, L995F, 995F, V390G, N1575Y, L21F, L995S

## Full text

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## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12954828/full.md

## References

74 references — full list in the complete paper: https://tomesphere.com/paper/PMC12954828/full.md

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Source: https://tomesphere.com/paper/PMC12954828