What does this research mean for the field?

Developing effective plant-based nano-biopesticides requires a 'DNA-conscious' engineering approach that integrates nanomaterial design with plant microbial buffering systems to balance delivery efficiency and genomic safety. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This review aims to explore the chemical interactions of nanoparticles with plant DNA and assess their impact on genomic stability and pest control.

May 16, 2026Open Access

Nanoengineering for DNA-Conscious Delivery of Plant-Based Biopesticides in Agroecosystems

Key Points

This review aims to explore the chemical interactions of nanoparticles with plant DNA and assess their impact on genomic stability and pest control.
Critical examination of chemical and cellular interactions between nanoparticles and plant DNA.
Review of experimental evidence on the effects of nanoparticles and beneficial microbes on plant genomic stability.
Discussion of design frameworks for stimuli-responsive nanocarriers to improve safety and efficacy.
Nanoparticles can both induce plant defense mechanisms and pose risks to genomic stability.
Positive microbial interactions help to mitigate nanoparticle-induced genomic damage.
Design strategies are proposed to enhance both safety and delivery efficacy of biopesticides.

Abstract

The widespread usage of synthetic pesticides has been questioned in the areas of ecological persistence, development of resistance, and genomic stress in crops in the long term. Ecologically compatible alternatives are plant-derived biopesticides, but the field performance of these biopesticides is limited because of volatility, low solubility, rapid degradation and low system mobility. The nanoengineering has come up as a formulation approach to promote stability and controlled delivery of phytochemicals. Metal-based, polymeric, and carbon nanocarriers enhance stability and bioavailability; however, their ability to penetrate cellular compartments and interact with chromatin necessitates rigorous evaluation of genotoxic, epigenetic, and transcriptional effects. This review critically examines the chemical and cellular interactions of nanoparticles with plant DNA, emphasizing their dual function as inducers of defense mechanisms and possible contributors to genomic instability. Evidence is available to show that positive mutualistic microbes, such as rhizobacteria, arbuscular mycorrhizal fungi, endophytes, and artificial microbiomes, act as genomic buffering systems, by sequestering reactive oxygen species, enhancing DNA repair pathways, and modulating epigenetic states. The interactions of microbials and nanoparticles also have an effect on nanoparticle physicochemistry, rhizosphere localization as well as controlled release dynamics. The design of stimuli-responsive, degradable, and microbiome-responsive nanocarriers is addressed to reduce the off-target genomic activity and preserve the pesticidal activity. This review offers a comprehensive approach to nano-biopesticide development through nanomaterial design, molecular plant response, and microbial protection to manage nano-biopesticide system development in agroecosystems by making genomic integrity the main assessment measure. • DNA-aware nanoengineering combines pesticidal efficacy with genomic safety limits • NP-DNA interactions encompass ROS signaling, chromatin remodeling, and epigenetics • SynComs and plant microbes control NP genotoxicity with regulated release • Proposed design frameworks balance DNA integrity and nano-delivery efficiency

Nanoengineering for DNA-Conscious Delivery of Plant-Based Biopesticides in Agroecosystems

Key Points

Abstract

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