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Home NEWS Science News Technology

Nanotechnology amplifies the effectiveness of natural biopesticides

Bioengineer by Bioengineer
May 19, 2026
in Technology
Reading Time: 3 mins read
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Nanotechnology amplifies the effectiveness of natural biopesticides — Technology and Engineering
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In a striking advancement poised to reshape sustainable pest management, researchers from VIB and Vrije Universiteit Brussel have unraveled a novel biological mechanism behind the efficiency of Bacillus thuringiensis (Bt), a cornerstone in eco-friendly agriculture. Their groundbreaking study, documented in Nature Communications, details the discovery of a unique fibrous protein network, coined ‘sporesilk’, that intricately binds infectious bacterial spores and toxin crystals, optimizing their collaborative assault on insect larvae. This revelation not only deepens scientific understanding of Bt’s modus operandi but also opens pathways to engineering more potent, resilient biopesticides.

Bacillus thuringiensis operates through a sophisticated two-pronged attack on susceptible insect larvae. Initially, Bt secretes specific crystalline toxins targeting and compromising the insect’s gut lining, which facilitates the penetration of bacterial spores into the larval body. These spores germinate inside, proliferate by consuming the host, and upon exhausting resources, generate new spores and toxins, continuing the infectious cycle. This naturally selective pest control agent is renowned for its specificity, posing negligible risk to non-target organisms including humans, beneficial insects like pollinators, and other wildlife.

While the synergistic relationship between Bt’s spores and toxins has long been recognized, the underlying question that has perplexed scientists is the mechanism by which these two critical components remain physically associated in diverse and often hostile environmental conditions until ingestion by the insect host. Understanding this has been pivotal for enhancing Bt efficacy and environmental persistence.

The VIB-VUB Center for Structural Biology team employed cutting-edge high-resolution imaging and biochemical analyses to unveil the presence of ultra-fine protein fibers enmeshing the spores and toxin crystals into compact clusters. These fibers, roughly eight nanometers in diameter, are architecturally remarkable: they assemble into organized, double-helical strands that are chemically crosslinked, conferring extraordinary mechanical robustness and chemical resistance.

Such a fibrous matrix acts like a molecular scaffold, encapsulating infectious units in a stable yet dynamic net. Notably, this sporesilk withstands extreme environmental stressors—surviving intense heat, desiccation, and presence of harmful chemicals without disintegration. This resilience is fundamental to the persistence and bioavailability of Bt in agricultural settings, where exposure to fluctuating climate and soil conditions is inevitable.

Professor Han Remaut, lead author and structural biology expert, emphasizes the exceptional nature of sporesilk: “This is one of the most resilient natural protein materials we’ve encountered, showcasing unique self-assembly and crosslinking chemistry that stabilizes Bt’s infectious machinery.” Such proteins exhibit functional sophistication beyond classical biopolymers like silk or collagen, hinting at evolutionary refinement for microbial survival and virulence.

Functionally, sporesilk creates enhanced infectious units by congregating spores and their associated Cry toxin crystals into tight clusters. Dr. Mike Sleutel articulates the significance: “The simultaneous delivery of spores alongside their toxic partners ensures that the larvae ingest a comprehensive lethal package, improving infection rates and mortality speed.” This molecular congregation optimizes pathogen-host interactions, reducing the chance that either component is lost or neutralized before infection takes hold.

Experimental disruption of sporesilk biosynthesis via gene knockout resulted in disaggregation of spores and toxins, diminishing Bt’s lethal efficacy and causing delays in larval mortality in controlled experiments. Conversely, reintroducing sporesilk fibers, either genetically or by supplementation with purified proteins, reinstated clustering and substantially increased pesticidal potency. These findings underscore sporesilk’s critical role as a molecular adhesive enhancing Bt’s biocontrol performance.

Beyond agricultural applications, the study points toward broader biotechnological potentials. Owing to their stability and self-assembling nature, sporesilk fibers might inspire the development of next-generation biomaterials for diverse applications, from environmentally robust nanofibers to novel bioengineered scaffolds in tissue engineering or materials science. This exemplifies how microbial structures can inform and transform synthetic biology and engineering disciplines.

As the global imperative to reduce chemical pesticide reliance intensifies, innovations like sporesilk-mediated enhancement of Bt stand at the forefront of sustainable pest management strategies. Deciphering and harnessing such natural microbial architectures can significantly contribute to eco-friendly agriculture, safeguarding biodiversity while maintaining crop yields.

This profound insight into Bt’s infectious strategy reshapes our understanding of microbial pathogenesis and highlights the hidden complexity within seemingly simple bacterial life cycles. Future research may delve deeper into the molecular dynamics governing sporesilk assembly and explore genetic manipulations to produce customized biopesticides tailored for diverse agricultural ecosystems.

In summary, the discovery of sporesilk elucidates a crucial molecular mechanism by which Bt maximizes its entomopathogenic efficiency. By stabilizing the spatial organization of spores and toxins into resilient infectious units, this protein fiber network ensures effective delivery and persistence, marking a milestone in microbial structural biology and applied environmental science. This work sets the stage for innovative biopesticide development and sustainable agricultural biotechnology.

Subject of Research: Cells

Article Title: Auto-crosslinking sporesilk fibers promote endospore and Cry toxin clustering

News Publication Date: 19 May 2026

Web References:
DOI: 10.1038/s41467-026-70495-z

Keywords

Bacillus thuringiensis, biopesticide, sporesilk, protein fibers, molecular net, Cry toxin, entomopathogen, nanofibers, self-assembly, structural biology, sustainable agriculture, microbial pathogenesis

Tags: Bacillus thuringiensis mechanismbiological pest control innovationBt toxin and spore synergyeco-friendly pest managementenvironmental safety of biopesticidesinsect larvae targeted biopesticidesnanotech-enhanced natural pesticidesnanotechnology in biopesticidesresilience in biopesticide engineeringselective pest control agentssporesilk fibrous proteinsustainable agriculture biopesticides

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