Heat shock protein and Cathepsin B genes play important roles in cadmium stress response in whitefly Bemisia tabaci

Dec 10, 2025The Science of the total environment

Heat Shock Protein and Cathepsin B Genes Help Whiteflies Respond to Cadmium Stress

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Regenerative Health on OpenScience ↗PubMed ↗DOI ↗

Abstract

Cadmium exposure increased oviposition in Bemisia tabaci females by 47.97-57.09% while reducing egg hatchability by -34.94%.

Cadmium significantly decreased the abundance of the beneficial endosymbiont Rickettsia to 13.38% of control levels.
Pathological effects included nuclear pyknosis in tissue cells following cadmium exposure.
Transcriptome profiling identified 529 differentially expressed genes related to stress response.
Silencing the heat shock protein gene (BtHSP) increased mortality rates in healthy adults by 2.57-fold.
Knockdown of cysteine cathepsin gene (BtCTSB) reduced mortality from cadmium toxicity by 63.27% and alleviated cellular damage.
Both BtHSP and BtCTSB silencing enhanced oviposition by +77% and +67%, respectively.

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Cadmium, a highly toxic heavy metal pollutant, rapidly accumulates and persists in organisms including the globally distributed agricultural pest Bemisia tabaci. While previous studies established that cadmium exposure increases whitefly mortality and reduces abundance of the beneficial endosymbiont Rickettsia, the underlying mechanisms remain poorly characterized. This study reveals cadmium's effects on Bemisia tabaci: cadmium stress significantly stimulated oviposition in B. tabaci females (+47.97-57.09 %) but markedly reduced egg hatchability (-34.94 %, p < 0.01) and Rickettsia abundance (13.38 % of controls, p < 0.01), concurrently inducing pathological nuclear pyknosis in tissue cells. Transcriptome profiling identified 529 differentially expressed genes, with enrichment analyses revealing pronounced regulation of heat shock protein genes (BtHSP/BtHSP) and cysteine cathepsin genes (BtCTSB/BtCTSB). Targeted RNAi silencing demonstrated that BtHSPknockdown significantly increased mortality in healthy adults (2.57-fold vs. dsEGFP controls, p < 0.01) and exacerbated cadmium-induced mortality and nuclear pyknosis. Conversely, BtCTSBsilencing conferred protection against cadmium toxicity, reducing mortality by 63.27 % (p < 0.01) and alleviating cellular damage. Notably, BtHSPand BtCTSBsilencing specifically enhanced oviposition (+77 % and +67 % respectively, p < 0.05). These results establish BtHSPas a cadmium-sensitivity factor and BtCTSBas a cadmium-resistance determinant, revealing their antagonistic roles in stress response and suggesting novel RNAi-based strategies for whitefly control in cadmium-contaminated agroecosystems. ENVIRONMENTAL IMPLICATION: Heavy metal pollution is detrimental to the health of humans and ecosystems. Heavy metals can accumulate in insects through the food chain and food web, poisoning them and impacting pest control strategies in farmland. This study uncovers the biological and physiological impacts of exposure to the heavy metal cadmium on the broadly distributed agriculture pest Bemisia tabaci. By elucidating key molecular responses, this research paves the way for RNAi-based strategies to control whiteflies in contaminated agricultural environments, highlighting the interconnected challenges of pollution control and sustainable pest management. 1 2 1 2 1 2 2 1 1 2

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Heat shock protein and Cathepsin B genes play important roles in cadmium stress response in whitefly Bemisia tabaci

Abstract

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