# Ultrasound treatment enhances tomato drought resistance from germination to seedling stage

**Authors:** António Nogueira, António Teixeira, Joana Martins, Hernâni Gerós, Hélder Puga

PMC · DOI: 10.3389/fpls.2026.1738812 · Frontiers in Plant Science · 2026-02-10

## TL;DR

Ultrasound treatment improves tomato seed germination and seedling growth under drought stress by boosting antioxidant activity and reducing damage.

## Contribution

Ultrasound-assisted seed treatment is introduced as a novel, eco-friendly method to enhance drought resistance in tomato plants.

## Key findings

- Ultrasound treatment increased germination percentage by up to 34% under high osmotic stress.
- Seedling vigor and chlorophyll content improved by up to 50% with ultrasound treatment.
- Ultrasound boosted antioxidant enzyme activity and reduced oxidative damage in seedlings.

## Abstract

Drought stress poses a major threat to tomato seed germination and early seedling growth. These critical stages for the establishment of a successful crop are compromised by drought, which disrupts water uptake, impairs metabolic functions, and induces oxidative damage. As a cornerstone of global agriculture, tomato (Solanum lycopersicum) is increasingly vulnerable to these environmental pressures during its early development stages. With climate change amplifying the frequency and intensity of droughts, these challenges are growing, thereby threatening agricultural productivity worldwide. This study investigates the efficacy of ultrasound-assisted seed treatment as a novel strategy to mitigate drought effects, using osmotic stress induced by D-mannitol (ranging from 0 to –0.75 MPa). Tomato seeds were treated with multifrequency and multimode ultrasound technology (19.8 kHz, 200 W, 7.5 min) and evaluated for germination, seedling vigor, and biochemical responses under controlled conditions. Results demonstrate that ultrasound significantly enhances the germination percentage (up to 34% at –0.75 MPa) and seedling emergence (up to 36% at –0.50 MPa), while reducing germination time by up to 17% under high osmotic stress (–0.50 and –0.75 MPa). Moreover, ultrasound significantly increased the seedling vigor index I and chlorophyll content (up to 50% at −0.50 MPa). Superoxide dismutase and catalase activity in seeds increased by up to 45% and 77%, respectively, with similar values observed in seedlings. Total antioxidant activity (DPPH, ABTS, FRAP) increased in seeds and seedlings by up to 70% (under all conditions). Ultrasound-treated seeds exhibited elevated malondialdehyde (MDA) levels (up to 31% at –0.75 MPa), indicating an initial mechanical stress, while the resulting seedlings showed a reduction of MDA in all conditions (up to 48%), suggesting enhanced membrane stability over time. Principal component analysis and correlation analysis revealed distinct physiological and biochemical trait variations, with ultrasound effects more pronounced in seedlings. These findings highlight ultrasound’s potential to activate adaptive mechanisms, counteracting drought-induced oxidative damage and improving early plant performance. This scalable, eco-friendly technique offers a promising alternative to conventional priming methods.

## Linked entities

- **Proteins:** Cat (Catalase)
- **Chemicals:** D-mannitol (PubChem CID 453), malondialdehyde (PubChem CID 10964), ABTS (PubChem CID 35688)
- **Species:** Solanum lycopersicum (taxon 4081)

## Full-text entities

- **Genes:** peroxidase [NCBI Gene 543959], Catalase [NCBI Gene 543990], FESOD (iron superoxide dismutase) [NCBI Gene 544259] {aka Fe-SODle, sodb}, beta-amylase [NCBI Gene 100736451], LOX1.1 (lipoxygenase) [NCBI Gene 543994] {aka loxA, tomloxA}, alpha-amylase [NCBI Gene 101254670]
- **Diseases:** Drought (MESH:C536747), water (MESH:D000069578)
- **Chemicals:** gibberellin (MESH:D005875), thiobarbituric acid (MESH:C029684), sodium carbonate (MESH:C005686), 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (MESH:C002502), Lipid (MESH:D008055), CO2 (MESH:D002245), Carotenoid (MESH:D002338), glutathione (MESH:D005978), D-mannitol (MESH:D008353), 2,4,6-tri(2-pyridyl)-s-triazine (MESH:C002849), water (MESH:D014867), hydroxyl radicals (MESH:D017665), ROS (MESH:D017382), folic acid (MESH:D005492), b (MESH:D001895), PEG (MESH:C000595216), flavonoid (MESH:D005419), ascorbate (MESH:D001205), membrane lipid (MESH:D008563), hydrochloric acid (MESH:D006851), polyvinylpyrrolidone (MESH:D011205), sodium acetate (MESH:D019346), Chl b (MESH:C037184), oxygen (MESH:D010100), salicylic acid (MESH:D020156), sodium phosphate (MESH:C018279), sugars (MESH:D000073893), gibberellic acid (MESH:C007842), phosphorus (MESH:D010758), potassium (MESH:D011188), ABA (MESH:D000040), melatonin (MESH:D008550), methanol (MESH:D000432), Trolox (MESH:C010643), H2O2 (MESH:D006861), L-methionine (MESH:D008715), Chl a (-), superoxide anions (MESH:D013481), carbon (MESH:D002244), potassium persulfate (MESH:C009007), carbohydrate (MESH:D002241), MDA (MESH:D008315), fatty acids (MESH:D005227), 1,1-diphenyl-2-picrylhydrazyl (MESH:C004931), trichloroacetic acid (MESH:D014238), Chlorophyll (MESH:D002734), agar (MESH:D000362), riboflavin (MESH:D012256), starch (MESH:D013213), FeCl3 (MESH:C024555), EDTA (MESH:D004492), isoflavones (MESH:D007529), nitrogen (MESH:D009584), amino acids (MESH:D000596), NBT (MESH:D009580)
- **Species:** Oryza sativa (Asian cultivated rice, species) [taxon 4530], Lolium arundinaceum (tall fescue, species) [taxon 4606], Brassica oleracea (wild cabbage, species) [taxon 3712], Bacillus thuringiensis (species) [taxon 1428], Ricinus communis (castor bean, species) [taxon 3988], Glycine max (soybean, species) [taxon 3847], Elymus (wild rye, genus) [taxon 15492], Solanum lycopersicum (tomato, species) [taxon 4081], Powellomyces sp. EA (species) [taxon 252690], Trigonella foenum-graecum (fenugreek, species) [taxon 78534], Homo sapiens (human, species) [taxon 9606]

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## References

73 references — full list in the complete paper: https://tomesphere.com/paper/PMC12930468/full.md

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Source: https://tomesphere.com/paper/PMC12930468