Whole-genome identification and expression characterization of the HSFP gene family of Triticum aestivum under heat and drought stress.

Comprehensive evaluation and physiological responses of 20 table grape varieties to sole and combined salt and drought stress.

Glutamine amidotransferase MdALI positively regulates apple drought tolerance by modulating amino acid metabolism.

Establishment of Physalis grisea genetic transformation system and overexpression of AtPAP1 enhances drought stress.

A non-specific lipid transfer protein gene HcnsLTP111 positively regulates drought and salt stress tolerance in kenaf (Hibiscus cannabinus L.).

Zanthoxylum armatum HD-ZIP II transcription factor ZaHB15 induces flowering and negatively regulates plant growth and drought tolerance.

Abiotic stress adaptation of the xerophyte Zygophyllum xanthoxylum is mediated by regulation of potassium homeostasis.

OsPP2C03 positively regulates rice drought stress resistance through a non-canonical ABA pathway.

Determining the dynamic response of maize to compound low-temperature and drought stress

Response of mature Norway spruce to experimental thermal and drought stress in relation to Ips typographus attack: Crown temperatures and sap flow

HvABI5 is an important ABA-dependent regulator of drought stress response at heading time in barley.

Corrigendum to “Whole-genome identification and expression characterization of the HSFP gene family of Triticum aestivum under heat and drought stress” [Plant Sci. 362 (January) (2026) 112780

Genotype-Specific Regulation of Dhurrin Metabolism Under Drought Stress in Sorghum.

Heterologous expression of Carex rigescens PDC1 enhances salt tolerance in transgenic Arabidopsis thaliana seedlings.

Genome-wide identification of LAC and CAD gene family and the function of lignin biosynthesis by co-expressed PsiLAC8-PsiCAD5 module in Populus simonii.

Alleviating drought and heat stress: a root-canopy coordination irrigation strategy synergistically elevating grapevine yield, quality, and water productivity

Genome-wide identification and evolution dynamics of the PLATZ gene family under drought and parasitic stress conditions in sunflowers (Helianthus annuus L.)

Plant drought stress: physiological, biochemical and molecular mechanisms

High salt tolerance and salt-mediated enhancement of drought stress tolerance in Zygophyllum fabago

ABSTRACT Physiologically, salinity causes osmotic stress due to high solute concentration in soil and disturbs the metabolic and photosynthetic activity of the cells by increasing the toxicity of Na+ in the cytoplasm. Plant adaptation to salt stress is characterized by cellular ion homeostasis and vacuolar sequestration of toxic ions from cytosol mediated by H+-pyrophosphatase (H + -PPase). The LfVP1 gene was cloned under the control of the Gal1 promoter for yeast transformation and the CaMV35S promoter for tobacco transformation. Yeast supplementation assay demonstrated that ena1 and ena1:nhx1 yeast mutants, transformed with LfVP1 genes, could only be able to partially complement the effect of NaCl and hygromycin in the presence of a functional Na+/H+ antiporter gene. Transgenic tobacco plants transformed with the LfVP1gene had significantly higher photosynthetic levels, stomatal conductivity, relative water content, membrane stability index, and negative osmotic potential under osmotic stress compared to wild-type plants (WT). Seeds of the transgenic line LfVP1-PB4 (single gene insertion) and WT were germinated on the MS0 medium supplemented with 200 and 250 mM NaCl. Transgenic plants showed better growth and tolerance to salinity stress than WT plants. Our findings indicate that the overexpressing LfVP1 gene has a potential role in enhancing the abiotic stress tolerance in crops such as rice, wheat, and maize.