Variations in Physiological and Biochemical Characteristics of Kalidium foliatum Leaves and Roots in Two Saline Habitats in Desert Region

Salt stress is a key environmental factor that has adverse effects on plant growth and development. High salinity induces a series of structural and functional changes in the morphological and anatomical features. The physiological and biochemical changes in K. foliatum in response to salt stress in...

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Published inForests Vol. 15; no. 1; p. 148
Main Authors Jiang, Lamei, Wu, Deyan, Li, Wenjing, Liu, Yuehan, Li, Eryang, Li, Xiaotong, Yang, Guang, He, Xuemin
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.01.2024
Subjects
Abiotic stress
Antioxidants
Biochemical characteristics
Biochemistry
Catalase
Chlorophyll
desert
Deserts
Environmental factors
Enzymes
Habitats
Kalidium foliatum
Leaves
Natural environment
Peroxidase
Physiological adaptation
Physiology
Plant growth
Plant tissues
Precipitation
Proline
Roots
Salinity
Salinity effects
Salt
salt stress
Salts
Sodium
Soils
Structure-function relationships
Superoxide dismutase
Thickness
Vegetation
Wetlands
Yeast
China
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Summary:Salt stress is a key environmental factor that has adverse effects on plant growth and development. High salinity induces a series of structural and functional changes in the morphological and anatomical features. The physiological and biochemical changes in K. foliatum in response to salt stress in natural environments are still unclear. Based on this, this study compared and analyzed the differences in the physiological and biochemical indicators between the leaf and root tissues in high-salt and low-salt habitats, selecting K. foliatum as the research object. The results showed that the chlorophyll contents in the leaves of K. foliatum decreased in the high-salt habitat, while the thicknesses of the upper and lower epidermises, as well as the thicknesses of the palisade tissue, significantly increased. The high-salt environment led to decreases in the N and P contents in the leaves and root tissues of K. foliatum, resulting in changes in the stoichiometric ratio of elements. The concentrations of C, N, and P in the roots of K. foliatum were lower than those in the leaves. The accumulation of Na+ in the K. foliatum roots was greater than that in the leaves, and the roots could promote the transport of sodium ions to the leaves. The contents of starch and soluble sugar in the leaves showed higher proportions in the high-salt habitat than in the low-salt habitat, while the changes in the roots and leaves were the opposite. As the salt content increased, the proline contents in the leaves and roots of K. foliatum significantly increased, and the proline contents in the roots of K. foliatum were lower than those in the leaves. The leaves and roots exhibited higher levels of peroxidase and superoxide enzymes in the high-salinity habitat than in the low-salinity habitat. The superoxide dismutase (SOD) activity of the K. foliatum leaves and catalase (CAT) activity of the roots were the “central traits” in the high-salt habitat. In the low-salt habitat, the leaf malondialdehyde (MDA) and root C/N were the central traits of the leaves and roots, indicating that K. foliatum adapts to changes in salt environments in different ways.
ISSN:1999-4907
1999-4907
DOI:10.3390/f15010148