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Phytoremediation through microstructural and functional alterations in alkali weed (Cressa cretica L.) in the hyperarid saline desert.

Authors :
Naz, Nargis
Asghar, Ansa
Basharat, Sana
Fatima, Sana
Hameed, Mansoor
Ahmad, Muhammad Sajid Aqeel
Ahmad, Farooq
Shah, Syed Mohsan Raza
Ashraf, Muhammad
Source :
International Journal of Phytoremediation; 2024, Vol. 26 Issue 6, p913-927, 15p
Publication Year :
2024

Abstract

Salt excretory halophytes are the major sources of phytoremediation of salt-affected soils. Cressa cretica is a widely distributed halophyte in hypersaline lands in the Cholistan Desert. Therefore, identification of key physio-anatomical traits related to phytoremediation in differently adapted C. cretica populations was focused on. Four naturally adapted ecotypes of non-succulent halophyte Cressa cretica L. form hyper-arid and saline desert Cholistan. The selected ecotypes were: Derawar Fort (DWF, ECe 20.8 dS m<superscript>−1</superscript>) from least saline site, Traway Wala Toba (TWT, ECe 33.2 dS m<superscript>−1</superscript>) and Bailah Wala Dahar (BWD, ECe 45.4 dS m<superscript>−1</superscript>) ecotypes were from moderately saline sites, and Pati Sir (PAS, ECe 52.4 dS m<superscript>−1</superscript>) was collected from the highly saline site. The natural population of this species was collected and carefully brought to the laboratory for different structural and functional traits. As a result of high salinity, Na<superscript>+</superscript>, Cl<superscript>–</superscript>, K<superscript>+</superscript>, and Ca<superscript>2+</superscript> content significantly increased at root and shoot level. At root level, some distinctive modifications such as increased sclerification in vascular bundles, enlarged vascular bundles, metaxylem vessels, phloem region, and storage parenchyma (cortex) are pivotal for water storage under extreme arid and osmotic condition. At the stem level, enhanced sclerification in outer cortex and vascular bundles, stem cellular area, cortical proportion, metaxylem and phloem area, and at the leaf level, very prominent structural adaptations were thicker and smaller leaves with increased density of salt glands and trichomes at surface, few and large stomata, reduced cortical and mesophyll parenchyma, and narrow xylem vessels and phloem area represent their non-succulent nature. The ecotype collected from hypersaline environments was better adapted regarding growth traits, ion uptake and excretion, succulence, and phytoremediation traits. More importantly, structural and functional traits such as root length and biomass, accumulation of toxic ions along with K<superscript>+</superscript> in root and shoot, accumulation of Ca<superscript>2+</superscript> in shoot and Mg<superscript>2+</superscript> in root, excretion of toxic ions were the highest in this ecotype. In conclusion, all these alterations strongly favor water conservation, which certainly contributes to ecotypes survival under salt-induced physiological drought. Naturally adapted salt tolerant plants provide exceptional material for exploring adaptive mechanisms they use to confront high salt concentrations. Cressa cretica is a hypersaline hyperarid desert colonizer, which was previously underexplored. In the present study, we focused on the new insight on relationship among anatomical modifications, salt accumulation and excretion and phytoremediation potential of this rare species. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
15226514
Volume :
26
Issue :
6
Database :
Complementary Index
Journal :
International Journal of Phytoremediation
Publication Type :
Academic Journal
Accession number :
176695293
Full Text :
https://doi.org/10.1080/15226514.2023.2282044