The Element Composition Strategies in Chenopodiaceae Halophytes Reveal Complex Plant-Soil Interactions in Saline-Alkali Grassland

Abstract

\n With the continuous increase of saline-alkali land, sustainable development of the global environment and ecology has been seriously affected. Chenopodiaceae is a pioneer plant family living in saline-alkali land, which plays a crucial role in sustaining the stability, composition and function of saline-alkali arid ecosystems. In this study, 11 elements were analyzed in different plant organs and rhizosphere soil of eight Chenopodiaceae species. Descriptive statistics of the leaf, stem and root element concentrations in eight halophyte species of contrasting salt tolerance types (salt-dilution halophytes and recretohalophytes) were calculated. Spearman’s rank correlation coefficients were used to compare the correlations of elements among the leaf, stem, root and soil property, as well as between the plant and soil. General linear model was employed to explore how the variance of element concentrations in leaves, stems and roots depends on salt tolerance type, soil salinity property and soil mineral elements. The results showed that salt tolerance type and soil mineral element concentrations explained most of the variation observed in element concentrations in Chenopodiaceae plants; the soil salinity property played only a minor role. It was concluded that the genetic factors are the prerequisite in the composition pattern of leaf elements in Chenopodiaceae, and soil factors are the key to determine element accumulation. These conclusions provide an effective reference for evaluating plant breeding and its response to environmental change in saline-alkali arid areas in Hulunbuir grassland and other parts of the world.