Anatomical and chemical characteristics of foliar vascular bundles in four reed ecotypes adapted to different habitats

Abstract

We investigated the anatomical and chemical characteristics of the foliar vascular bundles in four ecotypes of common reed ( Phragmites communis Trin.) inhabiting the desert region of northwest China: swamp reed (SR), low-salt meadow reed (LSMR), high-salt meadow reed (HSMR), and dune reed (DR). The cell walls of the vascular systems of all four ecotypes exhibited bright autofluorescence. Compared to SR, the three terrestrial ecotypes, LSMR, HSMR and DR, had higher percentages of bundle sheath cell areas, lower percentages of xylem and phloem areas, lower xylem/phloem ratios, and higher frequencies of leaf veins. In addition to differences in the autofluorescence intensity and the morphology of the detached cell walls of the vascular bundle sheath, the three terrestrial ecotypes also exhibited anatomical differences in the outerface tangential walls of the bundle sheath and higher frequencies of pit fields in the walls in comparison to SR. The Fourier transform infrared (FTIR) microspectroscopy spectra of the vascular bundle cell walls differed greatly among the tissues of the different ecotypes as well as within different tissues within each ecotype. Histochemical methods revealed that although pectins were present in all bundle tissue cell walls, large amounts of unesterified pectin were present in the phloem cell walls, especially in the salt reed ecotypes LSMR and HSMR, and large quantities of highly methyl-esterified pectin were present in the xylem and sclerenchyma cell walls of the SR and DR ecotypes. Differences were observed in the lignification and suberization of the xylem and sclerenchyma cell walls of the four ecotypes, but the phloem and bundle sheath cell walls were generally similar. These results suggest that the adaptation of common reed, a hydrophytic species, to saline or drought-prone dunes triggers changes in the anatomical and chemical characteristics of the foliar vascular bundle tissues. These alterations, including higher percentages of bundle sheath areas and lower percentages of xylem and phloem areas and their ratios, changes in the chemical compositions and modifications of the cell walls of different vascular bundle tissues, and differences in the deposition of major cell wall components in the walls of different vascular bundle tissues, could contribute to the high resistance of reeds to extreme habitats such as saline and drought-prone dunes.