AI Article Synopsis
- Quercus suber L., or cork oak, has been studied primarily for its cork layers, while its roots, which are susceptible to pathogens, have been less focused on.
- The research highlights the role of suberin in the roots, which acts as a protective barrier against water, ions, and pathogen infiltration, with the first deposits found in the endoderm Casparian strips.
- Using advanced microscopy techniques, the study demonstrates that suberin's structure varies in different root tissues depending on their maturity and function, revealing complex biochemical processes involved in root development and defense.
Article Abstract
Quercus suber L. has been investigated with special attention to the stem bark and its cork formation layer, but excluding the roots. Roots are the location of infection by pathogens such as Phytophthora cinnamomi responsible for the tree's sudden death. It is widely accepted that suberin establishes boundaries within tissues, serves as a barrier against free water and ion passage, and works as a shield against pathogen attacks. We followed the suberization of young secondary roots of cork oak. The first suberin deposition detectable by transmission electron microscopy (TEM) and neutral red (NR) was in the endoderm Casparian strips. Casparian strips are not detected by Sudan red 7B and Fluorol yellow (FY) that specifically stain lamellae suberin. Reaction to Sudan was verified in the endodermis and later on in phellem cells that resulted from the phellogen. Under TEM, the Sudan and FY-stained cells showed clear suberin lamellae while the newer formed phellem cells displayed a distinct NR signal compared to the outermost phellem cells. We concluded that suberin chemical components are arranged differently in the cell wall according to the physiological role or maturation stage of a given tissue.
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| http://dx.doi.org/10.1017/S1431927613000287 | DOI Listing |
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