کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
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1909151 | 1046709 | 2011 | 14 صفحه PDF | دانلود رایگان |
Salinity reduces Ca2+ availability, transport, and mobility to growing regions of the plant and supplemental Ca2+ is known to reduce salinity damages. This study was undertaken to unravel some of the ameliorative mechanisms of Ca2+ on salt stress at the cellular and tissue levels. Zea mays L. plants were grown in nutrient solution containing 1 or 80 mM NaCl with various Ca2+ levels. Measurements of growth and physiological parameters, such as ion imbalance, indicated that the Ca2+-induced alleviation mechanisms differed between plant organs. Under salinity, H2O2 levels increased in the leaf-growing tissue with increasing levels of supplemental Ca2+ and reached the levels of control plants, whereas superoxide levels remained low at all Ca2+ levels, indicating that Ca2+ affected growth by increasing H2O2 but not superoxide levels. Salinity completely abolished apoplastic peroxidase activity. Supplemental Ca2+ increased its activity only slightly. However, under salinity, polyamine oxidase (PAO) activity was shifted toward the leaf base probably as an adaptive mechanism aimed at restoring normal levels of reactive oxygen species (ROS) at the expansion zone where NADPH oxidase could no longer provide the required ROS for growth. Interestingly, addition of Ca2+ shifted the PAO-activity peak back to its original location in addition to its enhancement. The increase in PAO activity in conjunction with low levels of apoplastic peroxidase is supportive of cellular growth via nonenzymatic wall loosening derived by the increase in H2O2 and less supportive of the peroxidase-mediated cross-linking of wall material. Thus extracellular Ca2+ can modulate ROS levels at specific tissue localization and developmental stages thereby affecting cellular extension.
Journal: Free Radical Biology and Medicine - Volume 51, Issue 6, 15 September 2011, Pages 1221–1234