Abstract

In the present experiment, Zea mays L. was evaluated for its C4 modality through oxidative stress responses. Moreover, under variable concentrations (0, 50, 100µM) of hydrogen peroxide, the impacts were variable and modulated with titanium dioxide nanoparticle (TiO2-NP). Plants scored with elevated concentrations of H2O2 and superoxide (O2.-) maximum by 1.31 & 1.52-fold respectively over 0µM H2O2. TiO2-NP recovered those maximums with 8.69 & 7.89% as compared to control plants. The effects of H2O2 were moderated with malondialdehyde and carbonyl content by peak values 7.45 & 5.91% under TiO2-NP treatment respectively. A depletion in proline content recorded under H2O2 stress but recovered through highest 1.23-fold with TiO2-NP application. TiO2-NP recorded NADP-ME activities up-regulated in concentration gradient of H2O2. Oxidative exposure was also documented by in-vivo detection of H2O2 and O2.- by 3,3′-diaminobenzidine and nitroblue tetrazolium staining. For the anti-oxidative cascades superoxide dismutase activity had induced by 1.42-fold under H2O2 when pre-treated with TiO2-NP. However, glutathione reductase activity was differentially modulated under H2O2 through interaction with TiO2-NP. Activity of guaiacol peroxidase was significantly up-regulated by 1.07-fold when TiO2-NP applied. The inductions of oxidative stress recorded more evident when a distinct polymorphism for GPX protein resolved variations in band intensities, but not in number. Activity of catalase experience a down-regulated trend all through the H2O2 exposure and had significant sensitivity to TiO2-NP. The results depict the nature and reactivity of C4 modules under oxidative stress that would be the selection pressures and that might be modulated with TiO2-NP application.