Nitric Oxide in Plants. Группа авторов

Nitric Oxide in Plants - Группа авторов


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(Deng et al. 2016). However, several studies have demonstrated the integrative role of brassinosteroids with NO in response to pathogen attack in various species (Hayat et al. 2010; Shi et al. 2015; Zou et al. 2018; Kohli et al. 2019).

      1.4 Nitric Oxide’s Role in Abiotic Stress

      Mackerness et al. (2001) demonstrated the involvement of NO in plant response to UV-B radiation, demonstrating poststress induction of chalcone synthase expression, a rise in NOS-type protein activity, and an increase in NO levels. According to the findings of Shi et al. (2005), NO positively shields plants against UV-B radiation, most likely through increased activity of the antioxidative system. NO-donor treatment of potato tubers prior to UV-B irradiation resulted in the development of approximately 50% more healthy leaves than plants not subjected to NO treatment (Neill et al. 2003). Exogenous NO has been shown to reduce the deleterious effects of heavy metals, ethylene, and herbicides on plants in response to alternative abiotic stresses (Kopyra and Gwóźdź 2003). The authors explained the protective effect as a result of NO-donor treatment of plant materials by the effect of NO on the elevation of activity of antioxidative enzymes, particularly SOD (Kopyra and Gwóźdź 2003).

      It is important to note that many types of abiotic stress (cold and heat stress, salt and drought stress) increase polyamine (PA) synthesis (Bouchereau et al. 1999). Tun et al. (2006) discovered that PAs significantly increase NO generation. Work on Arabidopsis seedlings confirms that NO acts as a channel between PA-mediated stress responses and an alternative stress mediator, with NO as a stepping stone.

      By scavenging ROS, NO plays a significant role in inhibitor defense against many abiotic stresses. Salinity stress has a negative impact on plant morphological traits and diffusion balance. Additionally, it promotes membrane disintegration, DNA damage, particle discharge, and death. NO has been shown to have a potential effect on diffusion stress tolerance as well as increased spermatophyte growth in rice, lupin, and cucumber when subjected to salt stress (Uchida et al. 2002; Kopyra and Gwóźdź 2003; Fan et al. 2007, 2013; Barakat et al. 2012). Similar evidence has been reported demonstrating the potential effect of NO in mitigating salinity stress in alfalfa, barley, jatropha, chickpea, and sunflower (Nabi et al. 2019). In Oryza sativa, a NO donor SNP inhibited accumulation, reduced ROS generation, and improved root growth (Kushwaha et al. 2019). In various plant species, the potential role of gas in mitigating serious metal toxicity has been investigated (Ahmad et al. 2018; Yuanjie et al. 2019; Bhuyan et al. 2020; Wei et al. 2020; Khator et al. 2021). As a result, it is clear that NO gas could be a potential mitigating agent for abiotic stresses.

      1.4.1 Crosstalk of Nitric Oxide with Other Phytohormones in Plants to Confer Abiotic Stress Tolerance

      NO is involved in advanced signal mechanisms, as well as synergistic collaboration with phytohormones and alternative secondary signal molecules, to confer stress tolerance in plants. NO has been linked to a variety of phytohormones, including gibberellins, brassinosteroids, and ABA. The interaction of NO with phytohormones has been studied in a variety of ways. NO and plant hormones work together to regulate a wide range of physiological responses in plants. By activating Ca2+ and calcium‐dependent protein kinase via downstream signals, NO and auxin promote root development (Pagnussat et al. 2002). Similarly, the interaction of NO and auxin promotes Cd tolerance in the rosid dicot genus Truncatula by reducing auxin degradation (Xu et al. 2010). Furthermore, there is a growing of evidence pointing to the effect of NO in reducing serious metal toxicity (He et al. 2012; Yuan and Huang 2016; Wei et al. 2020). Iron deficiency, on the other hand, stimulates the assembly of auxin and increases NO levels, thereby upregulating ferric-chelate enzyme activity in Arabidopsis.


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