Metal-tolerant morganella morganii isolates can potentially mediate nickel stress tolerance in Arabidopsis by upregulating antioxidative enzyme activities.

Plant signaling & behavior Pub Date : 2024-12-31 Epub Date: 2024-03-25 DOI:10.1080/15592324.2024.2318513
Tahir Naqqash, Aeman Aziz, Muhammad Baber, Muhammad Shahid, Muhammad Sajid, Radicetti Emanuele, Abdel-Rhman Z Gaafar, Mohamed S Hodhod, Ghulam Haider
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Abstract

Plant growth-promoting rhizobacteria (PGPRs) have been utilized to immobilize heavy metals, limiting their translocation in metal contaminated settings. However, studies on the mechanisms and interactions that elucidate how PGPRs mediate Nickel (Ni) tolerance in plants are rare. Thus, in this study we investigated how two pre-characterized heavy metal tolerant isolates of Morganella morganii (ABT9 and ABT3) improve Ni stress tolerance in Arabidopsis while enhancing its growth and yield. Arabidopsis seedlings were grown for five weeks in control/Ni contaminated (control, 1.5 mM and 2.5 mM) potted soil, in the presence or absence of PGPRs. Plant growth characteristics, quantum yield, and antioxidative enzymatic activities were analyzed to assess the influence of PGPRs on plant physiology. Oxidative stress tolerance was quantified by measuring MDA accumulation in Arabidopsis plants. As expected, Ni stress substantially reduced plant growth (shoot and root fresh weight by 53.25% and 58.77%, dry weight by 49.80% and 57.41% and length by 47.16% and 64.63% over control), chlorophyll content and quantum yield (by 40.21% and 54.37% over control). It also increased MDA content by 84.28% at higher (2.5 mM) Ni concentrations. In contrast, inoculation with M. morganii led to significant improvements in leaf chlorophyll, quantum yield, and Arabidopsis biomass production. The mitigation of adverse effects of Ni stress on biomass observed in M. morganii-inoculated plants was attributed to the enhancement of antioxidative enzyme activities compared to Ni-treated plants. This upregulation of the antioxidative defense mechanism mitigated Ni-induced oxidative stress, leading to improved performance of the photosynthetic machinery, which, in turn, enhanced chlorophyll content and quantum yield. Understanding the underlying mechanisms of these tolerance-inducing processes will help to complete the picture of PGPRs-mediated defense signaling. Thus, it suggests that M. morganii PGPRs candidate can potentially be utilized for plant growth promotion by reducing oxidative stress via upregulating antioxidant defense systems in Ni-contaminated soils and reducing Ni metal uptake.

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耐金属的摩根菌分离物可能通过上调抗氧化酶活性来介导拟南芥对镍胁迫的耐受性。
植物生长促进根瘤菌(PGPRs)被用来固定重金属,限制重金属在金属污染环境中的转移。然而,有关植物生长促进根瘤菌如何介导植物耐受镍(Ni)的机制和相互作用的研究却很少见。因此,在本研究中,我们调查了摩根氏摩根菌(ABT9 和 ABT3)的两种预先定性的重金属耐受分离物如何改善拟南芥对镍胁迫的耐受性,同时提高其生长和产量。拟南芥幼苗在对照/镍污染(对照、1.5 毫摩尔和 2.5 毫摩尔)的盆栽土壤中生长了五周,无论是否存在 PGPRs。分析了植物生长特性、量子产量和抗氧化酶活性,以评估 PGPRs 对植物生理的影响。通过测量拟南芥植物体内 MDA 的积累,对其氧化胁迫耐受性进行了量化。正如预期的那样,镍胁迫大大降低了植物的生长(与对照相比,芽和根的鲜重分别减少了 53.25% 和 58.77%,干重分别减少了 49.80% 和 57.41%,长度分别减少了 47.16% 和 64.63%)、叶绿素含量和量子产量(与对照相比,分别减少了 40.21% 和 54.37%)。在镍浓度较高(2.5 mM)时,MDA 含量也增加了 84.28%。与此相反,接种摩根菌可显著提高叶片叶绿素、量子产量和拟南芥生物量产量。与镍处理植物相比,接种摩根菌的植物减轻了镍胁迫对生物量的不利影响,这归因于抗氧化酶活性的增强。这种抗氧化防御机制的上调减轻了镍引起的氧化应激,从而提高了光合机械的性能,进而提高了叶绿素含量和量子产量。了解这些耐受性诱导过程的基本机制将有助于全面了解 PGPRs 介导的防御信号转导。因此,这表明 M. morganii PGPRs 候选者有可能通过上调镍污染土壤中的抗氧化防御系统和减少镍金属吸收来降低氧化胁迫,从而促进植物生长。
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