Salinity Alleviation and Reduction in Oxidative Stress by Endophytic and Rhizospheric Microbes in Two Rice Cultivars.
Amrita GuptaArvind Nath SinghRajesh Kumar TiwariPramod Kumar SahuJagriti YadavAlok Kumar SrivastavaSanjay KumarPublished in: Plants (Basel, Switzerland) (2023)
Increased soil salinity poses serious limitations in crop yield and quality; thus, an attempt was made to explore microbial agents to mitigate the ill effects of salinity in rice. The hypothesis was mapping of microbial induction of stress tolerance in rice. Since the rhizosphere and endosphere are two different functional niches directly affected by salinity, it could be very crucial to evaluate them for salinity alleviation. In this experiment, endophytic and rhizospheric microbes were tested for differences in salinity stress alleviation traits in two rice cultivars, CO51 and PB1. Two endophytic bacteria, Bacillus haynesii 2P2 and Bacillus safensis BTL5, were tested with two rhizospheric bacteria, Brevibacterium frigoritolerans W19 and Pseudomonas fluorescens 1001, under elevated salinity (200 mM NaCl) along with Trichoderma viride as an inoculated check. The pot study indicated towards the presence of variable salinity mitigation mechanisms among these strains. Improvement in the photosynthetic machinery was also recorded. These inoculants were evaluated for the induction of antioxidant enzymes viz. CAT, SOD, PO, PPO, APX, and PAL activity along with the effect on proline levels. Modulation of the expression of salt stress responsive genes OsPIP 1, MnSOD 1, cAPXa , CATa , SERF , and DHN was assessed. Root architecture parameters viz. cumulative length of total root, projection area, average diameter, surface area, root volume, fractal dimension, number of tips, and forks were studied. Confocal scanning laser microscopy indicated accumulation of Na + in leaves using cell impermeant Sodium Green™, Tetra (Tetramethylammonium) Salt. It was found that each of these parameters were induced differentially by endophytic bacteria, rhizospheric bacteria, and fungus, indicating different paths to complement one ultimate plant function. The biomass accumulation and number of effective tillers were highest in T4 ( Bacillus haynesii 2P2) plants in both cultivars and showed the possibility of cultivar specific consortium. These strains and their mechanisms could form the basis for further evaluating microbial strains for climate-resilient agriculture.
Keyphrases
- microbial community
- climate change
- oxidative stress
- escherichia coli
- high resolution
- poor prognosis
- stress induced
- dna damage
- diabetic rats
- heavy metals
- genome wide
- magnetic resonance
- risk assessment
- staphylococcus aureus
- wastewater treatment
- bacillus subtilis
- ischemia reperfusion injury
- magnetic resonance imaging
- signaling pathway
- dna methylation
- binding protein
- mass spectrometry
- induced apoptosis
- plant growth
- amyotrophic lateral sclerosis
- heat shock protein
- raman spectroscopy