Molybdenum Supply Alleviates the Cadmium Toxicity in Fragrant Rice by Modulating Oxidative Stress and Antioxidant Gene Expression.

Muhammad Imran,Mouloumdema Pouwedeou Potcho,Mohamed A El-Esawi,Imran Ali Rajput,Umair Ashraf,Muhammad Riaz,Saddam Hussain,Meiyang Duan,Muhammad Hamzah Saleem,Muhammad Shoaib Rana,Xiangru Tang

doi:10.3390/biom10111582

Abstract

Increasing evidence shows that cadmium (Cd) toxicity causes severe perturbations on growth performance, physio-biochemical and molecular processes in crop plants. Molybdenum (Mo), an essential trace element, plays key roles in oxidative stress tolerance of higher plants. Hence, the present study has been conducted to investigate the possible role of Mo in alleviating Cd-induced inhibitions in two fragrant rice cultivars namely Guixiangzhan (GXZ) and Meixiangzhan-2 (MXZ-2). The results revealed that Mo application enhanced the plant dry biomass by 73.24% in GXZ and 58.09% in MXZ-2 under Cd stress conditions, suggesting that Mo supplementation alleviated Cd-induced toxicity effects in fragrant rice. The enhanced Cd-tolerance in fragrant rice plants prompted by Mo application could be ascribed to its ability to regulate Cd uptake and reduce Cd-induced oxidative stress as evident by lower hydrogen peroxide levels, electrolyte leakage and malondialdehyde contents in Cd-stressed plants. The ameliorative role of Mo against Cd-toxicity also reflected through its protection to the photosynthetic pigments, proline and soluble protein. Mo also induced antioxidant defense systems via maintaining higher contents of glutathione and ascorbate as well as enhancing the ROS-detoxifying enzymes such as catalase, peroxidase, superoxide dismutase and ascorbate peroxidase activities and up-regulating transcript abundance in both fragrant rice cultivars under Cd stress. Conclusively, Mo-mediated modulation of Cd toxicity in fragrant rice was through restricting Cd uptake, maintaining photosynthetic performance and alleviating oxidative damages via the strong anti-oxidative defense systems; however, GXZ cultivar is comparatively more Cd tolerant and Mo-efficient as evident from the less growth inhibition and biomass reduction as well as enhanced Mo-induced Cd stress tolerance and less oxidative damage than MXZ-2 fragrant rice cultivar.

Highlights

Agricultural sustainability, food production and crop productivity are not safe due to the persistent accumulation of heavy metals in soil profiles
HoweEvLebr,yc1o4m1.6p6a%readnwd i1t4h6.M74o%+, reCsdpe−cttirveealytm, iennGt,XlZowanedr rMisXeZu-2ndriecre csoeemdlbiningesd(F(iMguore+3)C. dH+o)wseuvperp, ly in H2O2cocomnptaernetds w(3i5th.89M%o+aCndd- 6tr1e.a9t2m%e)n,tM, loDwAercorinseteunntsde(2r3c.o0m1%binaendd(4M7o.4+5C%d+) )asnudpEplLy (i2n5H.323O%2 caonndte3n9ts.97%), respe(c3t5i.v8e9l%y,ainndG61X.9Z2%an),dMMDAXZco-2ntfernatgs r(2a3n.t01r%iceansdee4d7.l4in5%gs) ainnddiEcLat(e2s5.t3h3a%t aMndo 3h9a.9s7a%)s,irgensipfieccatinvetlryo, le in ameliionrGatXinZganCddMtoXxZic-2itfyraignrafrnatgrricaenstereidclei.ngs indicates that Mo has a significant role in ameliorating Cd toxicity in fragrant rice
Mo − Cd+ treatment severely hampered plant growth attributes in terms of plant height and biomass accumulations in both rice cultivars; the inhibition was more noticeable in MXZ-2 than GXZ cultivar (Table 2), and the reason might be GXZ cultivar is more resistant to Cd stress because it is well established that the production of plant biomass is an important indicator for evaluating plant tolerance to heavy metal stress [36]

Summary

Introduction

Agricultural sustainability, food production and crop productivity are not safe due to the persistent accumulation of heavy metals (non-essential plant elements) in soil profiles. Such polluted soils with various heavy metal pools have decreased plant growth by affecting the different physiological, biochemical and molecular pathways [1,2]. Previous studies have revealed that absorption, aggregation and transfer of micro- and macro-nutrients to various plant parts have been significantly affected by Cd toxicity [9,10,11] These interferences between Cd and other essential macro/micronutrients could be due to some kind of molecular rivalry in nutrient uptake channels or in plant metal transporters [10]

Methods

Results

Discussion

Conclusion