Agronomic biofortification and nutrient uptake of sorghum (Sorghum biochor L.) as influenced by fertilization strategies

Markole, Sharad Kumar; Suresh, K.; Madhavi, A.; Shanti, M.

doi:10.22271/chemi.2020.v8.i3ad.9520

Cited by 4 publications

(2 citation statements)

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“…The increase in these traits of particular accessions might be due to its genetic makeup where the basal and foliar application of Zn, Fe and Se imparts significant effects on plant height and stem diameter of sorghum. The response of different sorghum genotypes to Zn application also varied in previous studies (Markole et al 2020). However, among the treatments, Se recorded the maximum plant height, and stem diameter may be due to timely availability and efficient utilisation of Se and other nutrients (Witold et al 2008) that improved the catalytic action in plant and also resulted in early plant maturity.…”

Section: Original Papermentioning

confidence: 87%

Agronomic bio-fortification of iron, zinc and selenium enhance growth, quality and uptake of different sorghum accessions

Qureshi¹,

Ahmad²,

Iqbal³

et al. 2021

Plant Soil Environ.

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Agronomic bio-fortification is one of the main approaches for mitigation of micronutrient shortage in human populations and endorses sustainable production of food and feed. Studies related to agronomic bio-fortification of crops are mainly focused on single or rarely two micronutrients application, and no attempt has made to study the combined effect of zinc (Zn), iron (Fe) and selenium (Se) on forage sorghum. Therefore, this research was accomplished to evaluate the effect of Zn, Fe and Se bio-fortification on diverse sorghum accessions. The field experiments were conducted in a randomised complete block design with a split-plot arrangement. The treatments comprised of Zn (10 mg/L as ZnSO4∙5H2O), Fe (7 mg/L as FeSO4∙7H2O), Se (3 mg/L as SeSO4) and CK (control) were applied to five sorghum accessions: G1 (Y-16), G2 (YSH-166), G3 (YSH-134), G4 (YSS-98) and G5 (YSH-132). According to our results, the sorghum accession G5 showed superiority over all other accessions and produced maximum values of all growth and quality traits except grains number per panicle and 1 000-grain weight. All applied micronutrients (Zn, Fe and Se) enhanced the growth, quality and uptake of nutrients in sorghum accessions. However, Se recorded the highest plant height, stem diameter, 1 000-grain weight and Zn produced the maximum protein, oil and starch contents. Conclusively, it can be concluded that G5 with Se must be used to achieve the optimum values of agronomic traits, while G5 with Zn found more effective to improve the quality traits of sorghum.

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Section: Original Papermentioning

confidence: 87%

Agronomic bio-fortification of iron, zinc and selenium enhance growth, quality and uptake of different sorghum accessions

Qureshi¹,

Ahmad²,

Iqbal³

et al. 2021

Plant Soil Environ.

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“…This result was confirmed by the findings of Yuan et al (2013) [10] . There was a difference in grain Zn concentration among the genotypes and this may be due to the difference in loading ability of Zn from the panicle tissues to the grains (Markole et al, 2020) [11] .…”

Section: Whole Rice Grainsmentioning

confidence: 99%

Agronomic biofortification of zinc in different rice genotypes

Sudha¹

2020

Int. J. Chem. Stud.

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Zinc deficiency in soils and plants is a global micronutrient deficiency problem reported in many countries. Zinc deficiency can be corrected by enriching the food grains through fertilizer application to the plant in both soil and foliar method. A field experiment on agronomic biofortification with zinc in rice was carried out during thaladi season of 2013-14 and 2014-15 at Tamil Nadu Agricultural University, Coimbatore. The experiment was laid out in split plot design with three replications consisted of two zinc levels (-Zn and +Zn, 100 kg ZnSO4. 7 H2O ha -1 plus foliar spray @0.5%) in main plot and 18 rice genotypes in subplot. Soil and foliar application of zinc significantly increased the grain and straw yield and also the zinc concentration in processed rice grains. Based on the zinc concentration in processed rice the genotype Co43, Improved white ponni, ADT 38 and TRY 1 showed higher response for zinc application.

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