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

Qureshi, Muhammad Tamoor; Ahmad, Muhammad Faizan; Iqbal, Nasır; Waheed, Hasnain; Hussain, S Z; Brestič, Marián; Anjum, Adeel; Noorka, Ijaz Rasool

doi:10.17221/137/2021-pse

Cited by 13 publications

(6 citation statements)

References 38 publications

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“…In this study, the decrease in Ca 2+ contents of shoot under salinity and combined treatments of NaCl in Faba bean might be attributable to the reduction in Ca 2+ availability and a limitation of Ca 2+ absorption and transport to growth tissue under salinity [62]. Zinc plays a significant role in chlorophyll synthesis, pollen function, and fertilization and stabilizes proteins, membranes, and DNA-binding proteins such as Zn fingers [63]. Moreover, the foliar application of ZnONPs treatments considerably enhanced the nutritional content of Sweet Basil Plant leaves, including N, P, K, Fe, Zn, and Cu, compared to control leaves [64].…”

Section: Discussionmentioning

confidence: 79%

Nanoparticle Treatments Based on Zinc Oxide and Moringa oleifera Leaf Extracts Alleviate Salinity Stress in Faba Bean (Vicia faba L.)

Ragab¹,

Losenge²,

Runo³

et al. 2022

JACEN

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Section: Discussionmentioning

confidence: 79%

Nanoparticle Treatments Based on Zinc Oxide and Moringa oleifera Leaf Extracts Alleviate Salinity Stress in Faba Bean (Vicia faba L.)

Ragab¹,

Losenge²,

Runo³

et al. 2022

JACEN

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“…[29] mentioned that silicon has a role in improving plant growth indicators, including leaf area, by reducing the influence of biotic and abiotic stress on the plant. Also, micronutrients could have a role in influencing the leaf area of the plant, as indicated by [30] that fertilizing with iron and zinc has a significant effect in increasing the leaf area of the sorghum plant. [31] indicated that fertilizing with zinc and boron led to an increase in the leaf area of the sorghum plant.…”

Section: Leaf Area (M 2 )mentioning

confidence: 99%

“…While the treatment of the sorghum variety has significantly affected the leaf area of the plant, the variety (C 2 ), which achieved a leaf area of 0.45 M 2 , outperformed the variety (C 1 ), which achieved a leaf area of 0.34 M 2 , and this may be due to the difference between the two varieties in their genetic characteristics [14]. The results of Table (3) also indicate that the interaction between leaching requirements and the fertilization treatment has significantly affected the leaf area of the plant, with the highest average of the leaf area being 0.50 m 2 for the interaction treatment (L 1 F 5 ) and the lowest average was 0.27 m 2 for the treatment (L 1 F 0 ), which may be due to the role of leaching requirements in reducing soil salinity [24], in addition to the impact of fertilization treatments, whether in improving soil properties, increasing plant resistance to Environmental stresses, or improving plant growth indicators [31,22,30,21,29]. The results of Table (3) also indicate that the interaction between the sorghum variety and the leaching requirements, and the interaction between the sorghum variety and fertilization treatment, and the triple interaction between the treatment of sorghum variety, leaching requirements, and fertilization treatment, did not have a significant effect on leaf area of the plant.…”

Section: Leaf Area (M 2 )mentioning

confidence: 99%

Tolerance of Two Sorghum Varieties to Salinity Using Different Nutritional Practices and Two Leaching Requirements

Hameed,

Ali,

Karim

2023

IOP Conf. Ser.: Earth Environ. Sci.

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A field experiment was conducted at the Ministry of Agriculture research station in Abu Ghraib district to investigate the role of using different nutritional practices and two leaching requirements on the tolerance of two sorghum varieties to salt stress during the spring season of 2022. The experiment was laid out in a randomized complete block design “RCBD” with a split-plot arrangement and three replicates. The treatments included Two Sorghum verities (Al-Khair synthetic variety (C1) and Rabeh synthetic variety (C2), Two leaching requirements (normal leaching requirements (L1) and doubled leaching requirements (L2) and 7 fertilizer treatments (Control, NPK, NPKS, NPKS+ micronutrients, NPKS+ micronutrients+ Nano silicon, NPKS+ micronutrients + Nano silicon + calcium and magnesium nitrate, NPKS + micronutrients + Nano silicon + potassium Humates), symbolized as (F0, F1, F2, F3, F4, F5, and F6), respectively. Results showed that applications of fertilizer treatments F5 and F6 had a significant impact on the growth indicators of the plant, where the highest average of plant height was 1.11 m and the highest average of leaf area was 0.48 m2 for treatment F5. The highest chlorophyll content was 85.43 (SPAD), the highest biological yield was 11373.6 kg ha−1, and the highest grain yield 5191.6 kg ha-1 was with treatment F6. Doubled leaching requirements (L2) exceeded the normal leaching requirements (L1) in some parameters, which led to an increase in the height and biological yield of the plant. The results showed a significant superiority of the sorghum variety (C2) over (C1) in the leaf area of 0.45 m2, as well as the biological yield of 11235.5 kg ha-1. The dual interactions have a significant effect on increasing plant height, leaf area, chlorophyll, biological yield, and grain yield. Triple interactions had a significant effect in increasing the height and grain yield of the plant. These results clearly showed that the proper management practices could be used to improve soil properties and increase the availability of nutrients and improve plant tolerance to abiotic stress such as soil salinity.

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“…A number of studies have shown the utility of agronomic biofortification with zinc for plant growth and development (Haslett et al, 2001, Sharma et al, 2013, Oliveira et al, 2020, productivity (Qureshi et al, 2021) and grain quality (Rashid, 1992;Dhaliwal et al, 2009). Zinc deficiency causes chlorosis in the leaves of plants.…”

Section: Introductionmentioning

confidence: 99%

The Zinc Agronomic Biofortification and Its Influence on Winter Wheat Productivity and Quality

AGAPIE¹,

HORABLAGA²,

Bostan³

et al. 2021

LSSD

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This study evaluates the influence of agronomic biofortification with zinc on the productivity and quality of winter wheat. The large number of people, globally, affected by the nutritional deficiency of minerals, requires urgent measures to remedy this shortcoming. Agronomic biofortification of zinc cereals is much faster than biofortification through breeding programs. The experiment took place at ARDS Lovrin and was placed in the field according to the randomized block method, in three repetitions. The three experimental factors - factor A - seed treatment, with the following graduations: a1 - without seed fertilization, a2 - with seed fertilization, factor B - variety: b1 - Ciprian variety, b2 - Glosa variety, b3 - Dacian variety and factor C - zinc treatment - c1 - unfertilized control, c2 - soil fertilization, c3 - foliar fertilization at the end of the tillering period, c4 - foliar fertilization in the heading phase, c5 - foliar fertilization in the milk phase, were study both unilaterally and in different combinations. It is noted, in the climatic conditions of the experimental period, as the fertilization variant to increase the zinc content in the grain, the variant with soil fertilization with zinc sulfate, when combined with seed treatment. In this combination, the highest values of zinc in the green plant, in the grain, the best production and quality results, statistical assurance for the probability of transgression of 5% and 1% respectively, are recorded. Regarding the formation of productivity elements - spike length, spike weight, number of spikelets in spike, number of grains in spike, weight of grains in spike - obvious correlations are established between them and the fertilization system approached. Thus, the number of spikelets in main spike correlates very significantly with the length of the spike (r = 0.73***), the number of grains in the spike correlates significantly with the length of the spike (r = 0.68**) and with the number of spikelets/ spike (r = 0.65**), the weight of the spike correlates very significantly with the number of grains / spike (r = 0.73***) and significantly different with the weight of the spike (r = 0.59**) and with the length of the spike (r = 0.57**).

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

Cited by 13 publications

References 38 publications

Nanoparticle Treatments Based on Zinc Oxide and <i>Moringa oleifera</i> Leaf Extracts Alleviate Salinity Stress in Faba Bean (<i>Vicia faba</i> L.)

Nanoparticle Treatments Based on Zinc Oxide and <i>Moringa oleifera</i> Leaf Extracts Alleviate Salinity Stress in Faba Bean (<i>Vicia faba</i> L.)

Tolerance of Two Sorghum Varieties to Salinity Using Different Nutritional Practices and Two Leaching Requirements

The Zinc Agronomic Biofortification and Its Influence on Winter Wheat Productivity and Quality

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

Cited by 13 publications

References 38 publications

Nanoparticle Treatments Based on Zinc Oxide and &lt;i&gt;Moringa oleifera&lt;/i&gt; Leaf Extracts Alleviate Salinity Stress in Faba Bean (&lt;i&gt;Vicia faba&lt;/i&gt; L.)

Nanoparticle Treatments Based on Zinc Oxide and &lt;i&gt;Moringa oleifera&lt;/i&gt; Leaf Extracts Alleviate Salinity Stress in Faba Bean (&lt;i&gt;Vicia faba&lt;/i&gt; L.)

Tolerance of Two Sorghum Varieties to Salinity Using Different Nutritional Practices and Two Leaching Requirements

The Zinc Agronomic Biofortification and Its Influence on Winter Wheat Productivity and Quality

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Nanoparticle Treatments Based on Zinc Oxide and <i>Moringa oleifera</i> Leaf Extracts Alleviate Salinity Stress in Faba Bean (<i>Vicia faba</i> L.)

Nanoparticle Treatments Based on Zinc Oxide and <i>Moringa oleifera</i> Leaf Extracts Alleviate Salinity Stress in Faba Bean (<i>Vicia faba</i> L.)