Genetic transformation of tropical maize (Zea mays L.) inbred line with a phytase gene from Aspergillus niger

Geetha, S.; Joshi, Jarina; Kumar, K. K.; Arul, L.; Kokiladevi, E.; Balasubramanian, P.; Sudhakar, D.

doi:10.1007/s13205-019-1731-7

Cited by 9 publications

(4 citation statements)

References 47 publications

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“…The maize lpa1-1 and lpa2-1 lines, which contain the LPA-1 (Low Phytic Acid containing Gene.) gene, act as coding proteins of multidrug resistance protein (MRP) ATP-binding cassette (ABC) transporters, which might play a role in the phytic acid accumulation and transport rather than biosynthesis in maize [ 1 , 2 , 40 ] and produce 60% less phytic acid in seed [ 66 , 67 ]. But this type of seed shows a 23% and 30% reduction in seed dry weight and germination [ 31 , 66 ].…”

Section: Regulation and Deposition Of Iron And Zinc In Maize Endospermmentioning

confidence: 99%

“… S.N. Type of phytase gene and source Promoter Signal Sequence Phytase activity Reference 1 Phys- A. niger Rice glutelin-1 seed-specific promoter Murine immunoglobulin leader peptide sequence 2,900 U/kg [ 17 ] 2 , Phy2A- A. niger Embryo-specific globulin- 1 (Glb) promoter Synthetic barley α- amylase signal peptide sequence 2,200 U/kg [ 85 , 93 ] 3 PhyA- A. niger Endosperm-specific promoter Murine immunoglobulin leader peptide sequence 20.67 U/kg [ 67 , 94 ] 4 appA- E. coli a-amylase gene ( aAmy8 ) in rice α Amy8 signal peptide sequence in rice. 16,500 FTU/kg in Maize and 2,500 U/kg in Rice.…”

Section: Regulation and Deposition Of Iron And Zinc In Maize Endospermmentioning

confidence: 99%

See 1 more Smart Citation

Quantitative trait loci and candidate genes for iron and zinc bio-fortification in genetically diverse germplasm of maize (Zea mays L): A systematic review

Basnet¹,

Khanal²

2022

Heliyon

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Section: Regulation and Deposition Of Iron And Zinc In Maize Endospermmentioning

confidence: 99%

Section: Regulation and Deposition Of Iron And Zinc In Maize Endospermmentioning

confidence: 99%

Quantitative trait loci and candidate genes for iron and zinc bio-fortification in genetically diverse germplasm of maize (Zea mays L): A systematic review

Basnet¹,

Khanal²

2022

Heliyon

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“…UU., Australia, Colombia, México, Japón, Canadá, Taiwán y Nueva Zelanda (Garg et al, 2018). El hierro en el maíz se ha incrementado silenciando la expresión del transportador de unión al adenosín trifosfato [ATP] y mediante la expresión de la ferritina de soya y la fitasa por Aspergillus niger (Geetha et al, 2019).…”

Section: Cereales Transgénicosunclassified

Beneficios de los alimentos transgénicos biofortificados, una revisión del 2012 al 2022

Ortiz

Castiblanco

Sandoval-Cáceres

2022

Higo

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Los alimentos transgénicos biofortificados contribuyen como una herramienta futura, prometedora, innovadora, rentable y sostenible para suplir la necesidad de micronutrientes a una población sin dietas diversas brindando alternativas de micronutrientes. Los principales cultivos alimentarios se caracterizan por fuentes pobres de micronutrientes esenciales para el crecimiento humano. El objetivo es informar acerca de los principales alimentos transgénicos bioforticados con potencial para la reducción del hambre oculta. Se utilizaron ecuaciones de búsqueda en inglés y análisis bibliométrico de los términos alimentos transgénicos y biofortificación, encontrándose un total de mil registros principalmente se encontraron las categorías de cereales, vegetales, verduras, frutas y tubérculos. La fuente de consulta corresponde a las bases de datos de la BAC (Biblioteca Agropecuaria de Colombia). El manuscrito trata aspectos de la contribución de los cultivos transgénicos en la biofortificación. Se destacan casos de éxito como los del maíz enriquecido en proteínas de calidad en lisina y triptófano, el de batata naranja rica en vitamina A. Se amplia en los diferentes alimentos transgénicos, especialmente hortalizas, frutas, tubérculos y cereales, que suplen las necesidades nutricionales de la población. Los alimentos transgénicos tienen que enfrentar obstáculos debido a las limitaciones de aceptación entre los consumidores e incluso los gobiernos, con distintos procedimientos y normatividad de aprobación regulatoria que son costosos y lentos. Pero se destaca el potencial que tienen a futuro debido a su capacidad de eliminar la desnutrición de micronutrientes entre miles de millones de personas pobres, especialmente en los países en desarrollo que presentan tendencia al hambre oculta.

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“…Several researches have shown the reduction in phytic acid content of seeds following the expression of fungal phytases by plants, for example, wheat (reduction around 12-76%) [81] and Brassica napus (mutants showed an accumulation of 20.6-46.9% more phosphorous compared with the wild type when phytic acid was employed as phosphate source) [82]. Geeta et al [83] showed that seeds of Zea mays expressing an A. niger phytase had 0.6-to 5-fold more inorganic phosphorous content than the non-expressing ones.…”

Section: Filamentous Fungi Phytases Are Expressed By Yeast Plant Anmentioning

confidence: 99%

Fungal phytases: from genes to applications

Corrêa

Araújo

2020

Braz J Microbiol

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Phytic acid stores 60-90% of the inorganic phosphorus in legumes, oil seeds, and cereals, making it inaccessible for metabolic processes in living systems. In addition, given its negative charge, phytic acid complexes with divalent cations, starch, and proteins. Inorganic phosphorous can be released from phytic acid upon the action of phytases. Phytases are phosphatases produced by animals, plants, and microorganisms, notably Aspergillus niger, and are employed as animal feed additive, in chemical industry and for ethanol production. Given the industrial relevance of phytases produced by filamentous fungi, this work discusses the functional characterization of fungal phytase-coding genes/proteins, highlighting the physicochemical parameters that govern the enzymatic activity, the development of phytase super-producing strains, and key features for industrial applications.

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Genetic transformation of tropical maize (Zea mays L.) inbred line with a phytase gene from Aspergillus niger

Cited by 9 publications

References 47 publications

Quantitative trait loci and candidate genes for iron and zinc bio-fortification in genetically diverse germplasm of maize (Zea mays L): A systematic review

Quantitative trait loci and candidate genes for iron and zinc bio-fortification in genetically diverse germplasm of maize (Zea mays L): A systematic review

Beneficios de los alimentos transgénicos biofortificados, una revisión del 2012 al 2022

Fungal phytases: from genes to applications

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