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1.
Vitamin A deficiency is widely prevailing in children and women of developing countries. Deficiency of vitamin A causes night blindness, growth retardation, xerophthalmia and increases the susceptibility against epidemic diseases. Among different interventions of overcoming malnutrition, biofortification is the most acceptable and preferred intervention among researchers, growers and consumers. Maize is grown and consumed in those regions where vitamin A deficiency is most prevalent; thus, targeting this crop for provitamin A biofortification is the most appropriate solution. Different breeding strategies including diversity analysis, introduction and stability analysis of exotic germplasm, hybridization, heterosis breeding, mutagenesis and marker‐assisted selection are practised for exploring maize germplasm and development of provitamin A‐enriched cultivars. Genome‐wide association selection and development of transgenic maize genotypes are also being practised, whereas RNA interference and genome editing tools could also be used as potential strategies for provitamin A biofortification of maize genotypes. The use of these breeding strategies for provitamin A biofortification of maize is comprehensively reviewed to provide a working outline for maize breeders.  相似文献   
2.
Vitamin A deficiency in humans is a widespread health problem. Quality protein maize (QPM) is a popular food rich in lysine and tryptophan, but poor in provitamin A (proA). Here, we report the improvement of an elite QPM inbred, HKI1128Q for proA using marker‐assisted introgression of crtRB1‐favourable allele. HKI1128 was one of the parental lines of three popular hybrids in India and was converted to QPM in our earlier programme. Severe segregation distortion for crtRB1 was observed in BC1F1, BC2F1 and BC2F2. Background selection by 100 SSRs revealed mean recovery of 91.07% recurrent parent genome varying from 88.78% to 93.88%. Across years, introgressed progenies possessed higher mean β‐carotene (BC: 9.22 µg/g), β‐cryptoxanthin (BCX: 3.05 µg/g) and provitamin A (proA: 10.75 µg/g) compared to HKI1128Q (BC: 2.26 µg/g, BCX: 2.26 µg/g and proA: 3.38 µg/g). High concentration of essential amino acids, viz. lysine (mean: 0.303%) and tryptophan (0.080%) in endosperm, was also retained. Multi‐year evaluation showed that introgressed progenies possessed similar grain yield (1,759–1,879 kg/ha) with HKI1128Q (1,778 kg/ha). Introgressed progenies with higher lysine, tryptophan and proA hold immense potential as donors and parents in developing biofortified hybrids.  相似文献   
3.
Selenium (Se) biofortification via crops is one of the best strategies to elevate the daily Se intake in areas where soil Se levels are low. However, Se fertilizer recovery (SeFR) is low and most of the Se taken up accumulates in non‐harvested plant parts and returns to the soil with plant residues. A pot experiment with soil was undertaken to study the efficiency of inorganic Se (Na2SeO4) and Se‐enriched plant residues for biofortification, as well as to identify the bottlenecks in Se utilization by Brassica napus L. The soil was fertilized with Na2SeO4 (0 and 7 µg Se kg?1) or with Se in stem or leaf residues (0 and 7 µg Se kg?1). A treatment with autoclaved soil was included (0 and 7 µg kg?1 as Na2SeO4) to unravel the impact of microbial activity on Se uptake. The Se‐enriched plant residues produced a lower Se uptake efficiency (SeUPE) and SeFR than did inorganic Se, and soil autoclaving enhanced Se accumulation in the plants. The time required for decomposition seems to preclude crop residues as an alternative source of Se. Furthermore, B. napus had a limited capacity to accumulate Se in seeds. The study shows that the bottlenecks in Se biofortification appear to be its low bioavailability in soil and poor loading from the silique walls to seeds. Thus, improved Se translocation to seeds would be a useful breeding goal in B. napus to increase SeFR.  相似文献   
4.
In this research experiment, two commercial onion cultivars (Allium cepa L., cvs. Dorrcheh and Cebolla Valenciana) were grown in sand culture and exposed to two levels of selenium (Se) (0 and 25?µM) and two levels of sulfate (1 and 3?mM). According to the results obtained, addition of 25?µM Se in combination with 3?mM sulfate was not only effective in significant increase of onion bulb yield, but it significantly increased Se concentration of bulb. By considering the average consumption of onion in central Iran, the daily intake of Se via consumption of Se-biofortified onion is estimated to be 68.4–77.2?µg in spring and summer and 72.6–117.1?µg in fall and winter. These amounts of daily intakes of Se is higher than the sufficient levels of Se recommended by world health organization (WHO) but less than the maximum tolerable level of Se (400?µg Se per day) for human.  相似文献   
5.
为了筛选适宜叶面喷施硒强化的理想品种,对63个近年来长江中下游主推小麦品种(系)进行叶面喷施硒酸钠,强化浓度为300 mg Se/L(Se300),利用离子发射光谱-原子吸收仪测定了小麦籽粒中Se、Cu、Fe、Mn、Zn、K、Mg、K和S含量。结果显示,叶面喷施硒酸钠可以提高小麦籽粒中的硒含量,总硒含量平均值由对照组的2.13±0.73 mg/kg提高到9.13±3.86 mg/kg,但增幅因品种而异;籽粒中不同矿物质元素对叶面喷施硒酸钠的响应不同,硒降低了籽粒中Cu、Fe、K、Mg和S的含量,但提高了锌的含量,对Mn和Ca元素含量没有影响。综合比较显示江麦816是长江中下游主要推广品种中硒强化潜力较大的品种(系)之一。  相似文献   
6.
Development of wheat–alien translocation lines has facilitated practical utilization of alien species in wheat improvement. The production of a compensating Triticum aestivumThinopyrum bessarabicum whole‐arm Robertsonian translocation (RobT) involving chromosomes 6D of wheat and 6Eb of Th. bessarabicum (2n = 2x = 14, EbEb) through the mechanism of centric breakage–fusion is reported here. An F2 population was derived from plants double‐monosomic for chromosome 6D and 6Eb from crosses between a DS6Eb(6D) substitution line and bread wheat cultivar ‘Roushan’ (2n = 6x = 42, AABBDD) as female parent. Eighty F2 genotypes (L1–L80) were screened for chromosome composition. Three PCR‐based Landmark Unique Gene (PLUG) markers specific to chromosomes 6D and 6Eb were used for screening the F2 plants. One plant with a T6EbS.6DL centric fusion (RobT) was identified. A homozygous translocation line with full fertility was recovered among F3 families and verified with genomic in situ hybridization (GISH). Grain micronutrient analysis showed that the DS6Eb(6D) substitution line and T6EbS.6DL stock have higher Fe and Zn contents than the recipient wheat cultivar ‘Roushan’.  相似文献   
7.
水稻吸收、运输锌及其籽粒富集锌的机制   总被引:7,自引:0,他引:7  
 锌是人体必需而又易缺乏的营养元素。在粮食作物可食部位生物强化锌被认为是解决人体缺锌的最有潜力的途径。水稻根吸收锌可分为分泌麦根酸等根系分泌物将土壤颗粒中的金属离子活化和重金属转运蛋白把锌离子转运进植株根部两个过程,ZIP家族基因在后一过程中发挥重要作用。水稻锌在木质部中运输主要以离子态为主,也可同有机酸、尼克酰胺等配体协同运输。地上部锌通过韧皮部再转运到新生组织或装载进入籽粒,水稻韧皮部再转运能力是影响籽粒富锌的关键因素,而锌大量累积在糊粉层中或与植酸等结合后,大大降低了锌的生物有效性。研究粮食作物籽粒富锌机制,利用现代分子生物技术生物强化籽粒中的锌含量,对满足人类锌营养健康具有重要意义。综述了锌在植物体内的生理功能,水稻对锌的吸收、运输和再转运,锌装载进入籽粒,锌在植物体内的分布与赋存形态,以及锌在粮食作物中的生物强化等最新研究进展。  相似文献   
8.
Abstract

One of the problems in obtaining high wheat yield is the unavailability of micronutrients in balanced quantities. Zinc is an essential micronutrient due to its involvement in many metabolic processes in plant. In this experiment, seeds of two wheat cultivars (Faisalabad-2008 and Lasani-2008) were subjected to soak in aerated Zn solution of 0.1 and 0.01?M for 12?hr. For the seed coating, Zn was adhered to the wheat seeds by using Arabic gum by using zinc sulfate (ZnSO4·7H2O) as a source. Untreated dry seeds were considered as a control. Results indicated that field emergence was improved by Zn seed treatments, maximum numbers of seedlings were observed in seed priming with 0.01?M Zn solution. Seed osmoprimed with 0.01?M Zn solution improved the grain yield, biological yield, and other yield related traits. Grain and straw Zn enrichment were also enhanced in seed osmoprimed with 0.01?M Zn solution.  相似文献   
9.
Abstract

Biofortification of agricultural productions is important to enhance the quality of the products. The aims of this research were to investigate the possibility of selenium biofortification of alfalfa in the calcareous and non-calcareous soils by applying fertilizers differently (control, soil application, inoculant of seleno-bacteria, foliar application, combined soil, and foliar applications of selenate). Morpho-physiological properties and nutritional responses, such as shoot dry weight, phosphorus, potassium, selenium, zinc, and iron concentration in the plant’s tissue were measured. In all parameters, the use of selenium sources in the calcareous soils had a significant effect compared with the control treatment. Among the methods and sources of selenium, foliar application of sodium selenate gave the best response. By the usage of this treatment, Se concentration was increased up to 112.5% and 182%, respectively, compared with the control treatment in non-calcareous and calcareous soil. According to the results, inoculant of selenium bacteria and sodium selenate are recommended as a natural way to selenium biofortification in alfalfa and to improve the quality of the produced forage. In addition, attention to the biological potential of the soil and the use of native soil bacteria is also recommended.  相似文献   
10.
One sixth of the world’s population is suffering from hidden hunger that indicates a gross malnutrition particularly among children and women of third world countries. The deficiency of micro nutrients, especially iron (Fe) causes a number of ailments such as megaloblastic anemia and neural tube defects in poor population. There is a dire need to supplement iron in the diet. Current efforts implicate fortification of wheat flour and other grains with different iron formulations such as ethylenediaminetetraacetic acid (EDTA), FeSO4 and elemental iron. However, all such interventions are not sustainable due to logistic and quality assurance problems in resource-limited settings. For a long term solution, development of crop plants with increased micronutrients and iron bioavailability is essential. Therefore, biofortification of cereal grains using translational genomics approaches for enhancement of folate through genome editing in cereals is inevitable to mitigate the folate deficiency in poor remote population in a cost effective manner.  相似文献   
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