| 000 | 02989nab|a22004337a|4500 | ||
|---|---|---|---|
| 999 |
_c63621 _d63613 |
||
| 001 | 63620 | ||
| 003 | MX-TxCIM | ||
| 005 | 20231009164120.0 | ||
| 008 | 202101s2020||||sz |||p|op||||00||0|eng|d | ||
| 022 | _a1422-0067 (Online) | ||
| 024 | 8 | _ahttps://doi.org/10.3390/ijms21239280 | |
| 040 | _aMX-TxCIM | ||
| 041 | _aeng | ||
| 100 | 0 |
_aJingyang Tong _919596 |
|
| 245 | 1 | 0 |
_aDissection of molecular processes and genetic architecture underlying iron and zinc homeostasis for biofortification : _bfrom model plants to common wheat |
| 260 |
_aBasel (Switzerland) : _bMDPI, _c2020. |
||
| 500 | _aPeer review | ||
| 500 | _aOpen Access | ||
| 520 | _aThe micronutrients iron (Fe) and zinc (Zn) are not only essential for plant survival and proliferation but are crucial for human health. Increasing Fe and Zn levels in edible parts of plants, known as biofortification, is seen a sustainable approach to alleviate micronutrient deficiency in humans. Wheat, as one of the leading staple foods worldwide, is recognized as a prioritized choice for Fe and Zn biofortification. However, to date, limited molecular and physiological mechanisms have been elucidated for Fe and Zn homeostasis in wheat. The expanding molecular understanding of Fe and Zn homeostasis in model plants is providing invaluable resources to biofortify wheat. Recent advancements in NGS (next generation sequencing) technologies coupled with improved wheat genome assembly and high-throughput genotyping platforms have initiated a revolution in resources and approaches for wheat genetic investigations and breeding. Here, we summarize molecular processes and genes involved in Fe and Zn homeostasis in the model plants Arabidopsis and rice, identify their orthologs in the wheat genome, and relate them to known wheat Fe/Zn QTL (quantitative trait locus/loci) based on physical positions. The current study provides the first inventory of the genes regulating grain Fe and Zn homeostasis in wheat, which will benefit gene discovery and breeding, and thereby accelerate the release of Fe- and Zn-enriched wheats. | ||
| 526 |
_aWC _cFP2 |
||
| 546 | _aText in English | ||
| 591 | _aYuanfeng Hao : No CIMMYT Affiliation | ||
| 650 | 7 |
_aIron _2AGROVOC _93544 |
|
| 650 | 7 |
_aTrace elements _2AGROVOC _95624 |
|
| 650 | 7 |
_aGenes _2AGROVOC _93563 |
|
| 650 | 7 |
_aWheat _gAGROVOC _2 _91310 |
|
| 650 | 7 |
_aZinc _2AGROVOC _91315 |
|
| 700 | 0 |
_aMengjing Sun _919597 |
|
| 700 | 0 |
_aYue Wang _910965 |
|
| 700 | 0 |
_aYong Zhang _91857 |
|
| 700 | 1 |
_aAwais Rasheed _gGlobal Wheat Program _8I1706474 _91938 |
|
| 700 | 0 |
_aMing Li _914174 |
|
| 700 | 0 |
_aXianchun Xia _9377 |
|
| 700 | 1 |
_aHe Zhonghu _gGlobal Wheat Program _8INT2411 _9838 |
|
| 700 | 1 |
_aYuanfeng Hao _9919 _8INT3329 _gGlobal Wheat Program |
|
| 773 | 0 |
_tInternational Journal of Molecular Sciences _dBasel (Switzerland) : MDPI, 2020. _x1422-0067 _gv. 21, no. 23, art. 9280 _w57216 |
|
| 856 | 4 |
_yOpen Access through DSpace _uhttps://hdl.handle.net/10883/21487 |
|
| 942 |
_cJA _n0 _2ddc |
||