Regulation of Zn and Fe transporters by the GPC1 gene during early wheat monocarpic senescence

Stephen Pearce, Facundo Tabbita, Dario Cantu, Vince Buffalo, Raz Avni, Hans Vazquez-Gross, Rongrong Zhao, Christopher J. Conley, Assaf Distelfeld, Jorge Dubcovksy*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

95 Scopus citations

Abstract

Background: During wheat senescence, leaf components are degraded in a coordinated manner, releasing amino acids and micronutrients which are subsequently transported to the developing grain. We have previously shown that the simultaneous downregulation of Grain Protein Content (GPC) transcription factors, GPC1 and GPC2, greatly delays senescence and disrupts nutrient remobilization, and therefore provide a valuable entry point to identify genes involved in micronutrient transport to the wheat grain. Results: We generated loss-of-function mutations for GPC1 and GPC2 in tetraploid wheat and showed in field trials that gpc1 mutants exhibit significant delays in senescence and reductions in grain Zn and Fe content, but that mutations in GPC2 had no significant effect on these traits. An RNA-seq study of these mutants at different time points showed a larger proportion of senescence-regulated genes among the GPC1 (64%) than among the GPC2 (37%) regulated genes. Combined, the two GPC genes regulate a subset (21.2%) of the senescence-regulated genes, 76.1% of which are upregulated at 12 days after anthesis, before the appearance of any visible signs of senescence. Taken together, these results demonstrate that GPC1 is a key regulator of nutrient remobilization which acts predominantly during the early stages of senescence. Genes upregulated at this stage include transporters from the ZIP and YSL gene families, which facilitate Zn and Fe export from the cytoplasm to the phloem, and genes involved in the biosynthesis of chelators that facilitate the phloem-based transport of these nutrients to the grains. Conclusions: This study provides an overview of the transport mechanisms activated in the wheat flag leaf during monocarpic senescence. It also identifies promising targets to improve nutrient remobilization to the wheat grain, which can help mitigate Zn and Fe deficiencies that afflict many regions of the developing world.

Original languageEnglish
Article number368
JournalBMC Plant Biology
Volume14
Issue number1
DOIs
StatePublished - 2014

Funding

FundersFunder number
Howard Hughes Medical Institute
Gordon and Betty Moore FoundationGBMF3031
Bloom's Syndrome Foundation2007194, PIRG08-GA-2010-277036
National Institute of Food and Agriculture
United States - Israel Binational Science Foundation
University of California, Davis31.621/2010
Seventh Framework Programme277036
United States-Israel Binational Science Foundation
Universidad de Buenos Aires

    Keywords

    • GPC
    • Iron transport
    • Senescence
    • Wheat
    • ZIP
    • Zinc transport

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