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The intracellular distribution of the WHIRLY1 protein and its functions in early barley leaf development
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  • Barbara Karpinska,
  • Nurhayati Razak,
  • Euan James,
  • Jenny Morris,
  • Susan Verrall,
  • Pete Hedley,
  • Robert Hancock,
  • Christine Foyer
Barbara Karpinska
University of Birmingham
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Nurhayati Razak
University of Leeds
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Euan James
The James Hutton Institute
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Jenny Morris
The James Hutton Institute
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Susan Verrall
The James Hutton Institute
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Pete Hedley
The James Hutton Institute
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Robert Hancock
The James Hutton Institute
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Christine Foyer
University of Birmingham

Corresponding Author:[email protected]

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Abstract

The WHIRLY (WHY) DNA/RNA binding proteins fulfil multiple but poorly characterised functions in leaf development. WHY1 transcript levels were highest in the bases of 7-day old barley leaves. Immunogold labelling revealed that the WHY1 protein was more abundant in the nuclei than the proplastids of the leaf bases. Transcript and metabolite profiling analysis of barley lines (W1-1 and W1-7) lacking WHY1, which show delayed greening compared to the wild type. While the transcript profile of leaf development was largely unchanged in W1-1 and W1-7 leaves, there were differences in levels of several transcripts encoding transcription factors associated with chloroplast development. These include a barley homologue of the Arabidopsis GATA transcription factor that regulates stomatal development, greening and chloroplast development, NAC1, two transcripts with similarity to Arabidopsis GLK1 and two transcripts encoding ARF transcriptions factors with functions in leaf morphogenesis and development. Chloroplast proteins were less abundant in the W1-1 and W1-7 leaves than the wildtype. The levels of TCA cycle metabolites and GABA were significantly lower in WHY1 knockdown leaves than the wild type. We conclude that WHY1 functions in the nuclei of the cells in the leaf bases contributes to the regulation of chloroplast development.