Staying green postharvest: how three mutations in the Arabidopsis chlorophyll b reductase gene NYC1 delay degreening by distinct mechanisms

Stresses such as energy deprivation, wounding and water-supply disruption often contribute to rapid deterioration of harvested tissues. To uncover the genetic regulation behind such stresses, a simple assessment system was used to detect senescence mutants in conjunction with two rapid mapping techn...

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Bibliographic Details
Published in:Journal of experimental botany 2015-11, Vol.66 (21), p.6849-6862
Main Authors: Jibran, Rubina, Sullivan, Kerry L., Crowhurst, Ross, Erridge, Zoe A., Chagné, David, McLachlan, Andrew R.G., Brummell, David A., Dijkwel, Paul P., Hunter, Donald A.
Format: Article
Language:English
Subjects:
Amino Acid Sequence
Arabidopsis
Arabidopsis - genetics
Arabidopsis - metabolism
Arabidopsis Proteins - chemistry
Arabidopsis Proteins - genetics
Arabidopsis Proteins - metabolism
Base Sequence
Chlorophyll - metabolism
Gene Expression Regulation, Plant
Membrane Proteins - chemistry
Membrane Proteins - genetics
Membrane Proteins - metabolism
Mutation
Oxidoreductases - chemistry
Oxidoreductases - genetics
Oxidoreductases - metabolism
Polymorphism, Single Nucleotide
RESEARCH PAPER
Sequence Alignment
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Summary:Stresses such as energy deprivation, wounding and water-supply disruption often contribute to rapid deterioration of harvested tissues. To uncover the genetic regulation behind such stresses, a simple assessment system was used to detect senescence mutants in conjunction with two rapid mapping techniques to identify the causal mutations. To demonstrate the power of this approach, immature inflorescences of Arabidopsis plants that contained ethyl methanesulfonate-induced lesions were detached and screened for altered timing of dark-induced senescence. Numerous mutant lines displaying accelerated or delayed timing of senescence relative to wild type were discovered. The underlying mutations in three of these were identified using High Resolution Melting analysis to map to a chromosomal arm followed by a whole-genome sequencing-based mapping method, termed ‘Needle in the K-Stack’, to identify the causal lesions. All three mutations were single base pair changes and occurred in the same gene, NON-YELLOW COLORING1 (NYC1), a chlorophyll b reductase of the short-chain dehydrogenase/reductase (SDR) superfamily. This was consistent with the mutants preferentially retaining chlorophyll b, although substantial amounts of chlorophyll b were still lost. The single base pair mutations disrupted NYC1 function by three distinct mechanisms, one by producing a termination codon, the second by interfering with correct intron splicing and the third by replacing a highly conserved proline with a non-equivalent serine residue. This non-synonymous amino acid change, which occurred in the NADPH binding domain of NYC1, is the first example of such a mutation in an SDR protein inhibiting a physiological response in plants.
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/erv390