A de novo transcriptome analysis revealed that photomorphogenic genes are required for carotenoid synthesis in the dark-grown carrot taproot.

Resource Type: 
Publication
Publication Type: 
Journal Article
Title: 
A de novo transcriptome analysis revealed that photomorphogenic genes are required for carotenoid synthesis in the dark-grown carrot taproot.
Authors: 
Arias D, Maldonado J, Silva H, Stange C
Series Name: 
Molecular genetics and genomics : MGG
Volume: 
295
Issue: 
6
Page Numbers: 
1379-1392
Publication Year: 
2020
Publication Date: 
2020 Nov
DOI: 
10.1007/s00438-020-01707-4
ISSN: 
1617-4623
EISSN: 
1617-4623
Cross Reference: 
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Citation: 
Arias D, Maldonado J, Silva H, Stange C. A de novo transcriptome analysis revealed that photomorphogenic genes are required for carotenoid synthesis in the dark-grown carrot taproot.. Molecular genetics and genomics : MGG. 2020 Nov; 295(6):1379-1392.
Abstract: 

Carotenoids are terpenoid pigments synthesized by all photosynthetic and some non-photosynthetic organisms. In plants, these lipophilic compounds are involved in photosynthesis, photoprotection, and phytohormone synthesis. In plants, carotenoid biosynthesis is induced by several environmental factors such as light including photoreceptors, such as phytochromes (PHYs) and negatively regulated by phytochrome interacting factors (PIFs). Daucus carota (carrot) is one of the few plant species that synthesize and accumulate carotenoids in the storage root that grows in darkness. Contrary to other plants, light inhibits secondary root growth and carotenoid accumulation suggesting the existence of new mechanisms repressed by light that regulate both processes. To identify genes induced by dark and repressed by light that regulate carotenoid synthesis and carrot root development, in this work an RNA-Seq analysis was performed from dark- and light-grown carrot roots. Using this high-throughput sequencing methodology, a de novo transcriptome model with 63,164 contigs was obtained, from which 18,488 were differentially expressed (DEG) between the two experimental conditions. Interestingly, light-regulated genes are preferably expressed in dark-grown roots. Enrichment analysis of GO terms with DEGs genes, validation of the transcriptome model and DEG analysis through qPCR allow us to hypothesize that genes involved in photomorphogenesis and light perception such as PHYA, PHYB, PIF3, PAR1, CRY2, FYH3, FAR1 and COP1 participate in the synthesis of carotenoids and carrot storage root development.

Publication Model: 
Print-Electronic
Language: 
English
Language Abbr: 
eng
Journal Country: 
Germany
Keywords: 
  • Daucus carota
  • biosynthesis
  • carotenoids
  • carrots
  • genomics
  • lipophilicity
  • models
  • photomorphogenesis
  • photosynthesis
  • phytochrome
  • plant hormones
  • radiation resistance
  • root growth
  • tap roots
  • transcriptome
  • transcriptomics