Integrated Metabolomics and Transcriptome Analysis of Flavonoid Biosynthesis in Safflower (Carthamus tinctorius L.) With Different Colors.

Rui Wang,Jie Wang,Chao Chen,Shuai Dong,Jiang Chen,Chaoxiang Ren,Qinghua Wu,Jin Pei,Bin Xian

doi:10.3389/fpls.2021.712038

Rui Wang, Jie Wang + Show 7 more

Open Access

https://doi.org/10.3389/fpls.2021.712038

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Abstract

Safflower is widely used in dying and in traditional medicine, and C-glucosylquinochalcones are the main metabolic species in the red color of safflower. Various safflower cultivars have flowers with different colors. However, the metabolic and transcriptional differences among safflower cultivars with different-colored flowers and the genes participating in C-glucosylquinochalcone biosynthesis are largely unknown. To provide insights on this issue, we performed integrated metabolomics and transcriptome analyses on the flavonoid biosynthesis of flowers of different colors in safflower (white-W, yellow-Y, light red-LR, and deep red-DR). The metabolic analysis showed that flavonoid metabolites showed great differences among the different colors of safflower. More flavonoid metabolic species were detected in Y and W, while C-glucosylquinochalcones were not detected in W. The content of C-glucosylquinochalcones increased with increasing color. Transcriptional analysis showed that most of the annotated flavonoid biosynthesis genes were significantly increased in W. The expression of genes related to flavonoid biosynthesis decreased with increasing color. We analyzed the candidate genes associated with C-glucosylquinochalcones, and an integration of the metabolic and transcriptional analyses indicated that the differential expression of the chalcone synthase (CHS) gene is one of the main reasons for the difference in flavonoid species and content among the different colors of safflower. Combined with the expression pattern analysis, these results indicated that HH_035319, HH_032689, and HH_018025 are likely involved in C-glucosylquinochalcones biosynthesis. In addition, we found that their expression showed greatly increased after the methyl jasmonate (MeJA) treatment. Therefore, HH_035319, HH_032689, and HH_018025 might participate in C-glucosylquinochalcone biosynthesis, which ultimately leads to the red color in safflower.

Highlights

Safflower (Carthamus tinctorius) is a member of the Asteraceae or Compositae family and represents an important commercial crop cultivated as an oilseed livestock feed or a dye source or for medicinal purpose (Ekin, 2005)
Four safflower cultivars with white (W), yellow (Y), light red (LR), and deep red (DR) flowers were used in this study (Figure 2)
We screened the metabolic species involved in flavonoid biosynthesis (KEGG number: ko00941 to ko00944)

Summary

Introduction

Safflower (Carthamus tinctorius) is a member of the Asteraceae or Compositae family and represents an important commercial crop cultivated as an oilseed livestock feed or a dye source or for medicinal purpose (Ekin, 2005). This plant was likely domesticated in the fertile Mediterranean coastal zone over 4,000 years ago (Chapman and Burke, 2007). Safflower has been cultivated and used in China for more than 2,000 years. The flowers of safflower are mainly used as dyes and cosmetics worldwide (Azami et al, 2019), while they are used in traditional Chinese medicine as a medicine to improve cerebral blood flow and to treat various ailments, such as gynecological, cerebrovascular, and cardiovascular diseases, hypertension, and coronary heart disease (Lou and Liu, 1956; China T.S.P.Co, 2015)

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