Abstract
Flavonoid 3′-hydroxylase (F3’H) enzyme is essential in determining the flavonoids B-ring hydroxylation pattern. It is mainly implicated in the biosynthetic pathway of cyaniding-based anthocyanins, flavonols, and flavan-3-ols. However, the evolution and regulatory mechanism of these important flavonoid hydroxylases have not been systematically investigated in safflower (Carthamus tinctorius L.). In this study, we identified 22 duplicatedCtF3'H-encoding genes from safflower through genome-wide prediction and conservation analysis. Phylogenetic analysis revealed the pattern of conservation and divergence of CtF3'Hs encoding proteins and their homologs from different plant species. The distribution of conserved protein motifs and cis-regulatory units suggested several structural components that could be crucial in deciphering the final function of CtF3'H proteins. Furthermore, the results of RNA-seq and qRT-PCR assay in different flowering tissues suggested differential expression level of CtF3’H genes during flower development. Based on the unique homology of CtF3’H5 with flavonoid 3’ hydroxylases from other plant species, further validation of CtF3’H5 was carried out. The transient expression of CtF3’H5 in onion epidermal cells implied that the subcellular localization of the fusion construct containing CtF3’H5 and GFP was predominantly detected in the plasma membrane. Similarly, the prokaryotic expression and western blot hybridization of CtF3’H5 demonstrated the detection of a stable 50.3kD target protein. However, more efforts are needed to further extend the functional validation of CtF3’H5 in safflower. This study provides a fundamental gateway for future functional studies and understanding the genetic evolution of F3'Hs in plants.
Highlights
Safflower (Carthamus tinctorius L.) belongs to the Asteraceae family and is widely known as one of the essential self-pollinated species comprising a diploid genome (2n = 24)
Various physico-chemical properties of the selected CtF3’H including protein size, molecular weight (MW) and isoelectric point, and grand average of hydropathicity (GRAVY) were investigated using the online tools of ExPASy software available at
A total of 37 candidate CtF3'H genes were identified in the safflower genome
Summary
Flavonoids are an important class of natural products (Cerqueira et al, 2021); In particular, they belong to the polyphenolic group of plant metabolites, which are widely found in fruits, vegetables, and some beverages. The biochemical effects and antioxidant abilities of flavonoids are directly related to various diseases such as cancer, atherosclerosis, and Alzheimer's diseases (Du et al, 2021). They sometimes act as potent inhibitors of different groups of enzymes, such as xanthine oxyase (Lin et al, 2021), cyclo-oxyase, lipoxygenase, and 3-kinase phosphoinositide (Panche et al, 2016). The discovery of new genes will facilitate the underlying principles of the accumulation of plant specialized metabolites such as anthocyanins, luteolins, cyanadins to unravel the mechanism of pigmentation in flower petals, seed coats, or hypocotyls
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