SUMMARY Serine carboxypeptidase‐like acyltransferases (SCPL‐ATs) play a vital role in the diversification of plant metabolites. Galloylated flavan‐3‐ols highly accumulate in tea (Camellia sinensis), grape (Vitis vinifera), and persimmon (Diospyros kaki). To date, the biosynthetic mechanism of these compounds remains unknown. Herein, we report that two SCPL‐AT paralogs are involved in galloylation of flavan‐3‐ols: CsSCPL4, which contains the conserved catalytic triad S‐D‐H, and CsSCPL5, which has the alternative triad T‐D‐Y. Integrated data from transgenic plants, recombinant enzymes, and gene mutations showed that CsSCPL4 is a catalytic acyltransferase, while CsSCPL5 is a non‐catalytic companion paralog (NCCP). Co‐expression of CsSCPL4 and CsSCPL5 is likely responsible for the galloylation. Furthermore, pull‐down and co‐immunoprecipitation assays showed that CsSCPL4 and CsSCPL5 interact, increasing protein stability and promoting post‐translational processing. Moreover, phylogenetic analyses revealed that their homologs co‐exist in galloylated flavan‐3‐ol‐ or hydrolyzable tannin‐rich plant species. Enzymatic assays further revealed the necessity of co‐expression of those homologs for acyltransferase activity. Evolution analysis revealed that the mutations of the CsSCPL5 catalytic residues may have taken place about 10 million years ago. These findings show that the co‐expression of SCPL‐ATs and their NCCPs contributes to the acylation of flavan‐3‐ols in the plant kingdom.
SUMMARY Plant tannases (TAs) or tannin acyl hydrolases, a class of recently reported carboxylesterases in tannin‐rich plants, are involved in the degalloylation of two important groups of secondary metabolites: flavan‐3‐ol gallates and hydrolyzable tannins. In this paper, we have made new progress in studying the function of tea (Camellia sinensis) (Cs) TA—it is a hydrolase with promiscuous acyltransferase activity in vitro and in vivo and promotes the synthesis of simple galloyl glucoses and flavan‐3‐ol gallates in plants. We studied the functions of CsTA through enzyme analysis, protein mass spectrometry, and metabolic analysis of genetically modified plants. Firstly, CsTA was found to be not only a hydrolase but also an acyltransferase. In the two‐step catalytic reaction where CsTA hydrolyzes the galloylated compounds epigallocatechin‐3‐gallate or 1,2,3,4,6‐penta‐O‐galloyl‐β‐d‐glucose into their degalloylated forms, a long‐lived covalently bound Ser159‐linked galloyl–enzyme intermediate is also formed. Under nucleophilic attack, the galloyl group on the intermediate is transferred to the nucleophilic acyl acceptor (such as water, methanol, flavan‐3‐ols, and simple galloyl glucoses). Then, metabolic analysis suggested that transient overexpression of TAs in young strawberry (Fragaria × ananassa) fruits, young leaves of tea plants, and young leaves of Chinese bayberry (Myrica rubra) actually increased the total contents of simple galloyl glucoses and flavan‐3‐ol gallates. Overall, these findings provide new insights into the promiscuous acyltransferase activity of plant TA.
Members of the R2R3-MYB4 subgroup are well-known negative regulatory transcription factors of phenylpropane and lignin pathways. In this study, we found that transgenic tobacco plants overexpressing a R2R3-MYB4 subgroup gene from Camellia sinensis (CsMYB4a) showed inhibited growth that was not regulated by phenylpropane and lignin pathways, and these plants exhibited altered sensitivity to synthetic auxin 1-naphthaleneacetic acid (α-NAA) treatment. An auxin/indole-3-acetic acid 4 (AUX/IAA4) gene from Camellia sinensis (CsIAA4) participating in the regulation of the auxin signal transduction pathway was screened from the yeast two-hybrid library with CsMYB4a as the bait protein, and tobacco plants overexpressing this gene showed a series of auxin-deficiency phenotypes, such as dwarfism, small leaves, reduced lateral roots, and a shorter primary root. CsIAA4 transgenic tobacco plants were less sensitive to exogenous α-NAA than control plants, which was consistent with the findings for CsMYB4a transgenic tobacco plants. The knockout of the endogenous NtIAA4 gene (a CsIAA4 homologous gene) in tobacco plants alleviated growth inhibition in CsMYB4a transgenic tobacco plants. Furthermore, protein-protein interaction experiments proved that domain II of CsIAA4 is the key motif for the interaction between CsIAA4 and CsMYB4a and that the degradation of CsIAA4 is prevented when CsMYB4a interacts with CsIAA4. In summary, our results suggest that CsMYB4a is a multifunctional transcription factor that regulates the auxin signaling pathway, phenylpropane and lignin pathways. This study provides new insights into the multiple functions of R2R3-MYB4 subgroup members as a group of well-known negative regulatory transcription factors.
The high accumulation of galloylated flavan-3-ols in Camellia sp. is a noteworthy phenomenon. We identified a flavan-3-ol galloylation-related functional gene cluster in tannin-rich plant Camellia sp., which included UGT84A22 and SCPL-AT gene clusters. We investigated the possible correlation between the accumulation of metabolites and the expression of SCPL-ATs and UGT84A22. The results revealed that C. sinensis, C. ptilophylla, and C. oleifera accumulated galloylated cis-flavan-3-ols (EGCG), galloylated trans-flavan-3-ols (GCG), and hydrolyzed tannins, respectively; however, C. nitidissima did not accumulate any galloylated compounds. C. nitidissima exhibited no expression of SCPL-AT or UGT84A22, whereas the other three species of Camellia exhibited various expression patterns. This indicated that the functions of the paralogs of SCPL-AT vary. Enzymatic analysis revealed that SCPL5 was neofunctionalized as a noncatalytic chaperone paralog, a type of chaerone-like protein, associating with flavan-3-ol galloylation; moreover, CsSCPL4 was subfunctionalized in association with the galloylation of cis-and trans-flavan-3-ols. In C. nitidissima, an SCPL4 homolog was noted with mutations in two cysteine residues forming a disulfide bond, which suggested that this homolog was defunctionalized. The findings of this study improve our understanding of the functional diversification of SCPL paralogs in Camellia sp.
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