Metabolomics and Transcription Profiling of Pumpkin Fruit Reveals Enhanced Bioactive Flavonoids and Coumarins in Giant Pumpkin (Cucurbita maxima).

Atlantic giant (AG, Cucurbita maxima) is a type of giant pumpkin in the Cucurbitaceae family and has the world's largest fruit. AG possesses excellent ornamental and economic value due to its well-known large fruit. However, giant pumpkins are usually thrown away after viewing, thus generating a waste of resources. To explore the additional value of giant pumpkins, a metabolome assay was performed between AG and Hubbard (a small fruit pumpkin) fruits. We found that bioactive compounds, especially flavonoids (including 8-prenylnaringenin, tetrahydrocurcumin, galangin, and acacetin) and coumarins (including coumarin, umbelliferone, 4-coumaryl alcohol, and coumaryl acetate), with extensive antioxidant and pharmacological functions, showed higher accumulation in AG fruit than in Hubbard fruits. Comparative transcriptomics of the two pumpkin fruits indicated that the differentially expressed genes (DEGs) encoding PAL, C4H, 4CL, CSE, HCT, CAD, and CCoAOMT were relatively highly expressed, which promoted an increased accumulation of the identified flavonoids and coumarins in giant pumpkins. In addition, the construction of a co-expression network and cis-element analysis of the promoter demonstrated that differentially expressed MYB, bHLH, AP2, and WRKY transcription factors might play vital roles in regulating the expression of DEGs involved in the biosynthesis of several flavonoids and coumarins. Our current results provide new insights into the accumulation of active compounds in giant pumpkins.

Characterization and Coexpression Analysis of the TIFY Family Genes in Euryale ferox Related to Leaf Development.

TIFYs are plant-specific transcription factors that contain the TIFY structural domain and play an important role in plant leaf growth and development. However, the role played by TIFY in E. ferox (Euryale ferox Salisb.) leaf development has not been investigated. In this study, 23 TIFY genes were identified in E. ferox. Phylogenetic analyses of the TIFY genes showed clustering into three groups (JAZ, ZIM, and PPD). The TIFY domain was shown to be conserved. JAZ was mainly expanded via wholegenome triplication (WGT) in E. ferox. Based on analyses of the TIFY genes in nine species, we found that JAZ has a closer relationship with PPD, in addition to appearing the most recently and expanding most rapidly, leading to the rapid expansion of TIFYs in Nymphaeaceae. In addition, their different evolution types were discovered. Different gene expressions showed the distinct and corresponsive expression patterns of the EfTIFYs in different stages of tissue and leaf development. Finally, The qPCR analysis revealed that the expression of EfTIFY7.2 and EfTIFY10.1 showed an upward trend and high expression throughout leaf development. Further co-expression analysis indicated that EfTIFY7.2 might be more important for the development of E. ferox leaves. This information will be valuable when exploring the molecular mechanisms of EfTIFYs in plants.

Genome-Wide Identification of WD40 Proteins in Cucurbita maxima Reveals Its Potential Functions in Fruit Development.

WD40 proteins, a super gene family in eukaryotes, are involved in multiple biological processes. Members of this family have been identified in several plants and shown to play key roles in various development processes, including acting as scaffolding molecules with other proteins. However, WD40 proteins have not yet been systematically analyzed and identified in Cucurbita maxima. In this study, 231 WD40 proteins (CmWD40s) were identified in C. maxima and classified into five clusters. Eleven subfamilies were identified based on different conserved motifs and gene structures. The CmWD40 genes were distributed in 20 chromosomes; 5 and 33 pairs of CmWD40s were distinguished as tandem and segmental duplications, respectively. Overall, 58 pairs of orthologous WD40 genes in C. maxima and Arabidopsis thaliana, and 56 pairs of orthologous WD40 genes in C. maxima and Cucumis sativus were matched. Numerous CmWD40s had diverse expression patterns in fruits, leaf, stem, and root. Several genes were involved in responses to NaCl. The expression pattern of CmWD40s suggested their key role in fruit development and abiotic stress response. Finally, we identified 14 genes which might be involved in fruit development. Our results provide valuable basis for further functional verification of CmWD40s in C. maxima.