AI Article Synopsis
- The study identifies a class of genes known as UBiA in sunflowers, which are involved in crucial processes like growth and the production of secondary metabolites, including chlorophyll and vitamin E.
- Researchers discovered 10 UBiA genes with conserved domains spread across six chromosomes, and through phylogenetic analysis, they classified 119 genes from 12 different species into five major groups with specific motifs.
- The expression of two key UBiA genes, HaUBiA1 and HaUBiA5, was notably influenced by various abiotic stresses, with HaUBiA1 upregulating under stress conditions while HaUBiA5 showed a decrease, suggesting their potential roles in stress response mechanisms for sunflowers.
Article Abstract
The genes encode a large class of isopentenyltransferases, which are involved in the synthesis of secondary metabolites such as chlorophyll and vitamin E. They performed important functions in the whole plant's growth and development. Current studies on UBiA genes were not comprehensive enough, especially for sunflower genes. In this study, 10 were identified by domain analysis these had five major conserved domains and were unevenly distributed on six chromosomes. By constructing phylogenetic trees, 119 genes were found in 12 species with different evolutionary levels and divided into five major groups, which contained seven conserved motifs and eight UBiA subsuper family domains. Tissue expression analysis showed that were highly expressed in the roots, leaves, and seeds. By using promoter analysis, the cis-elements of genes were mainly in hormone signaling and stress responses. The qRT-PCR results showed that HaUBiA1 and HaUBiA5 responded strongly to abiotic stresses. Under ABA and MeJA treatments, HaUBiA1 significantly upregulated, while HaUBiA5 significantly decreased. Under cold stress, the expression of UBiA1 was significantly upregulated in the roots and stems, while UBiA5 expression was increased only in the leaves. Under anaerobic induction, UBiA1 and UBiA5 were both upregulated in the roots, stems and leaves. In summary, this study systematically classified the UBiA family and identified two abiotic stress candidate genes in the sunflower. It expands the understanding of the UBiA family and provides a theoretical basis for future abiotic stress studies in sunflowers.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9916351 | PMC |
| http://dx.doi.org/10.3390/ijms24031883 | DOI Listing |
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