Genes Promote Growth but Inhibit Flower Bud Differentiation in Loquat

Overview

Journal Front Plant Sci

Date 2020 Jun 13

PMID 32528491

Citations 10

Authors

Yuanyuan Jiang

Yunmei Zhu

Ling Zhang

Wenbing Su

Jiangrong Peng

Xianghui Yang

Huwei Song

Yongshun Gao

Shunquan Lin

Affiliations

Soon will be listed here.

Abstract

(), a key factor belonging to the phosphatidyl ethanolamine-binding protein (PEBP) family, controls flowering time and inflorescence architecture in some plants. However, the role of in loquat remains unknown. In this study, we cloned two -like genes ( and ) with conserved deduced amino acid sequences from cultivated loquat ( Lindl.). First, we determined that flower bud differentiation occurs at the end of June and early July, and then comprehensively analyzed the temporal and spatial expression patterns of these during loquat growth and development. We observed the contrasting expression trends for and in shoot apices, and were mainly expressed in young tissues. In addition, short-day and exogenous GA treatments promoted the expression of , and no flower bud differentiation was observed after these treatments in loquat. Moreover, EjTFL1s were localized to the cytoplasm and nucleus, and both interacted with another flowering transcription factor, EjFD, in the nucleus, and EjTFL1s-EjFD complex significantly repressed the promoter activity of . The two were overexpressed in wild-type Col-0, which delayed flowering time, promoted stem elongation, increased the number of branches, and also affected flower and silique phenotypes. In conclusion, our results suggested that and do not show the same pattern of expression whereas both are able of inhibiting flower bud differentiation and promoting vegetative growth in loquat by integrating GA and photoperiod signals. These findings provide useful clues for analyzing the flowering regulatory network of loquat and provide meaningful references for flowering regulation research of other woody fruit trees.

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