Abstract
Liriodendron chinense is a common ornamental tree that has attractive leaves, which is a valuable trait for use in landscape architecture. In this work, we aimed to identify the potential genes that control and regulate the development of L. chinense leaf lobes. Based on the transcriptome data for the leaf developmental stages we previously generated, two candidate genes were identified in this study. KNOTTED-LIKE HOMEOBOX(KNOX), encoding homeobox family proteins, play a large role in leaf lobe and leaf complexity regulation. Here, two full length KNOX genes from L. chinense were amplified and named LcKNOX1 and LcKNOX6 according to their sequence similarities with the respective Arabidopsis thaliana KNOX family genes. Overexpression vectors were constructed and subsequently transformed into wild type (WT) A. thaliana. Additionally, LcKNOX6 was expressed in tobacco leaves to examine its subcellular localization, and the 35S::LcKNOX6 transgenic A. thaliana leaf cells were imaged with the use of SEM. The expression of several genes that participate in KNOX gene regulation were validated by quantitative real-time PCR. The results show that LcKNOX1 produces almost the same phenotype as that found in WT A. thaliana. Notably, the LcKNOX6-1 lines presented deep leaf lobes that were similar to L. chinense leaf lobes. Two 35S::LcKNOX6 lines induced an abnormal growth phenotype whose seeds were abortive. In short, these results indicate that the LcKNOX6 gene might affect leaf development in A. thaliana and provide insights into the regulation of L. chinense leaf shaping.
Highlights
Leaves present tremendous diversity due to their adaption to variable environments, and they play an essential role in plant photosynthesis and transpiration
We aimed to examine whether LcKNOX1 and LcKNOX6 have the function to produce leaf lobe growth
The claimed that some class genes are only expressed in the and that their expression might claimed that some class I KNOX genes are only expressed in the shoot apical meristem (SAM) and that their expression be non-existent in leafinprimordia
Summary
Leaves present tremendous diversity due to their adaption to variable environments, and they play an essential role in plant photosynthesis and transpiration. Since photosynthesis in leaves is vital to plant growth and survival, variations in leaf shape may reflect natural selection according to function [1]. Leaf shape diversity is usually determined by alterations of the margin [3]. A report indicated that leaf shape might be an important but overlooked factor that affects the interactions between plants and leaf-processing herbivores [4]. Leaf shape has been examined in studies of the relationship between the environment and variation, as well as in studies of the evolution of species of angiosperms [3,5,6]
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