Combined transcriptome and plant hormone analysis revealed the potential mechanism of fern-leaved tomato mutant formation

IF 3.9 2区农林科学 Q1 HORTICULTURE

Scientia Horticulturae Pub Date : 2025-07-01 DOI:10.1016/j.scienta.2025.114273

Xindun Wang , Jiang Yue , Chaozhong Zhang , Shun Wang , Xiaogang Xiang , Jingyi Chen , Hui Wang , Wei Li , Jianmin Yan

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Abstract

To investigate the molecular regulation mechanisms and metabolic pathways associated with tomato leaf abnormalities, we utilized the leaves of wild-type Alisa Craig (AC) and the fern-leaved tomato mutant (fern mutant) as experimental materials. Phenotypic identification revealed that the young leaves of the fern mutant presented strip-shaped ((Fern), similar to fern leaves., while the mature leaves reverted to a morphology similar to that of AC leaves (referred to as Fern-NL). However, the leaf cleavage in Fern-NL was not pronounced, and the fern mutant exhibited dwarfism with shortened internode lengths. Microscopic analysis of the leaves from both Fern and Fern-NL, using AC as a control, indicated that the upper epidermal cells of Fern were elongated, the lower epidermal cells were irregularly arranged, the palisade tissue was densely packed, and the spongy tissue was sparse. In contrast, no significant differences were observed between the upper and lower epidermis of Fern-NL and that of AC; both exhibited tightly arranged palisade tissue and densely but irregularly arranged spongy tissue. Transcriptome sequencing data analysis using DEGsq revealed 2525 (157 up-regulated, 955 down-regulated) genes differentially expressed in AC vs Fern, 4864 (1679 up-regulated, 3185 down-regulated) in Fern vs Fern-NL, and 5341 (2151 up-regulated, 319 down-regulated) in AC vs Fern-NL. Functional analysis indicated significant differences in DEGs related to intrinsic components of the plasma membrane, ion transmembrane transport activity, and stimulation response. KEGG enrichment analysis highlighted active enrichment of DEGs in pathways such as plant hormone signal transduction, phenylpropanoid biosynthesis, plant-pathogen interaction, and carbon metabolism, suggesting their potential role in fern-leaved tomato mutant formation. Quantitative hormone analysis revealed significant alterations in auxin, cytokinin, gibberellin, abscisic acid, ethylene synthesis precursors, jasmonic acid, salicylic acid, and zeatin levels in the Fern mutant. Treatment with auxin promoter NAA and inhibitor TIBA demonstrated Fern's heightened sensitivity to NAA and TIBA, with NAA promoting leaf recovery and TIBA delaying it. Comprehensive analysis indicates that differentially expressed genes regulating the auxin signaling pathway act in concert with imbalances in hormones such as jasmonic acid and abscisic acid, leading to abnormal arrangement of epidermal cells and densification of palisade tissue, which ultimately drives the formation of fern-like leaf morphology. These findings offer insights into the molecular mechanisms underlying tomato leaf dysplasia and serve as a valuable resource for germplasm innovation, genetic resource exploration, and cultivation strategies.

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结合转录组和植物激素分析揭示了蕨类叶片番茄突变体形成的潜在机制

为了研究番茄叶片异常的分子调控机制和代谢途径，我们以野生型Alisa Craig （AC）和蕨类叶片番茄突变体（蕨类突变体）的叶片为实验材料。表型鉴定表明，突变体幼叶呈条状（(fern)），与蕨类植物叶片相似。，而成熟叶片则恢复到与AC叶片相似的形态（称为蕨类植物）。而蕨- nl突变体叶片劈裂不明显，节间长度缩短，呈矮化现象。以AC为对照，对蕨类和蕨类植物叶片的显微分析表明，蕨类植物的上表皮细胞呈细长状，下表皮细胞排列不规则，栅栏组织密集，海绵组织稀疏。Fern-NL的上、下表皮与AC的上、下表皮差异不显著；两者均表现出紧密排列的栅栏组织和密集但不规则排列的海绵组织。利用DEGsq进行转录组测序数据分析，发现AC与Fern中有2525个（157个上调，955个下调）基因差异表达，Fern与Fern- nl中有4864个（1679个上调，3185个下调）基因差异表达，AC与Fern- nl中有5341个（2151个上调，319个下调）基因差异表达。功能分析表明，与质膜固有成分、离子跨膜运输活性和刺激反应相关的deg存在显著差异。KEGG富集分析表明，DEGs在植物激素信号转导、苯丙素生物合成、植物-病原体相互作用和碳代谢等途径中具有活性富集，表明它们在蕨类叶片番茄突变体形成中可能发挥作用。定量激素分析显示，在蕨类突变体中，生长素、细胞分裂素、赤霉素、脱落酸、乙烯合成前体、茉莉酸、水杨酸和玉米素水平发生了显著变化。用生长素启动子NAA和抑制剂TIBA处理蕨类植物对NAA和TIBA的敏感性增强，NAA促进叶片恢复，TIBA延缓叶片恢复。综合分析表明，调控生长素信号通路的差异表达基因与茉莉酸、脱落酸等激素的失衡协同作用，导致表皮细胞排列异常，栅栏组织致密化，最终驱动蕨类叶片形态的形成。这些发现为番茄叶片发育不良的分子机制提供了新的认识，并为种质资源创新、遗传资源开发和栽培策略提供了宝贵的资源。

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来源期刊

Scientia Horticulturae 农林科学-园艺

CiteScore

8.60

自引率

4.70%

发文量

796

审稿时长

47 days

期刊介绍： Scientia Horticulturae is an international journal publishing research related to horticultural crops. Articles in the journal deal with open or protected production of vegetables, fruits, edible fungi and ornamentals under temperate, subtropical and tropical conditions. Papers in related areas (biochemistry, micropropagation, soil science, plant breeding, plant physiology, phytopathology, etc.) are considered, if they contain information of direct significance to horticulture. Papers on the technical aspects of horticulture (engineering, crop processing, storage, transport etc.) are accepted for publication only if they relate directly to the living product. In the case of plantation crops, those yielding a product that may be used fresh (e.g. tropical vegetables, citrus, bananas, and other fruits) will be considered, while those papers describing the processing of the product (e.g. rubber, tobacco, and quinine) will not. The scope of the journal includes all horticultural crops but does not include speciality crops such as, medicinal crops or forestry crops, such as bamboo. Basic molecular studies without any direct application in horticulture will not be considered for this journal.