Molecular Plant Pathology Laboratory, Beltsville Agricultural Research Center, Agricultural Research Service, United States Department of Agriculture, Beltsville, MD 20705, USA.
Electron and Confocal Microscopy Unit, Beltsville Agricultural Research Center, Agricultural Research Service, United States Department of Agriculture, Beltsville, MD 20705, USA.
Int J Mol Sci. 2022 Feb 5;23(3):1810. doi: 10.3390/ijms23031810.
Witches'-broom (WB, excessive initiation, and outgrowth of axillary buds) is one of the remarkable symptoms in plants caused by phytoplasmas, minute wall-less intracellular bacteria. In healthy plants, axillary bud initiation and outgrowth are regulated by an intricate interplay of nutrients (such as sugars), hormones, and environmental factors. However, how these factors are involved in the induction of WB by phytoplasma is poorly understood. We postulated that the WB symptom is a manifestation of the pathologically induced redistribution of sugar and phytohormones. Employing potato purple top phytoplasma and its alternative host tomato (), sugar metabolism and transportation, and the spatiotemporal distribution of phytohormones were investigated. A transmission electron microscopy (TEM) analysis revealed that starch breakdown was inhibited, resulting in the degradation of damaged chloroplasts, and in turn, premature leaf senescence. In the infected source leaves, two marker genes encoding asparagine synthetase () and trehalose-6-phosphate synthase () that induce early leaf senescence were significantly up-regulated. However, the key gibberellin biosynthesis gene that encodes ent-kaurene synthase () was suppressed. The assessment of sugar content in various infected tissues (mature leaves, stems, roots, and leaf axils) indicated that sucrose transportation through phloem was impeded, leading to sucrose reallocation into the leaf axils. Excessive callose deposition and the resulting reduction in sieve pore size revealed by aniline blue staining and TEM provided additional evidence to support impaired sugar transport. In addition, a spatiotemporal distribution study of cytokinin and auxin using reporter lines detected a cytokinin signal in leaf axils where the axillary buds initiated. However, the auxin responsive signal was rarely present in such leaf axils, but at the tips of the newly elongated buds. These results suggested that redistributed sucrose as well as cytokinin in leaf axils triggered the axillary bud initiation, and auxin played a role in the bud elongation. The expression profiles of genes encoding squamosa promoter-binding proteins (), and BRANCHED1 ( and ) that control axillary bud release, as determined by quantitative reverse transcription (qRT)-PCR, indicated their roles in WB induction. However, their interactions with sugars and cytokinins require further study. Our findings provide a comprehensive insight into the mechanisms by which phytoplasmas induce WB along with leaf chlorosis, little leaf, and stunted growth.
“ witches'-broom (WB, 过度萌发和腋芽生长) 是由植原体引起的植物的显著症状之一,植原体是一种微小的无壁细胞内细菌。在健康植物中,腋芽的萌发和生长受营养物质 (如糖) 、激素和环境因素的复杂相互作用调节。然而,植原体如何诱导 WB 尚不清楚。我们假设 WB 症状是病理诱导的糖和植物激素重新分布的表现。本研究采用马铃薯紫顶植原体及其替代宿主番茄,研究了糖代谢和运输以及植物激素的时空分布。透射电子显微镜 (TEM) 分析显示,淀粉分解受到抑制,导致受损叶绿体降解,进而导致叶片提前衰老。在感染的源叶中,两个标记基因编码天冬酰胺合成酶 () 和海藻糖-6-磷酸合酶 () ,它们诱导早期叶片衰老,显著上调。然而,关键的赤霉素生物合成基因编码 ent-贝壳杉烯合酶 () 被抑制。对各种感染组织 (成熟叶片、茎、根和叶片腋部) 中糖含量的评估表明,韧皮部通过韧皮部运输的蔗糖受到阻碍,导致蔗糖重新分配到叶片腋部。苯胺蓝染色和 TEM 显示的过度胼胝质沉积和由此导致的筛孔大小减小提供了证据,表明糖运输受损。此外,使用报告基因系对细胞分裂素和生长素进行时空分布研究,在腋芽萌发的叶片腋部检测到细胞分裂素信号。然而,在这些叶片腋部,生长素响应信号很少,但在新伸长的芽尖上。这些结果表明,重新分布的蔗糖以及叶片腋部的细胞分裂素触发了腋芽的萌发,而生长素在芽的伸长中起作用。定量逆转录 (qRT)-PCR 测定的基因编码伞形启动子结合蛋白 () 和 BRANCHED1 ( 和 ) 的表达谱表明,它们在 WB 诱导中起作用。然而,它们与糖和细胞分裂素的相互作用需要进一步研究。我们的研究结果提供了对植原体诱导 WB 以及叶片黄化、小叶和生长迟缓的机制的全面了解。”
