Tsutsui Hiroki, Kawakatsu Yaichi, Notaguchi Michitaka
Graduate School of Bioagricultural Sciences, Nagoya University, Nagoya, Japan.
Bioscience and Biotechnology Center, Nagoya University, Nagoya, Japan.
Bio Protoc. 2021 Jun 20;11(12):e4053. doi: 10.21769/BioProtoc.4053.
The micrografting technique in the model plant has been widely used in the field of plant science. Grafting experiments have demonstrated that signal transductions are systematically regulated in many plant characteristics, including defense mechanisms and responses to surrounding environments such as soil and light conditions. Hypocotyl micrografting is a powerful tool for the analysis of signal transduction between shoots and roots; however, the requirement for a high level of skill for micrografting, during which small seedlings are microdissected and micromanipulated, has limited its use. Here, we developed a silicone-made microdevice, called a micrografting chip, to perform micrografting easily and uniformly. The micrografting chip has tandemly arrayed units, each of which consists of a seed pocket for seed germination and a micro-path to hold hypocotyl. All micrografting procedures are performed on the chip. This method using a micrografting chip will avoid the need for training and promote studies of systemic signaling in plants. Graphic abstract: A silicone chip for easy grafting.
模式植物中的微嫁接技术已在植物科学领域得到广泛应用。嫁接实验表明,信号转导在许多植物特性中受到系统性调控,包括防御机制以及对土壤和光照条件等周围环境的响应。下胚轴微嫁接是分析地上部与根部之间信号转导的有力工具;然而,微嫁接需要较高的操作技巧,在此过程中要对小幼苗进行显微解剖和显微操作,这限制了其应用。在此,我们开发了一种由硅树脂制成的微器件,称为微嫁接芯片,以便轻松且均匀地进行微嫁接。微嫁接芯片具有串联排列的单元,每个单元由用于种子萌发的种子袋和用于固定下胚轴的微通道组成。所有微嫁接程序均在芯片上进行。这种使用微嫁接芯片的方法将无需培训,并促进植物系统性信号传导的研究。图形摘要:一种便于嫁接的硅树脂芯片。