Progress on the Molecular Mechanism of Scion-rootstock Interactions in Vegetable Grafting

doi:10.13560/j.cnki.biotech.bull.1985.2024-0284

Abstract

Abstract:

Grafting technology is one of the most cost-effective means to increase yield, improve quality and enhance stress tolerance in horticultural crops, and its application is still expanding. In addition to the requirement of continuous improvement of grafting technology, the mechanisms of graft affinity and scion-rootstock interactions need to be further explored. Graft survival includes a series of physiological and biochemical processes, and graft activation, hormonal pathways, or genes involved in vascular bundle formation may be involved in the regeneration and reconstruction of grafted tissues, and it is important to clarify their regulatory mechanisms. Grafting is a process of scion-rootstock mutual recognition and interaction, and long-distance signaling between rootstocks and scions is the basis for understanding the physiology of grafting. Grafted plants with scion-rootstock grafting combinations of different genotypes behave differently in terms of growth and development, phenotype, yield and stress resistance. In this paper, we review the research progress on the molecular mechanisms of scion-rootstock interactions in vegetable grafting, such as grafting survival, genetic signaling between rootstocks, grafting and epigenetic changes, and grafting and gene expression, with a view to providing theoretical references for in-depth studies on the molecular mechanisms of vegetable grafting, and providing guidance for rootstock selection and innovation of vegetable germplasm materials.

Key words: vegetable grafting, graft healing, genetic material exchange, epigenetic modification, gene expression regulation

WANG Feng-ting, ZHAO Fu-shun, QIAO Kai-bin, XU Xun, LIU Jin-liang. Progress on the Molecular Mechanism of Scion-rootstock Interactions in Vegetable Grafting[J]. Biotechnology Bulletin, 2024, 40(10): 149-159.

Figures/Tables 2

References 99

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RNA种类RNA type	名称 Name	作用 Function	蔬菜名称 Species	运动方向 Moving direction	参考文献 Reference
mRNA	NACP	影响顶端组织分化Affect the apical meristem	南瓜Pumpkin	砧木到接穗Rootstock to scion	[50]
	Homeobox1	调控块茎生长Regulate tuber growth	马铃薯Potato	砧木到接穗Rootstock to scion	[51]
	IAA18/28	影响根生长Affect root growth	甜瓜Melon	接穗到砧木Scion to rootstock	[52]
	GAI	影响顶端组织分化Affect the apical meristem	南瓜Pumpkin	接穗韧皮部到茎尖Scion phloem to shoot	[53]
	BEL11	抑制块茎的生长Inhibit tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[51]
	BEL29	抑制块茎的生长Inhibit tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[51]
	PS	抗灰霉病菌Resist to gray mold	番茄Tomato	双向运输Bidirectional movement	[54]
miRNA	miR399	稳定磷元素Stabilize phosphorus	油菜，南瓜 Rape, pumpkin	接穗到砧木Scion to rootstock	[55]
	miR395	稳定硫元素Stabilize sulfur	油菜Rape	接穗到砧木Scion to rootstock	[56]
	miR172	调控花和块茎的生长 Regulate the growth of flower and tuber	马铃薯Potato	接穗到砧木Scion to rootstock	[57]
	miR156	影响叶片形态和块茎生长 Affect leaf morphology and tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[58]
	miR408	稳定铜元素Stabilize copper	西瓜Watermelon	砧木到接穗Rootstock to scion	[59]
siRNA	siRNA	DNA甲基化DNA methylation	番茄Tomato	双向运输Bidirectional movement	[60]
siRNA	siRNA	影响病毒Affect virus	番茄Tomato	砧木到接穗Rootstock to scion	[61]
lncRNA	lncRNA	稳定磷元素Stabilize phosphorus	黄瓜Cucumber	接穗到砧木Scion to rootstock	[62]

RNA种类RNA type	名称 Name	作用 Function	蔬菜名称 Species	运动方向 Moving direction	参考文献 Reference
mRNA	NACP	影响顶端组织分化Affect the apical meristem	南瓜Pumpkin	砧木到接穗Rootstock to scion	[50]
	Homeobox1	调控块茎生长Regulate tuber growth	马铃薯Potato	砧木到接穗Rootstock to scion	[51]
	IAA18/28	影响根生长Affect root growth	甜瓜Melon	接穗到砧木Scion to rootstock	[52]
	GAI	影响顶端组织分化Affect the apical meristem	南瓜Pumpkin	接穗韧皮部到茎尖Scion phloem to shoot	[53]
	BEL11	抑制块茎的生长Inhibit tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[51]
	BEL29	抑制块茎的生长Inhibit tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[51]
	PS	抗灰霉病菌Resist to gray mold	番茄Tomato	双向运输Bidirectional movement	[54]
miRNA	miR399	稳定磷元素Stabilize phosphorus	油菜，南瓜 Rape, pumpkin	接穗到砧木Scion to rootstock	[55]
	miR395	稳定硫元素Stabilize sulfur	油菜Rape	接穗到砧木Scion to rootstock	[56]
	miR172	调控花和块茎的生长 Regulate the growth of flower and tuber	马铃薯Potato	接穗到砧木Scion to rootstock	[57]
	miR156	影响叶片形态和块茎生长 Affect leaf morphology and tuber growth	马铃薯Potato	接穗到砧木Scion to rootstock	[58]
	miR408	稳定铜元素Stabilize copper	西瓜Watermelon	砧木到接穗Rootstock to scion	[59]
siRNA	siRNA	DNA甲基化DNA methylation	番茄Tomato	双向运输Bidirectional movement	[60]
siRNA	siRNA	影响病毒Affect virus	番茄Tomato	砧木到接穗Rootstock to scion	[61]
lncRNA	lncRNA	稳定磷元素Stabilize phosphorus	黄瓜Cucumber	接穗到砧木Scion to rootstock	[62]