Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (10): 2154-2166.doi: 10.3864/j.issn.0578-1752.2021.10.011

• HORTICULTURE • Previous Articles     Next Articles

Research Advances of Applying Virus-Induced Gene Silencing in Vegetables

LI Jie(),LUO JiangHong,YANG Ping()   

  1. College of Life Science and Technology, Honghe University, Key Laboratory for Research and Utilization of Characteristic Biological Resources in Southern Yunnan, Mengzi 661100, Yunnan
  • Received:2020-07-31 Accepted:2020-12-08 Online:2021-05-16 Published:2021-05-24
  • Contact: Ping YANG E-mail:gsau23@126.com;gsau123@163.com

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Abstract:

Recently, the virus-induced gene silencing (VIGS) as a reverse genetics tool is used for gene function analysis. Due to its advantages of simple construction, low cost and short cycle, VIGS technology has been extensively and deeply studied in the field of functional genomics. VIGS technology, as a fast, effective, high-throughout new technology, has played an important role in research of vegetable functional genes in plant development processes, disease resistance, stress resistance, biosynthesis and metabolic regulation. Herein, it is of great significance to excavate new genes and identify the function of disease resistance, stress resistance genes, crop improvement and molecular breeding by using VIGS technology. Many VIGS systems with virus as vector have been successfully established in vegetable crops, but they still have some shortcomings. With the in-depth exploration of the mechanism of VIGS and the continuous development of virus vectors, VIGS has been applied to a wider range of vegetable crops. This paper reviewed the current status and research progresses of gene function of eggplant, melons and leafy vegetables based on VIGS technology in recent years, and the mechanism of VIGS technology, the application of virus vector and the progress of VIGS technology was briefly analyzed. Meanwhile, the advantages and disadvantages of VIGS technology, RNA interference (RNAi) and current CRISP/CAS9 technology were compared and analyzed. It focused on the application of VIGS technology in vegetable fruit development and disease resistance, and the latest progresses of VIGS technology in vegetable crop metabolic regulation, hormone regulation, biotic and abiotic stress responses were summarized. The cases of studying target genes function and silencing phenotypes of solanaceous, melon, leafy and legume vegetables by VIGS were listed. Finally, the problems and deficiencies of VIGS technology in studying gene function of vegetable crops were summarized, such as lack of suitable VIGS vector, lack of effective virus vector infection method, difficulty in systematic silencing in some tissues, low silencing efficiency, inherent limitations of VIGS, etc. At the same time, the future research directions of VIGS technology in the development of virus vectors with higher specificity and stability, selection of efficient gene fragments, and establishment of virus vectors suitable for more host range were proposed. The application foreground of gene function analysis, improvement, molecular breeding of vegetable crops and production not carrying exogenous gene of vegetable varieties by VIGS technique was prospected. This review would provide a guidance and give ideas for future studies on the growth and development of vegetable crops, secondary metabolism and adversity stress related gene function research and breakthrough in the key factors restricting VIGS technique.

Key words: gene silencing, VIGS, vegetable, gene function

Table 1

List of genes silenced by VIGS and the phenotype observed in solanaceous vegetable"

物种
Species		 靶基因
Target gene		 载体
Vector		 功能
Function		 沉默表型
Silencing phenotype		 参考文献
Reference
番茄
Tomato		 KAS III, KAS IV/II-like TRV 酰基糖代谢
Acyl glucose metabolism		 直链脂肪酸减少
Reduced straight-chain fatty acids		 [36]
番茄
Tomato		 SlSWEET1 TRV 糖的转运
Sugar transport		 己糖含量降低
Decreased hexose		 [37]
辣椒
Pepper		 CaMYB108 TRV 辣椒素合成
Capsaicin synthesis		 花粉延迟开裂
Delayed pollen cracking		 [38]
辣椒
Pepper		 pAMT ALSV 辣椒素合成
Capsaicin synthesis		 辣椒素含量降低
Capsaicin content decreased		 [39]
番茄
Tomato		 SLAR TRV 类胡萝卜素合成
Carotenoids synthesis		 类胡萝卜素含量降低
Carotenoids content decreased		 [40]
茄子
Eggplant		 PDS, CHLI, CHLH TRV 镁螯合酶
Magnesium chelatase		 叶片发黄
Foliage yellowing		 [41]
茄子
Eggplant		 CHS TRV 类黄酮的合成
Flavonoids synthesis		 果实颜色变浅,果实弯曲
Changed fruit color and fruit curved		 [42]
番茄
Tomato		 SlILL TRV 生长素合成
Auxin synthesis		 加速离层
Accelerate the abscission layer		 [43]
番茄
Tomato		 LeCTR1 TRV 乙烯合成
Ethylene synthesis		 叶片弯曲减轻
Reduced leaf curve		 [44]
番茄
Tomato		 DEK TRV 抗病性
Disease resistance		 抗病性减弱
Attenuates disease resistance		 [45]
茄子 SPDS TRV 抗枯萎病
Resistant to wilt		 抗病性减弱
Attenuates disease resistance		 [46]
辣椒
Pepper		 CaPHL8 TRV 青枯病
Bacterial wilt		 抗病性减弱
Attenuates disease resistance		 [47]
番茄
Tomato		 SAHH1, MS1, GAD2 TRV 青枯病
Bacterial wilt		 抗病性减弱
Attenuates disease resistance		 [48]
番茄
Tomato		 ShORR-1 TRV 白粉病
Powdery mildew		 叶片病斑增多
Leaf lesions increased		 [49]
辣椒
Pepper		 CaWRKY45, CaWRKY58 TRV 抗病和抗旱
Resistance to disease and drought		 抗性减弱
Attenuates disease resistance		 [50]
番茄
Tomato		 ABC-C6, ABC-G33 TRV 根系分泌
The root secretion		 根结线虫减少
Reduced nematodes		 [51]
茄子
Eggplant		 NBS-LRR TRV 根结线虫
Nematodes		 抗病性减弱
Attenuates disease resistance		 [52]
辣椒
Pepper		 CaWRKY27 TRV 盐胁迫
Salt stress		 抗性减弱
Attenuates resistance		 [53]
番茄
Tomato		 GSTU43 TRV 抗低温性
Chilling resistance		 抗性减弱
Attenuates resistance		 [54]
辣椒
Pepper		 CaDIF1, CaDIS1 TRV 脱落酸和干旱胁迫
ABA and drought stress		 气孔增大,蒸腾增加
Stomata and transpiration increases		 [55]
番茄
Tomato		 MYB80 TRV 抗低温
Chilling stress		 抗低温减弱
Attenuates chilling resistance		 [56]

Table 2

List of genes silenced by VIGS and the phenotype observed in melon, leaf and legume vegetable"

物种
Species		 靶基因
Target gene		 载体
Vector		 功能
Function		 沉默表型
Silencing phenotype		 参考文献
Reference
黄瓜
Cucumber		 GPAT6 TRV 不饱和脂肪酸的合成
Unsaturated fatty acids synthesis		 抗性增强
Enhanced resistance		 [62]
甜瓜
Muskmelon		 LOX10 TRV 脂氧合酶合成
Lipoxygenase synthesis		 细胞程序性死亡
Programmed cell death		 [63]
菠菜
Spinach		 GAL BCTV 调控开花
Regulation flowering		 雌花结构改变
Changed female flower		 [64]
叶用莴苣
Leaf lettuce		 Hsp70 TRV 耐热性
Thermotolerance		 茎伸长
Stem elongation		 [65]
白菜
Chinese Cabbage		 BrAN3, BrBRM TYMV 细胞伸长
Cell elongation		 叶片卷曲,小叶增多
Leaf curled and increased		 [66]
豌豆
Pea		 CHLI PEBV 叶绿素的合成
Chlorophyll synthesis		 叶片发黄
Leaf yellowing		 [67]
豌豆
Pea		 PsPIP2 PEBV 水通道蛋白合成
Aquaporin synthesis		 叶片和根系衰退
Organ declines of leaf and root		 [68]
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