Scientia Agricultura Sinica ›› 2020, Vol. 53 ›› Issue (15): 3158-3168.doi: 10.3864/j.issn.0578-1752.2020.15.015

• HORTICULTURE • Previous Articles     Next Articles

Cloning, Expression and Electrophysiological Function Analysis of Potassium Channel Gene VviSKOR in Grape

SHEN JingYuan1(),TANG MeiLing2(),YANG QingShan1,3,GAO YaChao1,LIU WanHao1,2,CHENG JieShan1,ZHANG HongXia1,SONG ZhiZhong1,4()   

  1. 1College of Agriculture, Ludong University/Key Laboratory of Molecular Module-Based Breeding of High Yield and Abiotic Resistant Plants in Universities of Shandong, Yantai 264025, Shandong, China
    2Institute of Grape, Yantai Academy of Agricultural Science, Yantai 264000, Shandong, China
    3Shandong Academy of Forestry, Jinan 250014, China
    4Department of Plant Science, University of Cambridge, Cambridge UK CB2 3EA
  • Received:2019-12-30 Accepted:2020-02-23 Online:2020-08-01 Published:2020-08-06
  • Contact: ZhiZhong SONG E-mail:1391570440@qq.com;tmling1999@163.com;szhzh2000@163.com

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Abstract:

【Objective】The aim of this study was to isolate and characterize potassium (K+) channel gene SKOR (stelar K+ outward rectifier) from grape genome, based on the analysis of the tissue-specific expression patterns of VviSKOR gene and response to K+ depletion, K+ excess, NaCl and ABA treatments, as well as function study by patch clamping electrophysiological technology.【Method】By carrying out homology-based cloning, a putative K+ channel gene VviSKOR was screened and isolated from grape genome. The details of VviSKOR gene were analyzed, and the protein encoded via utilizing bioinformatical analysis software. With the help of MEGA7.0 software, a phylogenetic tree was constructed by multiple alignments of SKOR proteins from grape, Arabidopsis, rice, maize, sorghum, slender false brome, soybean, tomato, cucumber, poplar, peach, pear, strawberry, apple, papaya, citrus, banana and pineapple. Using quantitative real-time PCR (qRT-PCR), the expression profiles of VviSKOR gene and its response to K+ depletion, NaCl and ABA treatments were analyzed. Preliminary analized the physiological function of VviSKOR gene by using patch clamping.【Result】VviSKOR was isolated and determined from grape genome. VviSKOR contained the functional domains of cyclic nucleotide-binding domain, ion channel transmembrane, ankyrin repeats and KHA domain, which belonged to the classic plant potassium channels. The amino acid sequences of SKOR protein from 18 plants shared an overall identity of 58.92%. Phylogenetic tree analysis showed that VviSKOR was closely clustered with homolog of CsaSKOR from cucumber. SKOR members from 4 grass family plants (maize, rice, slender false brome and sorghum) were prone to be clustered together, while SKOR members from Rosaceae, including strawberry, apple, pear and peach, were prone to be clustered together. VviSKOR was mainly localized in plasma membrane, which contained 6 transmembrane domains (TMs), and the theoretical isoelectric point (PI) was 6.24. Twelve kinds of cis-acting regulatory elements, including stress response, hormone response and cell cycle regulation, were found in the promoter region of VviSKOR gene. Database expression profile analysis showed that VviSKOR gene was expressed in different tissues or organs in grape, and the highest percentage was predicted in roots, followed by leaves and xylem. qRT-PCR analysis showed that VviSKOR gene was mainly expressed in roots of both 7-year-old ‘Marselan' and young seedlings. Moreover, VviSKOR gene was more sensitive to K+ depletion, ABA and NaCl treatments, whose expression were decreased under K+ depletion and ABA treatments, but induced under NaCl treatment in all tested tissues, including roots, and roots. Expression of VviSKOR gene had no response to NaCl treatment. Preliminary evidence of patch clamp analysis revealed that outward current was recorded in HEK293-T cells transfected with pTracer-CMV3-SKOR plasmid, and the amount of released K+ was reduced with elevated external-K+, indicating that VviSKOR was an outwardly rectifying K+ channel. In addition, the recorded current increased with the enhancement of voltage, indicating that VviSKOR was also a voltage dependent K+ channel.【Conclusion】VviSKOR gene was mainly expressed in grape roots (mature trees and seedlings). VviSKOR was closely clustered with homolog of CsaSKOR from cucumber in phylogenetic tree. Expression of VviSKOR gene was prone to be regulated by K+ depletion, ABA, and NaCl treatment. VviSKOR was an outwardly rectifying K+ channel that dominated the K+ release in grape roots.

Key words: grape, Shaker type potassium channel, SKOR, gene cloning and expression, patch clamping

Table 1

Specific primers used in this work"

目的
Intention		 引物
Primer (5′-3′)		 扩增产物大小
Amplicon size (bp)
VviSKOR CDS扩增
Amplication of VviSKOR CDS		 F: ATGATGAATGATTGGTTCTCTG
R: CTAAATATCTAGTGTTTCACAT		 2385
SKOR特异性表达引物
Specific expression primers of SKOR		 F: GTGGTTTTCTGTGTGCGACC
R: GCCACATGAAGTGGGGTTCT		 118
Ubiquitin特异性表达引物
Specific expression primers of Ubiquitin		 F: CCTCATCTTCGCTGGCAAAC
R: GGTGTAGGTCTTCTTCTTGCG		 133
pTracer-CMV3-SKOR质粒构建
Construction of plasmid of pTracer-CMV3-SKOR vector		 F: GAGAGAATTCCATGATGAATGATTGGTTC
R: GAGAGCGGCCGCCTAAATATCTAGTGTTTC		 2385

Fig. 1

Domain of VvSKOR and gene structure of VviSKOR gene A: Domain prediction; B: Gene structure analysis"

Table 2

Information of nineteen SKOR proteins from sequenced plant"

物种
Species		 蛋白
Protein		 GenBank登录号
GenBank No.		 编码区
CDS (bp)		 氨基酸数目
Amino acid No.
葡萄Vitis vinifera VviSKOR GSVIVT01030667001 2385 794
拟南芥Arabidopsis thaliana AthSKOR AT3G02850 2487 828
水稻Oryza sativa OsaSKOR LOC_Os06g14030 2577 858
玉米Zea mays ZmaSKOR GRMZM2G310569_T01 2640 879
高粱Sorghum bicolor SbiSKOR Sobic.010G102800 2565 854
短柄草Brachypodium distachyon BdiSKOR Bradi1g44317 2502 833
大豆Glycine max GmaSKOR Glyma.02G243400 2550 849
番茄Solanum lycopersicum SlySKOR Solyc11g011500 2490 829
黄瓜Cucumis sativus CsaSKOR Cucsa.034670 2487 828
白杨Populus trichocarpa PtrSKOR Potri.017G135400 2526 841
Prunus persica PpeSKOR Prupe.3G164900 2493 830
Pyrus bretschneideri PbrSKOR Pbr022827 2521 839
草莓Fragaria vesca FveSKOR mrna30492.1-v1.0-hybrid 3795 1264
苹果Malus domestica MdoSKOR MDP0000263295 2523 840
木瓜Carica papaya CpaSKOR evm.model.supercontig_116.82 2376 791
柑橘Citrus sinensis CsiSKOR orange1.1g003425m 2466 821
香蕉Musa acuminata MacSKOR GSMUA_Achr9T15840_001 2538 845
凤梨Ananas comosus AcoSKOR Aco002953 2457 818

Fig. 2

Identity analysis of highly conservative regions of SKOR proteins from 18 plants"

Fig. 3

The phylogenetic tree of SKOR proteins from 18 plants"

Fig. 4

Subcellular localization prediction of VviSKOR"

Table 3

The cis-elements in the promoter regions of VviSKOR"

顺式作用元件
cis-regulatory element		 特征序列
Characteristic sequence		 潜在调控途径
Putative regulatory pathway
CAAT-box CAAT 启动子和增强子区域
Promoter and enhancer regions
GATA-motif GATAGGG 光感应 Light response
Sp1 GGGCGG 光感应 Light response
Box 4 ATTAAT 光感应 Light response
G-Box CACGTT 光感应 Light response
TCT-motif TCTTAC 光感应 Light response
ARE AAACCA 厌氧诱导 Anaerobic induction
MSA-like TCAAACGGT 细胞周期调控 Cell cycle regulation
TGACG-motif TGACG 茉莉酮酸甲酯响应
Methyl jasmonate response
CGTCA-motif CGTCA 茉莉酮酸甲酯响应
Methyl jasmonate response
ABRE ACGTG 脱落酸响应 Abscisic acid response
LTR CCGAAA 低温感应Low temperature

Fig. 5

Expression profiles analysis of VviSKOR"

Fig. 6

Real time quantitative PCR expression analysis of VviSKOR in different tissues in 7-year-old grape tree"

Fig. 7

Response of VviSKOR gene under K+ depletion, high K+, ABA and NaCl stresses in seedlings **indicates statistically extremely significant differences (P<0.01)"

Fig. 8

Physiological function of VviSKOR gene by using patch clamping"

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