核桃JrERF2⁃2基因克隆及其对逆境的响应

doi:10.3969/j.issn.1000-2006.201909031

国家林草科技领军期刊
中国精品科技期刊
中国高校百佳科技期刊
江苏省新闻出版政府奖期刊奖
RCCSE林学权威期刊（A+）
CSCD核心期刊
Scopus数据库收录期刊
中文核心期刊
SCD核心期刊

作者加群：102861116

微信公众号：南京林业大学学报

高级检索

南京林业大学学报（自然科学版） ›› 2020, Vol. 44 ›› Issue (3): 58-64.doi: 10.3969/j.issn.1000-2006.201909031

核桃JrERF2⁃2基因克隆及其对逆境的响应

刘玉梅¹(), 赵焕元¹, 崔茂凯¹, 王田雨¹, 高向倩¹, 杨桂燕¹^,²()

^1.西北农林科技大学林学院山阳核桃试验示范站，陕西杨凌 712100
^2.西北农林科技大学林学院，陕西省经济植物资源开发利用重点实验室，陕西杨凌 712100

收稿日期:2019-09-13 修回日期:2020-02-21 出版日期:2020-05-30 发布日期:2020-06-11
通讯作者: 杨桂燕
作者简介:刘玉梅（2534666517@qq.com）。
基金资助:
国家自然科学基金项目(31800510);西北农林科技大学省级大学生创新创业训练计划项目(S201910712143)

Cloning and stress response of the JrERF2⁃2 gene from Juglans regia

LIU Yumei¹(), ZHAO Huanyuan¹, CUI Maokai¹, WANG Tianyu¹, GAO Xiangqian¹, YANG Guiyan¹^,²()

^1.Walnut Experiment Station of Shanyang, College of Forestry, Northwest A&F University, Yangling 712100, China
^2.Key Laboratory of Economic Plant Resources Development and Utilization in Shaanxi Province, College of Forestry, Northwest A&F University, Yangling 712100, China

Received:2019-09-13 Revised:2020-02-21 Online:2020-05-30 Published:2020-06-11
Contact: YANG Guiyan

摘要/Abstract

摘要： 目的

核桃（Juglans regia）是我国重要的木本粮油战略及扶贫攻坚树种，其生长发育受不良环境条件制约，但目前核桃响应逆境的适应机制尚不明确，影响了核桃产业的科学管理，妨碍了核桃产业综合效益的提高。该研究筛选优良抗逆候选基因，以揭示核桃抗逆适应机制。

方法

以“Ethylene Response Factor”为关键词在‘香玲’核桃转录组中筛选ERF转录因子家族成员，经同源比对、开放读码框（ORF）、序列基本特征、PCR克隆等分析后选取其中的JrERF2?2进行基本生物信息及逆境表达分析。胁迫包括盐（NaCl）、干旱（PEG₆₀₀₀）及脱落酸（ABA）处理。

结果

JrERF2?2基因的ORF长906 bp，编码蛋白含262个氨基酸，分子质量为74.43 ku，理论等电点为5.07，与白桦（Betula platyphylla）、欧洲栓皮栎（Quercus suber）的ERF蛋白具有较近的亲缘关系，其上游1 455 bp启动子中含多种逆境相关顺式作用元件，如干旱早期响应元件（ACGTATERD1）、热胁迫响应元件（CCAATBOX1）、低温响应元件（LTRE1HVBLT49）等。实时荧光定量PCR（qRT-PCR）发现，JrERF2?2在NaCl、PEG₆₀₀₀、ABA处理下均可被诱导表达，且在胁迫后不同时期表达程度不同。

结论

JrERF2?2受ABA和渗透胁迫诱导，在植物逆境响应中具有一定作用，是核桃逆境适应机制研究的重要候选基因。

关键词: 核桃, JrERF2?2, 基因克隆, 启动子, 逆境响应

Abstract: Objective

Walnut (Juglans regia) is an important woody oil stratey and poverty allevintion tree species in China. Whose growth and development can be affected by adverse environmental conditions such as low temperature, drought or high salt concentrations. However, adaptation mechanisms of walnut trees to such conditions are not comprehensively understood, which limits optimization of management strategies in the walnut industry in terms of improving production quantity and quality. In order to investigate walnut resistance to stress, candidate genes associated with stress resistance were screened in the present study.

Method

The Ethylene Response Factor (ERF) was used to screen members of the ERF transcription factor family in the transcriptome of ‘Xiangling’ walnut. Following homology alignments, open reading frame (ORF) confirmation, sequence basic characteristics analyses, and PCR-based vector cloning, an ERF termed JrERF2?2 was selected for further analyses.

Result

Using the ExPASy bioinformatics portal, prediction analyses suggested a 906 bp ORF of the JrERF2?2 gene that encodes a protein consisting of 262 amino acids; the mole?cular weight of this protein is 74.43 ku, and the theoretical isoelectric point is 5.07. CD?Search showed an AP2 domain in the JrERF2?2 protein. BLASTP and MEGA analyses suggested considerable similarity of the JrERF2?2 protein with ERF proteins of Betula platyphylla and Quercus suber, indicating potentially similar functions of JrERF2?2 and its homologs. Moreover, to investigate potential adaption to adverse stimuli, a 1 455 bp upstream promoter was identified in the walnut genome, and cis-acting elements were predicted using New PLACE analyses. The results showed that this promoter segment included a variety of stress-related cis-acting elements such as the drought early response element (ACGTATERD1), heat stress response element (CCAATBOX1), and low temperature response element (LTRE1HVBLT49), suggesting that this promoter may regulate JrERF2?2 expression during stress responses. Therefore, to further investigate the role of JrERF2?2 in stress response mechanisms, 2-year-old grafted ‘Xiangling’ walnut seedlings were subjected to salt, drought and abscisic acid (ABA) stress. JrERF2?2 expression was quantified using reverse-transcription quantitative PCR (qRT-PCR) analysis. Salt treatment was applied using 0.3 mol/L sodium chloride (NaCl) for 0, 3, 12 and 24 h; drought stress was elicited using 100 g/kg PEG₆₀₀₀ for 0, 3, 4 and 5 days, and the ABA treatment was applied using 0.1 mmol/L ABA for 0, 3, 24 and 48 h. Total RNA was isolated from leaf samples using a cetyltrimethylammonium bromide (CTAB) method. RNA was then reverse-transcribed to cDNA which was diluted 10-fold for use as a qRT-PCR template. Reverse transcription was performed using a PrimeScript^TMRT Reagent Kit (CWBIO, Kangwei Century, China), and the reaction was incubated at 42 ℃ for 60 min and at 85 ℃ for 5 s. A SYBR Green Real-time PCR Master Mix and the PCR primers JrERF2-2-F (5′-TGTCACCGAAGTTCCGGAT-3′) and JrERF2-2-R (5′-GATGCAGCTTCTCTAGTC-3′) were used for qRT-PCR. Walnut 18S rRNA (HE574850) was used as an internal reference. Relative expression le?vels were recorded using a 2^-ΔΔCtmethod. The qRT-PCR results showed that JrERF2?2 expression was induced by the NaCl, PEG₆₀₀₀ and ABA treatments, at different transcription levels. Under NaCl stress, JrERF2?2 expression levels increased over time. Relative expression at 12 and 24 h was 2.68- and 6.70-fold higher, respectively, than that at 3 h. Under exposure to PEG₆₀₀₀, JrERF2?2 expression also increased continuously over time with up to 4.12-fold increased expression compared to the control. In the ABA treatment, JrERF2?2 expression was similar to that under NaCl stress, and maximum values observed at 48 h were 6.57-fold higher than those at 3 h. NaCl, drought and ABA treatment results indicated that JrERF2?2 expression can be induced by these stressors.

Conclusion

Thus, JrERF2?2 is an important member of the ERF family and may have similar functions to homologs in other species. Its upstream promoter contains many cis-elements associated with stress responses, suggesting that this promoter can effectively regulate JrERF2?2 expression in response to stress. JrERF2?2 expression can be induced by salt, drought and ABA treatments, to varying degrees, and the expression patterns shared certain similarities, indicating that JrERF2?2 can respond to drought- and salt-induced osmotic stress. Moreover, JrERF2?2 may be involved in the ABA signaling pathway. Taken together, JrERF2?2 is an important candidate gene for revealing the mechanism of walnut adaptation to adverse conditions.

Key words: Juglans regia, JrERF2?2, gene cloning, promoter, stress response

中图分类号:

S785.5

刘玉梅,赵焕元,崔茂凯,等. 核桃JrERF2⁃2基因克隆及其对逆境的响应[J]. 南京林业大学学报（自然科学版）, 2020, 44(3): 58-64.

LIU Yumei, ZHAO Huanyuan, CUI Maokai, WANG Tianyu, GAO Xiangqian, YANG Guiyan. Cloning and stress response of the JrERF2⁃2 gene from Juglans regia[J].Journal of Nanjing Forestry University (Natural Science Edition), 2020, 44(3): 58-64.DOI: 10.3969/j.issn.1000-2006.201909031.

图/表 3

图1

表1

New PLACE预测JrERF2?2启动子顺式作用元件"

顺式作用元件 cis?element	起始位点 start site	序列 sequence	特性 characteristic
ACGTATERD1	35/809/844/1125/1156/1169/1221	ACGT	干旱早期响应early drought responsiveness
CCAATBOX1	1254	CCAAT	热胁迫响应heat stress responsiveness
CURECORECR	705/811/819/848	GTAC	铜响应元件copper?responsive element
GT1GMSCAM4	783/899	GAAAAA	病害、盐诱导disease, salt responsive element
LTRE1HVBLT49	1414	CCGAAA	低温响应low temperature responsiveness
LTRECOREATCOR15	1153	CCGAC	低温响应low temperature responsiveness
SURECOREATSULTR11	32/740	GAGAC	硫响应sulfur responsiveness
CAREOSREP1	1230	CAACTC	赤霉素调控gibberellin?responsive element
GAREAT	722	TAACAAR	GARE响应、赤霉素调控GARE responsiveness and gibberellin?responsive element
T/GBOXATPIN2	1124	AACGTG	茉莉酸(JA)诱导MeJA?responsiveness
ABRELATERD1	844/1125/1156	ACGTG	ABRE转录因子识别ABRE?like sequence
ABRERATCAL	843/1124	MACGYGB	ABRE转录因子识别ABRE?like sequence
ARR1AT	360/417/432/761/1021/1063/1443	NGATT	响应调节因子ARR1识别responsiveness regulated ARR1 binding site
ARFAT	1130	TGTCTC	激素响应因子ARF识别auxin response factor ARR1 binding site
CACGTGMOTIF	843	CACGTG	ERF转录因子识别ERF binding site
CBFHV	1091/1152	RYCGAC	CBF转录因子结合位点CBF binding site
DOFCOREZM	28/64/292/309/403/408/798/896/954/1107	AAAG	Dof转录因子识别Dof binding site
DPBFCOREDCDC3	842/1242	ACACNNG	bZIP转录因子识别bZIP binding site
DRE2COREZMRAB17	1152	ACCGAC	DREB转录因子识别、干旱响应DREB binding site and drought responsiveness
DRECRTCOREAT	1152	RCCGAC	DREB转录因子识别、干旱响应DREB binding site and drought responsiveness
LECPLEACS2	971/1033	TAAAATAT	Cys蛋白酶结合元件Cys proteinase combine element
MYBCORE	756/1010	CNGTTR	MYB转录因子识别MYB binding site
MYBGAHV	722	TAACAAA
MYBPZM	1360	CCWACC
MYBST1	232	GGATA
MYCATERD1	1294	CATGTG	MYC转录因子识别MYC binding site
MYCATRD22	500	CACATG
MYCCONSENSUSAT	500/843/1255/1263/1294	CANNTG
WBOXATNPR1	839/1119	TTGAC	W?BOX，WRKY识别W?BOX, WRKY binding site
WBOXHVISO1	118/1328	TGACT
WBOXNTERF3	118/1328	TGACY
WRKY71OS	118/488/840/1120/1328	TGAC
RAV1AAT	928	CAACA	RAV1转录因子识别RAV1 binding site
SEF1MOTIF	595	ATATTTAWW	SEF结合位点SEF binding site
SEF4MOTIFGM7S	964	RTTTTTR	SEF结合位点SEF binding site
EBOXBNNAPA	500/843/1255/1263/1294	CANNTG	E?box或R响应元件E?box or R responsive?element
NTBBF1ARROLB	374/710/1102	ACTTTA	组织特异性表达 tissue specific expression
OSE1ROOTNODULE	954/163/1438	AAAGAT
CAATBOX1	288/91/568/1255	CAAT
ROOTMOTIFTAPOX1	195/234/281/384/560/595/625/945/962/975/991/1039	ATATT
POLLEN1LELAT52	186/405/898	AGAAA
AACACOREOSGLUB1	723/727	AACAAAC
RHERPATEXPA7	1134/1219	KCACGW
TAAAGSTKST1	291/895/1106	TAAAG
POLASIG1	174/265/289/906	AATAAA	淀粉酶相关amylase?related
POLASIG3	273/333/340/380/862/886/941	AATAAT	淀粉酶相关amylase?related
NODCON1GM	954	AAAGAT	结瘤素相关nodulin?related
NODCON2GM	163/1438	CTCTT	结瘤素相关nodulin?related
-10PEHVPSBD	235	TATTCT	光调控相关light responsive element
BOXCPSAS1	1233	CTCCCAC
GATABOX	10/183/194/233/326/770/957/1201	GATA
GT1CONSENSUS	10187/782/783/899/957	GRWAAW
HDZIP2ATATHB2	272/332	TAATMATTA
IBOXCORE	10/957	GATAA
SORLIP1AT	671/1099	GCCAC

表1

图2

参考文献 24

1	张麒, 陈静, 李俐，等. 植物AP2/ERF转录因子家族的研究进展[J]. 生物技术通报, 2018, 34(8): 1-7.
	ZHANG Q, CHEN J, LI L, et al. Research progress on plant AP2/ERF transcription factor family [J]. Biotechnology Bulletin, 2018, 34(8): 1-7. DOI: 10. 13560/j. cnki. biotech. bull. 1985. 2017-1142.
2	孙滨, 占小登, 曹立勇，等. 水稻AP2/ERF转录因子的研究进展[J]. 农业生物技术学报, 2017, 25(11): 1860-1869.
	SUN B, ZHAN X D, CAO L Y, et al. Research progress of AP2/ERF transcription factor in rice (Oryza sativa) [J]. Journal of Agricultural Biotechnology, 2017, 25(11): 1860-1869. DOI: 10.3969/j.issn.1674-7968.2017.11.013.
3	宋康华, 黎宇婷, 张鲁斌. AP2/ERF转录因子调控果实品质研究进展[J]. 热带作物学报, 2019, 40(5): 1032-1040.
	SONG K H, LI Y T, ZHANG L B. Advances in the regulation of fruit quality by AP2⁃ERF transcription factor [J]. Chinese Journal of Tropical Crops, 2019, 40(5): 1032-1040. DOI: 10. 3969/j.issn.1000-2561.2019.05.028.
4	SAKUMA Y, LIU Q, DUBOUZET J G, et al. DNA‌⁃‌binding specificity of the ERF/AP2 domain of Arabidopsis DREBs, transcription factors involved in dehydration‌⁃ and cold‌⁃‌inducible gene expression‌[J]. Biochemical and Biophysical Research Communications, 2002,290(3):998-1009. DOI:10.1006/bbrc. 2001.6299.
5	王海波, 龚明, 郭俊云，等. 麻疯树AP2/ERF基因家族孤儿基因Soloist的克隆与原核表达分析[J]. 林业科学, 2018, 54(9): 60-69.
	WANG H B, GONG M, GUO J Y, et al. Molecular cloning and prokaryotic expression oforphan gene Soloist of AP2/ERF gene family [J]. Scientia Silvae Sinicae, 2018, 54(9): 60-69. DOI: 10.11707/j.1001-7488.20180908.
6	栗丽, 佟少明. 葡萄(Vitis vinifera)AP2/ERF转录因子基因家族序列分析[J]. 生物技术世界, 2016(4): 18-19.
	SU L, TONG S M. Sequence analysis of AP2/ERF transcription factor gene family of Vitis vinifera[J]. Biotechnology World, 2016(4): 18-19.
7	XIE Z L, NOLAN T, JIANG H, et al. The AP2/ERF transcription factor TINY modulates brassinosteroid‌⁃‌regulated plant growth and drought responses in Arabidopsis[J]. The Plant Cell, 2019, 31(8): 1788-1806. DOI: 10.1105/tpc.18.00918.
8	YUAN Q L, CHAO B L, YING C, et al. Transcriptome⁃based discovery of AP2/ERF transcription factors and expression profiles under herbivore stress conditions in bamboo (Bambusa emeiensis)[J]. Journal of Plant Biology, 2019, 62(4). DOI: 10. 1007/s12374-019-0059-5.
9	李大培, 王艺, 张尚昆，等. 核桃V⁃ATPase c亚基基因(JrVHAc4)的克隆和抗旱功能分析[J]. 南京林业大学学报(自然科学版), 2019, 43(2): 79-85.
	LI D P, WANG Y, ZHANG S K, et al. Drought resistance analysis of a V⁃ATPase c subunit (JrVHAc4) gene from Juglans regia [J]. J of Nanjing For Univ （Nat Sci Ed）, 2019, 43(2): 79-85. DOI: 10.3969/j. issn.1000-2006.
10	傅本重, 邹路路, 朱洁倩, 等. 中国核桃生产现状与发展思路[J]. 江苏农业科学, 2018, 46(18): 5-8.
	FU B Z, ZOU L L, ZHU J Q, et al. Current status and development ideas of China’s walnut production [J]. Jiangsu Agricultural Sciences, 2018, 46(18): 5-8. DOI: 10.15889/j.issn.1002-1302.2018. 18.002.
11	汪文科, 鲁维民, 杨会光. 核桃的经济价值及用途[J]. 中国果菜, 2017, 37(2): 11-14.
	WANG W K, LU W M, YANG H G. The economic value and use of walnut [J]. China Fruit Vegetable, 2017, 37(2): 11-14. DOI: 10. 19590/j. cnki. 1008-1038. 2017. 02. 003.
12	丁声俊, 马榕. 木本粮油产业: 一个重大新型特色产业[J]. 河南工业大学学报(社会科学版), 2015, 11(2): 1-12.
	DING S J, MA R. Woody grain and oil: a major new type of special industry [J]. Journal of Henan University Of Technology (Social Science Edition), 2015, 11(2): 1-12. DOI: 10. 16433/j.cnki.cn41-1379.2015.02.001.
13	张有林, 原双进, 王小纪. 中国核桃加工产业现状与对策[J]. 陕西林业科技, 2015(1): 1-6. ZHANG Y L, YUAN S J, WANG X J. China’s walnut processing and industry: status and countermeasures [J]. Shaanxi Forest Science and Technology, 2015(1): 1-6. DOI: 10.3969/j.issn.1001-2117.2015.01.001.
14	马凯恒, 李子仪, 李大培，等. 核桃JrEFM1转录因子响应逆境及激素的表达模式[J]. 西南师范大学学报(自然科学版), 2019, 44(6): 46-53.
	MA K H, LI Z Y, LI D P, et al. On expression patters of walnut R1⁃MYB transcription factor JrEFM1 responses to different stresses and plant hormones [J]. Journal of Southwest China Normal University (Natural Science Edition), 2019, 44(6): 46-53. DOI: 10.13718/j.cnki.xsxb.2019. 06.011.
15	MARTINE G P J, CREPEAU M W, PUIU D, et al. The walnut (Juglans regia) genome sequence reveals diversity in genes coding for the biosynthesis of non⁃structural polyphenols [J]. The Plant Journal, 2016, 87(5): 507-32. DOI: 10.1111/tpj.13207.
16	LIVAK K J, THOMAS D S. Analysis of relative gene expression data using real⁃time quantitative PCR and the 2^-ΔΔCT method [J]. Methods, 2001, 25(4). DOI: 10. 1006/meth.2001.1262.
17	彭婷, 冯蓝萍, 王艺琴，等. 梅花PmERF4基因的克隆及其表达分析[J]. 华中农业大学学报, 2019, 38(4): 20-26.
	PENG T, FENG L P, WANG Y Q, et al. Cloning and expression of PmERF4 gene in Prunus mume [J]. Journal of Huazhong Agricultural University, 2019, 38(4): 20-26. DOI: 10.13300/j.cnki.hnlkxb.2019.04.003.
18	滕珂, 张蕊, 檀鹏辉，等. 日本结缕草ZjERF1的克隆、转录激活活性、亚细胞定位及表达分析[J]. 草业学报, 2019, 28(6): 56-65.
	TENG K, ZHANG R, TAN P H, et al. Molecular cloning, transcriptional activation, subcellular localization analysis and expression characterization of ZjERF1 from Zoysia japonica [J]. Acta Prataculturae Sinica, 2019, 28(6): 56-65. DOI: 10. 11686/cyxb2018323.
19	王雅慧, 李彤, 黄莹，等. 番茄2个ERF⁃B1亚族转录因子基因的克隆及其对生物和非生物胁迫响应[J]. 核农学报, 2019, 33(10): 1893-1904.
	WANG Y H, LI T, HUANG Y, et al. Cloning and expression analysis under biotic and abiotic stresses of two ERF⁃B1 group transcription factor genes from Solanum lycopersicum[J]. Journal of Nuclear Agricultural Sciences, 2019,33(10):1893-1904. DOI: 10.11869/j.issn.100-8551.
20	王帆. 苹果MdbZIP26基因表达模式及其启动子的功能分析[D]. 杨凌：西北农林科技大学, 2019. WANG F. Expression pattern of apple MdbZIP26 gene and functional analysis of its promoter [D]. Yangling: Northwest Agriculture and Forestry University, 2019.
21	任丽, 董京祥, 杨洋, 等. 白桦BpTCP7基因启动子的克隆及表达分析[J]. 南京林业大学学报(自然科学版), 2019, 43(1): 32-38.
	REN L, DONG J X, YANG Y, et al. Cloning and expression analysis of BpTCP7 promoter from Betula platyphylla [J]. J of Nanjing For Univ (Nat Sci Ed), 2019, 43(1): 32-38. DOI: 10.3969/j.issn.1000-2006.
22	王爽, 王永鑫, 王瑜, 等. 茶树CsCIGR基因克隆及表达特性分析[J]. 西北植物学报, 2019, 39(5): 867-875.
	WANG S, WANG Y X, WANG Y, et al. Cloning and expression profiles analysis of CsCIGR gene in Camellia sinensis [J]. Acta Botanica Boreali⁃Occidentalia Sinica, 2019, 39(5): 867-875. DOI: 10. 7606/j. issn. 1000-4025.
23	SUN X M, ZHANG L L, DARREN C J, et al. The ethylene response factor VaERF092 from Amur grape regulates the transcription factor VaWRKY33, improving cold tolerance [J]. The Plant Journal, 2019, 99(5). DOI: 10.1111/tpj.14378.
24	张春霄. AP2/EREBP家族MfERF049基因对提高豆科植物生物胁迫和非生物胁迫抗性的功能分析[D]. 呼和浩特：内蒙古大学, 2019.
	ZHANG C X. Functional analysis of AP2/EREBP family MfERF049 gene to improve resistance to legumes and abiotic stress [D]. Hohhot: Mongolian University, 2019.

[1]	田梦阳, 朱树林, 窦全琴, 季艳红. 薄壳山核桃-茶间作对‘安吉白茶’速生期光合特性的影响[J]. 南京林业大学学报（自然科学版）, 2024, 48(2): 86-96.
[2]	刘增才, 王淑婷, 佟鑫宇, 邹莉. 暴马桑黄GPS基因克隆及响应茉莉酸甲酯诱导表达研究[J]. 南京林业大学学报（自然科学版）, 2023, 47(4): 123-130.
[3]	魏祯祯, 宋程威, 郭丽丽, 郭琪, 侯小改. ‘凤丹’PoERF4基因的克隆及表达分析[J]. 南京林业大学学报（自然科学版）, 2023, 47(3): 56-62.
[4]	张赟齐, 董宁光, 郝艳宾, 陈永浩, 张俊佩, 侯智霞, 苏淑钗, 吴佳庆, 齐建勋. 109份丰产核桃单株坚果表型多样性分析及性状评价[J]. 南京林业大学学报（自然科学版）, 2023, 47(3): 87-96.
[5]	李建挥, 李柏海, 吴思政, 柏文富, 禹霖, 聂东伶, 严佳文, 熊颖, 向祖恒, 彭先凤. 湘西地区核桃坚果表型特征及多样性研究[J]. 南京林业大学学报（自然科学版）, 2023, 47(1): 171-179.
[6]	唐敏, 杨开宇, 张赛男, 陈利英, 刘洋, 张雪梅, 齐国辉. 硒对核桃种仁抗氧化酶活性及果实品质的影响[J]. 南京林业大学学报（自然科学版）, 2022, 46(5): 127-134.
[7]	贾展慧, 贾晓东, 许梦洋, 莫正海, 翟敏, 宣继萍, 张计育, 王刚, 王涛, 郭忠仁. 薄壳山核桃原花青素合成关键酶基因的克隆与表达分析[J]. 南京林业大学学报（自然科学版）, 2022, 46(5): 49-57.
[8]	田梦阳, 窦全琴, 谢寅峰, 汤文华, 季艳红. 4个薄壳山核桃品种的光合特性研究[J]. 南京林业大学学报（自然科学版）, 2022, 46(5): 67-74.
[9]	黄小辉, 吴焦焦, 王玉书, 冯大兰, 孙向阳. 不同供氮水平的核桃幼苗生长及叶绿素荧光特性[J]. 南京林业大学学报（自然科学版）, 2022, 46(2): 119-126.
[10]	季琳琳, 陈素传, 吴志辉, 常君, 陶汝鹏, 周米生, 蔡新玲. 山核桃果实主要经济性状和养分含量的差异分析[J]. 南京林业大学学报（自然科学版）, 2022, 46(1): 131-137.
[11]	季艳红, 潘平平, 窦全琴, 谢寅峰. 不同泥炭替代基质对薄壳山核桃幼苗生长及叶绿素荧光特性的影响[J]. 南京林业大学学报（自然科学版）, 2022, 46(1): 145-155.
[12]	林莉莉, 胡安琪, 陈钢, 张霁月, 曹光球, 曹世江. 杉木ClWRKY44基因克隆及其表达特性分析[J]. 南京林业大学学报（自然科学版）, 2022, 46(1): 203-209.
[13]	季艳红, 汤文华, 窦全琴, 谢寅峰. 施肥对薄壳山核桃容器苗生长及养分积累的影响[J]. 南京林业大学学报（自然科学版）, 2021, 45(6): 47-56.
[14]	黎梦娟, 朱礼明, 霍俊男, 张景波, 施季森, 成铁龙. 唐古特白刺NtCBL1、NtCBL2基因克隆及表达分析[J]. 南京林业大学学报（自然科学版）, 2021, 45(3): 93-99.
[15]	蒋瑶, 魏海林, 高昌虎, 王大故, 冯楠可, 李睿, 刘榕榕, 吕芳德. 湖南低山丘陵区薄壳山核桃的开花物候期观测及品种配置[J]. 南京林业大学学报（自然科学版）, 2021, 45(1): 53-62.

核桃JrERF2⁃2基因克隆及其对逆境的响应

Cloning and stress response of the JrERF2⁃2 gene from Juglans regia

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 3

参考文献 24

相关文章 15

编辑推荐

Metrics

本文评价

作者

读者

审稿