nsLTPs基因参与植物逆境胁迫应答的研究进展

doi:10.11924/j.issn.1000-6850.casb2020-0806

中国农学通报 ›› 2021, Vol. 37 ›› Issue (18): 95-101.doi: 10.11924/j.issn.1000-6850.casb2020-0806

所属专题：生物技术

nsLTPs基因参与植物逆境胁迫应答的研究进展

马悦¹^,²(), 于冰¹^,²()

¹黑龙江大学农业微生物技术教育部工程研究中心,哈尔滨 150500
²黑龙江大学生命科学学院/黑龙江省普通高校分子生物学重点实验室,哈尔滨 150080

收稿日期:2020-12-21 修回日期:2021-02-08 出版日期:2021-06-25 发布日期:2021-07-13
通讯作者: 于冰
作者简介:马悦,女,1995年出生,黑龙江双鸭山人,硕士研究生,研究方向：植物分子生物学。通信地址：150080 黑龙江省哈尔滨市学府路74号黑龙江大学生命科学学院320室,Tel：18845125228,E-mail： 18845125228@163.com。
基金资助:
国家自然科学基金“甜菜M14品系乙二醛酶I基因抗盐能力的转录因子功能研究”(31671751);中国博士后面上项目“甜菜M14品系BvM14-STPK互作蛋白鉴定及其耐盐功能研究”(204968)

nsLTPs Genes Involved in Plant Response to Stress: Research Progress

Ma Yue¹^,²(), Yu Bing¹^,²()

¹Engineering Research Center of Agricultural Microbiology Technology, Ministry of Education, Heilongjiang University, Harbin 150500
²Key Laboratory of Microbiology, College of Heilongjiang Province/School of Life Sciences, Heilongjiang University, Harbin 150080

Received:2020-12-21 Revised:2021-02-08 Online:2021-06-25 Published:2021-07-13
Contact: Yu Bing

摘要/Abstract

摘要：

编码非特异性脂质转移蛋白的基因nsLTPs在植物应答生物和非生物胁迫以及植物的生长发育中起到重要作用。为了研究植物nsLTPs基因响应生物及非生物胁迫的分子机制,本文归纳了非特异性脂质转移蛋白nsLTPs的结构特点及分类,分析了nsLTPs的亚细胞定位情况,并重点总结了nsLTPs基因在植物逆境胁迫应答方面的相关研究进展,提出了植物不同物种中nsLTPs基因参与植物逆境胁迫的分子调控途径,为完善nsLTPs基因参与植物逆境胁迫应答调控机制提供理论基础。

关键词: nsLTPs基因, nsLTPs蛋白, 生物胁迫, 非生物胁迫, 分子调控机制

Abstract:

Genes encoding non-specific lipid transfer proteins, nsLTPs, play an important role in plant response to biotic and abiotic stress and in plant growth and development. In order to investigate the molecular mechanisms of plant nsLTPs genes in response to biotic and abiotic stress, this paper summarized the structural features and classification of non-specific lipid transfer proteins nsLTPs, analyzed the subcellular localization of nsLTPs, and focused on summarizing the relevant research progress of nsLTPs genes in plant stress response, and proposed the molecular regulatory pathways of nsLTPs genes involved in plant stress in different plant species, which could provide a theoretical basis for improving the regulatory mechanism of nsLTPs genes in plant stress response.

Key words: nsLTPs genes, nsLTPs protein, biotic stress, abiotic stress, molecular regulation mechanism

中图分类号:

S184

马悦, 于冰. nsLTPs基因参与植物逆境胁迫应答的研究进展[J]. 中国农学通报, 2021, 37(18): 95-101.

Ma Yue, Yu Bing. nsLTPs Genes Involved in Plant Response to Stress: Research Progress[J]. Chinese Agricultural Science Bulletin, 2021, 37(18): 95-101.

图/表 5

参考文献 50

[1]	Kader J. Proteins and the intracellular exchange of lipids.I. Stimulation of phospholipid exchange between mitochondria and microsomal fractions by proteins isolated from potato tuber[J]. Biochimica et Biophysica acta, 1975,380(1):31-44.
[2]	Kader J. Lipid-Transfer Proteins In Plants[J]. Plant Physiology, 1996,47:627-654.
[3]	黄岳, 朱璐, 罗人和, 等. 拟南芥和水稻非特异脂质转运蛋白的分子进化、表达模式以及在花药发育中的功能分析[J]. 基因组学与应用生物学, 2015,34(7):1510-1521.
[4]	Hincha D, Neukamm B, Sror H, et al. Cabbage cryoprotectin is a member of the nonspecific plant lipid transfer protein gene family[J]. Plant Physiology, 2001,125(2):835-846. doi: 10.1104/pp.125.2.835 URL
[5]	Cameron K, Teece M, Smart L J P. Increased accumulation of cuticular wax and expression of lipid transfer protein in response to periodic drying events in leaves of tree tobacco[J]. Plant Physiology, 2006,140(1):176-183. doi: 10.1104/pp.105.069724 URL
[6]	Dhar N, CaruananJ, Erdem I. An Arabidopsis DISEASE RELATED NONSPECIFIC LIPID TRANSFER PROTEIN 1 is required for resistance against various phytopathogens and tolerance to salt stress[J]. Gene, 2020,753:144802. doi: 10.1016/j.gene.2020.144802 URL
[7]	李蔚, 曲春浦, 许志茹, 等. 西伯利亚蓼非特异性脂质转移蛋白基因PsnsLTP的功能分析[J]. 植物研究. 2015,35(1):547-553.
[8]	Tian N, Liu F, Wang P, et al. Overexpression of BraLTP2, a Lipid Transfer Protein of Brassica napus, Results in Increased Trichome Density and Altered Concentration of Secondary Metabolites[J]. International Journal of Molecular Sciences, 2018,19(6):1265. doi: 10.3390/ijms19051265 URL
[9]	Lascombe M, Bakan B, Buhot N. The structure of "defective in induced resistance" protein of Arabidopsis thaliana, DIR1, reveals a new type of lipid transfer protein[J]. Protein Science : a publication of the Protein Society, 2008,17(9):1522-1530. doi: 10.1110/ps.035972.108 URL
[10]	Megeressa M, Siraj B, Zarina S. Structural characterization and in vitro lipid binding studies of non-specific lipid transfer protein 1 (nsLTP1) from fennel (Foeniculum vulgare) seeds[J]. Scientific Reports, 2020,10(1):21243. doi: 10.1038/s41598-020-77278-6 URL
[11]	McLaughlin J E, Al Darwish N, Garcia-Sanchez J. A lipid transfer protein has antifungal and antioxidant activity and suppresses Fusarium head blight disease and DON accumulation in transgenic wheat[J]. Phytopathology, 2020,16(2):173.
[12]	Deng W, Li R, Xu Y, et al. A lipid transfer protein variant with a mutant eight-cysteine motif causes photoperiod- and thermo-sensitive dwarfism in rice[J]. Journal of Experimental Botany, 2020,71(4):1294-1305. doi: 10.1093/jxb/erz500 URL
[13]	Fleury C, Gracy J, Gautier M F, et al. Comprehensive classification of the plant non-specific lipid transfer protein superfamily towards its sequence-structure-function analysis[J]. PeerJ, 2019,7:e7504. doi: 10.7717/peerj.7504 URL
[14]	Xie W Q, Zhao L Q, Bai W Y, et al. The effects of calmodulin on the lipid-binding activity of CaM-binding protein-10 and maize non-specific lipid transfer protein[J]. 植物生理与分子生物学学报, 2006,32(6):679-684.
[15]	Boutrot F, Chantret N, Gautier M. Genome-wide analysis of the rice and Arabidopsis non-specific lipid transfer protein (nsLtp) gene families and identification of wheat nsLtp genes by EST data mining[J]. BMC genomics, 2008,9:86. doi: 10.1186/1471-2164-9-86 pmid: 18291034
[16]	Bai W Y, Zhao L Q, Li Z P. et al. Cloning and expression of cDNA for maize nonspecific lipid transfer protein as well as calmodulin-binding activity analysis of the expression product[J]. 植物生理与分子生物学学报, 2006,32(5):570-576.
[17]	Meng C, Yan Y, Liu Z, et al. Systematic Analysis of Cotton Non-specific Lipid Transfer Protein Family Revealed a Special Group That Is Involved in Fiber Elongation[J]. Frontiers in Plant Science, 2018,9:1285. doi: 10.3389/fpls.2018.01285 URL
[18]	Tousheh M, Miroliaei M, Asghar Rastegari A, et al. Computational evaluation on the binding affinity of non-specific lipid-transfer protein-2 with fatty acids[J]. Computers In Biology And Medicine, 2013,43(11):1732-1738. doi: 10.1016/j.compbiomed.2013.08.012 URL
[19]	Aboushanab A. 番茄非特异性脂质转移蛋白的鉴定与表达分析[D]. 武汉: 华中农业大学, 2017.
[20]	Wang N J, Lee C C, Cheng C S, et al. Construction and analysis of a plant non-specific lipid transfer protein database (nsLTPDB)[J]. BMC genomics, 2012,13(1):19. doi: 10.1186/1471-2164-13-19 URL
[21]	Carvalho A O, Gomes V. Role of plant lipid transfer proteins in plant cell physiology-a concise review[J]. Peptides, 2007,28(5):1144-1153. doi: 10.1016/j.peptides.2007.03.004 URL
[22]	Schmitt A, Sathoff A, Holl C. The major nectar protein of Brassica rapa is a non-specific lipid transfer protein, BrLTP2.1, with strong antifungal activity[J]. Journal of Experimental Botany, 2018,69(22):5587-5597.
[23]	Pan Y, Li J, Jiao L. A Non-specific Setaria italica Lipid Transfer Protein Gene Plays a Critical Role under Abiotic Stress[J]. Frontiers in Plant Science, 2016,7:1752.
[24]	Ooi L S, Tian L, Su M. Isolation, characterization, molecular cloning and modeling of a new lipid transfer protein with antiviral and antiproliferative activities from Narcissus tazetta[J]. Peptides, 2008,29(12):2101-2109. doi: 10.1016/j.peptides.2008.08.020 URL
[25]	Wei K, Zhong X. Non-specific lipid transfer proteins in maize[J]. BMC Plant Biology, 2014,14:281. doi: 10.1186/s12870-014-0281-8 URL
[26]	Ossendorp B C, Voorhout W F, van Amerongen A. Tissue-specific distribution of a peroxisomal 46-kDa protein related to the 58-kDa protein (sterol carrier protein x; sterol carrier protein 2/3-oxoacyl-CoA thiolase)[J]. Arch Biochem Biophys, 1996,334(2):251-260. pmid: 8900399
[27]	Dansen T B, Westerman J, Wouters F S, et al. High-affinity binding of very-long-chain fatty acyl-CoA esters to the peroxisomal non-specific lipid-transfer protein (sterol carrier protein-2)[J]. Biochemical Journal, 1999,339(Pt 1):193-199. doi: 10.1042/bj3390193 URL
[28]	Hoh F, Pons J, Gautier M, et al. Structure of a liganded type 2 non-specific lipid-transfer protein from wheat and the molecular basis of lipid binding[J]. Acta Crystallogr D Biol Crystallogr, 2005,61:397-406. doi: 10.1107/S0907444905000417 URL
[29]	Castro M, Gerhardt I, Orrù S, et al. Purification and characterization of a small (7.3 kDa) putative lipid transfer protein from maize seeds[J]. Journal of Chromatography, 2003,794(1):109-114. doi: 10.1016/S0021-9673(97)00902-3 URL
[30]	Edstam M M, Viitanen L, Salminen T A, et al. Evolutionary history of the non-specific lipid transfer proteins[J]. Molecular Plant, 2011,4(6):947-964. doi: 10.1093/mp/ssr019 URL
[31]	Gonorazky A G, Regente M C, Canal L. Stress induction and antimicrobial properties of a lipid transfer protein in germinating sunflower seeds[J]. Journal of Plant Physiology, 2005,162(6):618-624. doi: 10.1016/j.jplph.2004.10.006 URL
[32]	Diz M S S, Carvalho A O, Rodrigues R, et al. Antimicrobial peptides from chili pepper seeds causes yeast plasma membrane permeabilization and inhibits the acidification of the medium by yeast cells[J]. Biochimica et Biophysica Acta, 2006,1760(9):1323-1332.
[33]	Lee S B, Go Y S, Bae H J, et al. Disruption of glycosylphosphatidylinositol-anchored lipid transfer protein gene altered cuticular lipid composition, increased plastoglobules, and enhanced susceptibility to infection by the fungal pathogen Alternaria brassicicola[J]. Plant Physiology, 2009,150(1):42-54. doi: 10.1104/pp.109.137745 URL
[34]	McLaughlin J, Bin-Umer M, Widiez T, et al. A Lipid Transfer Protein Increases the Glutathione Content and Enhances Arabidopsis Resistance to a Trichothecene Mycotoxin[J]. PLOS One, 2015,10(6):e0130204. doi: 10.1371/journal.pone.0130204 URL
[35]	Pitzschke A, Datta S, Persak H. Salt stress in Arabidopsis: lipid transfer protein AZI1 and its control by mitogen-activated protein kinase MPK3[J]. Molecular Plant, 2014,7(4):722-738. doi: 10.1093/mp/sst157 pmid: 24214892
[36]	Safi H, Wangorsch A, Lidholm J, et al. Identification and molecular characterization of allergenic non-specific lipid-transfer protein from durum wheat (Triticum turgidum)[J]. Clinical Experimental Allergy, 2019,49(1):120-129. doi: 10.1111/cea.2019.49.issue-1 URL
[37]	D'Agostino N, Buonanno M, Ayoub J, et al. Identification of non-specific Lipid Transfer Protein gene family members in Solanum lycopersicum and insights into the features of Sola l 3 protein[J]. Scientific Reports, 2019,9(1):1607. doi: 10.1038/s41598-018-38301-z pmid: 30733555
[38]	Martín-Pedraza L, González M, Gómez F, et al. Two nonspecific lipid transfer proteins (nsLTPs) from tomato seeds are associated to severe symptoms of tomato-allergic patients[J]. Molecular Nutrition Food Research, 2016,60(5):1172-1182. doi: 10.1002/mnfr.201500782 URL
[39]	Wu G, Robertson A, Liu X, et al. A lipid transfer protein gene BG-14 is differentially regulated by abiotic stress, ABA, anisomycin, and sphingosine in bromegrass (Bromus inermis)[J]. Journal of Plant Physiology, 2004,161(4):449-458. doi: 10.1078/0176-1617-01259 URL
[40]	刘芳, 卢长明. 植物非特异脂质转运蛋白研究现状与展望[J]. 遗传, 2013,35(03):307-314.
[41]	Trevino M, OConnell, M. Three drought-responsive members of the nonspecific lipid-transfer protein gene family in Lycopersicon pennellii show different developmental patterns of expression[J]. Plant Physiology, 1998,116(4):1461-1468. doi: 10.1104/pp.116.4.1461 URL
[42]	Cheng C S, Samuel D, Liu Y J, et al. Binding mechanism of nonspecific lipid transfer proteins and their role in plant defense[J]. Biochemistry, 2004,43(43):13628-13636. doi: 10.1021/bi048873j URL
[43]	Kristensen A K, Brunstedt J, Nielsen K K, et al. Characterization of a new antifungal non-specific lipid transfer protein (nsLTP) from sugar beet leaves[J]. Plant Science, 2000,155(1):31-40. doi: 10.1016/S0168-9452(00)00190-4 URL
[44]	Wang S Y, Wu J H, Ng T B, et al. A non-specific lipid transfer protein with antifungal and antibacterial activities from the mung bean[J]. Peptides, 2004,25(8):1235-1242. doi: 10.1016/j.peptides.2004.06.004 URL
[45]	Hoh F, Pons J, Gautier M, et al. Structure of a liganded type 2 non-specific lipid-transfer protein from wheat and the molecular basis of lipid binding[J]. Acta Crystallogr D Biol Crystallogr, 2005,61:397-406. doi: 10.1107/S0907444905000417 URL
[46]	徐扬. 非特异性脂转移蛋白NtLTP4作为正调控因子参与烟草对非生物和生物胁迫的响应[D]. 泰安: 山东农业大学, 2018.
[47]	Hincha D. Cryoprotectin: a plant lipid-transfer protein homologue that stabilizes membranes during freezing. Philosophical transactions of the Royal Society of London[J]. Biological Sciences, 2002,357(1423):909-916.
[48]	Gómez-Casado C, Díaz-Perales A. Allergen-Associated Immunomodulators: Modifying Allergy Outcome[J]. Archivum Immunologiae et Therapiae Experimentalis, 2016,64(5):339-347. doi: 10.1007/s00005-016-0401-2 pmid: 27178664
[49]	Guo L, Yang H, Zhang X, et al. Lipid transfer protein 3 as a target of MYB96 mediates freezing and drought stress in Arabidopsis[J]. Journal of Experimental Botany, 2013,64(6):1755-1767. doi: 10.1093/jxb/ert040 URL
[50]	Li C, Yue J, Wu X, et al. An ABA-responsive DRE-binding protein gene from Setaria italica, SiARDP, the target gene of SiAREB, plays a critical role under drought stress[J]. Journal of Experimental Botany, 2014,65(18):5415-5427. doi: 10.1093/jxb/eru302 URL

类型	GPI锚定位点	间距模式
Ⅰ	无	C-X_8,9-C-X_13-17-CC-X_18-20-CXC-X_19-24-C-X_7-14-C
Ⅱ	无	C-X₇-C-X_13,15-CC-X_8-10-CXC-X_{16, 21, 23}-C-X_5-6-C
C	无	C-X₉-C-X_{14, 16, 19}-CC-X₉-CXC-X₁₂-C-X₆-C
D	无	C-X_6-14-C-X_8-18-CC-X_9-17-CXC-X_19-28-C-X6_-14-C
E	无	C-X_11,13-C-X_15-16-CC-X₉-CXC-X_21-26-C-X_6-7-C
F	无	C-X₇-C-X₁₁-CC-X₁₀-CXC-X₁₉-C-X₉-C
G	有	C-X_6-11-C-X_14-19-CC-X_12-13-CXC-X_20-34-C-X_5-12-C
H	无	C-X_8,11-C-X_13,16-CC-X9-CXC-X21-C-X₉-C
J	无	C-X_11,14-C-X_14-15-CC-X₁₂-CXC-X_20-22-C-X₆-C
K	无	C-X₁₁-C-X₁₄-CC-X₁₃-CXC-X₂₄-C-X₇-C

类型	GPI锚定位点	间距模式
Ⅰ	无	C-X_8,9-C-X_13-17-CC-X_18-20-CXC-X_19-24-C-X_7-14-C
Ⅱ	无	C-X₇-C-X_13,15-CC-X_8-10-CXC-X_{16, 21, 23}-C-X_5-6-C
C	无	C-X₉-C-X_{14, 16, 19}-CC-X₉-CXC-X₁₂-C-X₆-C
D	无	C-X_6-14-C-X_8-18-CC-X_9-17-CXC-X_19-28-C-X6_-14-C
E	无	C-X_11,13-C-X_15-16-CC-X₉-CXC-X_21-26-C-X_6-7-C
F	无	C-X₇-C-X₁₁-CC-X₁₀-CXC-X₁₉-C-X₉-C
G	有	C-X_6-11-C-X_14-19-CC-X_12-13-CXC-X_20-34-C-X_5-12-C
H	无	C-X_8,11-C-X_13,16-CC-X9-CXC-X21-C-X₉-C
J	无	C-X_11,14-C-X_14-15-CC-X₁₂-CXC-X_20-22-C-X₆-C
K	无	C-X₁₁-C-X₁₄-CC-X₁₃-CXC-X₂₄-C-X₇-C

nsLTPs基因名称		植物材料	植物逆境		作用机制	参考文献
BrLTP2.1		甘蓝型油菜	真菌和细菌病原体		提高了转基因植株的抗病性^[31]	[31]
HvLTP		大麦	真菌和细菌病原体		提高了转基因植株的抗病性^[32]	[32]
CALTP1、CALTP2		胡椒	真菌和细菌病原体		提高了转基因植株的抗病性^[33]	[33]
PsnsLTP		烟草	炭疽病病菌、猝倒病病菌		提高了转基因植株的抗病性^[34]	[34]
AtLTP4.4		拟南芥	天花粉霉菌		提高了转基因植株的抗病性^[35]	[35]
StnsLTP1		马铃薯	青枯菌		提高了转基因植株的抗病性^[36]	[36]
AtLTPG1		拟南芥	真菌		基因沉默植株易感病^[37]	[37]
BrLTP2.1		甘蓝型油菜	高温		增强了转基因植株的热稳定性^[31]	[31]
StnsLTP1		马铃薯	高温		增强了转基因植株的热稳定性^[36]	[36]
ZmLTP		玉米	低温		提高了转基因植株的耐冷性^[38]	[38]
BG-14		无芒雀麦	低温		提高了转基因植株的耐冷性^[39]	[39]
ZmLTP		玉米	干旱		提高了转基因植株的耐旱性^[38]	[38]
OsDIL		水稻	干旱		提高了转基因植株的耐旱性^[40]	[40]
CALTP1		胡椒	干旱		提高了转基因植株的耐旱性^[33]	[33]
StnsLTP1		马铃薯	干旱		提高了转基因植株的耐旱性^[36]	[36]
NtLTP4		烟草	干旱		提高了转基因植株的耐旱性^[3]	[3]
LpLtp1、LpLtp2		潘那利番茄	干旱		提高了转基因植株的耐旱性^[41]	[41]
NtLTP4		烟草	盐		提高了转基因植株的耐盐性^[3]	[3]
StnsLTP1	马铃薯		盐	提高了转基因植株的耐盐性^[36]		[36]
AZI1	拟南芥		盐	基因沉默植株对盐胁迫敏感^[40]		[40]
ZmLTP	玉米		盐	提高了转基因植株的耐盐性^[38]		[38]
AtLTP1、AtLTP3	拟南芥		盐	提高了转基因植株的耐盐性^[40]		[40]
CALTP1	胡椒		盐	提高了转基因植株的耐盐性^[33]		[33]

nsLTPs基因名称		植物材料	植物逆境		作用机制	参考文献
BrLTP2.1		甘蓝型油菜	真菌和细菌病原体		提高了转基因植株的抗病性^[31]	[31]
HvLTP		大麦	真菌和细菌病原体		提高了转基因植株的抗病性^[32]	[32]
CALTP1、CALTP2		胡椒	真菌和细菌病原体		提高了转基因植株的抗病性^[33]	[33]
PsnsLTP		烟草	炭疽病病菌、猝倒病病菌		提高了转基因植株的抗病性^[34]	[34]
AtLTP4.4		拟南芥	天花粉霉菌		提高了转基因植株的抗病性^[35]	[35]
StnsLTP1		马铃薯	青枯菌		提高了转基因植株的抗病性^[36]	[36]
AtLTPG1		拟南芥	真菌		基因沉默植株易感病^[37]	[37]
BrLTP2.1		甘蓝型油菜	高温		增强了转基因植株的热稳定性^[31]	[31]
StnsLTP1		马铃薯	高温		增强了转基因植株的热稳定性^[36]	[36]
ZmLTP		玉米	低温		提高了转基因植株的耐冷性^[38]	[38]
BG-14		无芒雀麦	低温		提高了转基因植株的耐冷性^[39]	[39]
ZmLTP		玉米	干旱		提高了转基因植株的耐旱性^[38]	[38]
OsDIL		水稻	干旱		提高了转基因植株的耐旱性^[40]	[40]
CALTP1		胡椒	干旱		提高了转基因植株的耐旱性^[33]	[33]
StnsLTP1		马铃薯	干旱		提高了转基因植株的耐旱性^[36]	[36]
NtLTP4		烟草	干旱		提高了转基因植株的耐旱性^[3]	[3]
LpLtp1、LpLtp2		潘那利番茄	干旱		提高了转基因植株的耐旱性^[41]	[41]
NtLTP4		烟草	盐		提高了转基因植株的耐盐性^[3]	[3]
StnsLTP1	马铃薯		盐	提高了转基因植株的耐盐性^[36]		[36]
AZI1	拟南芥		盐	基因沉默植株对盐胁迫敏感^[40]		[40]
ZmLTP	玉米		盐	提高了转基因植株的耐盐性^[38]		[38]
AtLTP1、AtLTP3	拟南芥		盐	提高了转基因植株的耐盐性^[40]		[40]
CALTP1	胡椒		盐	提高了转基因植株的耐盐性^[33]		[33]

nsLTPs基因参与植物逆境胁迫应答的研究进展

nsLTPs Genes Involved in Plant Response to Stress: Research Progress

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

图/表 5

参考文献 50

相关文章 15

编辑推荐

Metrics

本文评价

关于本刊

作者中心

审者中心

在线期刊

联系我们

[1]	贾也纯, 陈润仪, 贺泽霖, 倪洪涛. 甜菜抗非生物胁迫研究进展[J]. 中国农学通报, 2022, 38(9): 33-40.
[2]	谢道龙, 谭智, 李虹烨, 付小侠, 王帆, 刘晓霞, 覃佐东, 何福林, 骆鹰. 银杏GbASR基因的克隆、生物信息学及表达分析[J]. 中国农学通报, 2021, 37(32): 34-41.
[3]	郝小聪, 王伟伟, 张风廷, 孙瑞, 房兆峰, 柳珊, 曹志琛, 朱文根, 赵昌平, 汪德州, 唐益苗. 小麦TaHPPR基因的克隆与表达分析[J]. 中国农学通报, 2021, 37(3): 129-138.
[4]	姜雪雍, 岳元春, 孙养存, 高冬妮, 平文祥, 葛菁萍. 副干酪乳杆菌与芽孢杆菌属共培养种间关系对产细菌素的影响[J]. 中国农学通报, 2021, 37(24): 124-132.
[5]	董春燕, 梁卫红, 程辉, 于东明, 吕东, 孙炎锋, 苗琛. 植物脂氧合酶在逆境胁迫应答中功能研究进展[J]. 中国农学通报, 2020, 36(33): 102-107.
[6]	邹锋康, 贾海伦, 丁广洲, 陈丽. 甜菜磷脂酰肌醇转运蛋白基因SbSEC14的克隆及低温胁迫下的表达分析[J]. 中国农学通报, 2020, 36(32): 39-48.
[7]	王爽, 李海英. 植物E3泛素连接酶与非生物胁迫相关研究进展[J]. 中国农学通报, 2020, 36(29): 47-53.
[8]	刘静妍, 闫双勇, 张融雪, 苏京平, 孙玥, 孙林静. 水稻耐低温研究重要进展[J]. 中国农学通报, 2020, 36(27): 1-5.
[9]	王琼, 郭毅晶, 康琳, 张少颖, 于有伟, 宋小青. 一氧化碳(CO)在植物体内的生理生化作用研究进展[J]. 中国农学通报, 2020, 36(12): 86-90.
[10]	张计育,王刚,黄胜男,宣继萍,贾晓东,郭忠仁. 乙醇脱氢酶基因家族在植物抵抗非生物胁迫过程中的作用研究进展[J]. 中国农学通报, 2015, 31(10): 246-250.
[11]	李莹,柳参奎. 植物类萌发素蛋白研究进展[J]. 中国农学通报, 2014, 30(30): 246-254.
[12]	郭文雅. 脱落酸(ABA)生物学作用研究进展[J]. 中国农学通报, 2014, 30(21): 205-210.
[13]	唐芬芬邵榆岚杨伟克杨海李平平李腾芳白兴荣. 昆虫响应非生物胁迫——表达热休克蛋白策略的研究进展[J]. 中国农学通报, 2013, 29(30): 181-184.
[14]	杨珍珍王志龙卢向阳王国梁. 水稻泛素连接酶功能研究进展[J]. 中国农学通报, 2013, 29(18): 1-5.
[15]	徐慧芳陈桢雨孟丹闵红星杨立明罗玉明. 新型气体信号分子H2S在植物生长发育中的作用研究进展[J]. 中国农学通报, 2013, 29(15): 5-9.