黄瓜花叶病毒侵染烟草对烟蚜生长发育、取食和选择行为的影响

doi:10.3864/j.issn.0578-1752.2021.08.008

Abstract

Abstract:

【Objective】The objective of this study is to investigate the effect of cucumber mosaic virus (CMV) infection on the growth, development and behavior of Myzus persicae on tobacco, and the role of 2b gene in the interaction between M. persicae and CMV.【Method】The host plants to be used were healthy tobacco, CMV-infected and CMV 2b gene deletion mutant (CMVΔ2b) infected tobacco. The Y-shaped olfactometer was used to determinate the selection tendency of M. persicae to different host tobacco plants, and electrical penetration graph (EPG) was used to monitor M. persicae feeding behavior combined with the detection of total sugar and free amino acid content in the host plant. The aphid life table was recorded through a single micro-cage to analyze the effects of CMV-infected tobacco on the growth and reproduction of M. persicae.【Result】The total sugar content of CMV-infected tobacco was significantly lower than that of healthy tobacco, while the content of free amino acids was significantly higher than that of healthy tobacco and CMVΔ2b-infected tobacco. The contents of threonine, glutamic acid, glycine, tyrosine, histidine, arginine and proline in the tobacco infected by CMVΔ2b were significantly higher than those of other treatments. The contents of valine and lysine in CMVΔ2b-infected tobacco were significantly higher than those of healthy tobacco. The content of aspartic acid in CMV-infected tobacco was significantly lower than that of other treatments, and its cystine content was significantly higher than that of CMVΔ2b-infected tobacco. Compared with CMV-infected tobacco, M. persicae had a stronger selection trend to healthy tobacco and CMVΔ2b-infected tobacco. There was no significant difference in the host selection behavior of M. persicae between healthy tobacco and CMVΔ2b-infected tobacco. CMV infection adversely affected the growth and feeding behavior of M. persicae. M. persicae had the most frequent probing behavior (pd wave) and the shortest duration of phloem feeding (E2 wave) on CMV-infected tobacco, and the frequency of xylem feeding (G wave) was significantly higher than that of healthy tobacco and CMVΔ2b-infected tobacco. The results indicated that CMV-infected tobacco was not suitable for aphid feeding. The growth characteristics of the M. persicae showed that CMV infection significantly prolonged the duration of the nymph aphid, increased the mortality rate of the 2nd-instar aphid, reduced the longevity of the aphid, and significantly reduced the fecundity of the aphid. The intrinsic rate of increase (r) and finite rate of increase (λ) of M. persicae on CMV-infected tobacco were significantly lower than those of healthy and CMVΔ2b-infected tobacco. CMV infection was not conducive to population growth of M. persicae.【Conclusion】CMV infection changes the composition of tobacco nutrients. The presence of CMV 2b gene increases the probing frequency and reduces the phloem feeding behavior. CMV infection results in prolonging pre-adult period, increasing mortality, decreasing longevity and fecundity of M. persicae. CMV infection reduces the host fitness of M. persicae, promotes aphids to transfer to new host plants, thus promoting the spread of the CMV.

Key words: cucumber mosaic virus (CMV), Myzus persicae, tobacco, growth and development, feeding behavior, host selection

CHEN Xi,LIU YingJie,DONG YongHao,LIU JinYan,LI Wei,XU PengJun,ZANG Yun,REN GuangWei. Effects of CMV-Infected Tobacco on the Performance, Feeding and Host Selection Behavior of Myzus persicae[J].Scientia Agricultura Sinica, 2021, 54(8): 1673-1683.

Figures/Tables 8

Fig. 1

Table 1

Fig. 2

Table 2

Statistics for EPG parameters of M. persicae probing on different tobacco hosts"

EPG参数 EPG parameter		健康烟草 Healthy tobacco (n=15)	CMV侵染烟草 CMV-infected tobacco (n=15)	CMVΔ2b侵染烟草 CMVΔ2b-infected tobacco (n=15)
1	第一次刺探发生时间Time to 1st probe from start of EPG (min)	0.64±0.16a	0.75±0.42a	0.76±0.17a
2	第一次E1波前刺探次数Number of probes to the 1st E1	20.40±6.69a	14.00±2.60a	15.33±4.05a
3	pd次数Number of probes	197.73±9.53ab	217.93±50.51a	184.27±11.28b
4	np次数Number of np	39.40±7.97a	48.00±7.57a	46.07±6.17a
5	np 持续时长Total duration of np (min)	52.69±8.52a	63.43±9.67a	61.79±8.56a
6	口针第一次到达韧皮部的时间Time to phloem from the start of EPG (min)	87.72±31.03a	67.05±8.22a	79.89±14.70a
7	E1次数Number of E1	19.53±2.77a	16.60±3.23a	19.13±2.81a
8	E1持续总时长Total duration of E1 (min)	58.31±6.58a	69.64±8.09a	62.00±6.83a
9	E1持续总时长/总记录时间Total duration of E1/total record time (%)	16.20±1.83a	16.56±2.25a	17.22±1.90a
10	E2的次数Number of E2	13.67±2.37a	9.27±2.45a	14.73±2.72a
11	E2持续时长>10 min次数Number of sustained E2 (>10 min)	0.80±0.24a	0.33±0.16a	1.00±0.29a
12	E2持续总时长Total duration of E2 (min)	41.70±9.55ab	19.15±5.30b	42.93±8.81a
13	E2持续总时长/记录总时间Total duration of E2/total record time (%)	11.59±2.65ab	5.32±1.47b	11.92±2.45a
14	E1+E2持续总时长Total duration of E (min)	100.03±13.87a	78.79±11.65a	104.92±11.91a
15	最长E2波时间Duration of the longest E2 (min)	15.50±4.16a	6.11±1.65b	15.54±3.33a
16	G波持续总时间Duration of G (min)	24.13±0.00a	24.52±20.08a	13.57±2.73b
17	出现G波的蚜虫百分比Percentage of aphids showing waveform G (%)	6.67b	20.00a	6.67b
18	C波持续总时长Total duration of C (min)	208.51±10.37a	213.59±11.85a	191.85±10.95a
19	C波持续总时长/记录总时间Total duration of C/total record time (%)	57.92±2.88a	59.33±3.29a	53.29±1.78a

Table 2

Fig. 3

Table 3

Table 4

Table 5

References 41

[1]	朱贤朝, 王彦亭, 王智发. 中国烟草病害. 北京: 中国农业出版社, 2002: 76-89.
	ZHU X C, WANG Y T, WANG Z F. Tobacco Disease of China. Beijing: China Agriculture Press, 2002: 76-89. (in Chinese)
[2]	GUO H, GU L, LIU F, CHEN F, GE F, SUN Y. Aphid-borne viral spread is enhanced by virus-induced accumulation of plant reactive oxygen species. Plant Physiology, 2019,179(1):143-155. pmid: 30381318
[3]	TUNGADI T, GROEN S C, MURPHY A M, PATE A E, IQBAL J, BRUCE T J A, CUNNIFFE N J, CARR J P. Cucumber mosaic virus and its 2b protein alter emission of host volatile organic compounds but not aphid vector settling in tobacco. Virology Journal, 2017,14(1):91. doi: 10.1186/s12985-017-0754-0 pmid: 28468686
[4]	MAUCK K E, DE MORAES C M, MESCHER M C. Evidence of local adaptation in plant virus effects on host-vector interactions. Integrative and Comparative Biology, 2014,54(2):193-209.
[5]	HILY J M, GARCIA A, MORENO A, PLAZA M, WILKINSON M D, FERERES A, FRAILE A, GARCIA-ARENAL F. The relationship between host lifespan and pathogen reservoir potential: An analysis in the system Arabidopsis thaliana-cucumber mosaic virus. PLoS Pathogens, 2014,10(11):e1004492. pmid: 25375140
[6]	STAFFORD C A, WALKER G P, ULLMAN D E. Infection with a plant virus modifies vector feeding behavior. Proceedings of the National Academy of Science of the United States of America, 2011,108(23):9350-9355.
[7]	MAUCK K E, DE MORAES C M, MESCHER M C. Deceptive chemical signals induced by a plant virus attract insect vectors to inferior hosts. Proceedings of the National Academy of Science of the United States of America, 2010,107(8):3600-3605.
[8]	MAUCK K E, DE MORAES C M, MESCHER M C. Effects of cucumber mosaic virus infection on vector and non-vector herbivores of squash. Communicative and Integrative Biology, 2010,3(6):579-582. doi: 10.4161/cib.3.6.13094 pmid: 21331245
[9]	GADHAVE K R, DUTTA B, COOLONG T, SRINIVASAN R. A non-persistent aphid-transmitted Potyvirus differentially alters the vector and non-vector biology through host plant quality manipulation. Scientific Reports, 2019,9:2503. doi: 10.1038/s41598-019-39256-5 pmid: 30792431
[10]	CASTEEL C L, YANG C, NANDURI A C, DE JONG H N, WHITHAM S A, JANDER G. The NIa-Pro protein of turnip mosaic virus improves growth and reproduction of the aphid vector, Myzus persicae (green peach aphid). The Plant Journal, 2014,77(4):653-663. pmid: 24372679
[11]	KERSCH-BECKER M F, THALER J S. Virus strains differentially induce plant susceptibility to aphid vectors and chewing herbivores. Oecologia, 2014,174(3):883-892.
[12]	LI H, LIU X, LIU X, MICHAUD J P, ZHI H, LI K, LI X, LI Z. Host plant infection by soybean mosaic virus reduces the fitness of its vector, Aphis glycines (Hemiptera: Aphididae). Journal of Economic Entomology, 2018,111(5):2017-2023. pmid: 29945216
[13]	NG J C, PERRY K L. Transmission of plant viruses by aphid vectors. Molecular Plant Pathology, 2004,5(5):505-511. doi: 10.1111/j.1364-3703.2004.00240.x pmid: 20565624
[14]	STAFFORD C A, WALKER G P, ULLMAN D E. Hitching a ride: Vector feeding and virus transmission. Communicative and Integrative Biology, 2012,5(1):43-49.
[15]	JIMÉNEZ J, GARZO E, ALBA-TERCEDOR J, MORENO A, FERERES A, WALKER G P. The phloem-pd: A distinctive brief sieve element stylet puncture prior to sieve element phase of aphid feeding behavior. Arthropod-Plant Interactions, 2020,14:67-78.
[16]	ALVAREZ A E, GARZO E, VERBEEK M, VOSMAN B, DICKE M, TJALLINGII W F. Infection of potato plants with potato leafroll virus changes attraction and feeding behaviour of Myzus persicae. Entomologia Experimentalis et Applicata, 2007,125(2):135-144.
[17]	COLLAR J L, AVILLA C, FERERES A. New correlations between aphid stylet paths and nonpersistent virus transmission. Environmental Entomology, 1997,26(3):537-544.
[18]	REN G W, WANG X F, CHEN D, WANG X W, FAN X J, LIU X D. Potato virus Y-infected tobacco affects the growth, reproduction, and feeding behavior of a vector aphid, Myzus persicae (Hemiptera: Aphididae). Applied Entomology and Zoology, 2015,50(2):239-243.
[19]	LIU J Y, LIU Y J, DONKERSLEY P, DONG Y H, CHEN X, ZANG Y, XU P J, REN G W. Preference of the aphid Myzus persicae (Hemiptera: Aphididae) for tobacco plants at specific stages of potato virus Y infection. Archives of Virology, 2019,164(6):1567-1573.
[20]	姚敏, 张天奇, 田志超, 王源超, 陶小荣. 农杆菌介导的CMV侵染性克隆及2b缺失突变体构建. 中国农业科学, 2011,44(14):3060-3068.
	YAO M, ZHANG T Q, TIAN Z C, WANG Y C, TAO X R. Construction of Agrobacterium-mediated cucumber mosaic virus infectious cDNA clones and 2b deletion viral vector. Scientia Agricultura Sinica, 2011,44(14):3060-3068. (in Chinese)
[21]	SARRIA E, CID M, GARZO E, FERERES A. Excel Workbook for automatic parameter calculation of EPG data. Computers and Electronics in Agriculture, 2009,67(1/2):35-42.
[22]	臧连生, 刘银泉, 刘树生. 一种适合粉虱实验观察的新型微虫笼. 昆虫知识, 2005,42(3):329-331.
	ZANG L S, LIU Y Q, LIU S S. A new clip-cage for whitefly experimental studies. Chinese Bulletin of Entomology, 2005,42(3):329-331. (in Chinese)
[23]	CHI H. Life-table analysis incorporating both sexes and variable development rates among individuals. Environmental Entomology, 1988,17(1):26-34.
[24]	CHI H, LIU H. Two new methods for the study of insect population ecology. Bulletin of the Institute of Zoology Academia Sinica, 1985,24(2):225-240.
[25]	KARIYAT R R, MAUCK K E, BALOGH C M, STEPHENSON A G, MESCHER M C, DE MORAES C M. Inbreeding in horsenettle (Solanum carolinense) alters night-time volatile emissions that guide oviposition by Manduca sexta moths. Proceedings of the Royal Society B: Biological Sciences, 2013,280(1757):20130020.
[26]	MAXWELL D J, PARTRIDGE J C, ROBERTS N W, BOONHAM N, FOSTER G D. The effects of plant virus infection on polarization reflection from leaves. PLoS ONE, 2016,11(4):e0152836.
[27]	MAUCK K E, DE MORAES C M, MESCHER M C. Biochemical and physiological mechanisms underlying effects of cucumber mosaic virus on host-plant traits that mediate transmission by aphid vectors. Plant, Cell and Environment, 2014,37(6):1427-1439. pmid: 24329574
[28]	DYER L A, PHILBIN C S, OCHSENRIDER K M, RICHARDS L A, MASSAD T J, SMILANICH A M, FORISTER M L, PARCHMAN T L, GALLAND L M, HURTADO P J, et al. Modern approaches to study plant-insect interactions in chemical ecology. Nature Reviews Chemistry, 2018,2(6):50-64.
[29]	WU D, QI T, LI W X, TIAN H, GAO H, WANG J, GE J, YAO R, REN C, WANG X B, LIU Y, KANG L, DING S W, XIE D. Viral effector protein manipulates host hormone signaling to attract insect vectors. Cell Research, 2017,27(3):402-415.
[30]	EIGENBRODE S D, DING H, SHIEL P, BERGER P H. Volatiles from potato plants infected with potato leafroll virus attract and arrest the virus vector, Myzus persicae (Homoptera: Aphididae). Proceedings of the Royal Society of London B: Biological Sciences, 2002,269(1490):455-460.
[31]	MAUCK K, BOSQUE-PÉREZ N A, EIGENBRODE S D, DE MORAES C M, MESCHER M C. Transmission mechanisms shape pathogen effects on host-vector interactions: Evidence from plant viruses. Functional Ecology, 2012,26(5):1162-1175.
[32]	WU J, LAN H, ZHANG Z F, CAO H H, LIU T X. Performance and transcriptional response of the green peach aphid Myzus persicae to the restriction of dietary amino acids. Frontiers in Physiology, 2020,11:487. pmid: 32523545
[33]	陈茜, 刘金燕, 徐蓬军, 刘英杰, 董勇浩, 臧云, 蔡宪杰, 任广伟. PVY侵染后烟草营养成分的变化及其对介体烟蚜生长发育的影响. 昆虫学报, 2020,63(2):181-190.
	CHEN X, LIU J Y, XU P J, LIU Y J, DONG Y H, ZANG Y, CAI X J, REN G W. Changes in the nutrient composition of tobacco plants after potato virus Y infection and their effects on the growth and development of the vector Myzus persicae (Hemiptera: Aphididae). Acta Entomologica Sinica, 2020,63(2):181-190. (in Chinese)
[34]	MARTIN B, COLLAR J L, TJALLINGII W F, FERERES A. Intracellular ingestion and salivation by aphids may cause the acquisition and inoculation of non-persistently transmitted plant viruses. Journal of General Virology, 1997,78:2701-2705.
[35]	POWELL G. Intracellular salivation is the aphid activity associated with inoculation of non-persistently transmitted viruses. Journal of General Virology, 2005,86(2):469-472.
[36]	SHI X, GAO Y, YAN S, TANG X, ZHOU X, ZHANG D, LIU Y. Aphid performance changes with plant defense mediated by cucumber mosaic virus titer. Virology Journal, 2016,13:70. doi: 10.1186/s12985-016-0524-4 pmid: 27103351
[37]	王佳, 王亚峰, 蒲颇, 陈媛, 刘映红. 烟草感染两种病毒对烟蚜种群增长、寄主选择与传毒的影响. 西南大学学报 (自然科学版), 2017,39(3):23-27.
	WANG J, WANG Y F, PU P, CHEN Y, LIU Y H. Effect of two viruses infecting tobacco on population growth, host plant selection and virus transmission efficiency of aphids. Journal of Southwest University (Natural Science Edition), 2017,39(3):23-27. (in Chinese)
[38]	ZIEBELL H, MURPHY A M, GROEN S C, TUNGADI T, WESTWOOD J H, LEWSEY M G, MOULIN M, KLECZKOWSKI A, SMITH A G, STEVENS M, POWELL G, CARR J P. Cucumber mosaic virus and its 2b RNA silencing suppressor modify plant-aphid interactions in tobacco. Scientific Reports, 2011,1:187.
[39]	TUNGADI T, DONNELLY R, QING L, IQBAL J, MURPHY A M, PATE A E, CUNNIFFE N J, CARR J P. Cucumber mosaic virus 2b proteins inhibit virus-induced aphid resistance in tobacco. Molecular Plant Pathology, 2020,21(2):250-257. doi: 10.1111/mpp.12892 pmid: 31777194
[40]	CASTLE S J, BERGER P H. Rates of growth and increase of Myzus persicae on virus-infected potatoes according to type of virus-vector relationship. Entomologia Experimentalis et Applicata, 1993,69(1):51-60.
[41]	MAUCK K E, DE MORAES C M, MESCHER M C. Infection of host plants by cucumber mosaic virus increases the susceptibility of Myzus persicae aphids to the parasitoid Aphidius colemani. Scientific Reports, 2015,5:10963. doi: 10.1038/srep10963 pmid: 26043237

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

游离氨基酸 Free amino acid	健康烟草 Healthy tobacco	CMV侵染烟草 CMV-infected tobacco	CMVΔ2b 侵染烟草 CMVΔ2b-infected tobacco
天冬氨酸Aspartic acid	1170.00±126.62a	576.67±61.19b	1230.00±92.37a
苏氨酸Threonine	786.67±91.34b	750.00±109.70b	2723.33±440.54a
丝氨酸Serine	636.67±126.67a	590.00±70.24a	930.00±104.40a
谷氨酸Glutamic acid	1960.00±292.63b	1886.67±144.95b	3030.00±135.77a
甘氨酸Glycine	10.00±0b	20.00±5.77b	70.00±10.00a
丙氨酸Alanine	253.33±8.82a	246.67±26.03a	263.33±12.02a
缬氨酸Valine	263.33±12.02b	306.67±26.03ab	356.67±29.63a
蛋氨酸Methionine	16.67±8.82a	6.67±6.67a	23.33±3.33a
异亮氨酸Isoleucine	53.33±3.33a	60.00±5.78a	50.00±3.77a
亮氨酸Leucine	70.00±5.77a	76.67±8.82a	76.67±8.82a
酪氨酸Tyrosine	63.33±3.33c	96.67±6.67b	133.33±12.02a
苯丙氨酸Phenylalanine	203.33±26.03a	226.67±24.04a	263.33±21.86a
赖氨酸Lysine	66.67±3.33b	76.67±8.82ab	100.00±11.54a
组氨酸Histidine	36.67±3.33b	50.00±5.77b	133.33±21.86a
精氨酸Arginine	26.67±6.67b	26.67±3.33b	56.67±6.67a
脯氨酸Proline	460.00±40.41b	373.00±67.41b	2763.33±316.88a
色氨酸Tryptophane	33.33±3.33a	80.00±5.77a	133.33±48.42a
胱氨酸Cystine	30.00±0ab	33.33±6.67a	16.67±3.33b

寄主植物 Host plant	1龄若蚜 1st instar	2龄若蚜 2nd instar	3龄若蚜 3rd instar	4龄若蚜 4th instar	若蚜历期 Pre-adult period	成虫期 Adult period	寿命 Adult longevity
健康烟草 Healthy tobacco	1.52±0.10b	1.61±0.11b	1.55±0.10b	2.16±0.14a	6.81±0.16b	15.66±1.52a	22.03±1.54a
CMV侵染烟草 CMV-infected tobacco	2.19±0.20a	2.80±0.21a	2.71±0.25a	2.00±0.22a	9.40±0.58a	11.47±1.68a	12.49±1.49b
CMVΔ2b侵染烟草 CMVΔ2b-infected tobacco	1.67±0.12b	1.83±0.17b	1.45±0.13b	2.32±0.15a	7.32±0.24b	16.09±1.77a	20.26±1.94a

寄主植物 Host plant	成虫繁殖前期 Adult pre-reproductive period (d)	总繁殖前期 Total pre-reproductive period (d)	繁殖期 Reproductive days (d)	繁殖力（单雌产蚜量） Fecundity (number of nymphs produced by one female aphid)
健康烟草 Healthy tobacco	0.88±0.16a	7.69±0.21b	10.66±1.19a	24.66±3.44a
CMV侵染烟草 CMV-infected tobacco	1.17±0.35a	10.33±0.88a	9.25±1.40a	12.13±2.93b
CMVΔ2b侵染烟草 CMVΔ2b-infected tobacco	0.81±0.19a	8.00±0.32b	10.86±1.17a	19.32±2.86ab

寄主植物 Host plant	内禀增长率 Intrinsic rate of increase (r, d^-1)	周限增长率 Finite rate of increase (λ, d^-1)	净生殖率 Net reproductive rate (R₀, offspring)	平均世代周期 Mean generation time (T, d)	总繁殖率 Gross reproduction rate (GRR)
健康烟草 Healthy tobacco	0.25±0.01a	1.28±0.02a	23.91±3.39a	12.95±0.32a	34.73±2.95a
CMV侵染烟草 CMV-infected tobacco	0.11±0.02c	1.11±0.02c	5.20±1.58b	15.65±1.36a	27.78±7.18ab
CMVΔ2b侵染烟草 CMVΔ2b-infected tobacco	0.20±0.01b	1.22±0.02b	15.74±2.69a	13.59±0.49a	27.43±2.24b

Effects of CMV-Infected Tobacco on the Performance, Feeding and Host Selection Behavior of Myzus persicae

RichHTML

PDF

Abstract

Cite this article

share this article

Figures/Tables 8

References 41

Related Articles 15

Metrics

Comments

Recommended 0

[1]	YANG KeXin, ZHANG Yong, LI YanXiu, XIE SiYao, XUE Bo, YANG ShaoJie, SONG DeWei, MA Qiang, ZOU Ping, LI Yang, MA SiQi, JING ChangLiang. Effects of Alginate Oligosaccharides on Alleviating Atrazine Phytotoxicity in Tobacco [J]. Scientia Agricultura Sinica, 2026, 59(1): 101-113.
[2]	ZHENG Yu, CHEN Yi, TI JinSong, SHI LongFei, XU XiaoBo, LI YuLin, GUO Rui. Evaluation of Carbon Footprint and Economic Benefit of Different Tobacco Rotation Patterns [J]. Scientia Agricultura Sinica, 2025, 58(4): 733-747.
[3]	CHEN JuanNi, CHEN PinLu, LI Yu, XIE MengXiao, LI XinBei, DING Wei. Mechanism of Tobacco Resistance to Bacterial Wilt Induced by Magnesium Oxide Nanoparticles [J]. Scientia Agricultura Sinica, 2025, 58(16): 3327-3344.
[4]	ZHAO LinLin, HE YuXi, PENG JieLi, WANG Xu, MA Jia, ZHANG XiuMin, HU Dong. Streptomyces TOR3209 and Its Volatile Organic Compounds Enhance Tobacco Resistance to Fusarium equiseti [J]. Scientia Agricultura Sinica, 2025, 58(11): 2162-2175.
[5]	ZENG XiangCui, YANG YongNian, LI RuYue, JIANG XueQian, JIANG Xu, XU YanRan, LIU ZhongKuan, LONG RuiCai, KANG JunMei, YANG QingChuan, LI MingNa. Identification of Alfalfa (Medicago sativa) MsCEP Genes and Functional Analysis of Its Regulation in Root Growth and Development [J]. Scientia Agricultura Sinica, 2024, 57(24): 4839-4853.
[6]	PENG ZhiXin, ZHANG XiFen, HAN XiaoBin, SI GuoDong, XU KangWen, ZHANG ChengSheng. Effect of Fatty Acid Natural Product 2E, 4E-Decadienoic Acid on Tobacco Rhizosphere Microbial Communities [J]. Scientia Agricultura Sinica, 2024, 57(18): 3601-3611.
[7]	GAO XiaoXiao, TU LiQin, YANG Liu, LIU YaNan, GAO DanNa, SUN Feng, LI Shuo, ZHANG SongBai, JI YingHua. Construction of an Infectious Clone of Tobacco Mild Green Mosaic Virus Isolate Infecting Pepper from Jiangsu Based on Genomic Clone [J]. Scientia Agricultura Sinica, 2023, 56(8): 1494-1502.
[8]	LI XingXing, ZHOU GuoFu, LUO GuanYu, CHEN SiRong, ZHANG JinLong, CHEN GuoHua, ZHANG XiaoMing. Selection Preference and Adaptability of Bactrocera dorsalis to Different Varieties of Malus pumila [J]. Scientia Agricultura Sinica, 2023, 56(17): 3358-3371.
[9]	WANG Jin, LIU YanFang, LIU WenWen, WANG YaQi, SONG ShiYang, ZHANG XingZi, LI FengXia. COXⅡ Functional Analysis in Tobacco sua-CMS Line [J]. Scientia Agricultura Sinica, 2023, 56(16): 3077-3087.
[10]	YAN LeLe,BU LuLu,NIU Liang,ZENG WenFang,LU ZhenHua,CUI GuoChao,MIAO YuLe,PAN Lei,WANG ZhiQiang. Widely Targeted Metabolomics Analysis of the Effects of Myzus persicae Feeding on Prunus persica Secondary Metabolites [J]. Scientia Agricultura Sinica, 2022, 55(6): 1149-1158.
[11]	PEI YueHong,LI FengWei,LIU WeiNa,WEN YuXia,ZHU Xin,TIAN ShaoRui,FAN GuangJin,MA XiaoZhou,SUN XianChao. Characteristics of Cysteine Proteinase Gene Family in Nicotiana benthamiana and Its Function During TMV Infection [J]. Scientia Agricultura Sinica, 2022, 55(21): 4196-4210.
[12]	YuXia WEN,Jian ZHANG,Qin WANG,Jing WANG,YueHong PEI,ShaoRui TIAN,GuangJin FAN,XiaoZhou MA,XianChao SUN. Cloning, Expression and Anti-TMV Function Analysis of Nicotiana benthamiana NbMBF1c [J]. Scientia Agricultura Sinica, 2022, 55(18): 3543-3555.
[13]	GUO YingXin,CHEN YongLiang,MIAO Qi,FAN ZhiYong,SUN JunWei,CUI ZhenLing,LI JunYing. Spatial-Temporal Variability of Soil Nutrients and Assessment of Soil Fertility in Erhai Lake Basin [J]. Scientia Agricultura Sinica, 2022, 55(10): 1987-1999.
[14]	ZHANG ChengQi,LIAO LuLu,QI YongXia,DING KeJian,CHEN Li. Functional Analysis of the Nucleoporin Gene FgNup42 in Fusarium graminearium [J]. Scientia Agricultura Sinica, 2021, 54(9): 1894-1903.
[15]	TongYu HOU,TingLi HAO,HaiJiang WANG,Ze ZHANG,Xin LÜ. Advances in Cotton Growth and Development Modelling and Its Applications in China [J]. Scientia Agricultura Sinica, 2021, 54(6): 1112-1126.