柑橘黄化花叶病毒的实时定量PCR检测及其在寄主植株中的时空分布规律

doi:10.3864/j.issn.0578-1752.2023.18.007

Abstract

Abstract:

【Background】Citrus yellow mosaic virus (CYMV) is a member of badnaviruses that was first discovered in India and caused serious damage to its citrus industry. At present, CYMV has been listed as a quarantine pest in the United States, Japan, New Zealand, Europe and the Mediterranean region, which has the potential risk of being introduced into China.【Objective】The objective of this study is to establish a real-time quantitative PCR (qPCR) detection system for CYMV, screen sensitive citrus varieties to CYMV, elucidate the spatial and temporal distribution of CYMV in host plant, and to provide technical support for monitoring of the virus.【Method】According to the conserved sequences of CYMV coat protein (CP) gene in NCBI, eight pairs of qPCR primers were designed using software Primer Premier 5, and were screened by conventional PCR for primer pairs with good amplification effect and high specificity. The concentration and annealing temperature of the primers were optimized to establish the CYMV qPCR detection system. The specificity of the system was evaluated by detecting different citrus pathogens. Conventional PCR and qPCR were performed in parallel with 1.98×10⁹-1.98 copies/μL of plasmid standards diluted in a gradient as template to evaluate the sensitivity of the established system. The field citrus samples were collected randomly and detected using conventional PCR and qPCR in parallel to evaluate the applicability of the method. Fifteen citrus varieties including Yuhuanyou (Citrus grandis), Chandler pomelo (C. grandis), No.22 karatachi (Poncirus trifoliata), etc., were inoculated with CYMV for symptom observation and molecular detection to screen sensitive indicator plants. Samples from different tissues of Madam Vinous orange (C. sinensis) plants were collected at different times post inoculation, and qPCR assays were performed with C. sinensis elongation factor 1 alpha as an internal reference gene to clarify the spatial and temporal distribution patterns of CYMV in the host plants.【Result】The qPCR detection system for CYMV was established with the optimal primer of CYMV-qF7/R7, the optimal concentration 200 nmol·L^-1 and the optimal annealing temperature 63 ℃. The results of the evaluation experiments showed that the specificity of the established qPCR system is strong, and the detection sensitivity is 1 000 times that of the conventional PCR. The detection results of 660 field citrus samples from different regions showed that the qPCR assay was consistent with the conventional PCR assay, and no CYMV-positive plants were detected except for the positive control. Among the 15 citrus varieties in the inoculation experiment, Yuhuanyou and Chandler pomelo showed strong and typical yellowing mosaic symptoms of CYMV infection at the earliest, suggesting that both could be used as sensitive indicator plants. The detection results of qPCR showed that the titer of CYMV in old leaves was the highest, the titer of virus in old cortex and root was higher, and the titer in tender cortex was lower. The relative content of CYMV in plants was highest from July to September, then decreased month by month, and reached the lowest value in January of the next year. From February of the next year, the relative content of CYMV began to rise, which was consistent with the change trend of the environmental temperature.【Conclusion】A qPCR assay for CYMV detection with high specificity and sensitivity was established, and the spatial and temporal distribution pattern of CYMV in the host plants was determined. In addition, Yuhuanyou and Chandler pomelo can be used as CYMV-sensitive indicator plants.

Key words: citrus yellow mosaic virus (CYMV), real-time quantitative PCR (qPCR), spatial and temporal distribution

CAO Peng, XU JianJian, LI ChuXin, WANG XinLiang, WANG ChunQing, SONG ChenHu, SONG Zhen. Real-Time Quantitative PCR Detection of Citrus Yellow Mosaic Virus and Its Spatial and Temporal Distribution in Host Plants[J].Scientia Agricultura Sinica, 2023, 56(18): 3574-3584.

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References 32

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引物名称 Primer name	引物序列 Primer sequence (5′-3′)	扩增产物长度 Product length (bp)	用途 Usage
CYMV-CP-F	GATGAATATGAGAACCTTGTTACAACT	642	CP序列扩增 CP sequence amplification
CYMV-CP-R	TCGTTTCACATTTCGCCG	642	CP序列扩增 CP sequence amplification
CYMV-JC-F	ACACCGGAAACGGTGAAGTT	342	CYMV检测 CYMV detection
CYMV-JC-R	ACCCTTCGAACATGGGCATT	342	CYMV检测 CYMV detection
EF-1α F	CTCAAGCCTGGTATGGTGGT	185	内参基因 Reference gene
EF-1α R	GGATCATCCTTCGAGTTGGA	185	内参基因 Reference gene
CYMV-qF1	TTGGTGTTTGCCCTCGGATT	119	qPCR检测 qPCR detection
CYMV-qR1	GCCTGGGATAGGGATTGAGC	119
CYMV-qF2	TGGGCATAGTTCAGGTTCGG	93
CYMV-qR2	CTCCTTGCCACCGATTGTCT	93
CYMV-qF3	CCAGTCGTGCTCGTACAGTT	119
CYMV-qR3	CCGCTGCCACTGCCTATAAT	119
CYMV-qF4	CAGGAGTACATCGCCTGGTG	149
CYMV-qR4	TTTCGCCTGCGAGAGTCTAC	149
CYMV-qF5	CAAAGACTGGGCGCATGTTC	142
CYMV-qR5	AGAATCCGAGGGCAAACACC	142
CYMV-qF6	AACAGTTAAGCAGGAGCGGT	128
CYMV-qR6	TCCTTGCCACCGATTGTCTC	128
CYMV-qF7	GCTCAATCCCTATCCCAGGC	208
CYMV-qR7	ACATTTCGCCGGTCATTTGG	208
CYMV-qF8	TGCAAAGATGCAGCGTTCA	59
CYMV-qR8	GGGATTGAGCTGCAAAAGGA	59

地区 <BOLD>R</BOLD>egion	采集品种 Variety	常规PCR（阳性数/总数） Conventional PCR (Positive/Total)	qPCR（阳性数/总数） qPCR (Positive/Total)
广西Guangxi	砂糖橘C. reticulata	0/60	0/60
湖南Hunan	宫川温州蜜柑C. unshiu	0/150	0/150
湖南Hunan	纽荷尔脐橙C. sinensis	0/150	0/150
重庆Chongqing	柠檬C. limon	0/200	0/200
重庆Chongqing	沙田柚C. maxima ‘Shatian Yu’	0/100	0/100
阳性对照Positive control	MV甜橙C. sinensis	25/30	30/30

Real-Time Quantitative PCR Detection of Citrus Yellow Mosaic Virus and Its Spatial and Temporal Distribution in Host Plants

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