两种高通量测序技术鉴定苹果病毒效果评价及两种新病毒的鉴定

doi:10.3864/j.issn.0578-1752.2025.02.005

摘要/Abstract

摘要：

【目的】宏转录组测序（macro-transcriptome sequencing）与小RNA测序（small RNA sequencing）是病毒鉴定中常用的高通量测序技术（high-throughput sequencing technique）。本文旨在评价两种高通量测序方法检测不同类型的组织样本对苹果新发病毒鉴定的效率，为苹果病毒病的准确诊断提供依据。【方法】2022年8月自衡水深州市采集带有新病毒症状的‘鲁丽’苹果果皮和枝皮，提取总RNA后，分别构建宏转录组文库和小RNA文库进行高通量测序，利用生物信息学技术和软件分析数据。首先，比较高通量测序结果的各项指标，然后，采用层次分析法（analytic hierarchy process，AHP）和5级分级评分法综合比较各项指标的加权值，评价不同测序方法的效果。最后，利用RT-PCR方法验证高通量测序结果，对新发病毒进行基因组特性和系统进化关系分析。【结果】从拼接效果来讲，采用相同的组织材料，宏转录组优于小RNA测序技术，采用相同的技术，果皮的拼接效果优于枝皮。从检出的病毒种类数量来讲，宏转录组测序技术检测枝皮检出的病毒种类最多，包括苹果褪绿叶斑病毒（apple chlorotic leaf spot virus，ACLSV）、苹果茎痘病毒（apple stem pitting virus，ASPV）、苹果茎沟病毒（apple stem grooving virus，ASGV）、苹果坏死花叶病毒（apple necrotic mosaic virus，ApNMV）、苹果胶质木病毒-2（apple rubbery wood virus 2，ARWV-2）、苹果绿皱果相关病毒（apple green crinkle associated virus，AGCaV）、柑橘囊胶相关病毒（citrus concave gum-associated virus，CCGaV）、柑橘碎叶病毒（citrus tatter leaf virus，CTLV）8种病毒；小RNA测序技术检测枝皮，检出病毒种类最少，小RNA测序技术检测果皮与枝皮病毒种类存在差异，采用果皮作为检测对象，两种方法检测出病毒种类数量相同。比较各项指标的综合评分，宏转录组检测枝皮分数最高。高通量测序结果与RT-PCR检测结果一致。ARWV-2、CCGaV在河北省为首次发现，分别命名为ARWV-2河北分离物（ARWV-2-HB）、CCGaV河北分离物（CCGaV-HB）。ARWV-2-HB CP GenBank登录号为PQ095583，CCGaV-HB MP和CP GenBank登录号分别为PQ095581、PQ095582，两种病毒基因序列与代表性分离物一致性均在96%以上，以ARWV-2和CCGaV CP氨基酸序列为基础构建系统发育树，ARWV-2-HB与LYXS（MZ819711）亲缘关系最近；CCGaV-HB与Mishima（MK940543）、Gala（MK940542）、Gala-BJ（OP820577）、Fuji-BJ（OP556109）和AC1（MH038043）亲缘关系相对密切。【结论】利用宏转录组测序与小RNA测序技术对相同‘鲁丽’果树疑似病毒病样本的果皮和枝皮分别进行测序，宏转录组测序技术检测苹果枝皮测序效果最好，检出病毒种类最多，获得相对完整的病毒基因组序列。采用小RNA测序，果皮和枝皮只能揭示部分病毒种类，检出的病毒种类存在差异，建议两种组织材料同时检测。在河北省报道了ARWV-2与CCGaV，揭示了ARWV-2-HB和CCGaV-HB的部分基因组序列，丰富了ARWV-2和CCGaV基因序列信息，明确了这两种病毒与其他代表性分离物的系统进化关系。

关键词: 宏转录组测序, 小RNA测序, 苹果病毒, 鉴定, 河北省

Abstract:

【Objective】Macro-transcriptome sequencing and small RNA sequencing are commonly used high-throughput sequencing techniques in virus identification. The objective of this study is to explore the application efficiency of macro-transcriptome sequencing and small RNA sequencing in the identification of emerging viruses in apples, analyze the impact of different tissue types on the identification results, and to provide a basis for the accurate diagnosis of apple virus diseases.【Method】The samples of apple peel and branch bark were collected from ‘Luli’ apple trees exhibiting novel viral symptoms in Shenzhou County of Hengshui City in August 2022. Total RNA was extracted, and macro-transcriptome libraries and small RNA libraries were constructed for high-throughput sequencing. Bioinformatic techniques and software were utilized to analyze and evaluate the sequencing data. Initially, the indicators from the high-throughput sequencing technique results were compared. Subsequently, a comprehensive evaluation of the effectiveness of each sequencing method was conducted using the analytic hierarchy process (AHP) and a 5-level grading system to calculate the weighted values of these indicators. Finally, RT-PCR was employed to validate the high-throughput sequencing results, and the genomic characteristics and phylogenetic relationships of the emerging viruses were analyzed.【Result】In terms of splicing effect, using the same tissue material, the macro-transcriptome sequencing outperformed small RNA sequencing. When the same technique was applied, the splicing effect for fruit peel tissue was better than that of branch bark. In terms of the number of virus species detected, macro-transcriptome sequencing identified the highest number of virus species in branch bark, including eight viruses: apple chlorotic leaf spot virus (ACLSV), apple stem pitting virus (ASPV), apple stem grooving virus (ASGV), apple necrotic mosaic virus (ApNMV), apple rubbery wood virus 2 (ARWV-2), apple green crinkle associated virus (AGCaV), citrus concave gum-associated virus (CCGaV), and citrus tatter leaf virus (CTLV). In contrast, small RNA sequencing technique detected the fewest virus types in branch bark. There were differences in virus types between fruit peels and branch barks detected through small RNA sequencing technique. When fruit peels were used as the detection target, both methods identified the same number of virus types. After comprehensively comparing the synthesis score of various indicators, the macro-transcriptome sequencing of bark samples scored the highest. The results of high-throughput sequencing were consistent with those obtained through RT-PCR. ARWV-2 and CCGaV were discovered for the first time in Hebei Province, and were designated as ARWV-2-HB and CCGaV-HB. The GenBank accession numbers for the coat protein (CP) gene of ARWV-2-HB and the movement protein (MP) and CP genes of CCGaV-HB are PQ095583, PQ095581, and PQ095582. The genomic sequences of both viruses showed over 96% identity to their respective representative isolates. Phylogenetic trees constructed based on the CP amino acid sequences of ARWV-2 and CCGaV revealed that ARWV-2-HB was most closely related to LYXS (MZ819711), while CCGaV-HB exhibited relatively close relationships with Mishima (MK940543), Gala (MK940542), Gala-BJ (OP820577), Fuji-BJ (OP556109), and AC1 (MH038043).【Conclusion】Using macro-transcriptome sequencing and small RNA sequencing techniques, the fruit peel and branch bark of the same ‘Luli’ apple tree were sequenced separately. Among two sequencing methods, the macro-transcriptome sequencing of branch bark showed the best sequencing effect, discovered the highest number of viruses and relatively complete viral genome sequences. When using small RNA sequencing, only a portion of virus types could be detected in both fruit peels and branch barks. Due to the differences in virus types detected from different tissue materials, it is recommended to test both tissue materials simultaneously. ARWV-2 and CCGaV were reported in Hebei Province in this study, and partial genomic sequences of ARWV-2-HB and CCGaV-HB were revealed, which enriching the genomic sequence information of ARWV-2 and CCGaV. Furthermore, the phylogenetic relationships of these two viruses with other representative isolates have been clarified.

Key words: macro-transcriptome sequencing, small RNA sequencing, apple virus, identification, Hebei Province

潘媛, 王德, 刘楠, 孟祥龙, 戴蓬博, 李波, 胡同乐, 王树桐, 曹克强, 王亚南. 两种高通量测序技术鉴定苹果病毒效果评价及两种新病毒的鉴定[J]. 中国农业科学, 2025, 58(2): 266-280.

PAN Yuan, WANG De, LIU Nan, MENG XiangLong, DAI PengBo, LI Bo, HU TongLe, WANG ShuTong, CAO KeQiang, WANG YaNan. Evaluation of the Effectiveness of Two High-Throughput Sequencing Techniques in Identifying Apple Viruses and Identification of Two Novel Viruses[J]. Scientia Agricultura Sinica, 2025, 58(2): 266-280.

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指标 Index	分值Score
指标 Index	2	4	6	8	10
病毒contigs数量Viral contigs number	0-12	12-24	24-36	36-48	48-50
病毒contigs长度Viral contigs length (bp)	1-1500	1500-3000	3000-4500	4500-6000	6000-7500
N50值N50 value (bp)	0-600	600-1200	1200-1800	1800-2400	2400-3000
N90值N90 value (bp)	0-100	100-200	200-300	300-400	400-500
完整性Completeness (%)	0-20	20-40	40-60	60-80	80-100
病毒种类Viral type	0-1	2-3	4-5	6-7	8

引物名称 Primer name	引物序列 Primer sequence (5′-3′)	产物大小 Product size (bp)	用途 Purpose	参考文献 Reference
ASPV-F	TGGAACCTCATGCTGCA	360	ASPV鉴定 ASPV identification	[26]
ASPV-R	TTGGGATCAACTTTACTAAAAAGCATAA	360	ASPV鉴定 ASPV identification	[26]
ARWV-F	ACAAGGCAGTAGTTATTATCAGCAA	484	ARWV-2鉴定 ARWV-2 identification	[19]
ARWV-R	TTCTGCAACTAACTTCAAGGCTG	484	ARWV-2鉴定 ARWV-2 identification	[19]
ASGV-F	CCCGCTGTTGGATTTGATACACCTC	525	ASGV鉴定 ASGV identification	[12]
ASGV-R	CTGCAAGACCGCGACCAAGTTT	525	ASGV鉴定 ASGV identification	[12]
ACLSV-F	GAGAGTTTCAGTTTGCTAGACA	566	ACLSV鉴定 ACLSV identification	[27]
ACLSV-R	GCAAATTCAGTCTGTAAAAG	566	ACLSV鉴定 ACLSV identification	[27]
AGCaV-F	TCGGAAAGACTGTCCCGTTG	647	AGCaV鉴定 AGCaV identification	[4]
AGCaV-R	ACTCTTGCCCCCGATTCTTG	647	AGCaV鉴定 AGCaV identification	[4]
ApNMV-F	ATGGTGTGCAATCGCTGTCA	657	ApNMV鉴定 ApNMV identification	[28]
ApNMV-R	CATCGACCATAAGGATATCA	657	ApNMV鉴定 ApNMV identification	[28]
CTLV-F	CCCTCTCAGCTAGAATTGAA	889	CTLV鉴定 CTLV identification	[29]
CTLV-R	AGAGTGGACAAACTCTAGAC	889	CTLV鉴定 CTLV identification	[29]
CCGaV-F	TGCCCATCCTTCTAACCTG	954	CCGaV鉴定 CCGaV identification	[21]
CCGaV-R	TTCCCATACAGTTTGCCG	954	CCGaV鉴定 CCGaV identification	[21]

分离物 Isolate	登录号 Accession number	寄主 Host	国家 Country
Fuji-BJ	OP547336	苹果Apple	巴西Brazil
R12	MF062141	苹果Apple	德国Germany
LYXS	MZ819711	梨Pear	中国China
982-11	MF062129	苹果Apple	加拿大Canada
982-11	MF062127	苹果Apple	加拿大Canada

分离物 Isolate	登录号 Accession number	寄主 Host	国家 Country	分离物 Isolate	登录号 Accession number	寄主 Host	国家 Country
Mishima	MK940543	苹果Apple	巴西Brazil	HU_Reglindis	ON593790	苹果Apple	匈牙利Hungary
Gala	MK940542	苹果Apple	巴西Brazil	HU_Jonagold	ON593789	苹果Apple	匈牙利Hungary
Fuji-BJ	OP556109	苹果Apple	巴西Brazil	CGW2	NC_035454	柑橘Citrus	意大利Italy
Weihai	MZ926714	苹果Apple	中国China	UN7	MH137741	柑橘Citrus	中国China
Gala-BJ	OP820577	苹果Apple	巴西Brazil	LR3	MG764564	柑橘Citrus	意大利Italy
AC1	MH038043	苹果Apple	美国USA	HU_Florina	ON593791	苹果Apple	匈牙利Hungary
CCGaV_RNA2_T	OR640154	苹果Apple	土耳其Turkey	CGW2	KX960111	柑橘Citrus	意大利Italy
CE-c3	OK495691	苹果Apple	意大利Italy

样品种类 Sample type	测序方法 Sequencing method	Clean reads数量 Clean reads number	Contigs 数量 Contigs number	Contigs 长度 Contigs length (bp)	N50值N50 value (bp)	N90值N90 value (bp)	病毒来源reads数量 Viral source reads number	病毒contigs数量 Viral contigs number	病毒contigs 长度 Viral contigs length (bp)
果皮 Fruit peel	宏转录组测序 Macro-transcriptome sequencing	5146706	9161	300-7543	2620	451	58188	31	319-7506
果皮 Fruit peel	小RNA测序 Small RNA sequencing	9274079	2093	33-362	1150	282	144	12	213-2708
枝皮 Branch bark	宏转录组测序 Macro-transcriptome sequencing	7901932	12244	300-6470	1339	396	12738	60	304-6470
枝皮 Branch bark	小RNA测序 Small RNA sequencing	9896385	793	300-460	738	232	526	10	205-2726