A型塞尼卡病毒基因组内保守基序介导翻译调控研究

doi:10.3864/j.issn.0578-1752.2026.12.015

摘要/Abstract

摘要：

【目的】利用核糖体图谱测序（ribosome sequencing，Ribo-seq）技术解析A型塞尼卡病毒（Senecavirus A，SVA）基因组中调控翻译延伸的关键序列，并评估其对病毒复制的影响。为阐明SVA编码区内RNA元件在翻译调控中的作用奠定基础。【方法】以rSVA-eGFP为模型进行Ribo-seq分析，绘制SVA全基因组翻译图谱，以定位核糖体翻译延伸停滞峰。针对停滞峰对应序列设计同义突变并构建全长cDNA重组质粒，通过反向遗传学拯救具有复制能力的重组病毒。随后，对重组病毒进行盲传、RT-PCR、测序和生长曲线测定等以评估突变对病毒复制的影响。选取代表性的重组病毒进行Ribo-seq分析，以明确改造位点对病毒复制和蛋白翻译的影响。【结果】Ribo-seq分析显示，SVA的VP1、2C和3D基因内均存在显著的核糖体翻译停滞峰，提示这些区域可能存在阻碍核糖体迁移的关键基序。为验证这一假设，对该3个区域进行同义突变以构建重组病毒。结果发现，仅3D区域突变能够成功拯救出具有复制能力的病毒，且该突变在连续20次传代后仍保持稳定，对病毒生长动力学无显著影响，说明3D区域的基序对病毒的复制是非必需的。相比之下，VP1和2C区域的突变均无法获得可复制病毒，表明其基序对病毒复制至关重要。进一步对重组病毒进行Ribo-seq分析发现，2C和3D区域的停滞峰均在突变后消失，认为2C区域所对应的关键基序，不是决定病毒蛋白翻译速率的唯一因素；而3D区域中的关键基序，其序列突变不影响病毒正常复制，但可影响病毒蛋白的翻译速率。【结论】本研究通过Ribo-seq分析SVA全基因组调控翻译延伸的关键序列发现，在VP1和2C区域中的关键基序对病毒复制至关重要，而3D区域中的关键基序虽对病毒复制非必需但可影响蛋白翻译速率。

关键词: 核糖体图谱测序, A型塞尼卡病毒, 反向遗传学, 核糖体停滞, 翻译调控

Abstract:

【Objective】Ribosome sequencing (Ribo-seq) technology was employed to analyze key sequences regulating translation elongation in the Senecavirus A (SVA) genome and to evaluate their impact on viral replication, thereby providing a theoretical foundation for elucidating the molecular mechanisms of SVA. Which could lay a foundation for clarifying the role of RNA elements in SVA coding region in translation regulation.【Method】Ribo-seq was performed using rSVA-eGFP as a model to generate a genome-wide translation profile of SVA and to identify ribosome pausing peaks. Synonymous mutations were then designed for the sequences corresponding to these pausing sites, and full-length cDNA recombinant plasmids were constructed. Replication-competent recombinant viruses were subsequently rescued through reverse genetics. The rescued viruses were subjected to serial blind passages, RT-PCR, sequencing, and growth-curve analyses to evaluate the effects of the mutations on viral replication. Representative recombinant viruses were selected for secondary Ribo-seq analysis to elucidate the effects of the modification site on viral replication and protein translation.【Result】Ribo-seq data revealed significant ribosomal translation-stall peaks in VP1, 2C, and 3D genes of SVA, suggesting the presence of key motifs that impede ribosome translocation. To test this hypothesis, synonymous mutations were introduced into these three regions to construct recombinant viruses. The results indicated that only the mutant in the 3D region successfully rescued replication-competent virus, and the introduced mutation remained stable after 20 consecutive passages, with no significant impact on viral growth kinetics. These findings indicated that the motifs in the 3D region were nonessential for viral replication. In contrast, mutations in the VP1 and 2C regions failed to produce viable viruses, demonstrating that the motifs in these regions were essential for viral replication. Further Ribo-seq analysis of the rescued virus revealed that the pausing peaks in both the 2C and 3D regions disappeared after mutation. This suggested that the key motifs in the 2C region, if any, were not the sole determinant of the translation rate of viral proteins, whereas the motif in the 3D region, although not required for viral replication, could modulate the translation efficiency of viral proteins.【Conclusion】Through genome-wide Ribo-seq profiling of SVA, this study identified critical sequence motifs that regulate translational elongation. The motifs in the VP1 and 2C regions were essential for viral replication, while the motif in the 3D region, though non-essential for viral replication, could affect protein translation rates.

Key words: ribosome sequencing, Senecavirus A, reverse genetics, ribosome stalling, translational regulation

李彦, 段笑笑, 王洁, DASHZEVGE Erdenechimeg, 李志娟, 王迁迁, 刘拂晓. A型塞尼卡病毒基因组内保守基序介导翻译调控研究[J]. 中国农业科学, 2026, 59(12): 2740-2749.

LI Yan, DUAN XiaoXiao, WANG Jie, DASHZEVGE Erdenechimeg, LI ZhiJuan, WANG QianQian, LIU FuXiao. Study of Translation Regulation Mediated by Conserved Motifs Within Senecavirus A Genome[J]. Scientia Agricultura Sinica, 2026, 59(12): 2740-2749.

图/表 5

表1

表2

图1

图2

图3

参考文献 35

[1]	WANG H, NIU C X, NONG Z R, QUAN D Q, CHEN Y, OUYANG K, HUANG W J, WEI Z Z. Emergence and phylogenetic analysis of a novel Seneca Valley virus strain in the Guangxi Province of China. Research in Veterinary Science, 2020, 130: 207-211. doi: S0034-5288(19)31101-4 pmid: 32200161
[2]	朱琳. 猪塞内卡病毒病综述及防控. 畜牧兽医科学(电子版), 2022(21): 148-150.
	ZHU L. Review and prevention of Seneca virus disease in pigs. Graziery Veterinary Sciences (Electronic Version), 2022(21): 148-150. (in Chinese)
[3]	TOUSIGNANT S J P, BRUNER L, SCHWARTZ J, VANNUCCI F, ROSSOW S, MARTHALER D G. Longitudinal study of Senecavirus a shedding in sows and piglets on a single United States farm during an outbreak of vesicular disease. BMC Veterinary Research, 2017, 13(1): 277. doi: 10.1186/s12917-017-1172-7 pmid: 28859639
[4]	FERNANDES M H V, DE LIMA M, JOSHI L R, DIEL D G. A virulent and pathogenic infectious clone of Senecavirus A. The Journal of General Virology, 2021, 102(8): 001643.
[5]	LI Y, LIU T Y, ZHANG Y M, DUAN X X, LIU F X. RNA recombination: non-negligible factor for preventing emergence or reemergence of Senecavirus A. Frontiers in Veterinary Science, 2024, 11: 1357179. doi: 10.3389/fvets.2024.1357179
[6]	ZHAO D, LI Y, LI Z W, ZHU L J, SANG Y X, ZHANG H, ZHANG F, NI B, LIU F X. Only fourteen 3'-end poly(a)s sufficient for rescuing Senecavirus A from its cDNA clone, but inadequate to meet requirement of viral replication. Virus Research, 2023, 328: 199076. doi: 10.1016/j.virusres.2023.199076
[7]	LIU F X, WANG Q Q, HUANG Y L, WANG N, SHAN H. A 5-year review of senecavirus a in China since its emergence in 2015. Frontiers in Veterinary Science, 2020, 7: 567792. doi: 10.3389/fvets.2020.567792
[8]	LI Y, ZHANG L, WANG L, LI J, ZHAO Y W, LIU F X, WANG Q Q. Structure and function of type IV IRES in picornaviruses: A systematic review. Frontiers in Microbiology, 2024, 15: 1415698. doi: 10.3389/fmicb.2024.1415698
[9]	LIU F X, ZHAO D, WANG N, LI Z W, DONG Y Q, LIU S, ZHANG F, CUI J, MENG H L, NI B, WEI R, SHAN H. Tolerance of senecavirus a to mutations in its kissing-loop or pseudoknot structure computationally predicted in 3′ untranslated region. Frontiers in Microbiology, 2022, 13: 889480. doi: 10.3389/fmicb.2022.889480
[10]	ZHAO D, WANG Q Q, WANG M Y, LYU L P, LIU S Q, JIANG Y J, ZHOU S N, LIU F X. A putative wild-type or wild-type-like hairpin structure is required within 3′ untranslated region of Senecavirus A for virus replication. Virology, 2023, 585: 72-77. doi: 10.1016/j.virol.2023.05.008
[11]	MENG H L, WANG X L, WANG L, WANG Q Q, ZHU L J, SANG Y X, LIU F X. Identification of cis-acting replication element in VP2- encoding region of Senecavirus A genome. Veterinary Microbiology, 2023, 280: 109717. doi: 10.1016/j.vetmic.2023.109717
[12]	WANG X L, MENG H L, DUAN X X, SANG Y X, ZHANG Y M, LI Y, LIU F X. The 3' end of the coding region of senecavirus A contains a highly conserved sequence that potentially forms a stem-loop structure required for virus rescue. Archives of Virology, 2023, 168(10): 256. doi: 10.1007/s00705-023-05863-x pmid: 37737963
[13]	KUMARI R, MICHEL A M, BARANOV P V. PausePred and Rfeet: Webtools for inferring ribosome pauses and visualizing footprint density from ribosome profiling data. Rna, 2018, 24(10): 1297-1304. doi: 10.1261/rna.065235.117 pmid: 30049792
[14]	YANG Z L, CAO S, MARTENS C A, PORCELLA S F, XIE Z, MA M, SHEN B, MOSS B. Deciphering poxvirus gene expression by RNA sequencing and ribosome profiling. Journal of Virology, 2015, 89(13): 6874-6886. doi: 10.1128/JVI.00528-15 pmid: 25903347
[15]	ZHAO J, HUANG Y H, LIUKANG C Y, YANG R H, TANG L H, SUN L, ZHAO Y, ZHANG G Z. Dissecting infectious bronchitis virus-induced host shutoff at the translation level. Journal of Virology, 2024, 98(7): e00830-e00824.
[16]	STERN-GINOSSAR N, INGOLIA N T. Ribosome profiling as a tool to decipher viral complexity. Annual Review of Virology, 2015, 2: 335-349. doi: 10.1146/virology.2015.2.issue-1
[17]	LIU F X, HUANG Y L, WANG Q Q, SHAN H. Construction of eGFP-tagged senecavirus a for facilitating virus neutralization test and antiviral assay. Viruses, 2020, 12(3): 283. doi: 10.3390/v12030283
[18]	DUNCAN C D S, JUAN M T. Effects of cycloheximide on the interpretation of ribosome profiling experiments in Schizosaccharomyces pombe. Scientific Reports, 2017, 7: 10331. doi: 10.1038/s41598-017-10650-1
[19]	DIAMENT A, TULLER T. Estimation of ribosome profiling performance and reproducibility at various levels of resolution. Biology Direct, 2016, 11(1): 24. doi: 10.1186/s13062-016-0127-4
[20]	BRAR G A, WEISSMAN J S. Ribosome profiling reveals the what, when, where and how of protein synthesis. Nature Reviews Molecular Cell Biology, 2015, 16(11): 651-664. doi: 10.1038/nrm4069 pmid: 26465719
[21]	LIMBU M S, XIONG T Z, WANG S F. A review of Ribosome profiling and tools used in Ribo-seq data analysis. Computational and Structural Biotechnology Journal, 2024, 23: 1912-1918. doi: 10.1016/j.csbj.2024.04.051 pmid: 38721586
[22]	IRIGOYEN N, FIRTH A E, JONES J D, CHUNG B Y, SIDDELL S G, BRIERLEY I. High-resolution analysis of coronavirus gene expression by RNA sequencing and ribosome profiling. PLoS Pathogens, 2016, 12(2): e1005473.
[23]	PENZA V, RUSSELL S J, SCHULZE A J. The long-lasting Enigma of polycytidine (polyC) tract. PLoS Pathogens, 2021, 17(8): e1009739.
[24]	LIU F X, WANG N, HUANG Y L, WANG Q Q, SHAN H. Stem II-disrupting pseudoknot does not abolish ability of Senecavirus A IRES to initiate protein expression, but inhibits recovery of virus from cDNA clone. Veterinary Microbiology, 2021, 255: 109024. doi: 10.1016/j.vetmic.2021.109024
[25]	LIU F X, WANG N, WANG Q, SHAN H. Motif mutations in pseudoknot stem I upstream of start codon in Senecavirus A genome: Impacts on activity of viral IRES and on rescue of recombinant virus. Veterinary Microbiology, 2021, 262: 109223. doi: 10.1016/j.vetmic.2021.109223
[26]	GRZYBOWSKA E A, WAKULA M. Protein binding to cis-motifs in mRNAs coding sequence is common and regulates transcript stability and the rate of translation. Cells, 2021, 10(11): 2910. doi: 10.3390/cells10112910
[27]	STEIN K C, FRYDMAN J. The stop-and-go traffic regulating protein biogenesis: How translation kinetics controls proteostasis. Journal of Biological Chemistry, 2019, 294(6): 2076-2084. doi: 10.1074/jbc.REV118.002814 pmid: 30504455
[28]	GINGOLD H, PILPEL Y. Determinants of translation efficiency and accuracy. Molecular Systems Biology, 2011, 7(1): MSB201114.
[29]	CHARNESKI C A, HURST L D. Positively charged residues are the major determinants of ribosomal velocity. PLoS Biology, 2013, 11(3): e1001508.
[30]	SOMOGYI P, JENNER A J, BRIERLEY I, INGLIS S C. Ribosomal pausing during translation of an RNA pseudoknot. Molecular and Cellular Biology, 1993, 13(11): 6931-6940. doi: 10.1128/mcb.13.11.6931-6940.1993 pmid: 8413285
[31]	RODNINA M V. The ribosome in action: Tuning of translational efficiency and protein folding. Protein Science, 2016, 25(8): 1390-1406. doi: 10.1002/pro.2950 pmid: 27198711
[32]	TULLER T, WALDMAN Y Y, KUPIEC M, RUPPIN E, SHERMAN F. Translation efficiency is determined by both codon bias and folding energy. Proceedings of the National Academy of Sciences of the United States of America, 2010, 107(8): 3645-3650.
[33]	KOZAK M. Influences of mRNA secondary structure on initiation by eukaryotic ribosomes. Proceedings of the National Academy of Sciences of the United States of America, 1986, 83(9): 2850-2854.
[34]	CASAS-VILA N, SAYOLS S, PÉREZ-MARTÍNEZ L, SCHEIBE M, BUTTER F. The RNA fold interactome of evolutionary conserved RNA structures in S. cerevisiae. Nature Communications, 2020, 11: 2789. doi: 10.1038/s41467-020-16555-4
[35]	DOMINGUEZ D, FREESE P, ALEXIS M S, SU A, HOCHMAN M, PALDEN T, BAZILE C, LAMBERT N J, VAN NOSTRAND E L, PRATT G A, YEO G W, GRAVELEY B R, BURGE C B. Sequence, structure, and context preferences of human RNA binding proteins. Molecular Cell, 2018, 70(5): 854-867.e9. doi: S1097-2765(18)30351-4 pmid: 29883606

	峰1 Peak 1（VP1）	峰2 Peak 2（2C）	峰3 Peak 3（3D）
原始序列 Original sequence	GTCAAGTTCCTGTTTGACCGATCTCGATTACTGAATGTAATTAAGGTA	CGGATCAACTACGACTTGACTCTAGAAGTATCTGAGGCCTACAAAAAG	TTTGACTCTTCACACGGCACTGGCTCCTTCGAAGCTCTCATCTCT
同义突变序列 Synonymously mutated sequence	GTGAAATTTTTATTCGATAGGAGCAGGCTTTTAAACGTTATAAAAGTT	AGAATTAATTATGATCTCACATTGGAGGTTAGCGAAGCGTATAAGAAA	TTCGATAGCAGTCATGGGACAGGGAGTTTTGAGGCATTGATAAGC

cDNA克隆 cDNA clone	正向引物1 FP1 (5′ to 3′)	反向引物1 RP1 (5′ to 3′)	正向引物2 FP2 (5′ to 3′)	反向引物2 RP2 (5′ to 3′)
cD-I	aactctagttggacctttgtcat	cgtccttctccagaacttttataacgtttaaaagcc	cgttataaaagttctggagaaggacgccgtcttccc	aattaggaaggtccggccggcca
cD-II	aactctagttggacctttgtcat	cataattaattctacgagagaccgcagaaggatcag	tgcggtctctcgtagaattaattatgatctcacatt	aattaggaaggtccggccggcca
cD-III	ctagaccctatggatccccaca	cggtgaaaaagtggcttatcaatgcctcaaaactcc	ggcattgataagccactttttcaccgttgacaatgg	gctgatcagcgggtttaaacgg