亚硫酸钠介导的s4U转化检测转录组新生RNA中m6A

doi:10.6023/A20100477

化学学报 ›› 2021, Vol. 79 ›› Issue (3): 326-330.DOI: 10.6023/A20100477 上一篇下一篇

研究论文

亚硫酸钠介导的s⁴U转化检测转录组新生RNA中m⁶A

危琦¹, 韩少卿¹, 陈玉琪¹, 周翔¹^,^*()

1 武汉大学化学与分子科学学院武汉 430072

投稿日期:2020-10-15 发布日期:2020-11-27
通讯作者: 周翔
作者简介:
* E-mail: xzhou@whu.edu.cn
基金资助:
项目受国家自然科学基金(91753201); 项目受国家自然科学基金(21721005); 项目受国家自然科学基金(21907079)

Sodium Sulfite-Mediated s⁴U Conversion for m⁶A Profiling of Nascent Transcriptome-Wide RNA

Qi Wei¹, Shaoqing Han¹, Yuqi Chen¹, Xiang Zhou¹^,^*()

1 College of Chemistry and Molecular Sciences, Wuhan University, Wuhan 430072, China

Received:2020-10-15 Published:2020-11-27
Contact: Xiang Zhou
About author:
† These authors contributed equally to this work.
Supported by:
National Natural Science Foundation of China(91753201); National Natural Science Foundation of China(21721005); National Natural Science Foundation of China(21907079)

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摘要/Abstract

发展了亚硫酸钠介导的4-硫代尿苷(s⁴U)转化为胞苷(C)的方法, 用s⁴U标记新生RNA, 通过反应将s⁴U转化为C可成功检测新生RNA. 将新生RNA使用s⁴U标记后进行反应, 再使用m⁶A抗体对m⁶A片段进行富集, 从m⁶A中分析T到C突变位点便成功区分出含m⁶A的新生RNA. 该方法有希望应用于单个基因上m⁶A的动态变化检测, 有助于人们进一步了解m⁶A的修饰机制, 为m⁶A功能研究提供新的方法.

关键词: 亚硫酸钠, 新生RNA, 4-硫代尿苷, N6-甲基腺嘌呤

RNA sequencing can profile gene expression at steady-state level but is weak in studying temporal RNA dynamics. A common method for nascent RNA analysis is metabolic labeling with nucleoside analog. We developed a method for nascent RNA sequencing based on sodium sulfite-mediated 4-thiouridine-to-cytidine (s⁴U-to-C) conversion. The RNA contained s⁴U is reacted in the buffer (10 mmol/L Na₂SO₃, 200 mmol/L NH₄Cl and 200 mmol/L Na₂HPO₄/NaH₂PO₄, pH 7.4) at 70 ℃ for 4 h, the yield can reach more than 90%. This method can efficiently distinguish nascent RNA information from total RNAs. SUC-seq is used to investigate the m⁶A, which is the most prevalent modification in mammalian mRNA and has been shown to have an essential regulatory role in the control of gene expression. Here, we provide a time resolved high-resolution profiling of m⁶A on nascent RNA transcripts. 3×10⁶ HEK293T cells were seeded per 10-cm cell dish and grown for 24 h. Then, s⁴U was added to the medium at a final concertation of 500 μmol/L chased for 0, 10, 15, 30, 60, 120 and 240 min. Total RNA was extracted using TRIzol reagent. 10 μg total RNA was fragmented using RNA fragmentation reagents at 70 ℃ for 10 min after gDNA was removed. Fragmented RNA was then subjected to s ⁴U reaction to realize the conversion of s⁴U to C. Subsequently, 5 μg treated RNA were taken to perform m ⁶A immunoprecipitation. After removing rRNA, library was constructed and perform next-generation sequencing. A large number of T to C mutations were observed in the mapping reads. The T to C mutation rate of the control RNA was kept at a low background level. The results show that our method can successfully distinguish nascent RNA from total RNA. Via analyzing the nascent RNA in m⁶A, the nascent m⁶A can be distinguished from the total m⁶A. This method can be a promising strategy to study the mechanism and function of m⁶A.

Key words: sodium sulfite, nascent RNA, 4-thiouridine, N6-methyladenosine

引用此文

危琦, 韩少卿, 陈玉琪, 周翔. 亚硫酸钠介导的s⁴U转化检测转录组新生RNA中m⁶A[J]. 化学学报, 2021, 79(3): 326-330.

Qi Wei, Shaoqing Han, Yuqi Chen, Xiang Zhou. Sodium Sulfite-Mediated s⁴U Conversion for m⁶A Profiling of Nascent Transcriptome-Wide RNA[J]. Acta Chimica Sinica, 2021, 79(3): 326-330.

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图/表 6

图1. s4U转化为C. (a) s4U在亚硫酸钠介导下与氯化氨反应生成C. (b) HPLC检测1 mmol/L s4U在37 ℃反应体系中反应1 h生成C. (c) LC-MS检测含s4U转录本转化反应反应效率. (d) TA克隆测序验证s4U位点成功突变为C, X=s4U.

Figure 1. s4U conversion to C. (a) The reaction of s4U with NH4Cl form C mediated by sodium sulfite. (b) Detect s4U reaction efficiency by HPLC. 1 mmol/L s4U was incubated in the buffer at 37 ℃ for 1 h. (c) Detection of s4U conversion reaction efficiency of by LC-MS. (Residues ratio of s4U is the s4U content after the reaction/the initial s4U). (d) TA-cloning study to test the feasibility of the strategy for RNA. The s4U is mutated to C after reaction, X=s4U.

图2. s4U标记2 h的RNA反应后在转录组进行测序检测. 测序文库中所有可能突变类型的比率.

Figure 2. RNA labeled with s4U for 2 h after the reaction and then sequencing at transcriptome-wide scale. Mutation rates of all possible mutation types in the sequencing libraries.

图3. RNA表达量差异性评估. (a) 箱线图显示对s4U孵育不同时间的m6A各组之间无显著差异. (b) 箱线图显示m6A峰上的基因与总体基因半衰期无显著差异.

Figure 3. Evaluation of the difference in expression level of markers at different times. (a) Box plot shows that there is no significant difference between the groups of m6A incubated at different times for s4U. (b) Box plot shows that the gene on the m6A peak is not significantly different from the overall gene.

图4. 新生m6A表达量. (a) 小提琴图显示随着标记时间增加, m6A peak中s4U含量增加. (b) 热图显示被s4U标记的m6A种类变化趋势.

Figure 4. Nascent m6A expression. (a) Violin chart shows that the s4U content in the m6A peak increases as the marking time increases. (b) Heat map shows the change trend of m6A species marked by s4U.

图5. 高通量测序分析新生m6A和总m6A. (a) 饼图显示了非重叠RNA片段中m6A位点的比例. (b) 饼图显示了非重叠新生RNA片段中m6A位点的比例. (c) m6A在基因上的占比. (d)新生m6A在基因上的占比. (e) 高通量测序验证m6A motif. (f) 新生m6A和总m6A在不同区段上的比较.

Figure 5. High-throughput sequencing analysis of nascent m6A and total m6A. (a) Pie chart presenting the fraction of m6A sites in each nonoverlapping RNA segment. (b) Pie chart presenting the fraction of nascent m6A sites in each nonoverlapping RNA segment. (c) The proportion of m6A in different segments of the gene. (d) The proportion of nascent m6A in different segments of the gene. (e) High-throughput sequencing to verify m6A motif. (f) Comparison of nascent m6A and total m6A in different sections.

图6. 高通量测序分析KIF1B和总体修饰水平变化差异. (a, b) KIF1B上的修饰水平变化. (c) 总m6A修饰水平变化.

Figure 6. High-throughput sequencing analysis of KIF1B and overall modification level changes. (a, b) Modification level change on KIF1B. (c) Modification level change of total m6A.

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亚硫酸钠介导的s⁴U转化检测转录组新生RNA中m⁶A

Sodium Sulfite-Mediated s⁴U Conversion for m⁶A Profiling of Nascent Transcriptome-Wide RNA

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