× 中 miRNA-mRNAs 网络参与耐寒性的全基因组分析

Genome-Wide Analysis of the miRNA-mRNAs Network Involved in Cold Tolerance in × .

机构信息

State Key Laboratory of Tree Genetics and Breeding, Northeast Forestry University, 26 Hexing Road, Harbin 150040, China.

College of Life Science, Northeast Forestry University, 26 Hexing Road, Harbin 150040, China.

出版信息

Genes (Basel). 2019 Jun 5;10(6):430. doi: 10.3390/genes10060430.

DOI:10.3390/genes10060430

PMID:31195761

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6627750/

Abstract

BACKGROUND

Cold tolerance is important for plants' geographical distribution and survival in extreme seasonal variations of climate. However, × shows wide adaptability and strong cold resistance. Transcriptional and post-transcriptional regulation of cold-responsive genes is crucial for cold tolerance in plants. To understand the roles of regulatory RNAs under cold induction in × , we constructed cDNA and small RNA libraries from leaf buds treated or not with -4 °C for 8 h for analysis.

RESULTS

Through high-throughput sequencing and differential expression analysis, 61 miRNAs and 1229 DEGs were identified under cold induction condition in × The result showed that miR167a, miR1450, miR319a, miR395b, miR393a-5p, miR408-5p, and miR168a-5p were downregulated, whereas transcription level of miR172a increased under the cold treatment. Thirty-one phased-siRNA were also obtained (reads ≥ 4) and some of them proceeded from TAS3 loci. Analysis of the differentially expressed genes (DEGs) showed that transcription factor genes such as Cluster-15451.2 (putative MYB), Cluster-16493.29872 (putative bZIP), Cluster-16493.29175 (putative SBP), and Cluster-1378.1 (putative ARF) were differentially expressed in cold treated and untreated plantlets of × Integrated analysis of miRNAs and transcriptome showed miR319, miR159, miR167, miR395, miR390, and miR172 and their target genes, including MYB, SBP, bZIP, ARF, LHW, and ATL, were predicted to be involved in ARF pathway, SPL pathway, DnaJ related photosystem II, and LRR receptor kinase, and many of them are known to resist chilling injury. Particularly, a sophisticated regulatory model including miRNAs, phasiRNAs, and targets of them was set up.

CONCLUSIONS

Integrated analysis of miRNAs and transcriptome uncovered the complicated regulation of the tolerance of cold in × MiRNAs, phasiRNAs, and gene-encoded transcription factors were characterized at a whole genome level and their expression patterns were proved to be complementary. This work lays a foundation for further research of the pathway of sRNAs and regulatory factors involved in cold tolerance.

摘要

背景

冷耐受性对于植物在气候变化的极端季节性变化中的地理分布和生存至关重要。然而， × 表现出广泛的适应性和很强的耐寒性。植物中冷响应基因的转录和转录后调控对于冷耐受性至关重要。为了了解冷诱导下 × 中调节 RNA 的作用，我们构建了叶芽的 cDNA 和小 RNA 文库，这些叶芽在 -4°C 下处理 8 小时或不处理。

结果

通过高通量测序和差异表达分析，在 × 中鉴定出 61 个 miRNA 和 1229 个 DEGs 在冷诱导条件下，miR167a、miR1450、miR319a、miR395b、miR393a-5p、miR408-5p 和 miR168a-5p 下调，而 miR172a 的转录水平在冷处理下增加。还获得了 31 个相位-siRNA（reads≥4），其中一些来自 TAS3 基因座。差异表达基因（DEGs）分析表明，转录因子基因如 Cluster-15451.2（假定的 MYB）、Cluster-16493.29872（假定的 bZIP）、Cluster-16493.29175（假定的 SBP）和 Cluster-1378.1（假定的 ARF）在冷处理和未处理的 × 植物中差异表达。miRNA 和转录组的综合分析表明，miR319、miR159、miR167、miR395、miR390 和 miR172 及其靶基因，包括 MYB、SBP、bZIP、ARF、LHW 和 ATL，被预测参与 ARF 途径、SPL 途径、DnaJ 相关光系统 II 和 LRR 受体激酶，其中许多已知可抵抗冷胁迫。特别是，建立了一个包括 miRNA、phasiRNA 和它们的靶基因的复杂调控模型。

结论

miRNA 和转录组的综合分析揭示了 × 冷耐受性的复杂调控。miRNAs、phasiRNAs 和基因编码的转录因子在全基因组水平上得到了表征，它们的表达模式被证明是互补的。这项工作为进一步研究冷胁迫相关的 sRNAs 和调节因子通路奠定了基础。

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× 中 miRNA-mRNAs 网络参与耐寒性的全基因组分析

Genome-Wide Analysis of the miRNA-mRNAs Network Involved in Cold Tolerance in × .

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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