秀珍菇不同生长阶段在低温刺激后的转录组及差异基因表达分析

doi:10.3969/j.issn.1674-7968.2020.10.012

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5723 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要秀珍菇(Pleurotus pulmonarius)属于变温结实菇种,低温刺激可诱导其子实体形成。为了探究秀珍菇结实的分子机制,本实验采用Illumina测序技术,对发菌完好的秀珍菇菌包的菌丝体常温培养阶段、低温诱导阶段、低温诱导后恢复至常温阶段、原基形成阶段4个不同生长发育阶段进行了全转录组测序,构建了4个样本的cDNA文库,并检测文库质量;利用Trinity软件拼接得到的转录组作为参考序列将4个样本的clean reads与之进行比对(mapping);最后对获得的有效序列进行功能注释及相关生物信息学分析。在4个不同生长阶段分别得到41 544 496、45 722 382、46 642 306和49 980 456个高质量测序标签。将所有高质量测序标签与参考序列进行比对定位,可以唯一定位到参考序列上的高质量标签数分别占总数的83.22%、82.85%、83.10%和82.59%。基因差异表达分析显示,与常温状态下相比,低温处理后秀珍菇菌丝体中上调表达基因个数为1 216个,下调表达基因的个数为1 046个;同时,与低温诱导后恢复至常温相比,原基形成阶段秀珍菇上调表达基因个数为1 331个,下调表达基因的个数为1 784个。经过Blast-Nr比对发现,经过低温诱导后,秀珍菇表达量上升的基因主要与烷基转移、天冬氨酸内肽酶活性、氧化还原、细胞壁形成和跨膜运输等相关;原基形成过程中,秀珍菇表达量上升的基因主要与转录调节、核糖体合成、甲基化和离子通道相关。GO (Go Ontology)富集分析表明,在常温处理与低温诱导后两个阶段与催化活性、单一生物体代谢过程和氧化还原酶活性等相关的GO 条目(term)中差异表达基因富集明显;在低温诱导后恢复至常温与原基形成两个阶段,催化活性、单组织过程及单组织代谢过程等GO term中差异表达基因富集明显。KEGG 通路(pathway)功能富集分析表明,TCA循环、内质网蛋白加工2条代谢通路中差异基因富集明显。通过对常温与低温诱导处理的菌丝体、低温诱导后恢复至常温的菌丝体与原基2对不同生长发育阶段转录组的比较研究,分别筛选出差异表达的基因2 262个和3 115个。qRT-PCR分析表明,所选基因在不同阶段的表达变化与转录组测序结果一致。本研究为进一步挖掘秀珍菇原基形成和子实体生长的关键基因奠定基础,也为应用基因工程培育优质、高产的秀珍菇新品种提供指导。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	王伟科
	陆娜
	闫静
	宋吉玲
	袁卫东
	周祖法

关键词 ：秀珍菇, 低温, 菌丝体, 原基, 差异表达基因

Abstract：Pleurotus pulmonarius has the characteristics of changing temperature and fruiting. Low temperature stimulation can induce the formation of fruiting body. Using Illumina sequencing technology, the complete transcriptome including four different stages of growth and development: Mycelial culture at normal temperature stage, low temperature induction stage, recovery to normal temperature stage after low temperature induction and primordium formation stage of Pleurotus pulmonarius were sequenced. There were 41 544 496, 45 722 382, 46 642 306 and 49 980 456 clean reads obtained at four different growth stages respectively. The clean reads of four different stages samples transcriptome sequencing were aligned to the reference sequences which were spliced by Trinity software. The alignmengt rate of the four sequencing samples was 83.22%, 82.85%, 83.10% and 82.59%, respectively. Analysis of differentially expressed genes showed that there were 1 216 genes up-regulated while 1 046 of them were down-regulated expressed between two libraries with normal and low-temperature induction. Meanwhile, 1 331 of genes were up-regulated while 1 784 of them were down-regulated in the primordium library compared with library of mycelium induced by low-temperature. Functional annotation with Blast-Nr database indicated that these up-regulated genes in mycelium induced by low-temperature were involved in transferring alkyl, aspartic-type endopeptidase activity, oxidation-reduction process, cell wall integrity and intracellular protein transport. And in primordium, these up-regulated genes were involved in regulation of transcription, ribosome synthetize, methelation and ion channel. Gene Ontology functional enrichment analysis showed that the differentially expressed genes involved in catalytic activity, single organism metabolic process and oxidoreductase activity were significantly enriched at two stages of normal temperature treatment and low temperature induction, while at the stages of recovery to normal temperature stage after low temperature induction and primordium formation catalytic activity, single tissue process and single tissue metabolism process were significantly enriched. KEGG metabolic pathway analysis showed that there were significant differences in gene enrichment in two metabolic pathways: TCA cycle and endoplasmic reticulum protein processing. Through the comparative study of transcriptome in different stages of growth and development, 2 262 and 3 115 differentially expressed genes were screened out. qRT-PCR analysis showed that the expression changes of the selected genes at different stages were consistent with the results of transcriptome sequencing. This study lays the foundation for further excavation of the key genes of primordium formation and fruiting body growth of Pleurotus pulmonarius, and also provides guidance for the application of genetic engineering to cultivate new high-quality and high-yield Pleurotus pulmonarius varieties.

Key words： Pleurotus pulmonarius Low-temperature Mycelium Primordium Differentially expressed gene

收稿日期: 2019-11-04

ZTFLH:	S646
	Q78

基金资助:浙江省农业(食用菌)新品种选育重大科技专项(2016C02057)

通讯作者: * akeok@126.com

引用本文:

王伟科, 陆娜, 闫静, 宋吉玲, 袁卫东, 周祖法. 秀珍菇不同生长阶段在低温刺激后的转录组及差异基因表达分析[J]. 农业生物技术学报, 2020, 28(10): 1837-1848.
WANG Wei-Ke, LU Na, YAN Jing, SONG Ji-Ling, YUAN Wei-Dong, ZHOU Zu-Fa. Analyses of Transcriptome and Differentially Expressed Genes at Different Developmental Stages of Pleurotus pulmonarius Treated with Low Temperature. 农业生物技术学报, 2020, 28(10): 1837-1848.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2020.10.012 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2020/V28/I10/1837

[1] 陈辉, 郝海波, 赵静, 等. 2020. 漆酶同工酶基因在斑玉蕈生长发育过程中的表达分析[J]. 菌物学报, 39(5): 1-11.
(Chen H, Hao H B, Zhao J, et al.2020. Expression analysis of laccase isozyme gene during Hypsizygus marmoreus growth and development[J]. Mycosystema, 39(5): 1-11.)
[2] 陈美元. 2012. 双孢蘑菇子实体原基与菇蕾蛋白质表达变化分析[J]. 食用菌学报, (03): 15-20.
(Chen M Y. 2012. Differential expression of proteins during the primordium and button stages of Agaricus bispous As2796[J]. Acta Edulis Fungi, (03): 15-20.)
[3] 陈美元, 廖剑华, 李洪荣, 等. 2015. 双孢蘑菇子实体发育不同阶段蛋白质组分析[J]. 菌物学报, 34(06): 1153-1164.
(Chen M Y, Liao J H, Li H R,et al.2015. Developmental proteomics analysis of the button mushroom Agaricus bisporus[J]. Mycosystema, 34(06): 1153-1164. )
[4] 崔波, 王洁琼, 宋彩霞, 等. 2016. 蝴蝶兰SOC1基因的克隆及表达分析[J], 分子植物育种, 14(3): 548-553.
(Cui B, Wang J Q, Song C X, et al.2016. Cloning and expression analysis of SOC1 gene from Phalaenopsis[J]. Molecular Plant Breeding, 14(3): 548-553.)
[5] 黄云柳. 2015. 人工冷刺激对桑枝屑栽培秀珍菇产量影响[J]. 食用菌, (1): 42-43.
(Huang Y L. 2015. Effect of artificial cold stimulation on the yield of Pleurotus pulmonarius[J]. Edible Fungi, (1): 42-43.)
[6] 贾昌路, 张瑶, 朱玲, 等. 2015. 转录组测序技术在生物测序中的应用研究进展[J]. 分子植物育种,13(10): 2388-2394.
(Jia C L, Zhang Y, Zhu L, et al.2015. Application progress of transcriptome sequencing technology in biological sequencing[J]. Molecular Plant Breeding, 13(10): 2388-2394.)
[7] 李琼洁. 2016. 冷诱导金针菇原基形成的相关基因研究[D]. 硕士学位论文, 华南农业大学, 导师: 郭丽琼, pp. 1-67.
(Li Q J.2016. Genes involves in cold induced the formation of primordia of Flammulia velutipes[D]. Thesis for M. S., South China Agricultural University, Supervisor: Guo L Q, pp. 1-67.)
[8] 刘芳, 王威, 谢宝贵. 2014. 金针菇菌丝与原基差异表达基因分析[J]. 食用菌学报, (1): 1-7.
(Liu F, Wang W, Xie B G. 2014. Comparison of gene expression patterns in the mycelium and primordia of Flammulina velutipes[J]. Acta Edulis Fungi, (1): 1-7.)
[9] 罗润. 2016. 金针菇子实体发育相关基因的功能研究[D]. 硕士学位论文,华南农业大学, 导师: 郭丽琼, pp. 3-64.
(Luo R.2016. Function identification of the Flammulina velutipes fruiting body development genes[D]. Thesis for M. S., South China Agricultural University, Supervisor: Guo L Q, pp. 3-64.)
[10] 沈颖越, 顾敏, 蔡为明, 等. 2014. 秀珍菇子实体发育相关消减杂交cDNA文库的构建与分析[J]. 浙江农业学报, 26(2): 330-334.
(Shen Y Y, Gu M, Cai W M, et al.2014. Construction and analysis of a suppressive subtractive hybridisation cDNA library related to fruiting body formation of Pleurotus pulmonarius after cold stimulation[J]. Acta Agriculturae Zhejiangensis, 26(2): 330-334.)
[11] 孙玉军, 江昌俊, 任四海. 2017. 秀珍菇多糖对D-半乳糖致衰老小鼠的保护作用[J]. 食品科学, 38(5): 251-256.
(Sun Y J, Jiang C J, Ren S H.2017. Protective effect of polysaccharides from the fruiting body of Pleurotus geesteranus against D-galactose-induced aging mice[J]. Food Science, 38(5): 251-256.)
[12] 解凡, 宋燕娇, 程冰, 等. 2019. 低温胁迫诱导肺形侧耳合成麦角甾醇的通路分析[J]. 菌物学报, 38(12): 2221-2231.
(Xie F, Song Y J, Cheng B, et al.2019. Transcriptome analyses of Pleurotus pulmonarius after cold stress challenge[J]. Mycosystema, 38(12): 2221-2231.)
[13] 闫述模, 袁媛, 杨滨, 等. 2016. 一种适用于不同发育期山楂果实总RNA提取的方法[J]. 中国实验方剂学杂志, (14): 39-43.
(Yan S M, Yuan Y, Yang B, et al.2016. Good method for isolating total RNA from Crataegi fructus at different developmental stages[J]. Chinese Journal of Experimental Traditional Medical Formulae, 22(14): 39-43.)
[14] 查磊, 赵瑞华, 余昌霞, 等. 2017. 蛋白质组学及其在食用菌中的研究进展[J]. 分子植物育种, (7): 2656-2661.
(Zha L, Zhao R H, Yu C X, et al. 2017. Proteomics and its advance in edible fungi[J]. Molecular Plant Breeding, (7): 2656-2661.)
[15] 张金霞, 黄晨阳, 郑素月. 2004. 平菇新品种--秀珍菇的特征特性[J]. 中国食用菌, 24(4): 25-26.
(Zhang J X, Huang C Y, Zheng S Y.2004. New varieties of Pleurotus ostreatus--Characteristics of “Xiuzhen mushroom”[J]. Edible Fungi of China, 24(4): 25-26.)
[16] 张盈, 夏琳, 逄文强, 等. 2011. 腺苷酸激酶与AMP信号在感知及维持机体能量中的作用[J]. 生命科学, 23(5):434-438.
(Zhang Y, Xia L, Pang W Q, et al.2011. The function of AK and AMP signaling in body energy sensing and balance[J]. Chinese Bulletin of Life Sciences, 23(5): 434-438.)
[17] 周烁红, 沈颖越, 蔡为明, 等. 2016. 肺形侧耳变温结实相关基因Ppcsl-1的克隆及功能预测[J]. 菌物学报, 35(8): 946-955.
(Zhou S H, Shen Y Y, Cai W M, et al.2016. Cloning and functional prediction of the Ppcsl-1 related to change-temperature fruiting of Pleurotus pulmonarius[J]. Mycosystema, 35(8): 946-955.)
[18] Clemens M J.2004. Targets and mechanisms for the regulation of translation in malignant transformation[J]. Oncogene, 23: 3180-3188.
[19] Huang J, Wang M M, Jiang Y, et al.2008. Expression analysis of rice A20/AN1-type zinc finger genes and characterization of ZFP177 that contributes to temperature stress tolerance[J]. Gene, 420(2): 135-144.
[20] Stoneley M, Willis A E.2003. Aberrant regulation of translation initiation in tumorigenesis[J]. Current Moecularl Medicine, 3(7): 597-603.
[21] Zhang X, Guo X, Lei C, et al.2011. Overexpression of SlCZFP1, a novel TFIIIA - type zinc finger protein from tomato, confers enhanced cold tolerance in transgenic Arabidopsis and rice[J]. Plant Molecular Biology Reporter, 29(1): 185-196.