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低温、机械损伤和外源水杨酸(SA)能刺激SA信号分子及其下游途径以及[此处原文不完整,推测是某个物种中]子实体的形成。

Low temperature, mechanical wound, and exogenous salicylic acid (SA) can stimulate the SA signaling molecule as well as its downstream pathway and the formation of fruiting bodies in .

作者信息

Li Ziyan, Wen Jin, Jing Zhuohan, Li Hui, Huang Jiahua, Yuan Chengjin, Xian Lijun, Gao Lingling, Zhu Jian, Xie Baogui, Tao Yongxin

机构信息

College of Horticulture, Fujian Agriculture and Forestry University, Fuzhou, Fujian, China.

Mycological Research Center, Fujian Agriculture and Forestry University, Fuzhou, Fujian, China.

出版信息

Front Microbiol. 2023 Aug 22;14:1197498. doi: 10.3389/fmicb.2023.1197498. eCollection 2023.

DOI:10.3389/fmicb.2023.1197498
PMID:37675426
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10477995/
Abstract

Low temperature (LT) and mechanical wound (MW), as two common physics methods, have been empirically used in production to stimulate the primordia formation of , which is typically produced using the industrial production mode. However, the detailed effect on the fruiting body formation and important endogenous hormones and signaling pathways in this process is poorly understood. In this study, LT, MW, their combination, i.e., MW + LT, and low concentration of SA (0.1 mM SA) treatments were applied to the physiologically mature mycelia of . The results showed that the primordia under the four treatments began to appear on the 5th-6th days compared with the 12th day in the control (no treatment). The MW + LT treatment produced the largest number of primordia (1,859 per bottle), followed by MW (757), SA (141), and LT (22), compared with 47 per bottle in the control. The HPLC results showed that the average contents of endogenous SA were significantly increased by 1.3 to 2.6 times under four treatments. A total of 11 SA signaling genes were identified in the genome, including 4 genes (), 5 genes (), and 2 genes (). with complete conserved domains (ANK and BTB/POZ) showed significantly upregulated expression under all four above treatments, while with one domain showed significantly upregulated response expression under the partial treatment of all four treatments. and showed 1.6-fold to 8.5-fold significant upregulation with varying degrees in response to four treatments. The results suggested that there was a correlation between "low temperature/mechanical wound-SA signal-fruiting body formation", and it will help researchers to understand the role of SA hormone and SA signaling pathway genes in the formation of fruiting bodies in fungi.

摘要

低温(LT)和机械损伤(MW)作为两种常见的物理方法,已在生产中凭经验用于刺激原基形成,原基通常采用工业生产模式产生。然而,在此过程中对子实体形成以及重要的内源激素和信号通路的具体影响尚不清楚。在本研究中,将低温、机械损伤、它们的组合即机械损伤 + 低温以及低浓度水杨酸(0.1 mM SA)处理应用于生理成熟的[具体真菌名称未给出]菌丝体。结果表明,与未处理的对照在第12天出现原基相比,四种处理下的原基在第5 - 6天开始出现。与对照每瓶47个相比,机械损伤 + 低温处理产生的原基数量最多(每瓶1859个),其次是机械损伤(757个)、水杨酸(141个)和低温(22个)。高效液相色谱结果表明,四种处理下内源水杨酸的平均含量显著增加了1.3至2.6倍。在[具体真菌名称未给出]基因组中总共鉴定出11个水杨酸信号基因,包括4个[具体基因类型1未给出]基因、5个[具体基因类型2未给出]基因和2个[具体基因类型3未给出]基因。具有完整保守结构域(ANK和BTB/POZ)的[具体基因名称1未给出]在上述所有四种处理下均表现出显著上调表达,而具有一个结构域的[具体基因名称2未给出]在所有四种处理的部分处理下表现出显著上调的响应表达。[具体基因名称3未给出]和[具体基因名称4未给出]在响应四种处理时表现出1.6倍至8.5倍的不同程度的显著上调。结果表明“低温/机械损伤 - 水杨酸信号 - 子实体形成”之间存在相关性,这将有助于研究人员了解水杨酸激素和水杨酸信号通路基因在真菌子实体形成中的作用。

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