First report on the regulation and function of carbon metabolism during large sclerotia formation in medicinal fungus Wolfiporia cocos

IF 2.4 3区 生物学 Q3 GENETICS & HEREDITY Fungal Genetics and Biology Pub Date : 2023-05-01 DOI:10.1016/j.fgb.2023.103793
Cong Zhang, Lianfu Chen, Mengting Chen, Zhangyi Xu
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引用次数: 1

Abstract

The medicinal fungus Wolfiporia cocos colonizes and then grows on the wood of Pinus species, and utilizes a variety of Carbohydrate Active Enzymes (CAZymes) to degrades wood for the development of large sclerotia that is mostly built up of beta-glucans. Some differentially expressed CAZymes were revealed by comparisons between the mycelia cultured on potato dextrose agar (PDA) and sclerotia formed on pine logs in previous studies. Here, different profile of expressed CAZymes were revealed by comparisons between the mycelia colonization on pine logs (Myc.) and sclerotia (Scl.b). To further explore the regulation and function of carbon metabolism in the conversion of carbohydrates from Pine species by W. cocos, the transcript profile of core carbon metabolism was firstly analyzed, and it was characterized by the up-regulated expression of genes in the glycolysis pathway (EMP) and pentose phosphate pathway (PPP) in Scl.b, as well as high expression of genes in the tricarboxylic acid cycle (TCA) in both Myc. and Scl.b stages. The conversion between glucose and glycogen and between glucose and β-glucan was firstly identified as the main carbon flow in the differentiation process of W. cocos sclerotia, with a gradual increase in the content of β-glucan, trehalose and polysaccharide during this process. Additionally, gene functional analysis revealed that the two key genes (PGM and UGP1) may mediate the formation and development of W. cocos sclerotia possibly by regulating β-glucan synthesis and hyphal branching. This study has shed light on the regulation and function of carbon metabolism during large W. cocos sclerotium formation and may facilitate its commercial production.

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药用真菌cocos Wolfiporia cocos大菌核形成过程中碳代谢的调控及功能首次报道
药用真菌Wolfiporia cocos在松树物种的木材上定植并生长,并利用各种碳水化合物活性酶(CAZymes)降解木材,形成主要由β-葡聚糖组成的大菌核。通过比较在马铃薯葡萄糖琼脂(PDA)上培养的菌丝体和在松木原木上形成的菌核,揭示了一些差异表达的CAZymes。通过比较菌丝在松原木(Myc.)和菌核(Scl.b)上的定殖,揭示了表达的CAZymes的不同图谱,其特征是Scl.b中糖酵解途径(EMP)和磷酸戊糖途径(PPP)中的基因表达上调,以及两种Myc中三羧酸循环(TCA)中的高表达。和Scl.b阶段。首次确定葡萄糖与糖原之间以及葡萄糖与β-葡聚糖之间的转化是茯苓菌核分化过程中的主要碳流,在此过程中β-葡聚糖、海藻糖和多糖的含量逐渐增加。此外,基因功能分析表明,两个关键基因(PGM和UGP1)可能通过调节β-葡聚糖的合成和菌丝分支来介导茯苓菌核的形成和发育。本研究揭示了大型椰子菌核形成过程中碳代谢的调节和功能,有助于其商业化生产。
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来源期刊
Fungal Genetics and Biology
Fungal Genetics and Biology 生物-遗传学
CiteScore
6.20
自引率
3.30%
发文量
66
审稿时长
85 days
期刊介绍: Fungal Genetics and Biology, formerly known as Experimental Mycology, publishes experimental investigations of fungi and their traditional allies that relate structure and function to growth, reproduction, morphogenesis, and differentiation. This journal especially welcomes studies of gene organization and expression and of developmental processes at the cellular, subcellular, and molecular levels. The journal also includes suitable experimental inquiries into fungal cytology, biochemistry, physiology, genetics, and phylogeny. Fungal Genetics and Biology publishes basic research conducted by mycologists, cell biologists, biochemists, geneticists, and molecular biologists. Research Areas include: • Biochemistry • Cytology • Developmental biology • Evolutionary biology • Genetics • Molecular biology • Phylogeny • Physiology.
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