Multiomics Provides a New Understanding of the Effect of Temperature Change on the Fermentation Quality of <i>Ophiocordyceps sinensis</i>

Multiomics Provides a New Understanding of the Effect of Temperature Change on the Fermentation Quality of <i>Ophiocordyceps sinensis</i>

<i>Ophiocordyceps sinensis</i> is a medicinal fungus with significant nutritional and utilization value. Temperature is a crucial factor influencing its growth, as temperature changes can impact enzyme activity, metabolite content, and gene expression during fungal cultivation. Currently...

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Bibliographic Details
Main Authors: Zhengfei Cao, Tao Wang, Hui He, Yuling Li, Xiuzhang Li
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Journal of Fungi
Subjects:
temperature stress
metabolite
antioxidant activity
metabolome
transcriptome
Online Access:https://www.mdpi.com/2309-608X/11/6/403
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Summary:<i>Ophiocordyceps sinensis</i> is a medicinal fungus with significant nutritional and utilization value. Temperature is a crucial factor influencing its growth, as temperature changes can impact enzyme activity, metabolite content, and gene expression during fungal cultivation. Currently, there are limited reports on the effects of temperature on the quality of fungal fermentation. This study focuses on <i>O. sinensis</i> and conducts temperature stress culture experiments. The results indicate that the optimal culture temperature range is between 18 and 23 °C, with extreme temperatures negatively affecting the morphology, growth rate, sporulation, and antioxidant systems of the strains. Further metabolomic and transcriptomic analyses revealed that differentially expressed genes (DEGs) and differentially accumulated metabolites (DAMs) were primarily enriched in four metabolic pathways: linoleic acid metabolism, arginine and proline metabolism, and lysine degradation. Many significantly enriched metabolites across various pathways appear to be predominantly regulated by ribosomal and RNA polymerase genes. Furthermore, we cultured <i>O. sinensis</i> mycelium at various temperatures and observed that a significant number of genes and metabolites associated with apoptosis and senescence were expressed at 28 °C. This led to cell damage, excessive energy consumption, and ultimately inhibited mycelial growth. In summary, this study elucidates the response mechanisms of <i>O. sinensis</i> to key metabolic pathways under different temperature growth conditions and explores factors contributing to strain degradation.
ISSN:2309-608X

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