Lignin degradation by co-cultured fungi: current status and future perspectives

Q4 Agricultural and Biological Sciences

Lilloa Pub Date : 2022-10-20 DOI:10.30550/j.lil/2022.59.s/2022.08.10

Jullio Kennedy Castro Soares, Vera Maria Valle Vitali, Marcelo Afonso Vallim

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Abstract

The lignocellulosic biomass is a highly abundant and renewable resource. However, its exploitation is limited by the recalcitrance of the lignin present in the plant cellwall. In the last three decades, fungal co-cultures have increasingly been applied to overcome lignin recalcitrance by enhancing the production of ligninolytic enzymes through microbial interactions. In this paper, we systematically compile studies on fungal co-cultures used in the degradation of lignin-containing substrates to clarify the advantages and limitations of this type of culture. Based on their different delignification rate potentials, co-cultures can be classified into synergistic, antagonistic, and neutral. Co-cultivation results are generally related to the balance or imbalance of antagonistic and synergistic effects arising from the specific compatibility between the species during the interaction. It is well known that the paired species and the microenvironmental system conditions are responsible for the reported degradations,however, the mechanisms underlying these interactions remain poorly understood. In conclusion, literature results demonstrate the promising application of fungalco-cultures in biotechnological sectors to improve the degradation of lignin and its derivatives, through their better understanding of the efficient exploitation ofbiological resources on ecological and industrial scales.

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共培养真菌降解木质素:现状与未来展望

木质纤维素生物质是一种高度丰富的可再生资源。然而，它的开发受到植物细胞壁中存在的木质素的难降解性的限制。在过去的三十年里，真菌共培养物越来越多地被应用于通过微生物相互作用增强木质素分解酶的产生来克服木质素的难降解性。在本文中，我们系统地汇编了用于降解含木质素底物的真菌共培养物的研究，以阐明这种培养物的优势和局限性。根据其不同的脱木素速率潜力，共培养物可分为协同、拮抗和中性。共育结果通常与相互作用过程中物种之间的特定兼容性所产生的拮抗和协同效应的平衡或不平衡有关。众所周知，配对物种和微环境系统条件是报道降解的原因，然而，对这些相互作用的机制仍知之甚少。总之，文献结果表明，真菌培养物在生物技术领域有很好的应用前景，通过更好地理解生态和工业规模上生物资源的有效开发，可以改善木质素及其衍生物的降解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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