Understanding and controlling filamentous growth of fungal cell factories: novel tools and opportunities for targeted morphology engineering.

Q1 Agricultural and Biological Sciences Fungal Biology and Biotechnology Pub Date : 2021-08-23 DOI:10.1186/s40694-021-00115-6

Vera Meyer, Timothy Cairns, Lars Barthel, Rudibert King, Philipp Kunz, Stefan Schmideder, Henri Müller, Heiko Briesen, Anna Dinius, Rainer Krull

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引用次数: 24

Abstract

Filamentous fungal cell factories are efficient producers of platform chemicals, proteins, enzymes and natural products. Stirred-tank bioreactors up to a scale of several hundred m³ are commonly used for their cultivation. Fungal hyphae self-assemble into various cellular macromorphologies ranging from dispersed mycelia, loose clumps, to compact pellets. Development of these macromorphologies is so far unpredictable but strongly impacts productivities of fungal bioprocesses. Depending on the strain and the desired product, the morphological forms vary, but no strain- or product-related correlations currently exist to improve process understanding of fungal production systems. However, novel genomic, genetic, metabolic, imaging and modelling tools have recently been established that will provide fundamental new insights into filamentous fungal growth and how it is balanced with product formation. In this primer, these tools will be highlighted and their revolutionary impact on rational morphology engineering and bioprocess control will be discussed.

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理解和控制真菌细胞工厂的丝状生长:目标形态学工程的新工具和机会。

丝状真菌细胞工厂是平台化学品、蛋白质、酶和天然产物的高效生产者。通常使用几百m³规模的搅拌槽生物反应器进行培养。真菌菌丝自组装成各种细胞大形态，从分散的菌丝、松散的团块到致密的球团。这些宏观形态的发展到目前为止是不可预测的，但强烈影响真菌生物过程的生产力。根据菌株和所需产品的不同，形态形式各不相同，但目前没有菌株或产品相关的相关性，以提高对真菌生产系统的过程理解。然而，最近建立了新的基因组学、遗传学、代谢、成像和建模工具，这些工具将为丝状真菌生长及其如何与产物形成平衡提供基本的新见解。在本入门中，这些工具将重点介绍，并讨论它们对理性形态学工程和生物过程控制的革命性影响。

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