Morphology and Rheology in Filamentous Cultivations

Overview

Journal Adv Appl Microbiol

Specialty Microbiology

Date 2010 Jul 7

PMID 20602989

Citations 28

Authors

T Wucherpfennig

K A Kiep

H Driouch

C Wittmann

R Krull

Affiliations

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Abstract

Because of their metabolic diversity, high production capacity, secretion efficiency, and capability of carrying out posttranslational modifications, filamentous fungi are widely exploited as efficient cell factories in the production of metabolites, bioactive substances, and native or heterologous proteins, respectively. There is, however, a complex relationship between the morphology of these microorganisms, transport phenomena, the viscosity of the cultivation broth, and related productivity. The morphological characteristics vary between freely dispersed mycelia and distinct pellets of aggregated biomass, every growth form having a distinct influence on broth rheology. Hence, the advantages and disadvantages for mycelial or pellet cultivation have to be balanced out carefully. Because of the still inadequate understanding of the morphogenesis of filamentous microorganisms, fungal morphology is often a bottleneck of productivity in industrial production. To obtain an optimized production process, it is of great importance to gain a better understanding of the molecular and cell biology of these microorganisms as well as the relevant approaches in biochemical engineering. In this chapter, morphology and growth of filamentous fungi are described, with special attention given to specific problems as they arise from fungal growth forms; growth and mass transfer in fungal biopellets are discussed as an example. To emphasize the importance of the flow behavior of filamentous cultivation broths, an introduction to rheology is also given, reviewing important rheological models and recent studies concerning rheological parameters. Furthermore, current knowledge on morphology and productivity in relation to the environom is outlined in the last section of this review.

Citing Articles

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Highly parallel bending tests for fungal hyphae enabled by two-photon polymerization of microfluidic mold.

Brinkmann S, Schrader M, Meinen S, Kampen I, Kwade A, Dietzel A Front Bioeng Biotechnol. 2024; 12:1449167.

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Validation of computational fluid dynamics of shake flask experiments at moderate viscosity by liquid distributions and volumetric power inputs.

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Recent Advances in Chitin Biosynthesis Associated with the Morphology and Secondary Metabolite Synthesis of Filamentous Fungi in Submerged Fermentation.

Gong Z, Zhang S, Liu J J Fungi (Basel). 2023; 9(2).

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Co-cultivation of filamentous microorganisms in the presence of aluminum oxide microparticles.

Boruta T, Antecka A Appl Microbiol Biotechnol. 2022; 106(17):5459-5477.

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