Growth and invertase production by Neurospora crassa in submerged and solid-state cultures

Q4 Biochemistry, Genetics and Molecular Biology

Mexican Journal of Biotechnology Pub Date : 2024-07-01 DOI:10.29267/mxjb.2024.9.3.20

Christian Jesús Mora-Pérez, Montserrat Citlali Sánchez-Ruiz, Daniel Salgado-Bautista, U. Carrasco-Navarro, E. Favela‐Torres

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引用次数: 0

Abstract

Filamentous fungi are widely used in industry to produce enzymes, organic acids, and secondary metabolites. Neurospora crassa has gained attention due to its flexibility for easy genetic manipulation, fast growth, and non-pathogenic characteristics. This study evaluated the growth of N. crassa and invertase production in submerged culture (SC) and solid-state culture (SSC) using pine sawdust (SSC-PS) and polyurethane foam (SSC-PUF) as supports. Modified Vogel's medium with initial sucrose concentrations of 1.5%, 3%, and 5% was used. The specific and maximum CO2 production rates were higher in SSC than SC, particularly with SSC-PS. Protein and invertase production were higher in SSC, with SSC-PS demonstrating the highest sucrose concentration as the inducer and carbon source. The water-holding capacity (WHC) of SSC-PUF was approximately 25 times higher than that of SSC-PS, facilitating a more productive process. SSC-PUF enables higher biomass growth, protein, and invertase production than SC. Moreover, using inert supports, such as PUF, allows the correct substrates and product assessment without interferences due to the chemical composition and heterogeneity of conventional agro-industrial by-products, such as PS.

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沉水和固态培养条件下十字花科黑孢子菌的生长和转化酶的产生

丝状真菌在工业中被广泛用于生产酶、有机酸和次级代谢产物。十字花科黑孢子菌（Neurospora crassa）因其易于遗传操作、生长速度快、无致病性等特点而备受关注。本研究以松树锯屑（SSC-PS）和聚氨酯泡沫（SSC-PUF）为支撑物，评估了 N. crassa 在浸没培养（SC）和固态培养（SSC）中的生长情况和转化酶产量。使用了初始蔗糖浓度为 1.5%、3% 和 5%的改良 Vogel 培养基。SSC 的特定和最大二氧化碳产生率均高于 SC，尤其是 SSC-PS。蛋白质和转化酶的产量在 SSC 中较高，SSC-PS 作为诱导剂和碳源的蔗糖浓度最高。SSC-PUF 的持水量（WHC）比 SSC-PS 高约 25 倍，有利于提高生产率。与 SC 相比，SSC-PUF 可实现更高的生物量增长、蛋白质和转化酶产量。此外，使用 PUF 等惰性支持物可以正确评估基质和产品，而不会受到 PS 等传统农用工业副产品的化学成分和异质性的干扰。

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来源期刊

Mexican Journal of Biotechnology Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

1.30

自引率

0.00%

发文量