Edible mycelium as proliferation and differentiation support for anchorage-dependent animal cells in cultivated meat production

IF 6.3 1区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

NPJ Science of Food Pub Date : 2024-04-30 DOI:10.1038/s41538-024-00263-0

Minami Ogawa, Alex S. Kermani, Mayrene J. Huynh, Keith Baar, J. Kent Leach, David E. Block

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Abstract

Cultivated meat production requires bioprocess optimization to achieve cell densities that are multiple orders of magnitude higher compared to conventional cell culture techniques. These processes must maximize resource efficiency and cost-effectiveness by attaining high cell growth productivity per unit of medium. Microcarriers, or carriers, are compatible with large-scale bioreactor use, and offer a large surface-area-to-volume ratio for the adhesion and proliferation of anchorage-dependent animal cells. An ongoing challenge persists in the efficient retrieval of cells from the carriers, with conflicting reports on the effectiveness of trypsinization and the need for additional optimization measures such as carrier sieving. To surmount this issue, edible carriers have been proposed, offering the advantage of integration into the final food product while providing opportunities for texture, flavor, and nutritional incorporation. Recently, a proof of concept (POC) utilizing inactivated mycelium biomass derived from edible filamentous fungus demonstrated its potential as a support structure for myoblasts. However, this POC relied on a model mammalian cell line combination with a single mycelium species, limiting realistic applicability to cultivated meat production. This study aims to advance the POC. We found that the species of fungi composing the carriers impacts C2C12 myoblast cell attachment—with carriers derived from Aspergillus oryzae promoting the best proliferation. C2C12 myoblasts effectively differentiated on mycelium carriers when induced in myogenic differentiation media. Mycelium carriers also supported proliferation and differentiation of bovine satellite cells. These findings demonstrate the potential of edible mycelium carrier technology to be readily adapted in product development within the cultivated meat industry.

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可食用菌丝体在肉类栽培生产中为依赖锚定的动物细胞提供增殖和分化支持

与传统细胞培养技术相比，培养肉的生产需要优化生物工艺，以实现高出多个数量级的细胞密度。这些工艺必须通过实现每单位培养基的高细胞生长生产力，最大限度地提高资源效率和成本效益。微载体（或称载体）与大规模生物反应器的使用兼容，并为依赖锚定的动物细胞的粘附和增殖提供了较大的表面积与体积比。如何从载体中有效回收细胞一直是个难题，关于胰蛋白酶化的效果以及是否需要采取其他优化措施（如筛分载体）的报道相互矛盾。为了解决这个问题，人们提出了可食用载体，它具有与最终食品一体化的优势，同时还能提供质地、风味和营养成分。最近，一项利用从可食用丝状真菌中提取的灭活菌丝体生物质的概念验证（POC）证明了其作为肌细胞支撑结构的潜力。然而，该概念验证依赖于哺乳动物细胞系模型与单一菌丝种类的结合，限制了其在肉类培养生产中的实际应用。本研究旨在推进 POC 的发展。我们发现，构成载体的真菌种类会影响 C2C12 成肌细胞的附着--其中来自黑曲霉的载体能促进最好的增殖。在成肌分化培养基中诱导时，C2C12 成肌细胞能有效地在菌丝体载体上分化。菌丝体载体还支持牛卫星细胞的增殖和分化。这些研究结果表明，可食用菌丝体载体技术可随时用于肉类栽培业的产品开发。

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来源期刊

NPJ Science of Food FOOD SCIENCE & TECHNOLOGY-

CiteScore

7.50

自引率

1.60%

发文量

期刊介绍： npj Science of Food is an online-only and open access journal publishes high-quality, high-impact papers related to food safety, security, integrated production, processing and packaging, the changes and interactions of food components, and the influence on health and wellness properties of food. The journal will support fundamental studies that advance the science of food beyond the classic focus on processing, thereby addressing basic inquiries around food from the public and industry. It will also support research that might result in innovation of technologies and products that are public-friendly while promoting the United Nations sustainable development goals.