Optimizing laboratory cultivation of wood-inhabiting fungi with emphasis on applied conservation

IF 4.3 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Applied Microbiology and Biotechnology Pub Date : 2025-09-30 DOI:10.1007/s00253-025-13603-1

Joette Crosier, Lorin von Longo-Liebenstein, Mattias Edman, Sylwia Adamczyk, Leena Hamberg

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引用次数: 0

Abstract

While fungi have been grown for centuries as food, cultivation knowledge rarely extends to rare fungi, usually confined to those with high biotechnology or food value. A more robust knowledge base on cultivating rare, challenging fungi may be critical for conservation, as many species face extinction. They should be cultivated for gene banks, reintroduction, and other conservation work. This study adapted mushroom growing techniques for seven threatened wood-inhabiting fungi, all red-listed in Finland and Sweden: Antrodia crassa, Antrodia infirma, Amylocystis lapponica, Skeletocutis stellae, Perenniporia tenuis, Radulodon erikssonii, and Haploporus odorus. We grew mycelium of these species (five strains each, two for P. tenuis) under various laboratory conditions. We tested wood dust supplementation (in agar), grain spawn substrate composition, gas exchange rates, two wood types (natural host and birch) on sawdust and dowel spawn, and temperature range (6.0–36.5 °C). We measured growth rate in all conditions and ergosterol (mycelial biomass indicator) in wood type and wood dust agar tests. We found wood dust–supplemented agar had an overall positive effect. Temperature effects varied by species, with some preferring relatively warm or cool temperatures, and some having a narrower growth range. Most species grew better on grain when vermiculite was added; gas exchange had no effect. Wood type had a variable effect, but birch was suitable in all cases, sometimes better than the natural host wood. Overall, our treatments had positive to neutral effects on mycelial growth of our fungal species.

• Optimized laboratory cultivation methods can benefit fungal conservation and other applied mycology efforts.

• Certain supplements for increasing media complexity or retaining substrate moisture lead to improved growth of challenging fungi.

• Optimal conditions vary by species and strain, but general guidelines may apply more broadly, and natural habitat conditions can offer a starting point.

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优化木质真菌的实验室培养，重点是应用保护。

虽然真菌作为食物已经种植了几个世纪，但栽培知识很少扩展到稀有真菌，通常仅限于那些具有高生物技术或食品价值的真菌。在培育稀有、具有挑战性的真菌方面，一个更强大的知识基础可能对保护至关重要，因为许多物种面临灭绝。它们应该被培育用于基因库、重新引入和其他保护工作。本研究对芬兰和瑞典列入红色名录的七种濒危木材真菌进行了蘑菇种植技术改造，这些真菌分别是：Antrodia crassa、Antrodia infirma、Amylocystis lapponica、Skeletocutis stellae、Perenniporia tenuis、Radulodon erikssonii和Haploporus odorus。我们在不同的实验室条件下培养了这些物种的菌丝体（每种5株，其中2株为P. tenuis）。我们测试了木屑添加量（琼脂）、颗粒产卵基质组成、气体交换率、木屑和木桩产卵上的两种木材类型（天然宿主和桦木）以及温度范围（6.0-36.5°C）。我们测量了在所有条件下的生长速率和麦角甾醇（菌丝生物量指标）在木材类型和木屑琼脂试验。我们发现木屑补充琼脂总体上有积极的影响。温度的影响因物种而异，有些喜欢相对温暖或凉爽的温度，有些生长范围较窄。添加蛭石后，大多数种属在籽粒上生长较好；气体交换没有效果。木材类型有不同的影响，但桦木在所有情况下都是合适的，有时比天然宿主木材更好。总的来说，我们的处理对真菌种类的菌丝生长有积极到中性的影响。•优化的实验室培养方法有利于真菌保护和其他应用真菌学工作。•某些增加培养基复杂性或保持基质水分的补充剂可改善挑战性真菌的生长。•最佳条件因物种和菌株而异，但一般准则可能适用范围更广，自然栖息地条件可以提供一个起点。

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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来源期刊

Applied Microbiology and Biotechnology 工程技术-生物工程与应用微生物

CiteScore

10.00

自引率

4.00%

发文量

535

审稿时长

2 months

期刊介绍： Applied Microbiology and Biotechnology focusses on prokaryotic or eukaryotic cells, relevant enzymes and proteins; applied genetics and molecular biotechnology; genomics and proteomics; applied microbial and cell physiology; environmental biotechnology; process and products and more. The journal welcomes full-length papers and mini-reviews of new and emerging products, processes and technologies.