Hoyos Laura V, Vasquez-Muñoz Luis E, Osorio Yuliana, Valencia-Revelo Daniela, Devia-Cometa Daiana, Große Miriam, Charria-Girón Esteban, Caicedo-Ortega Nelson H
Departamento de Ciencias Biológicas, Bioprocesos y Biotecnología. Facultad de Ingeniería, Diseño y Ciencias Aplicadas, Universidad Icesi, Cali, Colombia.
Department Microbial Drugs, Helmholtz Centre for Infection Research (HZI), German Centre for Infection Research (DZIF), Partner Site Hannover-Braunschweig, Inhoffenstrasse 7, 38124, Braunschweig, Germany.
Microb Cell Fact. 2024 Dec 5;23(1):328. doi: 10.1186/s12934-024-02567-y.
In the search for new antimicrobial secondary metabolites of fungi, optimizing culture conditions remains a critical challenge, as standard laboratory approaches often result in low yields. While non-selective methods, such as modifying culture media, have been effective in expanding the chemical diversity of fungal metabolites, they have not yet established a direct link to key process parameters crucial for further optimization. This study investigates the capacity of Diaporthe caliensis as a biofactory for biologically active secondary metabolites, employing tailored culture media to explore the relationship between chemical diversity and critical process variables.
The metabolomic profiles, antibacterial activities, and production yields of the extracts were analyzed to progressively adjust the culture conditions. This study was conducted in five steps, evaluating carbon and nitrogen source concentration, nitrogen source type, salt supplementation, and pH adjustment. Altering the rice starch concentration affected biomass yield per unit of oxygen consumed, while modifications to the nitrogen source concentration influenced both the bioactivity and chemical space by Diaporthe caliensis. Despite changes at the metabolome level, the extracts consistently exhibited potent antibacterial activities, influenced by the nitrogen source, added salts and pH adjustments. For instance, when using corn steep liquor and rice starch, supplemented with micronutrients, different metabolites were produced depending on whether buffer or water was used, though both conditions showed similar antibacterial activities (IC ≈ 0.10 mg mL against Staphylococcus aureus and ≈ 0.14 mg mL against Escherichia coli). In the treatment where buffer was used to stabilize pH change, there was an increase in the production of phomol-like compounds which are associated with known antibiotic properties. In contrast, in the treatments using water, the drop in pH stimulated the production of previously unidentified metabolites with potential antimicrobial activity.
This study proposes a strategic methodology for the tailored formulation of culture media aiming to promote the biosynthesis of diverse secondary metabolites. This approach revealed the critical role of nutrient limitation and pH regulation in stimulating the production of polyketide-lactone derivatives, including the antibiotic phomol. Ultimately, the systematic, custom-designed culture conditions developed in this work offer a promising strategy for expanding the chemical diversity of Diaporthe caliensis, while providing valuable insights into the key parameters needed for optimizing this fungal biofactory.
在寻找真菌新的抗菌次生代谢产物的过程中,优化培养条件仍然是一项严峻挑战,因为标准实验室方法往往产量较低。虽然非选择性方法,如改良培养基,在扩大真菌代谢产物的化学多样性方面很有效,但它们尚未与进一步优化所需的关键工艺参数建立直接联系。本研究调查了加利福尼亚间座壳作为生物活性次生代谢产物生物工厂的能力,采用定制培养基来探索化学多样性与关键工艺变量之间的关系。
分析提取物的代谢组学图谱、抗菌活性和产量,以逐步调整培养条件。本研究分五步进行,评估碳源和氮源浓度、氮源类型、盐补充和pH调节。改变大米淀粉浓度影响单位耗氧量的生物量产量,而氮源浓度的改变影响加利福尼亚间座壳的生物活性和化学空间。尽管代谢组水平发生了变化,但提取物始终表现出强大的抗菌活性,受氮源、添加盐和pH调节的影响。例如,当使用玉米浆和大米淀粉并补充微量营养素时,根据使用缓冲液还是水会产生不同的代谢产物,尽管两种条件下的抗菌活性相似(对金黄色葡萄球菌的IC约为0.10mg/mL,对大肠杆菌的IC约为0.14mg/mL)。在使用缓冲液稳定pH变化的处理中,与已知抗生素特性相关的类腐皮镰刀菌素化合物的产量增加。相比之下,在用水的处理中,pH下降刺激了具有潜在抗菌活性的先前未鉴定代谢产物的产生。
本研究提出了一种定制培养基配方的战略方法,旨在促进多种次生代谢产物的生物合成。这种方法揭示了营养限制和pH调节在刺激聚酮内酯衍生物(包括抗生素腐皮镰刀菌素)生产中的关键作用。最终,本研究中开发的系统、定制设计的培养条件为扩大加利福尼亚间座壳的化学多样性提供了一种有前景的策略,同时为优化这种真菌生物工厂所需的关键参数提供了有价值的见解。
