Ruiz-Muñoz Marina, Ontañón Ignacio, Cobos Rebeca, Calvo-Peña Carla, Otero-Suárez Rebeca, Ferreira Vicente, Roselló Jordi, Coque Juan José R
Instituto de Investigación de La Viña y El Vino, Escuela de Ingeniería Agraria, Universidad de León, Avenida de Portugal, 41, León, 24009, Spain.
Laboratorio de Análisis del Aroma y Enología, Facultad de Ciencias, Química Analítica, Instituto Agroalimentario de Aragón-IA2 (Universidad de Zaragoza-CITA), Zaragoza, 50009, Spain.
Microbiome. 2025 Jan 11;13(1):6. doi: 10.1186/s40168-024-02003-8.
The main application of cork is the production of stoppers for wine bottles. Cork sometimes contains 2,4,6-trichloroanisole, a compound that, at a concentration of ng/L, produces an unpleasant musty odor that destroys the organoleptic properties of wine and results in enormous economic losses for wineries and cork industries. Cork can exhibit a defect known as yellow stain, which is associated with high levels of 2,4,6-trichloroanisole. We describe how the microbiota of cork and yellow stain define a novel mechanism that explains the formation of chlorophenols and chloroanisoles (including 2,4,6-trichloroanisole) from p-hydroxybenzoate produced during lignin and/or suberin breakdown.
Electron microscopy revealed that cork affected by yellow stain exhibited significant structural degradation. This deterioration was attributed to the presence of higher microbial populations compared to those found in standard cork. Cork microbiota is rich in filamentous fungi able to metabolize lignin. A metataxonomic analysis confirmed that yellow stain contained significantly greater populations of fungal species belonging to Absidia, Geomyces, Mortierella, Mucor, Penicillium, Pseudogymnoascus, Talaromyces, and Umbelopsis. It also contained significantly greater amounts of bacteria belonging to Enterobacterales, Streptosporangiales, Tepidisphaerales, Pseudomonas, and several members of Burkholderiaceae, particularly species of the Burkholderia-Caballeronia-Paraburkholderia group. The extraction of aromatic compounds from cork samples allowed the identification of several compounds typically observed following lignin depolymerization. Notably, p-hydroxybenzoic acid and phenol were detected. Two strains of the genus Streptomyces isolated from yellow stain were able to biotransform p-hydroxybenzoate into phenol in resting cell assays. Phenol could be efficiently chlorinated in vitro to produce 2,4,6-trichlorophenol by a fungal chloroperoxidase, an enzymatic activity commonly found in filamentous fungi isolated from cork. Finally, as has been widely demonstrated before, 2,4,6-trichlorophenol can be efficiently O-methylated to 2,4,6-trichloroanisole by many of fungi that inhabit cork.
Chlorophenols and chloroanisoles can be produced de novo in cork from p-hydroxybenzoate generated by the microbial biodegradation of lignin and/or suberin through the participation of different types of microorganisms present in cork. The natural origin of these compounds, which are of great interest for the chlorine cycle and represent a new source of environmental contamination that differs from that caused by human activity, is described. Video Abstract.
软木塞的主要用途是生产葡萄酒瓶塞。软木塞有时含有2,4,6 - 三氯苯甲醚,该化合物在纳克/升的浓度下会产生令人不悦的霉味,破坏葡萄酒的感官特性,给葡萄酒厂和软木塞行业带来巨大经济损失。软木塞可能会出现一种称为黄斑的缺陷,这与高含量的2,4,6 - 三氯苯甲醚有关。我们描述了软木塞和黄斑中的微生物群如何定义一种新机制,该机制解释了木质素和/或栓质分解过程中产生的对羟基苯甲酸形成氯酚和氯苯甲醚(包括2,4,6 - 三氯苯甲醚)的过程。
电子显微镜显示,受黄斑影响的软木塞表现出明显的结构降解。这种降解归因于与标准软木塞相比存在更多的微生物种群。软木塞微生物群富含能够代谢木质素的丝状真菌。宏分类学分析证实,黄斑中属于犁头霉属、土生曲霉属、被孢霉属、毛霉属、青霉属、假裸囊菌属、帚霉属和伞状霉属的真菌种群显著更多。它还含有大量属于肠杆菌目、链孢囊菌目、暖球形菌目、假单胞菌属以及伯克霍尔德菌科的几个成员,特别是伯克霍尔德菌 - 卡瓦列罗尼亚菌 - 副伯克霍尔德菌属的细菌。从软木塞样品中提取芳香化合物后,鉴定出了几种木质素解聚后通常会观察到的化合物。值得注意的是,检测到了对羟基苯甲酸和苯酚。从黄斑中分离出的两株链霉菌菌株在静息细胞试验中能够将对羟基苯甲酸生物转化为苯酚。苯酚可以在体外被一种真菌氯过氧化物酶有效地氯化生成2,4,6 - 三氯苯酚,这种酶活性在从软木塞中分离出的丝状真菌中普遍存在。最后,正如之前广泛证明的那样,许多栖息在软木塞中的真菌可以将2,4,6 - 三氯苯酚有效地O - 甲基化生成2,4,6 - 三氯苯甲醚。
氯酚和氯苯甲醚可以在软木塞中由木质素和/或栓质微生物降解产生的对羟基苯甲酸通过软木塞中存在的不同类型微生物的参与而从头合成。描述了这些化合物的天然来源,它们对氯循环具有重要意义,并且代表了一种不同于人类活动造成的新的环境污染源。视频摘要。
