State Key Laboratory for Conservation and Utilization of Bio-Resources in Yunnan, Yunnan University, Kunming, Yunnan, China.
College of Life Science, Yunnan University, Kunming, Yunnan, China.
Microbiol Spectr. 2024 Jun 4;12(6):e0039024. doi: 10.1128/spectrum.00390-24. Epub 2024 May 10.
is a ubiquitous soil-borne fungus capable of causing diseases in a variety of plants and occasionally in humans. While populations of from infected plants have received significant attention, relatively little is known about its soil populations, including its population genetic structure and antifungal susceptibilities. In addition, over the last two decades, greenhouses have become increasingly important for food and ornamental plant production throughout the world, but how greenhouses might impact microbial pathogens such as populations remains largely unknown. Different from open crop fields, greenhouses are often more intensively cultivated, with each greenhouse being a relatively small and isolated space where temperature and humidity are higher than surrounding environments. Previous studies have shown that greenhouse populations of two common molds, and within a small community in southwestern China were variably differentiated. However, the relative contribution of physical separation among local greenhouses to the large-scale population structure remains unknown. Here, we isolated strains of from seven greenhouses in Shijiazhuang, northeast China. Their genetic diversity and triazole susceptibilities were analyzed and compared with each other and with 242 isolates from nine greenhouses in Kunming, southwest China. Results showed that the isolation of greenhouses located <1 km from each other locally contributed similarly to the overall genetic variation as that between the two distant geographic regions. In addition, our results indicate that greenhouses could be significant sources of triazole resistance, with greenhouses often differing in their frequencies of resistant strains to different triazoles.
Greenhouses have become increasingly important for food production and food security. However, our understanding of how greenhouses may contribute to genetic variations in soil microbial populations is very limited. In this study, we obtained and analyzed soil populations of the cosmopolitan fungal pathogen in seven greenhouses in Shijiazhuang, northeast China. Our analyses revealed high proportions of isolates being resistant to agricultural triazole fungicides and medical triazole drugs, including cross-resistance to both groups of triazoles. In addition, we found that greenhouse populations of located within a few kilometers showed similar levels of genetic differentiation as those separated by over 2,000 km between northeast and southwest China. Our study suggests that greenhouse populations of this and potentially other fungal pathogens represent an important ecological niche and an emerging threat to food security and human health.
是一种普遍存在于土壤中的真菌,能够引起多种植物的疾病,偶尔也会引起人类感染。虽然人们对来自受感染植物的种群进行了大量研究,但对其土壤种群的了解相对较少,包括其种群遗传结构和抗真菌药物敏感性。此外,在过去的二十年中,温室在世界各地的粮食和观赏植物生产中变得越来越重要,但温室如何影响真菌病原体,如 ,其种群仍然知之甚少。与开阔的农田不同,温室通常种植密度更高,每个温室都是一个相对较小且孤立的空间,其温度和湿度都高于周围环境。先前的研究表明,在中国西南部的一个小型社区中,两种常见霉菌 和 的温室种群存在不同程度的分化。然而,局部温室之间的物理隔离对大规模种群结构的相对贡献仍不清楚。在这里,我们从中国东北部石家庄的七个温室中分离出了 菌株。分析并比较了它们的遗传多样性和三唑类药物敏感性,以及来自中国西南部九个温室的 242 个分离株。结果表明,相距不到 1 公里的温室的分离物对整体遗传变异的贡献与两个遥远地理区域之间的遗传变异相似。此外,我们的结果表明,温室可能是三唑类耐药性的重要来源,不同温室对不同三唑类药物的耐药菌株的频率也不同。
温室对于粮食生产和粮食安全变得越来越重要。然而,我们对温室如何可能影响土壤微生物种群的遗传变异的理解非常有限。在这项研究中,我们获得并分析了来自中国东北部石家庄的七个温室中的 土壤种群。我们的分析显示,相当比例的分离物对农业用三唑类杀菌剂和医用三唑类药物具有抗药性,包括对这两类三唑类药物的交叉耐药性。此外,我们发现,位于几公里范围内的温室 种群表现出与中国东北和西南地区之间超过 2000 公里的种群分化水平相似。我们的研究表明,这种和其他潜在的真菌病原体的温室种群代表了一个重要的生态位,是对粮食安全和人类健康的一个新兴威胁。
