Rebecca R Sweany, Brian M Mack, Solomon T Gebru, Mark K Mammel, Jeffrey W Cary, Geromy G Moore, Matthew D Lebar, Carol H Carter-Wientjes, Matthew K Gilbert
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引用次数: 0
Abstract
The ascomycete fungus Aspergillus flavus infects and contaminates corn, peanuts, cottonseed, and tree nuts with toxic and carcinogenic aflatoxins. Subdivision between soil and host plant populations suggests that certain A. flavus strains are specialized to infect peanut, cotton, and corn despite having a broad host range. In this study, the ability of strains isolated from corn and/or soil in 11 Louisiana fields to produce conidia (field inoculum and male gamete) and sclerotia (resting bodies and female gamete) was assessed and compared with genotypic single-nucleotide polymorphism (SNP) differences between whole genomes. Corn strains produced upward of 47× more conidia than strains restricted to soil. Conversely, corn strains produced as much as 3000× fewer sclerotia than soil strains. Aspergillus flavus strains, typified by sclerotium diameter (small S-strains, <400 μm; large L-strains, >400 μm), belonged to separate clades. Several strains produced a mixture (M) of S and L sclerotia, and an intermediate number of conidia and sclerotia, compared with typical S-strains (minimal conidia, copious sclerotia) and L-strains (copious conidia, minimal sclerotia). They also belonged to a unique phylogenetic mixed (M) clade. Migration from soil to corn positively correlated with conidium production and negatively correlated with sclerotium production. Genetic differences correlated with differences in conidium and sclerotium production. Opposite skews in female (sclerotia) or male (conidia) gametic production by soil or corn strains, respectively, resulted in reduced effective breeding population sizes when comparing male:female gamete ratio with mating type distribution. Combining both soil and corn populations increased the effective breeding population, presumably due to contribution of male gametes from corn, which fertilize sclerotia on the soil surface. Incongruencies between aflatoxin clusters, strain morphotype designation, and whole genome phylogenies suggest a history of sexual reproduction within this Louisiana population, demonstrating the importance of conidium production, as infectious propagules and as fertilizers of the A. flavus soil population.
黄曲霉菌(Aspergillus flavus)会感染玉米、花生、棉籽和坚果,并使其受到污染,产生有毒的致癌黄曲霉毒素。土壤和寄主植物种群之间的细分表明,尽管黄曲霉的寄主范围很广,但某些菌株专门感染花生、棉花和玉米。本研究评估了从路易斯安那州 11 块田地的玉米和/或土壤中分离出的菌株产生分生孢子(田间接种体和雄配子)和硬粒(静止体和雌配子)的能力,并将其与全基因组之间的基因型单核苷酸多态性(SNP)差异进行了比较。与局限于土壤中的菌株相比,玉米菌株产生的分生孢子多达 47 倍。相反,玉米菌株产生的硬菌比土壤菌株少 3000 倍之多。黄曲霉菌株以硬菌直径(小 S 型菌株,400 μm)为典型,属于不同的支系。与典型的 S 型菌株(极少的分生孢子,大量的硬菌丝)和 L 型菌株(大量的分生孢子,极少的硬菌丝)相比,有几个菌株产生 S 型和 L 型硬菌丝的混合物(M 型),以及中间数量的分生孢子和硬菌丝。它们还属于一个独特的系统发育混合(M)支系。从土壤向玉米的迁移与分生孢子的产生呈正相关,而与硬菌的产生呈负相关。遗传差异与分生孢子和硬菌丝产量的差异相关。当比较雌雄配子比和交配类型分布时,土壤株系或玉米株系的雌性(硬菌丝)或雄性(分生孢子)配子产量的相反偏差分别导致有效繁殖种群数量的减少。将土壤种群和玉米种群结合在一起会增加有效繁殖种群,这可能是由于玉米雄配子的贡献,因为玉米雄配子会使土壤表面的硬粒菌受精。黄曲霉毒素簇、菌株形态类型命名和全基因组系统发育之间的不一致性表明,路易斯安那州的这一种群中存在有性生殖的历史,这证明了分生孢子的产生作为黄曲霉土壤种群的感染性繁殖体和肥料的重要性。
期刊介绍:
International in coverage, Mycologia presents recent advances in mycology, emphasizing all aspects of the biology of Fungi and fungus-like organisms, including Lichens, Oomycetes and Slime Molds. The Journal emphasizes subjects including applied biology, biochemistry, cell biology, development, ecology, evolution, genetics, genomics, molecular biology, morphology, new techniques, animal or plant pathology, phylogenetics, physiology, aspects of secondary metabolism, systematics, and ultrastructure. In addition to research articles, reviews and short notes, Mycologia also includes invited papers based on presentations from the Annual Conference of the Mycological Society of America, such as Karling Lectures or Presidential Addresses.