Vaghefi Niloofar, Kusch Stefan, Németh Márk Z, Seress Diána, Braun Uwe, Takamatsu Susumu, Panstruga Ralph, Kiss Levente
Centre for Crop Health, Institute for Life Sciences and the Environment, University of Southern Queensland, Toowoomba, QLD, Australia.
Faculty of Veterinary and Agricultural Sciences, University of Melbourne, Parkville, VIC, Australia.
Front Microbiol. 2022 Jun 9;13:903024. doi: 10.3389/fmicb.2022.903024. eCollection 2022.
Powdery mildew fungi (), common obligate biotrophic pathogens of many plants, including important agricultural and horticultural crops, represent a monophyletic lineage within the . Within the , molecular phylogenetic relationships and DNA-based species and genera delimitations were up to now mostly based on nuclear ribosomal DNA (nrDNA) phylogenies. This is the first comprehensive genome-scale phylogenetic analysis of this group using 751 single-copy orthologous sequences extracted from 24 selected powdery mildew genomes and 14 additional genomes from , the fungal order that includes the . Representative genomes of all powdery mildew species with publicly available whole-genome sequencing (WGS) data that were of sufficient quality were included in the analyses. The 24 powdery mildew genomes included in the analysis represented 17 species belonging to eight out of 19 genera recognized within the . The epiphytic genera, all but one represented by multiple genomes, belonged each to distinct, well-supported lineages. Three hemiendophytic genera, each represented by a single genome, together formed the hemiendophytic lineage. Out of the 14 other taxa from the , , a saprobic species, was the only taxon that grouped together with the 24 genome-sequenced powdery mildew fungi in a monophyletic clade. The close phylogenetic relationship between the and was revealed earlier by a phylogenomic study of the . Further analyses of powdery mildew and genomes may discover signatures of the evolutionary processes that have led to obligate biotrophy from a saprobic way of life. A separate phylogeny was produced using the 18S, 5.8S, and 28S nrDNA sequences of the same set of powdery mildew specimens and compared to the genome-scale phylogeny. The nrDNA phylogeny was largely congruent to the phylogeny produced using 751 orthologs. This part of the study has revealed multiple contamination and other quality issues in some powdery mildew genomes. We recommend that the presence of 28S, internal transcribed spacer (ITS), and 18S nrDNA sequences in powdery mildew WGS datasets that are identical to those determined by Sanger sequencing should be used to assess the quality of assemblies, in addition to the commonly used Benchmarking Universal Single-Copy Orthologs (BUSCO) values.
白粉菌是许多植物(包括重要的农作物和园艺作物)常见的专性活体营养型病原体,在白粉菌目中代表一个单系类群。在白粉菌目中,分子系统发育关系以及基于DNA的物种和属的界定目前大多基于核糖体DNA(nrDNA)系统发育。这是首次使用从24个选定的白粉菌基因组和来自白粉菌目(包括白粉菌)的另外14个基因组中提取的751个单拷贝直系同源序列,对该类群进行全面的基因组规模系统发育分析。分析中纳入了所有具有公开可用且质量足够的全基因组测序(WGS)数据的白粉菌物种的代表性基因组。分析中包含的24个白粉菌基因组代表了白粉菌目中19个公认属中的8个属的17个物种。附生属(除一个属外均由多个基因组代表)各自属于不同的、得到有力支持的谱系。三个半内生属各自由一个单基因组代表,共同形成了半内生谱系。在白粉菌目、座囊菌纲中的14个其他分类单元中,一个腐生物种是唯一与24个基因组测序的白粉菌真菌聚在一个单系类群中的分类单元。之前通过座囊菌纲的系统基因组学研究揭示了白粉菌目与座囊菌纲之间的密切系统发育关系。对白粉菌和座囊菌纲基因组的进一步分析可能会发现从腐生生活方式导致专性活体营养的进化过程的特征。使用同一组白粉菌标本的18S、5.8S和28S nrDNA序列构建了一个单独的系统发育树,并与基因组规模的系统发育树进行比较。nrDNA系统发育树在很大程度上与使用751个直系同源物构建的系统发育树一致。研究的这一部分揭示了一些白粉菌基因组中存在的多种污染和其他质量问题。我们建议,除了常用的基准通用单拷贝直系同源物(BUSCO)值外,还应使用白粉菌WGS数据集中与桑格测序确定的序列相同的28S、内转录间隔区(ITS)和18S nrDNA序列的存在情况来评估组装质量。
