Whole-Genome Sequencing of Newly Emerged Fungal Pathogen Aspergillus Lentulus and Its Azole Resistance Gene Prediction.

IF 1.1 4区 生物学 Q4 GENETICS & HEREDITY Genetic testing and molecular biomarkers Pub Date : 2024-10-01 DOI:10.1089/gtmb.2024.0002
Xiaodong Wang, Aikedai Yusufu, Hadiliya Hasimu, Paride Abliz
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The aim of this study was to investigate the <i>A. lentulus</i> signature at the molecular level, analyze the genome-wide profile of this strain, and predict its possible genes that execute azole resistance. <b><i>Methods:</i></b> In this study, a whole-genome sequencing of a clinically isolated <i>A. lentulus</i> strain (named <i>A. lentulus</i> PWCAL1) was studied by PacBio Sequel sequencing platform. Azole resistance genes were predicted based on whole-genome sequencing data analysis, gene function annotation, comparative genomic analysis, and BLASTP alignment using the Mycology Antifungal Resistance Database to comprehensively understanding the genome-wide features, pathogenicity, and resistance mechanisms of <i>A. lentulus</i>. <b><i>Results:</i></b> The results of whole-genome sequencing demonstrated that the total length of <i>A. lentulus</i> PWCAL1 genome was 31255105 bp, the GC content was 49.24%, and 6883 coding genes were predicted. A total of 4565, 1824, and 6405 genes were annotated in the Gene Ontology, Clusters of Orthologous Groups, and Kyoto Encyclopedia of Genes and Genomes databases, respectively. In the Pathogen Host Interactions Database and the Database of Fungal Virulence Factors, 949 and 259 interacting virulence factors were identified, respectively, with the main virulence factor-mutant virulence phenotype, being enriched in reduced virulence. Comparative genomic analysis showed that there were 5456 consensus core genes in this strain and four closely related strains of <i>A. fumigatus</i> complex, which were mainly involved in human diseases, metabolism, organismal systems, etc. Among the three aligned <i>A. lentulus</i> strains, the number of unique genes of this bacterium was the highest with a number of 171, and these genes were mainly associated with carbohydrate metabolism and cell growth and death. Resistance gene prediction demonstrated that the A5653 gene of this bacterium had <i>F46Y/N248T</i> double point mutations on the <i>CYP51A</i> gene, but no tandem repeat mutations in the promoter region were detected. Furthermore, 12 genes belonging to the fungal multidrug resistance ATP-binding cassette (ABC) transporters were identified based on the complete genome sequence and phylogenetic analysis of A. lentulus, which belonged to the ALDp subfamily, the PDR subfamily (<i>AtrB</i>, <i>CDR1</i>, and <i>CDR2</i>), and the MDR subfamily (<i>MDR1</i>), respectively, and there were four genes that are annotated to the major facilitator superfamily multidrug transporter. Further phylogenetic tree classification of the ABC transporter subfamilies predicted in the nine selected <i>A. fumigatus</i> complex strains showed that these putative ABC proteins were divided into two main clusters, which belonged to the PDR (<i>CDR1</i>, <i>CDR2</i>, <i>AtrB</i>, and <i>AtrF</i>) and MDR subfamilies (<i>MDR1</i>, <i>MDR2</i>, and <i>MDR3</i>). The distribution of these ABC proteins varies among different species of the <i>A. fumigatus</i> complex. <b><i>Conclusions:</i></b> The main result obtained from this study for the whole genome of <i>A. lentulus</i> provide new insights into better understanding the biological characteristics, pathogenicity, and resistance mechanisms of this bacterium. In this study, two resistance mechanisms, which include <i>CYP51A</i> gene mutation and multidrug-resistant ABC transporter, were predicted in a single isolate. Based on the predicted <i>CYP51A-F46Y/N248T</i> site mutation combination, we speculate that the <i>CYP51A</i> gene of <i>A. lentulus</i> may be partially responsible for azole resistance. Based on the predicted ABC transporter family genes, we hypothesize that resistance to multiple azoles in <i>A. lentulus</i> is mediated, at least in part, by these ABC transporters with resistance.</p>","PeriodicalId":12603,"journal":{"name":"Genetic testing and molecular biomarkers","volume":"28 10","pages":"410-430"},"PeriodicalIF":1.1000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Genetic testing and molecular biomarkers","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1089/gtmb.2024.0002","RegionNum":4,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"GENETICS & HEREDITY","Score":null,"Total":0}
引用次数: 0

Abstract

Aims: Aspergillus lentulus is an important newly recorded species in the A. fumigatus complex and its resistance to azole drugs and the high mortality rate of infected individuals have emerged as problems. Comprehensive understanding of the A. lentulus is limited due to lack of genome-wide fine mapping data. The aim of this study was to investigate the A. lentulus signature at the molecular level, analyze the genome-wide profile of this strain, and predict its possible genes that execute azole resistance. Methods: In this study, a whole-genome sequencing of a clinically isolated A. lentulus strain (named A. lentulus PWCAL1) was studied by PacBio Sequel sequencing platform. Azole resistance genes were predicted based on whole-genome sequencing data analysis, gene function annotation, comparative genomic analysis, and BLASTP alignment using the Mycology Antifungal Resistance Database to comprehensively understanding the genome-wide features, pathogenicity, and resistance mechanisms of A. lentulus. Results: The results of whole-genome sequencing demonstrated that the total length of A. lentulus PWCAL1 genome was 31255105 bp, the GC content was 49.24%, and 6883 coding genes were predicted. A total of 4565, 1824, and 6405 genes were annotated in the Gene Ontology, Clusters of Orthologous Groups, and Kyoto Encyclopedia of Genes and Genomes databases, respectively. In the Pathogen Host Interactions Database and the Database of Fungal Virulence Factors, 949 and 259 interacting virulence factors were identified, respectively, with the main virulence factor-mutant virulence phenotype, being enriched in reduced virulence. Comparative genomic analysis showed that there were 5456 consensus core genes in this strain and four closely related strains of A. fumigatus complex, which were mainly involved in human diseases, metabolism, organismal systems, etc. Among the three aligned A. lentulus strains, the number of unique genes of this bacterium was the highest with a number of 171, and these genes were mainly associated with carbohydrate metabolism and cell growth and death. Resistance gene prediction demonstrated that the A5653 gene of this bacterium had F46Y/N248T double point mutations on the CYP51A gene, but no tandem repeat mutations in the promoter region were detected. Furthermore, 12 genes belonging to the fungal multidrug resistance ATP-binding cassette (ABC) transporters were identified based on the complete genome sequence and phylogenetic analysis of A. lentulus, which belonged to the ALDp subfamily, the PDR subfamily (AtrB, CDR1, and CDR2), and the MDR subfamily (MDR1), respectively, and there were four genes that are annotated to the major facilitator superfamily multidrug transporter. Further phylogenetic tree classification of the ABC transporter subfamilies predicted in the nine selected A. fumigatus complex strains showed that these putative ABC proteins were divided into two main clusters, which belonged to the PDR (CDR1, CDR2, AtrB, and AtrF) and MDR subfamilies (MDR1, MDR2, and MDR3). The distribution of these ABC proteins varies among different species of the A. fumigatus complex. Conclusions: The main result obtained from this study for the whole genome of A. lentulus provide new insights into better understanding the biological characteristics, pathogenicity, and resistance mechanisms of this bacterium. In this study, two resistance mechanisms, which include CYP51A gene mutation and multidrug-resistant ABC transporter, were predicted in a single isolate. Based on the predicted CYP51A-F46Y/N248T site mutation combination, we speculate that the CYP51A gene of A. lentulus may be partially responsible for azole resistance. Based on the predicted ABC transporter family genes, we hypothesize that resistance to multiple azoles in A. lentulus is mediated, at least in part, by these ABC transporters with resistance.

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新出现的真菌病原体曲霉(Aspergillus Lentulus)的全基因组测序及其抗唑基因预测。
目的:扁平曲霉(Aspergillus lentulus)是烟曲霉菌群中新记录的一个重要菌种,其对唑类药物的抗药性和感染个体的高死亡率已成为问题。由于缺乏全基因组精细图谱数据,对扁平曲霉的全面了解十分有限。本研究的目的是在分子水平上研究猪肺酵母菌的特征,分析该菌株的全基因组特征,并预测其可能的唑类抗性基因。研究方法本研究利用 PacBio Sequel 测序平台对一株临床分离的扁平苔藓菌株(命名为扁平苔藓 PWCAL1)进行了全基因组测序。根据全基因组测序数据分析、基因功能注释、比较基因组分析以及利用Mycology抗真菌耐药性数据库进行的BLASTP比对,预测了唑类耐药性基因,以全面了解扁平苔藓菌的全基因组特征、致病性和耐药性机制。研究结果全基因组测序结果表明,A. lentulus PWCAL1 基因组总长度为 31255105 bp,GC 含量为 49.24%,预测编码基因 6883 个。在基因本体、同源组簇和京都基因与基因组百科全书数据库中分别注释了 4565、1824 和 6405 个基因。在病原体宿主相互作用数据库和真菌毒力因子数据库中,分别发现了 949 个和 259 个相互作用的毒力因子,其中主要的毒力因子-突变毒力表型富集在毒力降低上。基因组比较分析表明,该菌株与烟曲霉复合菌株中的4个近缘菌株有5456个共识核心基因,主要涉及人类疾病、新陈代谢、机体系统等。在三株对齐的烟曲霉菌株中,该菌的独特基因数量最多,达 171 个,这些基因主要与碳水化合物代谢、细胞生长和死亡有关。抗性基因预测表明,该菌的 A5653 基因在 CYP51A 基因上有 F46Y/N248T 双点突变,但在启动子区域没有发现串联重复突变。此外,根据扁豆菌的全基因组序列和系统进化分析,确定了属于真菌多药耐药性ATP结合盒(ABC)转运体的12个基因,分别属于ALDp亚家族、PDR亚家族(AtrB、CDR1和CDR2)和MDR亚家族(MDR1),有4个基因被注释为主要促进剂超家族多药转运体。对所选的九个烟曲霉复合菌株中预测的 ABC 转运体亚家族进行进一步的系统发生树分类显示,这些假定的 ABC 蛋白分为两大类,分别属于 PDR(CDR1、CDR2、AtrB 和 AtrF)和 MDR 亚家族(MDR1、MDR2 和 MDR3)。这些 ABC 蛋白的分布在烟曲霉复合体的不同物种之间存在差异。结论:本研究获得的关于烟曲霉全基因组的主要结果为更好地了解该细菌的生物学特征、致病性和抗性机制提供了新的视角。本研究预测了单个分离株的两种耐药机制,包括 CYP51A 基因突变和耐多药 ABC 转运体。根据预测的 CYP51A-F46Y/N248T 位点突变组合,我们推测扁平苔藓杆菌的 CYP51A 基因可能是导致其产生唑类耐药性的部分原因。根据预测的 ABC 转运体家族基因,我们推测,扁豆 A 对多种唑类的抗性至少部分是由这些具有抗性的 ABC 转运体介导的。
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来源期刊
CiteScore
2.50
自引率
7.10%
发文量
63
审稿时长
1 months
期刊介绍: Genetic Testing and Molecular Biomarkers is the leading peer-reviewed journal covering all aspects of human genetic testing including molecular biomarkers. The Journal provides a forum for the development of new technology; the application of testing to decision making in an increasingly varied set of clinical situations; ethical, legal, social, and economic aspects of genetic testing; and issues concerning effective genetic counseling. This is the definitive resource for researchers, clinicians, and scientists who develop, perform, and interpret genetic tests and their results. Genetic Testing and Molecular Biomarkers coverage includes: -Diagnosis across the life span- Risk assessment- Carrier detection in individuals, couples, and populations- Novel methods and new instrumentation for genetic testing- Results of molecular, biochemical, and cytogenetic testing- Genetic counseling
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