Abstract
The affordability of next generation sequencing (NGS) is transforming the field of mutation analysis in bacteria. The genetic basis for phenotype alteration can be identified directly by sequencing the entire genome of the mutant and comparing it to the wild-type (WT) genome, thus identifying acquired mutations. A major limitation for this approach is the need for an a-priori sequenced reference genome for the WT organism, as the short reads of most current NGS approaches usually prohibit de-novo genome assembly. To overcome this limitation we propose a general framework that utilizes the genome of relative organisms as mediators for comparing WT and mutant bacteria. Under this framework, both mutant and WT genomes are sequenced with NGS, and the short sequencing reads are mapped to the mediator genome. Variations between the mutant and the mediator that recur in the WT are ignored, thus pinpointing the differences between the mutant and the WT. To validate this approach we sequenced the genome of Bdellovibrio bacteriovorus 109J, an obligatory bacterial predator, and its prey-independent mutant, and compared both to the mediator species Bdellovibrio bacteriovorus HD100. Although the mutant and the mediator sequences differed in more than 28,000 nucleotide positions, our approach enabled pinpointing the single causative mutation. Experimental validation in 53 additional mutants further established the implicated gene. Our approach extends the applicability of NGS-based mutant analyses beyond the domain of available reference genomes.
Highlights
Next-generation sequencing (NGS) technologies have revolutionized the field of microbial genomics and genetics [1]
The millions of short reads produced by NGS are mapped to an a-priori sequenced reference genome of the wild-type (WT) [3] and mutations are inferred from the differences between the WT reference and the sequenced mutant [4]
The high sequence coverage generated by NGS for bacterial genomes allows detection of local base differences without the need for whole genome assembly; positions that are consistently different between the mapped reads and the mediator genome are marked as genetic changes (Figure 1)
Summary
Next-generation sequencing (NGS) technologies have revolutionized the field of microbial genomics and genetics [1]. It is affordable to sequence an entire prokaryotic genome in order to identify acquired mutations [2]. The millions of short reads produced by NGS are mapped to an a-priori sequenced reference genome of the wild-type (WT) [3] and mutations are inferred from the differences between the WT reference and the sequenced mutant [4]. Several studies have utilized NGS for identifying mutations. Isolates of the ethanol producing yeast Pichia stipitis were sequenced to detect mutations that facilitated efficient fermentation [5]. The geographical transmission of methicillin-resistant Staphylococcus aureus (MRSA) was traced, across a timescale of years, by genome-wide profiling of mutations in multiple isolates [6]. Evolution of bacterial symbionts [7] and pathogenic strains in the laboratory [8] were studied by whole genome NGS
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