And we postulate that a different subset of genes may be

And we postulate that a different subset of genes may be involved in mastitis in other phylogenetic backgrounds. In sum, the analysis presented in this work provides strong evidence for candidate genes and functions involved in the successful colonisation and infection of the bovine udder by E. coli of phylogroup A and provides further evidence that adaptation to site-specifying nutritional milieu plays significant roles in niche-specific pathogenicity. We are actively perusing these candidates for further functional studies.Acquisition of published genome sequences. We SB 202190 cost downloaded the genome sequences for all 2951 E. coli available from public databases at the outset of the study. Since our planned analyses required good representation of the gene content for each isolate, we removed genomes where the number of contigs present in the assembly exceeded 400. This resulted in the exclusion of 202 genome sequences from further analysis. We found that two phylogroup A MPEC sequenced by a previous study (ECA-727 and ECA-O157)23 had contig counts which were higher than our thresholds, likely due to the low reported sequence coverage of these genomes23. As a result, these two genome sequences were excluded from further analysis. The 62 MPEC genomes newly sequenced in this study had contig counts of 100?50. Details of all strains used in the analysis are included in Additional Table 1. MPEC isolation and genome sequencing. Sixty-two MPEC were provided by the KOlimastIR consortium for genome sequencing. These strains were isolated from the milk of cows exhibiting clinical mastitis, using routine microbiological techniques, in diagnostic laboratories in origin countries. Total DNA was extracted using the Masterpure DNA Purification Kit (Epicentre, Madison, WI, USA) according to the manufacturer’s instructions. Sequencing was performed using an Illumina MiSeq sequencer at Glasgow Polyomics, Wolfson Wohl Cancer Research Centre, Glasgow, UK. A multiplex sequencing approach was used, involving 12 separately tagged libraries sequenced simultaneously in two lanes of an eight channel GAII flow cell. The standard Illumina Indexing protocol involved fragmentation of 2 g genomic DNA by acoustic shearing to enrich for 200-bp fragments, A-tailing, adapter ligation and an Cyanein web overlap extension PCR using the Illumina 3 primer set to introduce specific tag sequences between the sequencing and flow cell binding sites of the Illumina adapter. DNA clean-up was carried out after each step to remove DNA < 150 bp using a 1:1 ratio of AMPure paramagnetic beads (Beckman Coulter, Inc., USA), and a qPCR was used for final DNA quantification. De novo genome assembly for each strain was carried out using CLC Genomics Workbench (version 6.5.2). Reads were trimmed by the removal of ambiguous nucleotides from read ends, and when quality scores fell below 0.001. Reads below 20 nucleotides were also removed. For assembly, default parameters were used (automatic bubble size, automatic word size), scaffolding was performed and paired distances were automatically detected. The minimum contig length was set to 200 bp. Genome sequences were uploaded to NCBI under the accession numbers given in Additional Table 1. The NCBI BioProject accession for this study is PRJNA305846. Elaboration of the E. coli population structure. To build an initial phylogenetic tree to confirm the placement of the 66 MPEC genomes into phylogroup A, we extracted the nucleotide sequences of 159 core genes from all.And we postulate that a different subset of genes may be involved in mastitis in other phylogenetic backgrounds. In sum, the analysis presented in this work provides strong evidence for candidate genes and functions involved in the successful colonisation and infection of the bovine udder by E. coli of phylogroup A and provides further evidence that adaptation to site-specifying nutritional milieu plays significant roles in niche-specific pathogenicity. We are actively perusing these candidates for further functional studies.Acquisition of published genome sequences. We downloaded the genome sequences for all 2951 E. coli available from public databases at the outset of the study. Since our planned analyses required good representation of the gene content for each isolate, we removed genomes where the number of contigs present in the assembly exceeded 400. This resulted in the exclusion of 202 genome sequences from further analysis. We found that two phylogroup A MPEC sequenced by a previous study (ECA-727 and ECA-O157)23 had contig counts which were higher than our thresholds, likely due to the low reported sequence coverage of these genomes23. As a result, these two genome sequences were excluded from further analysis. The 62 MPEC genomes newly sequenced in this study had contig counts of 100?50. Details of all strains used in the analysis are included in Additional Table 1. MPEC isolation and genome sequencing. Sixty-two MPEC were provided by the KOlimastIR consortium for genome sequencing. These strains were isolated from the milk of cows exhibiting clinical mastitis, using routine microbiological techniques, in diagnostic laboratories in origin countries. Total DNA was extracted using the Masterpure DNA Purification Kit (Epicentre, Madison, WI, USA) according to the manufacturer's instructions. Sequencing was performed using an Illumina MiSeq sequencer at Glasgow Polyomics, Wolfson Wohl Cancer Research Centre, Glasgow, UK. A multiplex sequencing approach was used, involving 12 separately tagged libraries sequenced simultaneously in two lanes of an eight channel GAII flow cell. The standard Illumina Indexing protocol involved fragmentation of 2 g genomic DNA by acoustic shearing to enrich for 200-bp fragments, A-tailing, adapter ligation and an overlap extension PCR using the Illumina 3 primer set to introduce specific tag sequences between the sequencing and flow cell binding sites of the Illumina adapter. DNA clean-up was carried out after each step to remove DNA < 150 bp using a 1:1 ratio of AMPure paramagnetic beads (Beckman Coulter, Inc., USA), and a qPCR was used for final DNA quantification. De novo genome assembly for each strain was carried out using CLC Genomics Workbench (version 6.5.2). Reads were trimmed by the removal of ambiguous nucleotides from read ends, and when quality scores fell below 0.001. Reads below 20 nucleotides were also removed. For assembly, default parameters were used (automatic bubble size, automatic word size), scaffolding was performed and paired distances were automatically detected. The minimum contig length was set to 200 bp. Genome sequences were uploaded to NCBI under the accession numbers given in Additional Table 1. The NCBI BioProject accession for this study is PRJNA305846. Elaboration of the E. coli population structure. To build an initial phylogenetic tree to confirm the placement of the 66 MPEC genomes into phylogroup A, we extracted the nucleotide sequences of 159 core genes from all.