Abstract
Shigella species are specialised lineages of Escherichia coli that have converged to become human-adapted and cause dysentery by invading human gut epithelial cells. Most studies of Shigella evolution have been restricted to comparisons of single representatives of each species; and population genomic studies of individual Shigella species have focused on genomic variation caused by single nucleotide variants and ignored the contribution of insertion sequences (IS) which are highly prevalent in Shigella genomes. Here, we investigate the distribution and evolutionary dynamics of IS within populations of Shigella dysenteriae Sd1, Shigella sonnei and Shigella flexneri. We find that five IS (IS1, IS2, IS4, IS600 and IS911) have undergone expansion in all Shigella species, creating substantial strain-to-strain variation within each population and contributing to convergent patterns of functional gene loss within and between species. We find that IS expansion and genome degradation are most advanced in S. dysenteriae and least advanced in S. sonnei; and using genome-scale models of metabolism we show that Shigella species display convergent loss of core E. coli metabolic capabilities, with S. sonnei and S. flexneri following a similar trajectory of metabolic streamlining to that of S. dysenteriae. This study highlights the importance of IS to the evolution of Shigella and provides a framework for the investigation of IS dynamics and metabolic reduction in other bacterial species.
Author summary
Originally classified as a genus due to shared disease features, Shigella species actually represent distinct lineages of Escherichia coli that have become human-restricted dysentery pathogens via convergent evolution. A hallmark of this host-adaptation is the accumulation of insertion sequences (IS), which interrupt genes and cause deletions or genome rearrangements. Due to technical limitations in identifying IS insertions from short-read data, our understanding of the contribution of IS to the evolution of Shigella and other host- restricted bacteria has relied on analyses of either single genome representatives, or small numbers of genomes, and there are no large-scale population genomic studies exploring IS dynamics within bacterial species. Here we explore IS variation within and between Shigella species, revealing their historical and ongoing contributions to evolutionary convergence and metabolic streamlining.
Introduction
Shigellae are Gram-negative intracellular bacterial pathogens transmitted via the faecal-oral route and are the bacterial agents of dysentery [1,2]. Four species are currently defined on the basis of serotypes: Shigella dysenteriae, Shigella flexneri, Shigella sonnei and Shigella boydii. S. flexneri and S. sonnei are endemic in human populations globally and contribute most to the dysentery disease burden [1]; S. dysenteriae is associated with epidemic bacillary dysentery [3] and S. boydii is rare and mostly restricted to the Indian sub-continent [1]. All Shigella are restricted to the human host, with no known animal or environmental reservoirs. DNA sequence analyses show that the serologically defined Shigella ‘species’ are in fact paraphyletic members of species Escherichia coli (see Fig 1A), which have converged on similar human-adapted dysentery-associated phenotypes through parallel evolutionary processes [4–8]. These include gains of function via acquisition of the virulence plasmid pINV which carries genes for invasive infection including the mix-spa locus encoding a type 3 secretion system [9], and of genomic islands SHI-1, which carries several toxins [10], and SHI-2, which encodes the siderophore aerobactin as well as bactericidal and immune evasion genes.
Genome degradation–a common signature of host-restricted pathogens associated with passing through an evolutionary bottleneck and adapting to a narrow host range [11–14] –is also recognised as an important part of the convergent evolution of Shigella species [15]. Unlike most E. coli, Shigella species are non-motile due to inactivation of flagella and also lack fimbrial adhesins [15], which likely impedes host immune recognition [16,17]. Four metabolic pathways present in E. coli are known to be deleted or inactivated in all Shigella [18]: nadA/nadB, which are responsible for the nicotine acid pathway [19,20]; cadA, which encodes a lysine decarboxylase [15]; speG which converts spermidine into the non-reactive acetylspermidine [21]; and ompT, an outer membrane protease [15]. Restoring function for each of these pathways has been shown to interfere with the ability of Shigella to cause disease in humans [18].
The degradation of Shigella genomes is associated with a variety of mutational processes including deletions, nonsense mutations, and insertion sequences (IS)–small transposable elements that are ubiquitous in Shigella genomes and contribute to functional gene loss by disrupting coding sequences or facilitating genome rearrangements and deletions between homologous IS copies [15,22]. In other bacterial pathogens, IS have also been shown to influence gene expression [23]. Within Shigella, loss of the flagella flhDC and curli csg operons in each species has been mediated by IS [5,18], as well as the inactivation of the cadA gene in S. sonnei [18]. Yang et al recognised the high number of IS in individual Shigella genomes (one per species), including quantifying which IS were present and hypothesised that they were the likely causative agent of the observed large-scale genome rearrangements [15]. Other reviews of Shigella have simply noted that IS are overrepresented in Shigella genomes or detailed specific instances of IS-mediated gene deletion of important metabolic pathways [18]. To date no studies have examined in detail the impact IS have had on the evolutionary history of Shigella or compared their impact to that of other mutational processes.
Recent genomic studies of S. flexneri, S. dysenteriae, and S. sonnei have begun to elucidate the finer population structure of the major clades of these species (S5, S4 and S2, respectively, according to the nomenclature of Sahl et al [7]; see Fig 1A). The S. flexneri study focused on clade S5 (C3 according to the nomenclature of Yang et al [8]) which comprises serotypes 1, 2, 3, 4, 5, X and Y (Fig 1A). These serotypes accounted for 80% of S. flexneri identified in the paediatric Global Enteric Multicenter Study (GEMS) [24]. S. flexneri clade S5/C3 has seven deep branching phylogenetic lineages, which are separated from one another by mean 0.089% nucleotide divergence and 150–600 years of evolution, are each broadly geographically distributed, and cause endemic disease in developing countries [25]. The S. dysenteriae study focused on type 1 (Sd1), which is the dominant agent of epidemic bacillary dysentery and forms a single monophyletic clade (S4) in the E. coli tree (Fig 1A). Phylogenomic analysis showed that Sd1 isolated from dysentery outbreaks spanning the last century share a recent common ancestor in the 18th century, which has diverged into four lineages (mean 0.017% divergence) that spread globally during the late 19th century [26]. S. sonnei are monophyletic in the E. coli tree (clade S2, Fig 1A) and accounted for 24% of all Shigella cases in GEMS [24]. Phylogenomic analysis showed S. sonnei isolates from the last 80 years share a common ancestor in the late 17th century and the population has since diverged into three major lineages that are ~0.023% divergent from one another [27]. Lineage III is currently the most prevalent and geographically widespread [27], and is replacing circulating lineages of S. flexneri in developing nations [28,29].
The population structure and natural history of S. boydii has not yet been clearly elucidated. Currently available S. boydii genomes are broadly distributed across multiple clades in the E. coli phylogeny (see Fig 1A), including clades S3/C2 (together with multiple non-Sd1 S. dysenteriae serotypes) and clade S1/C1 (together with S. flexneri serotype 6 and non-Sd1 S. dysenteriae). The largest comparative study of S. boydii genomes (n = 42 genomes) confirmed that isolates assigned to this ‘species’ by serology are paraphyletic [30]. The largest monophyletic S. boydii clade in that study (part of S1/C1) contained just n = 18 genomes, and there are no published studies investigating the evolution or population structure of particular S. boydii clades or of the mixed Shigella clades, S1/C1 or S3/C2, to which most S. boydii belong. This is likely because these clades are much rarer amongst human dysentery cases, comprising just 5% of Shigella isolated in GEMS [24].
The published population genomic studies of S. sonnei, S. flexneri S5 and S. dysenteriae Sd1 primarily focused on elucidating population structure defined by single nucleotide variants (SNVs), which are readily extracted from high-throughput short read sequencing data [25–27]; however they did not investigate IS dynamics within each population nor their contribution to convergent evolution between Shigella species or clades. Here we apply new IS detection and genome-scale metabolic modelling tools to investigate and compare IS dynamics within the three major Shigella clades S. sonnei, S. flexneri S5 and S. dysenteriae Sd1 (shaded in Fig 1A), contextualised within the broader E. coli species. We identify five IS that have undergone dramatic parallel expansions in Shigella but not other E. coli, and reconstruct their evolutionary history in the three major Shigella clades. Notably these clades are responsible for the majority of the global dysentery disease burden: S. dysenteriae Sd1 (responsible for majority of epidemic dysentery); S. sonnei and S. flexneri S5 (main contributors to the endemic disease burden, together responsible for >76% of Shigella cases in GEMS [24]). We examine the contribution of IS to past and ongoing functional diversification within and between the major Shigella clades, and elucidate convergent patterns of metabolic pathway loss.
Results
IS distribution in Shigella populations
Genome size, gene counts and IS counts for the various Shigella reference genomes and selected E. coli reference genomes are shown in Fig 1B and 1C. As previously reported [15], Shigella chromosomes are significantly smaller than other E. coli (mean 4.6 Mbp vs 4.9 Mbp; p = 0.03 using Wilcoxon test and counting one strain per lineage), with more IS (median 339 vs 32; p = 0.0007), which account for 5–8% of bases in the Shigella genomes compared to <1% in other E. coli (p = 0.0007; see Fig 1C; S1 Table). S. dysenteriae Sd1 has the smallest chromosome (4.3 Mbp), with the smallest coding capacity (4270 intact protein coding sequences (CDS)) and highest density of IS (9.26 per 100 kbp of sequence, 13–42 times that of other E. coli; see S1 Table).
The Shigella reference chromosomes each harboured 229–348 IS insertions, including five IS common to all species (IS1, IS2, IS4, IS600, IS911) and up to eight additional IS per species (S1 Table). We used ISMapper [31] to identify chromosomal insertion sites for these IS in short-read data sets for the three major Shigella global genome collections (n = 125 S. dysenteriae serotype 1 (clade S4 in Fig 1A, hereafter referred to simply as S. dysenteriae) [26], n = 343 S. flexneri (clade S5 in Fig 1A, hereafter referred to simply as S. flexneri) [25], n = 126 S. sonnei [27]. ISMapper analysis detected a median of 286 IS insertions per chromosome (range 175–322) in S. sonnei, 194 (range 132–241) in S. flexneri and 197 (range 183–219) in S. dysenteriae (Fig 2, S1 Table). These numbers are lower (median 53–86%) than those identified in completed reference chromosomes (Fig 1B) [15]. This underestimation is expected because ISMapper detects insertion sites relative to an IS-free reference sequence for each species [31], and cannot detect insertions of IS within other IS (which does occur in the reference genomes) [15]. IS are also present in the virulence plasmid sequences of finished Shigella reference genomes [15] (S2 Table); however as the plasmid is frequently lost during culture [32] and was lacking from many of the short read data sets [27], IS variation in the virulence plasmid was not further examined in this study. There may be additional IS present in these genomes that were not found in the reference genome. However these IS are likely to be rare, as they are not conserved in the population, and therefore were not present during the bottleneck event that occurred when each species adapted to humans; thus are likely to have relatively minor impact on evolutionary patterns compared to the major five IS that have been expanding in these species clades since their emergence. Across all genomes, n = 609 unique IS insertion sites were identified in the S. dysenteriae chromosome, n = 1,778 in S. flexneri and n = 1,227 in S. sonnei (S1–S3 Figs, S3–S5 Tables).
Within each Shigella species, we observed substantial variation in the number (Fig 2) and location (S1–S3 Figs, S3–S5 Tables) of IS insertion sites detected, to the extent that phylogenetic lineages within each species could generally be distinguished from one another by IS insertion profiles alone (see insets, Fig 2A–2C). This indicates IS transposition has been a persistent feature of Shigella genomes during the diversification of each population from its most recent common ancestor (MRCA), represented by the root of each species tree in Fig 2A–2C. Strain-specific IS insertion sites, which reflect recent transposition events since the divergence of each isolate from its nearest relative in the sampled population, were identified in 67% of S. dysenteriae genomes, 60% of S. flexneri genomes and 75% of S. sonnei genomes, indicating IS continue to generate population diversity in each species.
IS dynamics and population structure
The three phylogenetic lineages of S. sonnei each showed highly differentiated IS profiles (inset, Fig 2C), with pairs of isolates from different lineages sharing only 53% of their IS insertion sites (compared to mean 84% of IS sites shared between pairs from the same lineage, Fig 3B). However within each lineage, the temporal dynamics of IS accumulation were quite similar. Linear regression of IS insertion count on year of isolation for the observed S. sonnei genomes estimated a mean contemporary IS accumulation rate of 0.34 IS per year (Fig 2D). The correlation between IS and date of isolation was significant (p = 0.001 using a date randomisation test to account for phylogenetic non-independence, see S4 Fig). To more directly model the recent evolutionary history of IS expansion in S. sonnei, we used maximum parsimony ancestral state reconstruction to infer the presence/absence of each IS insertion at internal nodes of the dated phylogeny (Fig 2E), and interpreted transitions between inferred states at linked nodes as IS gain/loss events (see Methods). The total number of gains across the tree was significantly correlated with the number of strain-specific insertions for each IS (correlation coefficient = 0.88, R2 = 0.76, p = 0.0001; S5A Fig), indicating strong agreement between both measures of recent IS activity. The overall patterns of inferred gain/loss events were biologically plausible, with few instances of biologically unlikely scenarios such as re-insertion of the same IS at the same site following a loss event (see S1 Text for more details). The ancestral state reconstruction analysis showed strikingly parallel IS-through-time trajectories for S. sonnei lineages II and III (Fig 2E). Lineage I genomes carried fewer IS insertion sites than lineages II and III (median 243 (IQR 217–251) unique insertion sites per chromosome vs 299 (286–312) and 294 (289–298) respectively; see Fig 2C). However the ancestral state reconstruction analysis indicated a very similar IS accumulation rate in all three lineages, albeit starting from a lower copy number in the lineage I MRCA (Fig 2E). Based on further investigation of the IS that distinguish lineage I from II and III, we propose this substantial gap in IS load most likely arose through a rapid expansion of IS1 on the branch leading to the MRCA of lineages II and III, accumulating ~45 new IS1 insertions over ~35 years, or 1.3 IS per year; see Methods, S1 Text, S6 Table.
Despite being distinguished by nucleotide divergence levels similar to those of S. sonnei lineages (Fig 3A), S. dysenteriae lineages were not differentiated in terms of the number of IS insertion sites identified by ISMapper (Fig 2A) and shared most of the same IS sites (mean 82% shared both within and between lineages; see Fig 3B and 3C and S1 Fig). Ancestral state reconstruction and lack of a strong association between IS insertion counts and year of isolation (R2 = 0.07, p = 0.012) further supports that IS have been relatively stable in the S. dysenteriae Sd1 genome for the century since the extant lineages diverged (S6 Fig), although lineages could still be distinguished based on IS profiles (see inset in Fig 2A).
S. flexneri lineages were 4–5 times more divergent from one another at the nucleotide level than were lineages of S. sonnei and S. dysenteriae (Fig 3A), and accordingly IS insertion counts and sites varied much more extensively between S. flexneri lineages as expected given the much greater amount of evolutionary time separating them (Fig 2B, Fig 3B and 3C, S2 Fig). Notably, pairs of isolates from different S. flexneri lineages still shared on average a third of their IS insertion sites (Fig 3B), indicating that a substantial IS expansion had occurred in the MRCA of S. flexneri prior to their diversification hundreds of years ago.
Parallel expansions of common IS
The five common IS (IS1, IS2, IS4, IS600, IS911) accounted for most IS insertions detected in the Shigella reference genomes (including S. boydii Sb227 (clade C1/S1 in Fig 1A), see Fig 1B and S1 Table) and short-read population surveys (Fig 2), together comprising 99% of the IS burden in S. dysenteriae, 86% in S. flexneri and 85% in S. sonnei. IS1 contributed most to the number of IS insertion sites in all three species (median 42–59% of insertions across all genomes within each species as detected by ISMapper, see Fig 5B; 46–73% of insertions identified in reference genomes, see Fig 1B and S1 Table). To assess the recent activity of these common IS in the various Shigella populations, we counted the number of strain-specific IS insertions and normalised these counts against the number of strain-specific SNVs (which is closely correlated with evolutionary time (R2 = 0.83) due to a strong molecular clock; see reference [33]). According to this measure, S. sonnei had significantly greater recent activity for each IS (p < 0.0003 in all cases; Fig 4). S. dysenteriae showed the lowest levels of recent activity for each IS except IS600, whose activity in S. dysenteriae was almost as high as in S. sonnei (Fig 4). The same five IS are present in the broader E. coli population, but at ~14-fold lower copy number per chromosome (median 15 in the non-redundant set of E. coli chromosomes; see Fig 1 and S7 Table). These results confirm that the same five IS have undergone parallel expansion in all four Shigella species, and are still active in the S. sonnei, S. flexneri and S. dysenteriae populations under study.
To understand the expansions we observed in Shigella in the context of other pathogenic E. coli lineages, we examined six well-known human pathogenic lineages: (i) 99 genomes of the globally disseminated ST131, associated with drug resistant extra-intestinal infections [34–38]; (ii) 36 genomes of the O104:H4 Shiga toxin-producing enteroaggregative E. coli ST678, associated with a massive foodborne outbreak in Germany [39]; (iii) 199 genomes of O157:H7 enterohemorrhagic E. coli ST11, associated with frequent foodborne outbreaks globally [40]; and three different lineages of enteroinvasive E. coli (EIEC) from Public Health England: (iv) ST6 (n = 28), (v) ST99 (n = 24), and (vi) ST270 (n = 8) [41] (genome accessions listed in S8 Table). All genomes from the three EIEC lineages were confirmed to carry a variant of the virulence plasmid, the hallmark of the EIEC pathotype.
The median IS insertion site counts in these lineages (estimated using ISMapper) were 9, 17 and 49 (non-EIEC), and 118, 71 and 164 (EIEC); with the exception of EIEC ST270 (n = 164), these are substantially lower than total IS copies estimated with the same method in the Shigella populations (median 286, 194, 197; see Fig 5A). Notably all three EIEC pathotypes had higher IS copy numbers than the three non-EIEC pathotypes, providing more evidence of IS expansion in these lineages. We also compared IS copy numbers identified from completed E. coli chromosome sequences available in PATRIC, which confirmed that the three non-EIEC pathotypes had IS copy numbers within the typical range of IS counts for E. coli generally (median 32, IQR 22–57), whereas EIEC ST6, ST270 and Shigella chromosomes were outliers Fig 5C).
IS1 was present in all of the pathogenic E. coli lineages but was expanded only in EIEC lineages ST6 and ST270 (median 0–2 in other lineages, see Fig 5B). IS2 was found in all EIEC lineages (median 16 in ST6, 6 in ST99, 2 in ST270) and in a single copy in ST131. IS4, IS600 and IS911 were found in EIEC lineages but absent from non-EIEC lineages (S1 Table). Interestingly, the pathogenic E. coli lineages showed some signs of expansion of different IS not present in Shigella: ISEc12 and ISEc23 in ST131 (median n = 5), ISEc8 and IS1203 in ST11 (median n = 14 and n = 18, respectively), ISEc23 in O104:H4 (median n = 5), and IS621 in EIEC ST99 (median n = 24).
We hypothesised that the parallel IS expansions observed in Shigella chromosomes might be associated with introduction of IS variants via pINV. The presence of the same five IS in the chromosomes of pINV-carrying EIEC lineages would be consistent with this. However IS1 is native to E. coli [42], which almost universally carry IS1 in the chromosome, and phylogenetic analyses of IS1 sequences suggest that each Shigella species has undergone independent proliferation of its resident E. coli chromosomal IS1 variant (S7A Fig). The other four IS were common but not universal in E. coli genomes (present in 50–69% of the completed genomes). Shigella genomes shared a subpopulation of IS2 and IS4 variants distinct from those found in E. coli chromosomes (S7B and S7C Fig), consistent with transfer of IS2 and IS4 between Shigella species possibly via pINV, whose IS2 and IS4 sequences were intermingled with chromosomal sequences in the phylogenies. Notably the IS2 and IS4 alleles found in EIEC clustered with the Shigella alleles, consistent with introduction via pINV. IS600 and IS911 showed similar patterns but with more intermingling between Shigella and other E. coli, suggesting more widespread transfer mechanisms other than pINV (S7D and S7E Fig); consistent with this, IS911 is lacking from pINV of S. dysenteriae and S. sonnei and IS600 is lacking from pINV of S. boydii Sb227 (S2 Table).
IS and genome degradation
All Shigella reference genomes had ≥199 pseudogenes (CDS inactivated by IS or other mutations), comprising ≥5% of CDS in each genome (S1 Table). Across the whole collection of S. dysenteriae (the species with the most-reduced coding capacity), 672 (15%) CDS were inactivated in at least one genome (by either an IS, a nonsense mutation, or a frameshift causing indel); in S. sonnei and S. flexneri, the numbers were 719 (14%) and 1,545 (30%) CDS, respectively. These natural gene-knockouts (pseudogenes) create strain-to-strain variation in coding capacity within each species, some of which shows evidence of fixation within lineages (median 103, 91 and 116 pseudogenes shared between within-lineage pairs of S. dysenteriae, S. sonnei or S. flexneri, respectively; S8A Fig), and some of which varies within lineages (median 37, 40 and 53 non-shared pseudogenes between pairs, respectively; S8B Fig).
The proportion of pseudogenes that were directly attributable to IS insertion was 50% in S. sonnei, 22% in S. flexneri and 35% in S. dysenteriae (S9A Fig). A further 12%, 24% and 11%, respectively, of interrupted genes harboured both IS and other inactivating mutations, thus could reflect initial inactivation by one mechanism followed by further degradation by another (S9A Fig). Notably, in all species the vast majority of conserved pseudogenes (i.e. those inactivated in ≥95% of genomes) were interrupted by IS (24/24 in S. sonnei, 19/20 in S. flexneri, 77/78 in S. dysenteriae). In S. dysenteriae and S. sonnei most of these lacked any other inactivating mutations, suggesting the IS insertion was the inactivating event (Fig 6A). Within each species, much of the strain-to-strain variation in pseudogene content was IS-driven, both within and between lineages (median 35–60% of pairwise differences; see blue and grey boxes in S9B–S9D Fig). To quantify and compare the diversification of IS and pseudogene profiles over time within species, we modelled pairwise counts of non-shared IS insertions and non-shared pseudogenes as a linear function of pairwise SNVs (Fig 6B). Strong linear relationships were evident in all cases (p<0.001 using Mantel test, see S10 Fig). The results indicate that diversification of both IS and pseudogene profiles is occurring most rapidly in S. sonnei (mean 141 IS and 73 pseudogenes per 1,000 SNVs), whereas ongoing diversification of both types has slowed in S. dysenteriae (25.9 IS and 35.9 pseudogenes per 1,000 SNVs) (Fig 4B). Note that the reported substitution rates for these species are very similar (6.0x10-7 per site per year for S. sonnei [27], 8.7x10-7 for S. dysenteriae [26], and between 6.4x10-7 (lineage 1) and 9.5x10-7 (lineage 2) for S. flexneri [25]), hence these IS and pseudogene rates normalised to SNV counts are also comparable as clock rates.
Taken together, our results indicate that S. sonnei, S. flexneri and S. dysenteriae have undergone similar patterns of IS expansion and genome degradation; and that S. dysenteriae is the furthest along this evolutionary trajectory, with the greatest number of IS copies and the most reduced genome but also the lowest current IS activity or copy number expansion, which is consistent with the end-point of IS saturation as predicted by published models of IS expansion [43]. Next we consider the functional impacts of IS and genome degradation, and the evidence that these mechanisms contribute to convergence towards functionally-similar streamlined genomes that are adapted to the human-restricted niche associated with Shigella. As S. dysenteriae is the furthest along the evolutionary trajectory away from other E. coli, we compare functional loss in the other Shigella species with that observed in S. dysenteriae.
IS and convergent gene loss
The ratio of IS insertions per base for genic vs intergenic regions was well below one in all three species (0.20 in S. flexneri, 0.29 in S. sonnei, 0.11 in S. dysenteriae), suggesting an overall pattern of purifying selection against insertions within CDS for each species. There was also evidence of parallel loss of the same genes in S. sonnei or S. flexneri compared to the most-reduced species S. dysenteriae (S9 Table), indicative of convergent evolution. We compared the number of pseudogenes in S. sonnei and S. flexneri that were either fixed pseudogenes (inactive in ≥90% of S. dysenteriae genomes), or completely missing from S. dysenteriae and assessed significance using a permutation test (see Methods). In S. sonnei, 61% (440/719) of the pseudogenes identified in any genome were also either fixed pseudogenes (n = 12/719, 2%, p = 0.013) or missing (n = 428/719, 59%, p<0.001) in S. dysenteriae (see S11 Fig). Of the 428 that were missing in S. dysenteriae, 334 (78%) were conserved in ≥90% of E. coli genomes, suggesting they were likely present in an ancestor of S. dysenteriae but have been deleted during genome degradation. Similarly, 54% (n = 832/1545) of S. flexneri pseudogenes were either inactivated (n = 23/1545, 2%, p = 0.001) or absent (n = 809/1545, 52%, p<0.001) in S. dysenteriae (see S11 Fig). Again, 576 (71%) of the 809 S. flexneri pseudogenes that were missing in S. dysenteriae were conserved in ≥90% of E. coli, consistent with their deletion from an S. dysenteriae ancestor. A similar pattern was observed when considering the most common S. flexneri lineages 1 and 3 separately (S11 Fig). Taken together, these results indicate that the degree of parallel functional gene loss in S. sonnei and S. flexneri compared to S. dysenteriae exceeds that due to random chance and thus is indicative of selection.
There was no significant functional enrichment amongst the genes lost in parallel between species (see Methods); however in each species the largest functional class assigned to pseudogenes was carbohydrate metabolism (S12 Fig), and in each species, 37–43% of pseudogenes with known function were metabolism related.
IS and convergent metabolic reduction
We used genome-scale models of metabolism (GEMs) [44,45] to simulate growth capabilities for the various Shigella populations in silico [46]. GEMs for the IS-free reference genomes of all four Shigella species were built with reference to a recent E. coli GEM [47] (see Methods, S10 Table & S11 Table). A total of 1,704 reactions were shared by all four Shigella reference GEMs and a further 604 reactions were found in at least one (Fig 7A and 7B). From these we built strain-specific GEMs for all S. sonnei, S. flexneri, and S. dysenteriae genomes, by removing from the species reference model reactions that were predicted to be interrupted in that genome (~20% of all pseudogenes were components of GEMs, see S9A Fig; 32–47% of these harbour IS). We used the resulting GEMs to predict the carbon, nitrogen, phosphorous and sulphur substrates that could support growth of each isolate (n = 386 substrates tested, referred to hereafter as predicted growth capabilities; see S13–S17 Figs). Metabolic maps showing conservation of each reaction pathway can be found in S18–S20 Figs.
This analysis confirmed S. dysenteriae to be the most metabolically limited of all four Shigella species, with less than two-thirds the predicted growth capabilities of the others (median 161 per strain) and little evidence of variation between strains (S13 Fig): all of the S. dysenteriae isolates were predicted to be capable of growth on the 161 substrates in the ancestral model (Fig 7C). S. sonnei had the greatest number of predicted growth capabilities (median 270 per isolate) and some strain variation (median 12 pairwise differences), whereas S. flexneri strains showed an intermediate number of predicted growth capabilities (median 230 per strain) with some variation between strains (median 20 pairwise differences; see Fig 7C, S13 Fig). Notably, pairwise differences in predicted growth phenotypes of strains of S. sonnei and S. flexneri accumulated in a linear fashion compared to SNVs, at mean rates of 11.4 and 4.1 per 1,000 SNVs, respectively (Fig 6B, S10 Fig); in contrast S. dysenteriae appears to have settled in a static reduced metabolic state, with occasional transient (non-fixed) further loss of phenotypes (Fig 6B, Fig 7C and 7E).
To explore convergence of metabolic phenotypes in Shigella species, we compared the Shigella GEMs with those reported previously for 47 diverse E. coli strains [44] as well as GEMs we built for the three EIEC reference genomes (S12 Table). The 47 E. coli GEMs shared a set of 316 core predicted growth capabilities (common to 90% of the strains), accounting for median 95% of capabilities per strain. Extensive loss of these core E. coli capabilities was apparent in each Shigella species, ranging from median 51 and 58 (16% and 18%) in S. boydii Sb227 and S. sonnei, to median 91 (29%) in S. flexneri and 177 (56%) in S. dysenteriae (blue in Fig 7D). Notably, the majority of the core E. coli metabolic capabilities lacking from S. boydii Sb227, S. sonnei or S. flexneri overlapped with those lacking in the most-reduced species S. dysenteriae (median 96%, 78%, 60%, respectively), consistent with convergent metabolic reduction across Shigella species (Fig 7D and 7E). To assess the significance of this apparent convergence towards the reduced metabolic capacity of S. dysenteriae, we permuted null distributions of core E. coli phenotype loss vs observed phenotype loss in S. dysenteriae (S21 Fig). For S. sonnei, S. boydii Sb227, S. flexneri lineage 1 and S. flexneri lineage 3, the core phenotypes lost overlapped with those lost in S. dysenteriae much more than expected under a model of random loss of core E. coli phenotypes (p<0.001 using permutation test). The three EIEC lineages also showed some loss of core E. coli capabilities (median 14, 4%); 89% of these were also lost from S. dysenteriae (significant overlap, p = <0.001 using permutation test) and 99% from either S. flexneri or S. sonnei, consistent with these pINV-carrying lineages being at an earlier point on a similar evolutionary trajectory to Shigella (Fig 7D and 7E).
This convergent loss of metabolic pathways was attributable to independent genetic lesions in each Shigella species, including a mix of IS and other mutations occurring in the same or different genes, often with degradation of multiple genes in the same pathway (examples of convergent loss of taurine as a sulfur source, and of maltodextrins as a carbon source, are shown in Fig 7F).
To address the impact of IS on pathway loss in the three Shigella species populations, we identified all inactivating events (either IS or mutational) affecting each metabolic reaction in each species. For each species, we identified the most frequent mutation event affecting each reaction, reasoning that the highest frequency event is the most conserved and thus the earliest inactivating event. We further classified the earliest inactivating event affecting each reaction as either ancient (conserved in >80% of genomes in that species), intermediate (20–80%), or recent (<20%) (S22 Fig). In S. sonnei and S. dysenteriae, all ancient inactivating events (>80% of genomes) within metabolic reactions were IS insertions (S22 Fig). In S. flexneri, 30% of ancient inactivating events in metabolic reactions were IS, but notably all completely conserved mutations (n = 3) were IS insertions. This supports our hypothesis that IS have significantly contributed to pathway loss in each species.
Only 109 metabolic phenotypes were common to all four Shigella species (present in S. boydii Sb227 and >90% of genomes from each of the three target species; see S13 Table). These phenotypes are all part of the 316 core E. coli capabilities defined above, and may constitute the minimum metabolic requirements for Shigella (S13–S17 Figs). This core set of Shigella growth capabilities includes 19 carbon, 30 nitrogen, 3 phosphorous and 6 sulfur sources. It accounted for mean 67% of growth capabilities identified in each S. dysenteriae strain, but only mean 47% of those in S. flexneri strains and mean 40% in S. sonnei, suggesting the latter species could continue on the trajectory of metabolic loss for some time.
Discussion
Overall our data show that IS have had a substantial impact on the evolutionary history of the three major Shigella species clades and continue to shape the ongoing diversification and evolutionary trajectories of S. sonnei and S. flexneri. Despite the fact that the genome collection for each species group was relatively small (~120 for S. sonnei and S. dysenteriae, 343 for S. flexneri), we believe that these genomes are representative of each population. All three of the genome collections were selected using a similar method–each are a representative snapshot from historical collections that captured diversity across both time and space. The collections represent 65 (S. sonnei), 96 (S. dysenteriae) and 98 (S. flexneri) years of isolation and have genome representatives from at least four continents. In the case of S. dysenteriae, additional effort was made to ensure that there were representatives of all recorded serotype 1 outbreaks for which isolates could be obtained [26].
All three major Shigella species clades examined in this study were found to have significantly higher IS copy numbers and reduced genomes compared to their E. coli relatives, consistent with previous reports [15]. Notably our data indicate highly parallel expansions of the same five IS types at similar relative levels in these three Shigella species (Figs 2 and 5) and S. boydii Sb227 (Fig 1); in contrast we found no evidence of a similar IS expansion in most other E. coli, including known pathogenic lineages. The exceptions were the EIEC lineages, which carried the same five IS and showed expansion of some of these, although to a lesser degree than in Shigella (IS1, IS2, IS4, IS911 in ST66; IS2, and IS600 in ST99; IS1, IS4, IS600 in ST270; see Fig 5B). EIEC are characterised by the presence of the Shigella invasion plasmid pINV, which provides them a similar ability to invade the human intestinal epithelium to cause severe diarrhea. All E. coli carry IS1, and our data suggests that each Shigella and EIEC lineage underwent expansion of their resident IS1 alleles; however IS2, IS4, IS600 and IS911 are much rarer in the E. coli population and our data are consistent with the hypothesis that pINV is a potential source for the introduction of these IS into Shigella and EIEC lineages.
The expansion of IS within Shigella has accompanied large scale genome reduction and convergent evolution towards a similar phenotype profile, in line with expectations about genetic bottlenecks related to host adaptation of bacterial pathogens in general and Shigella species in particular [15,18]. However, this study is unique in identifying the dynamics of IS expansion and genome degradation within Shigella species as they continue to diversify and evolve under selection (Figs 2, 3, 6 and 7). Particularly striking were the multiple lines of evidence indicating that IS activity is contributing to ongoing diversification of S. sonnei and S. flexneri, and that each shows convergence towards a streamlined genome that is similar to the highly-reduced S. dysenteriae (Fig 7), via both parallel evolution (through the inactivation of genes homologous to those lost from S. dysenteriae) and convergent evolution (whereby the same functional pathways are disrupted in each species but through different mechanisms). The accuracy of the GEMS used here to predict growth capabilities have been previously estimated at 80%. Unfortunately the isolates included in the genome collections under study (chosen for their diverse representative sampling, as discussed above) were not available to us hence we could not confirm individual metabolic phenotype predictions in individual strains. However, as our analyses focus on comparisons between phylogenetic groups of genomes modelled using the same underlying E. coli reactome model, inaccuracies in that underlying model cannot explain the observed similarities between Shigella clades relative to other E. coli. Furthermore, our conclusions do not rest on any single growth capability but rather the overall patterns of predicted phenotypes compared within and between clades, and confirming predictions for a small number of substrates would have little impact on the overall conclusions. Notably, the convergent metabolic losses identified here provide a starting point to guide future experimental work focussed on functional questions, such as whether convergent metabolic slimlining has any functional impact on host adaptation and/or pathogenicity in Shigella.
Notably, our analysis predicts a remarkable degree of strain-to-strain functional variation within the S. sonnei and S. flexneri species clades, which could have implications for experimental studies of Shigella pathogenicity, host interactions and antimicrobial resistance that typically rely on a limited number of lab strains [48]. For example, the S. sonnei lab strain 53G (lineage II) differed from lineage III isolates (which are responsible for the majority of S. sonnei case isolates sequenced worldwide in the past decade [27,29,49,50]) by median 24 predicted substrate growth capabilities (IQR, 23–25). In general, lineage II S. sonnei isolates differ from lineage III isolates by median 97 protein-coding genes (IQR 93–101). For S. flexneri, the common lab strains are serotype 5a strain M90T (lineage 5 [9]) and serotype 2a strains 301 or 2457T (lineage 3 [51]; note strain 301 was used in the present study as a reference genome). S. flexneri serotype 2a/lineage 3 are common amongst clinical isolates [24,52], however recent genomes of lineage 3 clinical isolates are quite diverged from 301 –in our analysis lineage 3 strains differed pairwise by median 45 protein-coding genes (IQR 37–55) and 59 predicted substrate growth capabilities (IQR 37–55). S. flexneri serotype 5a/lineage 5 is rare (not detected at all in GEMS [24]), and we estimate lineage 5 strains such as M90T differ pairwise from the clinically dominant lineage 3 by median 139 protein-coding genes (IQR 134–144) and 62 (IQR 56–63) substrates.
The available evidence suggests that much of the convergent loss of metabolic function is due to IS activity in the evolutionary histories of each the various Shigella species (Figs 6 and 7F). Firstly, in all Shigella species, nearly all conserved pseudogenes (i.e. genes that have been inactivated for some time but not yet deleted from the genome) were disrupted by IS (Fig 6A). Secondly, fixed deletions accounted for 33–51% of degradation in the Shigella reference GEMS compared to E. coli GEMS. Whilst it is difficult to attribute past deletion of specific genes to IS activity, it is likely that a significant proportion of overall gene loss in the IS-laden Shigella genomes has been IS-mediated. Thirdly, IS disruption accounted for a large proportion (32–47%) of all within-species variation in metabolic genes included in the Shigella GEMS, indicating that IS continue to play a central role in ongoing Shigella evolution.
IS are known to have played a key role in host adaptation and genome degradation in many other pathogens, including Bordatella pertussis [14],Yersinia pestis [46], Mycobacterium leprae [13] and Mycobacterium ulcerans [53]. There have been previous studies that examine the impact of IS on the evolutionary trajectories of bacterial pathogens, including Mycobacterium tuberculosis [54], Acinetobacter baumannii [55,56], Klebsiella pneumoniae [56] and Burkholderia cenocepacia [57]. However, these studies relied on a small number of genome representatives, captured shorter evolutionary timescales, did not use genome-scale metabolic modelling to systematically explore the functional impact of IS activity, and did not attempt systematic comparisons between multiple species or lineages. The present study provides a novel framework to examine with greater scrutiny the impact and dynamics of IS in other bacterial pathogens on a large scale, and to assess evidence for their role in convergent evolution. In particular we have shown how ISMapper can be applied to derive novel insights into IS variation and evolutionary dynamics using existing high-throughput short-read data, and that genome-scale metabolic modelling can be harnessed to help unravel convergent evolution at the pathway level. Notably, a recent study examining the impact of IS on the transcriptome of B. pertussis showed that many IS insertions modified the expression of neighbouring genes, creating strain-specific differences in gene regulation [23]. This approach could be combined with ours to establish an even more detailed understanding of the role of IS in pathogen evolution.
Methods
Detection of IS in Shigella and E. coli reference genomes
IS were detected in each of the reference genomes included in Fig 1 using ISSaga [58]. ISSaga screens the genome for known homologs of all IS sequences contained in the ISFinder [59] database. IS which had at least 80% nucleotide identity to an IS in the ISFinder database and that were present in at least one complete copy were included. Reference sequences for each of the detected IS were downloaded from the ISFinder database, and screened against each reference genome using BLAST+ v2.6.0 [60]. Nucleotide hits with ≥95% identity and ≥99% coverage were counted in the IS copy number tally for each reference chromosome (S1 Table) and plasmid (S2 Table).
In order to calculate the IS burden in the general E. coli population, all E. coli genomes marked as ‘completed’ in PATRIC [61] (as at January 8, 2020, n = 1943) were downloaded. This set of genomes was then de-replicated using the Assembly Dereplicator tool (https://github.com/rrwick/Assembly-Dereplicator) with a threshold of 0.005. From the set of de-replicated genomes, 100 genomes were randomly selected for further analysis (S14 Table). BLAST+ v2.2.30 was used to screen each E. coli genome for IS, including the five common Shigella-expanded IS (IS1, IS2, IS4, IS600 and IS911). Nucleotide BLAST+ hits with ≥95% identity and ≥90% coverage were counted in each genome’s tally for each IS (S7 Table).
Creation of IS-free Shigella reference genomes
To allow for more precise detection of IS insertion sites within genes, and provide a basis for constructing GEMS, IS-free versions of the chromosome sequences of S. sonnei 53G (accession NC_016822), S. dysenteriae Sd197 (accession NC_007606) and S. flexneri 2a strain 301 (accession AE005674) were created as follows. IS detected in the reference genomes using ISSaga and BLAST+ as described above were annotated, and manually inspected using the Artemis genome browser [62] to ensure that the IS sequence was complete and any target site duplications were included in the annotated feature. Each of the annotated features (i.e. IS plus target site duplication if present) was then deleted from the reference chromosome sequence. Annotations of CDS and gene features in the complete reference genome were then transferred to the IS-free reference chromosome sequence using RATT [63], with the strain transfer parameter. The IS-free reference chromosome sequences are deposited in FigShare (doi: 10.26188/5c7daac90d298).
Completion of E. coli ST270 reference genome 8-3-Ti
As no complete reference genome for E. coli ST270 was available, we used a combination of short and long read sequencing to complete the genome of isolate 8-3-Ti (provided by Prof David Gordon, Australian National University). Genomic DNA was prepared from bacterial pellets using GenFind v3 reagents (Beckman Coulter). Illumina sequencing libraries were made with Nextera Flex reagents and the Illumina CD indexes as per manufacturer’s instructions, with one major deviation from described protocol–reactions were scaled down to 25% of recommended usage. Illumina libraries were sequenced on the NovaSeq platform using the 6000 S1 Reagent Kit (300 cycles). Resulting Illumina reads had a mean length of 149 bp, with an estimated depth of 107x. A long-read sequencing library for Oxford Nanopore Technologies (ONT) was prepared using the ligation library kit (LSK-109) with native barcoding expansion packs (EXP-NBD104 and NBD114), with sequencing performed as previously described [64]. Reads were basecalled using Guppy v3.4.4. N50 read length was 27,590 bp, with an estimated depth of 35x. A hybrid assembly was constructed using both the ONT and Illumina reads with Unicycler v0.4.8 (default settings) [65]. The resulting assembly had a total genome size of 5,141,082 bp and consisted of three replicons–the chromosome (4,899,710 bp), and two plasmids (233,800 bp (pINV) and 7,413 bp). The complete genome sequence was deposited in GenBank under accessions CP050865, CP050866 and CP050867.
Detection of IS in Shigella and E. coli populations from short read data
The S. sonnei data comprised 132 isolates from the Holt et. al global study [27], sequenced on the Illumina Genome Analyzer GAII, generating paired end reads. Sequenced genomes had mean read length 59 bp and mean read depth 83x (range 68x - 91x); six genomes with low mean depth (<10x) were excluded from the analysis. The remaining 126 genomes were screened for the 12 IS identified in S. sonnei 53G by ISSaga (IS1, IS2, IS4, IS21, IS600, IS609, IS630, IS911, ISEc20, ISSso1, ISSso4, ISSso6) using ISMapper v1 [31] to identify the insertion sites of each IS relative to the IS-free S. sonnei 53G reference sequence (using typing mode and default parameters). Briefly, ISMapper maps paired short reads to each IS query sequence, and identifies unmapped partners of reads that mapped to the IS. The former demarcate DNA sequences that flank IS insertion sites, and are mapped to the reference genome sequence to determine the precise location and orientation of IS insertions captured in the short read data [31].
The S. dysenteriae data comprised 125 genomes from the Njamkepo et. al global study [26], with Illumina paired reads of 100–146 bp (mean read length 115 bp) and mean read depth 193x (range 312x - 2889x). Insertion sites for the six IS detected in the S. dysenteriae Sd197 complete reference genome (IS1, IS2, IS4, IS600, IS911 and ISEc8) were identified in all 125 genomes using ISMapper v1 with the same settings described for S. sonnei but using the IS-free S. dysenteriae Sd197 reference sequence.
The S. flexneri data consisted of 343 genomes from the Connor et. al global study [25], sequenced via Illumina HiSeq with 100 bp paired end reads with mean read depth 102x (range 19x - 419x). Insertion sites for the twelve IS detected in the S. flexneri reference genomes (IS1, IS2, IS4, IS600, IS609, IS911, IS1203, IS150, ISEc17, ISEhe3, ISSlf3 and ISSfl4) were identified in each of the 343 genomes using ISMapper v1 with the same settings described for S. sonnei but using the IS-free S. flexneri 301 reference sequence.
To investigate IS expansion in other pathogenic lineages of E. coli (Fig 5), six different clonal lineages representing different pathotypes and STs of E. coli were analysed. ST131 uropathogenic E. coli (UPEC) (n = 99) and reference strain EC958 [58] (accession HG941718) were collated from multiple separate studies [34–38]. ST11 enterohemorrhagic E. coli (EHEC) genomes (n = 199) from the public GenomeTrackr were identified based on MLST data from Ingle et. al [40]. The ST11 reference genome was E. coli O157:H5 strain EDL933 [59] (accession NZ_CP008957). Representatives of the German outbreak clone O104:H4 (n = 36) [39] with reference E. coli strain C227-11 [60] (accession NC_018658) were obtained from NCBI. Three different enteroinvasive (EIEC) lineages, ST6 (n = 28), ST99 (n = 24) and ST270 (n = 8) were obtained from a single study [41]. ST6 genomes were compared to reference strain E. coli NCTC 9031 (https://www.sanger.ac.uk/resources/downloads/bacteria/nctc/); ST99 genomes to reference E. coli CFSAN029787 (accession CP011416); ST270 genomes to reference strain E. coli 8-3-Ti3 (completed for this study, accession CP050865). Accessions for all E. coli short-read data are listed in S8 Table. Read statistics were: ST131, mean length 100 bp, mean depth 60x (range 34x - 202x); ST11, mean length 170 bp, mean depth 80x (range 16x - 245x); O104:H4, mean length 98 bp, mean depth 57x (range 8x - 214x); ST6, mean length 100 bp, mean depth 37x (range 28x – 75x); ST99, mean length 100 bp, mean depth 55x (range 25x – 84x); ST270, mean length 100 bp, mean depth 40x (range 25x – 59x). IS were identified in each E. coli reference genome using ISSaga as described above. This revealed five IS in ST131, nine IS in ST11, thirteen IS in O104:H4, four in ST6, thirteen in ST99, and twelve in ST270 (see S1 Table for IS). For each E. coli lineage, the IS detected in their reference, and the five IS common to Shigella, were used as queries with ISMapper to identify the IS insertion sites in each genome of that lineage, using the same parameters as described for Shigella. (We note that the original reporting of IS copy number in these genomes differs from our analysis, due to differences in methods. Whilst Cowley et al [41] used ISMapper, they compared all three EIEC lineages to the S. sonnei Ss046 reference genome, which is likely to yield less accurate results than our analysis using lineage-specific references for each ST. Additionally, Cowley et al did not state which IS elements they examined, making a direct comparison impossible.)
Detection of SNVs and pseudogenes in Shigella
All 125 S. dysenteriae, 343 S. flexneri and 126 S. sonnei genomes were mapped to their respective IS-free reference genomes using the RedDog pipeline v01.9b (www.github.com/katholt/RedDog) to detect SNVs and indels. Briefly, RedDog uses Bowtie2 v2.2.3 [66] with the sensitive-local parameter and a maximum insert size of 2000 bp to map all read sets to the reference genome. High quality SNV sites (homozygous calls supported by ≥10 reads, phred score ≥30, in at least one genome) were identified using SAMtools v0.0.19 [67], and high quality alleles at each SNV site determined across all genomes by extracting the consensus base from each genome using SAMtools pileup (low quality base calls–defined as phred quality ≤20, read depth ≤5, or a heterozygous base call– were set to the gap character to indicate an unknown allele).
We defined pseudogenes as genes that contained a nonsense mutation or a frameshift causing indel. To identify genes with nonsense mutations, the SNV consequences file from RedDog was used, which annotates each SNV with its coding effect (i.e. whether it is intergenic or genic; and for genic SNVs what the effect on the encoded protein is), based on the annotation of the coding features in the reference genome (in this case, the IS-free reference genomes). From this SNV consequences file, only SNVs generating nonsense mutations were extracted and kept for downstream gene inactivation analysis. Indel positions were extracted from the VCF files output by RedDog, and these indel positions were compared to the annotations in IS-free reference genomes to determine which indels were within genes. Only indel positions causing frameshifts within genes were kept for downstream pseudogene analysis.
Phylogenetic inference
To construct phylogenies for each Shigella species clade, the alignments of SNV alleles produced by the RedDog analyses (described above) were each filtered to exclude SNVs falling in repeat regions or phage (detected using PHAST [68]). The resulting alignments were 10,798 SNVs in length for S. dysenteriae; 40,073 SNVs for S. flexneri; and 6,843 SNVs for S. sonnei. These alignments were used to construct either dated (S. sonnei and S. dysenteriae) or maximum likelihood phylogenies (S. flexneri).
The S. flexneri maximum likelihood phylogeny (Fig 2B, S2 Fig) was generated using RAxML v8.2.8 [69], with a GTR+G substitution model and ascertainment bias correction. Dated phylogenies (Fig 2, S1 & S3 Figs) were inferred for S. sonnei and S. dysenteriae, as these species represent clonal lineages with strong molecular clock signal across their respective species trees. For S. dysenteriae, we used the dated phylogeny generated previously in Njamkepo et. al [26]. For S. sonnei, since six genomes used in the original study were excluded from the present study due to having insufficient read depth for reliable ISMapper analysis, we inferred a new dated phylogeny from the SNV alignment of the 126 included high-depth genomes using BEAST v1.6 [70] and the same model as described in Holt et al. Ten chains of 100 million iterations were combined, burn-in removed, and summarised into a MCC tree.
To generate the phylogeny of all Shigella reference genomes, E. coli reference genomes and the non-redundant set of completed E. coli genomes (S14 Table) in Fig 1A, we used panaroo v1.2 [71] to generate a core genome alignment of the genomes (using a frequency threshold of 95% to define 2,290 core genes). IQtree v2.0 [72] was used to generate a maximum likelihood phylogeny from this core genome alignment, using a GTR+F+I+G4 substitution model. E. coli clades were annotated with their Clermont phylogroup using ClermonTyper [73].
To generate phylogenies for each of the five common IS (S7 Fig), the Shigella and E. coli reference genomes (listed in S1 Table) and the non-redundant set of completed E. coli genomes (S14 Table) were screened for the five common IS using BLAST+ v2.2.30 [60]. BLAST hits with >95% identity and >90% coverage were extracted. Identical nucleotide sequences for each IS were removed, and an alignment was generated with MUSCLE v3.8.1 [74]. ML phylogenies were generated for each alignment using IQTree 1.6.12 [75] using the best-fit substitution model as selected by IQTree.
Ancestral reconstruction of IS insertion sites in S. sonnei and S. dysenteriae
The status (presence/absence) of each IS insertion site at each internal node of the dated phylogenies was inferred using maximum parsimony ancestral state reconstruction, implemented in the ancestral.pars function in the R package phangorn v2.1.1 [76]. For each IS site, the number of events inferred across the tree (either gain or loss) was then calculated as follows. For each node A where the IS insertion was inferred to be absent, but inferred as present on its parent node B, a loss event was recorded for the branch leading to node A. For each node A where the IS insertion was inferred to be present, but inferred as absent on its parent node B, a gain event was recorded for the branch leading to node A. If there was no change in the inferred IS state between node A and its parent node, then no event was recorded. These results were collated to determine the total number of gain and loss events occurring on each branch (excluding the branches directly descendant from the tree roots as these are non-separable due to lack of outgroups), across all IS insertions.
Testing for convergent gene loss compared with S. dysenteriae
Pseudogene content in S. sonnei or S. flexneri (all strains, or the subsets of strains from lineages 1 or 3) were compared with that of S. dysenteriae. We examined whether there were either (a) a significant number of pseudogenes (inactivated in at least one strain of that species) that were fixed pseudogenes in S. dysenteriae (pseudogenes in ≥90% of genomes); or (b) whether there were a significant number of pseudogenes in each species that were either fixed pseudogenes, or completely missing, in S. dysenteriae.
First, all genes were extracted from the IS-free reference genomes for each species, and RSD [77] was used to identify homologous genes (see S9 Table).
For each target species, we randomly sampled N genes (where N is the total number of pseudogenes detected in ≥1 strain) and calculated (a) the number of these genes that overlapped with the observed fixed pseudogene complement in S. dysenteriae, and (b) the number of these genes that overlapped with the observed fixed pseudogene complement in S. dysenteriae or were absent from the S. dysenteriae reference genome. We performed this random sampling 1000 times to generate two null distributions for each target species, and compared the observed values to these distribution (S11 Fig).
For genes missing in S. dysenteriae that were present in either S. sonnei or S. flexneri, these gene protein sequences were extracted and their frequency in the non-redundant set of E. coli (from Fig 1A) was determined using bi-directional BLAST hits.
Testing for functional enrichment of interrupted genes
Functional assignments for Shigella genes in each reference genome were extracted from RAST [78] annotations of each reference genome, which annotates each CDS using the SEED database. SEED is a curated database of protein families, called FIGfams, which organises genes into functional categories, subcategories and subsystems [79]. Chi-square tests were performed on each SEED category to test whether the proportion of genes within that category were enriched for inactivation across multiple Shigella species; p-values were corrected for multiple testing using FDR.
Assessing correlation between pairwise differences
To assess correlation between pairwise SNV counts vs pairwise distances in terms of IS, pseudogenes or metabolic phenotypes, we conducted Mantel tests using the mantel.test function in R package ape (v5.3), with 1000 permutations to assess significance.
Metabolic modelling
Genome-scale models of metabolism were built for each of the Shigella species based on the IS-free reference genomes, and for the three EIEC reference genomes based on their full chromosomal sequences. The iML1515 GEM of E. coli K-12 MG1655 [47] was used as a basis for reconstruction of the Shigella and EIEC reference GEMs. Bi-directional best BLAST hits (BBH) were used to detect orthologs between E. coli K-12 MG1655 and each of the genomes. A BBH with greater than 80% identity was used to assign orthologs between each organism. Genes and their corresponding reactions that were not detected above this threshold were removed from the resulting models. The resulting reference models are available in Figshare (doi:10.6084/m9.figshare.8800673.v1).
Strain-specific Shigella GEMs were created by removing genes and their corresponding reactions from the corresponding reference model, using the gene interruption matrices (incorporating IS interruptions and mutational interruptions) for each species.
Each constraints-based model consists of a stoichiometric matrix (S) with m rows and n columns, where m is the number of distinct metabolites and n is the number of reactions. Each of the n reactions has an upper and lower bound on the flux it can carry. Reversible reactions have an upper bound of 1000 mmol gDW-1 h-1 and a lower bound of -1000 mmol gDW-1 h-1, while irreversible reactions have a lower bound of zero. Flux Based Analysis (FBA) [46] can be used to identify optimal steady-state flux distributions of constraint-based models. Linear programming is used to find a solution to the equation Sv = 0 that optimizes an objective cT*v, given the set of upper and lower bound constraints. v is a vector of reaction fluxes of length n. Typically, c is a vector of 0s of length n with a 1 at the position of the reaction flux to be maximized or minimized. For all growth simulations, the core biomass reaction is set as the objective to be maximized.
Prediction of different carbon, nitrogen, phosphorus, and sulfur sources
The possible growth-supporting carbon, nitrogen, phosphorus, and sulfur sources for each model were identified using FBA. First, all exchange reactions for extracellular metabolites containing the four elements were identified from the metabolite formulas. Every extracellular compound containing carbon was considered a potential carbon source. Next, to determine possible growth supporting carbon sources, the lower bound of the glucose exchange reaction was constrained to zero. Then the lower bound of each carbon exchange reaction was set, one at a time, to -10 mmol gDW-1 h-1, and growth was maximized by FBA using the core biomass reaction. The target substrate was considered growth supporting if the predicted growth rate was above zero. While identifying carbon sources, the default nitrogen, phosphorus, and sulfur sources were ammonium (nh4), inorganic phosphate (pi), and inorganic sulfate (so4). Prediction of growth supporting sources for these other three elements was performed in the same manner as growth on carbon, with glucose as the default carbon source.
Testing for convergent phenotype loss of core E. coli metabolic phenotypes
Core E. coli metabolic phenotypes were defined as those predicted in ≥95% of the E. coli GEMS (excluding Shigella and EIEC). To assess significance of overlap between core phenotypes lost from each Shigella/EIEC clade with those lost from the most-reduced species S. dysenteriae, we first calculated the number of core phenotypes lost in each isolate and calculated the median number for each clade, Nclade (Fig 7D). We then simulated random phenotype loss by sampling without replacement, for each clade, Nclade core phenotypes and then calculating the number that overlap with the observed set of core phenotypes lost from S. dysenteriae. Random sampling was performed 1000 times for each clade, to generate a null distribution against which assess the observed overlapping phenotype loss was compared (S21 Fig).
Supporting information
Acknowledgments
The authors would like to thank Sebastian Duchêne, who helped generate the models of IS evolution in S. sonnei, found in S1 Text. The authors would also like to thank David Gordon, who generously provided the EIEC strains.
Data Availability
The IS-free Shigella reference genomes can be found in Figshare (doi: 10.26188/5c7daac90d298). The metabolic models for each reference strain can be found in Figshare (doi:10.6084/m9.figshare.8800673.v1).
Funding Statement
KEH was supported by the Bill and Melinda Gates Foundation (OPP1175797) and the Sylvia and Charles Viertel Charitable Foundation (Senior Medical Research Fellowship). JMM and BP were supported by Grant 1-U01-AI124316 from the NIH NIAID. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
References
- 1.Kotloff KL, Winickoff JP, Ivanoff B. Global burden of Shigella infections: implications for vaccine development and implementation of control strategies. Bulletin of the World Health Organization. 1999;77: 651 666. [PMC free article] [PubMed] [Google Scholar]
- 2.Neter E. THE GENUS SHIGELLA: (Dysentery Bacilli and Allied Species). Bacteriol Rev. 1942;6: 1–36. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 3.O’Loughlin EV, Robins-Browne RM. Effect of Shiga toxin and Shiga-like toxins on eukaryotic cells. Microbes and Infection. 2001;3: 493 507. 10.1016/s1286-4579(01)01405-8 [DOI] [PubMed] [Google Scholar]
- 4.Rolland K, Lambert-Zechovsky N, Picard B, Denamur E. Shigella and enteroinvasive Escherichia coli strains are derived from distinct ancestral strains of E. coli. Microbiology+. 1998;144: 2667 2672. 10.1099/00221287-144-9-2667 [DOI] [PubMed] [Google Scholar]
- 5.Pupo GM, Lan R, Reeves PR. Multiple independent origins of Shigella clones of Escherichia coli and convergent evolution of many of their characteristics. Proc National Acad Sci. 2000;97: 10567 10572. 10.1073/pnas.180094797 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 6.The HC, Thanh DP, Holt KE, Thomson NR, Baker S. The genomic signatures of Shigella evolution, adaptation and geographical spread. Nat Rev Microbiol. 2016;14: 235 250. 10.1038/nrmicro.2016.10 [DOI] [PubMed] [Google Scholar]
- 7.Sahl JW, Morris CR, Emberger J, Fraser CM, Ochieng JB, Juma J, et al. Defining the Phylogenomics of Shigella Species: a Pathway to Diagnostics. Ledeboer NA, editor. J Clin Microbiol. 2015;53: 951 960. 10.1128/JCM.03527-14 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 8.Yang J, Nie H, Chen L, Zhang X, Yang F, Xu X, et al. Revisiting the molecular evolutionary history of Shigella spp. J Mol Evol. 2007;64: 71 79. 10.1007/s00239-006-0052-8 [DOI] [PubMed] [Google Scholar]
- 9.Sansonetti PJ, Kopecko DJ, Formal SB. Involvement of a plasmid in the invasive ability of Shigella flexneri. Infection and Immunity. 1982;35: 852 860. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.Al-Hasani K, Henderson IR, Sakellaris H, Rajakumar K, Grant T, Nataro JP, et al. The sigA gene which is borne on the she pathogenicity island of Shigella flexneri 2a encodes an exported cytopathic protease involved in intestinal fluid accumulation. Infect Immun. 2000;68: 2457 2463. 10.1128/iai.68.5.2457-2463.2000 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 11.Andersson SGE, Kurland CG. Reductive evolution of resident genomes. Trends Microbiol. 1998;6: 263 268. 10.1016/s0966-842x(98)01312-2 [DOI] [PubMed] [Google Scholar]
- 12.Moran NA, Plague GR. Genomic changes following host restriction in bacteria. Curr Opin Genet Dev. 2004;14: 627 633. 10.1016/j.gde.2004.09.003 [DOI] [PubMed] [Google Scholar]
- 13.Cole ST, Eiglmeier K, Parkhill J, James KD, Thomson NR, Wheeler PR, et al. Massive gene decay in the leprosy bacillus. Nature. 2001;409: 1007 1011. 10.1038/35059006 [DOI] [PubMed] [Google Scholar]
- 14.Parkhill J, Sebaihia M, Preston A, Murphy LD, Thomson N, Harris DE, et al. Comparative analysis of the genome sequences of Bordetella pertussis, Bordetella parapertussis and Bordetella bronchiseptica. Nat Genet. 2003;35: 32 40. 10.1038/ng1227 [DOI] [PubMed] [Google Scholar]
- 15.Yang F, Yang J, Zhang X, Chen L, Jiang Y, Yan Y, et al. Genome dynamics and diversity of Shigella species, the etiologic agents of bacillary dysentery. Nucleic Acids Res. 2005;33: 6445 6458. 10.1093/nar/gki954 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 16.Ramos HC, Rumbo M, Sirard J-C. Bacterial flagellins: mediators of pathogenicity and host immune responses in mucosa. Trends Microbiol. 2004;12: 509 517. 10.1016/j.tim.2004.09.002 [DOI] [PubMed] [Google Scholar]
- 17.Bergsten G, Wullt B, Svanborg C. Escherichia coli, fimbriae, bacterial persistence and host response induction in the human urinary tract. Int J Med Microbiol. 2005;295: 487 502. 10.1016/j.ijmm.2005.07.008 [DOI] [PubMed] [Google Scholar]
- 18.Prosseda G, Martino MLD, Campilongo R, Fioravanti R, Micheli G, Casalino M, et al. Shedding of genes that interfere with the pathogenic lifestyle: the Shigella model. Res Microbiol. 2012;163: 399 406. 10.1016/j.resmic.2012.07.004 [DOI] [PubMed] [Google Scholar]
- 19.Mantis NJ, Sansonetti PJ. The nadB gene of Salmonella typhimurium complements the nicotinic acid auxotrophy of Shigella flexneri. Mol Gen Genetics Mgg. 1996;252: 626 629. 10.1007/BF02172409 [DOI] [PubMed] [Google Scholar]
- 20.Prunier A-L, Schuch R, Fernández RE, Mumy KL, Kohler H, McCormick BA, et al. nadA and nadB of Shigella flexneri 5a are antivirulence loci responsible for the synthesis of quinolinate, a small molecule inhibitor of Shigella pathogenicity. Microbiology+. 2007;153: 2363 2372. 10.1099/mic.0.2007/006916-0 [DOI] [PubMed] [Google Scholar]
- 21.Barbagallo M, Martino MLD, Marcocci L, Pietrangeli P, Carolis ED, Casalino M, et al. A new piece of the Shigella pathogenicity puzzle: spermidine accumulation by silencing of the speG gene. Adler B, editor. Plos One. 2011;6: e27226 10.1371/journal.pone.0027226 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 22.Siguier P, Gourbeyre E, Varani A, Ton-Hoang B, Chandler M. Everyman’s guide to bacterial insertion sequences. Microbiol Spectr. 2015;3 10.1128/microbiolspec.mdna3-0030-2014 [DOI] [PubMed] [Google Scholar]
- 23.Amman F, D’Halluin A, Antoine R, Huot L, Bibova I, Keidel K, et al. Primary transcriptome analysis reveals importance of IS elements for the shaping of the transcriptional landscape of Bordetella pertussis. Rna Biol. 2018;15: 967–975. 10.1080/15476286.2018.1462655 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 24.Livio S, Strockbine NA, Panchalingam S, Tennant SM, Barry EM, Marohn ME, et al. Shigella isolates from the global enteric multicenter study inform vaccine development. Clin Infect Dis. 2014;59: 933 941. 10.1093/cid/ciu468 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 25.Connor TR, Barker CR, Baker KS, Weill F-X, Talukder KA, Smith AM, et al. Species-wide whole genome sequencing reveals historical global spread and recent local persistence in Shigella flexneri. Tautz D, editor. Elife. 2015;4: e07335 10.7554/eLife.07335 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 26.Njamkepo E, Fawal N, Tran-Dien A, Hawkey J, Strockbine N, Jenkins C, et al. Global phylogeography and evolutionary history of Shigella dysenteriae type 1. Nat Microbiol. 2016;1: 16027 10.1038/nmicrobiol.2016.27 [DOI] [PubMed] [Google Scholar]
- 27.Holt KE, Baker S, Weill F-X, Holmes EC, Kitchen A, Yu J, et al. Shigella sonnei genome sequencing and phylogenetic analysis indicate recent global dissemination from Europe. Nat Genet. 2012;44: 1056 1059. 10.1038/ng.2369 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 28.Thompson CN, Duy PT, Baker S. The Rising Dominance of Shigella sonnei: An Intercontinental Shift in the Etiology of Bacillary Dysentery. Plos Neglect Trop D. 2015;9: e0003708 10.1371/journal.pntd.0003708 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29.Holt KE, Nga TVT, Thanh DP, Vinh H, Kim DW, Tra MPV, et al. Tracking the establishment of local endemic populations of an emergent enteric pathogen. Proc National Acad Sci. 2013;110: 17522 17527. 10.1073/pnas.1308632110 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 30.Kania DA, Hazen TH, Hossain A, Nataro JP, Rasko DA. Genome diversity of Shigella boydii. Thomson N, editor. Pathog Dis. 2016;74: ftw027 10.1093/femspd/ftw027 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 31.Hawkey J, Hamidian M, Wick RR, Edwards DJ, Billman-Jacobe H, Hall RM, et al. ISMapper: identifying transposase insertion sites in bacterial genomes from short read sequence data. Bmc Genomics. 2015;16: 667 10.1186/s12864-015-1860-2 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 32.Sansonetti PJ, Kopecko DJ, Formal SB. Shigella sonnei plasmids: evidence that a large plasmid is necessary for virulence. Infection and Immunity. 1981;34: 75 83. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 33.Duchêne S, Holt KE, Weill F-X, Hello SL, Hawkey J, Edwards DJ, et al. Genome-scale rates of evolutionary change in bacteria. Microb Genom. 2016;2 10.1099/mgen.0.000094 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 34.Petty NK, Zakour NLB, Stanton-Cook M, Skippington E, Totsika M, Forde BM, et al. Global dissemination of a multidrug resistant Escherichia coli clone. Proc National Acad Sci. 2014;111: 5694 5699. 10.1073/pnas.1322678111 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 35.Williamson DA, Roberts SA, Paterson DL, Sidjabat H, Silvey A, Masters J, et al. Escherichia coli Bloodstream Infection After Transrectal Ultrasound–Guided Prostate Biopsy: Implications of Fluoroquinolone-Resistant Sequence Type 131 as a Major Causative Pathogen. Clin Infect Dis. 2012;54: 1406–1412. 10.1093/cid/cis194 [DOI] [PubMed] [Google Scholar]
- 36.Rogers BA, Kennedy KJ, Sidjabat HE, Jones M, Collignon P, Paterson DL. Prolonged carriage of resistant E. coli by returned travellers: clonality, risk factors and bacterial characteristics. Eur J Clin Microbiol. 2012;31: 2413–2420. 10.1007/s10096-012-1584-z [DOI] [PubMed] [Google Scholar]
- 37.Peirano G, Bij AK van der, Gregson DB, Pitout JDD. Molecular Epidemiology over an 11-Year Period (2000 to 2010) of Extended-Spectrum β-Lactamase-Producing Escherichia coli Causing Bacteremia in a Centralized Canadian Region. J Clin Microbiol. 2012;50: 294–299. 10.1128/JCM.06025-11 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 38.Pitout JDD, Church DL, Gregson DB, Chow BL, McCracken M, Mulvey MR, et al. Molecular Epidemiology of CTX-M-Producing Escherichia coli in the Calgary Health Region: Emergence of CTX-M-15-Producing Isolates▿. Antimicrob Agents Ch. 2007;51: 1281–1286. 10.1128/aac.01377-06 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 39.Rohde H, Qin J, Cui Y, Li D, Loman NJ, Hentschke M, et al. Open-Source Genomic Analysis of Shiga-Toxin–Producing E. coli O104:H4. New Engl J Medicine. 2011;365: 718 724. 10.1056/nejmoa1107643 [DOI] [PubMed] [Google Scholar]
- 40.Ingle DJ, Valcanis M, Kuzevski A, Tauschek M, Inouye M, Stinear T, et al. In silico serotyping of E. coli from short read data identifies limited novel O-loci but extensive diversity of O:H serotype combinations within and between pathogenic lineages. Microb Genom. 2016;2 10.1099/mgen.0.000064 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 41.Cowley LA, Oresegun DR, Chattaway MA, Dallman TJ, Jenkins C. Phylogenetic comparison of enteroinvasive Escherichia coli isolated from cases of diarrhoeal disease in England, 2005–2016. J Med Microbiol. 2018; 10.1099/jmm.0.000739 [DOI] [PubMed] [Google Scholar]
- 42.Wagner A, Chaux N de la. Distant horizontal gene transfer is rare for multiple families of prokaryotic insertion sequences. Mol Genet Genomics. 2008;280: 397–408. 10.1007/s00438-008-0373-y [DOI] [PubMed] [Google Scholar]
- 43.Iranzo J, Gómez MJ, Saro FJL de, Manrubia S. Large-scale genomic analysis suggests a neutral punctuated dynamics of transposable elements in bacterial genomes. Plos Comput Biol. 2014;10: e1003680 10.1371/journal.pcbi.1003680 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 44.Monk JM, Charusanti P, Aziz RK, Lerman JA, Premyodhin N, Orth JD, et al. Genome-scale metabolic reconstructions of multiple Escherichia coli strains highlight strain-specific adaptations to nutritional environments. Proc National Acad Sci. 2013;110: 20338 20343. 10.1073/pnas.1307797110 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 45.Bosi E, Monk JM, Aziz RK, Fondi M, Nizet V, Palsson BØ. Comparative genome-scale modelling of Staphylococcus aureus strains identifies strain-specific metabolic capabilities linked to pathogenicity. Proc National Acad Sci. 2016;113: E3801 9. 10.1073/pnas.1523199113 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 46.Orth JD, Thiele I, Palsson BØ. What is flux balance analysis? Nat Biotechnol. 2010;28: 245 248. 10.1038/nbt.1614 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 47.Monk JM, Lloyd CJ, Brunk E, Mih N, Sastry A, King Z, et al. iML1515, a knowledgebase that computes Escherichia coli traits. Nat Biotechnol. 2017;35: 904 908. 10.1038/nbt.3956 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 48.Anderson M, Sansonetti PJ, Marteyn BS. Shigella Diversity and Changing Landscape: Insights for the Twenty-First Century. Front Cell Infect Mi. 2016;6: 45 10.3389/fcimb.2016.00045 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 49.Ingle DJ, Easton M, Valcanis M, Seemann T, Kwong JC, Stephens N, et al. Co-circulation of Multidrug-resistant Shigella Among Men Who Have Sex With Men in Australia. Clin Infect Dis. 2019; 10.1093/cid/ciz005 [DOI] [PubMed] [Google Scholar]
- 50.Bardsley M, Jenkins C, Mitchell HD, Mikhail AFW, Baker KS, Foster K, et al. Persistent transmission of shigellosis in England is associated with a recently emerged multi-drug resistant strain of Shigella sonnei. J Clin Microbiol. 2020; 10.1128/jcm.01692-19 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 51.Li P, Jiang W, Yu Q, Liu W, Zhou P, Li J, et al. Ubiquitination and degradation of GBPs by a Shigella effector to suppress host defence. Nature. 2017;551: 378–383. 10.1038/nature24467 [DOI] [PubMed] [Google Scholar]
- 52.Baker KS, Dallman TJ, Field N, Childs T, Mitchell H, Day M, et al. Genomic epidemiology of Shigella in the United Kingdom shows transmission of pathogen sublineages and determinants of antimicrobial resistance. Sci Rep-uk. 2018;8: 7389 10.1038/s41598-018-25764-3 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 53.Doig KD, Holt KE, Fyfe JAM, Lavender CJ, Eddyani M, Portaels F, et al. On the origin of Mycobacterium ulcerans, the causative agent of Buruli ulcer. Bmc Genomics. 2012;13: 258 10.1186/1471-2164-13-258 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 54.Roychowdhury T, Mandal S, Bhattacharya A. Analysis of IS6110 insertion sites provide a glimpse into genome evolution of Mycobacterium tuberculosis. Sci Rep-uk. 2015;5: 12567 10.1038/srep12567 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 55.Hamidian M, Hawkey J, Wick R, Holt KE, Hall RM. Evolution of a clade of Acinetobacter baumannii global clone 1, lineage 1 via acquisition of carbapenem- and aminoglycoside-resistance genes and dispersion of ISAba1. Microb Genom. 2019;5 10.1099/mgen.0.000242 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 56.Adams MD, Bishop B, Wright MS. Quantitative assessment of insertion sequence impact on bacterial genome architecture. Microb Genom. 2016;2 10.1099/mgen.0.000062 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 57.Nunvar J, Capek V, Fiser K, Fila L, Drevinek P. What matters in chronic Burkholderia cenocepacia infection in cystic fibrosis: Insights from comparative genomics. Plos Pathog. 2017;13: e1006762 10.1371/journal.ppat.1006762 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 58.Varani AM, Siguier P, Gourbeyre E, Charneau V, Chandler M. ISsaga is an ensemble of web-based methods for high throughput identification and semi-automatic annotation of insertion sequences in prokaryotic genomes. Genome Biol. 2011;12: R30 10.1186/gb-2011-12-3-r30 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 59.Siguier P, Perochon J, Lestrade L, Mahillon J, Chandler M. ISfinder: the reference centre for bacterial insertion sequences. Nucleic Acids Res. 2006;34: D32 6. 10.1093/nar/gkj014 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 60.Camacho C, Coulouris G, Avagyan V, Ma N, Papadopoulos J, Bealer K, et al. BLAST+: architecture and applications. Bmc Bioinformatics. 2009;10: 421 10.1186/1471-2105-10-421 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 61.Wattam AR, Abraham D, Dalay O, Disz TL, Driscoll T, Gabbard JL, et al. PATRIC, the bacterial bioinformatics database and analysis resource. Nucleic Acids Research. 2014; [DOI] [PMC free article] [PubMed] [Google Scholar]
- 62.Carver T, Harris SR, Berriman M, Parkhill J, McQuillan JA. Artemis: an integrated platform for visualization and analysis of high-throughput sequence-based experimental data. Bioinformatics. 2012;28: 464–469. 10.1093/bioinformatics/btr703 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 63.Otto TD, Dillon GP, Degrave WS, Berriman M. RATT: Rapid Annotation Transfer Tool. Nucleic Acids Res. 2011;39: gkq1268 e57. 10.1093/nar/gkq1268 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 64.Wick RR, Judd LM, Gorrie CL, Holt KE. Completing bacterial genome assemblies with multiplex MinION sequencing. Microb Genom. 2017;3: e000132 10.1099/mgen.0.000132 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 65.Wick RR, Judd LM, Gorrie CL, Holt KE. Unicycler: Resolving bacterial genome assemblies from short and long sequencing reads. Plos Comput Biol. 2017;13: e1005595 10.1371/journal.pcbi.1005595 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 66.Langmead B, Salzberg SL. Fast gapped-read alignment with Bowtie 2. Nat Methods. 2012;9: 357 359. 10.1038/nmeth.1923 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 67.Li H, Handsaker B, Wysoker A, Fennell T, Ruan J, Homer N, et al. The Sequence Alignment/Map format and SAMtools. Bioinformatics. 2009;25: 2078 2079. 10.1093/bioinformatics/btp352 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 68.Zhou Y, Liang Y, Lynch KH, Dennis JJ, Wishart DS. PHAST: A Fast Phage Search Tool. Nucleic Acids Res. 2011;39: W347 W352. 10.1093/nar/gkr485 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 69.Stamatakis A. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics. 2014;30: 1312 1313. 10.1093/bioinformatics/btu033 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 70.Drummond AJ, Rambaut A. BEAST: Bayesian evolutionary analysis by sampling trees. Bmc Evol Biol. 2007;7: 214 10.1186/1471-2148-7-214 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 71.Tonkin-Hill G, MacAlasdair N, Ruis C, Weimann A, Horesh G, Lees JA, et al. Producing Polished Prokaryotic Pangenomes with the Panaroo Pipeline. Biorxiv. 2020; 2020January28922989 10.1101/2020.01.28.922989 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 72.Minh BQ, Schmidt HA, Chernomor O, Schrempf D, Woodhams MD, Haeseler A von, et al. IQ-TREE 2: New Models and Efficient Methods for Phylogenetic Inference in the Genomic Era. Mol Biol Evol. 2020; 10.1093/molbev/msaa015 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 73.Beghain J, Bridier-Nahmias A, Nagard H, Denamur E, Clermont O. ClermonTyping: an easy-to-use and accurate in silico method for Escherichia genus strain phylotyping. Microb Genom. 2018;4 10.1099/mgen.0.000192 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 74.Edgar RC. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Research. 2004; [DOI] [PMC free article] [PubMed] [Google Scholar]
- 75.Nguyen L, Schmidt H, Haeseler A, Minh B. IQ-TREE: A Fast and Effective Stochastic Algorithm for Estimating Maximum-Likelihood Phylogenies. Mol Biol Evol. 2015;32: 268–274. 10.1093/molbev/msu300 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 76.Schliep KP. phangorn: phylogenetic analysis in R. Bioinformatics. 2011;27: 592 593. 10.1093/bioinformatics/btq706 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 77.Wall DP, Fraser HB, Hirsh AE. Detecting putative orthologs. Bioinformatics. 2003;19: 1710 1711. 10.1093/bioinformatics/btg213 [DOI] [PubMed] [Google Scholar]
- 78.Aziz RK, Bartels D, Best AA, DeJongh M, Disz T, Edwards RA, et al. The RAST Server: Rapid Annotations using Subsystems Technology. Bmc Genomics. 2008;9: 75 10.1186/1471-2164-9-75 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 79.Overbeek R, Olson R, Pusch GD, Olsen GJ, Davis JJ, Disz T, et al. The SEED and the Rapid Annotation of microbial genomes using Subsystems Technology (RAST). Nucleic Acids Res. 2014;42: D206 14. 10.1093/nar/gkt1226 [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The IS-free Shigella reference genomes can be found in Figshare (doi: 10.26188/5c7daac90d298). The metabolic models for each reference strain can be found in Figshare (doi:10.6084/m9.figshare.8800673.v1).