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. 2014 Jun 17;5(3):e01305-14.
doi: 10.1128/mBio.01305-14.

Evidence of extensive DNA transfer between bacteroidales species within the human gut

Michael J Coyne  1 Naamah Levy Zitomersky  2 Abigail Manson McGuire  3 Ashlee M Earl  3 Laurie E Comstock  4
Affiliations

Evidence of extensive DNA transfer between bacteroidales species within the human gut

Michael J Coyne et al. mBio. .

Abstract

The genome sequences of intestinal Bacteroidales strains reveal evidence of extensive horizontal gene transfer. In vitro studies of Bacteroides and other bacteria have addressed mechanisms of conjugative transfer and some phenotypic outcomes of these DNA acquisitions in the recipient, such as the acquisition of antibiotic resistance. However, few studies have addressed the horizontal transfer of genetic elements between bacterial species coresident in natural microbial communities, especially microbial ecosystems of humans. Here, we examine the genomes of Bacteroidales species from two human adults to identify genetic elements that were likely transferred among these Bacteroidales while they were coresident in the intestine. Using seven coresident Bacteroidales species from one individual and eight from another, we identified five large chromosomal regions, each present in a minimum of three of the coresident strains at near 100% DNA identity. These five regions are not found in any other sequenced Bacteroidetes genome at this level of identity and are likely all integrative conjugative elements (ICEs). Such highly similar and unique regions occur in only 0.4% of phylogenetically representative mock communities, providing strong evidence that these five regions were transferred between coresident strains in these subjects. In addition to the requisite proteins necessary for transfer, these elements encode proteins predicted to increase fitness, including orphan DNA methylases that may alter gene expression, fimbriae synthesis proteins that may facilitate attachment and the utilization of new substrates, putative secreted antimicrobial molecules, and a predicted type VI secretion system (T6SS), which may confer a competitive ecological advantage to these strains in their complex microbial ecosystem.

Importance: By analyzing Bacteroidales strains coresident in the gut microbiota of two human adults, we provide strong evidence for extensive interspecies and interfamily transfer of integrative conjugative elements within the intestinal microbiota of individual humans. In the recipient strain, we show that the conjugative elements themselves can be modified by the transposition of insertion sequences and retroelements from the recipient's genome, with subsequent transfer of these modified elements to other members of the microbiota. These data suggest that the genomes of our gut bacteria are substantially modified by other, coresident members of the ecosystem, resulting in highly personalized Bacteroidales strains likely unique to that individual. The genetic content of these ICEs suggests that their transfer from successful adapted members of an ecosystem confers beneficial properties to the recipient, increasing its fitness and allowing it to better compete within its particular personalized gut microbial ecosystem.

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Figures

FIG 1
FIG 1
Comparisons of regions 1 to 5 in the three or four genomes containing these MGEs. Differences between strains for each region following sequencing to resolve Ns are shown. The remaining SNPs displayed were not tested by sequencing and represent the original genome sequence for each isolate. The positions of IS and RE in regions 1 and 2 are shown with the corresponding sizes of these elements.
FIG 2
FIG 2
Open reading frame (ORF) maps of regions 1 to 5. Regions are oriented so that the majority of the tra genes (red) read left to right. The letter above the red genes indicates the particular tra gene. An open reading frame map, excluding variable IS and RE, is shown for each region, with the locations of IS and RE indicated. Genes encoding selective orthologous proteins present in each region are color coded as indicated above. Genes comprising the type VI secretion system (T6SS) of region 2 are shown (blue). The 24,866-bp region 1 (boxed) and the 17,607-bp region 3 (boxed) are extended to show the likely extent of the MGEs that were transferred between strains.
FIG 3
FIG 3
Likely extent of the MGEs containing regions 1 and 3. Boxed regions are the extent of regions 1 and 3 identified by the indicated BLAST criteria. (A) Expansion of region 1 in two of the three genomes. (B) Expansion of region 3 based on smaller matching scaffolds in each of the two genomes that are noncontiguous with the region from P. merdae.
FIG 4
FIG 4
ORF map of portion of region 2, encoding a putative T6SS. Genes encoding proteins characteristic of or commonly associated with T6SS are color coded as indicated below. These designations are based on the analyses as outlined in Table S6 in the supplemental material. The putative functions of all gene products encoded by the genes shown here are included in Table S6.
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