Pushing the limits of de novo genome assembly for complex prokaryotic genomes harboring very long, near identical repeats

Schmid, Michael; Frei, Daniel; Patrignani, Andrea; Schlapbach, Ralph; Frey, Jürg E.; Remus-Emsermann, Mitja N. P.; Ahrens, Christian H.

doi:10.1093/nar/gky726

Cited by 86 publications

(90 citation statements)

References 62 publications

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“…The association of key adaptive traits with duplicated regions has also been reported for the p1 megaplasmid-carrying Pseudomonas koreensis strain P19E3 (64) , with genes encoding heavy metal resistance, aromatic compound degradation, and DNA repair occurring within large repeats in the genome. Consistent with our observations, repetitive genes in p1 were identified close to transposase and phage genes suggesting a key role for mobile elements like transposons in shaping these large genome duplications (64) .…”

Section: Discussionsupporting

confidence: 90%

“…The pRB16 megaplasmid was identified in P. citronellolis SJTE-3, an estrogen and polycyclic aromatic hydrocarbon degrading bacterium isolated from active sludge at a wastewater treatment plant in China (75) . P. koreensis P19E3, harbouring the megaplasmid p1, was isolated from healthy marjoram ( Origanum marjorana ) leaf material during an isolation survey on an organic herb farm (Boppelsen, Switzerland) in 2014 (64) . The presence on p1 of a cluster of genes encoding copper resistance suggests that whilst members of the megaplasmid family share a common backbone, they are flexible in the adaptive traits that they carry.…”

Section: Discussionmentioning

confidence: 99%

“…Rarefaction and accumulation curves, used to estimate the core and pan-genome size of the megaplasmid family, were indicative of an open pan-genome with a well-defined core, and suggested that the addition of more genomes was unlikely to impact much further on the size of the core genome ( Figure 3). Further analysis was carried out to distinguish between the strict core genome (present in all 15 megaplasmids), and other pan-genome compartments (40) (Figure 4, Supplementary Figure S5), indicating that the greatest number of gene clusters corresponded to unique, or nearly unique genes, but with numbers varying between the different megaplasmids from only one to 93 unique genes (Supplementary Figure S5, Supplementary Table 4), the latter being found in plasmid p1, a plasmid present in a P. koreensis isolate from healthy marjoram leaf material (64) . Genes unique to plasmid p1 include a large cluster related to copper resistance and catabolic genes for the conversion of 4-hydroxy benzoate ( pobA , phbH ), or vanillate ( vanA , vanB , iacF , vanK ) to protocatechuate, which can then be metabolised to central metabolism intermediates via the β-ketoadipate pathway.…”

Section: Core Genome and Pan-genome Analysis Of The Pbt2436-like Megamentioning

confidence: 99%

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A megaplasmid family responsible for dissemination of multidrug resistance inPseudomonas

Cazares

Moore

Grimes

et al. 2019

Preprint

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Multidrug resistance (MDR) represents a global threat to health. Although plasmids can play an important role in the dissemination of MDR, they have not been commonly linked to the emergence of antimicrobial resistance in the pathogen Pseudomonas aeruginosa . We used whole genome sequencing to characterize a collection of P. aeruginosa clinical isolates from a hospital in Thailand. Using long-read sequence data we obtained complete sequences of two closely related megaplasmids (>420 kb) carrying large arrays of antibiotic resistance genes located in discrete, complex and dynamic resistance regions, and revealing evidence of extensive duplication and recombination events. A comprehensive pangenomic and phylogenomic analysis indicated that 1) these large plasmids comprise a family present in different members of the Pseudomonas genus and associated with multiple sources (geographical, clinical or environmental); 2) the megaplasmids encode diverse niche-adaptive accessory traits, including multidrug resistance; 3) the pangenome of the megaplasmid family is highly flexible and diverse, comprising a substantial core genome (average of 48% of plasmid genes), but with individual members carrying large numbers of unique genes. The history of the megaplasmid family, inferred from our analysis of the available database, suggests that members carrying multiple resistance genes date back to at least the 1970s.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: Core Genome and Pan-genome Analysis Of The Pbt2436-like Megamentioning

confidence: 99%

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A megaplasmid family responsible for dissemination of multidrug resistance inPseudomonas

Cazares

Moore

Grimes

et al. 2019

Preprint

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Section: Complete Genome Sequences Of Egd-e and Scotta And Comparativmentioning

confidence: 99%

“…An analysis of the repeat complexity of all publicly available, completely sequenced genomes of L. monocytogenes strains (status: March, 2018) revealed that almost 95% of the roughly 150 strains are so-called "class I" genomes, which are straightforward to assemble (few repeats, none longer than the rDNA operons of up to 7 kb) [17]. In contrast, eight strains also had few repeats overall, but those present were up to 11 kb in length [17]. Using long-read Pacific Biosciences (PacBio) sequencing data (including a BluePippin size selection step; see Materials and Methods) and the assembly algorithm HGAP3 [50], we were able to de novo assemble one complete chromosome for EGD-e (2.94 Mbp) and one for ScottA (3.03 Mbp) with PacBio read coverages of 260x and 280x, respectively (Fig 2).…”

Section: Complete Genome Sequences Of Egd-e and Scotta And Comparativmentioning

confidence: 99%

A proteogenomic resource enabling integrated analysis ofListeriagenotype-proteotype-phenotype relationships

Varadarajan

Pavlou

Goetze

et al. 2019

Preprint

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Listeria monocytogenes is an opportunistic foodborne pathogen responsible for listeriosis, a potentially fatal foodborne disease. Many different Listeria strains and serotypes exist, but a proteogenomic resource that bridges the gap in our molecular understanding of the relationships between the Listeria genotypes and phenotypes via proteotypes is still missing. Here we devised a next-generation proteogenomics strategy that enables the community to rapidly proteotypeListeria strains and relate this information back to the genotype. Based on sequencing and de novo assembly of the two most commonly used Listeria model strains, EGD-e and ScottA, we established two comprehensive Listeria proteogenomic databases. A genome comparison established core-and strain-specific genes potentially responsible for virulence differences. Next, we established a DIA/SWATH-based proteotyping strategy, including a new and robust sample preparation workflow, that enables the reproducible, sensitive, and relative quantitative measurement of Listeria proteotypes. This reusable and publically available DIA/SWATH library covers 70% of open reading frames of Listeria and represents the most extensive spectral library for Listeria proteotype analysis to date. We used these two new resources to investigate the Listeria proteotype in states mimicking the upper gastrointestinal passage. Exposure of Listeria to bile salts at 37 o C, which simulates conditions encountered in the duodenum, showed significant proteotype perturbations including an increase of FlaA, the structural protein of flagella. Given that Listeria is known to lose its flagella above 30 o C, this was an unexpected finding. The formation of flagella, which might have implications on infectivity, was validated by parallel reaction monitoring and light and scanning electron microscopy. flaA transcript levels were not significantly different with and without exposure to bile salts at 37 o C, suggesting regulation at the post-transcriptional level. Together, these analyses provide a comprehensive proteogenomic resource and toolbox for the Listeria community enabling the analysis of Listeria genotype-proteotype-phenotype relationships.[5], among these three (1/2a, 1/2b, and 4b) are responsible for the majority of clinical cases. EGDe, a widely used model system of serotype 1/2a, is the serotype most frequently recovered from foods or food-processing plants. In contrast, ScottA is a widely used model system of serotype 4b, which causes the majority of human epidemics [5]. Infection by L. monocytogenes usually occurs after digestion of contaminated foods and in individuals with impaired cell-mediated immunity. The elderly, immunosuppressed patients, pregnant women, and neonates are particularly susceptible [2]. An infection may lead to meningitis, sepsis, or, by crossing the placenta, infection of the fetus and subsequent abortion [5]. Upon ingestion, L. monocytogenes must resist multiple stresses encountered in the gastrointestinal (GI) tract, including variation in pH, osmolarity, an...

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Structure and Evolution of Diatom Nuclear Genes and Genomes

Möck

Hodgkinson

et al. 2022

The Molecular Life of Diatoms

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Pushing the limits of de novo genome assembly for complex prokaryotic genomes harboring very long, near identical repeats

Cited by 86 publications

References 62 publications

A megaplasmid family responsible for dissemination of multidrug resistance inPseudomonas

A megaplasmid family responsible for dissemination of multidrug resistance inPseudomonas

A proteogenomic resource enabling integrated analysis ofListeriagenotype-proteotype-phenotype relationships

Structure and Evolution of Diatom Nuclear Genes and Genomes

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