Clades of huge phages from across Earth’s ecosystems

Al-Shayeb, Basem; Sachdeva, Rohan; Chen, Lin-Xing; Ward, Fred R.; Munk, Patrick; Devoto, Audra E.; Castelle, Cindy J.; Olm, Matthew R.; Bouma‐Gregson, Keith; Amano, Yuki; He, Christine; Méheust, Raphaël; Brooks, Brandon; Thomas, Alex D.; Lavy, Adi; Carnevali, Paula B. Matheus; Sun, Christine; Goltsman, Daniela S. Aliaga; Borton, Mikayla A.; Sharrar, Allison; Jaffe, Alexander L.; Nelson, Tara Colenbrander; Kantor, Rose; Keren, Ray; Lane, Katherine R.; Farag, Ibrahim; Lei, Shufei; Finstad, Kari; Amundson, R.; Anantharaman, Karthik; Zhou, Jizhong; Probst, Alexander J.; Power, Mary E.; Tringe, Susannah G.; Li, Wenjun; Wrighton, Kelly; Harrison, Susan T.L.; Morowitz, Michael J.; Relman, David A.; Doudna, Jennifer A.; Lehours, Anne‐Catherine; Warren, Lesley A.; Cate, Jamie H. D.; Santini, Joanne M.; Banfield, Jillian F.

doi:10.1038/s41586-020-2007-4

Cited by 362 publications

(419 citation statements)

References 85 publications

(75 reference statements)

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“…Another seemingly rare error involves the artificial concatenation of an identical sequence, sometimes of hundreds of base pairs in length, repeated up to (or more than) three times. This has been a problem with some sequences of seemingly large phage deposited in public databases, as discussed by Devoto et al (2019) and Al-Shayeb et al (2020). This phenomenon is easily identified by running a repeat finder, a step that should also be included in the curation to completion pipeline (see below).…”

Section: Genome Curation: Filling Scaffolding Gaps and Removal Of Locmentioning

confidence: 99%

Accurate and complete genomes from metagenomes

et al. 2020

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Genomes are an integral component of the biological information about an organism; thus, the more complete the genome, the more informative it is. Historically, bacterial and archaeal genomes were reconstructed from pure (monoclonal) cultures, and the first reported sequences were manually curated to completion. However, the bottleneck imposed by the requirement for isolates precluded genomic insights for the vast majority of microbial life. Shotgun sequencing of microbial communities, referred to initially as community genomics and subsequently as genome-resolved metagenomics, can circumvent this limitation by obtaining metagenome-assembled genomes (MAGs); but gaps, local assembly errors, chimeras, and contamination by fragments from other genomes limit the value of these genomes. Here, we discuss genome curation to improve and, in some cases, achieve complete (circularized, no gaps) MAGs (CMAGs). To date, few CMAGs have been generated, although notably some are from very complex systems such as soil and sediment. Through analysis of about 7000 published complete bacterial isolate genomes, we verify the value of cumulative GC skew in combination with other metrics to establish bacterial genome sequence accuracy. The analysis of cumulative GC skew identified potential misassemblies in some reference genomes of isolated bacteria and the repeat sequences that likely gave rise to them. We discuss methods that could be implemented in bioinformatic approaches for curation to ensure that metabolic and evolutionary analyses can be based on very high-quality genomes.

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Section: Genome Curation: Filling Scaffolding Gaps and Removal Of Locmentioning

confidence: 99%

Accurate and complete genomes from metagenomes

et al. 2020

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“…For the first time in oral microbiota publications, we discovered six phages with genomes larger than 200 kb (Fig. S6, Table 1), that were classified as jumbo, and had been rarely found but recently began to be identified across Earth’s ecosystems (37, 38). We also discovered five jumbo (>200 kb) prophages.…”

Section: Resultsmentioning

confidence: 99%

“…3), and identified as much as ten jumbo oral phages/prophages (including the plasmid-like element) in an oral environment, significantly increasing our knowledge about “who is there” in the human oral cavity. Such jumbo phages were previously found among approximately 20 host bacterial genus (38, 46, 47) and recently began to be identified across Earth’s ecosystems (37). However, so far, there is no publication of those in the human oral cavity.…”

Section: Discussionmentioning

confidence: 99%

Long-read shotgun metagenome sequencing using PromethION uncovers novel bacteriophages, their abundance, and interaction with host bacterial immunity in the oral microbiota

Yahara

Suzuki

Hirabayashi

et al. 2020

Preprint

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17 18 Bacteriophages (phages), or bacterial viruses, are very diverse and highly abundant worldwide, 19 including human microbiomes. Although a few metagenomic studies have focused on oral 20 phages, they relied on short-read sequencing. Here, we conducted a long-read metagenomic 21 study of human saliva for the first time using PromethION that requires a smaller amount of 22 DNA than PacBio. Our analyses, which integrated both PromethION and HiSeq data of >30 Gb 23 per sample, revealed N50 ranging from 187-345 kb and thousands of contigs with >1 kb 24 accounting for > 99% of all contigs on which 94-96% of HiSeq reads were mapped. We 25 identified hundreds of viral contigs (95 phages and 333 prophages on an average per sample); 26 0-43.8% and 12.5-56.3% of the "most confident" phages and prophages, respectively, didn't 27 cluster with those reported previously and were identified as novel. Our integrated analyses 28 identified highly abundant oral phages/prophages, including a novel Streptococcus phage 29 cluster and nine jumbo phages/prophages. Interestingly, 86% of the phage cluster and 67% of 30 the jumbo phages/prophages contained remote homologs of antimicrobial resistance genes, 31 suggesting their potential role as a source of recombination to generate new resistance genes. 32Pan-genome analysis of the phages/prophages revealed remarkable diversity, identifying 0.3% 33 and 86.4% of the genes as core and singletons, respectively. Functional annotation revealed 34 that the highest fraction of the core genes was enriched in phage morphogenesis, followed by 35 the fraction enriched in host cellular processes. Furthermore, our study suggested that oral 36 phages present in human saliva are under selective pressure for escaping CRISPR immunity. 37 (250/250 words) 38 39 Importance 40 41Despite the abundance and grave implications oral bacterial viruses in health and disease, little 42 is known regarding the different groups of oral bacterial viruses, their relative abundances 43 under various conditions, and their activities. We provided answers to these questions for the first time utilizing a recently developed sequencer that can capture and sequence long DNA 45 fragments, including viruses, and requires only a small amount of DNA input, making it 46 suitable for analyzing human oral samples. We identified hundreds of viral sequences, 47 (147/150 words) 54 55

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“…By nature, viruses are smaller than the cells they infect, but the range of virus sizes is nonetheless substantial, with lengths of viral particles (virions) varying from 17 nm to ~1.5 µm, and genome size varying from ~1 kb to 2.5 Mb (Campillo-Balderas et al 2015). The largest 'giant' viruses have primarily been isolated from unicellular protists (Campillo-Balderas et al 2015, Wilhelm et al 2017, although there is metagenomic evidence for 'megaphages' of prokaryotes with genomes up to 716 kb (Devoto et al 2019, Al-Shayeb et al 2020, and a chaetognath appears to be infected by viruses 1.25 µm in length (Shinn and Bullard 2018). In contrast, the known viruses of plants and fungi have genomes < 30 kb (Campillo-Balderas et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Making sense of virus size and the tradeoffs shaping viral fitness

Edwards

Steward

Schvarcz

2020

Preprint

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Viruses span an impressive size range, with genome length varying more than a thousandfold and capsid volume nearly a millionfold. Physical constraints suggest that smaller viruses may have multiple fitness advantages, because a greater number of viral offspring can be created from limited host resources, and because smaller particles diffuse to encounter new hosts more rapidly. At the same time, a larger genome size allows for numerous additional functions that may increase fitness, such as better control of replication, transcription, translation, and host metabolism, and neutralization of host defenses. However, it is unclear whether important viral traits correlate with size, and whether this causes size to vary among host types or environmental contexts. Here we focus on viruses of aquatic unicellular organisms, which exhibit the greatest known range of virus size. We develop and synthesize theory, and analyze data where available, to consider how size affects the primary components of viral fitness. We suggest that the costs of larger size (lower burst size and diffusivity) are mitigated by the role of a larger genome in increasing infection efficiency, broadening host range, and potentially increasing attachment success and decreasing decay rate. These countervailing selective pressures may explain why such a breadth of sizes exist and can even coexist when infecting the same host populations. We argue that oligotrophic environments may be particularly enriched in unusually large or "giant" viruses, because environments with diverse, resourcelimited phagotrophic eukaryotes at persistently low concentrations may select for broader host range, better control of host metabolism, lower decay rate, and a physical size that mimics bacterial prey. Finally, we describe areas where further research is needed to understand the ecology and evolution of viral size diversity.

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Clades of huge phages from across Earth’s ecosystems

Cited by 362 publications

References 85 publications

Accurate and complete genomes from metagenomes

Accurate and complete genomes from metagenomes

Long-read shotgun metagenome sequencing using PromethION uncovers novel bacteriophages, their abundance, and interaction with host bacterial immunity in the oral microbiota

Making sense of virus size and the tradeoffs shaping viral fitness

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