Release and persistence of extracellular DNA in the environment

Nielsen, Kaare M.; Johnsen, Pål Jarle; Bensasson, Douda; Daffonchio, Daniele

doi:10.1051/ebr:2007031

Cited by 464 publications

(391 citation statements)

References 155 publications

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“…Our findings open for the possibility that natural genetic exchange can occur with DNA up to several hundreds of thousands years old. microbial evolution | horizontal gene transfer | DNA degradation | early life | anachronistic evolution D NA molecules are continuously released into the surroundings through decomposition of organic matter and are ubiquitous in most environments (1). DNA degradation is initiated at cell death by coreleased cellular nucleases and continued by microbes feeding on organic matter (1).…”

mentioning

confidence: 99%

“…microbial evolution | horizontal gene transfer | DNA degradation | early life | anachronistic evolution D NA molecules are continuously released into the surroundings through decomposition of organic matter and are ubiquitous in most environments (1). DNA degradation is initiated at cell death by coreleased cellular nucleases and continued by microbes feeding on organic matter (1). Because fragmentation proceeds quickly, larger (gene-length) fragments are not expected to persist in the environment (1).…”

mentioning

confidence: 99%

“…DNA degradation is initiated at cell death by coreleased cellular nucleases and continued by microbes feeding on organic matter (1). Because fragmentation proceeds quickly, larger (gene-length) fragments are not expected to persist in the environment (1). Extracellular DNA is further modified by spontaneous biochemical, chemical, or physical processes, of which the most important are hydrolysis and oxidation (2).…”

mentioning

confidence: 99%

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Bacterial natural transformation by highly fragmented and damaged DNA

Overballe‐Petersen¹,

Harms

Orlando³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

164

142

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DNA molecules are continuously released through decomposition of organic matter and are ubiquitous in most environments. Such DNA becomes fragmented and damaged (often <100 bp) and may persist in the environment for more than half a million years. Fragmented DNA is recognized as nutrient source for microbes, but not as potential substrate for bacterial evolution. Here, we show that fragmented DNA molecules (≥20 bp) that additionally may contain abasic sites, cross-links, or miscoding lesions are acquired by the environmental bacterium Acinetobacter baylyi through natural transformation. With uptake of DNA from a 43,000-y-old woolly mammoth bone, we further demonstrate that such natural transformation events include ancient DNA molecules. We find that the DNA recombination is RecA recombinase independent and is directly linked to DNA replication. We show that the adjacent nucleotide variations generated by uptake of short DNA fragments escape mismatch repair. Moreover, doublenucleotide polymorphisms appear more common among genomes of transformable than nontransformable bacteria. Our findings reveal that short and damaged, including truly ancient, DNA molecules, which are present in large quantities in the environment, can be acquired by bacteria through natural transformation. Our findings open for the possibility that natural genetic exchange can occur with DNA up to several hundreds of thousands years old. microbial evolution | horizontal gene transfer | DNA degradation | early life | anachronistic evolution

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confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Bacterial natural transformation by highly fragmented and damaged DNA

Overballe‐Petersen¹,

Harms

Orlando³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

164

142

View full text Add to dashboard Cite

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“…However, this rate of transformation is likely to be much greater than what would be possible in natural environments where the persistence of DNA in a transformable state and availability of suitable competent bacteria is expected to be much lower (Nielsen et al, 2007;Simpson et al, 2007).…”

Section: Hgt From Gm Plants To Bacteriamentioning

confidence: 99%

“…Nevertheless, most gene transfers between multicellular eukaryotes and other organisms are detected over time scales of millions of years. This is despite the abundant availability of genetic material in living organisms, and externally, such as in soil, water, feces or even processed foods (Brinkmann and Tebbe, 2007;Douville et al, 2007;Kharazmi et al, 2003;Nielsen et al, 2007). Only a few types of HGT occur sufficiently often to be observed.…”

Section: General Conclusionmentioning

confidence: 99%

Risks from GMOs due to Horizontal Gene Transfer

Keese¹

2008

Environ. Biosafety Res.

131

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Horizontal gene transfer (HGT) is the stable transfer of genetic material from one organism to another without reproduction or human intervention. Transfer occurs by the passage of donor genetic material across cellular boundaries, followed by heritable incorporation to the genome of the recipient organism. In addition to conjugation, transformation and transduction, other diverse mechanisms of DNA and RNA uptake occur in nature. The genome of almost every organism reveals the footprint of many ancient HGT events. Most commonly, HGT involves the transmission of genes on viruses or mobile genetic elements. HGT first became an issue of public concern in the 1970s through the natural spread of antibiotic resistance genes amongst pathogenic bacteria, and more recently with commercial production of genetically modified (GM) crops. However, the frequency of HGT from plants to other eukaryotes or prokaryotes is extremely low. The frequency of HGT to viruses is potentially greater, but is restricted by stringent selection pressures. In most cases the occurrence of HGT from GM crops to other organisms is expected to be lower than background rates. Therefore, HGT from GM plants poses negligible risks to human health or the environment.

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Abalone Withering Syndrome Disease Dynamics: Infectious Dose and Temporal Stability in Seawater

et al. 2020

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Withering syndrome (WS) is a chronic bacterial disease that affects numerous northeastern Pacific abalone Haliotis spp. The causative agent of WS is an obligate intracellular Rickettsiales‐like bacterium (WS‐RLO) that remains unculturable, thereby limiting our understanding of WS disease dynamics. The objectives of our study were to (1) determine the temporal stability of WS‐RLO DNA outside of its abalone host in 14°C and 18°C seawater, (2) develop a standardized protocol for exposing abalones to known concentrations of WS‐RLO DNA, and (3) calculate the dose of WS‐RLO DNA required to generate 50% infection prevalence (ID50) in the highly cultured red abalone Haliotis rufescens. The WS‐RLO stability trials were conducted in October 2016, February 2017, and June 2017. A quantitative PCR (qPCR) analysis was used to quantify bacterial DNA for 7 d in seawater collected at an abalone farm in southern California, where the pathogen is now endemic. For all trials and temperature treatments, WS‐RLO DNA was unstable in seawater for longer than 2 d. To determine an ID50, groups of uninfected juvenile red abalone were subjected to 3‐h bath exposures with four concentrations of WS‐RLO at 0, 103, 104, and 105 DNA copies/mL. Abalone feces were tested biweekly for the presence of WS‐RLO DNA, and abalone tissues were sampled 9 weeks postinfection for histological and qPCR analyses. The ID50 results indicated that our protocol was successful in generating WS‐RLO infections; a pathogen dose of 2.3 × 103 DNA copies/mL was required to generate a 50% infection prevalence in red abalone tissue. These findings are critical components of disease dynamics that will help assess WS transmission risk within and among abalone populations and facilitate appropriate management and restoration strategies for both wild and cultured abalone species in WS‐endemic areas.

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Release and persistence of extracellular DNA in the environment

Cited by 464 publications

References 155 publications

Bacterial natural transformation by highly fragmented and damaged DNA

Bacterial natural transformation by highly fragmented and damaged DNA

Risks from GMOs due to Horizontal Gene Transfer

Abalone Withering Syndrome Disease Dynamics: Infectious Dose and Temporal Stability in Seawater

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