Architecturally diverse proteins converge on an analogous mechanism to inactivate Uracil-DNA glycosylase

Cole, A.R.; Ofer, Sapir; Ryzhenkova, K.; Baltulionis, G.; Hornyák, Péter; Savva, Renos

doi:10.1093/nar/gkt633

Cited by 13 publications

(31 citation statements)

References 50 publications

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“…However, inhibition of SbcCD is unlikely to contribute to the antibacterial potentiation effect observed here, because cells lacking SbcCD activity are not sensitive to ciprofloxacin (Henderson and Kreuzer, 2015; Aedo and Tse-Dinh, 2013; Liu et al, 2010). DNA mimicry has been observed previously for phage-encoded proteins that target type I restriction endonucleases and glycosylases (Kennaway et al, 2009; Baños-Sanz et al, 2013; Cole et al, 2013) and it may be a common mechanism for bacteriophages to modulate DNA replication and repair in their hosts. Bacteriophage P22 codes for another, distinctive RecBCD inhibitor called Abc2 but this operates by a poorly-characterised mechanism (Murphy, 2000).…”

Section: Discussionmentioning

confidence: 74%

Structural basis for the inhibition of RecBCD by Gam and its synergistic antibacterial effect with quinolones

Wilkinson

Troman

Ismah

et al. 2016

eLife

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Our previous paper (Wilkinson et al, 2016) used high-resolution cryo-electron microscopy to solve the structure of the Escherichia coli RecBCD complex, which acts in both the repair of double-stranded DNA breaks and the degradation of bacteriophage DNA. To counteract the latter activity, bacteriophage λ encodes a small protein inhibitor called Gam that binds to RecBCD and inactivates the complex. Here, we show that Gam inhibits RecBCD by competing at the DNA-binding site. The interaction surface is extensive and involves molecular mimicry of the DNA substrate. We also show that expression of Gam in E. coli or Klebsiella pneumoniae increases sensitivity to fluoroquinolones; antibacterials that kill cells by inhibiting topoisomerases and inducing double-stranded DNA breaks. Furthermore, fluoroquinolone-resistance in K. pneumoniae clinical isolates is reversed by expression of Gam. Together, our data explain the synthetic lethality observed between topoisomerase-induced DNA breaks and the RecBCD gene products, suggesting a new co-antibacterial strategy.DOI: http://dx.doi.org/10.7554/eLife.22963.001

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Section: Discussionmentioning

confidence: 74%

Structural basis for the inhibition of RecBCD by Gam and its synergistic antibacterial effect with quinolones

Wilkinson

Troman

Ismah

et al. 2016

eLife

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“…In these phages, they either enable synthesis of uracil-enriched DNA or protect against the cleavage of phage genome at uracil positions thereby facilitating viral DNA replication (Cole et al, 2013). Uracilation of viral DNA also plays a role in other host-virus interactions (Chen et al, 2002; Sire et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

“…The very first finding that led to the identification of UGI was that Bacillus subtilis bacteriophages PBS1, and PBS2 possess a genome in which thymine is replaced by uracil (Takahashi and Marmur, 1963). UGI is an early phage protein that prevents degradation by the host UNG and therefore it is indispensable for the maintenance of the uracilated phage genome (Cone et al, 1980; Cole et al, 2013). To date two other bacteriophages have been discovered that possess uracil containing DNA, namely, ΦR1-37 infecting Y. enterocolitica (Kiljunen et al, 2005), and phage S6 infecting Staphylococcace (Uchiyama et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Life without dUTPase

et al. 2016

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Fine-tuned regulation of the cellular nucleotide pools is indispensable for faithful replication of Deoxyribonucleic Acid (DNA). The genetic information is also safeguarded by DNA damage recognition and repair processes. Uracil is one of the most frequently occurring erroneous bases in DNA; it can arise from cytosine deamination or thymine-replacing incorporation. Two enzyme activities are primarily involved in keeping DNA uracil-free: dUTPase (dUTP pyrophosphatase) activity that prevent thymine-replacing incorporation and uracil-DNA glycosylase activity that excise uracil from DNA and initiate uracil-excision repair. Both dUTPase and the most efficient uracil-DNA glycosylase (UNG) is thought to be ubiquitous in free-living organisms. In the present work, we have systematically investigated the genotype of deposited fully sequenced bacterial and Archaeal genomes. We have performed bioinformatic searches in these genomes using the already well described dUTPase and UNG gene sequences. For dUTPases, we have included the trimeric all-beta and the dimeric all-alpha families and also, the bifunctional dCTP (deoxycytidine triphosphate) deaminase-dUTPase sequences. Surprisingly, we have found that in contrast to the generally held opinion, a wide number of bacterial and Archaeal species lack all of the previously described dUTPase gene(s). The dut– genotype is present in diverse bacterial phyla indicating that loss of this (or these) gene(s) has occurred multiple times during evolution. We discuss potential survival strategies in lack of dUTPases, such as simultaneous lack or inhibition of UNG and possession of exogenous or alternate metabolic enzymes involved in uracil-DNA metabolism. The potential that genes previously not associated with dUTPase activity may still encode enzymes capable of hydrolyzing dUTP is also discussed. Our data indicate that several unicellular microorganisms may efficiently cope with a dut– genotype lacking all of the previously described dUTPase genes, and potentially leading to an unusual uracil-enrichment in their genomic DNA.

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“…If that is not surprising enough, γ-herpesvirus Ung includes the exaptation of a key motif essential for Ung catalysis to underpin viral replication competence ( Figure 5) [49][50][51][52]. The aforementioned Ung catalytic motif is, in fact, the same one that, in the host Ung and its canonical relatives in bacteria, is targeted by viruses that silence the cellular Ung protein as part of their replication strategy ( Figure 5) [70][71][72].…”

Section: Herpesviruses and Ung A Surprising Relationship And Remarkamentioning

confidence: 99%

“…Intriguingly this conserved mechanism has evolved convergently from three independent, unrelated protein architectures: Ugi [and its structural homologue SAUGI, a horizontally transferred gene found in SCCmec mobile genetic elements of Staphylococcaceae] from myoviruses, p56 from salasviruses and Vpr from primate lentiviruses. Charge-based alignment and contact from the inhibitor protein elicits concerted Ung loop motion, resulting in an effectively irreversible sterically-blockaded sequestration of Ung via hydrophobic trapping of the apical aliphatic side chain of the Ung loop by the virus inhibitor protein ( Figure 5) [41,[70][71][72]76].…”

Section: Herpesviruses and Ung A Surprising Relationship And Remarkamentioning

confidence: 99%

The Essential Co-Option of Uracil-DNA Glycosylases by Herpesviruses Invites Novel Antiviral Design

Savva

2020

Microorganisms

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Vast evolutionary distances separate the known herpesviruses, adapted to colonise specialised cells in predominantly vertebrate hosts. Nevertheless, the distinct herpesvirus families share recognisably related genomic attributes. The taxonomic Family Herpesviridae includes many important human and animal pathogens. Successful antiviral drugs targeting Herpesviridae are available, but the need for reduced toxicity and improved efficacy in critical healthcare interventions invites novel solutions: immunocompromised patients presenting particular challenges. A conserved enzyme required for viral fitness is Ung, a uracil-DNA glycosylase, which is encoded ubiquitously in Herpesviridae genomes and also host cells. Research investigating Ung in Herpesviridae dynamics has uncovered an unexpected combination of viral co-option of host Ung, along with remarkable Subfamily-specific exaptation of the virus-encoded Ung. These enzymes apparently play essential roles, both in the maintenance of viral latency and during initiation of lytic replication. The ubiquitously conserved Ung active site has previously been explored as a therapeutic target. However, exquisite selectivity and better drug-like characteristics might instead be obtained via targeting structural variations within another motif of catalytic importance in Ung. The motif structure is unique within each Subfamily and essential for viral survival. This unique signature in highly conserved Ung constitutes an attractive exploratory target for the development of novel beneficial therapeutics.

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Architecturally diverse proteins converge on an analogous mechanism to inactivate Uracil-DNA glycosylase

Cited by 13 publications

References 50 publications

Structural basis for the inhibition of RecBCD by Gam and its synergistic antibacterial effect with quinolones

Structural basis for the inhibition of RecBCD by Gam and its synergistic antibacterial effect with quinolones

Life without dUTPase

The Essential Co-Option of Uracil-DNA Glycosylases by Herpesviruses Invites Novel Antiviral Design

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