Disruption of Transcriptional Coactivator Sub1 Leads to Genome-Wide Re-distribution of Clustered Mutations Induced by APOBEC in Active Yeast Genes

Lada, Artem G.; Kliver, Sergei; Dhar, Alok; Polev, Dmitrii E.; Masharsky, Alexey; Rogozin, Igor B.; Pavlov, Youri I.

doi:10.1371/journal.pgen.1005217

Cited by 52 publications

(68 citation statements)

References 83 publications

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“…It is possible that a larger mutational harvest would reveal a significant transcription strand bias, especially in highly transcribed genes, but in our data, any such bias was overwhelmed by the observed replication strand bias. In contrast, Lada et al found that most mutations caused by the lamprey cytosine deaminase, PmCDA1, in nondividing yeast were correlated with transcription (40). Together, these observations suggest that in dividing cells, the greatest source of C:G to T:A mutations is the deamination of cytosines in the template for the lagging strand synthesis, but transcription may play a larger role in nondividing cells.…”

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confidence: 95%

“…One characteristic of cancer genome mutations is that they are found in clusters, suggesting that they occur in genomic regions that contain stretches of ssDNA (34). Although a number of cellular processes, including replication, transcription, and recombination, have been proposed as sources of ssDNA targets for APOBEC3s (13,34,(40)(41)(42), experimental evidence for these ideas is limited. The data presented here suggest that the LGST at the replication forks of rapidly dividing cancer cells would be accessible to these enzymes, and hence the cytosines mutated in cancer genomes should be found preferentially in the LGST compared with the LDST.…”

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confidence: 99%

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Strand-biased cytosine deamination at the replication fork causes cytosine to thymine mutations in Escherichia coli

Bhagwat

Hao

Townes

et al. 2016

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

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The rate of cytosine deamination is much higher in single-stranded DNA (ssDNA) than in double-stranded DNA, and copying the resulting uracils causes C to T mutations. To study this phenomenon, the catalytic domain of APOBEC3G (A3G-CTD), an ssDNA-specific cytosine deaminase, was expressed in an Escherichia coli strain defective in uracil repair (ung mutant), and the mutations that accumulated over thousands of generations were determined by whole-genome sequencing. C:G to T:A transitions dominated, with significantly more cytosines mutated to thymine in the lagging-strand template (LGST) than in the leading-strand template (LDST). This strand bias was present in both repair-defective and repair-proficient cells and was strongest and highly significant in cells expressing A3G-CTD. These results show that the LGST is accessible to cellular cytosine deaminating agents, explains the well-known GC skew in microbial genomes, and suggests the APOBEC3 family of mutators may target the LGST in the human genome.uracil-DNA glycosylase | APOBEC3A | APOBEC3B | kataegis | cancer genome mutations P airing of complementary DNA strands protects the DNA bases against modification by a number of hydrolytic, oxidizing, and alkylating chemicals (1-4). For example, water reacts with cytosine, creating uracil, and the rate of this reaction in single-stranded DNA (ssDNA) is more than 100-fold the rate in double-stranded DNA [dsDNA (5-7)]. Uracil-DNA glycosylase (Ung) excises uracils created by cytosine deamination in both ssDNA and dsDNA, resulting in abasic (AP) sites. In dsDNA, the AP sites are replaced with cytosines as a result of copying of the guanine in the complementary strand during repair by the base-excision repair (BER) pathway (8). In contrast, cytosine deaminations occurring in ssDNA are problematic because the complementary strand is not available to the BER pathway. Uracils that escape repair create C:G to T:A mutations, and incomplete repair of uracils can result in persistent AP sites and strand breaks that can destabilize the genome. Hence, identifying ssDNA regions that are susceptible to damage will increase our understanding of causes of mutations and genome instability.The AID/APOBEC (activation-induced deaminase/apolipoprotein B mRNA editing enzyme, catalytic polypeptide-like) family of DNA-cytosine deaminases are specific for ssDNA (9, 10). They are found only in vertebrates and are good probes of ssDNA in cells because of their relatively small size (about 190-amino acid catalytic domain). They are active in heterologous hosts such as Escherichia coli (11, 12) and yeast (13-15) and cause mutations in the same sequence context as in their known targets, such as Ig genes and the DNA copy of HIV-1 genome (11,16,17). In particular, the catalytic domain of human APOBEC3G (A3G-CTD) was expressed in an engineered yeast strain lacking the UNG gene and was shown to target ssDNA generated through aberrant resection of telomeric ends (13).To similarly probe ssDNA in E. coli, we expressed A3G-CTD on a plasmid (pA3G-CTD) in...

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confidence: 95%

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confidence: 99%

Strand-biased cytosine deamination at the replication fork causes cytosine to thymine mutations in Escherichia coli

Bhagwat

Hao

Townes

et al. 2016

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

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“…Cytidine deamination by AID on ssDNA during transcription of variable regions in the immunoglobulin locus is required for the initiation of both class-switch recombination and somatic hypermutation [18,19]. Interestingly, the activity of AID is regulated at the transcription bubble through the interaction with transcriptional co factors that assist with AID catalytic activity [20,21]. The expression of AID in B cells is essential as AID deficiency leads to Hyper-IgM syndrome and the inability to produce antibodies other than IgM M2 [22].…”

Section: Evolution Of Apobec3 Activitymentioning

confidence: 99%

“…For a related family member AID, which normally deaminates the immunoglobulin genes to enable antibody maturation and class switching [11], targeting of AID to the correct genomic region and maximizing its access to both strands of the genomic DNA requires many interacting partner [186]. Although AID can access other regions of the genome, it is thought that interactions with transcription machinery occur to facilitate its specific role in deaminating cytosine in immunoglobulin genes [20,21]. These protein-protein interactions may not only assist in targeting immunoglobulin genes during B-cell activation, but may be required for AID to catalyze deaminations since its catalytic rate is slow [187].…”

Section: Role Of Apobec In Somatic Mutagenesismentioning

confidence: 99%

“…The generation of increased amounts of ssDNA promotes the activity of A3 and increases the mutational frequency Thus, it is notable that A3B is not problematic until a cellular alteration occurs that increases A3B expression and increases replication stress [177,192,203]. In contrast, the ssDNA generated on the nontranscribed strand during transcription is accessible at multiple times during the cell cycle of a normal or transformed cell, especially during RNA polymerase stalling [20,21]. Although A3 enzymes would still need to access transiently available nontranscribed ssDNA that interacts with the RNA polymerase, the ssDNA is solvent accessible [204].…”

Section: Role Of Apobec In Somatic Mutagenesismentioning

confidence: 99%

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Biochemical Basis of APOBEC3 Deoxycytidine Deaminase Activity on Diverse DNA Substrates

2018

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Apolipoprotein B mRNA-editing enzyme-catalytic, polypeptide-like 3 (APOBEC3) enzymes are a family of single-stranded (ss)DNA cytosine deaminases that serve as a host restriction factors for retrotransposons and viruses that contain a ssDNA intermediate. While the APOBEC3 family was originally expanded to restrict endogenous retroelements, the majority of these targets are now inactivated and the family has been found to act on different targets, such as viral ssDNA as a mechanism of viral defense. Some of the family members also catalyze "offtarget" deaminations in human ssDNA and have been implicated in somatic mutagenesis that can lead to cancer.My PhD thesis research investigated the biochemical mechanisms underlying both the benefits and the risks of the A3 family of enzymes. The central hypothesis of this work is that A3 enzymes have evolved distinct biochemical mechanisms to deaminate ssDNA that differentiate A3 restriction of retroelements and retroviruses from A3-induced somatic mutagenesis.Therefore, we investigated the biochemical mechanisms the A3 enzymes utilize during restriction of Human Immunodeficiency Virus (HIV) in both deamination-dependent and deaminationindependent modes, as well as the unique mechanisms employed during mutation of genomic DNA. There are seven APOBEC3 members (A-H, excluding E) and of these, four members (A3D, A3F, A3G, A3H) have been identified to restrict HIV replication in CD4 T+ cells, and currently three members (A3A, A3B and A3H haplotype I) have been implicated in somatic mutagenesis.The APOBEC3 enzymes that restrict HIV replication function optimally in the absence of the HIV viral infectivity factor (Vif). Vif targets APOBEC3 for degradation via the proteasome in HIV infected cells. For APOBEC3s that are able to fortuitously escape Vif mediated degradation and become encapsidated, the enzymes can deaminate cytosines to form uracils in viral (-)DNA. Replication of (-)DNA to (+)DNA causes HIV-1 reverse transcriptase to incorporate adenines opposite uracils which creates C/G→T/A transition mutations. While restriction of HIV most commonly occurs through this deamination-dependent mechanism, APOBEC3s have also been identified to interfere with HIV reverse transcriptase processes in a deamination-independent manner, although this mechanism is secondary to the deaminationdependent mode. In order to restrict retroelements and viruses such as HIV, the A3 enzymes iii require an efficient processive ssDNA scanning mechanism that allows them to search for, and locate cytosines on ssDNA in the finite amount of time the substrate is available during formation of the double-stranded DNA provirus. To understand if this requirement was lost in A3 enzymes unable to restrict HIV, we studied A3C. Human A3C is not able to restrict HIV, in comparison to the more active gorilla and chimpanzee A3C orthologs that can restrict HIV, however an explanation for this difference was lacking. A polymorphism, S188I, in human A3C, which is found in less than 3% of the global population lead...

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Objective review of de novo stand‐alone error correction methods for NGS data

Alic

Ruzafa

Dopazo

et al. 2016

WIREs Comput Mol Sci

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The sequencing market has increased steadily over the last years, with different approaches to read DNA information, prone to different types of errors. Multiple studies demonstrated the impact of sequencing errors on different applications of Next Generation Sequencing (NGS), making error correction a fundamental initial step. Different methods in the literature use different approaches and fit different types of problems. We analysed a number of 50 methods divided into five main approaches (k-spectrum, suffix arrays, multiple sequence alignment, read clustering and probabilistic models). They are not published as a part of a suite (stand-alone) and target raw, unprocessed data without an existing reference genome (de Novo). These correctors handle one or more sequencing 1 Correspondence to: asalic@posgrado.upv.es 1 technologies using the same or different approaches. They face general challenges (sometimes with specific traits for specific technologies) such as repetitive regions, uncalled bases and ploidy. Even assessing their performance is a challenge in itself because of the approach taken by various authors, the unknown factor (de Novo) and the behaviour of the third party tools employed in the benchmarks. This work aims at helping the researcher in the field to advance the state-of-the-art, the educator to have a brief but comprehensive companion and the bioinformatician to choose the right tool for the right job.The Next Generation Sequencing (NGS) appeared in 2005 and since then its market has increased steadily, with various technologies being developed. The NGS has evolved faster than the the Moore's law in Computer Science, allowing us to sequence and assemble large genomes like the Loblolly Pine with 22 Gb 1 or the Norway Spruce with 20 Gb 2 for a reasonable cost in time and resources. However, there are many other species (e.g. the Amoeba Dubia with a 670 Gb estimated genome size 3 , 200x human genome's size) that are still challenging to assemble. The errors introduced by the sequencing process are one of the main reasons NGS data has to be corrected before any further use. Multiple studies have demonstrated the impact of sequencing errors on different applications of NGS, making error correction a fundamental initial step. [4][5][6][7] There are many error correction tools in the literature that cope with different technologies and error types. However, to our knowledge, there is no complete, objective review of the modern methods that could help researchers, educators and users at the same time. There are benchmarks summarizing a number of methods, but there is none extensively focusing on the implementation, features and the overall domain (including challenges). Our work synthesises 50 de Novo stand-alone error-correction software. The Supplementary Material includes the description of the approach used to search the literature along with the inclusion criteria.The article continues with the motivation (also containing a brief description of the sequencing technologies and various err...

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Disruption of Transcriptional Coactivator Sub1 Leads to Genome-Wide Re-distribution of Clustered Mutations Induced by APOBEC in Active Yeast Genes

Cited by 52 publications

References 83 publications

Strand-biased cytosine deamination at the replication fork causes cytosine to thymine mutations in Escherichia coli

Strand-biased cytosine deamination at the replication fork causes cytosine to thymine mutations in Escherichia coli

Biochemical Basis of APOBEC3 Deoxycytidine Deaminase Activity on Diverse DNA Substrates

Objective review of de novo stand‐alone error correction methods for NGS data

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