Restriction of AID activity and somatic hypermutation by PARP-1.

Affinity maturation of the humoral immune response depends on somatic hypermutation (SHM) of immunoglobulin (Ig) genes, which is initiated by targeted lesion introduction by activation-induced deaminase (AID), followed by error-prone DNA repair. Stringent regulation of this process is essential to prevent genetic instability, but no negative feedback control has been identified to date. Here we show that poly(ADP-ribose) polymerase-1 (PARP-1) is a key factor restricting AID activity during somatic hypermutation. Poly(ADP-ribose) (PAR) chains formed at DNA breaks trigger AID-PAR association, thus preventing excessive DNA damage induction at sites of AID action. Accordingly, AID activity and somatic hypermutation at the Ig variable region is decreased by PARP-1 activity. In addition, PARP-1 regulates DNA lesion processing by affecting strand biased A:T mutagenesis. Our study establishes a novel function of the ancestral genome maintenance factor PARP-1 as a critical local feedback regulator of both AID activity and DNA repair during Ig gene diversification.

AID and APOBEC deaminases: balancing DNA damage in epigenetics and immunity.

DNA mutations and genomic recombinations are the origin of oncogenesis, yet parts of developmental programs as well as immunity are intimately linked to, or even depend on, such DNA damages. Therefore, the balance between deleterious DNA damages and organismal survival utilizing DNA editing (modification and repair) is in continuous flux. The cytosine deaminases AID/APOBEC are a DNA editing family and actively participate in various biological processes. In conjunction with altered DNA repair, the mutagenic potential of the family allows for APOBEC3 proteins to restrict viral infection and transposons propagation, while AID can induce somatic hypermutation and class switch recombination in antibody genes. On the other hand, the synergy between effective DNA repair and the nonmutagenic potential of the DNA deaminases can induce local DNA demethylation to support epigenetic cellular identity. Here, we review the current state of knowledge on the mechanisms of action of the AID/APOBEC family in immunity and epigenetics.

Processive DNA demethylation via DNA deaminase-induced lesion resolution.

Base modifications of cytosine are an important aspect of chromatin biology, as they can directly regulate gene expression, while DNA repair ensures that those modifications retain genome integrity. Here we characterize how cytosine DNA deaminase AID can initiate DNA demethylation. In vitro, AID initiated targeted DNA demethylation of methyl CpGs when in combination with DNA repair competent extracts. Mechanistically, this is achieved by inducing base alterations at or near methyl-cytosine, with the lesion being resolved either via single base substitution or a more efficient processive polymerase dependent repair. The biochemical findings are recapitulated in an in vivo transgenic targeting assay, and provide the genetic support of the molecular insight into DNA demethylation. This targeting approach supports the hypothesis that mCpG DNA demethylation can proceed via various pathways and mCpGs do not have to be targeted to be demethylated.

Simultaneous in vitro characterisation of DNA deaminase function and associated DNA repair pathways.

During immunoglobulin (Ig) diversification, activation-induced deaminase (AID) initiates somatic hypermutation and class switch recombination by catalysing the conversion of cytosine to uracil. The synergy between AID and DNA repair pathways is fundamental for the introduction of mutations, however the molecular and biochemical mechanisms underlying this process are not fully elucidated. We describe a novel method to efficiently decipher the composition and activity of DNA repair pathways that are activated by AID-induced lesions. The in vitro resolution (IVR) assay combines AID based deamination and DNA repair activities from a cellular milieu in a single assay, thus avoiding synthetically created DNA-lesions or genetic-based readouts. Recombinant GAL4-AID fusion protein is targeted to a plasmid containing GAL4 binding sites, allowing for controlled cytosine deamination within a substrate plasmid. Subsequently, the Xenopus laevis egg extract provides a source of DNA repair proteins and functional repair pathways. Our results demonstrated that DNA repair pathways which are in vitro activated by AID-induced lesions are reminiscent of those found during AID-induced in vivo Ig diversification. The comparative ease of manipulation of this in vitro systems provides a new approach to dissect the complex DNA repair pathways acting on defined physiologically lesions, can be adapted to use with other DNA damaging proteins (e.g. APOBECs), and provide a means to develop and characterise pharmacological agents to inhibit these potentially oncogenic processes.

The 2012 IMB Conference: DNA demethylation, repair and beyond. Institute of Molecular Biology, Mainz, Germany, 18-21 October 2012.

Headline-grabbing attention has been given to DNA demethylation pathways as new epigenetic mechanisms, with reviews and hypotheses outnumbering research papers. As candidate proteins for DNA demethylation include well-known DNA repair enzymes, it was timely to join epigenetics and DNA repair experts at the first international meeting on DNA Demethylation, Repair and Beyond. New mechanistic insights were presented for known players orchestrating the symphony on cytosine - 'the symphony on C' (TET1, 2, 3; GADD45; AID; and TDG), while new instruments and classical themes were pulled into the amalgamation. What may appear as just an unintentional cacophony of random oxidative lesions and abasic sites in a bed of chromatin noise may turn out to be a gene-expressing regulatory melody.

Hormones and AID: balancing immunity and autoimmunity.

The human immune system is a complex dynamic network of soluble factors and specialized cells that can and need to act in an instance or keep a lifelong protection, with the consequence that health has to be maintained through genetic and environmental stimuli. Autoimmunity is a multifactorial disease, where this combination of genetic predisposition and environmental factors lead to disease etiology. As some autoimmune diseases, such as systemic lupus erythematosus (SLE), rheumatoid arthritis (RA) or other B cell autoimmunities have a very strong female gender bias, hormones, especially estrogen, have been implicated as environmental factors in driving the disease. One of the key regulators of B cell development is activation-induced deaminase (AID), as its molecular mechanism of cytosine deamination induces immunoglobulin affinity maturation and antibody class switching. In this review we will highlight some of the recent findings of how estrogen directly and indirectly activates AID expression, which in turn can lead to immune hyper-stimulation. Those regulatory pathways can be direct when the estrogen receptor (ER) binds the AID promoter, or indirect via activation of transcription factors that enhance AID expression (e.g., HoxC4). Estrogen's influence on AID will also be discussed in terms of microRNA processing for miRNA-155 and miRNA-181b. Important other external stimuli, such as EBV virus, in conjunction with estrogen can add another layer of regulation during autoimmune disease progression. Understanding these pathways will become more important as AID has now been implicated to play an important role in immune tolerance and actual elimination of autoantibodies.

A role for the RNA pol II-associated PAF complex in AID-induced immune diversification.

Antibody diversification requires the DNA deaminase AID to induce DNA instability at immunoglobulin (Ig) loci upon B cell stimulation. For efficient cytosine deamination, AID requires single-stranded DNA and needs to gain access to Ig loci, with RNA pol II transcription possibly providing both aspects. To understand these mechanisms, we isolated and characterized endogenous AID-containing protein complexes from the chromatin of diversifying B cells. The majority of proteins associated with AID belonged to RNA polymerase II elongation and chromatin modification complexes. Besides the two core polymerase subunits, members of the PAF complex, SUPT5H, SUPT6H, and FACT complex associated with AID. We show that AID associates with RNA polymerase-associated factor 1 (PAF1) through its N-terminal domain, that depletion of PAF complex members inhibits AID-induced immune diversification, and that the PAF complex can serve as a binding platform for AID on chromatin. A model is emerging of how RNA polymerase II elongation and pausing induce and resolve AID lesions.

5-Methylcytosine DNA demethylation: more than losing a methyl group.

Demethylation of 5-methylcytosine in DNA is integral to the maintenance of an intact epigenome. The balance between the presence or absence of 5-methylcytosine determines many physiological aspects of cell metabolism, with a turnover that can be measured in minutes to years. Biochemically, addition of the methyl group is shared among all living kingdoms and has been well characterized, whereas the removal or reversion of this mark seems diverse and much less understood. Here, we present a summary of how DNA demethylation can be initiated directly, utilizing the ten-eleven translocation (TET) family of proteins, activation-induced deaminase (AID), or other DNA modifying enzymes, or indirectly, via transcription, RNA metabolism, or DNA repair; how intermediates in those pathways are substrates of the DNA repair machinery; and how demethylation pathways are linked and possibly balanced, avoiding mutations.

AID enzymatic activity is inversely proportional to the size of cytosine C5 orbital cloud.

Activation induced deaminase (AID) deaminates cytosine to uracil, which is required for a functional humoral immune system. Previous work demonstrated, that AID also deaminates 5-methylcytosine (5 mC). Recently, a novel vertebrate modification (5-hydroxymethylcytosine - 5 hmC) has been implicated in functioning in epigenetic reprogramming, yet no molecular pathway explaining the removal of 5 hmC has been identified. AID has been suggested to deaminate 5 hmC, with the 5 hmU product being repaired by base excision repair pathways back to cytosine. Here we demonstrate that AID's enzymatic activity is inversely proportional to the electron cloud size of C5-cytosine - H > F > methyl >> hydroxymethyl. This makes AID an unlikely candidate to be part of 5 hmC removal.

AIDing the immune system-DIAbolic in cancer.

Activation induced deaminase (AID) has evolved with the immune system to enhance the ability of antibodies to bind and eliminate pathogens. It is a member of the AID/APOBEC family of proteins, which deaminate cytosine (or 5-methyl cytosine) in DNA leading to uracil (thymidine). These base modifications can lead to repair, DNA demethylation, mutagenesis, recombination, or viral/foreign DNA elimination. Because of their physiological function, their ubiquitous expression, and hormonal regulation (e.g. estrogen), these proteins play an important role in oncogenesis, with AID being directly implicated in B cell lymphomas. The targeting preference of each DNA deaminase provides a means to identify their mutation foot-print in tumours, and have implicated them in mutating the genome, including the loci of tumour suppressors, of various cancers (e.g. breast). In this special issue devoted to understanding AID function and regulation, leading members of the field discuss all aspects from AID transcriptional regulation, mRNA turnover, protein expression, modification, and transport, to complex formation, targeting and enzymatic turnover. AID's function will be discussed in context of DNA repair and how changes of key components of each pathway have an influence on the overall efficacy of targeted DNA deamination.

Progesterone inhibits activation-induced deaminase by binding to the promoter.

Regulation of activation-induced deaminase (AID), an essential factor in Ig diversification, can alter not only somatic hypermutation and class switch recombination (CSR), but may also influence oncogenesis. AID deaminates cytosine to uracil in the Ig locus, thereby initiating Ig diversification. Unregulated AID can induce oncogenic DNA alterations in Ig and non-Ig loci, leading to mutations, recombination, and translocations. In this study, we demonstrate that AID mRNA production in activated mouse splenic B cells can be reduced by treatment with the sex hormone progesterone. This down-regulation is independent of translation or splicing and is predominantly achieved by inhibiting transcription. During cell treatment we could detect progesterone receptor bound to the AID promoter in proximity to NF-kappaB binding. Importantly, the progesterone-induced repression was also extended to the protein level of AID and its activity on somatic hypermutation and class switch recombination.

DNA deaminases: AIDing hormones in immunity and cancer.

It is well established that hormones can cause cancer, much less known is how they induce this change in our somatic cells. This review highlights the recent finding that estrogen can exert its DNA-damaging potential by directly activating DNA deaminases. This recently discovered class of proteins deaminate cytosine to uracil in DNA, and are essential enzymes in the immune system. The enhanced production of a given DNA deaminase, induced by estrogen, can lead not only to a more active immune response, but also to an increase in mutations and oncogenic translocations. Identifying the direct molecular link between estrogen and a mutation event provides us with new targets for studying and possibly inhibiting the pathological side-effects of estrogen.

Alternative induction of meiotic recombination from single-base lesions of DNA deaminases.

Meiotic recombination enhances genetic diversity as well as ensures proper segregation of homologous chromosomes, requiring Spo11-initiated double-strand breaks (DSBs). DNA deaminases act on regions of single-stranded DNA and deaminate cytosine to uracil (dU). In the immunoglobulin locus, this lesion will initiate point mutations, gene conversion, and DNA recombination. To begin to delineate the effect of induced base lesions on meiosis, we analyzed the effect of expressing DNA deaminases (activation-induced deaminase, AID, and APOBEC3C) in germ cells. We show that meiotic dU:dG lesions can partially rescue a spo11Delta phenotype in yeast and worm. In rec12 Schizosaccharomyces pombe, AID expression increased proper chromosome segregation, thereby enhancing spore viability, and induced low-frequency meiotic crossovers. Expression of AID in the germ cells of Caenorhabditis elegans spo-11 induced meiotic RAD-51 foci formation and chromosomal bivalency and segregation, as well as an increase in viability. RNAi experiments showed that this rescue was dependent on uracil DNA-glycosylase (Ung). Furthermore, unlike ionizing radiation-induced spo-11 rescue, AID expression did not induce large numbers of DSBs during the rescue. This suggests that the products of DNA deamination and base excision repair, such as uracil, an abasic site, or a single-stranded nick, are sufficient to initiate and alter meiotic recombination in uni- and multicellular organisms.

Estrogen directly activates AID transcription and function.

The immunological targets of estrogen at the molecular, humoral, and cellular level have been well documented, as has estrogen's role in establishing a gender bias in autoimmunity and cancer. During a healthy immune response, activation-induced deaminase (AID) deaminates cytosines at immunoglobulin (Ig) loci, initiating somatic hypermutation (SHM) and class switch recombination (CSR). Protein levels of nuclear AID are tightly controlled, as unregulated expression can lead to alterations in the immune response. Furthermore, hyperactivation of AID outside the immune system leads to oncogenesis. Here, we demonstrate that the estrogen-estrogen receptor complex binds to the AID promoter, enhancing AID messenger RNA expression, leading to a direct increase in AID protein production and alterations in SHM and CSR at the Ig locus. Enhanced translocations of the c-myc oncogene showed that the genotoxicity of estrogen via AID production was not limited to the Ig locus. Outside of the immune system (e.g., breast and ovaries), estrogen induced AID expression by >20-fold. The estrogen response was also partially conserved within the DNA deaminase family (APOBEC3B, -3F, and -3G), and could be inhibited by tamoxifen, an estrogen antagonist. We therefore suggest that estrogen-induced autoimmunity and oncogenesis may be derived through AID-dependent DNA instability.

The nuclear DNA deaminase AID functions distributively whereas cytoplasmic APOBEC3G has a processive mode of action.

AID deaminates cytosine in the context of single stranded DNA to generate uracil, essential for effective class-switch recombination, somatic hypermutation and gene conversion at the B cell immunoglobulin locus. As a nuclear DNA mutator, AID activity must be tightly controlled and regulated, but the genetic analysis of AID and other DNA deaminases has left unstudied a number of important biochemical details. We have asked fundamental questions regarding AID's substrate recognition and processing, i.e. whether AID acts distributively or processively. We demonstrate that in vitro, human AID exhibits turnover, a prerequisite for our analysis, and show that it exhibits a distributive mode of action. Using a variety of different assays, we established that human AID is alone unable to act processively on any of a number of DNA substrates, i.e. one AID molecule is unable to carry out multiple, sequential deamination events on the same substrate. This is in contrast to the cytoplasmically expressed anti-viral DNA deaminase APOBEC3G, which acts in a processive manner, possibly suggesting that evolutionary pressure has altered the ability of DNA deaminases to act in a processive or distributive manner, depending on the physiological need.

Genetic and in vitro assays of DNA deamination.

The DNA deaminase family encompasses enzymes that have been highly conserved throughout vertebrate evolution and which display wide-ranging positive effects upon innate and adaptive immune system and development. Activation-induced cytidine deaminase was identified as a DNA mutator after its necessity in the successful development of high-affinity B cells via somatic hypermutation, class switch recombination, and gene conversion was determined. APOBEC3 exhibits the ability to deaminate retroviral first strand cDNA in a variety of viral infections, including HIV and hepatitis. Recent work has highlighted the potential importance of activation-induced cytidine deaminase (AID) and APOBEC1 in epigenetic reprogramming, and also the role that AID and the APOBECs may have in the development of cancer. In addition to the known activities of these members of the protein family, there are still other deaminases, such as APOBEC2, whose targets and functions are as yet unknown. This chapter provides the details of two assays that have proved to be invaluable in elucidating the exact specificities of deaminases both in vitro and in Escherichia coli. The application of these assays to future studies of the deaminase family will provide an indispensible tool in determining the potentially diverse functions of the remainder of this family of enzymes.

Evolution of the AID/APOBEC family of polynucleotide (deoxy)cytidine deaminases.

The AID/APOBEC family (comprising AID, APOBEC1, APOBEC2, and APOBEC3 subgroups) contains members that can deaminate cytidine in RNA and/or DNA and exhibit diverse physiological functions (AID and APOBEC3 deaminating DNA to trigger pathways in adaptive and innate immunity; APOBEC1 mediating apolipoprotein B RNA editing). The founder member APOBEC1, which has been used as a paradigm, is an RNA-editing enzyme with proposed antecedents in yeast. Here, we have undertaken phylogenetic analysis to glean insight into the primary physiological function of the AID/APOBEC family. We find that although the family forms part of a larger superfamily of deaminases distributed throughout the biological world, the AID/APOBEC family itself is restricted to vertebrates with homologs of AID (a DNA deaminase that triggers antibody gene diversification) and of APOBEC2 (unknown function) identifiable in sequence databases from bony fish, birds, amphibians, and mammals. The cloning of an AID homolog from dogfish reveals that AID extends at least as far back as cartilaginous fish. Like mammalian AID, the pufferfish AID homolog can trigger deoxycytidine deamination in DNA but, consistent with its cold-blooded origin, is thermolabile. The fine specificity of its mutator activity and the biased codon usage in pufferfish IgV genes appear broadly similar to that of their mammalian counterparts, consistent with a coevolution of the antibody mutator and its substrate for the optimal targeting of somatic mutation during antibody maturation. By contrast, APOBEC1 and APOBEC3 are later evolutionary arrivals with orthologs not found in pufferfish (although synteny with mammals is maintained in respect of the flanking loci). We conclude that AID and APOBEC2 are likely to be the ancestral members of the AID/APOBEC family (going back to the beginning of vertebrate speciation) with both APOBEC1 and APOBEC3 being mammal-specific derivatives of AID and a complex set of domain shuffling underpinning the expansion and evolution of the primate APOBEC3s.

Activation-induced cytidine deaminase deaminates 5-methylcytosine in DNA and is expressed in pluripotent tissues: implications for epigenetic reprogramming.

DNA deaminases of the Aid/Apobec family convert cytosine into uracil and play key roles in acquired and innate immunity. The epigenetic modification by methylation of cytosine in CpG dinucleotides is also mutagenic, but this is thought to occur by spontaneous deamination. Here we show that Aid and Apobec1 are 5-methylcytosine deaminases resulting in a thymine base opposite a guanine. Their action can thus lead to C --> T transition mutations in methylated DNA, or in conjunction with repair of the T:G mismatch, to demethylation. The Aid and Apobec1 genes are located in a cluster of pluripotency genes including Nanog and Stella and are co-expressed with these genes in oocytes, embryonic germ cells, and embryonic stem cells. These results suggest that Aid and perhaps some of its family members may have roles in epigenetic reprogramming and cell plasticity. Transition in CpG dinucleotides is the most frequent mutation in human genetic diseases, and sequence context analysis of CpG transitions in the APC tumor suppressor gene suggests that DNA deaminases may play a significant role in tumor etiology.

Comparison of the differential context-dependence of DNA deamination by APOBEC enzymes: correlation with mutation spectra in vivo.

To investigate the extent to which in vivo mutation spectra might reflect the intrinsic specificities of active mutators, genetic and biochemical assays were used to analyse the DNA target specificities of cytidine deaminases of the APOBEC family. The results reveal the critical importance of nucleotides immediately 5' of the targeted C for the specificity of all three enzymes studied (AID, APOBEC1 and APOBEC3G). At position -1, APOBEC1 showed a marked preference for dT, AID for dA/dG and APOBEC3G a strong preference for dC. Furthermore, AID and APOBEC3G showed distinct dependence on the nucleotide at position -2 with dA/dT being favoured by AID and dC by APOBEC3G. Most if not all activity of the recombinant deaminases on free dC could be attributed to low-level contamination by host enzymes. The target preference of APOBEC3G supports it being a major but possibly not sole contributor to HIV hypermutation without making it a dominant contribution to general HIV sequence variation. The specificity of AID as deduced from the genetic assay (which relies on inactivation of sacB of Bacillus subtilis) agrees well with that deduced by Pham et al. using an in vitro assay although we postulate that major intrinsic mutational hotspots in immunoglobulin V genes in vivo might reflect favoured sites of AID action being generated by proximal DNA targets located on opposite DNA strands. The target specificity of AID also accords with the spectrum of mutations observed in B lymphoma-associated oncogenes. The possibility of deaminase involvement in non-lymphoid human tumours is hinted at by tissue-specific differences in the spectra of dC transitions in tumour-suppressor genes. Thus, the patterns of hypermutation in antibodies and retroviruses owe much to the intrinsic sequence preferences of the AID/APOBEC family of DNA deaminases: analogous biases might also contribute to the spectra of cancer-associated mutation.