AID and partners: for better and (not) for worse

Activation-induced cytidine deaminase in tertiary lymphoid structures: dual roles and implications in cancer prognosis

Activation-induced cytidine deaminase (AID) serves as a critical molecular orchestrator in the germinal center (GC) reaction within secondary lymphoid organs (SLOs), driving the production of high-affinity antibodies through somatic hypermutation. While its pathological implications are well-documented - including ectopic expression in non-B cell populations and transcriptional dysregulation linked to hematological malignancies and solid tumorigenesis - the cellular provenance of AID in solid tumors remains an unresolved paradox. This review advances two principal hypotheses: (1) AID may derive from tertiary lymphoid structures (TLSs), ectopic immune niches mirroring SLO organization, and (2) exhibits context-dependent transcriptional duality, capable of both potentiating and suppressing gene expression based on microenvironmental cues. Through systematic analysis of AID/GC involvement across cancer subtypes, we delineate mechanistic connections between lymphoid neogenesis and tumor progression. Our examination extends to TLS architecture, revealing three critical dimensions: (i) structural organization and cellular heterogeneity, (ii) developmental trajectories, and (iii) bidirectional interactions with tumor microenvironments. Crucially, we establish functional parallels between tumor-infiltrating B cells (TIL-Bs) in SLOs versus TLSs, while elucidating the differential roles of AID in canonical GC versus TLS-associated GC formation. This synthesis ultimately proposes that AID's functional dichotomy - acting as both oncogenic collaborator and tumor suppressor - underlies the paradoxical prognostic associations observed with TLS presence across malignancies. The review thereby provides a conceptual framework reconciling AID's dual functionality with the context-dependent immunobiology of tumor-associated lymphoid structures.

Epigenetic activation of JAG1 by AID contributes to metastasis of hepatocellular carcinoma

Metastasis is a major cause of fatality in hepatocellular carcinoma (HCC), although the precise mechanisms driving the metastatic process remain incompletely understood. In this study, we have made several important findings. Firstly, we have discovered that elevated activation-induced cytidine deaminase (AID) expression is positively correlated with Jagged 1 (JAG1) levels in clinically metastatic HCC patients. Moreover, we observed that depletion of either AID or JAG1 leads to a reduction in HCC metastasis. Secondly, we have identified AID acts as a transcriptional regulator that regulates JAG1 transcription by interacting with histone acetyltransferase 1 (HAT1) in metastatic HCC cells. Furthermore, our results demonstrate that any domains of AID can cooperate with HAT1 to enhance JAG1 transcription. Importantly, we have determined that the AID/HAT1 complex directly binds to specific regions within the JAG1 gene body, specifically -1.504 kb to -1.104 kb region, thereby influencing the epigenetic state of the JAG1 promoter through modulating histone methylation, histone acetylation, and DNA methylation. Furthermore, we have elucidated that the AID-JAG1/NOTCH-c-FOS axis plays a pivotal role in facilitating HCC metastasis. Consequently, the inhibitory effects of MG149 on both AID and JAG1 significantly mitigate the progression of HCC. This investigation uncovers a heretofore unappreciated function of AID as a transcriptional regulator in the metastasis of HCC, heralding a promising therapeutic approach.

The off-target effects of AID in carcinogenesis

Activation-induced cytidine deaminase (AID) plays a crucial role in promoting B cell diversification through somatic hypermutation (SHM) and class switch recombination (CSR). While AID is primarily associated with the physiological function of humoral immune response, it has also been linked to the initiation and progression of lymphomas. Abnormalities in AID have been shown to disrupt gene networks and signaling pathways in both B-cell and T-cell lineage lymphoblastic leukemia, although the full extent of its role in carcinogenesis remains unclear. This review proposes an alternative role for AID and explores its off-target effects in regulating tumorigenesis. In this review, we first provide an overview of the physiological function of AID and its regulation. AID plays a crucial role in promoting B cell diversification through SHM and CSR. We then discuss the off-target effects of AID, which includes inducing mutations of non-Igs, epigenetic modification, and the alternative role as a cofactor. We also explore the networks that keep AID in line. Furthermore, we summarize the off-target effects of AID in autoimmune diseases and hematological neoplasms. Finally, we assess the off-target effects of AID in solid tumors. The primary focus of this review is to understand how and when AID targets specific gene loci and how this affects carcinogenesis. Overall, this review aims to provide a comprehensive understanding of the physiological and off-target effects of AID, which will contribute to the development of novel therapeutic strategies for autoimmune diseases, hematological neoplasms, and solid tumors.

Mechanism and regulation of class switch recombination by IgH transcriptional control elements

Class switch recombination (CSR) plays an important role in humoral immunity by generating antibodies with different effector functions. CSR to a particular antibody isotype is induced by external stimuli, and occurs between highly repetitive switch (S) sequences. CSR requires transcription across S regions, which generates long non-coding RNAs and secondary structures that promote accessibility of S sequences to activation-induced cytidine deaminase (AID). AID initiates DNA double-strand breaks (DSBs) intermediates that are repaired by general DNA repair pathways. Switch transcription is controlled by various regulatory elements, including enhancers and insulators. The current paradigm posits that transcriptional control of CSR involves long-range chromatin interactions between regulatory elements and chromatin loops-stabilizing factors, which promote alignment of partner S regions in a CSR centre (CSRC) and initiation of CSR. In this review, we focus on the role of IgH transcriptional control elements in CSR and the chromatin-based mechanisms underlying this control.

Activation-induced cytidine deaminase can target multiple topologies of double-stranded DNA in a transcription-independent manner

Activation-induced cytidine deaminase (AID) mutates immunoglobulin genes and acts genome-wide. AID targets robustly transcribed genes, and purified AID acts on single-stranded (ss) but not double-stranded (ds) DNA oligonucleotides. Thus, it is believed that transcription is the generator of ssDNA for AID. Previous cell-free studies examining the relationship between transcription and AID targeting have employed a bacterial colony count assay wherein AID reverts an antibiotic resistance stop codon in plasmid substrates, leading to colony formation. Here, we established a novel assay where kb-long dsDNA of varying topologies is incubated with AID, with or without transcription, followed by direct sequencing. This assay allows for an unselected and in-depth comparison of mutation frequency and pattern of AID targeting in the absence of transcription or across a range of transcription dynamics. We found that without transcription, AID targets breathing ssDNA in supercoiled and, to a lesser extent, in relaxed dsDNA. The most optimal transcription only modestly enhanced AID action on supercoiled dsDNA in a manner dependent on RNA polymerase speed. These data suggest that the correlation between transcription and AID targeting may reflect transcription leading to AID-accessible breathing ssDNA patches naturally occurring in de-chromatinized dsDNA, as much as being due to transcription directly generating ssDNA.

The IGH locus relocalizes to a "recombination compartment" in the perinucleolar region of differentiating B-lymphocytes

The immunoglobulin heavy chain (IGH) gene loci are subject to specific recombination events during B-cell differentiation including somatic hypermutation and class switch recombination which mark the end of immunoglobulin gene maturation in germinal centers of secondary lymph nodes. These two events rely on the activity of activation-induced cytidine deaminase (AID) which requires DNA double strand breaks be created, a potential danger to the cell. Applying 3D-fluorescence in situ hybridization coupled with immunofluorescence staining to a previously described experimental system recapitulating normal B-cell differentiation ex vivo, we have kinetically analyzed the radial positioning of the two IGH gene loci as well as their proximity with the nucleolus, heterochromatin and γH2AX foci. Our observations are consistent with the proposal that these IGH gene rearrangements take place in a specific perinucleolar “recombination compartment” where AID could be sequestered thus limiting the extent of its potentially deleterious off-target effects.

Essential role of immobilized chemokine CXCL12 in the regulation of the humoral immune response

Chemokines control the migration of a large array of cells by binding to specific receptors on cell surfaces. The biological function of chemokines also depends on interactions between nonreceptor binding domains and proteoglycans, which mediate chemokine immobilization on cellular or extracellular surfaces and formation of fixed gradients. Chemokine gradients regulate synchronous cell motility and integrin-dependent cell adhesion. Of the various chemokines, CXCL12 has a unique structure because its receptor-binding domain is distinct and does not overlap with the immobilization domains. Although CXCL12 is known to be essential for the germinal center (GC) response, the role of its immobilization in biological functions has never been addressed. In this work, we investigated the unexplored paradigm of CXCL12 immobilization during the germinal center reaction, a fundamental process where cellular traffic is crucial for the quality of humoral immune responses. We show that the structure of murine germinal centers and the localization of GC B cells are impaired when CXCL12 is unable to bind to cellular or extracellular surfaces. In such mice, B cells carry fewer somatic mutations in Ig genes and are impaired in affinity maturation. Therefore, immobilization of CXCL12 is necessary for proper trafficking of B cells during GC reaction and for optimal humoral immune responses.

Epigenetics of Peripheral B-Cell Differentiation and the Antibody Response

Epigenetic modifications, such as histone post-translational modifications, DNA methylation, and alteration of gene expression by non-coding RNAs, including microRNAs (miRNAs) and long non-coding RNAs (lncRNAs), are heritable changes that are independent from the genomic DNA sequence. These regulate gene activities and, therefore, cellular functions. Epigenetic modifications act in concert with transcription factors and play critical roles in B cell development and differentiation, thereby modulating antibody responses to foreign- and self-antigens. Upon antigen encounter by mature B cells in the periphery, alterations of these lymphocytes epigenetic landscape are induced by the same stimuli that drive the antibody response. Such alterations instruct B cells to undergo immunoglobulin (Ig) class switch DNA recombination (CSR) and somatic hypermutation (SHM), as well as differentiation to memory B cells or long-lived plasma cells for the immune memory. Inducible histone modifications, together with DNA methylation and miRNAs modulate the transcriptome, particularly the expression of activation-induced cytidine deaminase, which is essential for CSR and SHM, and factors central to plasma cell differentiation, such as B lymphocyte-induced maturation protein-1. These inducible B cell-intrinsic epigenetic marks guide the maturation of antibody responses. Combinatorial histone modifications also function as histone codes to target CSR and, possibly, SHM machinery to the Ig loci by recruiting specific adaptors that can stabilize CSR/SHM factors. In addition, lncRNAs, such as recently reported lncRNA-CSR and an lncRNA generated through transcription of the S region that form G-quadruplex structures, are also important for CSR targeting. Epigenetic dysregulation in B cells, including the aberrant expression of non-coding RNAs and alterations of histone modifications and DNA methylation, can result in aberrant antibody responses to foreign antigens, such as those on microbial pathogens, and generation of pathogenic autoantibodies, IgE in allergic reactions, as well as B cell neoplasia. Epigenetic marks would be attractive targets for new therapeutics for autoimmune and allergic diseases, and B cell malignancies.

Parp3 negatively regulates immunoglobulin class switch recombination

To generate highly specific and adapted immune responses, B cells diversify their antibody repertoire through mechanisms involving the generation of programmed DNA damage. Somatic hypermutation (SHM) and class switch recombination (CSR) are initiated by the recruitment of activation-induced cytidine deaminase (AID) to immunoglobulin loci and by the subsequent generation of DNA lesions, which are differentially processed to mutations during SHM or to double-stranded DNA break intermediates during CSR. The latter activate the DNA damage response and mobilize multiple DNA repair factors, including Parp1 and Parp2, to promote DNA repair and long-range recombination. We examined the contribution of Parp3 in CSR and SHM. We find that deficiency in Parp3 results in enhanced CSR, while SHM remains unaffected. Mechanistically, this is due to increased occupancy of AID at the donor (Sμ) switch region. We also find evidence of increased levels of DNA damage at switch region junctions and a bias towards alternative end joining in the absence of Parp3. We propose that Parp3 plays a CSR-specific role by controlling AID levels at switch regions during CSR.

During infections, B cells diversify the antibodies they produce by two mechanisms: somatic hypermutation (SHM) and class switch recombination (CSR). SHM mutates the regions encoding the antigen-binding site, generating high-affinity antibodies. CSR allows B cells to switch the class of antibody they produce (from IgM to IgA, IgG or IgE), providing novel effector functions. Together, SHM and CSR establish highly specific and pathogen-adapted antibody responses. SHM and CSR are initiated by the recruitment of the activation-induced cytidine deaminase (AID) enzyme to antibody genes. Once recruited, AID induces DNA lesions that are processed into mutations during SHM or chromosomal DNA breaks during CSR. These breaks activate multiple DNA repair proteins and are resolved by replacing the IgM gene segments by those encoding IgA, IgG or IgE. AID carries a significant oncogenic potential that needs to be controlled to preserve genome integrity. Nevertheless, the underlying mechanisms remain poorly understood. Here we show that Poly(ADP)ribose polymerase 3 (Parp3), an enzyme recently implicated in DNA repair, contributes to antibody diversification by negatively regulating CSR without affecting SHM. We show that Parp3 facilitates the repair of AID-induced DNA damage and controls AID levels on chromatin. We propose that Parp3 protects antibody genes from sustained AID-dependent DNA damage.

Isotype-switched follicular lymphoma displays dissociation between activation-induced cytidine deaminase expression and somatic hypermutation

In B-cells, activation-induced cytidine deaminase (AID) is required for somatic hypermutation (SHM) and class switch recombination (CSR) of immunoglobulin genes. AID introduces mutations in immunoglobulin variable regions (IGV) during B-cell receptor affinity maturation, but may also introduce aberrant mutations into non-immunoglobulin genes, most commonly BCL6. Follicular lymphoma (FL) B-cells constitutively express AID and undergo CSR, SHM and aberrant SHM. We have studied AID expression, the presence of SHM mutations, CSR, and aberrant SHM in BCL6 in a cohort of 75 FL patients. Whereas IgM-expressing (non-switched) FL were characterized by an expected positive correlation between AID and IGV and BCL6 mutations, isotype-switched FL showed dissociation between AID expression and aberrant SHM, and inverse correlation between SHM and AID expression. Our results unveil two manifest biological subgroups of FL and indicate that the specific dissociation between AID and SHM after isotype switch may correlate with the clinical outcome of this heterogeneous disease.

IgH chain class switch recombination: mechanism and regulation

IgH class switching occurs rapidly after activation of mature naive B cells, resulting in a switch from expression of IgM and IgD to expression of IgG, IgE, or IgA; this switch improves the ability of Abs to remove the pathogen that induces the humoral immune response. Class switching occurs by a deletional recombination between two switch regions, each of which is associated with a H chain constant region gene. Class switch recombination (CSR) is instigated by activation-induced cytidine deaminase, which converts cytosines in switch regions to uracils. The uracils are subsequently removed by two DNA-repair pathways, resulting in mutations, single-strand DNA breaks, and the double-strand breaks required for CSR. We discuss several aspects of CSR, including how CSR is induced, CSR in B cell progenitors, the roles of transcription and chromosomal looping in CSR, and the roles of certain DNA-repair enzymes in CSR.

APOBEC3A is implicated in a novel class of G-to-A mRNA editing in WT1 transcripts

Classic deamination mRNA changes, including cytidine to uridine (C-to-U) and adenosine to inosine (A-to-I), are important exceptions to the central dogma and lead to significant alterations in gene transcripts and products. Although there are a few reports of non-classic mRNA alterations, as yet there is no molecular explanation for these alternative changes. Wilms Tumor 1 (WT1) mutations and variants are implicated in several diseases, including Wilms tumor and acute myeloid leukemia (AML). We observed two alternative G-to-A changes, namely c.1303G>A and c.1586G>A in cDNA clones and found them to be recurrent in a series of 21 umbilical cord blood mononuclear cell (CBMC) samples studied. Two less conserved U-to-C changes were also observed. These alternative changes were found to be significantly higher in non-progenitor as compared to progenitor CBMCs, while they were found to be absent in a series of AML samples studied, indicating they are targeted, cell type-specific mRNA editing modifications. Since APOBEC/ADAR family members are implicated in RNA/DNA editing, we screened them by RNA-interference (RNAi) for WT1-mRNA changes and observed near complete reversal of WT1 c.1303G>A alteration upon APOBEC3A (A3A) knockdown. The role of A3A in mediating this change was confirmed by A3A overexpression in Fujioka cells, which led to a significant increase in WT1 c.1303G>A mRNA editing. Non-progenitor CBMCs showed correspondingly higher levels of A3A-mRNA and protein as compared to the progenitor ones. To our knowledge, this is the first report of mRNA modifying activity for an APOBEC3 protein and implicates A3A in a novel G-to-A form of editing. These findings open the way to further investigations into the mechanisms of other potential mRNA changes, which will help to redefine the RNA editing paradigm in both health and disease.

Epigenetic function of activation-induced cytidine deaminase and its link to lymphomagenesis

Activation-induced cytidine deaminase (AID) is essential for somatic hypermutation and class switch recombination of immunoglobulin (Ig) genes during B cell maturation and immune response. Expression of AID is tightly regulated due to its mutagenic and recombinogenic potential, which is known to target not only Ig genes, but also non-Ig genes, contributing to lymphomagenesis. In recent years, a new epigenetic function of AID and its link to DNA demethylation came to light in several developmental systems. In this review, we summarize existing evidence linking deamination of unmodified and modified cytidine by AID to base-excision repair and mismatch repair machinery resulting in passive or active removal of DNA methylation mark, with the focus on B cell biology. We also discuss potential contribution of AID-dependent DNA hypomethylation to lymphomagenesis.

Mechanisms regulating the targeting and activity of activation induced cytidine deaminase

Activation induced cytidine deaminase (AID) plays a central role in the vertebrate adaptive immune response, initiating immunoglobulin (Ig) somatic hypermutation (SHM) and class-switch recombination (CSR). AID converts deoxycytosine (dC) in the DNA to deoxyuridine (dU), causing a DNA base-pairing mismatch. How this mismatch is recognised and resolved determines whether the site will undergo mutation, recombination or high-fidelity repair. Although AID action is essential for antibody diversification it is also known to act upon many non-Ig genes where it can cause tumourigenic mutations and translocations. Although much is known about the pathways of Ig diversification, there is still very little known about the mechanisms that target AID to its sites of action and regulate the different repair processes that can participate at these sites.

Why does somatic hypermutation by AID require transcription of its target genes?

In this review, I discuss the currently available experimental evidence concerning the molecular interactions of the activation-induced cytidine deaminase (AID) with transcription of its target genes. The basic question that underlies the transcription relationship is how the process of somatic hypermutation of Ig genes can be restricted to their variable (V) regions. This hallmark of SHM assures that high affinity antibodies can be created while the biological functions of their constant (C) region are undisturbed. I present a revised model of AID function in somatic hypermutation (SHM): In a B cell that produces AID protein and undergoes mutation of the V regions of the expressed Ig heavy and light chain genes, only some of the transcription complexes initiating at the active V-region promoters are associated with AID. When AID travels with the elongating RNA polymerase (pol), it attracts proteins that cause the pausing/stalling of pol and termination of transcription, followed by termination of SHM. This differential AID loading model would allow the mutating B cell to continue producing full-length Ig proteins that are required to avoid apoptosis by permitting the cell to assemble functional B cell receptors.

Scaffold functions of 14-3-3 adaptors in B cell immunoglobulin class switch DNA recombination

Class switch DNA recombination (CSR) of the immunoglobulin heavy chain (IgH) locus crucially diversifies antibody biological effector functions. CSR involves the induction of activation-induced cytidine deaminase (AID) expression and AID targeting to switch (S) regions by 14-3-3 adaptors. 14-3-3 adaptors specifically bind to 5'-AGCT-3' repeats, which make up for the core of all IgH locus S regions. They selectively target the upstream and downstream S regions that are set to undergo S-S DNA recombination. We hypothesized that 14-3-3 adaptors function as scaffolds to stabilize CSR enzymatic elements on S regions. Here we demonstrate that all seven 14-3-3β, 14-3-3ε, 14-3-3γ, 14-3-3η, 14-3-3σ, 14-3-3τ and 14-3-3ζ adaptors directly interacted with AID, PKA-Cα (catalytic subunit) and PKA-RIα (regulatory inhibitory subunit) and uracil DNA glycosylase (Ung). 14-3-3 adaptors, however, did not interact with AID C-terminal truncation mutant AIDΔ(180-198) or AIDF193A and AIDL196A point-mutants (which have been shown not to bind to S region DNA and fail to mediate CSR). 14-3-3 adaptors colocalized with AID and replication protein A (RPA) in B cells undergoing CSR. 14-3-3 and AID binding to S region DNA was disrupted by viral protein R (Vpr), an accessory protein of human immunodeficiency virus type-1 (HIV-1), which inhibited CSR without altering AID expression or germline IH-CH transcription. Accordingly, we demonstrated that 14-3-3 directly interact with Vpr, which in turn, also interact with AID, PKA-Cα and Ung. Altogether, our findings suggest that 14-3-3 adaptors play important scaffold functions and nucleate the assembly of multiple CSR factors on S regions. They also show that such assembly can be disrupted by a viral protein, thereby allowing us to hypothesize that small molecule compounds that specifically block 14-3-3 interactions with AID, PKA and/or Ung can be used to inhibit unwanted CSR.

Active demethylation in mouse zygotes involves cytosine deamination and base excision repair

BACKGROUND

DNA methylation in mammals is an epigenetic mark necessary for normal embryogenesis. During development active loss of methylation occurs in the male pronucleus during the first cell cycle after fertilisation. This is accompanied by major chromatin remodelling and generates a marked asymmetry between the paternal and maternal genomes. The mechanism(s) by which this is achieved implicate, among others, base excision repair (BER) components and more recently a major role for TET3 hydroxylase. To investigate these methylation dynamics further we have analysed DNA methylation and hydroxymethylation in fertilised mouse oocytes by indirect immunofluorescence (IF) and evaluated the relative contribution of different candidate factors for active demethylation in knock-out zygotes by three-dimensional imaging and IF semi-quantification.

RESULTS

We find two distinct phases of loss of paternal methylation in the zygote, one prior to and another coincident with, but not dependent on, DNA replication. TET3-mediated hydroxymethylation is limited to the replication associated second phase of demethylation. Analysis of cytosine deaminase (AID) null fertilised oocytes revealed a role for this enzyme in the second phase of loss of paternal methylation, which is independent from hydroxymethylation. Investigation into the possible repair pathways involved supports a role for AID-mediated cytosine deamination with subsequent U-G mismatch long-patch BER by UNG2 while no evidence could be found for an involvement of TDG.

CONCLUSIONS

There are two observable phases of DNA demethylation in the mouse zygote, before and coincident with DNA replication. TET3 is only involved in the second phase of loss of methylation. Cytosine deamination and long-patch BER mediated by UNG2 appear to independently contribute to this second phase of active demethylation. Further work will be necessary to elucidate the mechanism(s) involved in the first phase of active demethylation that will potentially involve activities required for early sperm chromatin remodelling.

Activation-induced cytidine deaminase (AID) is strongly expressed in the fetal bovine ileal Peyer's patch and spleen and is associated with expansion of the primary antibody repertoire in the absence of exogenous antigens

Due to a limited range of immunoglobulin (Ig) genes, cattle and several other domestic animals rely on postrecombinatorial amplification of the primary repertoire. We report that activation-induced cytidine deaminase (AID) is strongly expressed in the fetal bovine ileal Peyer's patch and spleen but not in fetal bone marrow. The numbers of IGHV (immunoglobulin heavy chain variable) mutations correlate with AID expression. The mutational profile in the fetuses is similar to postnatal and immunized calves, with targeting of complementarity-determining region (CDR) over framework region (FR), preference of replacement over silent mutations in CDRs but not in FRs, and targeting of the AID hotspot motif RGYW/WRCY. Statistical analysis indicates negative selection on FRs and positive selection on CDRs. Our results suggest that AID-mediated somatic hypermutation and selection take place in bovine fetuses, implying a role for AID in the diversification of the primary antibody repertoire in the absence of exogenous antigens.

Epigenetics of the antibody response

Epigenetic marks, such as DNA methylation, histone post-translational modifications and miRNAs, are induced in B cells by the same stimuli that drive the antibody response. They play major roles in regulating somatic hypermutation (SHM), class switch DNA recombination (CSR), and differentiation to plasma cells or long-lived memory B cells. Histone modifications target the CSR and, possibly, SHM machinery to the immunoglobulin locus; they together with DNA methylation and miRNAs modulate the expression of critical elements of that machinery, such as activation-induced cytidine deaminase (AID), as well as factors central to plasma cell differentiation, such as B lymphocyte-induced maturation protein-1 (Blimp-1). These inducible B cell-intrinsic epigenetic marks instruct the maturation of antibody responses. Their dysregulation plays an important role in aberrant antibody responses to foreign antigens, such as those of microbial pathogens, and self-antigens, such as those targeted in autoimmunity, and B cell neoplasia.

Induction of activation-induced cytidine deaminase-targeting adaptor 14-3-3γ is mediated by NF-κB-dependent recruitment of CFP1 to the 5'-CpG-3'-rich 14-3-3γ promoter and is sustained by E2A

Class switch DNA recombination (CSR) crucially diversifies Ab biologic effector functions. 14-3-3γ specifically binds to the 5'-AGCT-3' repeats in the IgH locus switch (S) regions. By interacting directly with the C-terminal region of activation-induced cytidine deaminase (AID), 14-3-3γ targets this enzyme to S regions to mediate CSR. In this study, we showed that 14-3-3γ was expressed in germinal center B cells in vivo and induced in B cells by T-dependent and T-independent primary CSR-inducing stimuli in vitro in humans and mice. Induction of 14-3-3γ was rapid, peaking within 3 h of stimulation by LPSs, and sustained over the course of AID and CSR induction. It was dependent on recruitment of NF-κB to the 14-3-3γ gene promoter. The NF-κB recruitment enhanced the occupancy of the CpG island within the 14-3-3γ promoter by CFP1, a component of the COMPASS histone methyltransferase complex, and promoter-specific enrichment of histone 3 lysine 4 trimethylation (H3K4me3), which is indicative of open chromatin state and marks transcription-competent promoters. NF-κB also potentiated the binding of B cell lineage-specific factor E2A to an E-box motif located immediately downstream of the two closely-spaced transcription start sites for sustained 14-3-3γ expression and CSR induction. Thus, 14-3-3γ induction in CSR is enabled by the CFP1-mediated H3K4me3 enrichment in the promoter, dependent on NF-κB and sustained by E2A.

The role of activation-induced deaminase in antibody diversification and genomic instability

More than a decade ago, activation-induced deaminase (AID) was identified as the initiator for somatic hypermutation (SHM) and class switch recombination (CSR). Since then, tremendous progress has been achieved toward elucidating how AID functions. AID targets the highly repetitive switch regions of the immunoglobulin heavy chain (IgH) locus to induce DNA double-strand breaks (DSBs), which can be rejoined, leading to switch of constant regions of antibody. When targeting to variable region exons of IgH and IgL loci, AID predominantly induces point mutations, termed SHM, resulting in increased affinity of antibody for antigen. While SHM and CSR enhance antibody diversity, AID-initiated DSBs and mutations may predispose B cells to carcinogenesis. This review focuses on the mechanisms that provide the specificity of AID targeting to Ig loci and the role of AID in genomic instability.

Changes in RNA polymerase II progression influence somatic hypermutation of Ig-related genes by AID

Ongoing transcription of the Ig gene coupled with temporary pausing within the targeted region facilitates somatic hypermutation.

Somatic hypermutation (SHM) of Ig genes is initiated by the activation-induced cytidine deaminase (AID), and requires target gene transcription. We previously proposed that AID may associate with the RNA polymerase II (Pol). Here, to determine aspects of the transcription process required for SHM, we knocked-in a transcription terminator into an Ig gene variable region in DT40 chicken B cell line. We found that the human β-globin terminator was an efficient inhibitor of downstream transcription in these cells. The terminator reduced mutations downstream of the poly(A) signal, suggesting that the process of transcription is essential for efficient SHM and that AID has better access to its target when Pol is in the elongating rather than terminating mode. Mutations upstream of the poly(A) site were almost doubled in the active terminator clones compared with an inactivated terminator, and this region showed more single-stranded DNA, indicating that Pol pausing assists SHM. Moreover, the nontranscribed DNA strand was the preferred SHM target upstream of the active terminator. Pol pausing during poly(A) site recognition may facilitate persistence of negative supercoils, exposing the coding single strand and possibly allowing the nascent RNA intermittent reannealing with the template strand, for prolonged access of AID.

Chromosome translocation, B cell lymphoma, and activation-induced cytidine deaminase

Studies of B cell lymphomas in the early 1980s led to the cloning of genes (c-MYC and IGH) at a chromosome translocation breakpoint. A rush followed to identify recurrently translocated genes in all types of cancer, which led to remarkable advances in our understanding of cancer genetics. B lymphocyte tumors commonly bear chromosome translocations to immunoglobulin genes, which points to a role for antibody gene diversification processes in tumorigenesis. The discovery of activation-induced cytidine deaminase (AID) and the use of murine models to study translocation have led to a new understanding of how these events contribute to the genesis of lymphomas. Here, we review these advances with a focus on AID and insights gained from the study of translocations in primary cells.

Close proximity to Igh is a contributing factor to AID-mediated translocations

Class switch recombination (CSR) has the potential to generate genomic instability in B cells as activation-induced cytidine deaminase (AID), which mediates this process, is known to target many sites outside Igh. Nonetheless we do not fully understand what factors influence AID targeting genome-wide. Given that errors in CSR can lead to dangerous, oncogenic chromosomal translocations it is important to identify the elements that determine which genes are at risk of being "hit" and could be involved in aberrant rearrangements. Here we have investigated the influence of nuclear organization in determining "off-target" activity and the choice of fusion partners. Our studies indicate that the vast majority of known AID-mediated Igh translocation partners are found in chromosomal domains that contact this locus during class switching. Further, these interaction domains can be used to identify other genes that are hit by AID.

An evolutionary view of the mechanism for immune and genome diversity

An ortholog of activation-induced cytidine deaminase (AID) was, evolutionarily, the first enzyme to generate acquired immune diversity by catalyzing gene conversion and probably somatic hypermutation (SHM). AID began to mediate class switch recombination (CSR) only after the evolution of frogs. Recent studies revealed that the mechanisms for generating immune and genetic diversity share several critical features. Meiotic recombination, V(D)J recombination, CSR, and SHM all require H3K4 trimethyl histone modification to specify the target DNA. Genetic instability related to dinucleotide or triplet repeats depends on DNA cleavage by topoisomerase 1, which also initiates DNA cleavage in both SHM and CSR. These similarities suggest that AID hijacked the basic mechanism for genome instability when AID evolved in jawless fish. Thus, the risk of introducing genome instability into nonimmunoglobulin loci is unavoidable but tolerable compared with the advantage conferred on the host of being protected against pathogens by the enormous Ig diversification.

Origin of immunoglobulin isotype switching

BACKGROUND

From humans to frogs, immunoglobulin class switching introduces different effector functions to antibodies through an intrachromosomal DNA recombination process at the heavy-chain locus. Although there are two conventional antibody classes (IgM, IgW) in sharks, their heavy chains are encoded by 20 to >100 miniloci. These representatives of the earliest jawed vertebrates possess a primordial immunoglobulin gene organization where each gene cluster is autonomous and contains a few rearranging gene segments (VH-D1-D2-JH) with one constant region, μ or ω.

RESULTS

V(D)J rearrangement always takes place within the μ cluster, but here we show that the VDJ can be expressed with constant regions from different clusters, although IgH genes are spatially distant, at >120 kb. Moreover, reciprocal exchanges take place between Igω and Igμ genes. Switching is augmented with deliberate immunization and is concomitant with somatic hypermutation activity. Because switching occurs independently of the partners' linkage position, some events involve transchromosomal recombination. The switch sites consist of direct joins between two genes in the 3' intron flanking JH.

CONCLUSIONS

Our data are consistent with a mechanism of cutting or joining of distal DNA lesions initiated by activation-induced cytidine deaminase (AID), in the absence of mammalian-type switch regions. We suggest that, in shark, with its many autonomous IgH targeted by programmed DNA breakage, factors predisposing broken DNA ends to translocate configured the earliest version of class switch recombination.

APOBEC3B and AID have similar nuclear import mechanisms

Members of the APOBEC (apolipoprotein B mRNA editing enzyme, catalytic polypeptide-like) protein family catalyze DNA cytosine deamination and underpin a variety of immune defenses. For instance, several family members, including APOBEC3B (A3B), elicit strong retrotransposon and retrovirus restriction activities. However, unlike the other proteins, A3B is the only family member with steady-state nuclear localization. Here, we show that A3B nuclear import is an active process requiring at least one amino acid (Val54) within an N-terminal motif analogous to the nuclear localization determinant of the antibody gene diversification enzyme AID (activation-induced cytosine deaminase). Mechanistic conservation with AID is further suggested by A3B's capacity to interact with the same subset of importin proteins. Despite these mechanistic similarities, enforced A3B expression cannot substitute for AID-dependent antibody gene diversification by class switch recombination. Regulatory differences between A3B and AID are also visible during cell cycle progression. Our studies suggest that the present-day A3B enzyme retained the nuclear import mechanism of an ancestral AID protein during the expansion of the APOBEC3 locus in primates. Our studies also highlight the likelihood that, after nuclear import, specialized mechanisms exist to guide these enzymes to their respective physiological substrates and prevent gratuitous chromosomal DNA damage.

Nucleosome stability dramatically impacts the targeting of somatic hypermutation

Somatic hypermutation (SHM) of immunoglobulin (Ig) genes is initiated by the activation-induced cytidine deaminase (AID). However, the influence of chromatin on SHM remains enigmatic. Our previous cell-free studies indicated that AID cannot access nucleosomal DNA in the absence of transcription. We have now investigated the influence of nucleosome stability on mutability in vivo. We introduced two copies of a high-affinity nucleosome positioning sequence (MP2) into a variable Ig gene region to assess its impact on SHM in vivo. The MP2 sequence significantly reduces the mutation frequency throughout the nucleosome, and especially near its center, despite proportions of AID hot spots similar to those in Ig genes. A weak positioning sequence (M5) was designed based on rules deduced from published whole-genome analyses. Replacement of MP2 with M5 resulted in much higher mutation rates throughout the nucleosome. This indicates that both nucleosome stability and positioning significantly influence the SHM pattern. We postulate that, unlike RNA polymerase, AID has reduced access to stable nucleosomes. This study outlines the limits of nucleosome positioning for SHM of Ig genes and suggests that stable nucleosomes may need to be disassembled for access of AID. Possibly the variable regions of Ig genes have evolved for low nucleosome stability to enhance access to AID, DNA repair factors, and error-prone polymerases and, hence, to maximize variability.

Hypermutation of ApoB mRNA by rat APOBEC-1 overexpression mimics APOBEC-3 hypermutation

APOBEC-3 proteins induce C-to-U hypermutations in the viral genome of various viruses and have broad antiviral activity. Generally, only a small proportion of viral genomes (<10(-)(2)) are hypermutated by APOBEC-3s, but often many cytidines (up to 40%) are converted into uridine. The mechanism of this unique selective hypermutation remains unknown. We found that rat APOBEC-1 overexpression had a hypermutation pattern similar to that of APOBEC-3s on its substrate apolipoprotein B (apoB) mRNA. Transient plasmid transfection of rat APOBEC-1 resulted in 0.4% and 1.8% hypermutations with apoB mRNA in HepG2 and McA7777 cells, respectively. The low frequency of hypermutated apoB mRNA targets was enriched by differential DNA denaturation PCR at 72-76 °C, with hypermutation levels increasing up to 67%. Up to 69.6% of cytidines in HepG2 and up to 75.5% of cytidines in McA7777 cells were converted into uridines in the hypermutated apoB mRNA. When rat APOBEC-1 was overexpressed by adenovirus, the hypermutation frequency of apoB mRNA increased from 0.4% to ∼20% and was readily detected by regular PCR. However, this higher expression efficiency only increased the frequency of hypermutation, not the number of affected cytidines in hypermutated targets. Rat APOBEC-1 hypermutation was modulated by cofactors and eliminated by an E181Q mutation, indicating the role of cofactors in hypermutation. The finding of an APOBEC-3 hypermutation pattern with rat APOBEC-1 suggests that cofactors could also be involved in APOBEC-3 hypermutation. Using hepatitis B virus hypermutation, we found that KSRP increased APOBEC-3C and APOBEC-3B hypermutation. These data show that, like rat APOBEC-1 hypermutation, cellular factors may play a regulatory role in APOBEC-3 hypermutation.

YY1 controls immunoglobulin class switch recombination and nuclear activation-induced deaminase levels

Activation-induced deaminase (AID) is an enzyme required for class switch recombination (CSR) and somatic hypermutation (SHM), processes that ensure antibody maturation and expression of different immunoglobulin isotypes. AID function is tightly regulated by tissue- and stage-specific expression, nuclear localization, and protein stability. Transcription factor YY1 is crucial for early B cell development, but its function at late B cell stages is unknown. Here, we show that YY1 conditional knockout in activated splenic B cells interferes with CSR. Knockout of YY1 did not affect B cell proliferation, transcription of the AID and IgM genes, or levels of various switch region germ line transcripts. However, we show that YY1 physically interacts with AID and controls the accumulation of nuclear AID, at least in part, by increasing nuclear AID stability. We show for the first time that YY1 plays a novel role in CSR and controls nuclear AID protein levels.

APOBEC3 proteins and genomic stability: the high cost of a good defense

The human APOBEC3 family of cytidine deaminases constitutes a cellular intrinsic defense mechanism that is effective against a range of viruses and retro-elements. While it is well established that these enzymes are powerful mutators of viral DNA, the possibility that their activity could threaten the integrity of the host genome has only recently begun to be investigated. Here, we discuss the implications of new evidence suggesting that APOBEC3 proteins can mediate the deamination of cellular DNA. The maintenance of genomic integrity in the face of this potential off-target activity must require high fidelity DNA repair and strict regulation of APOBEC3 gene expression and enzyme activity. Conversely, the ability of specific members of the APOBEC3 family to activate DNA damage signaling pathways might also reflect another way that these proteins contribute to the host immune response.

Optimal functional levels of activation-induced deaminase specifically require the Hsp40 DnaJa1

The enzyme activation-induced deaminase (AID) deaminates deoxycytidine at the immunoglobulin genes, thereby initiating antibody affinity maturation and isotype class switching during immune responses. In contrast, off-target DNA damage caused by AID is oncogenic. Central to balancing immunity and cancer is AID regulation, including the mechanisms determining AID protein levels. We describe a specific functional interaction between AID and the Hsp40 DnaJa1, which provides insight into the function of both proteins. Although both major cytoplasmic type I Hsp40s, DnaJa1 and DnaJa2, are induced upon B-cell activation and interact with AID in vitro, only DnaJa1 overexpression increases AID levels and biological activity in cell lines. Conversely, DnaJa1, but not DnaJa2, depletion reduces AID levels, stability and isotype switching. In vivo, DnaJa1-deficient mice display compromised response to immunization, AID protein and isotype switching levels being reduced by half. Moreover, DnaJa1 farnesylation is required to maintain, and farnesyltransferase inhibition reduces, AID protein levels in B cells. Thus, DnaJa1 is a limiting factor that plays a non-redundant role in the functional stabilization of AID.

Complex regulation and function of activation-induced cytidine deaminase

Activation-induced cytidine deaminase (AID) instigates mutations and DNA breaks in Ig genes that undergo somatic hypermutation and class switch recombination during B cell activation in response to immunization and infection. This review discusses how AID expression and activity are regulated, including recent discoveries of AID-interacting proteins that might recruit AID to Ig genes, and allow it to target both DNA strands. Also discussed is the accumulating evidence that AID binds to, mutates, and creates breaks at numerous non-Ig sites in the genome, which initiates cell transformation and malignancies.