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.
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.
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.
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