The discovery and characterization of activation-induced cytidine deaminase (AID) 10 years ago provided the basis for a mechanistic understanding of secondary antibody diversification and the subsequent generation and maintenance of cellular memory in B lymphocytes, which signified a major advance in the field of B cell immunology. Here we celebrate and review the triumphs in the mission to understand the mechanisms through which AID influences antibody diversification, as well as the implications of AID function on human physiology. We also take time to point out important ongoing controversies and outstanding questions in the field and highlight key experiments and techniques that hold the potential to elucidate the remaining mysteries surrounding this vital protein.
Specification of cell identity and the proper functioning of a mature cell depend on precise regulation of gene expression. Both binary ON/OFF regulation of transcription, as well as more fine-tuned control of transcription levels in the ON state, are required to define cell types. The Drosophila melanogaster Hox gene, Ultrabithorax (Ubx), exhibits both of these modes of control during development. While ON/OFF regulation is needed to specify the fate of the developing wing (Ubx OFF) and haltere (Ubx ON), the levels of Ubx within the haltere differ between compartments along the proximal-distal axis. Here, we identify and molecularly dissect the novel contribution of a previously identified Ubx cis-regulatory module (CRM), anterobithorax (abx), to a negative auto-regulatory loop that decreases Ubx expression in the proximal compartment of the haltere as compared to the distal compartment. We find that Ubx, in complex with the known Hox cofactors, Homothorax (Hth) and Extradenticle (Exd), acts through low-affinity Ubx-Exd binding sites to reduce the levels of Ubx transcription in the proximal compartment. Importantly, we also reveal that Ubx-Exd-binding site mutations sufficient to result in de-repression of abx activity in a transgenic context are not sufficient to de-repress Ubx expression when mutated at the endogenous locus, suggesting the presence of multiple mechanisms through which Ubx-mediated repression occurs. Our results underscore the complementary nature of CRM analysis through transgenic reporter assays and genome modification of the endogenous locus; but, they also highlight the increasing need to understand gene regulation within the native context to capture the potential input of multiple genomic elements on gene control.
Protein-protein interactions are typically identified by either biochemical purification coupled to mass spectrometry or genetic approaches exemplified by the yeast two-hybrid assay; however, neither assay works well for the identification of cofactors for poorly soluble proteins. Solubility of a poorly soluble protein is thought to increase upon cofactor binding, possibly by masking otherwise exposed hydrophobic domains. We have exploited this notion to develop a high-throughput genetic screen to identify interacting partners of an insoluble protein fused to chloramphenicol acetyltransferase by monitoring the survival of bacteria in the presence of a drug. In addition to presenting proof-of-principle experiments, we apply this screen to activation-induced cytidine deaminase (AID), a poorly soluble protein that is essential for antibody diversification. We identify a unique cofactor, RING finger protein 126 (RNF126), verify its interaction by traditional techniques, and show that it has functional consequences as RNF126 is able to ubiquitylate AID. Our results underpin the value of this screening technique and suggest a unique form of AID regulation involving RNF126 and ubiquitylation.ubiquitin | immunology | lymphocyte M ost large-scale protein-protein interaction data published to date has been produced with yeast two-hybrid assays (1-3) and in vivo pull-down approaches followed by mass spectrometry to identify proteins that coprecipitate with the protein of interest. Although these purification methods were first developed for small-scale protein identification experiments, they have been successfully adapted for use in genome-wide proteomics studies (4-6). Proteins that are poorly soluble or insoluble when ectopically expressed are least amenable to characterization using these tools. Improper folding or exposure of hydrophobic domains can result in insolubility when proteins are expressed individually; however, soluble complexes can form upon coexpression of a native partner. Based on this idea, we have devised a high-throughput protein-protein interaction screen, which involves the coexpression and cofolding of two proteins: an unknown protein expressed from a cDNA library and a known, insoluble "bait" fused to a protein that confers antibiotic resistance. Thus, solubility is directly linked to a traceable marker. We apply this technique to identify cofactors for activation-induced cytidine deaminase (AID), an enzyme that deaminates deoxycytidines in single-stranded DNA.AID initiates both somatic hypermutation (SHM) and classswitch recombination (CSR) during antibody diversification (7,8). A number of cofactors have been identified by a combination of genetic and proteomic approaches, which suggest that AID synchronizes with other broadly important cellular pathways including, but not limited to, RNA splicing and processing (9, 10), cellular trafficking (11)(12)(13)(14), and transcription/RNA polymerase stalling (8,(15)(16)(17); however, a concise picture of the players involved in the AID reaction and the...
We characterized the establishment of an Epidermal Growth Factor Receptor (EGFR) organizing center (EOC) during leg development in Drosophila melanogaster. Initial EGFR activation occurs in the center of leg discs by expression of the EGFR ligand Vn and the EGFR ligand-processing protease Rho, each through single enhancers, vnE and rhoE, that integrate inputs from Wg, Dpp, Dll and Sp1. Deletion of vnE and rhoE eliminates vn and rho expression in the center of the leg imaginal discs, respectively. Animals with deletions of both vnE and rhoE (but not individually) show distal but not medial leg truncations, suggesting that the distal source of EGFR ligands acts at short-range to only specify distal-most fates, and that multiple additional ‘ring’ enhancers are responsible for medial fates. Further, based on the cis-regulatory logic of vnE and rhoE we identified many additional leg enhancers, suggesting that this logic is broadly used by many genes during Drosophila limb development.
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