Marilyn Diaz

The Translesion DNA Polymerase ζ Plays a Major Role in Ig and bcl-6 Somatic Hypermutation

Ig somatic mutations would be introduced by a polymerase (pol) while repairing DNA outside main DNA replication. We show that human B cells constitutively express the translesion pol zeta, which effectively extends DNA past mismatched bases (mispair extender), and pol eta, which bypasses DNA lesions in an error-free fashion. Upon B cell receptor (BCR) engagement and coculture with activated CD4+ T cells, these lymphocytes upregulated pol zeta, downregulated pol eta, and mutated the Ig and bcl-6 genes. Inhibition of the pol zeta REV3 catalytic subunit by specific phosphorothioate-modified oligonucleotides impaired Ig and bcl-6 hypermutation and UV damage-induced DNA mutagenesis, without affecting cell cycle or viability. Thus, pol zeta plays a critical role in Ig and bcl-6 hypermutation, perhaps facilitated by the downregulation of pol eta.

Cutting Edge: DGYW/WRCH Is a Better Predictor of Mutability at G:C Bases in Ig Hypermutation Than the Widely Accepted RGYW/WRCY Motif and Probably Reflects a Two-Step Activation-Induced Cytidine Deaminase-Triggered Process

A feature of Ig hypermutation is the presence of hypermutable DNA sequences that are preferentially found in the V regions of Ig genes. Among these, RGYW/WRCY is the most pronounced motif (G:C is a mutable position; R = A/G, Y = C/T, and W = A/T). However, a molecular basis for the high mutability of RGYW was not known until recently. The discovery that activation-induced cytidine deaminase targets the DNA encoding V regions, has enabled the analysis of its targeting properties when expressed outside of the context of hypermutation. We analyzed these data and found evidence that activation-induced cytidine deaminase is the major source of the RGYW mutable motif, but with a new twist: DGYW/WRCH (G:C is the mutable position; D = A/G/T, H = T/C/A) is a better descriptor of the Ig mutation hotspot than RGYW/WRCY. We also found evidence that a DNA repair enzyme may play a role in modifying the sequence of hypermutation hotspots.

Decreased Frequency of Somatic Hypermutation and Impaired Affinity Maturation but Intact Germinal Center Formation in Mice Expressing Antisense RNA to DNA Polymerase ζ

To examine a role of DNA polymerase ζ in somatic hypermutation, we generated transgenic mice that express antisense RNA to a portion of mouse REV3, the gene encoding this polymerase. These mice express high levels of antisense RNA, significantly reducing the levels of endogenous mouse REV3 transcript. Following immunization to a hapten-protein complex, transgenic mice mounted vigorous Ab responses, accomplished the switch to IgG, and formed numerous germinal centers. However, in most transgenic animals, the generation of high affinity Abs was delayed. In addition, accumulation of somatic mutations in the VH genes of memory B cells from transgenic mice was decreased, particularly among those that generate amino acid replacements that enhance affinity of the B cell receptor to the hapten. These data implicate DNA polymerase ζ, a nonreplicative polymerase, in the process of affinity maturation, possibly through a role in somatic hypermutation, clonal selection, or both.

Autoreactivity in an HIV-1 broadly reactive neutralizing antibody variable region heavy chain induces immunologic tolerance

We previously reported that some of the rare broadly reactive, HIV-1 neutralizing antibodies are polyreactive, leading to the hypothesis that induction of these types of neutralizing antibody may be limited by immunologic tolerance. However, the notion that such antibodies are sufficiently autoreactive to trigger B cell tolerance is controversial. To test directly whether rare neutralizing HIV-1 antibodies can activate immunologic tolerance mechanisms, we generated a knock-in mouse in which the Ig heavy chain (HC) variable region rearrangement (VHDJH) from the polyreactive and broadly neutralizing human monoclonal antibody 2F5 was targeted into the mouse Igh locus. In vitro, this insertion resulted in chimeric human/mouse 2F5 antibodies that were functionally similar to the human 2F5 antibody, including comparable reactivity to human and murine self-antigens. In vivo, the 2F5 VHDJH insertion supported development of large- and small pre-B cells that expressed the chimeric human/mouse Igμ chain but not the production of immature B cells expressing membrane IgM. The developmental arrest exhibited in 2F5 VHDJH knock-in mice is characteristic of other knock-in strains that express the Ig HC variable region of autoreactive antibodies and is consistent with the loss of immature B cells bearing 2F5 chimeric antibodies to central tolerance mechanisms. Moreover, homozygous 2F5 VHDJH knock-in mice support reduced numbers of residual splenic B cells with low surface IgM density, severely diminished serum IgM levels, but normal to elevated quantities of serum IgGs that did not react with autoantigens. These features are consistent with elimination of 2F5 HC autoreactivity by additional negative selection mechanism(s) in the periphery.

Mechanisms of environmental influence on human autoimmunity: A national institute of environmental health sciences expert panel workshop

The mechanisms leading to autoimmune diseases remain largely unknown despite numerous lines of experimental inquiry and epidemiological evidence. The growing number of genome-wide association studies and the largely incomplete concordance for autoimmune diseases in monozygotic twins support the role of the environment (including infectious agents and chemicals) in the breakdown of tolerance leading to autoimmunity via numerous mechanisms. The present article reviews the major theories on the mechanisms of the environmental influence on autoimmunity by addressing the different degrees of confidence that characterize our knowledge. The theories discussed herein include (i) the role of innate immunity mediated by toll-like receptors in triggering the autoimmune adaptive response characterizing the observed pathology; (ii) changes in spleen marginal zone B cells in autoantibody production with particular focus on the B10 subpopulation; (iii) Th17 cell differentiation and T regulatory cells in the aryl hydrocarbon receptor model; (iv) self antigen changes induced by chemical and infectious agents which could break tolerance by post-translational modifications and molecular mimicry; and finally (v) epigenetic changes, particularly DNA methylation, that are induced by environmental stimuli and may contribute to autoimmunity initiation. We are convinced that these working hypotheses, in most cases supported by solid evidence, should be viewed in parallel with animal models and epidemiological observations to provide a comprehensive picture of the environmental causes of autoimmune diseases.

Abrogation of Lupus Nephritis in Activation-Induced Deaminase-Deficient MRL/lpr Mice

We generated MRL/lpr mice deficient in activation-induced deaminase (AID). Because AID is required for Ig hypermutation and class switch recombination, these mice lack hypermutated IgG Abs. Unlike their AID wild-type littermates, AID-deficient MRL/lpr mice not only lacked autoreactive IgG Abs but also experienced a dramatic increase in the levels of autoreactive IgM. This phenotype in AID-deficient mice translated into a significant reduction in glomerulonephritis, minimal mononuclear cell infiltration in the kidney, and a dramatic increase in survival to levels comparable to those previously reported for MRL/lpr mice completely lacking B cells and well below those of mice lacking secreted Abs. Therefore, this study wherein littermates with either high levels of autoreactive IgM or autoreactive IgG were directly examined proves that autoreactive IgM Abs alone are not sufficient to promote kidney disease in MRL/lpr mice. In addition, the substantial decrease in mortality combined with a dramatic increase in autoreactive IgM Abs in AID-deficient MRL/lpr mice suggest that autoreactive IgM Abs might not only fail to promote nephritis but may also provide a protective role in MRL/lpr mice. This novel mouse model containing high levels of autoreactive, unmutated IgM Abs will help delineate the contribution of autoreactive IgM to autoimmunity.

Somatic immunoglobulin hypermutation.

Immunoglobulin hypermutation provides the structural correlate for the affinity maturation of the antibody response. Characteristic modalities of this mechanism include a preponderance of point-mutations with prevalence of transitions over transversions, and the mutational hotspot RGYW sequence. Recent evidence suggests a mechanism whereby DNA-breaks induce error-prone DNA synthesis in immunoglobulin V(D)J regions by error-prone DNA polymerases. The nature of the targeting mechanism and the trans-factors effecting such breaks and their repair remain to be determined.

Rescue of HIV-1 broad neutralizing antibody-expressing B cells in 2F5 VH x VL knockin mice reveals multiple tolerance controls.

The HIV-1 broadly neutralizing Ab (bnAb) 2F5 has been shown to be poly-/self-reactive in vitro, and we previously demonstrated that targeted expression of its VDJ rearrangement alone was sufficient to trigger a profound B cell developmental blockade in 2F5 VH knockin (KI) mice, consistent with central deletion of 2F5 H chain-expressing B cells. In this study, we generate a strain expressing the entire 2F5 bnAb specificity, 2F5 VH × VL KI mice, and find an even higher degree of tolerance control than observed in the 2F5 VH KI strain. Although B cell development was severely impaired in 2F5 VH × VL KI animals, we demonstrate rescue of their B cells when cultured in IL-7/BAFF. Intriguingly, even under these conditions, most rescued B cell hybridomas produced mAbs that lacked HIV-1 Envelope (Env) reactivity due to editing of the 2F5 L chain, and the majority of rescued B cells retained an anergic phenotype. Thus, when clonal deletion is circumvented, κ editing and anergy are additional safeguards preventing 2F5 VH/VL expression by immature/transitional B cells. Importantly, 7% of rescued B cells retained 2F5 VH/VL expression and secreted Env-specific mAbs with HIV-1–neutralizing activity. This partial rescue was further corroborated in vivo, as reflected by the anergic phenotype of most rescued B cells in 2F5 VH × VL KI × Eμ-Bcl-2 transgenic mice and significant (yet modest) enrichment of Env-specific B cells and serum Igs. The rescued 2F5 mAb-producing B cell clones in this study are the first examples, to our knowledge, of in vivo-derived bone marrow precursors specifying HIV-1 bnAbs and provide a starting point for design of strategies aimed at rescuing such B cells.

Activation-induced deaminase-deficient MRL/lpr mice secrete high levels of protective antibodies against lupus nephritis.

OBJECTIVE We previously generated MRL/lpr mice deficient in activation-induced deaminase (AID) that lack isotype switching and immunoglobulin hypermutation. These mice have high levels of unmutated (germline) autoreactive IgM, yet they experienced an increase in survival and an improvement in lupus nephritis that exceeded that of MRL/lpr mice lacking IgG. The purpose of the present study was to test the hypothesis that high levels of germline autoreactive IgM in these mice confer protection against lupus nephritis. METHODS Autoreactive IgM antibodies of various specificities, including antibodies against double-stranded DNA (dsDNA), from AID-deficient MRL/lpr mice were given to asymptomatic MRL/lpr mice, and the levels of cytokines, proteinuria, immune complex deposition in the kidneys, and glomerulonephritis were examined. Novel AID-deficient MRL/lpr mice that lack any antibodies were generated for comparison to AID-deficient MRL/lpr mice that secrete only IgM. RESULTS Treatment with IgM anti-dsDNA resulted in a dramatic improvement in lupus nephritis. Other autoreactive IgM antibodies, such as antiphospholipid and anti-Sm, did not alter the pathologic changes. Secretion of proinflammatory cytokines by macrophages and the levels of inflammatory cells and apoptotic debris in the kidneys were lower in mice receiving IgM anti-dsDNA. Protective IgM derived from AID-deficient MRL/lpr mice displayed a distinct B cell repertoire, with a bias toward members of the V(H) 7183 family. CONCLUSION IgM anti-dsDNA protected MRL/lpr mice from lupus nephritis, likely by stopping the inflammatory cascade leading to kidney damage. A distinct repertoire of V(H) usage in IgM anti-dsDNA hybridomas from AID-deficient mice suggests that there is enrichment of a dedicated B cell population that secretes unmutated protective IgM in these mice.

A Smad Signaling Network Regulates Islet Cell Proliferation

Pancreatic β-cell loss and dysfunction are critical components of all types of diabetes. Human and rodent β-cells are able to proliferate, and this proliferation is an important defense against the evolution and progression of diabetes. Transforming growth factor-β (TGF-β) signaling has been shown to affect β-cell development, proliferation, and function, but β-cell proliferation is thought to be the only source of new β-cells in the adult. Recently, β-cell dedifferentiation has been shown to be an important contributory mechanism to β-cell failure. In this study, we tie together these two pathways by showing that a network of intracellular TGF-β regulators, smads 7, 2, and 3, control β-cell proliferation after β-cell loss, and specifically, smad7 is necessary for that β-cell proliferation. Importantly, this smad7-mediated proliferation appears to entail passing through a transient, nonpathologic dedifferentiation of β-cells to a pancreatic polypeptide–fold hormone-positive state. TGF-β receptor II appears to be a receptor important for controlling the status of the smad network in β-cells. These studies should help our understanding of properly regulated β-cell replication.