Betty Diamond

Comparative transcriptional and functional profiling defines conserved programs of intestinal DC differentiation in humans and mice

Dendritic cells (DCs) that orchestrate mucosal immunity have been studied in mice. Here we characterized human gut DC populations and defined their relationship to previously studied human and mouse DCs. CD103+Sirpα− DCs were related to human blood CD141+ DCs and to mouse intestinal CD103+CD11b− DCs and expressed markers of cross-presenting DCs. CD103+Sirpα+ DCs aligned with human blood CD1c+ DCs and mouse intestinal CD103+CD11b+ DCs and supported the induction of regulatory T cells. Both CD103+ DC subsets induced the TH17 subset of helper T cells, while CD103−Sirpα+ DCs induced the TH1 subset of helper T cells. Comparative analysis of transcriptomes revealed conserved transcriptional programs among CD103+ DC subsets and identified a selective role for the transcriptional repressors Bcl-6 and Blimp-1 in the specification of CD103+CD11b− DCs and intestinal CD103+CD11b+ DCs, respectively. Our results highlight evolutionarily conserved and divergent programming of intestinal DCs.Dendritic cells (DCs) that orchestrate mucosal immunity have been studied in mice. Here we characterize human gut DC populations, and define their relationship to previously studied human and mouse DCs. CD103+Sirpα− DCs were related to human blood CD141+ and to mouse intestinal CD103+CD11b− DCs and expressed markers of cross-presenting DCs. CD103+Sirpα+ DCs aligned with human blood CD1c+ DCs and mouse intestinal CD103+CD11b+ DCs and supported regulatory T cell induction. Both CD103+ DC subsets induced TH17 cells, while CD103−Sirpα+ DCs induced TH1 cells. Comparative transcriptomics revealed conserved transcriptional programs among CD103+ DC subsets and uncovered a selective role for Bcl-6 and Blimp-1 in CD103+Sirpα− and intestinal CD103+CD11b+ DC specification, respectively. These results highlight evolutionarily conserved and divergent programming of intestinal DCs.

Polyreactive autoantibodies in systemic lupus erythematosus have pathogenic potential.

The present study was undertaken to determine whether germline encoded and polyreactive antibodies might be pathogenic and whether the breach of early tolerance checkpoints in systemic lupus erythematosus (SLE) might lead to a population of B cells expressing germline encoded antibodies that become pathogenic merely by class switching to IgG in a pro-inflammatory milieu. We demonstrate here that IgM, DNA-reactive antibodies obtained from lupus patients that are unmutated and display polyreactivity can bind to isolated glomeruli and exhibit neurotoxic potential. Thus, the IgM polyreactive repertoire in SLE includes antibodies that may acquire pathogenic function merely by undergoing class-switch recombination to become IgG antibodies.

Requirement for cyclin D3 in germinal center formation and function.

Germinal centers (GC) of secondary lymphoid tissues are critical to mounting a high-affinity humoral immune response. B cells within the GC undergo rapid clonal expansion and selection while diversifying their antibody genes. Although it is generally believed that GC B cells employ a unique proliferative program to accommodate these processes, little is known about how the GC-associated cell cycle is orchestrated. The D-type cyclins constitute an important component of the cell cycle engine that enables the cells to respond to physiological changes. Cell type- and developmental stage-specific roles of D-type cyclins have been described but the cyclin D requirement during GC reaction has not been addressed. In this study, we report that cyclin D3 is largely dispensable for proliferation and Ig class switching of in vitro activated B cells. In contrast, GC development in Ccnd3−/− mice is markedly impaired, as is the T cell-dependent antibody response. Within the GC, although both switched and unswitched B cells are affected by cyclin D3 inactivation, the IgM− pool is more severely reduced. Interestingly, despite a compensatory increase in cyclin D2 expression, a significant number of Ccnd3−/− GC B cells accumulate in quiescent G0 state. Lastly, although cyclin D3 inactivation did not disrupt BCL6 expression in GC B cells, it completely blocked the GC promoting effect of BCL6 overexpression, suggesting that cyclin D3 acts downstream of BCL6 to regulate GC formation. This is the first demonstration that cyclin D3 plays an important and unique role at the GC stage of B cell development.

Phenotypic characterization of autoreactive B cells--checkpoints of B cell tolerance in patients with systemic lupus erythematosus.

DNA-reactive B cells play a central role in systemic lupus erythematosus (SLE); DNA antibodies precede clinical disease and in established disease correlate with renal inflammation and contribute to dendritic cell activation and high levels of type 1 interferon. A number of central and peripheral B cell tolerance mechanisms designed to control the survival, differentiation and activation of autoreactive B cells are thought to be disturbed in patients with SLE. The characterization of DNA-reactive B cells has, however, been limited by their low frequency in peripheral blood. Using a tetrameric configuration of a peptide mimetope of DNA bound by pathogenic anti-DNA antibodies, we can identify B cells producing potentially pathogenic DNA-reactive antibodies. We, therefore, characterized the maturation and differentiation states of peptide, (ds) double stranded DNA cross-reactive B cells in the peripheral blood of lupus patients and correlated these with clinical disease activity. Flow cytometric analysis demonstrated a significantly higher frequency of tetramer-binding B cells in SLE patients compared to healthy controls. We demonstrated the existence of a novel tolerance checkpoint at the transition of antigen-naïve to antigen-experienced. We further demonstrate that patients with moderately active disease have more autoreactive B cells in both the antigen-naïve and antigen-experienced compartments consistent with greater impairment in B cell tolerance in both early and late checkpoints in these patients than in patients with quiescent disease. This methodology enables us to gain insight into the development and fate of DNA-reactive B cells in individual patients with SLE and paves the way ultimately to permit better and more customized therapies.

A model for lupus brain disease

Summary:u2002 Systemic lupus erythematosus is an autoimmune disease characterized by antibodies that bind target autoantigens in multiple organs in the body. In peripheral organs, immune complexes engage the complement cascade, recruiting blood‐borne inflammatory cells and initiating tissue inflammation. Immune complex‐mediated activation of Fc receptors on infiltrating blood‐borne cells and tissue resident cells amplifies an inflammatory cascade with resulting damage to tissue function, ultimately leading to tissue destruction. This pathophysiology appears to explain tissue injury throughout the body, except in the central nervous system. This review addresses a paradigm we have developed for autoantibody‐mediated brain damage. This paradigm suggests that antibody‐mediated brain disease does not depend on immune complex formation but rather on antibody‐mediated alterations in neuronal activation and survival. Moreover, antibodies only access brain tissue when blood‐brain barrier integrity is impaired, leading to a lack of concurrence of brain disease and tissue injury in other organs. We discuss the implications of this model for lupus and for identifying other antibodies that may contribute to brain disease.

It takes guts to grow a brain

A new study entitled “Normal gut microbiota modulates brain development and behavior”, published in the Proceedings of the National Academy of Sciences, requires that we reconsider the notion that the brain is an immune‐privileged site. The authors demonstrate that intestinal microbiota must be present within a set time‐frame for normal synaptogenesis to occur in the brain. In the absence of intestinal microbiota, histopathological and behavioral abnormalities arise. These observations necessitate a new look at the many interconnections of the immune system and the brain, suggesting new frontiers for research and new therapeutic strategies for neurodevelopmental diseases.

Identification of DNA-reactive B cells in patients with systemic lupus erythematosus.

Autoreactive B cells play a central role in systemic lupus erythematosus (SLE). Characterization of DNA-reactive B cells in the blood of lupus patients has been limited by the low frequency of the population. Using a tetrameric configuration of a peptide mimetope of DNA, we identified peptide-reactive B cells in peripheral blood. Antibodies derived from these B cells bound to peptide and were largely cross-reactive to dsDNA. This methodology enables us to track the development of autoreactive B cells, which recognize peptide and dsDNA, in individual patients with SLE and permits the isolation of autoreactive B cells for further characterization.

Aspects of CNS lupus: mouse models of anti-NMDA receptor antibody mediated reactivity.

This chapter describes methods utilized in establishing a mouse model of neuropsychiatric lupus encompassing both cognitive and emotional dysfunction, and a model of the influence of maternal antibody on the developing brain. The antibody of interest binds the N-methyl-D: -aspartate receptor (NMDAR), a receptor for glutamate that is a major excitatory neurotransmitter in the brain involved in synaptic plasticity, in memory and learning, and in emotional responses.We introduce basic concepts of these models and provide protocols for the following: (1) the induction of anti-dsDNA, anti-NMDAR antibodies, (2) testing serum antibody titer by ELISA, (3) breaching blood brain barrier (BBB) integrity with LPS and epinephrine, (4) passive transfer of pathology by injecting human and mouse brain-reactive antibodies into adult mouse as well as injecting the antibody into gestating mice and transfer of antibody from dam to fetus, (5) blocking NMDAR-mediated pathogenicity in vivo, (6) evacuation of blood from the brain by cardiac perfusion to preserve the brain for histology, (7) evaluating injured/apoptotic neurons in brain histology, (8) preparing membrane-enriched brain -fractions for NMDAR analysis.