Project description:Type I interferon (IFN), namely IFN- α, and B cell aberrations are long recognized in systemic lupus erythematosus (SLE) pathogenesis. Type I IFN receptor blockade has undergone clinical trials in SLE with varying degrees of success. Type III IFN (IFN-λ) produce a gene signature currently indistinguishable from that of type I in responsive cell types. IFN-λ are not blocked by type I IFN receptor blockade as they utilize a unique receptor (IFNLR1). Type III IFN are appreciated to have an important role in viral infection at epithelial barriers where IFNLR1 is strongly expressed.  The effects of IFN-λ on immune cells remain understudied and are different between human and murine models.  We have previously shown that human B cells can transcribe type I IFN genes after IFN-λ treatment including those associated with SLE. We have found that IFN-λ is detected in the serum of human SLE patients and correlates with IgD- CD27- CD21- CD24- (DN2) B cells, a compartment which contains CD11c+ age/autoimmunity B cells (ABC).  ABC are a target of interest as recent studies suggest they are poised for plasma cell differentiation and enriched in autoreactivity and thus have the potential to contribute to SLE pathogenesis. Results: Naïve and DN cells display a prominent type I IFN gene expression profile in SLE. Transcript for type I, type II, and type III IFN receptors (IFNAR1, IFNAR2, IFNGR1, IFNGR2, IFNLR1, and IL10RB) are detected in HD and SLE B cells. CD11c+ CD21- frequency increased in DN compared to naïve B cells for SLE and HD (both p< 0.001). The mean and range of CD11c+ CD21- frequency was higher in SLE DN (30.7± 9.5%, mean±SEM; range 4.8-74.7%) compared to HD DN (7.6%±1.0%,3.6-9.4%). Increased IFNLR1 transcript correlated with CD11c+ CD21- B cell expansion (r2=0.922, p<0.0001). Increased pSTAT1 after IFN-α2 treatment is found in monocytes, T cells, and B cells but only in the B cells after IFN-λ1 treatment. Naïve, DN, switched, and unswitched memory HD B cells are responsive to type I and type III IFN, but demonstrated a higher pSTAT1 fold change with type I IFN treatment compared to type III IFN. In all B cell subsets, CD11c+ cells had a higher pSTAT1 fold change after IFN-λ1 stimulation than did CD11c- B cells. In HD with well-defined populations of CD11c+ CD21- DN cells, pSTAT1 fold change for IFN-λ approached that of IFN-α2. Conclusions: All human B cell subsets defined by CD27 and IgD respond to IFN-α and IFN-λ, but those expressing CD11c+ have increased responsiveness to IFN-λ. CD11c+ cells expand in SLE and associate with autoreactive plasma cell development. Thus, the role of IFN-λ may take on increased clinical significance in the setting type I IFN receptor blockade. These results suggest IFN-λ is an underappreciated driver of the IFN signature and B cell aberrations in SLE.

Project description:IgD-CD27- “double negative” (DN) B cells are known to be expanded in the blood in many disease contexts and the IgD-CD27-CXCR5-CD11c+ DN2 B cell subset has been most widely studied in autoimmune diseases. In addition to DN2 B cells, a distinct IgD-CD27-CXCR5-CD11c- DN3 B cell subset accumulates in the blood both in IgG4-related disease, an autoimmune disease in which inflammation and fibrosis can be reversed by B cell depletion, and in severe COVID-19. DN3 B cells, but not DN2 B cells, prominently accumulate in the blood and end-organs of IgG4-related disease.

Project description:Separation of B cells has been historically important in discovering their functional relevance, particularly in relation to infection, immune disorders and vaccination. Traditional use of phenotypic markers often poses problems in distinguishing heterogeneous populations such as the Double Negative (DN, CD19+CD27-IgD-) cells. B cells represent a small subset of PBMCs; this represents challenges to use bottom-up approaches such as single-cell transcriptomics in defining B cell subpopulations. In this study we therefore used the 10X single-cell RNAseq platform on B cell populations already defined by FACS sorting (Transitional, CD19+CD27-IgD+CD10+; Naïve, CD19+CD27-IgD+CD10-; Classical Memory, CD19+CD27+IgD-; IgM Memory, CD19+CD27+IgD+; and DN). These data match known phenotypes to transcriptionally defined B cell subpopulations, and provide a reference atlas for researchers interested in better defining B cell subsets in their data.

Project description:Despite a successful antiretroviral therapy (ART), adolescents living with perinatally acquired HIV (PHIV) experience signs of B-cell hyperactivation with expansion of 'namely' atypical B-cell phenotypes, including double negative (CD27-IgD-) and termed age associated (ABCs) B-cells(T-bet+CD11c+), which may result in reduced cell functionality, including loss of vaccine-induced immunological memory and higher risk of developing B-cells associated tumors. In this context,perinatally HIV infected children (PHIV) deserve particular attention, given their life-long exposure to chronic immune activation.

Project description:ATAC-seq in sorted GC centroblasts (GCB: CD20+CD44-CD10+CXCR4+), GC centrocytes (CC: CD20+CD44-CD10+CXCR4-), naïve B cells (NB: CD20+CD44+CD10-IgD+), memory B cells (MB: CD20+CD44+CD10-CD38-CD27+), and plasma cells (PC: CD20+CD44+CD10-CD38+CD27+)

Project description:CD11c+ B cells (IgD+ and IgD-) are pathogenic B cells expanded in autoimmune disease. The purpose of this study is to identify the pathways unique to IgD+ CD11c B cells and IgD- CD11c B cells.

Project description:Dramatic expansions of class switched B cells lacking IgD and CD27 (double negative; DN), are characteristic of Systemic Lupus Erythematous (SLE). However, their origin, clinical and immunological significance and their relationship to CD27+ memory B cells remain unclear. We demonstrate that SLE DN expansions are dominated by a CXCR5- CD21- subset with a pre-plasma cell phenotype and distinctive transcriptional, and functional properties. SLE patients with an expansion of CXCR5- DN are predominantly African-American with higher disease activity and anti-Smith/RNP autoantibodies. CXCR5- DN cells display a distinct transcriptome characterized by differential expression of cytokine receptors, transcription factors, and signaling molecules. DN express high levels of the key INFg effector factor, T-bet and associated transcription factor Zeb2 and uniquely among B cell subsets, do not express TRAF5, a negative regulator of TLR signaling. Consistent with this pattern gene expression SLE DN have enhanced responsiveness to TLR7 and can differentiate into autoantibody secreting plasma cells

Project description:RNA microarray profiling analysis was performed on splenic B cell subsets: “IgD+CD27-” (naive B cells) and “IgD+CD27+” (MZB B cells) isolated from splenic samples of 6 adults

Project description:The cause of systemic lupus erythematosus (SLE) is unknown. Interferonα (IFNα) has been suggested as a causative agent of SLE, however, it is not proven, and to what extent and how IFNα contributes to the disease is unknown. We here directly studied the contribution of IFNα to SLE by generating inducible IFNα transgenic mice which showed that conditional up-regulation of IFNα induced a typical manifestation of SLE including serum immune complex (IC), autoantibody against double stranded DNA (anti-dsDNA Ab) and the organ manifestations classical to SLE such as IC-deposited glomerulonephritis, classical splenic onion-skin lesion, and alopecia, epidermal liquefaction, positive lupus-band test of the skin. In the spleen of mice, activated effector CD4 T cells, interferonγ-producing CD8 T cells, B220+CD86+ cells and CD11c+CD86+ cells were increased, and the T cells produced increased amounts of IL-4, IL-6, IL-17 and IFNγ and decreased IL-2. In particular, activated CD3+CD4-CD8- double-negative T (DNT) cells positive for TCRαβ, B220, CD1d-teteramer, PD-1 and Helios, which produced increased amounts of IFNγ, IL-4, IL-17 and TNFα, were significantly expanded. They infiltrated into kidney and induced de novo glomerulonephritis and alopecia when transferred into naïve recipients. Thus, conditional up-regulation of IFNα is sufficient to induce SLE, and the DNT cells as expanded by IFNα are directly responsible for the organ manifestations such as lupus skin disease or nephritis.

Project description:RNA sequencing of B cell subsets (CD11c hi IgD+ B cells, CD11c hi IgD- B cells, Memory B cells and Naïve B cells) from healthy subjects and subjects with Systemic lupus erythematosus (SLE) or Rheumatoid arthritis (RA)