Project description:The purpose of this study was to explore the splicing landscape in unstimulated versus stimulated B cells in both ELL2 sufficient and deficient mice. This would allow us to see the magnitidue of splicing changes in the transition from unstimulated to stimulated B cells, as well as the importance of ELL2 in this process.
Project description:We measured genes expression differences in antibody secreting cells from LynKO mice in following treatment with a BMI-1 inhibitor (PTC-028) or a vehicle control. BMI-1 inhibition lead to a reduction in antibody secreting cells in LynKO mice and in humans donors. We performed RNA sequencing to understand the impact of BMI-1 inhibition on antibody secreting cells in LynKO mice.
Project description:The CD19 positive antibody secreting cells (ASC) in both bone marrow (BM) have the capacity to provide immune memory in addition to cells traditionally considered long-lived, the CD19-negative BM ASC. We performed flow cytometry (FCM) immunophenotyping, fluorescence-activated cell sorting (FACS) for cell subset isolation, ELISpot assays detecting the isotype of antibody secretion as well as antibodies against vaccine derived antigens, and comparative gene expression analyses of CD19- ASC, CD19+ ASC, CD20- B cells, and CD20+ B cells from BM. The findings may aid in the understanding of the differential cell subsets created through vaccination and lead to improved vaccine strategies and production. FACS sorted tissue B cells and antibody secreting cell subset gene expression.
Project description:We report whole transcriptome RNASeq data for cell-sorted pop2, pop3, and pop5 which are antibody-secreting cells from human peripheral blood
Project description:Following activation by cognate antigen, B cells undergo fine-tuning of their antigen receptors and may ultimately differentiate into antibody-secreting cells (ASCs). While antigen-specific antibodies from B cell receptor (BCR) expressing B cells can be readily cloned and sequenced following flow sorting, antigen-specific plasma cells that lack surface BCR cannot be easily profiled in a high-throughput way. Here, we report an approach, TRAPnSeq (antigen specificity mapping through Ig secretionTRAPandSequencing), that allows capture of secreted antibodies on the surface of ASCs, which in turn enables high-throughput screening of single ASCs against large antigen panels and recovery of paired VH:VL antibody sequences. This approach incorporates flow cytometry, standard microfluidic platforms and DNA barcoding technologies to isolate and characterize antigen-specific ASCs through single cell V(D)J, RNA and antigen barcode sequencing. We show the utility of TRAPnSeq by profiling antigen-specific IgG and IgE plasma cells from mouse and humans and validate antigen binding by ELISA. TRAPnSeq can easily be combined with existing B cell platforms to accelerate antibody discovery from ASCs and can further be expanded to any protein secreting-cells.