ABSTRACT Rheumatoid arthritis (RA) and systemic lupus erythematosus (SLE) are different diseases clinically and the most important tissue damage occurs in joints and kidneys, respectively. Yet, both SLE and RA share a central common theme of adaptive T and B cell interactions that result in autoantibody production. Both tissues develop chronic inflammatory reactions that also include myeloid cell populations, neutrophils and other innate leukocytes. The two diseases cluster in families and share a number of closely related risk alleles suggesting related immune mechanisms. Developing targeted therapies for lupus has been frustrating and while a number of therapies can reduce disease activity in RA, a large unmet need exists in the form of TNF inadequate responders; and there is no cure. Based on the RA/SLE AMP consortium, single cell RNA-seq and CyTOF analysis has phenotypically and transcriptionally identified many unexpected cell types and cell states present in the inflamed kidney in lupus nephritis and RA synovitis. Here, we select a set of important cell populations specific to, or highly enriched in, the involved tissues in both diseases. Given the importance of B cells and antibody production, we focus on the novel subset of age (or autoimmunity) associated B cells (ABC B cells) and B helper T cells including both T follicular helper (Tfh) and the recently discovered T peripheral helper (Tph) T cells in Project 1. The project focuses on defining the relationship of ABC to other B cell populations and examines the role of Tph and Tfh cells in driving ABC B cells and their cross-talk. ABC B cells and Tph/Tfh cells are enriched in both lupus kidney and RA synovium allowing their comparison across diseases. Project 2 examines novel macrophage inflammatory states found in lupus kidney and seeks to define the main activating factors and transcription factors that drive cell state changes to achieve the inflammatory CM4 state that predominates in nephritis. Project 3 examines the fibroblastic stroma that drives inflammation in RA. A population of inflammatory sublining CD90+DR+ fibroblasts is profoundly expanded in RA and implicated in perpetuating inflammation. Project 3 examines the role of a Notch gradient and Notch signaling in driving the differentiation and activation of this population in synovium and kidney and its role in inflammatory arthritis. All 3 projects interact to examine the cell types of interest across diseases, to determine which cells are interacting most closely by integrated imaging analysis. By utilizing the synchronized expert pipelines of the Computational Systems Immunology Core for single cell RNA-seq and image analysis, the data gathered from both diseases and tissues can be effectively compared. All 3 projects focus on determining the drivers and transitions that yield the important cell states that have been discovered directly in the involved tissues. Together, the program will provide new insights into the tiss...