ABSTRACT: Although significant progress has been achieved in elucidating the genetic architecture of systemic lupus erythematosus (SLE), identifying genes underlying the pathogenesis has been challenging. The NZM2410-derived lupus susceptibility Sle3 locus is associated with T cell hyperactivity and activated myeloid cells. However, candidate genes associated with these phenotypes have not been identified. Here, we narrow the Sle3 locus to a smaller genomic segment (Sle3k) and show that mice carrying Sle3k and Sle1 loci developed lupus nephritis. We identify Klf13 as the primary candidate gene upregulated in Sle3k mice and demonstrate that Klf13 upregulation is associated with genome-wide transcription changes resulting in higher levels of proinflammatory cytokines, enhanced T cell activation, and hyperresponsiveness of myeloid cells. Correspondingly, Klf13 –/– mice display striking repression of genes involved in mediating immune activation, including key proinflammatory cytokines/chemokines. Furthermore, Klf13 –/– mice show profound dysregulation in cytokine signaling pathways in myeloid cells in response to toll receptor ligands, thus revealing a key role of KLF13 in modulating myeloid cell function. Klf13 upregulation is associated with increased production of RANTES, a key chemokine in lupus nephritis, in activated T cells and the kidneys of lupus-prone mice. In sum, our findings reveal Klf13 as a key gene in the Sle3 interval in mediating lupus pathogenesis that may have implications in the rational design of new therapies for SLE and other autoimmune/inflammatory diseases.