[Mutation of nuclear autoantigenic sperm protein (NASP) gene aggravates autoimmune response in induced lupus model mice].

Objective To prepare inducible lupus model mice and investigate the effect of nuclear autoantigenic sperm protein (NASP) gene mutation on the autoimmune response of mice with induced systemic lupus erythematosus (SLE). Methods The 3-month wild-type B6 (B6-WT) mice were used as a control group and the NASP mutant B6 (B6-NASPM) mice as an experimental group. Mouse spleen lymphocytes were activated with concanavalin A (ConA), and the DNA was extracted as autoantigen. B6-WT mice and B6-NASPM mice were immunized three times. Serum anti-double stranded DNA (dsDNA) IgG levels were detected by ELISA. Renal lesions were detected by HE staining. Immunohistochemical staining was performed to detect the deposition of IgG and complement C3 in the renal tissues. Flow cytometry was applied to compare the spleen lymphocyte subsets in B6-WT and B6-NASPM mice and to explore the mechanism of NASP gene mutation affecting the immune response in mice. Results Compared with B6-WT mice, B6-NASPM mice showed no significant changes in body weight, kidney index and spleen index; serum anti-dsDNA IgG levels significantly increased; glomerular cell proliferation was obvious and the deposition of IgG and C3 in the renal tissues increased. The proportion of spleen CD3+ T cells and natural killer (NK) cells decreased, while the proportion of CD19+ B cells and regulatory B cells (Breg) increased. Conclusion Mutation in the NASP gene can increase the levels of anti-dsDNA IgG antibodies, promote cell proliferation in the glomerulus of the kidney, deposition of IgG antibodies and complement C3, alter the proportion of immune cells in the spleen and aggravate the autoimmune response in lupus model mice.

A Variant of the Histone-Binding Protein sNASP Contributes to Mouse Lupus.

The Sle2c1rec1c (rec1c) sublocus is derived from the mouse lupus susceptibility 2 (Sle2) locus identified in the NZM2410 model. Our current study dissected the functional characters and the genetic basis of the rec1c locus relative to lupus when co-expressed with the Fas lpr mutation, an established inducer of autoimmunity. The rec1c.lpr mice exhibited mild expansion of lymph nodes and had a normal T cell cellularity, but developed significantly kidney and lung inflammation, indicating that the rec1c amplifies lpr-induced autoimmune pathogenesis. A variant of somatic nuclear autoantigenic sperm protein (sNASP) was identified from the rec1c interval as a substitution of two consecutive amino acid residues in the histone-binding domain, resulting in an increased binding affinity to histone H4 and H3.1/H4 tetramer. To determine the role of the sNASP rec1c allele in mouse lupus, a novel strain was generated by introducing the rec1c mutations into the B6 genome. In this transgenic model, the sNASP allele synergized with the lpr mutation leading to moderate autoimmune phenotypes and aggravating inflammatory pathology alterations in kidney and lung that were similar to those observed in the rec1c.lpr mice. These results establish that the sNASP allele is a pathogenic genetic element in the rec1c sublocus, which not only promotes autoimmunity, but also exacerbates the inflammation reaction of end organs in mouse lupus pathogenesis. It also shows the complexity of the Sle2c locus, initially mapped as the major locus associated with B1a cell expansion. In addition to Cdkn2c, which regulates this expansion, we have now identified in the same locus a protective allele of Csf3r, a variant of Skint6 associated with T cell activation, and now a variant of sNASP that amplifies autoimmunity and tissue damage.