Most members of the TLR family are detectable at mRNA level in isolated mouse glomeruli with TLR3 and TLR4 having the most abundant expression (5). Immunohistochemical staining showed that TLR4 protein is localized in podocytes. In cultured podocytes, the treatment with lipopolysaccharides (LPS), a PAMP ligand for TLR4, induced the expression of CCL2, CCL7, CXCL1, CXCL5, CCL3, CCL5, CXCL7, CXCL9, CXCL11, and CXCL13. Moreover, fibrinogen, a DAMP ligand of TLR4, also induced the expression of CCL2, CCL7, CXCL1, and CXCL5 (5). Consistently, nuclear factor kappa B (NFκB) signaling was found activated in podocytes that were treated with TLR ligands (6). Supportively, the essential components of TLR signaling in cultured podocytes, including MyD88, IRAK, TRAF6, etc., have also been detected (7). In patients with lupus nephritis, polyoma virus infection, or hemolytic uremic syndrome, TLR9 was found to be de novo expressed in podocytes and thought to be involved in immune response and inflammation in glomeruli (8–10).

The major components of inflammasomes, NLRP3, ASC, and caspase 1, were found to be expressed in podocytes (11), and PAMP treatment was capable of upregulating the expression of NLRP3, pro-caspase 1, posttranslational processing of pro-caspase 1, and the release of IL-18 in podocytes (12). Cellular endogenous reactive oxygen species (ROS) was observed to induce the activation of NLRP3 and formation of inflammasomes in mouse podocytes and glomeruli (13).

Retinoic acid-inducible gene 1 belongs to the family of RIG-I-like helicases, which recognize viral RNA. It is expressed in podocytes and fully functional via downstream pathways, IRF3 (transcription factor interferon regulatory factor 3), and NFκB, leading to cytokines expression and podocyte injury (14).

Receptor of advanced glycation endproducts is one of the PRRs and can use DAMPS as its ligands. These DAMPs include advanced glycation endproducts (AGE), high-mobility group box protein 1 (HMGB1), S100A proteins, etc. RAGE is expressed in podocytes and upregulated in diabetic nephropathy (DN) (15, 16), and mediate podocyte injury induced by AGE (17). More recently, advanced oxidation protein products were also shown to be ligands of RAGE and capable of inducing podocyte apoptosis (18).

In SLE-prone MRL-Fas(lpr) mice, the treatment with DNA derived from bacteria or CpG ODN facilitated the development of SLE and LN in the mice through activating TLR9 in B cells (36, 37). The treated mice manifested an increase of DNA autoantibodies, cytokines, or chemokines in circulation, and infiltration of immune cells in tissues, including kidney.

In addition to B cells, mtDNA–TLR9 may also facilitate SLE development through plasmacytoid predendritic cells (PDCs) as there has been a study showing that viral DNA or the DNA in the immune complexes can stimulate PDCs through TLR9 to express and secrete IFN-α, a cytokine that is involved in anti-dsDNA antibody production (38). Meanwhile, mtDNA has been shown to have antigenicity that contributes to the formation of anti-dsDNA antibodies. Interestingly, oxidized form of mtDNA exhibited an enhanced antigenicity compared to that not oxidized (39). Additionally, the autoantibodies in SLE patients are reactive to mtDNA and have a higher affinity with mtDNA than nDNA (40, 41). Consistently, the level of anti-mitochondrial antibody is correlated with the development of SLE (42). These observations suggest that mtDNA and TLR9 are involved in the development of SLE and LN.

Puromycin aminonucleoside is capable of inducing IFN-α expression in podocytes via mtDNA and TLR9 interaction (7). In addition, several studies have shown that TLR9 is de novo expressed in podocytes in a proportion of SLE patients (8–10). This raises a possibility that podocytes are an alternative source of IFN-α and other cytokines that are involved in SLE and LN development. SLE is characterized by the production of anti-double stranded (ds) DNA antibodies, which bind to dsDNA to form immune complexes (ICs). Such DNA-containing ICs are capable of stimulating plasmacytoid PDCs to express IFN-α through TLRs, including TLR9 (38), it is thus reasonable to speculate that the anti-dsDNA antibodies can also bind mtDNA to form ICs. Since lupus nephritis is pathologically characterized by the deposition of the ICs in glomeruli, we speculate that the mtDNA in the ICs may be transported to podocytes through endocytosis and then either reach endolysosomes to activate the de novo expressed TLR9 or act on NLRP3/inflammasomes, resulting in podocyte injury/apoptosis and IFN-α and proinflammatory IL-1 production thereby facilitating LN development. To prove this hypothesis, it would be important to examine whether the ICs in lupus contain mtDNA.

As having mentioned above that TLR9 de novo expression in podocytes occurs in some of the patients of LN with urinary protein level of 0.3–0.5 g/24 h or a negative urinary protein (9), it would be interesting to investigate the consequences of TLR9 de novo expression in podocytes in the condition. Hu and colleague have recently reported that podocytopathy in the LN patients with nephrotic range of proteinuria can be divided into two types, MCD/mesangial proliferation and FSGS, which differ in pathology, tubular lesion, and treatment outcome (43). Whether TLR9 expression underlies the difference of the two types of lupus podocytopathy warrants further investigation. One feasible approach for the study could be to perform immunohistochemical staining of TLR9 with renal biopsies in a cohort of LN consisting of patients with MCD/mesangial proliferation and FSGS; and then test whether TLR9 de novo expression in podocytes correlates with the patients with FSGS, which manifests with podocyte injury and loss in contrast with MCD.