Dendritic cells (DCs) are professional antigen-presenting cells that are critical for the activation of T and B cells, initiating an immune response. DC dysfunction has long been considered a driver of the autoimmune response in SLE (30). Among the various types of DCs, plasmacytoid DCs (pDCs) have garnered significant attention due to their superior ability to produce type I interferon (IFN) (31). Additionally, pDCs produce BAFF and APRIL (32) and activate autoreactive B cells through cell–cell interactions (33). In the context of SLE pathogenesis, pDC activation can be triggered by neutrophil extracellular traps (NETs), which are present at higher levels in SLE patients (34). In lupus-prone mice, pDC dysfunction manifests in several ways: aged lupus-prone mice show pDC resistance to glucocorticoids (35), and pDCs from NZB mice have a longer lifespan than those from C57BL/6 mice, leading to elevated IFN-α levels in the former. Although pDCs are generally decreased in the peripheral blood of SLE patients, there is a concomitant infiltration of pDCs into nephritic kidneys (36).

Given the prominent role of pDCs in SLE pathogenesis, particularly as the main producers of type I IFN, inhibiting pDC activation and exploring pDC depletion have been investigated as potential treatments for human SLE by targeting surface receptors (BDCA and CD123) on human pDCs (36, 37). However, it remains unclear whether these interventions can benefit LN patients. Since pDCs rely on BCL-2 for survival, venetoclax, a BCL-2 inhibitor, has been trialed in women with SLE (38).

Targeting type I IFN has been extensively explored for SLE treatment, with biologics targeting either type I IFN itself or its receptor (IFNAR) (37). Anifrolumab is a monoclonal antibody that targets IFNAR, thereby blocking all type I interferons. In the TULIP trials, patients treated with anifrolumab demonstrated a higher proportion achieving an SLE Responder Index 4 (SRI-4) response at 52 weeks. Additionally, these patients experienced significant improvements in cutaneous (skin) and musculoskeletal (joint) manifestations. Some individuals also showed reductions in anti-dsDNA antibody levels and improvements in low complement levels (39). It is worth noting that anifrolumab has not been reported to be used for the treatment of lupus nephritis (LN).

The activation of B cells, including autoreactive B cells, often requires help from T cells. The following section will briefly discuss the role of T cells in the pathogenesis of systemic lupus erythematosus (SLE).

The IL-17 family consists of six distinct members (IL-17A to IL-17F) that exert their physiological effects through interactions with IL-17 receptors (IL-17RA to IL-17RE). Among these, IL-17A (hereafter referred to as IL-17) has been extensively studied and, along with IL-17F, mediates its biological functions by binding to IL-17RA and IL-17RC. IL-17 is primarily produced by CD4⁺T cells known as T helper 17 (Th17) cells (61). An increase in Th17 cells in lupus nephritis (LN) has been observed in the peripheral blood mononuclear cells of LN patients (61, 62). However, kidney CD4⁺T cell clusters from LN patients have also been reported, with unclear associations to Th1 or Th17 signatures (21). Nonetheless, IL-17 can originate from various cellular sources, including CD8⁺T cells, γδ T cells, innate lymphoid cells (ILCs), natural killer (NK) cells, invariant NK T cells, mucosal-associated invariant T cells, mast cells, and Paneth cells. Furthermore, while T cell receptor (TCR) activation is crucial for IL-17 production by conventional T cells, innate immune cells rely on inflammatory cytokines—particularly IL-1β and IL-23—to drive IL-17 secretion (63).

In lupus nephritis, IL-17A is implicated in multiple stages of disease progression, including modifying the structure and function of specialized renal cells, fostering an inflammatory environment, and contributing to recurrent tissue damage and ineffective repair processes, ultimately leading to renal fibrosis and functional decline. The following section outlines existing research on the impact of IL-17A on distinct renal cell types and compartments (63).

Studies investigating the pathological roles of IL-17 in systemic lupus erythematosus (SLE) suggest that IL-17A is a promising therapeutic target for this condition. The cytokines and receptors within the IL-17 family possess distinctive molecular structures that differentiate them from other protein families, making them attractive candidates for therapeutic intervention (89, 90). Current Th17-targeted therapies primarily involve monoclonal antibodies directed against IL-17, IL-23, and their receptors. Notable IL-17A antagonists include secukinumab and ixekizumab, while bimekizumab targets both IL-17A and IL-17F. Brodalumab inhibits IL-17 by binding to the IL-17 receptor (IL-17R) (91). Additionally, upstream neutralization of IL-23 can be achieved with guselkumab, risankizumab, tildrakizumab, and ustekinumab. These modalities have been widely used for the treatment of psoriasis (PsO), psoriatic arthritis (PsA), and spondyloarthritides (SpA) and even inflammatory bowel diseases (IBD) (92, 93). Given the success of anti-IL-17 therapies in treating these autoimmune diseases, the potential for similar approaches in SLE to reduce disease activity has also been investigated (94).

Ongoing clinical trials, SELUNE and ORCHID-LN, are evaluating secukinumab and guselkumab in lupus nephritis. The SELUNE study (NCT04181762) is a phase III randomized, double-blind trial designed to assess the efficacy and safety of secukinumab in conjunction with standard care therapy for individuals with active lupus nephritis. However, the study was prematurely halted by the sponsor following a futility analysis (9). The ORCHID-LN trial investigates the safety and efficacy of guselkumab in individuals with active lupus nephritis, comparing its addition to standard care with a placebo combined with standard care. This study was also prematurely terminated by the sponsor due to difficulties in participant enrollment.

Although numerous IL-17-related biologics have been evaluated in systemic lupus erythematosus and lupus nephritis, most phase II trials have not yielded statistically significant results that meet the regulatory criteria. Nonetheless, there are documented case reports indicating the successful use of IL-17 antagonism in lupus nephritis ( Table 1 ).

Most clinical trials with IL-17 antagonists have not demonstrated statistically significant outcomes for lupus nephritis (LN) patients despite encouraging signals from several case reports. Combination therapy targeting additional molecules or pathways might be beneficial for complex diseases like lupus nephritis. Given the documented association of the IL-36 pathway with systemic lupus erythematosus (SLE), reciprocal regulation, and the synergistic action between IL-17 and IL-36 in inflammation and fibrosis ( Figure 2 ), we discuss the rationale for co-blockading IL-17 and IL-36 pathways in lupus nephritis.

The IL-36 cytokines, which include three agonists—IL-36α, IL-36β, and IL-36γ—and two antagonists—IL-36Ra and IL-38—belong to the IL-1 family. IL-36 exhibits pro-inflammatory characteristics and plays a crucial role in immune cell activation and antigen presentation. The signaling pathways initiated by IL-36 agonists interact with IL-1RAcP and IL-36R, leading to the recruitment of MyD88, IRAK4, and TRAF6. This cascade ultimately activates the NF-κB and MAPK pathways, facilitating pro-inflammatory signaling. In contrast, IL-36 antagonist signals bind to IL-1RAcP and IL-36R, inhibiting NF-κB and MAPK signaling, thereby promoting anti-inflammatory responses (103).

The skin serves as the primary site for IL-36 cytokine expression, with several studies indicating their significant involvement in the pathogenesis of various skin diseases. Monoclonal antibodies targeting IL-36R have been approved for treating generalized pustular psoriasis, and research is ongoing to investigate the role of IL-36 signaling in other autoimmune conditions (104).

The association of IL-36 with systemic lupus erythematosus (SLE) has been recognized for some time. In a study involving 43 SLE patients and 16 normal control (NC) subjects, the plasma concentrations of IL-36α and IL-36γ were significantly elevated in active SLE patients compared with NC. Notably, the plasma levels of IL-36α and IL-36γ correlated positively with SLE disease activity. Additionally, the proportions of circulating IL-36R-positive CD19⁺B lymphocytes among total B lymphocytes and PBMCs were significantly higher in active SLE patients. Upon ex vivostimulation with IL-36α and IL-36γ, the production of IL-6 and CXCL8 was significantly increased in SLE patients compared with NC, suggesting that IL-36α may act as a pathogenic factor in SLE (105).

Another study involving 72 SLE patients and 63 healthy controls in China also found significantly increased serum levels of IL-36α and IL-36γ along with decreased serum IL-36Ra levels in SLE patients compared with healthy controls. Active SLE patients (SLEDAI (Systemic Lupus Erythematosus Disease Activity Index) score ≥5) exhibited significantly higher serum levels of IL-36α and IL-36γ than the inactive patients (SLEDAI score ≤4). Moreover, these levels were strongly correlated with SLEDAI scores and complement C3 levels. Notably, SLE patients with arthritis had significantly elevated serum IL-36α and IL-36γ levels compared with those without arthritis (106). A recent study extended the investigation to IL-36β and IL-36R, finding that these proteins were expressed in immune cells as well as epithelial cells of SLE patients, linking them to specific disease features (107). In another study, significantly increased serum levels of IL-36α and pentraxin 3 were detected in both active (P= 0.000 for both) and inactive SLE patients (P= 0.003 and P= 0.001, respectively) compared with normal controls. Nevertheless, active SLE patients had significantly higher IL-36α levels compared with inactive patients (108). Similar conclusions were reached when evaluating the IL-36α mRNA levels. In a separate study involving 49 SLE patients and 40 healthy controls, IL-36α mRNA was significantly higher in SLE patients, with fold changes indicating increased expressions in those with moderate to high disease activity (SLEDAI >5) compared with those with mild activity (SLEDAI ≤5) (109).

In the context of lupus nephritis (LN), the urinary levels of IL-36 cytokines were examined in a study involving 196 SLE patients—comprising 97 with active LN, 42 with inactive LN, and 57 with active lupus without renal involvement—as well as 25 healthy subjects (110). Although the cytokine levels in urine were generally low, the urinary IL-36γ levels were significantly elevated in SLE patients compared with healthy controls. Patients with active LN exhibited markedly higher IL-36γ levels than those without renal involvement, and these levels showed a moderate correlation with renal SLEDAI scores. Notably, the urinary IL-36γ levels decreased significantly after 3 months of immunosuppressive therapy in patients with active LN (110).

IL-38, an antagonist of the IL-36 family, has been implicated in various autoimmune and inflammatory diseases, predominantly functioning as an anti-inflammatory cytokine (111). In the context of lupus nephritis, IL-38 levels were found to be significantly higher in samples from systemic lupus erythematosus (SLE) patients—particularly those with active disease—compared with healthy controls. Furthermore, the presence of IL-38 was linked to an increased risk of renal lupus.

Peripheral blood mononuclear cells (PBMCs) treated with IL-38 siRNA (small interfering RNA) produced up to 28-fold more of the pro-inflammatory mediators IL-6, CCL2, and APRIL than control siRNA-transfected cells when stimulated with Toll-like receptor agonists, suggesting a protective role for IL-38 (112, 113). Additionally, both the mRNA and protein levels of IL-38 in the peripheral blood of SLE patients were observed to decrease (114).

It is worth noting that a recent study also evaluated both IL-36 and IL-17 in SLE patients. Consistent with previous findings, the IL-36α levels were significantly higher in SLE patients, particularly in those with an active disease. Furthermore, the serum IL-17 levels were elevated in SLE patients, with a positive correlation observed between IL-36α and IL-17 levels. Importantly, patients with lupus nephritis had higher serum IL-36α levels compared with those without LN. This study also noted that patients receiving glucocorticoid treatment had lower IL-36α levels than those not receiving such treatment (115).

While the role of IL-36 has not been directly examined in the context of LN, an increased expression of IL-36α has been reported in renal tubular epithelial cells from a mouse model of unilateral ureteral obstruction (UUO). Compared with UUO-treated wild-type mice, IL-36 knockout (IL-36-/-) mice exhibited a markedly reduced NLRP3 inflammasome activation as well as decreased macrophage and T cell infiltration in the kidneys and T cell activation in the renal draining lymph nodes, leading to diminished formation of renal tubulointerstitial lesions (TILs). Notably, in vitrostudies demonstrated that recombinant IL-36α facilitated NLRP3 inflammasome activation in renal tubular epithelial cells, macrophages, and dendritic cells and enhanced dendritic cell-induced T cell proliferation and Th17 differentiation. Furthermore, the deficiency of IL-23, which was diminished in IL-36R knockout UUO mice, also reduced renal TIL formation in UUO models (116).

In a related study using the UUO model, IL-36α was found to be overexpressed in injured distal tubules (DTs). Importantly, IL-36α expression significantly correlated with the progression of tubulointerstitial cell infiltration and tubular epithelial cell death in UUO kidneys. The IL-1RL2 receptor for IL-36α localized to podocytes, proximal tubules, and DTs in healthy kidneys, but in UUO kidneys IL-1RL2 was expressed in interstitial cells, platelets, and extended primary cilia of DT epithelial cells. Stimulation with IL-36α promoted the production of IL-6 and Prss35, an inflammatory cytokine and collagen remodeling-associated enzyme, respectively, in cultured NIH3T3 (the embryonic mouse fibroblast cell line) fibroblasts. IL-36α knockout (KO) mice exhibited milder features of kidney injury compared with wild-type (WT) mice in UUO models (117).

A few studies have conducted a detailed dissection of the IL-36 family’s role in lupus nephritis. In MRL/MpJ-Faslpr/lpr mice, IL-36R deficiency resulted in reduced glomerular lesions, particularly mesangial matrix expansion, with significant amelioration observed in both sexes of IL-36R^-/-mice compared with WT mice. IL-36R deficiency had minimal effects on the indices of immune abnormalities, renal function, and serum anti-dsDNA antibody levels (118).

Notably, recombinant IL-38 was found to attenuate clinical severity in the MRL/lpr mouse model (119). In a pristane-induced lupus mouse model, the deficiency of IL-38 exacerbated inflammation, upregulated inflammatory cytokines and autoantibodies, and led to severe pathological changes in the kidneys. The administration of recombinant murine IL-38 to pristane-treated IL-38-/- mice improved their renal histopathology (120). Treatment with human recombinant IL-38 protein in vitroreduced the levels of IKKα/β, NF-κB, and TNF-α and decreased the anti-dsDNA antibodies in PBMCs from SLE patients. Additionally, kidney function—reflected by creatinine and blood urea nitrogen levels—along with anti-dsDNA antibodies, complement C3, and urinary protein levels decreased following treatment with IL-38 protein in MRL/lpr lupus mice. However, IL-38 protein treatment also induced mild hyperplasia of glomerular mesangial cells and lymphocyte infiltration (114).

Molecular analyses have demonstrated the strong cooperative effects of IL-17A and IL-36 cytokines in regulating target genes, including CCL-20, IL-8, and antimicrobial peptides (AMPs) (128). Adult normal human epidermal keratinocytes were stimulated for 24 h with recombinant IL-36 and IL-17. Both IL-36α and IL-36γ self-amplified their mRNAs and synergistically enhanced the mRNA and protein levels when combined with IL-17A. Notably, IL-17C was significantly increased by IL-36 alone or in synergy with IL-17A. Additionally, combinations of IL-17A and IL-36γ significantly elevated the expressions of IL12B and IL23A. We recently reported that IL-17 and IL-36 work together to amplify the expression of pro-inflammatory and pro-fibrotic genes in normal human dermal fibroblasts (NHDF). Co-blocking IL-17 and IL-36 is more effective at inhibiting the production of IL-6 and IL-8 in NHDF stimulated by IL-17A and IL-36 compared with using two separate monoclonal antibodies (131).

It is clear that the IL-17 and IL-36 signaling pathways have both overlapping and distinct roles in various inflammatory contexts. However, the interaction between these two cytokines in the pathogenesis of chronic kidney diseases, including lupus nephritis (LN), remains to be fully explored. Given that a combination of approaches may be necessary to harness the potential of IL-17 antagonism in LN, it is important to determine whether co-targeting both pathways could enhance disease management, leading to immunological improvements and overall better disease outcomes.