Characterisation of an enhanced preclinical model of experimental MPO‐ANCA autoimmune vasculitis

Experimental autoimmune vasculitis (EAV) is a model of antineutrophil cytoplasm antibody (ANCA)‐associated vasculitis (AAV) induced by immunisation of susceptible rat strains with myeloperoxidase (MPO). Animals develop circulating MPO‐ANCA, pulmonary haemorrhage, and glomerulonephritis, although renal injury is mild and recovers spontaneously without treatment. In this study we aimed to augment the severity of glomerulonephritis. Following induction of EAV on day 0, a sub‐nephritogenic dose of nephrotoxic serum (NTS) containing heterologous antibodies to glomerular basement membrane was administered on day 14. This resulted in a significant increase in disease severity at day 28 compared to MPO immunisation alone – with more urinary abnormalities, infiltrating glomerular leucocytes, and crescent formation that progressed to glomerular and tubulointerstitial scarring by day 56, recapitulating important features of human disease. Importantly, the glomerulonephritis remained pauci‐immune, and was strictly dependent on the presence of autoimmunity to MPO, as there was no evidence of renal disease following administration of sub‐nephritogenic NTS alone or after immunisation with a control protein in place of MPO. Detailed phenotyping of glomerular leucocytes identified an early infiltrate of non‐classical monocytes following NTS administration that, in the presence of autoimmunity to MPO, may initiate the subsequent influx of classical monocytes which augment glomerular injury. We also showed that this model can be used to test novel therapeutics by using a small molecule kinase inhibitor (fostamatinib) that rapidly attenuated both glomerular and pulmonary injury over a 4‐day treatment period. We believe that this enhanced model of MPO‐AAV will prove useful for the study of glomerular leucocyte behaviour and novel therapeutics in AAV in the future. © 2021 The Authors. The Journal of Pathology published by John Wiley & Sons, Ltd. on behalf of The Pathological Society of Great Britain and Ireland.


Introduction
Anti-neutrophil cytoplasm antibody (ANCA)-associated vasculitis (AAV) is a rare systemic autoimmune disease, which can cause life-threatening lung haemorrhage and end-stage kidney disease (ESKD) [1]. The typical renal lesion in AAV is pauci-immune crescentic glomerulonephritis. Circulating ANCAs are directed to myeloperoxidase (MPO) or proteinase-3 (PR3), which are present in the granules of neutrophils and lysosomes of monocytes [2,3], and a number of experimental and clinical observations indicate that they have a direct pathogenic role in disease pathogenesis [4,5].
Studies in animal models have been critical for understanding disease mechanisms, and several rodent models of anti-MPO vasculitis have been developed [6]. These include passive transfer of anti-MPO antibodies, raised in MPO-deficient mice, to naïve wild-type mice, causing glomerulonephritis (GN) and pulmonary capillaritis [5][6][7]. Models of active autoimmunity in mice have also been developed; mice immunised with mouse MPO develop anti-MPO antibodies at low titre, but these are not sufficient to cause GN, and a 'second-hit' is required to induce disease. For example, a subsequent injection of heterologous anti-mouse glomerular basement membrane (GBM) globulin results in transient neutrophil recruitment to the glomerulus. This 'planting' of the MPO autoantigen (derived from retained neutrophils) results in recruitment of MPO-specific CD4 + T cells, neutrophils, and macrophages to the glomerulus, and the development of crescentic GN [8,9]. The disease triggered by anti-GBM globulin is dependent on MPO; disease does not occur in MPO-deficient mice. A limitation of this model is that the response to anti-GBM globulin is itself nephritogenic; by 4 days, mice develop an autologous immune response to deposited anti-GBM antibody, leading to severe GN, even in the absence of pre-immunisation with MPO. As such, study of anti-MPO-mediated disease is limited to early time points, meaning that therapeutics can only be tested in preventative studies, not after the development of vasculitis [9,10].
A model of experimental autoimmune vasculitis (EAV) in the susceptible Wistar-Kyoto (WKY) rat strain was previously described by Little et al in our laboratory. Rats immunised with human MPO develop polyclonal MPO-ANCA cross-reactive to rat MPO expressed in neutrophils and monocytes, and subsequently small vessel vasculitis, pauci-immune GN, and haemorrhagic pulmonary capillaritis [11][12][13][14]. A limitation of the model is that renal disease is relatively mild; glomerular lesions are mainly proliferative, crescent formation is rare, and disease spontaneously resolves from 6 weeks post-induction. It has been shown in other studies in rats that addition of a low dose of NTS, containing heterologous anti-rat GBM antibodies, after immunisation with MPO results in increased disease severity [15,16], similar to the approach described in mice. However, this approach is not well characterised in rats, and in these reports the administration of NTS alone, in the absence of autoimmunity to MPO, induced GN, and immunoglobulin deposits could be detected in glomeruli.
In this study, we aim to augment disease severity of EAV by the addition of a truly sub-nephritogenic dose of NTS that is insufficient to induce disease in the absence of autoimmunity to MPO. To investigate possible mechanisms by which sub-nephritogenic NTS increases disease severity, we isolate and phenotype glomerular leucocytes using flow cytometry. Finally, we show that an enhanced model can be used to test therapeutic approaches in a preclinical study.

Animal husbandry
WKY and Lewis rats were purchased from Charles River (Saffron Walden, UK) and maintained in a pathogen-free animal facility at the Central Biomedical Services unit, Hammersmith Hospital Campus, Imperial College London. All procedures were carried out in accordance with the regulations of the UK Animals (Scientific Procedures) Act (1986) and ARRIVE (Animal Research: Reporting of In Vivo Experiments) guidelines.

Experimental autoimmune vasculitis/NTS administration
NTS was prepared in rabbits as previously described [17]. For the NTS titration experiment, male WKY rats aged 8-9 weeks (n = 4 per group) were immunised intravenously (i.v.) with 100 μl of NTS (or serial dilutions in sterile PBS) and maintained until 10 days postimmunisation.
For 'double' immunisation studies, on day 14 after initial immunisation with MPO, 100 μl of a 1:100 dilution of NTS or normal rabbit serum (NRS) was administered i.v. Urine was collected weekly by housing animals in individual metabolism cages overnight, and blood collected every 14 days by lateral tail vein bleed. Animals were sacrificed after 28, 42 or 56 days.
For additional experiments to assess glomerular cell infiltrate at early time points, neat or 1:100 NTS was given i.v. to 8-to 9-week-old male WKY rats (n = 4 per group) and animals were sacrificed after 3 h, 24 h or 7 days.

Assessment of renal disease
Proteinuria was measured by the sulphosalicylic acid method and haematuria by urine dipstick (Multistix 8; Siemens, Munich, Germany) [18]. At the end of each experiment, animals were exsanguinated under terminal anaesthesia. Renal tissue was fixed in 10% neutral buffered formalin, transferred to 70% ethanol, and processed to paraffin blocks. Sections were stained with periodic acid Schiff (PAS), haematoxylin and eosin, and Jones' silver stain. Fifty consecutive glomeruli were assessed for crescents AE necrosis, segmental necrosis, or minor changes such as segmental endocapillary proliferation by a blinded observer, and results were expressed as the mean proportion of glomeruli for each animal. Immunoperoxidase staining was carried out using CD68 (ED-1; Bio-Rad, Watford, UK; dilution 1:500), CD8 (OX-8; Bio-Rad; dilution 1:50), CD3 (1F4; Bio-Rad; dilution 1:400), and for smooth muscle actin (M0851; Dako, Ely, UK; dilution 1:100). The number of positive cells was quantified using ImageProPlus software to measure percentage area staining in 20 consecutive glomeruli, or 20 consecutive high-power fields (HPFs) for interstitial staining, and results were expressed as the mean percentage for each animal. Smooth muscle actin immunostaining was used to

Assessment of lung injury
Severity of lung injury was graded by visual inspection of the lungs using a semi-quantitative scoring system which graded lungs as 0, normal; 1, fewer than 10 petechiae; 2, 10-20 petechiae; or 3, if more than 20 petechiae were seen. Lung tissue was also collected and processed as for kidney tissue. Perls' Prussian blue staining was used to quantify haemosiderin-laden macrophages using ImageProPlus software by measuring the proportion of stained cells in 5 HPFs.

Assessment of autoantibody response
Anti-MPO antibodies were assayed in serum using a direct ELISA. Plates were coated with 1.33 μg/ml hMPO overnight, blocked with 3% BSA followed by rat serum, and standards diluted in PBS. A goat anti-rat IgG-ALP conjugate (1:1000; Sigma) was used as a secondary antibody and plates were developed with p-nitrophenyl-phosphate solution (Sigma).
IgG binding to rat leucocytes was assayed using flow cytometry and indirect immunofluorescence (IIF). For flow cytometry, whole blood was collected via cardiac puncture; red cells were lysed (1X RBC Lysis Buffer; eBioscience); and cells were used for cell surface staining with antibodies against CD3 (eBioG4.18, PE), B220 (HIS24, PE), and CD161a (3.2.3, PE), all 1:40. Cells were fixed and permeabilised, then incubated with 1:1000 dilution of rat serum followed by an Alexa 647-conjugated anti-rat IgG secondary (1:1000; BioLegend). Cells were analysed on a BD LSRFortessa flow cytometer with standard lasers, and gating strategy and analysis performed using FlowJo v10 software. The mean fluorescence intensity (MFI) of PE-negative cells was used to quantify IgG binding. For IIF, rat bone marrow was applied to microscope slides using a cytospin at 300 rpm for 3 min. Cells were fixed in 95% ice-cold ethanol for 10 min, blocked for 20 min in 20% goat serum, and incubated with rat serum diluted 1:10 in PBS. Bound IgG was detected using FITC-conjugated goat anti-rat IgG (1:1000; Sigma).
Deposited rat and rabbit IgG was assessed using direct immunofluorescence on frozen kidney sections using FITC-labelled antibodies and quantified by examining 20 glomeruli and scoring each as 0 to 3+, with results expressed as mean per animal. Indirect immunofluorescence for C3 was carried out using anti-C3 (1:200, 12E2; Abcam) with anti-mouse FITC secondary (1:200; Vector Laboratories, Peterborough, UK). Direct immunofluorescence for MPO was carried out using anti-MPO FITC (2D4; Abcam) and to aid visualisation of glomeruli, tomato-lectin-DyLight 594 conjugate was added (Vector Laboratories).
For electron microscopy, renal tissue was collected in 2.5% glutaraldehyde. Processing of tissue sections and imaging was carried out by North West London Pathology.

SYK inhibitors
Fostamatinib disodium (R788) was a gift from Rigel Pharmaceuticals (South San Francisco, CA, USA). It was reconstituted in vehicle formulation (0.1% carboxymethylcellulose, 0.1% methylparaben sodium, 0.02% propylparaben sodium, in distilled water, pH 6.5). Based on a previous dose-ranging study in nephrotoxic nephritis (NTN) in WKY rats, animals received 30 mg/kg, administered by twice daily oral gavage [21]. Control animals received an equivalent volume and schedule of vehicle formulation.

Statistical analysis
Statistical analysis was conducted using Prism 8.0 (GraphPad Software Inc, San Diego, CA, USA). Unless otherwise stated, all data are reported as median with interquartile range. Where appropriate, Mann-Whitney U and Kruskal-Wallis tests were used to assess the difference between two or more than two groups, with Dunn's post hoc test to compare individual groups.

Results
Administration of a sub-nephritogenic dose of NTS in EAV increases renal injury in the presence of autoimmunity to myeloperoxidase, and disease remains pauci-immune In the conventional NTN model, WKY rats are immunised with 100 μl of neat (undiluted) rabbit anti-rat NTS by intravenous (i.v.) injection, resulting in rapid glomerular deposition of rabbit IgG, urinary abnormalities by day 4, deposition of autologous rat IgG by day 6, and severe crescentic GN by day 10 [17].
To identify a sub-nephritogenic dose of NTS, rats were immunised with serial dilutions of NTS from neat An experimental model of MPO-ANCA vasculitis 109 to 1:100 (n = 4 per group) and assessed at day 10. After immunisation with 1:50 or lower dilutions of NTS, there was no detectable glomerular injury, and there was no evidence of either deposited rabbit or autologous rat IgG within the kidney by direct immunofluorescence (supplementary material, Figure S1A-J). Thus, a 1:100 dilution of NTS was selected as a sub-nephritogenic dose for all subsequent experiments.
To assess whether the addition of this sub-nephritogenic dose of NTS could augment disease severity in EAV, WKY rats were immunised with human MPO [or human serum albumin (HSA) as control] on day 0, followed by 1:100 NTS [or 1:100 normal rabbit serum (NRS) as control] on day 14 (n = 4-6 per group). This time point (day 14) after MPO immunisation was selected because rats have developed circulating Figure 1 Legend on next page.

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M Prendecki et al MPO-ANCA but no urinary abnormalities or glomerular injury. By 7 days after administration of NTS (21 days after MPO immunisation), animals began to develop urinary abnormalities. At day 28 after initial immunisation with MPO, the addition of 1:100 NTS caused significant increases in haematuria ( Figure 1A; median dipstick haematuria 3, 0, 0, 0 for MPO/NTS, MPO/NRS, HSA/NTS, HSA/NRS, respectively; p < 0.0001) and proteinuria ( Figure 1B; median proteinuria 137.0, 5.0, 6.0, 3.4 mg/day for MPO/NTS, MPO/NRS, HSA/NTS, HSA/NRS, respectively; p < 0.0001). Histological assessment at day 28 showed glomerular necrosis and crescents in all animals immunised with MPO/NTS, with around 60% abnormal glomeruli, including 30% with crescents. Disease was similar to that seen in AAV, with focal disease, crescents, and segmental necrosis the main features ( Figure 1C,I). In animals immunised with MPO/NRS, there were mild proliferative changes and occasional crescent formation, in keeping with early conventional EAV (supplementary material, Figure S2). Animals immunised with HSA and NTS/NRS had near-normal glomerular histology (supplementary material, Figure S2). There was a significant increase in cell infiltration into glomeruli at 28 days in MPO/NTS animals when assessed by immunostaining and this was predominantly CD68/ED-1 + monocyte/macrophages [ Figure 1D Importantly, in animals immunised with subnephritogenic NTS, disease remained pauci-immune with no detection of deposited autologous rat IgG or C3 at day 28 in any group by indirect immunofluorescence (Figure 2A-F). There were no deposited immune complexes seen using electron microscopy in any group ( Figure 2G,H). Cellular crescents and cells interacting with the GBM were seen by electron microscopy in animals immunised with MPO/NTS but not in other groups ( Figure 2G,H and supplementary material, Figure S3A-D).
Susceptibility to GN in this model was limited to the WKY rat strain. Despite developing robust autoimmunity to MPO, Lewis rats did not develop urinary or glomerular abnormalities following immunisation with MPO and low-dose NTS (supplementary material, Figure S4A-F). Immunostaining for monocytes/macrophages using CD68/ED-1 identified a small cellular infiltrate (supplementary material, Figure S4G,H). This was also seen on flow cytometry phenotyping of glomerular cellular infiltrate, which identified a small infiltrate of NC monocytes (supplementary material, Figure S4I).
Addition of a sub-nephritogenic dose of NTS has no effect on lung injury or circulating autoantibodies There was no difference in lung haemorrhage severity in animals given 1:100 NTS in addition to MPO, either by visual inspection ( Figure 3A; median lung haemorrhage score 1, 1, 0, 0 for MPO/NTS, MPO/NRS, HSA/NTS, HSA/NRS, respectively) or by Perls' staining for haemosiderin-laden macrophages (Figure 3B,C; median Perls' stain 0.13, 0.11, 0, 0 au for MPO/NTS, MPO/NRS, HSA/NTS, HSA/NRS, respectively). The degree of lung injury was in keeping with that seen in our previous studies of EAV without additional NTS/NRS [14]. There was no difference in circulating MPO-ANCA levels between the groups of rats immunised with MPO, either by ELISA using human MPO or by flow cytometry to assess IgG binding to rat leucocytes ( Figure 3D,E). IIF using normal rat bone marrow cells confirmed that sera from rats immunised with hMPO (AE NTS) resulted in perinuclear staining in cells with neutrophil nuclear morphology ( Figure 3F). Rats immunised with MPO followed by a sub-nephritogenic dose of NTS develop glomerular and tubulointerstitial scarring at 6 and 8 weeks In the conventional EAV model, disease spontaneously resolves beyond 6 weeks. To assess disease phenotype at later time points in this enhanced model, WKY rats (n = 5 or 6 per group) were immunised with the protocol described above for examination at days 42 and 56. We did not examine control animals (MPO/NRS, HSA/NTS, HSA/NRS) at these time points as no significant disease was present in these groups at 28 days. Proteinuria decreased steadily after day 28 in 10/11 rats. One animal developed persistently high levels of proteinuria until day 56 ( Figure 4A; median proteinuria 69.9, 54.5, 55.8, 37.9, and 40.1 mg/day at days 28, 35, Images/quantification in experimental animals were obtained at day 28 (14 days after immunisation with NTS). Images for comparison following neat NTS administration were obtained at day 14 after immunisation with NTS (without prior immunisation with MPO). Electron microscopy images from control groups are shown in supplementary material, Figure S3. NTS, nephrotoxic serum; NRS, normal rabbit serum.

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42, 49, and 56, respectively). All rats continued to have 3+ haematuria until the time of sacrifice ( Figure 4B). Cellular crescents at day 28 progressed to a mixture of cellular and fibrocellular crescents at day 42, with further progression at day 56 ( Figure 4C,H). Glomerular cell infiltrate decreased sequentially at days 42 and 56 ( Figure 4D,E). CD68/ ED-1 + cell infiltrate was predominately tubulointerstitial and peri-glomerular at both time points ( Figure 4E,G; median glomerular CD68/ED-1 staining 1.0% and 0.6% per GCS at weeks 6 and 8, respectively). Smooth muscle actin (SMA) staining was used to identify myofibroblasts and the development of fibrocellular crescents, with predominantly interstitial staining seen at day 42, and glomerular and interstitial staining by day 56 ( Figure 4F,G,J; median tubulointerstitial staining 0.23%, 2.7%, and 6.1% per HPF at days 28, 42, and 56, respectively; p = 0.0004; median glomerular staining 0.03%, 1.2%, and 10.1% per GCS at days 28, 42, and 56 respectively; p < 0.0001). There was continuing evidence of lung haemorrhage in most animals, more severe at day 42 than at day 56, in keeping with the natural history of conventional EAV (supplementary material, Figure S5A-C; median Perls' stain 1.4 and 0.4 at days 42 and 56, respectively). Circulating MPO-ANCA levels peaked at day 42 after immunisation (supplementary material, Figure S5D). There was no evidence of deposited glomerular rat or rabbit IgG at days 42 or 56.

Sub-nephritogenic NTS induces early infiltrate of non-classical monocytes
In the autoimmune MPO model of GN in mice, administration of NTS is thought to cause glomerular neutrophil infiltration and degranulation, extracellular MPO deposition, and augmented glomerular injury in mice with autoimmunity to MPO [9,10]. To investigate this in our model, we re-examined early time points after administration of NTS. Rats were immunised with either neat or 1:100 NTS and sacrificed at 3 or 24 h (n = 4 per group). By direct immunofluorescence, there was strong linear deposition of rabbit IgG following immunisation with neat (undiluted) NTS and faint deposition of rabbit IgG within the kidney at 3 h with 1:100 NTS, which largely resolved by 24 h ( Figure 5A). It was not possible to quantify the difference in fluorescence intensity between this and neat NTS as the magnitude of the difference was so great that images could not be captured with comparable exposure times. Images of direct immunofluorescence for rabbit IgG in a normal rat and after immunisation with 1:100 NRS with equivalent exposure times are shown for comparison ( Figure 5A). At 3 h after immunisation with 1:100 NTS, there was patchy deposition of complement C3, of decreased intensity compared with animals immunised with neat NTS ( Figure 5B). We then examined glomerular cell infiltrate at these early time points using two methods ( Figure 5C-E). By both indirect immunofluorescence and flow cytometry, there was significant neutrophil infiltrate and deposition of granular extracellular MPO within glomeruli at 3 h after immunisation with neat NTS. This was not seen following immunisation with 1:100 NTS; the neutrophil number in this group was similar to that in normal rats. The neutrophil infiltrate seen with neat NTS reduced by 24 h, suggesting a transient effect on neutrophil recruitment ( Figure 5C; median neutrophils per    Using flow cytometry, by 24 h after immunisation with 1:100 NTS there was a small infiltrate of nonclassical monocytes, lower than that seen with neat NTS, but significantly higher than normal rats ( Figure 5C; median 5.8, 4.9, and 7.7 cells per glomerulus for normal, 3 h, and 24 h after 1:100 NTS, respectively; p = 0.03 for 24 h compared with normal). This suggests that a sub-nephritogenic dose of NTS may alter early non-classical monocyte, rather than neutrophil, retention within glomeruli in this model.

Fostamatinib treatment reduces the severity of renal and lung injury in augmented EAV
We next set out to identify whether this model was useful for evaluation of therapeutic strategies. We have previously used fostamatinib, a small molecule inhibitor of spleen tyrosine kinase (Syk), as treatment in experimental models of GN, including EAV [14,21]. Given the rapid onset of therapeutic effect in previous experiments, we elected to assess a short period of treatment in the

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M Prendecki et al present study. Animals were treated from day 24 (after onset of renal disease evidenced by urinary abnormalities) until day 28. In keeping with our previous studies, fostamatinib was administered at a dose of 30 mg/kg twice daily by oral gavage (n = 5 or 6 per group). After 4 days' treatment with fostamatinib, there was a significant reduction in proteinuria compared with vehicle-treated animals ( Figure 6A; median proteinuria per day 62.8 mg and 9.4 mg for vehicle-and fostamatinib-treated rats, respectively; p = 0.002). There was a non-significant reduction in haematuria, but this was not seen in all animals, likely reflecting the short treatment period ( Figure 6B; median dipstick 3 and 2.5 for vehicle-and fostamatinib-treated rats, respectively). There was a significant improvement in glomerular injury, with near-normal histology in fostamatinib-treated animals, and around 50% abnormal glomeruli in vehicle-treated rats ( Figure 6C). Glomerular infiltrating leucocytes were reduced by both CD68/ ED-1 immunohistochemistry ( Figure 6D; median CD68/ED-1 % staining per GCS 4.2 and 0.02 for vehicle-and fostamatinib-treated rats, respectively; p = 0.004) and flow cytometry ( Figure 6E). Fostamatinib also improved lung injury; compared with vehicletreated animals, there were decreases in visual lung haemorrhage score ( Figure 6F; median score 1.5 and 0 for vehicle-and fostamatinib-treated rats, respectively; p = 0.04) and haemosiderin-laden cells ( Figure 6G; median Perls' score 0.11 and 0 for vehicle-and fostamatinib-treated rats, respectively; p = 0.01). As expected with a short duration of treatment, there was no difference in circulating MPO-ANCA levels ( Figure 6H).

Discussion
We have shown that adding a sub-nephritogenic dose of NTS to immunisation with MPO results in significant augmentation of renal injury in EAV. By using a low dose of NTS, this model remains pauci-immune with no detectable immune complex deposition by conventional methods (either immunofluorescence or electron microscopy) at the time of crescentic GN. The model remains critically dependent on the presence of autoimmunity to MPO, as disease does not occur following immunisation with a control human protein.
In contrast to previously described rodent models, an autologous response to NTS does not occur at any time point in this model [9,[22][23][24]. In a previous study in the Brown Norway rat, which is less susceptible to GN than the WKY strain, animals immunised with low-dose NTS, even in the absence of autoimmunity to MPO, developed clear evidence of GN, including proteinuria and glomerular macrophage infiltration. In addition, disease was not pauci-immune, as strong linear deposits of rabbit IgG were seen at all time points, with deposited rat IgG in areas of crescent formation [16]. Another study used the susceptible WKY strain, as in our model. Again, however, the dose of NTS in isolation caused overt GN with substantial haematuria and 5% glomerular crescents by light microscopy, and no data were provided regarding the pattern of glomerular immunoglobulin deposition [15]. By contrast, in our study, the dose of NTS was decreased such that no urinary or glomerular abnormalities occurred in rats immunised with low-dose NTS following a control protein.
This model has several advantages over the conventional EAV protocol; it allows for a shortened disease course from 42 to 28 days and, as disease is more reproducible and of greater severity, for a reduction in the number of rats needed to test therapeutic approaches. Rather than complete resolution after day 28, disease progresses to fibrosis and scarring, which more accurately recapitulates the natural history of ANCA-associated GN in humans. Disease is somewhat heterogeneous, particularly the degree of proteinuria (which ranged from 36 to 220 mg/day). Glomerular crescents and CD68/ ED-1 + cell infiltration were less variable; these may be better outcome measures to use in studies of therapeutic approaches.
Analysis of glomerular infiltrating cells at day 28 showed that a 1:100 NTS dose alone induced a small influx of non-classical monocytes (median 8.2 and 6 cells per glomerulus in animals immunised with HSA/NTS and normal WKY rats, respectively; p = 0.1) but in the presence of autoimmunity to MPO, this was much greater (17.3 cells per glomerulus, p = 0.0005) and was accompanied by a significant infiltrate of classical monocytes. Although we could not detect immune complexes or deposited autologous IgG within the kidney, low-dose NTS is clearly mediating a biological effect. We show that within 3 h of injection it is transiently localised to the kidney at very low levels, accompanied by C3 deposition, and this is followed by a small but significant infiltration of non-classical monocytes by 24 h. We hypothesise that this influx of non-classical, patrolling monocytes occurs in response to low-dose NTS in glomeruli, via direct Fc receptor-(CD16-) or complementdependent mechanisms. This is in keeping with intravital microscopy studies in both mice and rats with NTN [20,[25][26][27][28]. In WKY rats, we have recently shown that in response to nephritogenic stimuli, there is increased LFA-1-dependent surveillance of the endothelium by non-classical monocytes, and subsequent classical monocyte retention within the glomerulus in conventional NTN [20]. We now show that this response is insufficient to initiate GN after a reduced dose of NTS alone. However, these non-classical monocytes express MPO, and we hypothesise an interaction with circulating MPO-ANCA in MPO-immune ratssuch that these retained and activated non-classical monocytes may initiate disease and promote classical monocyte recruitment.
In a well-characterised mouse model of MPO-AAV, low-dose NTS is thought to mediate its actions by recruiting neutrophils to the glomerulus. In our model, we could not detect early infiltration of neutrophils following a sub-nephritogenic dose of NTS. This does not exclude a role for neutrophils in this cell type, as An experimental model of MPO-ANCA vasculitis 117 neutrophil survival may be impaired during tissue processing and may lead to an underestimate of their true number in our flow cytometric analysis. Future studies using intravital microscopy and live cell imaging will be useful to definitively assess early glomerular cell infiltrate following injection of neat and 1:100 NTS. Mechanisms may also differ between species and rodent strains. The WKY rat has a pro-inflammatory monocyte/macrophage phenotype, such that disease in this strain may be dependent on these cell types [29]. In keeping with this, we show that although Lewis rats develop a small glomerular infiltrate of non-classical monocytes at day 28 after immunisation with MPO and low-dose NTS, they do not develop features of GN, again suggesting that monocyte/macrophage responses contribute to disease initiation in this model. This may have relevance for clinical translation, as there is increasing evidence that monocytes play a previously underappreciated role in AAV. Monocytes express the ANCA autoantigens; stimulation with ANCA in vitro leads to cytokine production and generation of ROS; and monocytes and macrophages are the predominant cell types identified in renal biopsies from patients with AAV. As such, a monocyte/macrophage-dependent mechanism in this model may be in keeping with aspects of disease pathogenesis in humans.
Finally, we also showed that this model is useful for testing therapeutic approaches, by administering a Syk inhibitor during established disease. Notably, in the present study we used a very short treatment period of only 4 days and showed rapid reversal of glomerular injury, with a significant effect on infiltrating monocytes. These data support clinical investigation of Syk inhibition as a therapeutic target.
By adding a sub-nephritogenic dose of NTS to the existing model of EAV, we have developed a model of MPO-AAV which has several advantages over the standard protocol. It is more reproducible, with a greater proportion of crescents and more severe glomerular damage. This allows for a reduction in the number of animals required when testing therapeutic agents and, by timing of the administration of therapeutic interventions, it is possible for investigators to distinguish their effects on both autoimmunity and glomerular injury. Unlike standard EAV, this model progresses to scarring and fibrosis, meaning that it can also be used to study endpoints relevant to clinical disease. Crucially, disease remains pauci-immune and critically dependent on the presence of autoimmunity to MPO. We believe that this model complements existing in vivo approaches for investigating AAV and that it will prove valuable for future preclinical therapeutic studies. Figure S1. A dilution of 1:100 NTS is a sub-nephritogenic dose