**3.2 iNKT cell phenotype**

#### **3.2.1 Response to α-GalCer**

Kojo et al. (2001) examined the functional phenotype of Vα24Jα18+ DN iNKT cells in patients with RA and other autoimmune diseases. Peripheral blood mononuclear cells (PBMC) stimulated with α-GalCer for 10 days resulted in expansion of iNKT cells in just 3 out of 10 RA patients (from 0-10 to 61-1480 cells/105 lymphocytes) as compared to all 7 healthy controls (from 6-123 to 350-3169 cells/105 lymphocytes). The proportion of responders was 50% in patients with SLE (n=10) and SSc (n=8). No clear relationship was noted to disease activity.

In further experiments, Linsen et al. (2005) also characterised the phenotype of Vα24+Vϐ11+CD3+ iNKT cells in RA compared to healthy controls. The capacity of NKT cells to respond to α-GalCer was tested in peripheral blood of 7 healthy and 13 RA patients as well as the SF from 5 RA patients. PBMC or synovial mononuclear cells (SFMC) were stimulated with α-GalCer and re-stimulated at day 7 with pulsed, irradiated PBMCs then analysed by flow cytometry at day 14. The number of NKT cells from RA peripheral blood (PB) and SF remained lower than that of healthy controls (8.4 and 4.4 vs 15.8%, respectively). Like Kojo et al. (2001), the investigators noted two separate RA populations comprised of non-responders (6/13 patients) and responders (7/13 patients). In fact, RA responders showed stronger responses than healthy controls (294 vs 149 fold, respectively). They too did not find any correlation between response and clinical or treatment phenotype. SF iNKT cells however responded in all tested patients.

In keeping with these earlier results, our own experiments showed that peripheral iNKT cells stimulated with α-GalCer for 12 days display impaired expansion in RA patients compared to controls (31 vs 121 fold, respectively). Using the 25th percentile of foldexpansion in healthy controls, 75% of RA vs 20% of healthy controls are non-responders with no detectable differences between early and late RA (Tudhope et al., 2010).

While investigating the mechanism underlying non-response to α-GalCer in RA patients, Kojo et al. (2001) found that non-responder APCs could expand responder iNKT cells in the presence of α-GalCer and IL-2, albeit with a lower response than responder APCs. In contrast, non-responder iNKT cells failed to expand in the presence of responder APCs under the same culture conditions. This suggested that in non-responders, the defect lay within iNKT cells rather than APCs.

#### **3.2.2 Cytokine production**

24 Rheumatoid Arthritis – Etiology, Consequences and Co-Morbidities

peripheral blood (0.03% vs 0.11%, respectively) but unlike Spadaro et al. (2004), their synovial fluid samples showed an inconsistent trend toward higher percentage of NKT cells in SF from seven patients as compared to matched peripheral blood (0.08% vs 0.05%,

have been shown to be functionally distinct and therefore individual subset frequency may

In a study of patients with a range of autoimmune diseases including 20 patients with RA, Vα24Jα18+ DN T cells were found to express polymorphic Vϐ11 and CD161 almost universally, suggesting that these were likely to be true iNKT cells. The frequency of these DN NKT cells was markedly reduced in RA patients who had a mean of 48.8 cells/ml as compared to 290 cells/ml in healthy controls. Similar findings applied to patients with SLE, systemic sclerosis (SSc) and Sjogren's syndrome (SS) but not Behcet's disease (BD), and

Vα24+CD8+ NKT cells have been shown to consist mainly of CD161+, CD1d-restricted NKT cells that have an immunoregulatory phenotype (Ho et al. 2004; Takahashi 2002). Mitsuo et al. (2006) examined the frequency of this NKT cell subset in patient with RA (n=24), SLE (n=54), SSc (n=14), mixed connective tissue disease (MCTD) (n=15) and polymyositis/ dermatomyositis (PM/DM) (n=13) compared to healthy controls (n=18). The absolute frequency of CD161+CD8+ T cells was reduced in all patients compared to healthy donors, although in RA patients the relative frequency was not statistically significantly lower. No

Whilst Yanagihara et al. (1999) found no correlation between iNKT cell frequency and clinical disease activity, Parietti et al. (2010) noted a trend toward lower iNKT cell numbers with higher disease activity (DAS28), ESR and CRP. Our group also found no correlation with disease activity although a moderate but statistically significant inverse relationship

Parietti et al. (2010) measured iNKT cell frequencies in seven patients before and after treatment with rituximab, an anti-CD20 monoclonal antibody targeting B cells. They found a significant increase in NKT frequency and percentage from baseline at days 45 and 120 post-infusion (1.7, 3.4 and 4.1 cells/μL, or 0.1%, 0.32% and 0.3%, respectively). There was also a clear correlation between clinical outcome and NKT cell frequency change with nonresponders showing no change whilst responders saw a 600% increase in frequency. In our study, we measured iNKT cell frequencies in seven patients before and after initiating methotrexate therapy and found that iNKT frequency increased as early as two weeks after the start of treatment. Unlike Parietti et al.'s results however, we found no obvious link to

Kojo et al. (2001) examined the functional phenotype of Vα24Jα18+ DN iNKT cells in patients with RA and other autoimmune diseases. Peripheral blood mononuclear cells

be immunologically more relevant than global iNKT cell numbers.

CD4+ NKT cells were similarly reduced in frequency (Kojo et al., 2001).

correlation with age, gender or treatment was noted (Mitsuo et al., 2006).

**3.1.4 Correlation with disease activity and treatment response** 

with CRP could be demonstrated (Tudhope et al., 2010).

clinical response (Tudhope et al., 2010).

**3.2 iNKT cell phenotype 3.2.1 Response to α-GalCer**  (DN), CD4+ and CD8+ cells. iNKT cells from these subsets

respectively).

**3.1.3 iNKT cell subsets**  iNKT cell subsets include CD4-

> In keeping with iNKT cell frequency as measured by flow cytometry, linsen et al. performed ELISPOT analysis of cytokine production by isolated PBMC stimulated with α-GalCer and found a decreased frequency of reactive cells producing IFN-γ (2.3 vs 24.3, respectively) and IL-4 (0.2 vs 3.9, respectively) in RA patients compared to healthy controls. The IL-4/IFN-γ ratio was also reduced (0.07 vs 0.30, respectively), suggesting a Th1-like phenotypic bias in RA which could not be explained by any differences in CD4+ and CD4- subsets, or selective clonal expansion as shown by Vα24 and Vϐ11 TCR CDR3 fragment length spectra analysis (Linsen et al., 2005).

> Intracellular cytokine staining of iNKT cells in PB revealed marked differences between RA patients and healthy controls for IFN-γ+ (92.5 vs 64.5%, respectively), IL-4+ (1.4 vs 15.7%, respectively) and IFN-γ+IL-4+ iNKT cells (6.1 vs 19.7%, respectively), confirming the Th1 bias in PBMC-derived iNKT cells. In contrast, cytokine profiles for SF iNKT cells were more similar to that of healthy control PB iNKT cells, with smaller proportion of IL-4+ and higher proportion of IFN-γ+IL-4+ iNKT cells (5.3 and 28.4%, respectively), suggesting a Th0-profile in SF-derived iNKT cells. No correlation with response to α-GalCer, or disease and treatment parameters was noted (Linsen et al., 2005).

Invariant Natural Killer T Cells in Rheumatoid Arthritis and Other Inflammatory Arthritides 27

Finally, migration of iNKT cells into secondary lymphoid, liver or joint compartments might account for some of the apparent reduction in iNKT cell numbers in RA. Selective migration into joint synovial tissue or synovial fluid however is not supported by analysis of cell frequency and clonality in these compartments, but we cannot exclude migration into secondary lymphoid organs or liver as a possible factor. As most iNKT cells are found in the spleen or liver tissues, with relatively significantly fewer iNKT cells in peripheral blood, assessing the iNKT cell population size from peripheral blood frequency alone is therefore

Given the distribution of iNKT cells to organs which are not easily amenable to investigation in human subjects, animal models of RA-like inflammatory arthritis have provided invaluable insight into the possible pathogenic or protective roles played by iNKT

iNKT cells. Furthermore, these models have given investigators an opportunity to explore interventions to either harness or subdue iNKT cell functions for therapeutic benefit. In this section, we review the findings and attempt to make sense of the occasionally puzzling and

Collagen-induced arthritis (CIA) in mice was first demonstrated in 1981 by Wooley et al. as a promising animal model of inflammatory arthritis. The parenteral administration of heterologous chicken or bovine-derived type II collagen (CII) in complete Freund's adjuvant (CFA) containing heat-killed *Mycobacterium tuberculosis*, followed by a booster 21 days later to genetically susceptible mice results in a persistent inflammatory arthritis sharing many of the features of RA, including mononuclear synovial infiltrate, presence of rheumatoid factor and pannus formation, leading to cartilage destruction and bone erosion. CD4+ T cells are thought to be the primary mediators of disease induction characterised by early Th1 polarisation, whilst complement-fixing anti-CII autoantibody are responsible for the chronic inflammation during the effector phase of the immune response (Luross & Williams, 2001). CIA has been extensively characterised and has proved useful not only in furthering our understanding of basic pathophysiological mechanisms involved in inflammatory arthritis, but also in testing the therapeutic efficacy of potential new treatments for RA (Hegen et al.,

Unlike the susceptible DBA/1 mice normally used in collagen-induced arthritis models, C57BL/6 mice NKT cells express the NK1.1 marker but are also susceptible to CIA with a 70% arthritis incidence. Prior to the widespread availability of more specific detection reagents, Wang et al. (2003) first noted that C57BL/6 mice with higher clinical arthritis scores had lower NK1.1+CD3+ T cell spleen and LN frequency but greater synovial membrane infiltration in more severely affected joints. NK1.1+ cell depletion before CIA

In a further C57BL/6 model of CIA, Ohnishi et al. (2005) found significantly reduced arthritis incidence and severity in Jα281 and CD1d knockout mice. Serum anti-CII autoantibody levels were also significantly reduced. Splenocyte proliferation assays to CII at day 9 post-primary immunisation however revealed no significant difference and neither

/- or invariant Jα281-

/-

knockout mice deficient in

potentially misleading (Eberl et al., 1999; Matsuda et al., 2000).

conflicting data arising from experimental animal studies.

induction however did not lead to disease amelioration.

**3.4 Animal models of rheumatoid arthritis** 

cells, particularly with the help of CD1d-

**3.4.1 Collagen-induced arthritis** 

2008).

**3.4.1.1 C57BL/6 mice** 

#### **3.2.3 Clonal heterogeneity**

proposition.

Linsen et al. (2005) also examined clonal heterogeneity by TCR CDR3 region fragment length analysis using primers for Vα24 and the TCR-α constant region on PBMC from 5 healthy controls and 7 paired PB-SF or PB-ST samples from RA patients. In PB, whilst healthy controls exhibited a polyclonal peak profile corresponding to the invariant NKT TCR α chain at 350 base pairs, RA patients exhibited a more restricted monoclonal (1 peak) or oligoclonal (2-4 peaks) pattern which included the invariant TCR-α chain in all patients. In SF or ST, Vα24 TCR usage was more variably skewed or polyclonal although all samples peaked corresponding to the invariant TCR-α chain thus confirming iNKT cells are present in SF and ST.

#### **3.3 Why are iNKT cells defective in RA?**

The above studies suggest that cross-subset iNKT cell frequency is reduced in RA as compared to healthy controls in peripheral blood, with conflicting reports on the synovial fluid compartment. This reduction is not specific for RA and at best would appear to correlate weakly with disease activity or systemic inflammation. Notably, iNKT cell frequency deficiency is reversible as shown by the response to treatment with methotrexate or rituximab. This is associated with a functional defect in a majority of RA patients, as shown by impaired proliferative and altered cytokine responses to α-GalCer.

So why are iNKT cells reduced in frequency and defective in peripheral blood of RA patients? Peripheral blood iNKT cell homeostasis depends on both thymic output, cell turnover and migration into extra-vascular compartments. It has previously been shown that recent thymic emigrants of conventional T cells, identified by the presence of T-cell receptor excision circles (TRECs), are reduced in number compared to age-matched controls (Koetz et al., 2000; Ponchel et al., 2002). Whether similar thymic dysregulation applies to iNKT cells remains yet to be investigated. Whether the survival of iNKT cells in the periphery is abnormally shortened in RA patients also remains undetermined, although it seems unlikely that the reduced frequency is due to a selective loss of a limited number of iNKT clones as shown by the polyclonal Vϐ11 profile of expanded peripheral RA iNKT cells. In non-responders, impaired iNKT cell response to α-GalCer and potentially to self-lipid ligands could be a sign of an intrinsic defect that might lead to reduced physiological expansion or a shortened cellular lifespan, but this phenomenon was restricted to the PB compartment only. Abnormal CD1d-mediated ligand presentation by APCs could similarly also impact on iNKT cell homeostasis but experimental data do not support a major defect in APC function. In fact, CD1d expression on PBMC from RA patients is similar to that of healthy controls (Kojo et al., 2003). Intriguingly, a soluble form of CD1d with capacity to bind α-GalCer and stimulate iNKT cells is significantly reduced in RA as compared to healthy controls, and correlates with Vα24+Vϐ11+ NKT cell frequency (Segawa et al., 2009). It has been suggested by Kojo et al. (2001) that low iNKT cell number and functional defect could be due to chronic activation and overstimulation as has been shown for anti-CD3ε or IL-12 stimulated NKT cells (Eberl & MacDonald, 1998). In this respect, it would be interesting to analyse markers of iNKT cell activation to support or refute this theory. In the same vein, Linsen et al. (2005) proposed that the measured deficiency in iNKT cell numbers is in fact artefactual, stemming from down-regulation of the TCR as a result of chronic activation (Wilson et al., 2003). Further studies are also required to examine this latter Finally, migration of iNKT cells into secondary lymphoid, liver or joint compartments might account for some of the apparent reduction in iNKT cell numbers in RA. Selective migration into joint synovial tissue or synovial fluid however is not supported by analysis of cell frequency and clonality in these compartments, but we cannot exclude migration into secondary lymphoid organs or liver as a possible factor. As most iNKT cells are found in the spleen or liver tissues, with relatively significantly fewer iNKT cells in peripheral blood, assessing the iNKT cell population size from peripheral blood frequency alone is therefore potentially misleading (Eberl et al., 1999; Matsuda et al., 2000).

#### **3.4 Animal models of rheumatoid arthritis**

26 Rheumatoid Arthritis – Etiology, Consequences and Co-Morbidities

Linsen et al. (2005) also examined clonal heterogeneity by TCR CDR3 region fragment length analysis using primers for Vα24 and the TCR-α constant region on PBMC from 5 healthy controls and 7 paired PB-SF or PB-ST samples from RA patients. In PB, whilst healthy controls exhibited a polyclonal peak profile corresponding to the invariant NKT TCR α chain at 350 base pairs, RA patients exhibited a more restricted monoclonal (1 peak) or oligoclonal (2-4 peaks) pattern which included the invariant TCR-α chain in all patients. In SF or ST, Vα24 TCR usage was more variably skewed or polyclonal although all samples peaked corresponding to the invariant TCR-α chain thus confirming iNKT cells are present

The above studies suggest that cross-subset iNKT cell frequency is reduced in RA as compared to healthy controls in peripheral blood, with conflicting reports on the synovial fluid compartment. This reduction is not specific for RA and at best would appear to correlate weakly with disease activity or systemic inflammation. Notably, iNKT cell frequency deficiency is reversible as shown by the response to treatment with methotrexate or rituximab. This is associated with a functional defect in a majority of RA patients, as

So why are iNKT cells reduced in frequency and defective in peripheral blood of RA patients? Peripheral blood iNKT cell homeostasis depends on both thymic output, cell turnover and migration into extra-vascular compartments. It has previously been shown that recent thymic emigrants of conventional T cells, identified by the presence of T-cell receptor excision circles (TRECs), are reduced in number compared to age-matched controls (Koetz et al., 2000; Ponchel et al., 2002). Whether similar thymic dysregulation applies to iNKT cells remains yet to be investigated. Whether the survival of iNKT cells in the periphery is abnormally shortened in RA patients also remains undetermined, although it seems unlikely that the reduced frequency is due to a selective loss of a limited number of iNKT clones as shown by the polyclonal Vϐ11 profile of expanded peripheral RA iNKT cells. In non-responders, impaired iNKT cell response to α-GalCer and potentially to self-lipid ligands could be a sign of an intrinsic defect that might lead to reduced physiological expansion or a shortened cellular lifespan, but this phenomenon was restricted to the PB compartment only. Abnormal CD1d-mediated ligand presentation by APCs could similarly also impact on iNKT cell homeostasis but experimental data do not support a major defect in APC function. In fact, CD1d expression on PBMC from RA patients is similar to that of healthy controls (Kojo et al., 2003). Intriguingly, a soluble form of CD1d with capacity to bind α-GalCer and stimulate iNKT cells is significantly reduced in RA as compared to healthy controls, and correlates with Vα24+Vϐ11+ NKT cell frequency (Segawa et al., 2009). It has been suggested by Kojo et al. (2001) that low iNKT cell number and functional defect could be due to chronic activation and overstimulation as has been shown for anti-CD3ε or IL-12 stimulated NKT cells (Eberl & MacDonald, 1998). In this respect, it would be interesting to analyse markers of iNKT cell activation to support or refute this theory. In the same vein, Linsen et al. (2005) proposed that the measured deficiency in iNKT cell numbers is in fact artefactual, stemming from down-regulation of the TCR as a result of chronic activation (Wilson et al., 2003). Further studies are also required to examine this latter

shown by impaired proliferative and altered cytokine responses to α-GalCer.

**3.2.3 Clonal heterogeneity** 

**3.3 Why are iNKT cells defective in RA?** 

in SF and ST.

proposition.

Given the distribution of iNKT cells to organs which are not easily amenable to investigation in human subjects, animal models of RA-like inflammatory arthritis have provided invaluable insight into the possible pathogenic or protective roles played by iNKT cells, particularly with the help of CD1d- / or invariant Jα281- / knockout mice deficient in iNKT cells. Furthermore, these models have given investigators an opportunity to explore interventions to either harness or subdue iNKT cell functions for therapeutic benefit. In this section, we review the findings and attempt to make sense of the occasionally puzzling and conflicting data arising from experimental animal studies.

### **3.4.1 Collagen-induced arthritis**

Collagen-induced arthritis (CIA) in mice was first demonstrated in 1981 by Wooley et al. as a promising animal model of inflammatory arthritis. The parenteral administration of heterologous chicken or bovine-derived type II collagen (CII) in complete Freund's adjuvant (CFA) containing heat-killed *Mycobacterium tuberculosis*, followed by a booster 21 days later to genetically susceptible mice results in a persistent inflammatory arthritis sharing many of the features of RA, including mononuclear synovial infiltrate, presence of rheumatoid factor and pannus formation, leading to cartilage destruction and bone erosion. CD4+ T cells are thought to be the primary mediators of disease induction characterised by early Th1 polarisation, whilst complement-fixing anti-CII autoantibody are responsible for the chronic inflammation during the effector phase of the immune response (Luross & Williams, 2001). CIA has been extensively characterised and has proved useful not only in furthering our understanding of basic pathophysiological mechanisms involved in inflammatory arthritis, but also in testing the therapeutic efficacy of potential new treatments for RA (Hegen et al., 2008).

#### **3.4.1.1 C57BL/6 mice**

Unlike the susceptible DBA/1 mice normally used in collagen-induced arthritis models, C57BL/6 mice NKT cells express the NK1.1 marker but are also susceptible to CIA with a 70% arthritis incidence. Prior to the widespread availability of more specific detection reagents, Wang et al. (2003) first noted that C57BL/6 mice with higher clinical arthritis scores had lower NK1.1+CD3+ T cell spleen and LN frequency but greater synovial membrane infiltration in more severely affected joints. NK1.1+ cell depletion before CIA induction however did not lead to disease amelioration.

In a further C57BL/6 model of CIA, Ohnishi et al. (2005) found significantly reduced arthritis incidence and severity in Jα281 and CD1d knockout mice. Serum anti-CII autoantibody levels were also significantly reduced. Splenocyte proliferation assays to CII at day 9 post-primary immunisation however revealed no significant difference and neither

Invariant Natural Killer T Cells in Rheumatoid Arthritis and Other Inflammatory Arthritides 29

The DBA/1 mouse model of CIA is more susceptible to CIA than C57BL/6 mice despite similar CD1d/α-GalCer-dimer+ NKT cell frequency and in vivo or in vitro function. In a

reduced incidence and severity of CIA, IgG2a and IgG1 CII-specific antibody levels, CIIstimulated production of IFN-γ, IL-17, IL-1ϐ and IL-6, and increased production of IL-10 by

producing IFN-γ were maintained throughout all disease stages whilst IL-17 producing iNKT cells steadily increased in frequency and number until the late stages of disease (Jung

In a further DBA/1 model of CIA, Miellot-Gafsou et al. (2010) found that hepatic iNKT cells released IFN-γ, IL-4 and IL-17A in response to intra-peritoneal (i.p.) α-GalCer 2hr before euthanasia at day 6, i.e. early during the course of CIA. This was associated with increased expression of CD69 on CD1d/α-GalCer-tetramer+ hepatic iNKT cells without any difference in the proportion of iNKT cells as compared to non-immunized mice. In keeping with an early role in disease development, anti-CD1d administered early (days 0, 3 and 6 postinduction) but not late (days 27-39) delayed onset, reduced disease incidence and ameliorated clinical and histological severity. No difference in FoxP3+ Treg frequency in spleen and lymph nodes or their suppressor function was noted. Splenic dendritic and macrophage APCs however showed reduced expression of CD40, CD80 and CD86 co-

In addition, Jung et al. (2010) have demonstrated a more subtle late regulatory role for NKT cells in tolerogenic DC (Tol-DC) mediated suppression of CIA. Thus TGF-ϐ induced, peritoneal exudate cell (PEC)-derived Tol-DC from CD1d+/- but not CD1d-/- mice could suppress the incidence, onset and severity of CIA when administered on day 28. This was associated with suppressed serum and joint tissue IFN-γ and IL-17 cytokine and mRNA production, respectively. Anti-CII specific IgG2a was reduced whilst IgG1 was higher in

but not CD1d-/- Tol-DC produced lower levels of IFN-γ and IL-17, and higher levels of IL-4

Although the initating event and processes involved in RA and animal models of autoimmune arthritis may differ, the final inflammatory pathways leading to joint damage are more likely to be common to both (Nandakumar & Holmdahl 2006). Antibody-mediated models of autoimmune arthritis give us a unique opportunity to study these terminal events independently of the initation processes involved, and thereby to evaluate more clearly the

The K/BxN mouse model of spontaneous autoimmune arthritis is a cross between the KRN TCR C57BL/6 transgenic mouse that is specific for an I-Ak restricted peptide of bovine ribonuclease (RNase), and the non-obese diabetic (NOD) mouse (Kouskoff et al., 1996). The K/BxN mouse T cells recognise an I-Ag7-restricted peptide from glucose-6-phosphate isomerase (G6PI) and B cells produce G6PI-specific antibodies (Matsumoto et al., 1999). Serum transfer alone into C57BL/6 mice can also mediate disease after just several days (Ji

compared to CD1d-/- Tol-DC. Similarly, CII-stimulated splenocytes from CD1d+/-

/-

knockout mice display a

mice. In wild-type mice, iNKT cells

DBA/1 model of CIA, Jung et al. (2009) showed that CD1d-

splenocytes on day 35, as compared to CD1d+/-

stimulatory molecules (Miellot-Gafsou et al., 2010).

role of iNKT cells during the terminal effector stage of disease.

**3.4.1.2 DBA1/J mice** 

et al., 2009).

CD1d+/-

and IL-10 .

**3.4.2 Antibody mediated arthritis** 

**3.4.2.1 K/BxN serum transfer model** 

did IL-4 and IFN-γ cytokine responses differ between Jα281 knockout and wild-type C57BL/6 mice. At 5 days after booster immunisation on day 21, and therefore during the disease development phase, there were fewer activated CD69+ T and B cells in Jα281 knockout mice. This was associated with lower splenocyte mRNA for IL-4 and IL-1ϐ, and higher IFN-γ expression.

Using more specific detection reagents, Chiba et al. (2005) analysed the frequency of Vα24+ iNKT cells stained with α-GalCer-loaded CD1d dimers in C57BL/6 murine models of CIA. Unlike human and earlier murine studies using less specific detection reagents, they found increased liver and peripheral blood, but not lymph node or spleen iNKT cell numbers which peaked with clinical disease severity in CIA compared with control mice. Anti-CD1d blocking antibody administered bi-weekly from day 21 resulted in disease amelioration but not susceptibility. Furthermore, Jα281 knockout mice showed an increased IgG1/IgG2a ratio of anti-CII antibodies in keeping with a Th2 deviation in iNKT cell deficient mice. Accordingly, draining lymph node (DLN) lymphoid cells stimulated with CII 10 days postsecondary immunisation produced much more IL-10 in Jα281 knockout mice than wild-type C57BL/6 mice, but less IL-2 and IFN-γ although levels of these two cytokines were already low in wild-type mice.

IL-17 produced by Th17 lymphocytes has been shown to mediate an IL-1-independent role in synovial inflammation and joint destruction in CIA (Lubberts et al., 2001). Studies of IL17- /- mice have shown a role in T cell priming, collagen-specific IgG2a production and a markedly suppressed CIA severity in the absence of this cytokine (Nakae et al., 2003). TGF-ϐ and IL-6 promote Th17 cell development (Bettelli et al., 2006; Mangan et al., 2006; Veldhoen et al., 2006) whilst IL-23 has been shown to be essential to Th17 cell maintenance (Aggarwal et al., 2003; Langrish et al., 2005). Thus IL-23- /- knockout mice lack Th17 cells, and similarly fail to develop clinical or histological disease in CIA (Murphy et al., 2003). Neutralisation with anti-IL-17 after the onset of arthritis results in suppression of disease in keeping with a role in both induction and effector phases of CIA (Lubberts et al., 2004). Interestingly, IFN-γ suppresses IL-17 production by CII-specific T cells and may be relevant to the suppressive role of IFN-γ during the effector stage of CIA (Chu et al., 2007). This was subsequently demonstrated in experiments showing that the neutralisation of IFN-γ after day 10 postprimary immunisation results in IL-17 dependent exacerbation of CIA (Sarkar et al., 2009). Yoshiga et al. (2008) confirmed the pathogenic role of iNKT cells in C57BL/6 CIA by noting the reduced disease incidence and severity in Jα281 knockout mice compared to wild-type mice. DLN cells from Jα281- / mice stimulated with CII at day 11 post-primary immunisation produced similar amounts of IFN-γ and minimal IL-4, with increased IL-10 (not significantly) and significantly less IL-17. This was associated with a marked reduction in the percentage of IL-17 producing CD4+ cells. Administration of α-GalCer in C57BL/6 but not Jα281-/- mice resulted in IL-17 production by splenocytes with detectable IL-17+ iNKT cells distinct from the IFN-γ+ and IL-4+ population, as well as increased IL-17 production by non-iNKT cells as compared to Jα281- / mice. Splenic naïve and stimulated iNKT cells were found to express IL-23R and RORγt mRNA similarly to Th17 cells, but only stimulated cells expressed IL-17. NK1.1+ and NK1.1 iNKT cells splenocytes were incubated with mitomycin-C-treated CD11c+ DCs with either IL-23 or α-GalCer. Results showed that IL-17 is only produced by the NK1.1- subset in response to α-GalCer and more weakly after IL-23 stimulation. Furthermore, α-GalCer-induced IL-17 could not be abrogated with IL-23 and IL-23 was not detectable in culture supernatant, suggesting that NK1.1- iNKT cells can produce IL-17 is both IL-23-dependent and independent (Yoshiga et al., 2008).

### **3.4.1.2 DBA1/J mice**

28 Rheumatoid Arthritis – Etiology, Consequences and Co-Morbidities

did IL-4 and IFN-γ cytokine responses differ between Jα281 knockout and wild-type C57BL/6 mice. At 5 days after booster immunisation on day 21, and therefore during the disease development phase, there were fewer activated CD69+ T and B cells in Jα281 knockout mice. This was associated with lower splenocyte mRNA for IL-4 and IL-1ϐ, and

Using more specific detection reagents, Chiba et al. (2005) analysed the frequency of Vα24+ iNKT cells stained with α-GalCer-loaded CD1d dimers in C57BL/6 murine models of CIA. Unlike human and earlier murine studies using less specific detection reagents, they found increased liver and peripheral blood, but not lymph node or spleen iNKT cell numbers which peaked with clinical disease severity in CIA compared with control mice. Anti-CD1d blocking antibody administered bi-weekly from day 21 resulted in disease amelioration but not susceptibility. Furthermore, Jα281 knockout mice showed an increased IgG1/IgG2a ratio of anti-CII antibodies in keeping with a Th2 deviation in iNKT cell deficient mice. Accordingly, draining lymph node (DLN) lymphoid cells stimulated with CII 10 days postsecondary immunisation produced much more IL-10 in Jα281 knockout mice than wild-type C57BL/6 mice, but less IL-2 and IFN-γ although levels of these two cytokines were already

IL-17 produced by Th17 lymphocytes has been shown to mediate an IL-1-independent role in synovial inflammation and joint destruction in CIA (Lubberts et al., 2001). Studies of IL17- /- mice have shown a role in T cell priming, collagen-specific IgG2a production and a markedly suppressed CIA severity in the absence of this cytokine (Nakae et al., 2003). TGF-ϐ and IL-6 promote Th17 cell development (Bettelli et al., 2006; Mangan et al., 2006; Veldhoen et al., 2006) whilst IL-23 has been shown to be essential to Th17 cell maintenance (Aggarwal

fail to develop clinical or histological disease in CIA (Murphy et al., 2003). Neutralisation with anti-IL-17 after the onset of arthritis results in suppression of disease in keeping with a role in both induction and effector phases of CIA (Lubberts et al., 2004). Interestingly, IFN-γ suppresses IL-17 production by CII-specific T cells and may be relevant to the suppressive role of IFN-γ during the effector stage of CIA (Chu et al., 2007). This was subsequently demonstrated in experiments showing that the neutralisation of IFN-γ after day 10 postprimary immunisation results in IL-17 dependent exacerbation of CIA (Sarkar et al., 2009). Yoshiga et al. (2008) confirmed the pathogenic role of iNKT cells in C57BL/6 CIA by noting the reduced disease incidence and severity in Jα281 knockout mice compared to wild-type

immunisation produced similar amounts of IFN-γ and minimal IL-4, with increased IL-10 (not significantly) and significantly less IL-17. This was associated with a marked reduction in the percentage of IL-17 producing CD4+ cells. Administration of α-GalCer in C57BL/6 but not Jα281-/- mice resulted in IL-17 production by splenocytes with detectable IL-17+ iNKT cells distinct from the IFN-γ+ and IL-4+ population, as well as increased IL-17 production by

found to express IL-23R and RORγt mRNA similarly to Th17 cells, but only stimulated cells

C-treated CD11c+ DCs with either IL-23 or α-GalCer. Results showed that IL-17 is only produced by the NK1.1- subset in response to α-GalCer and more weakly after IL-23 stimulation. Furthermore, α-GalCer-induced IL-17 could not be abrogated with IL-23 and IL-23 was not detectable in culture supernatant, suggesting that NK1.1- iNKT cells can

/- knockout mice lack Th17 cells, and similarly

mice stimulated with CII at day 11 post-primary

mice. Splenic naïve and stimulated iNKT cells were

iNKT cells splenocytes were incubated with mitomycin-

higher IFN-γ expression.

low in wild-type mice.

et al., 2003; Langrish et al., 2005). Thus IL-23-

/-

/-

produce IL-17 is both IL-23-dependent and independent (Yoshiga et al., 2008).

mice. DLN cells from Jα281-

non-iNKT cells as compared to Jα281-

expressed IL-17. NK1.1+ and NK1.1-

The DBA/1 mouse model of CIA is more susceptible to CIA than C57BL/6 mice despite similar CD1d/α-GalCer-dimer+ NKT cell frequency and in vivo or in vitro function. In a DBA/1 model of CIA, Jung et al. (2009) showed that CD1d- / knockout mice display a reduced incidence and severity of CIA, IgG2a and IgG1 CII-specific antibody levels, CIIstimulated production of IFN-γ, IL-17, IL-1ϐ and IL-6, and increased production of IL-10 by splenocytes on day 35, as compared to CD1d+/ mice. In wild-type mice, iNKT cells producing IFN-γ were maintained throughout all disease stages whilst IL-17 producing iNKT cells steadily increased in frequency and number until the late stages of disease (Jung et al., 2009).

In a further DBA/1 model of CIA, Miellot-Gafsou et al. (2010) found that hepatic iNKT cells released IFN-γ, IL-4 and IL-17A in response to intra-peritoneal (i.p.) α-GalCer 2hr before euthanasia at day 6, i.e. early during the course of CIA. This was associated with increased expression of CD69 on CD1d/α-GalCer-tetramer+ hepatic iNKT cells without any difference in the proportion of iNKT cells as compared to non-immunized mice. In keeping with an early role in disease development, anti-CD1d administered early (days 0, 3 and 6 postinduction) but not late (days 27-39) delayed onset, reduced disease incidence and ameliorated clinical and histological severity. No difference in FoxP3+ Treg frequency in spleen and lymph nodes or their suppressor function was noted. Splenic dendritic and macrophage APCs however showed reduced expression of CD40, CD80 and CD86 costimulatory molecules (Miellot-Gafsou et al., 2010).

In addition, Jung et al. (2010) have demonstrated a more subtle late regulatory role for NKT cells in tolerogenic DC (Tol-DC) mediated suppression of CIA. Thus TGF-ϐ induced, peritoneal exudate cell (PEC)-derived Tol-DC from CD1d+/- but not CD1d-/- mice could suppress the incidence, onset and severity of CIA when administered on day 28. This was associated with suppressed serum and joint tissue IFN-γ and IL-17 cytokine and mRNA production, respectively. Anti-CII specific IgG2a was reduced whilst IgG1 was higher in CD1d+/ compared to CD1d- /- Tol-DC. Similarly, CII-stimulated splenocytes from CD1d+/ but not CD1d-/- Tol-DC produced lower levels of IFN-γ and IL-17, and higher levels of IL-4 and IL-10 .

### **3.4.2 Antibody mediated arthritis**

Although the initating event and processes involved in RA and animal models of autoimmune arthritis may differ, the final inflammatory pathways leading to joint damage are more likely to be common to both (Nandakumar & Holmdahl 2006). Antibody-mediated models of autoimmune arthritis give us a unique opportunity to study these terminal events independently of the initation processes involved, and thereby to evaluate more clearly the role of iNKT cells during the terminal effector stage of disease.

#### **3.4.2.1 K/BxN serum transfer model**

The K/BxN mouse model of spontaneous autoimmune arthritis is a cross between the KRN TCR C57BL/6 transgenic mouse that is specific for an I-Ak restricted peptide of bovine ribonuclease (RNase), and the non-obese diabetic (NOD) mouse (Kouskoff et al., 1996). The K/BxN mouse T cells recognise an I-Ag7-restricted peptide from glucose-6-phosphate isomerase (G6PI) and B cells produce G6PI-specific antibodies (Matsumoto et al., 1999). Serum transfer alone into C57BL/6 mice can also mediate disease after just several days (Ji

Invariant Natural Killer T Cells in Rheumatoid Arthritis and Other Inflammatory Arthritides 31

indicating a mixed invariant and non-invariant NKT cell population. Furthermore, TCR stimulation of liver mononuclear cells (LMNCs) by α-GalCer/CD1d upregulated FcγRIII expression. Aggregated IgG but not soluble IgG, could activate NKT cells from B6 mice but not T or NK cells or NKT cells from Fcγ-/- mice, and upregulate activation markers CD25 and CD69. NKT cell FcγRIII engagement by aggregated IgG could upregulate expression of T-bet and GATA-3, and induce production of IL-4, IL-10, IL-13 and IFN-γ independently of simultaneous TCR stimulation. Simultaneous TCR and FcγRIII engagement resulted in cytokine output greater than either signal alone. In mice treated with K/BxN serum, joint

NKT cells from B6 mice showed similar disease severity to wild-type mice, but administration of NKT from FcγR-/- B6 mice showed minimal joint swelling and only mild inflammatory infiltrate. Joint tissue Vα14Jα281 TCR mRNA was similar in CD1d-

administered B6 NKT cells and CD1d-/- administered FcγR-/- B6 NKT cells. Furthermore, there was no difference in hepatic NKT, NK, CD4 and CD8 T cell numbers in Fcγ-/- B6 mice and α-GalCer/CD1d complex-stimulated LMNC cells from FcγR-/- mice produced IL-4, IL-10, IL-13 and IFN-γ similarly to wild-type B6 mice. These findings suggested that FcγR engagement rather than TCR engagement mediated NKT activation in the serum transfer model. RT-PCR analysis confirmed elevated joint tissue but not liver levels of TGFϐ-1 and reduced levels of IL-4 and IFN-γ in CD1d-/- mice administered FcγR-/- NKT cells as compared to B6 NKT cells, indicating that FcγRIII engagement by joint tissue –deposited IgG enhances IL-4 and IFN-γ production and results in suppressed TFG-ϐ1 (Kim et al.,

IL-12 has previously been shown both to attenuate and to exacerbate CIA in C57BL/6 (Murphy et al., 2003) and DBA/1 mice (Butler et al., 1999; Malfait et al., 1998; Matthys et al., 1998), respectively. To elucidate the role of IL-12 in the terminal effector stages of arthritis,

/- mice. Knockout mice had slower onset and less severe disease associated with milder inflammatory synovial infiltrate as compared to B6 mice. IL-12 mRNA was detected in joint tissues in B6 mice and recombinant (rm) IL-12 could restore arthritis severity in knockout mice. Serum transfer resulted in infiltration of large numbers of CD11b+ and Gr1+ granulocytes and smaller numbers of B, T, NK and CD11c+ cells. Using IL-12p40 cytokine reporter mice, the investigators showed that IL-12 is produced most prominently by CD11c+ cells, but also by CD11b+ cells and Gr1+ granulocytes. Joint tissue TGF-ϐ transcript was higher and IFN-γ, IL-6 and IL-4 were lower in knockout mice. IL-17 and IL-23 were undetectable in wild-type and knockout mice, and joint inflammation and cytokine production were similar in B6 and IL-17-/- mice. Recombinant IL-12 restored cytokine levels to wild-type pattern. Both rmIFN-γ and anti-TGF-ϐ restored arthritis severity in IL-12p35-/ mice. In joint tissue only NK1.1+TCR-ϐ- NK and NK1.1+TCR-ϐ+ NKT cells were found to express surface IL-12Rϐ2. Adoptive transfer of splenocytes from B6 and Gr-1+ granulocyte-

arthritis severity and maintained higher levels of joint tissue TGF-ϐ transcript. The investigators therefore suggested that IL-12p35 produced by CD11b+, CD11c+ and Gr-1+ cells promote antibody-induced inflammation by engaging IL-12 Rϐ2 expressed on iNKT

Park et al. (2010) studied the K/BxN mice serum transfer model in IL-12p35-

and IL-4, whereas transfer of splenocytes from iNKT-deficient Jα281-

swelling was detected at 4-5 days and maximal at 8-9 days. CD1d-/-

cells. Of these, 62% stained with α-GalCer/CD1d tetramer,

mice administered

/-

mice restored arthritis severity and production of IFN-γ

/-

had no effect on

and IL-12Rϐ2-

/-

mainly on CD4+ or CD4-

2006).

depleted B6 mice into IL-12Rϐ2-/-

cells in joint tissues (Park et al., 2010).

et al. 2001). Complement, neutrophils and mast cells play an essential role, and it is also apparent that Fcγ receptors (FcγRs) and IL-1 are also required in mediating joint inflammation and destruction (Ditzel, 2004).

In an earlier study of the K/BxN serum transfer model of inflammatory arthritis, Chiba et al. (2005) found an increased percentage of Vα24+α-GalCer/CD1d-dimer+ iNKT cells in liver, peripheral blood, spleen and lymph nodes as compared to control mice given BxN serum. CD1d- /- and Jα281-/- knockout mice deficient in iNKT cells exhibited milder disease and reduced histological severity but not susceptibility, supporting a role for iNKT cells during the inflammatory effector phase of arthritis.

Subsequently, Kim et al. (2006) showed using in the K/BxN serum transfer model that CD1d- /- and Jα281-/- knockout mice have reduced clinical disease severity and neutrophil inflammatory infiltration, while transfer of liver NK1.1+TCR-ϐ+ NKT cells from normal B6 mice into CD1d-/- knockout mice restored wild-type disease severity. Furthermore, splenocytes from Vα14Jα281 TCR transgenic (Tg) RAG- /- mice but not Jα281- / knockout mice restored disease severity in CD1d- /- mice, confirming the specific role of iNKT cells and in addition, the injection of α-GalCer as an in vivo activator of iNKT cells resulted in exacerbation of disease in B6 but not CD1d- / mice. These investigators went on to dissect the mechanisms by which iNKT cells play a pro-inflammatory role in the KxB/N mouse model. Joint tissue Vα24Jα281 TCR mRNA measured by RT-PCR was observed at days 3, 5 and 7 in wild-type B6 (C57BL/6) mice, but not on day 0 or in CD1d- /- knockout mice, suggesting *de novo* iNKT cell infiltration during the inflammatory response. Joint tissue mRNA level of TGF-ϐ1 was increased but IL-4 and IFN-γ were reduced in CD1d-/- mice compared to B6 mice, although similar levels were noted in splenocytes. Adoptive transfer of NKT cells reduced TGF-ϐ1 and restored IL-4 and IFN-γ mRNA in joint tissue without changing splenic transcript levels. Postulating a role for TGF-ϐ1 in resistance to joint inflammation, anti-TGF-ϐ mAb was administered i.p. three times a week before and after serum transfer in CD1d- /- and wild-type mice. Anti-TGF-ϐ increased disease severity to wild-type levels in CD1d- /- but had no effect in wild-type mice. Administration of recombinant TGF-ϐ1 to wild-type mice in turn reduced disease severity, suggesting that iNKT cells mediate their pathogenic role in a TGF-ϐ1-dependent fashion. But how do iNKT cells regulate TGF-ϐ1 production? To answer this, synovial cells from B6 mice were stimulated with concanavalin A (ConA) to induce TGF-ϐ1 production. This was suppressed by α-GalCer or anti-CD1d mAb in keeping with iNKT cell-mediated regulation. Similarly, injection of α-GalCer into treated B6 mice resulted in suppressed TGF-ϐ1 production in joint tissues, indicating the capacity of NKT cells to specifically suppress TGF-ϐ1 production. Blocking IL-4 and IFN-γ could restore TGF-ϐ1 production, while IL-4- / or IFN-γ- /- mice NKT cells transferred into CD1d-/- serum-treated mice resulted in minimal joint swelling and TGF-ϐ1 transcriptional expression remained elevated. In contrast, transfer of NKT cells from B6 mice restored wild-type disease severity and TGF-ϐ1 suppression. Finally, anti-IL-4 or anti-IFN-γ resulted in resistance to joint inflammation and enhanced TGF-ϐ1 production in Vα14Jα281 TCR Tg RAG-/ mice (Kim, 2005).

Speculating that the observed NKT-mediated aggravation K/BxN serum transfer model of autoimmune arthritis may not be due to TCR-mediated recognition of CD1d-restricted selflipid but instead could be due to Fcγ receptor engagement by immune complexes providing activating signals to NKT cells independently of TCR, Kim et al. (2006) showed that hepatic, splenic and thymic NK1.1+TCR-ϐ+ NKT cells in B6 mice selectively expressed FcγRIII,

et al. 2001). Complement, neutrophils and mast cells play an essential role, and it is also apparent that Fcγ receptors (FcγRs) and IL-1 are also required in mediating joint

In an earlier study of the K/BxN serum transfer model of inflammatory arthritis, Chiba et al. (2005) found an increased percentage of Vα24+α-GalCer/CD1d-dimer+ iNKT cells in liver, peripheral blood, spleen and lymph nodes as compared to control mice given BxN serum.

Subsequently, Kim et al. (2006) showed using in the K/BxN serum transfer model that

mice restored disease severity in CD1d-/- mice, confirming the specific role of iNKT cells and in addition, the injection of α-GalCer as an in vivo activator of iNKT cells resulted in exacerbation of disease in B6 but not CD1d-/- mice. These investigators went on to dissect the mechanisms by which iNKT cells play a pro-inflammatory role in the KxB/N mouse model. Joint tissue Vα24Jα281 TCR mRNA measured by RT-PCR was observed at days 3, 5 and 7 in wild-type B6 (C57BL/6) mice, but not on day 0 or in CD1d-/- knockout mice, suggesting *de novo* iNKT cell infiltration during the inflammatory response. Joint tissue mRNA level of TGF-ϐ1 was increased but IL-4 and IFN-γ were reduced in CD1d-/- mice compared to B6 mice, although similar levels were noted in splenocytes. Adoptive transfer of NKT cells reduced TGF-ϐ1 and restored IL-4 and IFN-γ mRNA in joint tissue without changing splenic transcript levels. Postulating a role for TGF-ϐ1 in resistance to joint inflammation, anti-TGF-ϐ mAb was administered i.p. three times a week before and after

recombinant TGF-ϐ1 to wild-type mice in turn reduced disease severity, suggesting that iNKT cells mediate their pathogenic role in a TGF-ϐ1-dependent fashion. But how do iNKT cells regulate TGF-ϐ1 production? To answer this, synovial cells from B6 mice were stimulated with concanavalin A (ConA) to induce TGF-ϐ1 production. This was suppressed by α-GalCer or anti-CD1d mAb in keeping with iNKT cell-mediated regulation. Similarly, injection of α-GalCer into treated B6 mice resulted in suppressed TGF-ϐ1 production in joint tissues, indicating the capacity of NKT cells to specifically suppress TGF-ϐ1 production.

NKT cells transferred into CD1d-/- serum-treated mice resulted in minimal joint swelling and TGF-ϐ1 transcriptional expression remained elevated. In contrast, transfer of NKT cells from B6 mice restored wild-type disease severity and TGF-ϐ1 suppression. Finally, anti-IL-4 or anti-IFN-γ resulted in resistance to joint inflammation and enhanced TGF-ϐ1 production

Speculating that the observed NKT-mediated aggravation K/BxN serum transfer model of autoimmune arthritis may not be due to TCR-mediated recognition of CD1d-restricted selflipid but instead could be due to Fcγ receptor engagement by immune complexes providing activating signals to NKT cells independently of TCR, Kim et al. (2006) showed that hepatic, splenic and thymic NK1.1+TCR-ϐ+ NKT cells in B6 mice selectively expressed FcγRIII,

Blocking IL-4 and IFN-γ could restore TGF-ϐ1 production, while IL-4-/-

mice (Kim, 2005).

/-

/- and Jα281-/- knockout mice deficient in iNKT cells exhibited milder disease and reduced histological severity but not susceptibility, supporting a role for iNKT cells during

/- and Jα281-/- knockout mice have reduced clinical disease severity and neutrophil inflammatory infiltration, while transfer of liver NK1.1+TCR-ϐ+ NKT cells from normal B6 mice into CD1d-/- knockout mice restored wild-type disease severity. Furthermore,

/- mice but not Jα281-

/- and wild-type mice. Anti-TGF-ϐ increased disease severity to

/- but had no effect in wild-type mice. Administration of

/-

or IFN-γ-

/ mice

knockout

inflammation and destruction (Ditzel, 2004).

the inflammatory effector phase of arthritis.

splenocytes from Vα14Jα281 TCR transgenic (Tg) RAG-

CD1d-

CD1d-

serum transfer in CD1d-

wild-type levels in CD1d-

in Vα14Jα281 TCR Tg RAG-

mainly on CD4+ or CD4- cells. Of these, 62% stained with α-GalCer/CD1d tetramer, indicating a mixed invariant and non-invariant NKT cell population. Furthermore, TCR stimulation of liver mononuclear cells (LMNCs) by α-GalCer/CD1d upregulated FcγRIII expression. Aggregated IgG but not soluble IgG, could activate NKT cells from B6 mice but not T or NK cells or NKT cells from Fcγ- / mice, and upregulate activation markers CD25 and CD69. NKT cell FcγRIII engagement by aggregated IgG could upregulate expression of T-bet and GATA-3, and induce production of IL-4, IL-10, IL-13 and IFN-γ independently of simultaneous TCR stimulation. Simultaneous TCR and FcγRIII engagement resulted in cytokine output greater than either signal alone. In mice treated with K/BxN serum, joint swelling was detected at 4-5 days and maximal at 8-9 days. CD1d- / mice administered NKT cells from B6 mice showed similar disease severity to wild-type mice, but administration of NKT from FcγR-/- B6 mice showed minimal joint swelling and only mild inflammatory infiltrate. Joint tissue Vα14Jα281 TCR mRNA was similar in CD1d- / administered B6 NKT cells and CD1d-/- administered FcγR-/- B6 NKT cells. Furthermore, there was no difference in hepatic NKT, NK, CD4 and CD8 T cell numbers in Fcγ-/- B6 mice and α-GalCer/CD1d complex-stimulated LMNC cells from FcγR-/- mice produced IL-4, IL-10, IL-13 and IFN-γ similarly to wild-type B6 mice. These findings suggested that FcγR engagement rather than TCR engagement mediated NKT activation in the serum transfer model. RT-PCR analysis confirmed elevated joint tissue but not liver levels of TGFϐ-1 and reduced levels of IL-4 and IFN-γ in CD1d-/- mice administered FcγR-/- NKT cells as compared to B6 NKT cells, indicating that FcγRIII engagement by joint tissue –deposited IgG enhances IL-4 and IFN-γ production and results in suppressed TFG-ϐ1 (Kim et al., 2006).

IL-12 has previously been shown both to attenuate and to exacerbate CIA in C57BL/6 (Murphy et al., 2003) and DBA/1 mice (Butler et al., 1999; Malfait et al., 1998; Matthys et al., 1998), respectively. To elucidate the role of IL-12 in the terminal effector stages of arthritis, Park et al. (2010) studied the K/BxN mice serum transfer model in IL-12p35- / and IL-12Rϐ2- /- mice. Knockout mice had slower onset and less severe disease associated with milder inflammatory synovial infiltrate as compared to B6 mice. IL-12 mRNA was detected in joint tissues in B6 mice and recombinant (rm) IL-12 could restore arthritis severity in knockout mice. Serum transfer resulted in infiltration of large numbers of CD11b+ and Gr1+ granulocytes and smaller numbers of B, T, NK and CD11c+ cells. Using IL-12p40 cytokine reporter mice, the investigators showed that IL-12 is produced most prominently by CD11c+ cells, but also by CD11b+ cells and Gr1+ granulocytes. Joint tissue TGF-ϐ transcript was higher and IFN-γ, IL-6 and IL-4 were lower in knockout mice. IL-17 and IL-23 were undetectable in wild-type and knockout mice, and joint inflammation and cytokine production were similar in B6 and IL-17-/- mice. Recombinant IL-12 restored cytokine levels to wild-type pattern. Both rmIFN-γ and anti-TGF-ϐ restored arthritis severity in IL-12p35- / mice. In joint tissue only NK1.1+TCR-ϐ- NK and NK1.1+TCR-ϐ+ NKT cells were found to express surface IL-12Rϐ2. Adoptive transfer of splenocytes from B6 and Gr-1+ granulocytedepleted B6 mice into IL-12Rϐ2-/- mice restored arthritis severity and production of IFN-γ and IL-4, whereas transfer of splenocytes from iNKT-deficient Jα281- / had no effect on arthritis severity and maintained higher levels of joint tissue TGF-ϐ transcript. The investigators therefore suggested that IL-12p35 produced by CD11b+, CD11c+ and Gr-1+ cells promote antibody-induced inflammation by engaging IL-12 Rϐ2 expressed on iNKT cells in joint tissues (Park et al., 2010).

Invariant Natural Killer T Cells in Rheumatoid Arthritis and Other Inflammatory Arthritides 33

activated or the mechanism(s) whereby they skew the phenotypic immune response to CII. Given that iNKT cells are found in diseased joints, do they play any direct role in terminal

Models of antigen and antibody-mediated arthritis are useful in clearly dissecting the role of iNKT cells during the induction and effector stages of autoimmune arthritis and confirm that iNKT cells play a pathogenic role during the terminal effector phase of disease. The work of Kim et al. (2006) and Park et al. (2010) was a particularly elegant demonstration of how iNKT cells appear to be stimulated through their IL-12Rϐ2 and FcγRIII receptors, resulting in increased IL-4 and IFN-γ and suppressed TGF-ϐ production, and subsequent modulation of arthritis severity. The only caveat to their work is the use of relatively nonspecific markers which did not distinguish iNKT from other NKT cell subsets. It also still remains unclear which iNKT cell subsets are important and whether invariant TCR-selflipid-CD1d interaction plays any role in iNKT cell activation during the effector stage. Further work is required to define the source of seemingly critical IL-4, IFN-γ and TGF-ϐ, and ultimately, the extent to which these findings are applicable to rheumatoid arthritis in

Despite the demonstrated pathogenicity of iNKT cells in animal models of autoimmune arthritis, their frequency and phenotype may yet serve as useful biomarkers, and their immune manipulation may serve a beneficial therapeutic purpose as shown in the context of

It seems that peripheral iNKT cell frequency is reduced in a range of autoimmune diseases including diabetes, multiple sclerosis and SLE. This may indicate a response to systemic inflammation or a generalised association with autoimmunity. As such, iNKT cells could in theory be used to distinguishing RA from other forms of arthritis. Furthermore, additional detailed analysis of iNKT subsets and function may provide prognostic information to guide individual treatment. Finally, it is tempting to speculate whether iNKT cells could serve as markers of self-tolerance to signal the safe withdrawal of long term

Our own work in this area showed that peripheral iNKT cell frequency was reduced among patients with RA, osteoarthritis (OA) and other inflammatory non-RA groups compared to patients with non-inflammatory, non-OA joint pain and healthy controls. This indicates that in practice iNKT cell frequency alone would prove of limited diagnostic or disease monitoring value. Whilst iNKT cell counts appear to improve with methotrexate therapy, we found no correlation with clinical response and therefore the significance of this

OCH, a synthetic analogue of α-GalCer with a truncated sphingosine chain, has been shown to induce a Th2 bias in iNKT cytokine production and can efficiently inhibit EAE in C57BL/6 mice. Chiba et al. therefore studied the effects of intra-peritoneal α-GalCer and OCH administration, before and after induction of CIA in C57BL/6 mice. Unlike α-GalCer, OCH significantly reduced the clinical severity score of CIA from 13 to 4.6. When OCH was

joint inflammation and tissue destruction?

**3.5 Clinical relevance of iNKT cells in RA** 

infection, cancer immunity and other autoimmune diseases.

immunosuppression in patients achieving clinical remission.

observation remains unknown (Tudhope et al., 2010).

**3.5.2 Manipulating iNKT cells for clinical benefit** 

**3.5.1 iNKT cells as diagnostic and prognostic tools** 

humans.

#### **3.4.2.2 Other models of autoimmune arthritis**

Chiba et al. (2005) administered a mixture of four anti-CII mAb to C57BL/6 mice, followed 72h later by LPS. Jα281-/- and CD1d-/- knockout mice also showed reduced disease severity without any difference in susceptibility, in keeping with a role for iNKT cells during the effector as well as adaptive stages of CIA.

Antigen-induced arthritis (AIA) occurs when bovine serum albumin (BSA) is injected into the knee joint of B6 mice after priming with subcutaneous BSA injection, resulting in a week-long acute inflammatory arthritis (van den Berg et al., 2007). Teige et al. (2010) showed that CD1d-/- knockout mice experience a more severe AIA associated with a stronger splenocyte antigen-specific IFN-γ response without any difference in cell proliferation. Notably, NK1.1-depletion resulted in more severe arthritis.

## **3.4.3 Lessons learnt from animal models of autoimmune arthritis**

CIA models using either C57BL/6 or the more susceptible DBA/1 mouse strains have consistently shown that iNKT cell deficient animals experience a reduced incidence and/or severity of arthritis. This therefore suggests that in contrast to other models of autoimmune disease and despite the apparent reduction in frequency of peripheral iNKT cells in RA, iNKT cells play a pathogenic role in animal models of autoimmune arthritis.

The increased incidence is a clue for an early role for iNKT cells in disease initiation, and this is supported by the observation of DLN cytokine deviation by day 11 in C57BL/6 mice (Yoshiga et al., 2008) and a reduction in incidence and disease amelioration when anti-CD1d is administered early, but not late in DBA1/J mice (Miellot-Gafsou et al., 2010). Ohnishi et al. (2005) found however no evidence of an effect on splenocyte cytokine deviation until day 26 in C57BL/6 mice, but given that they used the same mouse strains and CIA induction protocol as Yoshiga et al. (2008), the conflicting results are likely to be due to site and timespecific differences between DLN and splenocyte populations.

There is also reasonable evidence that iNKT cells play a role in later, effector stages of CIA too. IL-17 producing iNKT cells have been noted to steadily increase in numbers until the very late stages of disease in DBA/1 mice (Jung et al., 2009) and anti-CD1d administered to C57BL/6 mice on day 21 results in disease amelioration (Chiba et al., 2005). In addition, Jung et al. demonstrated that CD1d+/ but not CD1d-/- Tol-DC could suppress CIA in DBA/1 mice when administered as late as day 28 (Jung et al., 2010).

So how do iNKT cells influence the immune pathogenesis of CIA? Experimental data suggest that early on during induction and continuing into the effector stage of disease, iNKT cells skew the immune response to CII by promoting a Th1 and/or Th17 phenotype. It seems likely that by altering the cytokine environment, iNKT cells also influence the corresponding observed shift in autoantibody isotype from IgG1 to complement-fixing IgG2a. Furthermore, iNKT cells enhance both T and B cell responses as evidenced by the expression of activation markers and levels of circulating anti-CII autoantibodies, no doubt mediated in part by increased APC co-stimulatory molecule expression.

Whilst providing remarkable insight into the immunological role of iNKT cells in autoimmunity, murine models of CIA have also raised new issues and left us with many unanswered questions. It is unclear which particular iNKT cell subset is responsible for exacerbating disease, whether the same subsets are pathogenic at different stages or even whether some subsets play a protective role as suggested by Jung et al.'s Tol-DC experimental model (Jung et al., 2010). Neither do we know how iNKT cells become activated or the mechanism(s) whereby they skew the phenotypic immune response to CII. Given that iNKT cells are found in diseased joints, do they play any direct role in terminal joint inflammation and tissue destruction?

Models of antigen and antibody-mediated arthritis are useful in clearly dissecting the role of iNKT cells during the induction and effector stages of autoimmune arthritis and confirm that iNKT cells play a pathogenic role during the terminal effector phase of disease. The work of Kim et al. (2006) and Park et al. (2010) was a particularly elegant demonstration of how iNKT cells appear to be stimulated through their IL-12Rϐ2 and FcγRIII receptors, resulting in increased IL-4 and IFN-γ and suppressed TGF-ϐ production, and subsequent modulation of arthritis severity. The only caveat to their work is the use of relatively nonspecific markers which did not distinguish iNKT from other NKT cell subsets. It also still remains unclear which iNKT cell subsets are important and whether invariant TCR-selflipid-CD1d interaction plays any role in iNKT cell activation during the effector stage. Further work is required to define the source of seemingly critical IL-4, IFN-γ and TGF-ϐ, and ultimately, the extent to which these findings are applicable to rheumatoid arthritis in humans.

#### **3.5 Clinical relevance of iNKT cells in RA**

32 Rheumatoid Arthritis – Etiology, Consequences and Co-Morbidities

Chiba et al. (2005) administered a mixture of four anti-CII mAb to C57BL/6 mice, followed 72h later by LPS. Jα281-/- and CD1d-/- knockout mice also showed reduced disease severity without any difference in susceptibility, in keeping with a role for iNKT cells during the

Antigen-induced arthritis (AIA) occurs when bovine serum albumin (BSA) is injected into the knee joint of B6 mice after priming with subcutaneous BSA injection, resulting in a week-long acute inflammatory arthritis (van den Berg et al., 2007). Teige et al. (2010) showed that CD1d-/- knockout mice experience a more severe AIA associated with a stronger splenocyte antigen-specific IFN-γ response without any difference in cell proliferation.

CIA models using either C57BL/6 or the more susceptible DBA/1 mouse strains have consistently shown that iNKT cell deficient animals experience a reduced incidence and/or severity of arthritis. This therefore suggests that in contrast to other models of autoimmune disease and despite the apparent reduction in frequency of peripheral iNKT cells in RA,

The increased incidence is a clue for an early role for iNKT cells in disease initiation, and this is supported by the observation of DLN cytokine deviation by day 11 in C57BL/6 mice (Yoshiga et al., 2008) and a reduction in incidence and disease amelioration when anti-CD1d is administered early, but not late in DBA1/J mice (Miellot-Gafsou et al., 2010). Ohnishi et al. (2005) found however no evidence of an effect on splenocyte cytokine deviation until day 26 in C57BL/6 mice, but given that they used the same mouse strains and CIA induction protocol as Yoshiga et al. (2008), the conflicting results are likely to be due to site and time-

There is also reasonable evidence that iNKT cells play a role in later, effector stages of CIA too. IL-17 producing iNKT cells have been noted to steadily increase in numbers until the very late stages of disease in DBA/1 mice (Jung et al., 2009) and anti-CD1d administered to C57BL/6 mice on day 21 results in disease amelioration (Chiba et al., 2005). In addition,

So how do iNKT cells influence the immune pathogenesis of CIA? Experimental data suggest that early on during induction and continuing into the effector stage of disease, iNKT cells skew the immune response to CII by promoting a Th1 and/or Th17 phenotype. It seems likely that by altering the cytokine environment, iNKT cells also influence the corresponding observed shift in autoantibody isotype from IgG1 to complement-fixing IgG2a. Furthermore, iNKT cells enhance both T and B cell responses as evidenced by the expression of activation markers and levels of circulating anti-CII autoantibodies, no doubt

Whilst providing remarkable insight into the immunological role of iNKT cells in autoimmunity, murine models of CIA have also raised new issues and left us with many unanswered questions. It is unclear which particular iNKT cell subset is responsible for exacerbating disease, whether the same subsets are pathogenic at different stages or even whether some subsets play a protective role as suggested by Jung et al.'s Tol-DC experimental model (Jung et al., 2010). Neither do we know how iNKT cells become

but not CD1d-

/-

Tol-DC could suppress CIA in

**3.4.2.2 Other models of autoimmune arthritis** 

effector as well as adaptive stages of CIA.

Notably, NK1.1-depletion resulted in more severe arthritis.

specific differences between DLN and splenocyte populations.

DBA/1 mice when administered as late as day 28 (Jung et al., 2010).

mediated in part by increased APC co-stimulatory molecule expression.

Jung et al. demonstrated that CD1d+/-

**3.4.3 Lessons learnt from animal models of autoimmune arthritis** 

iNKT cells play a pathogenic role in animal models of autoimmune arthritis.

Despite the demonstrated pathogenicity of iNKT cells in animal models of autoimmune arthritis, their frequency and phenotype may yet serve as useful biomarkers, and their immune manipulation may serve a beneficial therapeutic purpose as shown in the context of infection, cancer immunity and other autoimmune diseases.

#### **3.5.1 iNKT cells as diagnostic and prognostic tools**

It seems that peripheral iNKT cell frequency is reduced in a range of autoimmune diseases including diabetes, multiple sclerosis and SLE. This may indicate a response to systemic inflammation or a generalised association with autoimmunity. As such, iNKT cells could in theory be used to distinguishing RA from other forms of arthritis. Furthermore, additional detailed analysis of iNKT subsets and function may provide prognostic information to guide individual treatment. Finally, it is tempting to speculate whether iNKT cells could serve as markers of self-tolerance to signal the safe withdrawal of long term immunosuppression in patients achieving clinical remission.

Our own work in this area showed that peripheral iNKT cell frequency was reduced among patients with RA, osteoarthritis (OA) and other inflammatory non-RA groups compared to patients with non-inflammatory, non-OA joint pain and healthy controls. This indicates that in practice iNKT cell frequency alone would prove of limited diagnostic or disease monitoring value. Whilst iNKT cell counts appear to improve with methotrexate therapy, we found no correlation with clinical response and therefore the significance of this observation remains unknown (Tudhope et al., 2010).

#### **3.5.2 Manipulating iNKT cells for clinical benefit**

OCH, a synthetic analogue of α-GalCer with a truncated sphingosine chain, has been shown to induce a Th2 bias in iNKT cytokine production and can efficiently inhibit EAE in C57BL/6 mice. Chiba et al. therefore studied the effects of intra-peritoneal α-GalCer and OCH administration, before and after induction of CIA in C57BL/6 mice. Unlike α-GalCer, OCH significantly reduced the clinical severity score of CIA from 13 to 4.6. When OCH was

Invariant Natural Killer T Cells in Rheumatoid Arthritis and Other Inflammatory Arthritides 35

Screening a panel of analogs of α-GalCer for the ability to suppress the development of arthritis in a B6 model of K/BxN serum transfer-induced arthritis, Kaieda et al. (2007) found SGL-S23, an analog with a 5-carbon longer sphingosine base that could inhibit clinical and histological disease severity to a greater degree than α-GalCer by i.p. administration on days 0, 3 and 7. Furthermore, they showed a therapeutic effect when administered to mice with established arthritis. By injecting Jα281-/- knockout mice, they confirmed that SGL-S23 mediated disease suppression requires iNKT cells. Neutralisation of IL-4, IL-10 or TGF-ϐ1 did not abolish the protective effect of SGL-S23. Instead, SGL-S23 was able to stimulate weaker in vitro cell proliferation and IFN-γ production than α-GalCer. Similarly, in vivo injection of SGL-S23 resulted in weaker IFN-γ serum responses. In keeping with the known essential role played by mast cells in the development of arthritis in the K/BxN serum transfer model, Kaieda et al. (2007) showed an elevation in serum histamine level five minutes after serum injection, abolished by pre-treatment with low-dose IFN-γ. SGL-S23 also suppressed histamine release, and more effectively so than α-GalCer or high dose

Finally, CIA suppression through NKT cell manipulation can be accomplished with nonglycolipid stimulation as shown by Liu et al. (2011). Immunisation with murine CII induces a weaker responsethan heterologous collagen, characterised by multiple epitopes sharing a common motif, the strongest located at position 707-721. B10.Q or B6 mice immunised with mCII707-721 mount a strong and specific immune response. In fact murine mCII707-721 can bind to CD1d and partially competes with α-GalCer. B10.Q immunisation with mCII707-721 resulted in significant expansion of CD4+NK1.1+ NKT cells. Reactive cells showed skewed TCR usage toward Vα14Jα18 with a diverse range of Vϐ chains, with some skewing toward Vϐ8.2. NKT cell proliferation was dependent on CD40-CD40L and B7-CD28 co-stimulation, while activated NKT cells produced IFN-γ, IL-4 and TGF-ϐ but less TNF-α, peaking at 72h and thus resembling conventional T cell kinetics. Vaccination with mCII707-721 ameliorated CIA, reducing clinical severity, joint inflammation, CD4 synovial infiltration and joint tissue

In summary, both α-GalCer and its analogues have been shown to modulate the severity of autoimmune arthritis in animal models during both the initiation and effector stages of disease. The mechanism of iNKT cell-mediated protection appears to be complex as evidenced by conflicting reports of Th1/Th2/Th17 polarisation, variable immunoglobulin isotype profiles and anergy induction by some agonists but not others. Immune alteration however is not restricted to the adaptive system, as shown by effects on mast cell activation in a serum transfer model of autoimmune arthritis. Before glycolipid ligands can be considered for use in rheumatoid arthritis, we will need to gain a better understanding of the factors important in predicting how these ligands will modulate the immune response,

Invariant NKT cells are powerful immune protagonists that can be engaged during innate immune system activation to amplify and direct subsequent adaptive immune responses by cytokine and cell contact-mediated cross-talk with a wide range of other immune players. In both rheumatoid arthritis and other autoimmune disorders, iNKT cells appear to be deficient in both number and function. Nevertheless, animal models of autoimmune arthritis consistently tell us that iNKT cells play a pathogenic rather than protective role.

including ligand structure, dose, route of administration and timing of treatment.

IFN-γ.

IFN-γ, IL-4 and TNF-α production.

**4. Conclusion** 

administered to Jα281-knockout mice, there was no difference in disease severity score as compared with vehicle alone, confirming the requirement for iNKT cells for OCH-mediated suppression of CIA. αGalCer injection induced a rapid rise in serum IL-4 and IFN-γ levels, while OCH increased IL-4 levels with much less IFN-γ production. Consistent with an iNKT cell derived source of cytokines, Jα281 knockout mice did not exhibit a rise in either IL-4 or IFN-γ (Chiba et al., 2004).

Miellot et al. (2005) explored the therapeutic potential of α-GalCer in the autoimmune prone DBA/1 model of CIA. Mice immunised with intra-peritoneal α-GalCer both before, at or after induction showed reduced disease severity but no difference in susceptibility or timing of disease onset. The optimal effect was noted with a single injection on day 0 and correlated with reduced histological inflammation and tissue destruction without any difference in levels of IgG1, IgG2a or IgG1/IgG2a ratio. Cytokine production by draining lymph node (DLN) CD4+ T cells in response to CII stimulation showed no significant differences for IFNγ or IL-4, but a significant increase in IL-10 production in α-GalCer/CII/CFA as compared to CII/CFA-immunised mice. Accordingly, the protective effect of α-GalCer on CIA was completely abrogated by blocking with anti-IL10R mAb.

Administration of a single dose of α-GalCer in a DBA/1 model of CIA on day 5 postimmunisation by Coppieters et al. (2007) resulted in an attenuated course of clinical disease and histological parameters. Splenic T-bet expression was reduced whilst GATA-3 was unchanged, suggesting an altered balance in favour of Th2 differentiation associated with a reduced antigen-specific CII proliferative response in DLN cells. Similar disease attenuation occurred following administration of the α-C-GalCer analog, a C-glycoside analogue of α-GalCer. Serum cytokine analysis after α-C-GalCer administration however showed marked differences as compared to α-GalCer administration, with negligible production of IL-2, TNF-α, IL-4 and IL-10, reduced IL-5 and IFN-γ, and increased IL-12p70 and IL-6. α-GalCer, but not α-C-GalCer, induced increased IgG1 levels with no difference in IgG2a between groups. T cell cytokine profiles induced with in vivo administration of anti-CD3 on day 14 after arthritis onset confirmed that mice treated with α-GalCer exhibited increased IL-10 production whilst mice treated with α-C-GalCer revealed lower levels of IL-4, IL-5 and IFNγ. Furthermore, IL-10 production at 10 days post-immunisation was increased in α-GalCertreated wild-type but not Jα281-/- mice, suggesting that the increased IL-10 in α-GalCer treated mice is iNKT cell-dependent. The authors therefore proposed that α-GalCer protection may be mediated by the development of an IL-10 producing population of regulatory cells whilst α-C-GalCer may operate by inducing a general hyporesponsive state as evidence by lower cytokine production.

α-carba-GalCer is another analogue of α-GalCer known to stimulate Th1 responses in iNKT cells. In DBA/1 mice, α-carba-GalCer can strongly induce IFN-γ, IL-2 and IL-12 but unlike α-GalCer, does not induce IL-4. When administered with CII/CFA on day 0, α-carba-GalCer reduced the incidence and severity of arthritis in an IFN-γ-dependent manner. This was associated with reduced CII-specific IgG2a antibody levels and inhibition of IL-17 production by CII-stimulated DLN cells. No change in apoptotic or regulatory FoxP3+ T cell frequency in DLN was noted. As early as day 3, DLN cells expressed reduced IL-6 and IL-23p19 with unchanged TGF-ϐ while CD1d-tetramer+ iNKT cells produced higher IFN-γ in spleen, liver and DLN. On day 10, DLN T cells stimulated with PMA and ionomycin showed polarisation towards Th1 and suppression of Th17 cell differentiation, in keeping with protective Th1 deviation during the initiation phase of CIA (Yoshiga et al., 2011).

Screening a panel of analogs of α-GalCer for the ability to suppress the development of arthritis in a B6 model of K/BxN serum transfer-induced arthritis, Kaieda et al. (2007) found SGL-S23, an analog with a 5-carbon longer sphingosine base that could inhibit clinical and histological disease severity to a greater degree than α-GalCer by i.p. administration on days 0, 3 and 7. Furthermore, they showed a therapeutic effect when administered to mice with established arthritis. By injecting Jα281-/- knockout mice, they confirmed that SGL-S23 mediated disease suppression requires iNKT cells. Neutralisation of IL-4, IL-10 or TGF-ϐ1 did not abolish the protective effect of SGL-S23. Instead, SGL-S23 was able to stimulate weaker in vitro cell proliferation and IFN-γ production than α-GalCer. Similarly, in vivo injection of SGL-S23 resulted in weaker IFN-γ serum responses. In keeping with the known essential role played by mast cells in the development of arthritis in the K/BxN serum transfer model, Kaieda et al. (2007) showed an elevation in serum histamine level five minutes after serum injection, abolished by pre-treatment with low-dose IFN-γ. SGL-S23 also suppressed histamine release, and more effectively so than α-GalCer or high dose IFN-γ.

Finally, CIA suppression through NKT cell manipulation can be accomplished with nonglycolipid stimulation as shown by Liu et al. (2011). Immunisation with murine CII induces a weaker responsethan heterologous collagen, characterised by multiple epitopes sharing a common motif, the strongest located at position 707-721. B10.Q or B6 mice immunised with mCII707-721 mount a strong and specific immune response. In fact murine mCII707-721 can bind to CD1d and partially competes with α-GalCer. B10.Q immunisation with mCII707-721 resulted in significant expansion of CD4+NK1.1+ NKT cells. Reactive cells showed skewed TCR usage toward Vα14Jα18 with a diverse range of Vϐ chains, with some skewing toward Vϐ8.2. NKT cell proliferation was dependent on CD40-CD40L and B7-CD28 co-stimulation, while activated NKT cells produced IFN-γ, IL-4 and TGF-ϐ but less TNF-α, peaking at 72h and thus resembling conventional T cell kinetics. Vaccination with mCII707-721 ameliorated CIA, reducing clinical severity, joint inflammation, CD4 synovial infiltration and joint tissue IFN-γ, IL-4 and TNF-α production.

In summary, both α-GalCer and its analogues have been shown to modulate the severity of autoimmune arthritis in animal models during both the initiation and effector stages of disease. The mechanism of iNKT cell-mediated protection appears to be complex as evidenced by conflicting reports of Th1/Th2/Th17 polarisation, variable immunoglobulin isotype profiles and anergy induction by some agonists but not others. Immune alteration however is not restricted to the adaptive system, as shown by effects on mast cell activation in a serum transfer model of autoimmune arthritis. Before glycolipid ligands can be considered for use in rheumatoid arthritis, we will need to gain a better understanding of the factors important in predicting how these ligands will modulate the immune response, including ligand structure, dose, route of administration and timing of treatment.

#### **4. Conclusion**

34 Rheumatoid Arthritis – Etiology, Consequences and Co-Morbidities

administered to Jα281-knockout mice, there was no difference in disease severity score as compared with vehicle alone, confirming the requirement for iNKT cells for OCH-mediated suppression of CIA. αGalCer injection induced a rapid rise in serum IL-4 and IFN-γ levels, while OCH increased IL-4 levels with much less IFN-γ production. Consistent with an iNKT cell derived source of cytokines, Jα281 knockout mice did not exhibit a rise in either IL-4 or

Miellot et al. (2005) explored the therapeutic potential of α-GalCer in the autoimmune prone DBA/1 model of CIA. Mice immunised with intra-peritoneal α-GalCer both before, at or after induction showed reduced disease severity but no difference in susceptibility or timing of disease onset. The optimal effect was noted with a single injection on day 0 and correlated with reduced histological inflammation and tissue destruction without any difference in levels of IgG1, IgG2a or IgG1/IgG2a ratio. Cytokine production by draining lymph node (DLN) CD4+ T cells in response to CII stimulation showed no significant differences for IFNγ or IL-4, but a significant increase in IL-10 production in α-GalCer/CII/CFA as compared to CII/CFA-immunised mice. Accordingly, the protective effect of α-GalCer on CIA was

Administration of a single dose of α-GalCer in a DBA/1 model of CIA on day 5 postimmunisation by Coppieters et al. (2007) resulted in an attenuated course of clinical disease and histological parameters. Splenic T-bet expression was reduced whilst GATA-3 was unchanged, suggesting an altered balance in favour of Th2 differentiation associated with a reduced antigen-specific CII proliferative response in DLN cells. Similar disease attenuation occurred following administration of the α-C-GalCer analog, a C-glycoside analogue of α-GalCer. Serum cytokine analysis after α-C-GalCer administration however showed marked differences as compared to α-GalCer administration, with negligible production of IL-2, TNF-α, IL-4 and IL-10, reduced IL-5 and IFN-γ, and increased IL-12p70 and IL-6. α-GalCer, but not α-C-GalCer, induced increased IgG1 levels with no difference in IgG2a between groups. T cell cytokine profiles induced with in vivo administration of anti-CD3 on day 14 after arthritis onset confirmed that mice treated with α-GalCer exhibited increased IL-10 production whilst mice treated with α-C-GalCer revealed lower levels of IL-4, IL-5 and IFNγ. Furthermore, IL-10 production at 10 days post-immunisation was increased in α-GalCertreated wild-type but not Jα281-/- mice, suggesting that the increased IL-10 in α-GalCer treated mice is iNKT cell-dependent. The authors therefore proposed that α-GalCer protection may be mediated by the development of an IL-10 producing population of regulatory cells whilst α-C-GalCer may operate by inducing a general hyporesponsive state

α-carba-GalCer is another analogue of α-GalCer known to stimulate Th1 responses in iNKT cells. In DBA/1 mice, α-carba-GalCer can strongly induce IFN-γ, IL-2 and IL-12 but unlike α-GalCer, does not induce IL-4. When administered with CII/CFA on day 0, α-carba-GalCer reduced the incidence and severity of arthritis in an IFN-γ-dependent manner. This was associated with reduced CII-specific IgG2a antibody levels and inhibition of IL-17 production by CII-stimulated DLN cells. No change in apoptotic or regulatory FoxP3+ T cell frequency in DLN was noted. As early as day 3, DLN cells expressed reduced IL-6 and IL-23p19 with unchanged TGF-ϐ while CD1d-tetramer+ iNKT cells produced higher IFN-γ in spleen, liver and DLN. On day 10, DLN T cells stimulated with PMA and ionomycin showed polarisation towards Th1 and suppression of Th17 cell differentiation, in keeping with protective Th1 deviation during the initiation phase of CIA (Yoshiga et al., 2011).

IFN-γ (Chiba et al., 2004).

completely abrogated by blocking with anti-IL10R mAb.

as evidence by lower cytokine production.

Invariant NKT cells are powerful immune protagonists that can be engaged during innate immune system activation to amplify and direct subsequent adaptive immune responses by cytokine and cell contact-mediated cross-talk with a wide range of other immune players. In both rheumatoid arthritis and other autoimmune disorders, iNKT cells appear to be deficient in both number and function. Nevertheless, animal models of autoimmune arthritis consistently tell us that iNKT cells play a pathogenic rather than protective role.

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**3** 

*UK* 

**IL-12 Family Cytokines in Inflammation and** 

*2Tissue Engineering and Reparative Dentistry, Dental School of Cardiff University,* 

Rheumatoid arthritis (RA) is an autoimmune disease characterised by chronic joint inflammation. The precise aetiology of this autoimmune process remains unclear. Soluble factors produced by infiltrating synovial cells play an important role in driving the inflammatory process that leads to inflammatory cell migration and proliferation in the synovial tissue. These soluble factors consist mainly of cytokines that either promote or

A number of cytokines have been identified in synovial fluid and the synovial membrane. Cytokines such as TNF, IL-1 and IL-6 stimulate T-cells and induce subsequent cartilage and bone erosion (Kang et al., 2009). Along with IL-18, these cytokines are produced by synovial macrophages and synovial fibroblasts. IL-18 causes joint inflammation and subsequent bone destruction by facilitating T-cell activation and stimulating B-cell production of autoantibodies. Deletion of the IL-18 gene in mice has been shown to result in a significant reduction in the incidence of joint inflammation and bone destruction (Wei et

CD4+ T-cells proliferate in inflamed synovial joints through stimulation of IL-15. Inhibition IL-15 results in a significantly lower production of TNF and IL-1. As such, IL-15 blockade abolishes severe joint inflammation in collagen induced-arthritis mouse models (Ruchatz et al., 1998). In the CD4+ T-cell population, Th17 has been demonstrated as a pathogenic T-cell that produces IL-17 to induce neutrophil migration (Shibata et al., 2009). IL-17 is known to stimulate receptor-activator of nuclear factor kappa-B ligand (RANKL) production by osteoblast cells to promote osteoclastogenesis in RA bone erosion (Joosten et al., 2003). Th17 development is governed by TGF, IL-1 and IL-23 (Paradowska-Gorycka et al., 2010; Santarlasci et al., 2009). Higher concentrations of IL-23 (a member of the IL-12 family cytokines) are detected in the serum and synovial fluid of patients with greater severity of RA (Melis et al., 2010). IL-23 can also be produced by osteoblast cells after stimulation with

 It is possible that remission of joint inflammation in RA patients can occur spontaneously. The fluctuation in inflammation within the joint results from auto-inhibition through the production of anti-inflammatory cytokines via regulatory T (Treg) cells (Raghavan et al.,

**1. Introduction**

suppress inflammation.

TNF (unpublished data).

al., 2001).

**Bone Erosion of Rheumatoid Arthritis** 

Ran Wei1, Alastair J. Sloan2 and Xiao-Qing Wei2 *1Chelsea and Westminster Hospital NHS Foundation Trust,* 

