Maria C Denis

Transmembrane TNF protects mutant mice against intracellular bacterial infections, chronic inflammation and autoimmunity

Using targeted mutagenesis in mice, we have blocked shedding of endogenous murine TNF by deleting its cleavage site. Mutant mice produce physiologically regulated levels of transmembrane TNF (tmTNF), which suffice to support thymocyte proliferation but cannot substitute for the hepatotoxic activities of wild‐type TNF following LPS/D‐galactosamine challenge in vivo and are not sufficient to support secondary lymphoid organ structure and function. Notably, however, tmTNF is capable of exerting anti‐Listerial host defenses while remaining inadequate to mediate arthritogenic functions, as tested in the tristetraprolin‐deficient model of TNF‐dependent arthritis. Most interestingly, in the EAE model of autoimmune demyelination, tmTNF suppresses disease onset and progression and retains the autoimmune suppressive properties of wild‐type TNF. Together, these results indicate that tmTNF preserves a subset of the beneficial activities of TNF while lacking detrimental effects. These data support the hypothesis that selective targeting of soluble TNF may offer several advantages over complete blockade of TNF in the treatment of chronic inflammation and autoimmunity.

Identification of microRNA-221/222 and microRNA-323-3p association with rheumatoid arthritis via predictions using the human tumour necrosis factor transgenic mouse model

Objective To identify novel microRNA (miR) associations in synovial fibroblasts (SF), by performing miR expression profiling on cells isolated from the human tumour necrosis factor (TNF) transgenic mouse model (TghuTNF, Tg197) and patients biopsies. Methods miR expression in SF from TghuTNF and wild-type (WT) control mice were determined by miR deep sequencing (miR-seq) and the arthritic profile was established by pairwise comparisons. Quantitative PCR analysis was utilised for profile validation, miR and gene quantitation in patient SF. Dysregulated miR target genes and pathways were predicted via bioinformatic algorithms and validated using gain-of-function coupled with reporter assay experiments. Results miR-seq demonstrated that TghuTNF-SF exhibit a distinct pathogenic profile with 22 significantly upregulated and 30 significantly downregulated miR. Validation assays confirmed the dysregulation of miR-223, miR-146a and miR-155 previously associated with human rheumatoid arthritis (RA) pathology, as well as that of miR-221/222 and miR-323-3p. Notably, the latter were also found significantly upregulated in patient RA SF, suggesting for the first time their association with RA pathology. Bioinformatic analysis suggested Wnt/cadherin signalling as a putative pathway target. miR-323-3p overexpression was shown to enhance Wnt pathway activation and decrease the levels of its predicted target β-transducin repeat containing, an inhibitor of β-catenin. Conclusions Using miR-seq-based profiling in SF from the TghuTNF mouse model and validations in RA patient biopsies, the authors identified miR-221/222 and miR-323-3p as novel dysregulated miR in RA SF. Furthermore, the authors show that miR-323-3p is a positive regulator of WNT/cadherin signalling in RA SF suggesting its potential pathogenic involvement and future use as a therapeutic target in RA.

TNFR2 on non-haematopoietic cells is required for Foxp3+ Treg-cell function and disease suppression in EAE

The TNF/TNFR system exerts multiple proinflammatory and immunosuppressive functions in the pathogenesis of chronic inflammation and autoimmunity. In EAE, the experimental model of Multiple Sclerosis (MS), genetic ablation of TNFR2, results in exacerbated immune reactivity and chronic disease course. The underlying mechanism driving this immunosuppressive function of TNFR2 remains unclear. We show here that chronic exacerbated EAE in TNFR2 KO mice is associated with increased Th17‐cell responses and reduced numbers of Foxp3+ Treg cells both in the spinal cord and peripheral lymphoid organs. Treg cells from TNFR2‐deficient animals developing EAE show decreased proliferative and suppressive functions, both ex vivo and in vivo, and appear responsible for the exacerbated non‐remitting disease, as evidenced by phenotypic rescue following adoptive transfer of Treg cells from WT but not TNFR2−/− donors. Reciprocal BM transplantation experiments between WT and TNFR2‐deficient mice demonstrated that the capacity of TNFR2 to support Treg‐cell expansion and function during EAE is non‐intrinsic to Treg or other haematopoietic cells but requires expression of TNFR2 in radiation‐resistant cells of the host. These results reveal a previously unsuspected role for non‐haematopoietic TNFR2 in modulating Treg‐cell expansion and immune suppression during development of autoimmunity and suggest that a similar mechanism may affect chronicity and relapses characterizing human autoimmune disease, including MS.

Improved topical delivery of tacrolimus: A novel composite hydrogel formulation for the treatment of psoriasis

We have developed a composite hydrogel for improved topical delivery of the poorly soluble drug Tacrolimus (TAC) to psoriasis lesions. TAC is efficiently solubilized in methoxy poly- (ethylene glycol) hexyl substituted poly-(lactic acid) (mPEGhexPLA) based nanocarriers. For convenient and patient-friendly topical administration, TAC loaded polymeric nanocarriers were incorporated in a Carbopol® based hydrogel, to yield a composite hydrogel formulation (TAC composite hydrogel). TAC composite hydrogel was designed to have superior pharmaceutical formulation properties, delivery efficiency and local bioavailability, compared to currently available paraffin-based TAC ointments. Composite hydrogel formulations had good local tolerance and showed no signs of immediate toxicity after repeated topical administration in healthy mice. Skin delivery of TAC composite hydrogel in an imiquimod-induced psoriasis mouse model was found to be twice as high as for the commercial formulation Protopic™, used as benchmark. TAC composite hydrogel showed significant improvement in the in vivo and histopathological features of the imiquimod-induced psoriasis model.

Comorbid TNF-mediated heart valve disease and chronic polyarthritis share common mesenchymal cell-mediated aetiopathogenesis

Objectives Patients with rheumatoid arthritis and spondyloarthritisshow higher mortality rates, mainly caused by cardiac comorbidities. The TghuTNF (Tg197) arthritis model develops tumour necrosis factor (TNF)-driven and mesenchymalsynovial fibroblast (SF)-dependent polyarthritis. Here, we investigate whether this model develops, similarly to human patients, comorbid heart pathology and explore cellular and molecular mechanisms linking arthritis to cardiac comorbidities. Methods Histopathological analysis and echocardiographic evaluation of cardiac function were performed in the Tg197 model. Valve interstitial cells (VICs) were targeted by mice carrying the ColVI-Cretransgene. Tg197 ColVI-Cre Tnfr1 fl/fl and Tg197 ColVI-Cre Tnfr1 cneo/cneo mutant mice were used to explore the role of mesenchymal TNF signalling in the development of heart valve disease. Pathogenic VICs and SFs were further analysed by comparative RNA-sequencing analysis. Results Tg197 mice develop left-sided heart valve disease, characterised by valvular fibrosis with minimal signs of inflammation. Thickened valve areas consist almost entirely of hyperproliferative ColVI-expressing mesenchymal VICs. Development of pathology results in valve stenosis and left ventricular dysfunction, accompanied by arrhythmic episodes and, occasionally, valvular regurgitation. TNF dependency of the pathology was indicated by disease modulation following pharmacological inhibition or mesenchymal-specific genetic ablation or activation of TNF/TNFR1 signalling. Tg197-derived VICs exhibited an activated phenotype ex vivo, reminiscent of the activated pathogenic phenotype of Tg197-derived SFs. Significant functional similarities between SFs and VICs were revealed by RNA-seq analysis, demonstrating common cellular mechanisms underlying TNF-mediated arthritides and cardiac comorbidities. Conclusions Comorbidheart valve disease and chronic polyarthritis are efficiently modelled in the Tg197 arthritis model and share common TNF/TNFR1-mediated, mesenchymal cell-specific aetiopathogenic mechanisms.

Mesenchymal TNFR2 promotes the development of polyarthritis and comorbid heart valve stenosis

Mesenchymal TNF signaling is etiopathogenic for inflammatory diseases such as rheumatoid arthritis and spondyloarthritis (SpA). The role of Tnfr1 in arthritis has been documented; however, Tnfr2 functions are unknown. Here, we investigate the mesenchymal-specific role of Tnfr2 in the TnfΔARE mouse model of SpA in arthritis and heart valve stenosis comorbidity by cell-specific, Col6a1-cre-driven gene targeting. We find that TNF/Tnfr2 signaling in resident synovial fibroblasts (SFs) and valvular interstitial cells (VICs) is detrimental for both pathologies, pointing to common cellular mechanisms. In contrast, systemic Tnfr2 provides protective signaling, since its complete deletion leads to severe deterioration of both pathologies. SFs and VICs lacking Tnfr2 fail to acquire pathogenic activated phenotypes and display increased expression of antiinflammatory cytokines associated with decreased Akt signaling. Comparative RNA sequencing experiments showed that the majority of the deregulated pathways in TnfΔARE mesenchymal-origin SFs and VICs, including proliferation, inflammation, migration, and disease-specific genes, are regulated by Tnfr2; thus, in its absence, they are maintained in a quiescent nonpathogenic state. Our data indicate a pleiotropy of Tnfr2 functions, with mesenchymal Tnfr2 driving cell activation and arthritis/valve stenosis pathogenesis only in the presence of systemic Tnfr2, whereas nonmesenchymal Tnfr2 overcomes this function, providing protective signals and, thus, containing both pathologies.

04.14 Aortic valve disease co-develops with polyarthritis in the tnf-driven models and shares a common mesenchymal cell-mediated causality

Introduction and objectives Rheumatoid arthritis (RA) is a chronic condition characterised by inflammation of the joints as well as destruction of bone and cartilage. Studies on TNF transgenic models of polyarthritis established Tumour Necrosis Factor (TNF) targeting the mesenchymal-origin Synovial Fibroblasts (SFs) as a key event instigating the pathology. RA patients often show higher mortality rates, mainly due to the development of extraarticular disease including cardiovascular, gut and skin manifestations. The Tg197 and TnfΔARE/+ mouse models overexpress TNF and develop spontaneous chronic polyarthritis, fully mimicking human RA pathology. Here, we investigate whether these models develop, similarly to human patients, co-morbid heart pathology. Materials and methods We used the Tg197 and TnfΔARE/+ mouse models to evaluate possible arthritis-related cardiovascular disease. For further ex vivo analysis, we isolated Valve Interstitial Cells (VICs), which are the mesenchymal-origin fibroblasts constituting the aortic valve. We used a GFP reporter mouse labelling specifically mesenchymal-origin cells (ColVICre;mTm/mGFP) to target VICs. Similarities of pathogenic VICs and SFs were analysed by comparing their expression profiling with RNA sequencing analysis. Results Both arthritis models examined develop TNF-dependent aortic valve thickening, as indicated by the amelioration of the pathology following treatment with anti-TNF biologics. Aortic valves exhibited significant fibrosis with minimal signs of inflammatory cell infiltration and thickened areas, consisting almost entirely of VICs, indicating proliferation of this cell type as a hallmark of the observed phenotype. Isolated VICs from mutant mice exhibited a more proliferative and migratory phenotype and expressed high levels of TNF. Interestingly, VIC activation resembles the activated phenotype of pathogenic SFs isolated from the same mice. A significant functional correlation between these two pathogenic cells of mesenchymal origin was also supported by RNA-seq analysis, suggesting common cellular mechanisms operating in RA and RA-related heart pathology. Conclusion TNF-driven arthritis models, apart from their arthritic symptoms, develop co-morbid heart valve disease, similarly to reported comorbidities in RA patients. These two co-morbid diseases are shown here to share common mesenchymal-cell driven aetiopathogenesis.

Cover Picture: Eur. J. Immunol. 2/12

The cover is based on a spinal cord histology section taken from a TNFR2−/− mouse adoptively transferred with TNFR2−/− Treg cells prior to immunization with MOG35–55 to induce EAE. The section is stained with Luxol Fast blue to detect demyelination; Luxol Fast Red, which detects inflammatory infiltration, is the counterstain. The image is taken from the article by Tsakiri et al. (pp. 403–412) in which it is shown that TNFR2 on non-haematopoietic cells is necessary for Treg-cell suppressive activity and repression of EAE development. The colour of the image has been digitally altered for the cover.