P124 Elucidating the role of risk variants in the BIM gene enhancer in T-Cell dysregulation and rheumatoid arthritis pathogenesis

The balance governing T-cell responses is pivotal for immune homeostasis. Disruptions to this balance may lead to aberrant behaviours, potentially resulting in autoimmunity. Rheumatoid Arthritis (RA), an autoimmune disorder primarily manifesting in the joints, is characterised by a defective immune response, resulting in chronic inflammation. Enhanced T-cell apoptosis resistance in this context can contribute to sustained activation and abnormal proliferation in a pro-inflammatory environment. Understanding these disease mechanisms could lead to improvements in clinical care. Genome-wide association studies (GWAS) have identified hundreds of single nucleotide polymorphisms (SNPs) associated with RA, preferentially enriched in non-coding, T-cell-specific putative enhancers. Enhancers are DNA elements that can regulate the transcription of specific genes, often from many kilobases away. Our previous work identified BCL2L11, or BIM, as the probable causal gene within the RA locus rs13396472, despite the GWAS variants' intronic positioning relative to ACOXL. The RA risk variant disrupts a distant enhancer regulating the BIM gene, pivotal for apoptosis. Given the role of apoptosis in immune tolerance, disruption of this pathway driven by RA risk variants could pave the way for autoimmune responses. Our aim was to investigate the effect of this enhancer on T-cell proliferation and function in an in vivo model.

We mapped the human RA-locus to the mouse genome and utilised CRISPR-Cas9 to delete this putative RA enhancer in mice. Two sgRNAs, combined with Cas9, were microinjected into C57BL6/J zygote pronuclei, followed by embryo transfer to pseudo-pregnant mice. PCR and Sanger sequencing confirmed enhancer deletion in pups, establishing an RA-enhancer deletion colony. To gauge cell proportion differences, murine splenocytes or thymocytes were stained with specific fluorochrome markers and analysed via a flow cytometer. For the antigen-induced arthritis (AIA) model, wildtype and RA-enhancer deletion mice were subjected to arthritis induction via intra-articular injection of methylated bovine serum albumin, following prior immunisation, and monitored for arthritis signs.

We observed an increased CD4+CD8+ double positive (DP) T-cell population in aged mice homozygous and heterozygous for the RA-enhancer deletion, but not in younger and wild-type controls. Knockout mice exhibited visibly enlarged spleens in response to the immunisation step prior to AIA induction. Further work will establish the mechanisms underlying this and disease progression after arthritis induction. These observations underscore a potential impact this enhancer might have on immune responses and survival upon immune system alteration.

Our research indicates that perturbing mouse non-coding sequences syntenic to human GWAS loci can provide a physiological model to elucidate novel mechanisms underlying RA, potentially suggesting therapeutic targets. Future research will explore the mechanism by which the enhancer deletion leads to an increase in DP T-cells and the altered phenotype, and the implications of such a change for T- and B-cell biology and RA.

S. Rossi: None. E. Richards: None. J. Ding: None. C. Shi: None. M. Menon: None. J. Gibbs: None. R. Grencis: None. A. Adamson: None. G. Orozco: None.