Pharmacological inhibition of the chemokine receptor CX3CR1 attenuates disease in a chronic-relapsing rat model for multiple sclerosis

One hallmark of multiple sclerosis (MS) and experimental autoimmune encephalomyelitis (EAE) is infiltration of leukocytes into the CNS, where chemokines and their receptors play a major mediatory role. CX3CR1 is a chemokine receptor involved in leukocyte adhesion and migration and hence a mediator of immune defense reactions. The role of CX3CR1 in MS and EAE pathogenesis however remains to be fully assessed. Here, we demonstrate CX3CR1 mRNA expression on inflammatory cells within active plaque areas in MS brain autopsies. To test whether blocking CNS infiltration of peripheral leukocytes expressing CX3CR1 would be a suitable treatment strategy for MS, we developed a selective, high-affinity inhibitor of CX3CR1 (AZD8797). The compound is active outside the CNS and AZD8797 treatment in Dark Agouti rats with myelin oligodendrocyte glycoprotein-induced EAE resulted in reduced paralysis, CNS pathology, and incidence of relapses. The compound is effective when starting treatment before onset, as well as after the acute phase. This treatment strategy is mechanistically similar to, but more restricted than, current very late antigen-4–directed approaches that have significant side effects. We suggest that blocking CX3CR1 on leukocytes outside the CNS could be an alternative approach to treat MS.Multiple sclerosis (MS) is a chronic inflammatory, demyelinating and degenerative disease of the central nervous system (CNS). It was already discovered in the early 1900s that a similar disease could be induced in different animal species by injection of spinal cord extracts or myelin-derived proteins (1–3). This group of animal models for MS, called experimental autoimmune encephalomyelitis (EAE), has provided an experimental platform for building an extensive understanding of the pathology of MS, as well as discovering strategies for intervention of the disease. A typical feature of the pathogenesis in both MS and EAE is the infiltration of leukocytes from the blood stream into the CNS (3). Leukocyte adhesion and extravasation includes several well defined steps and various adhesion molecules, chemokines and their receptors are important mediators for this process. In line with this, the recently developed therapeutic drugs natalizumab and fingolimod, which broadly target leukocyte migration to the brain, exhibit efficacy in EAE models (4, 5), and they are now established therapies in MS (6).Natalizumab, blocking the interaction between very late antigen-4 (VLA-4) and CD106 (VCAM-1), is an effective treatment both on clinical endpoints and MRI biomarkers (7). Fingolimod, the first oral drug for relapsing remitting MS (RRMS), acts on S1P receptors preventing lymphocytes from moving out of lymphoid tissue (8). Natalizumab is only approved as a second-line monotherapy in RRMS or in patients with very active disease, because it carries increased risk of developing the often fatal progressive multifocal leukoencephalopathy (7, 9). Treatment with fingolimod is associated with side effects such as signs of immune suppression, including increased frequency of infections (8).Considering the pronounced presence of inflammatory cells in the brain of MS patients, the significant correlation between inflammation and axonal injury (10) and the efficiency of treatments that broadly block infiltration of immune cells, a similar but more restricted therapeutic approach is appealing. Chemokines are synthesized and released at sites of inflammation, where they act on specific receptors expressed by immune cells to mediate directed cell migration in synergy with adhesion molecules, such as VLA-4, from the blood stream and into the sites of inflammation. CX3CR1 is a unique member of the chemokine receptor family (11) and binds with high affinity to its ligand CX3CL1 fractalkine (FKN)]. FKN is produced in a membrane bound form but can also be released following proteolytic cleavage, making it important for mediating both adhesion and migration of CX3CR1-expressing cells. In contrast to VLA-4, which is broadly expressed on most leukocytes except neutrophils (7, 12), the expression of CX3CR1 is restricted to subpopulations of monocytes, T lymphocytes, and natural killer (NK) cells (13–16). We have previously demonstrated intense accumulation of CX3CR1-expressing microglia/macrophages within inflammatory foci in the spinal cord of Dark Agouti (DA) rats with EAE induced by myelin oligodendrocyte glycoprotein (MOG) (17) and formed the hypothesis that CX3CR1 would be an attractive therapeutic target for treating MS.To test the hypothesis, we have developed a selective, high-affinity small-molecule inhibitor of CX3CR1 (AZD8797) (18). This molecule has the potential to be administered as an oral drug in humans. However, because of the decrease in potency to rat CX3CR1 and a modest oral bioavailability in rats (39%), we have chosen continuous s.c. dosing for the proof-of-concept studies in rats. The MOG_1-125–induced EAE model in DA rats was used, because it exhibits pathology very similar to MS with infiltration of inflammatory cells, demyelination, and axonal degeneration in the CNS, as well as a relapsing remitting disease course (19, 20). To further mimic the human treatment situation, we have not only treated rats before the onset of paralysis but also initiated treatment during ongoing disease. We present efficacy (reduced paralysis) versus exposure data, analysis of CNS pathology, and measurements of functional inhibition of CX3CR1. These data, in combination with an analysis for CX3CR1 expression within MS brain autopsy samples, clearly demonstrate the potential of CX3CR1 inhibition as an alternative and unique approach for treating MS.