Siponimod therapy implicates Th17 cells in a preclinical model of subpial cortical injury
Lesley A. Ward, Dennis S.W. Lee, Anshu Sharma, Angela Wang, Ikbel Naouar, Xianjie I. Ma, Natalia Pikor, Barbara Nuesslein-Hildesheim, Valeria Ramaglia, Jennifer L. Gommerman
Lesley A. Ward, Dennis S.W. Lee, Anshu Sharma, Angela Wang, Ikbel Naouar, Xianjie I. Ma, Natalia Pikor, Barbara Nuesslein-Hildesheim, Valeria Ramaglia, Jennifer L. Gommerman
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Research Article Immunology

Siponimod therapy implicates Th17 cells in a preclinical model of subpial cortical injury

Abstract

Subpial demyelination is a specific hallmark of multiple sclerosis and a correlate of disease progression. Although the mechanism(s) that mediate pathogenesis in the subpial compartment remain unclear, it has been speculated that inflammation in the overlying meninges may be associated with subpial injury. Here we show that adoptive transfer of proteolipid protein–primed Th17 cells into SJL/J recipient mice induces subpial demyelination associated with microglial/macrophage activation, disruption of the glial limitans, and evidence of an oxidative stress response. This pathology was topologically associated with foci of immune cells in the meninges and occurred in the absence of measurable anti–myelin oligodendrocyte glycoprotein IgM or IgG antibodies. To test the role of brain-infiltrating leukocytes on subpial injury, we modulated sphingosine 1-phosphate (S1P) receptor1,5 activity with BAF312 (siponimod) treatment. Administration of BAF312, even after adoptively transferred T cells had entered the brain, significantly ameliorated clinical experimental autoimmune encephalomyelitis and diminished subpial pathology, concomitant with a selective reduction in the capacity of transferred T cells to make Th17 cytokines. We conclude that sustained subpial cortical injury is associated with the capacity for brain-resident T cells to produce Th17 cytokines, and this pathological process occurs in an S1P receptor1,5–dependent manner.

Authors

Lesley A. Ward, Dennis S.W. Lee, Anshu Sharma, Angela Wang, Ikbel Naouar, Xianjie I. Ma, Natalia Pikor, Barbara Nuesslein-Hildesheim, Valeria Ramaglia, Jennifer L. Gommerman

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Figure 3

Alternative EAE models, with anti-MOG antibody production, do not produce significant cortical pathology.

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Alternative EAE models, with anti-MOG antibody production, do not produc...
ELISA was used to measure anti-mouse MOG IgG (A) and anti-mouse MOG IgM (B) in the blood. EAE was induced in C57BL/6 mice by immunization with hMOG and by adoptive transfer in SJL/J mice. (B) Anti-MOG IgM was quantified by comparing the IC50 of dilution curves (see Methods and Supplemental Figure 3). Sera from Aicda–/– mice immunized with hMOG were pooled to create a “standard” lot that was run as an internal control and is denoted by the dotted line. (C) Immunostaining and (D) quantitative analysis for PLP in layers 1–3 of the somatosensory cortex of naive wild-type (C57BL/6) mice (n = 4) and C57BL/6 (n = 8) or Aicda–/– mice (n = 6) immunized with hMOG. Values are shown as mean ± (A and B) SD or (D) SEM. Statistical significance for hMOG ELISAs was determined by Mann-Whitney U; **P < 0.01, and ***P < 0.0001. Statistical analysis for histology was done by Kruskal-Wallis with Dunn’s correction for multiple comparisons. Sera were collected from A/T SJL/J EAE mice on day 11 after adoptive transfer, and sera from hMOG mice were collected during the chronic phase of EAE. Scale bars: 50 μm.