A strategy for uncovering germline variants altering anti-tumor CD8 T cell response.

Among many factors known to alter the outcomes of T cell receptor (TCR)-induced proximal signaling, the role of human germline variants in dictating the individuality of the anti-tumor CD8 T cell response has remained challenging to address. Here, we describe a convenient strategy for molecular and functional characterization of phosphotyrosine-altering non-synonymous single nucleotide variations (pTyr-SNVs) that directly impact TCR-induced proximal phosphotyrosine motif-based signaling pathways. We devise an experimental co-cultivation set-up comprising a C57BL/6 mouse-derived metastatic melanoma cell line engineered to constitutively present ovalbumin (OVA) antigens and retrovirally engineered syngeneic major histocompatibility complex (MHC) Class I restricted OVA TCR-transgenic CD8 T cells (OT-I). Using the synthetic version of pTyr-SNV rs1178800678-G/T-encoding integrin alpha 4 (ITGA4) p.S1027I variant as a prototype, we show that under identical TCR stimulation conditions, genetically determined membrane-proximal immunoreceptor tyrosin activation motif (ITAM) results in increased tyrosine phosphorylation of 70 kDa zeta-chain-associated protein (ZAP70) and the levels of cytotoxic effector molecule granzyme B (GZMB), which in turn result in enhanced cytotoxic activity against metastatic melanoma cell line. This strategy paves the way for rapid molecular and functional characterization of anti-tumor immune response-linked germline pTyr-SNVs so as to improve our understanding of the genetic basis of individual-to-individual differences in anti-tumor CD8 T cell response.

Neuronal cholesterol synthesis is essential for repair of chronically demyelinated lesions in mice.

Astrocyte-derived cholesterol supports brain cells under physiological conditions. However, in demyelinating lesions, astrocytes downregulate cholesterol synthesis, and the cholesterol that is essential for remyelination has to originate from other cellular sources. Here, we show that repair following acute versus chronic demyelination involves distinct processes. In particular, in chronic myelin disease, when recycling of lipids is often defective, de novo neuronal cholesterol synthesis is critical for regeneration. By gene expression profiling, genetic loss-of-function experiments, and comprehensive phenotyping, we provide evidence that neurons increase cholesterol synthesis in chronic myelin disease models and in patients with multiple sclerosis (MS). In mouse models, neuronal cholesterol facilitates remyelination specifically by triggering oligodendrocyte precursor cell proliferation. Our data contribute to the understanding of disease progression and have implications for therapeutic strategies in patients with MS.