Transduction of Cultured Oligodendrocytes from Normal and Twitcher Mice by a Retroviral Vector Containing Human Galactocerebrosidase (GALC) cDNA

Krabbe disease or globoid cell leukodystropy is a lysosomal disorder caused by a deficiency of galactocerebrosidase (GALC) activity. This results in defects in myelin that lead to severe symptoms and early death in most human patients and animals with this disease. With the cloning of the GALC gene and the availability of the mouse model, called twitcher, it was important to evaluate the effects of providing GALC via a retroviral vector to oligodendrocytes in culture. After differentiation, the untransduced cells from normal mice extended highly branched processes while those from the twitcher mice did not. oligodendrocytes in culture can be readily transduced to produce much higher than normal levels of GALC activity. Transduced normal and twitcher cells formed clusters when plated at high density. Transduction of twitcher oligodendrocytes plated at lower density, followed by differentiation, resulted in some cells having a completely normal appearance with highly branched processes. Other cells showed retraction and fragmentation. Perhaps over expression of GALC activity may be detrimental to oligodendrocytes. These studies demonstrate that the phenotype of twitcher oligodendrocytes can be corrected by providing GALC via gene transfer, and this could lead the way to future studies to treat this disease.     

Quantitative phosphoproteomic analysis reveals involvement of PD-1 in multiple T cell functions

Programmed cell death protein 1 (PD-1) is a critical inhibitory receptor that limits excessive T cell responses. Cancer cells have evolved to evade these immunoregulatory mechanisms by upregulating PD-1 ligands and preventing T cell–mediated anti-tumor responses. Consequently, therapeutic blockade of PD-1 enhances T cell–mediated anti-tumor immunity, but many patients do not respond and a significant proportion develop inflammatory toxicities. To improve anti-cancer therapy, it is critical to reveal the mechanisms by which PD-1 regulates T cell responses. We performed global quantitative phosphoproteomic interrogation of PD-1 signaling in T cells. By complementing our analysis with functional validation assays, we show that PD-1 targets tyrosine phosphosites that mediate proximal T cell receptor signaling, cytoskeletal organization, and immune synapse formation. PD-1 ligation also led to differential phosphorylation of serine and threonine sites within proteins regulating T cell activation, gene expression, and protein translation. In silico predictions revealed that kinase/substrate relationships engaged downstream of PD-1 ligation. These insights uncover the phosphoproteomic landscape of PD-1–triggered pathways and reveal novel PD-1 substrates that modulate diverse T cell functions and may serve as future therapeutic targets. These data are a useful resource in the design of future PD-1–targeting therapeutic approaches.