Rational design of environmentally responsive antibodies with pH-sensing synthetic amino acids.

Antibodies are widely used as therapeutic agents to tackle various diseases. In the present study, to enhance their clinical values, we rationally designed pH-responsivity by exploiting the idiosyncratic protonation/deprotonation profiles of non-natural amino acids. 3-Nitro-L-tyrosine, 3-cyano-L-tyrosine, and 3, 5-halogenated-L-tyrosine, each with near neutral pKa, were thus incorporated into Fab fragments in place of tyrosines and other residues in the variable regions. Cell-based assays showed that these modifications achieved up to 140-fold tighter binding to antigens and several-fold tighter cytotoxicity to antigen-expressing cell at pH 6.0 than pH 7.4. The pH-dependent binding effect was retained in full-length antibodies. In silico structural analyses revealed electrostatic repulsion at neutral pH between antigens and antibodies or inside the antibody as the underlying mechanisms of the acid preference, and this finding increases the designability of pH-dependent antigen binding. The development of antibodies responsive to the microenvironments of diseased tissues will allow more disease-related antigens to be targeted in treatments, because of the reduced cross-reactivity toward healthy tissues.

Single-molecule localization microscopy reveals STING clustering at the trans-Golgi network through palmitoylation-dependent accumulation of cholesterol.

Stimulator of interferon genes (STING) is critical for the type I interferon response to pathogen- or self-derived DNA in the cytosol. STING may function as a scaffold to activate TANK-binding kinase 1 (TBK1), but direct cellular evidence remains lacking. Here we show, using single-molecule imaging of STING with enhanced time resolutions down to 5 ms, that STING becomes clustered at the trans-Golgi network (about 20 STING molecules per cluster). The clustering requires STING palmitoylation and the Golgi lipid order defined by cholesterol. Single-molecule imaging of TBK1 reveals that STING clustering enhances the association with TBK1. We thus provide quantitative proof-of-principle for the signaling STING scaffold, reveal the mechanistic role of STING palmitoylation in the STING activation, and resolve the long-standing question of the requirement of STING translocation for triggering the innate immune signaling.

Homeostatic regulation of STING by retrograde membrane traffic to the ER.

Coat protein complex I (COP-I) mediates the retrograde transport from the Golgi apparatus to the endoplasmic reticulum (ER). Mutation of the COPA gene, encoding one of the COP-I subunits (α-COP), causes an immune dysregulatory disease known as COPA syndrome. The molecular mechanism by which the impaired retrograde transport results in autoinflammation remains poorly understood. Here we report that STING, an innate immunity protein, is a cargo of the retrograde membrane transport. In the presence of the disease-causative α-COP variants, STING cannot be retrieved back to the ER from the Golgi. The forced Golgi residency of STING results in the cGAS-independent and palmitoylation-dependent activation of the STING downstream signaling pathway. Surf4, a protein that circulates between the ER/ ER-Golgi intermediate compartment/ Golgi, binds STING and α-COP, and mediates the retrograde transport of STING to the ER. The STING/Surf4/α-COP complex is disrupted in the presence of the disease-causative α-COP variant. We also find that the STING ligand cGAMP impairs the formation of the STING/Surf4/α-COP complex. Our results suggest a homeostatic regulation of STING at the resting state by retrograde membrane traffic and provide insights into the pathogenesis of COPA syndrome.