RESUMO
Antitumor immune responses depend on the infiltration of solid tumors by effector T cells, a process guided by chemokines. In particular, the chemokine CXCL10 has been shown to play a critical role in mediating recruitment of CXCR3 + cytolytic T and NK cells in tumors, though its use as a therapeutic agent has not been widely explored. One of the limitations is due to the rapid inactivation of CXCL10 by dipeptidyl peptidase 4 (DPP4), a broadly expressed enzyme that is active in plasma and other bodily fluids. In the present study, we describe a novel method to produce synthetic CXCL10 that is resistant to DPP4 N-terminal truncation. Using a Fmoc solid-phase peptide synthesis approach, synthetic murine WT CXCL10 was produced, showing similar biochemical and biological properties to the recombinant protein. This synthesis method supported production of natural (amino acid substitution, insertion or deletion) and non-natural (chemical modifications) variants of CXCL10. In association with a functional screening cascade that assessed DPP4-mediated cleavage, CXCR3 signaling potency and chemotactic activity, we successfully generated 20 murine CXCL10 variants. Among those, two non-natural variants with N-methylated Leu3 (MeLeu3) and a reduced amide bond between Pro2 and Leu3 (rLeu3), respectively, showed resistance to DPP4 truncation but decreased CXCR3 signaling and chemotactic activity. Interestingly, MeLeu3 and rLeu3 CXCL10 behaved as DPP4 inhibitors, preventing the truncation of WT CXCL10. This study highlights the potential of using Fmoc solid-phase chemistry in association with biochemical and biological characterization to rapidly identify CXCL10 variants with desired properties. These novel methods unlock the opportunity to develop DPP4 resistant CXCL10 variants, as well as other chemokine substrates, while maintaining chemotactic properties.