Zwitterionic polymer with minimal reactivity against PEG antibodies to enhance the therapeutic effects of cytokine-targeting DNA aptamer

Abstract

Overcoming poor in vivo pharmacokinetics is a critical challenge in developing therapeutic aptamers, and conjugation to poly(ethylene glycol) (PEG) is a well-established technique for aptamers to prolong blood circulation. However, the existence of antibodies that specifically recognize PEG and their adverse effects on in vivo behaviors have been increasingly reported, highlighting the necessity of alternative modification strategies for aptamers. To address this issue, we focused on a zwitterionic polymer, particularly poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC), as a PEG alternative to modify DNA aptamers. We conjugated PMPC to a DNA aptamer targeting IFN-gamma and investigated the properties of the PMPC-conjugated DNA aptamer as a therapeutic agent. PMPC modification did not affect the neutralizing activity of the aptamer. PMPC demonstrated lower reactivity against anti-PEG antibodies than PEG-like aptamer modifiers previously reported to exhibit low reactivity against PEG antibodies. In addition, PMPC extended the blood circulation time of the aptamer as long as or longer than PEG with a similar molecular size. In the LPS-induced inflammation animal model, the survival rate after treatment with the PMPC-aptamer conjugate was significantly superior to that with unmodified aptamer. These results indicate that PMPC has potential as an aptamer or other nucleic acid drug modifier to replace or be compatible with PEG.