Broadening the versatility of lentiviral vectors as a tool in nucleic acid research via genetic code expansion.

With the aim of broadening the versatility of lentiviral vectors as a tool in nucleic acid research, we expanded the genetic code in the propagation of lentiviral vectors for site-specific incorporation of chemical moieties with unique properties. Through systematic exploration of the structure-function relationship of lentiviral VSVg envelope by site-specific mutagenesis and incorporation of residues displaying azide- and diazirine-moieties, the modifiable sites on the vector surface were identified, with most at the PH domain that neither affects the expression of envelope protein nor propagation or infectivity of the progeny virus. Furthermore, via the incorporation of such chemical moieties, a variety of fluorescence probes, ligands, PEG and other functional molecules are conjugated, orthogonally and stoichiometrically, to the lentiviral vector. Using this methodology, a facile platform is established that is useful for tracking virus movement, targeting gene delivery and detecting virus-host interactions. This study may provide a new direction for rational design of lentiviral vectors, with significant impact on both basic research and therapeutic applications.

Precise and combinatorial PEGylation generates a low-immunogenic and stable form of human growth hormone.

In this study, we aimed to develop a safe and stable form of human growth hormone (hGH) and to refine PEGylation methods for therapeutic proteins via genetic code expansion. Through this precise approach, a series of polyethylene glycol (PEG) moieties and sites were combined in various ways. Additionally, the effects of combinatorial PEGylation on the biological, pharmacological, and immunogenic properties of hGH in vitro and vivo were analyzed. Our results showed that combinatorial PEGylation at Y35, G131, and K145 significantly reduced immunogenicity and improved pharmacokinetic (PK) profiles compared with mono-PEGylation, while retaining biological activity. Upon re-examination of the pharmacodynamics in hypophysectomized rats, multi-PEGylated hGH was found to be much more stable than mono-PEGylated hGH. Thus, this method for combinatorial, precise PEGylation may facilitate the development of next-generation, long-acting hGH with low immunogenicity.

Development of next generation of therapeutic IFN-α2b via genetic code expansion.

With the aim to overcome the heterogeneity associated with marketed IFN-α2b PEGylates and optimize the size of the PEG moiety and the site of PEGylation, we develop a viable and facile platform through genetic code expansion for PEGylation of IFN-α2b at any chosen site(s). This approach includes site-specific incorporation of an azide-bearing amino acid into IFN-α2b followed by orthogonal and stoichiometric conjugation of a variety of PEGs via a copper-free click reaction. By this approach, only the chosen site(s) within IFN-α2b is consistently PEGylated under mild conditions, leading to a single and homogenous conjugate. Furthermore, it makes the structure-activity relationship study of IFN-α2b possible by which the opposite effects of PEGylation on the biological and pharmacological properties are optimized. Upon re-examination of the PEGylated IFN-α2b isomers carrying different sizes of PEG at different sites, we find mono-PEGylates at H34, A74 and E107 with a 20-, 10- and 10-kDa PEG moiety, respectively, have both higher biological activities and better PK profiles than others. These might represent the direction for development of the next generation of PEGylated IFN-α2b.