Mass Spectrometric Detection of Targeting Peptide Bioconjugation to <i>Red clover necrotic mosaic virus</i> Ruqi Wang Dustin M. Lockney Michael B. Goshe Stefan Franzen 10.1021/bc2001769.s001 https://acs.figshare.com/articles/journal_contribution/Mass_Spectrometric_Detection_of_Targeting_Peptide_Bioconjugation_to_i_Red_clover_necrotic_mosaic_virus_i_/2599078 Plant virus nanoparticle (PVN) formulations constructed from <i>Red clover necrotic mosaic virus</i> by drug infusion and targeting peptide conjugation can be employed as drug delivery tools. In this investigation, we studied the cross-linked structures formed by application of sulfosuccinimidyl-4-(<i>N</i>-maleimidomethyl) cyclohexane-1-carboxylate (sSMCC) and succinimidyl-[(<i>N</i>-maleimidopropionamido)-hexaethylene glycol] ester (SMPEG) as heterobifunctional linkers in the bioconjugation process. The plant virus formulations using several targeting peptides cross-linked to the plant virus capsid were characterized by LC/MS<sup>E</sup> analysis, which produced at least 69% sequence coverage using trypsin and chymotrypsin digestion. The results showed evidence for several types of modification located in three domains of the capsid protein. Extensive linker modifications on lysines or cysteines were detected in all the domains, including both intended peptide–capsid cross-links and unintended intracapsid cross-links. Surprisingly, the most extensive peptide modification was observed in the R domain, which is thought to be quite inaccessible to peptides and cross-linking reagents in solution, since it is on the interior of the virus. These results show that heterobifunctional linkers may not be the most efficient method for attachment of peptides to plant virus capsids. As an alternative conjugation strategy, maleimide peptides were used to conjugate with the virus in a one-step reaction. Analysis by LC/MS<sup>E</sup> showed that these one-step maleimide coupling reactions were more specific, such as modifications of C154 and to a lesser extent C267, and provide a means for achieving more effective PVN formulations. 2011-10-19 00:00:00 plant virus formulations peptide Extensive linker modifications plant virus capsids alternative conjugation strategy Targeting Peptide Bioconjugation heterobifunctional linkers SMPEG PVN Red clover plant virus capsid mass Spectrometric Detection LC drug delivery tools mosaic virusPlant virus nanoparticle