ABSTRACT
The use of sequence-defined polymers is an interesting emerging solution for materials identification and traceability. Indeed, a very large amount of identification sequences can be created using a limited alphabet of coded monomers. However, in all reported studies, sequence-defined taggants are usually included in a host material by noncovalent adsorption or entrapment, which may lead to leakage, aggregation, or degradation. To avoid these problems, sequence-defined polymers are covalently attached in the present work to the mesh of model materials, namely acrylamide hydrogels. To do so, sequence-coded polyurethanes containing a disulfide linker and a terminal methacrylamide moiety are synthesized by stepwise solid-phase synthesis. These methacrylamide macromonomers are afterward copolymerized with acrylamide and bisacrylamide in order to achieve cross-linked hydrogels containing covalently-bound polyurethane taggants. It is shown herein that these taggants can be selectively detached from the hydrogel mesh by reactive desorption electrospray ionization. Using dithiothreitol the disulfide linker that links the taggant to the gel can be selectively cleaved. Ultimately, the released taggants can be decoded by tandem mass spectrometry.
Subject(s)
Acrylamides , Polymers , Disulfides/chemistry , Hydrogels/chemistry , Polyurethanes , Acrylamide , Spectrometry, Mass, Electrospray Ionization/methodsABSTRACT
We report the sensitivity of the membrane asymmetry of ABC (PEO-b-PCL-b-PMOXA) polymersomes towards the end-group modification of a shorter C block. While a non-modified ABC polymer formed polymersomes with the A block outside and the C block inside, a mixture of ABC and ABC-biotin formed polymersomes with the C block outside.
Subject(s)
Polyamines/chemical synthesis , Polyesters/chemical synthesis , Biotin/chemical synthesis , Biotin/chemistry , Catalysis , Copper/chemistry , Molecular Structure , Polyamines/chemistry , Polyesters/chemistryABSTRACT
Sequence-defined oligourethanes were tested as inâ vivo taggants for implant identification. The oligomers were prepared in an orthogonal solid-phase iterative approach and thus contained a coded monomer sequence that can be unequivocally identified by tandem mass spectrometry (MS/MS). The oligomers were then included in small amounts (1â wt %) in square-centimeter-sized crosslinked poly(vinyl alcohol) (PVA) model films, which were intramuscularly and subcutaneously implanted in the abdomen of rats. After one week, one month, or three months of implantation, the PVA films were explanted. The rat tissues exposed to the implants did not exhibit any adverse reactions, which suggested that the taggants are not harmful and probably not leaching out from the films. Furthermore, the explanted films were immersed in methanol, as a solvent for oligourethanes, and the liquid extract was analyzed by mass spectrometry. In all cases, the oligourethane taggant was detected, and its sequence was identified by MS/MS.
Subject(s)
Polyurethanes/chemistry , Polyvinyl Alcohol/chemistry , Prostheses and Implants , Abdomen/pathology , Animals , Cell Line , Cell Survival/drug effects , Humans , Methanol/chemistry , Mice , Polyurethanes/toxicity , Polyvinyl Alcohol/analysis , Rats , Spectrometry, Mass, Electrospray IonizationABSTRACT
Here we report the discovery that bifunctional thiol- and amine-reactive electrophiles serve as mechanism-based covalent cross-linkers for HECT E3 ubiquitin ligase-substrate pairs. We demonstrate that these chemical cross-linkers covalently cross-link the catalytic Cys residue of the yeast HECT E3 ubiquitin ligase Rsp5 with the Lys of the ubiquitination site in the model substrate Sic60-GFP. This work represents the first example of a mechanism-based covalent cross-link of HECT E3-substrate pairs that converts transiently interacting HECT E3-substrate pairs into stable, covalently cross-linked protein complexes, thereby facilitating their subsequent isolation, identification, and study.