Abstract
ABSTRACTWe report the reversible aggregation of gold nanoparticle (AuNPs) assemblies via a diarginine peptide additive and thiolated PEGs (HS-PEGs). The AuNPs were first aggregated by attractive forces between the citrate-capped surface and the arginine side chains. We found that HS-PEG thiol group has higher affinity for the AuNPs surface, thus leading to redispersion and colloidal stability. In turn, there was a robust and obvious color change due to on/off plasmonic coupling. The assemblies’ dissociation was directly related to the HS-PEG structural properties such as their size or charge. As an example, HS-PEGs with a molecular weight below 1 kDa could dissociate 100% of the assemblies and restore the exact optical properties of the initial AuNPs suspension (prior to the assembly). Surprisingly, the dissociation capacity of HS-PEGs was not affected by the composition of the operating medium and could be performed in complex matrices such as plasma, saliva, bile, urine, cell lysates or even sea water. The high affinity of thiols for the gold surface encompasses by far the one of endogenous molecules and is thus favorized. Moreover, starting with AuNPs already aggregated ensured the absence of background signal as the dissociation of the assemblies was far from spontaneous. Remarkably, it was possible to dry the AuNPs assemblies and to solubilize them back with HS-PEGs, improving the colorimetric signal generation. We used this system for protease sensing in biological fluid. Trypsin was chosen as model enzyme and highly positively charged peptides were conjugated to HS-PEG molecules as cleavage substrate. The increase of positive charge of the HS-PEG-peptide conjugate quenched the dissociation capacity of the HS-PEG molecules which could only be restored by the proteolytic cleavage. Picomolar limit of detection was obtained as well as the detection in saliva or urine.TOC
Publisher
Cold Spring Harbor Laboratory