RESUMO
Creating new environmentally friendly and non-toxic biomaterials with novel properties is required for numerous applications in healthcare and sensing. Protein bound gold nanoclusters constitute one such class of materials that offer promise in fluorescence imaging and sensing applications. However, unlike alkane thiol-protected gold nanoclusters, the number of protein-templated gold nanoclusters with such properties is limited and there is a need to expand the repertoire of such attractive hybrid quantum clusters. Herein, we report the synthesis, characterization, and applications of new fluorescent gold nanoclusters with tunable emission properties including blue, orange, and red, within a four-helix bundle copper storage protein (Csp1). The template protein consists of 13 cysteines along the length of the helix, which are suitable ligands to template Au and stabilize the resulting 14-19 atom clusters within the protein. The resulting clusters were extensively characterized by employing spectroscopic, microscopic and other analytical methods. The optical emission, relative quantum yields, and the excited state lifetime of the clusters are shown to depend on synthetic conditions. The clusters were found to be sensitive to the ppm level of transition metal ions with the quenching capabilities following the Irving-Williams series of metals (Co2+ < Ni2+ < Cu2+), which is rationalized based on the relative affinities of transition metals for a given set of ligands. The clusters were also found to be stable across the pH range 4-8.5 which, along with tunable emission properties paves the path for live bio-imaging and bio-sensing applications under physiological conditions.
RESUMO
Accurate measurements of intracellular pH are of crucial importance in understanding the cellular activities and in the development of intracellular drug delivery systems. Here we report a highly sensitive pH probe based on a fluorescein-conjugated Au22 nanocluster. Steady-state photoluminescence (PL) measurements have shown that, when conjugated to Au22, fluorescein exhibits more than 160-fold pH-contrasting PL in the pH range of 4.3-7.8. Transient absorption measurements show that there are two competing ultrafast processes in the fluorescein-conjugated Au22 nanocluster: the intracore-state relaxation and the energy transfer from the nonthermalized states of Au22 to fluorescein. The latter becomes predominant at a higher pH, leading to dramatic PL enhancement of fluorescein. In addition to the intrinsically low toxicity, fluorescein-conjugated Au22 nanoclusters exhibit high pH sensitivity, wide dynamic range, and excellent photostability, providing a powerful tool for the study of intracellular processes.