As well known, metal clusters show obviously different absorption features compared to their corresponding nanoparticles. As shown in Figure 2a, the UV absorption spectra of these sample solutions prepared at various Au3+ concentrations did not indicate any formation of AuNPs due to the absence of localized surface plasmon resonance bands (ca. 520 nm). The absorption peaks at 280 nm could be attributed to the features of aromatic amino acids LY2874455 purchase in proteins. Due to the addition of exogenous agents, the absorption profile of Au and Pt at 280 nm is relatively wider than that of pure egg white, indicating that the variation of the microenvironment has an evident effect to protein conformations. Since circular dichroism
(CD) is a kind of effect tool to study proteins’ conformational changes, therefore, we performed CD spectroscopy to reveal their secondary structure changes in detail before and after the formation of metal clusters. As shown in Figure 2b, the CD spectrum of pure egg white aqueous solution displays a negative band around 215 nm and a positive band around 195 nm from the β-sheet as the main structures. However, a negative
band around 200 nm from the random coil structure was dominantly Selleck P505-15 observed for the egg white-templated metal clusters. The conformational change indicates that egg white has given rise to denaturation due to the addition of metal ions and strong base. Figure 2 Spectral Analysis of aqueous solution of chicken egg white and metal clusters. (a) UV-vis absorption spectra; (b) CD spectra. The high-resolution transmission electron microscope (HRTEM) image showed the presence of metal clusters in the size of approximately 2.5 nm (in diameter) for red-emitting Au (Figure 3a), where the crystal lattice fringes are 0.23 nm, which correspond to the (111) planes of the metallic Au. We deduced that the larger sizes could be due to the continuous irradiation of high-energy electron beams, which leads to the aggregation of the clusters. We failed to observe these dark spots in the HRTEM images of pink-emitting Au, blue-emitting Au, and blue-emitting Pt, which could be attributed to their ultra-small sizes. The fluorescence
emissions of the four samples are also shown in Figure 3b. A broad emission Nintedanib (BIBF 1120) maximum at approximately 650 nm for red-luminescent Au (red curve) was shown when the 380-nm exciting wavelength is used. The broad emission could be attributed to the multiple cluster size distributions or the intricate chemical environments around the metal core as pointed out by Xavier et al. [18]. Additionally, a front emission peak at approximately 450 nm was also observed, which is confirmed to be from the egg white (data not shown). The pink-luminescent Au (pink curve) shows an emission maximum at approximately 410 nm (excitation wavelength 330 nm). The blue-luminescent Au (blue curve) and blue-luminescent Pt (green curve) show nearly the same emission maximum at approximately 350 nm.