Abstract:
Tailored metallic nanoparticles (NPs) coupled to specific proteins (bio-nanohybrids)
can provide tunable functional materials at the nanoscale. Malleable
characteristics of the NPs and diversity of the protein functions widen
the horizons of conceivable applications of such bio-nanohybrids. In the presented
work the interplay between Photosystem I (PSI) from Thermosynechococcus
elongatus (T. elongatus) and different plasmonic NPs was investigated.
PSI, an abundant photoactive pigment-protein complex is the essential
component of photosynthesis. It binds 300 chlorophyll molecules
(Chl a) per trimer within its protein scaffolding to facilitate the conversion
of solar energy into chemical energy.
PSI complexes were coupled to different mono- and bimetallic NPs and corresponding
plasmonic interaction effects on the fluorescence properties of the
PSI were investigated using single-molecule spectroscopy (SMS). The used
metallic NPs were fabricated by thermal annealing of thin metallic films.
Measurements were performed at different temperatures in a range 1.6 -
250 K and variations in the emission properties of isolated and NP-coupled
PSI complexes were analyzed comprehensively.
Interactions with bimetallic NPs exhibiting various metallic compositions
were studied at cryogenic temperature (1.6 K). The fluorescence emission of
the PSI was intensified upon coupling with NPs. Different compositions of
the bimetallic NPs resulted in different enhancement factors (EFs). NPs with
Au/Au composition led the maximum enhancement followed by the Ag/Au
and Au/Ag. On average the fluorescence was enhanced up to 4.4 (Au/Au),
2.3 (Ag/Au), and 1.1 (Au/Ag)-fold. For individual complexes, however, EFs
even up to 22.9 (Au/Au), 5.1 (Ag/Au), and 1.7 (Au/Ag)-fold were observed.The enhancement of the fluorescence demonstrated strong wavelength dependence
for all compositions. This was explained considering the largely
extended multichromophoric composition of PSI.
To further study the impact of temperature on metal-enhanced fluorescence
(MEF) of PSI, monometallic NPs composed of gold only were employed.
Measurements were performed at 1.6, 90, 190 and 250 K. A strong temperature
dependence of the shape and intensity of the emission spectra was
noticed. On average the fluorescence was enhanced 4.3 (1.6 K), 19.4 (90 K),
57.6 (190 K) and 84.0 (250 K)-fold. However, for individual complexes,
the EFs up to 230, 250 and even 441-fold were observed. The remarkable
increase in EFs at higher temperatures was discussed taking into account
the low initial fluorescence yield of PSI, an increase in excitation rate, appearance
of new emission channels due to altered excitation energy transfer
(EET) pathways and increased spectral overlap between absorption spectrum
of gold nanoparticles (AuNPs) and emission spectrum of PSI.
In the last part, photopatterned self-assembled monolayers (SAMs) of the
thiols were applied to achieve a precise and controlled attachment of the proteins
to the gold substrate. Two thiols, i.e., perfluorinated and carboxylic
acid-terminated were applied to prevent the unwanted and encourage the
wanted adsorption, respectively. Different surface analysis techniques were
used to examine the formation and photopatterning of the SAMs. It was
noticed that to ensure the complete photooxidation of the perfluorinated
thiol, it is essential to use a specific wavelength of UV light. Perfluorinated
thiol did not prove a strong resister against unwanted attachment, as an
adequate amount of the PSI was found at nonspecific sites. Carboxylic acidterminated
thiol, however, fulfilled the objective and appeared as a suitable
candidate to encourage the desired attachment of the PSI.
single-molecule spectroscopy
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