doi: 10.1021/acsomega.0c01038.
eCollection 2020 Apr 28.
In Situ Absorption and Fluorescence Microspectroscopy Investigation of the Molecular Incorporation Process into Single Nanoporous Protein Crystals
Affiliations
- PMID: 32363313
- PMCID: PMC7191835
- DOI: 10.1021/acsomega.0c01038
Item in Clipboard
In Situ Absorption and Fluorescence Microspectroscopy Investigation of the Molecular Incorporation Process into Single Nanoporous Protein Crystals
ACS Omega.
.
Abstract
Protein crystals exhibit distinct three-dimensional structures, which contain well-ordered nanoporous solvent channels, providing a chemically heterogeneous environment. In this paper, the incorporation of various molecules into the solvent channels of native hen egg-white lysozyme crystals was demonstrated using fluorescent dyes, including acridine yellow G, rhodamine 6G, and eosin Y. The process was evaluated on the basis of absorption and fluorescence microspectroscopy at a single-crystal level. The molecular loading process was clearly visualized as a function of time, and it was determined that the protein crystals could act as nanoporous materials. It was found that the incorporation process is strongly dependent on the molecular charge, leading to heterogeneous molecular aggregation, which suggests host-guest interaction of protein crystals from the viewpoint of nanoporous materials.
Copyright © 2020 American Chemical Society.
Conflict of interest statement
The authors declare no competing financial interest.
Figures
Transmittance microscopic images of hen egg-white lysozyme
crystals
obtained using the above experimental procedure. The (a) hexagonal
and (b) square-shaped ones correspond to (110) and (101) faces of
the tetragonal HEWL crystals, respectively. (c) Schematic illustration
of the morphology of a tetragonal HEWL crystal, showing the crystallographic
axes and faces. (d) c-axis projection of the structure
of the tetragonal HEWL crystal.
Stereoscopic
microscopic images of a single well of a 48-well crystallization
plate containing already-grown hen egg-white lysozyme (HEWL) crystals
with the mother solution immediately after injection of 400 μM
eosin Y solution into the (a) well and (b) 1 day after the injection.
(a) Temporal
change of transmittance and fluorescence images of
a single HEWL crystal immediately after the injection of 400 μM
acridine yellow G into the mother solution and up to 1 day following
the injection. (b) Differential fluorescence image between the one
obtained after 1 day and the one obtained immediately after the dye
injection. (c) Temporal change of fluorescence intensity at inside
(red) and outside (black) the crystal after the injection of acridine
yellow G. The measured positions are indicated in image (a) (red and
black crosses). (d) Space-resolved fluorescence spectra of the inside
of a single HEWL crystal 1 day after acridine yellow G incorporation
(red) and outside the crystal (black). The measured positions are
indicated in image (a) (red and black crosses).
(a) Temporal changes of the transmittance and fluorescence
images
of a single HEWL crystal obtained immediately after the injection
of 400 μM rhodamine 6G into the mother solution and up to 1
day. (b) Temporal changes of fluorescence intensities at inside (red)
and outside (black) the crystal after the injection of rhodamine 6G.
The measured positions are indicated in image (a) (red and black crosses).
(c) Temporal changes of fluorescence intensity at inside (red) and
outside (black) the crystal after the injection of rhodamine 6G. (c)
Space-resolved absorption spectrum of the inside of a single HEWL
crystal following rhodamine 6G incorporation (red). The spectrum was
taken from the indicated position in image (a) (red cross). For comparison,
an absorption spectrum of a 10 μM rhodamine 6G sodium acetate
buffer solution is also shown (black). (d) Space-resolved fluorescence
spectra of the inside of a single HEWL crystal 1 day after rhodamine
6G incorporation (red) and of the outside of the crystal (black).
The measured positions are indicated in image (a) (red and black crosses).
(a) Temporal changes of the transmittance
and fluorescence images
of a single HEWL crystal obtained immediately after injection of 400
μM eosin Y into the mother solution and up to 1 day. (b) Temporal
changes of fluorescence intensity at inside (blue) and outside (black)
the crystal and the surface (red) after the injection of eosin Y.
The measured positions are indicated in image (a) (blue, red, and
black crosses). (c) Space-resolved absorption spectrum of the inside
of a single HEWL crystal following eosin Y incorporation (red). The
spectrum was taken from the position indicated in image (a) (blue
and red crosses). For comparison, the absorption spectrum of a 10
μM eosin Y sodium acetate buffer solution is also shown (black).
(d) Space-resolved fluorescence spectra of the inside and the surface
of a single HEWL crystal 1 day after eosin Y incorporation (blue and
red) and outside of the crystal (black). The measured positions are
indicated in image (a) (blue, red, and black crosses).
Transmittance and fluorescence images of a single HEWL
crystal,
which directs the (101) face to the top side 1 day after injection
of 400 μM eosin Y into the mother solution.
Schematic illustration of the molecular incorporation
process into
a HEWL crystal along the c-axis in the case of (a)
cationic molecules (rhodamine 6G) and (b) anionic molecules (eosin
Y).
References
-
- Vilenchik L. Z.; Griffith J. P.; Clair N.; Navia M. A.; Margolin A. L. Protein Crystals as Novel Microporous Materials. J. Am. Chem. Soc. 1998, 120, 4290–4294. 10.1021/ja973449+. - DOI
-
- Brühwiler D.; Calzaferri G.; Torres T.; Ramm J. H.; Gartmann N.; Dieu L.-Q.; López-Duarte I.; Martínez-Díaz M. V. Nanochannels for Supramolecular Organization of Luminescent Guests. J. Mater. Chem. 2009, 19, 8040–8067. 10.1039/b907308f. - DOI
LinkOut - more resources
Full Text Sources