Ning Chu1,2, Lili Cong1, Jing Yue1,3, Weiqing Xu1,2, Shuping Xu1,2,4. 1. State Key Laboratory of Supramolecular Structure and Materials, College of Chemistry, Jilin University, Changchun 130012, P. R. China. 2. Institute of Theoretical Chemistry, College of Chemistry, Jilin University, Changchun 130012, P. R. China. 3. College of Chemical Engineering, Huanggang Normal University, Huanggang, Hubei, 438000, P. R. China. 4. Center for Supramolecular Chemical Biology, College of Chemistry, Jilin University, Changchun 130012, P. R. China.
Abstract
Fluorescent dyes and probes play an indispensable role in bioimaging. The mitochondrion is one of the crucial organelles which takes charge of energy production and is the primary site of aerobic respiration in the cell. To illuminate mitochondria, a series of supramolecular fluorescent imaging probes were developed based on the host-guest assembly of 1,4-bis[2-(4-pyridyl)ethenyl]-benzene (BPEB) derivatives and cucurbituril[6] (CB[6]). These host-guest conjugates can be efficiently internalized into cells due to their water solubility and target mitochondria according to their positive charges. In response to the intracellular microenvironments, these conjugates start dynamic disassembly. The released BPEBs show a highly hydrophobic feature, which can crystallize to form fluorescent solids that illuminate the mitochondria. The intracellular disassembly of the host-guest probes was evidenced by fluorescence lifetime imaging in situ. These smart mitochondrion-targeting fluorescent imaging probes can be available to investigate the structures and functions of mitochondria, which are of great significance in the intracellular dynamic transformation of supramolecular assemblies.
Fluorescent dyes and probes play an indispensable role in bioimaging. The mitochondrion is one of the crucial organelles which takes charge of energy production and is the primary site of aerobic respiration in the cell. To illuminate mitochondria, a series of supramolecular fluorescent imaging probes were developed based on the host-guest assembly of 1,4-bis[2-(4-pyridyl)ethenyl]-benzene (BPEB) derivatives and cucurbituril[6] (CB[6]). These host-guest conjugates can be efficiently internalized into cells due to their water solubility and target mitochondria according to their positive charges. In response to the intracellular microenvironments, these conjugates start dynamic disassembly. The released BPEBs show a highly hydrophobic feature, which can crystallize to form fluorescent solids that illuminate the mitochondria. The intracellular disassembly of the host-guest probes was evidenced by fluorescence lifetime imaging in situ. These smart mitochondrion-targeting fluorescent imaging probes can be available to investigate the structures and functions of mitochondria, which are of great significance in the intracellular dynamic transformation of supramolecular assemblies.
Fluorescent dyes and probes
play an increasingly important role
in the field of biochemistry and bioimaging.[1−5] By proper fluorescent labeling or recognition,[6] real-time fluorescent imaging of specific biomolecules[7,8] and physiological processes[9] can be observed.
The continuous innovation and development of cell biology have put
forward new requirements for fluorescent probes.[1] Probes with cellular region-targeting features are valuable
for studying the functions and morphologies of specific organelles
under fluorescent imaging. To achieve organelle-specific imaging,
the probes usually feature charges or stimulus-responsive properties
to intracellular species, such as reactive oxygen species, metal ions,[10,11] anions,[12,13] biological sulfides,[14,15] specific overexpression proteases[4,13] in cancerous
cells, and cell microenvironments, including viscosity, polarity,
pH, and so forth.[16,17] Within many developed organelle-specific
probes, supramolecular probes have been attractive in recent years
due to their flexible stimulus-responsive characteristics.[12,18] The assembly–disassembly processes of these supramolecular
conjugates have also been applied for targeting drug delivery and
theranostic studies.[19] The mitochondrion
is one of the crucial organelles in cells. It plays many vital roles
in intracellular physiological processes, including energy conversion,
oxidative stress, metabolism, stress responses, cell death, and so
forth.[19−21] Mitochondrion-specific fluorescent probes are various,[22,23] and they can be cataloged by mitochondrial membrane potential (JC-1,
JC-9, TMRE, Rh123, etc.), mitochondrial mass (e.g., nonyl acridine
orange, and MitoTracker series), and mitochondrial reactive oxygen
species (MitoSOX and MitoPY-1).[24−26] In combination with fluorescence
imaging, mitochondrial structures and functions can be explored.[8]1,4-Bis[2-(4-pyridyl)ethenyl]-benzene(BPEB)
has a unique symmetric
structure and contains multiple double bonds. The [2 + 2] photodimerization
reaction can occur between the molecules.[27−30] The pyridine group is a Lewis
base, which can coordinate with a variety of metal ions and can also
form crystals with hydroxyl groups through hydrogen bonding and with
halogen atoms through halogen–nitrogen interaction. BPEB molecules
and their derivatives have attracted much attention due to their unique
structural characteristics of double bonds and pyridine groups and
are widely used in coordination compounds, metal–organic frameworks,
cocrystals, molecular assembly, and other fields.[30]Here, a series of supramolecular host–guest
assembly-based
fluorescent imaging probes, BPEB derivatives (DCn: n = 8, 12, and 16), and cucurbituril[6] (CB[6])
conjugates were developed, for mitochondrion-specific imaging.[31] These DCn-CB[6] conjugates
are positively charged and water-soluble, which assist them in being
highly internalized in mitochondria. Due to the dynamic disassembly
in response to intracellular microenvironments, these probes dissociate
and release hydrophobic BPEB derivatives, forming fluorescence radiative
solids that illuminate mitochondria. The biocompatibility of these
supramolecular mitochondrion-specific probes was assessed. These fluorescent
imaging probes targeting mitochondria based on supramolecular host–guest
assembly and disassembly can be applied to investigate the mitochondrial
functions and structures in mitochondrion-related studies. The novelty
of this study can be summarized in three aspects, (1) a series of
supramolecular host–guest assemblies were achieved, and their
disassembly can light up the mitochondria selectively. (2) The disassembly
of DC8-CB[6] is the intracellular microenvironment-responsive. (3)
The fluorescence imaging of mitochondria was assigned to the crystalline
DC8 with a low dissolubility, and a switch of crystallinity of DC8
under the intracellular condition was achieved.
Experimental Section
Materials
Terephthalaldehyde (A.R.
Aladdin), acetic anhydride (A.R. Beijing Chemical Works), zinc chloride
(A.R. Beijing Chemical Works), 4-methylpyridine (A.R. Aladdin), 1-bromine
octane (A.R. Aladdin), 1-bromododecane (A.R. Aladdin), 1-bromohexadecane
(A.R. Aladdin), glycoluril (A.R. Aladdin), methanal (A.R. Beijing
Chemical Works), hydrochloric acid (A.R. Beijing Chemical Works),
sulfuric acid (A.R. Beijing Chemical Works), acetone, and ethanol
(A.R. Beijing Chemical Works) were obtained.MCF-7 (human breast
cancer cell line), HepG2 (human liver cancer cell carcinoma), and
HeLa (human cervical cancer cell line) were bought from the Shanghai
ATCC cell bank issued with the permission of the Human Research Ethics
Committee of the country for manipulation of human’s cells.
The WST-1 kit, culture media (DMEM), and fetal bovine serum (FBS)
were obtained from JIBCO. Phosphate-buffered-saline solution (PBS,
pH = 7.4) was obtained from Beijing Chemical Reagent Company.
Characterizations
A nuclear magnetic
resonance spectrometer 500 MHz (NMR, Avance III 500, Brucker, Switzerland),
a nuclear magnetic resonance spectrometer 600 MHz (NMR, Avance III
600, Brucker, Switzerland), a differential scanning calorimeter (DSC204,
NETZSCH, Germany), and a high-resolution liquid chromatography–mass
spectrometry system (Agilent1290-micrOTOF Q II, Bruker, Switzerland)
were used. The solid ultraviolet spectra of DCn and
their CB[6] conjugates were collected using a Lambda 950 ultraviolet–visible
near-infrared spectrophotometer (PerkinElmer), and the back base was
barium sulfate. Fluorescence spectroscopy (RF-5301 pc, Shimadzu) was
used to characterize the probes with an excitation light of 473 nm.
We measured the quantum yield of DC8 in solid by the time-correlated
single-photon counting method via a steady/transient fluorescence
spectrometer (Edinburgh Instruments, FLS980) equipped with an integrating
sphere. An inverted fluorescence microscope (IX71, Olympus) with an
imaging charge-coupled device was employed to take the fluorescent
image of DC microcrystals. A ×20, NA = 0.4 lens was employed.
Olympus Fluoview Ver.16b software was used to deal with images, and
the “colocalization” button was used to plot the scatter
graph and calculate Pearson’s correlation coefficient.A Leica STALLARIS 8 scanning confocal microscope equipped with a
white laser (450–790 nm) and a 405 nm laser was employed, and
FALCON and TauSense functions were used for fluorescent lifetime imaging
(FLIM). A ×63 oil lens was used for imaging, and the excitation
wavelength was set as 458 nm. The lifetime was analyzed by fitting
data from the region of interest (ROI).
Synthesis of BPEB Derivatives, CB[6], and
Their Assembles
BPEB was first synthesized following the
literature.[32] Zinc chloride (13.64 g) was
added to a solution containing 13.7 g of 4-methylpyridine and 6.7
g of p-phthalaldehyde in 40 mL of acetic anhydride.
The mixture was heated for 8 h under reflux, cooled to room temperature,
and filtered. The precipitate (yellowish powder) was washed with ethanol
and recrystallized from pyridine.DC8, DC12, and DC16 were synthesized
according to the literature.[30] The synthetic
method of DC8 was as follows. BPEB (2.86 g) and 1-bromooctane (5.79
g) with a molar ratio of 1:3 were mixed in 200 mL of DMF. The remaining
procedures were the same as those for BPEB. DC12 and DC16 were prepared
using the same procedures as DC8, except that 1-bromooctane was replaced
with 1-bromododecane or 1-bromohexadecane. The molar ratio of BPEB
was still kept at 1:3. The coarse products were recrystallized from
ethanol. the 1H NMR, 13C NMR, and MS characterizations
of BPEB and DCn (n = 8, 12, and
16) are provided in our previous publication.[33]Cucurbituril[6] (CB[6]) is synthesized according to the literature.[34] The mixture containing 5.68 g of glycide (40
mmol), 7.0 mL of formaldehyde solution (37% w/w), and 20 mL of sulfuric
acid (9.0 M) was heated at 75 °C for 24 h and then heated at
100 °C for another 12 h. After pouring the mixture into 200 mL
of deionized water, we added 1.0 L of acetone to produce precipitates
thoroughly. The products experienced vacuum extraction, filtration,
and cleaning with a water/acetone 1:4 solution. The obtained products
were transferred to a 500 mL beaker. 300 mL of water/acetone (1:2,
v/v) solution was added, and it was stirred at room temperature for
1 h. CB[6] was obtained by filtration using a vacuum pump. The NMR
and MS characterization of CB[6] are provided in the Supporting Information
(Figures S1 and S2).DC8-CB[6] DC8
was dissolved in DMSO at 1.0 × 10–4 mol/L.
CB[6] was dissolved in H2O at 1.0 × 10–5 mol/L. DC8 and CB[6] were mixed and diluted to a
specific concentration by H2O. The molar ratio (DC8/CB[6])
was 1:4. Different molar ratios of DC8 and CB[6] were also optimized,
as shown in the Supporting Information (Figure S3).
Cellular Toxicity Assessment (WST-1 Assay)
Before the probes were applied for cellular experiments, the cellular
viabilities of MCF-7 cells after they were incubated with different
concentrations of supramolecular probes were tested by the WST-1 assay
[2-(4-iodophenyl)-3-(4-nitrophenyl)-5-(2, 4-disulfophenyl)-2H-tetrazolium, monosodium salt]. The MCF-7 cells were grown
in the Iscove’s modified Dulbecco’s medium (IMDM, Gibco)
supplemented with 4.5 g/L of glucose and sodium pyruvate, 10% v/v
of FBS (Mediatech), and 1% of antimycotic solution (Mediatech). Cell
cultures were maintained at 37 °C in a 5% CO2 humidified
incubator. MCF-7 (human breast cancer cell line) were cultured in
96-well plates for 24 h. The cells were cultured with a fresh culture
medium containing different concentrations (1.0 × 10–5, 1.0 × 10–6, 1.0 × 10–7, 1.0 × 10–8, and 1.0 × 10–9 mol/L) of DC8, DC12, DC16, DC8-CB[6], DC12-CB[6], and DC16-CB[6]
for 20 min. Then, the probes were removed and washed with PBS. Next,
10 μL of the WST-1 solution in 90 μL of the cell culture
medium was added to each well, and the plate was further incubated
for 2 h. Finally, the optical density values at 450 nm were recorded
by a microplate reader (Tecan Sunrise) to calculate cell viability.
The cells without any treatment were used as the control group.
Colocalization Fluorescence Imaging
Cells were seeded on a clean glass slide to grow to the proper density.
They were cultured in the culture plate with 1.0 μM of supramolecular
probes for 15 min. After incubation, the coverslips were cleaned three
times with PBS, each time for 5 min. Then, cells were incubated with
MitoTracker Green for 20 min at room temperature in the dark. After
removing the staining dyes by washing with PBS three times, the cells
were fixed with 4% formaldehyde for 20 min at room temperature and
further cleaned with PBS. The fluorescence images were taken under
a laser scanning confocal microscope (Olympus FV1000). Pearson’s
correlation coefficient was calculated from the whole cell region
by the colocalization function of Olympus Fluoview software (ver.
16b), and the graph indicating the colocation quantification was presented
and overlap indices were provided as well.It should be noted
that we set 543 nm for our probe in colocalization experiments. The
maximum excitation wavelength and emission wavelength of MitoTracker
Green are 490 and 516 nm, respectively. The absorption range of MitoTracker
Green is from 400 to 530 nm. In order to avoid the crosstalk from
MitoTracker Green (λex = 488 nm, λem = 500 nm), λex = 543 nm was selected for DC8 solid,
while λem = 610 nm.
Fluorescence Lifetime Imaging
The
MCF-7 cells were seeded and grown in a glass-bottom dish. Our developed
probe, DC8-CB[6] with a concentration of 1.0 μM, was added and
incubated with cells for 15 min. Then, the cells were washed with
a cell culture medium, and they were measured by FALCON and TauSense
functions of a Leica STALLARIS 8 laser scanning confocal microscope
for FLIM. A ×63 oil lens was used for imaging. λex = 458 nm and λem = 500–600 nm.
Results and Discussion
Characterization of the Host–Guest
Supramolecular Probes
The complex supramolecular probes are
composed of a cucurbituril[6] (CB[6]) as a host and BPEB derivatives[35] as a guest. Three BPEB derivatives by grafting
BPEB with different lengths of chains were synthesized by following
the literature,[30,34,36] denoted DC8, DC12, and DC16 (Scheme ), respectively. DC8 has an octane structure, and it
is a water-carrying molecule. CB[6] has a cavity with an inner diameter
of 0.58 nm and a height of 0.91 nm.[37] It
can be a host for the host–guest assembly through hydrogen
bonding,[38] electrostatic interaction,[39] and other supramolecular interactions.[40,41] Owing to the size limitation, CB[6] can be a nest for the alkyl
chain of the guest molecule, and the guest accommodated in its cavity
is no more than one molecule.[42−45]Figures S1 and S2 show
the 1H NMR and mass spectra of CB[6] we used in this study.
The BPEB derivatives can assemble with CB[6] to produce supramolecular
structures (Scheme ), DC8-CB[6], which improves its water solubility and cellular internalization
as well. The synthesis procedures of the supramolecular host–guest
assemblies are stated in the Supporting Information.[30,34,36] The assembly
of DC8 in CB[6] was characterized by NMR and fluorescence spectra.
Taking DC8 in CB[6] as an example, we first analyzed the 1H NMR spectra of the achieved DC8-CB[6], as shown in Figure . The assignments of 1H NMR spectra of DC8 are shown in Table S1. The chemical shifts (5.5–6.0, 4.0–4.5) belong to
CB[6]. The chemical shifts (0.75–1.5) belong to the alkyl chain
(Ha–Hf), while the chemical shifts (8.76,
8.75) are assigned to the pyridine group Hh. The chemical
shifts (8.21, 8.20) belong to the pyridine group Hi. When
CB[6] was combined with DC8, the chemical shift of DC8 was kept unchanged
(Figure A). The peak
profiles change at Ha–Hf (0.75–1.5),
Hh (8.76, 8.75), and Hi (8.21, 8.20) in Figure B–D. Owing
to the 1H NMR results, CB[6] traps the alkyl chain and
pyridine group of DC8, as presented in Scheme . To further confirm the location of CB[6]
assembled with DC8, a 2D NOESY NMR spectrum of CB[6]-DC8 was recorded
(Figure F). Region
(a) is the effect between CB[6] and the alkyl chain, while region
(b) refers to the effect between CB[6] and the pyridine group. From
this, we can prove that CB[6] nests the alkyl chain and pyridine group
of DC8, as shown in Figure E. Region (c) reflects the effect of the structure of BPEB.
We can deduce that the lumen of CB[6] cannot accommodate two benzenes
because of its limited size.[35,46] Because the number
of dissociative DC8 was large, a ratio of 1:4 of DC8/CB[6] was selected
in the present study. When DC8 was mixed with different concentrations
of CB[6], the fluorescence peak at 472 nm remained unchanged (Figure S3), indicating that the binding of DC8
with CB[6] is not located at the chromophore of BPEB.
Scheme 1
Structures of BPEB, DC8, DC12, and DC16
Schematic diagrams
of the supramolecular
host–guest assembly (DC8-CB[6]), its intracellular disassembly,
and forming fluorescent DC8 solid in mitochondria.
Figure 1
(A) Sections of 1H NMR spectra (500 MHz, acetic acid-d6/D2O = 1:1)
of DC8 and DC8-CB[6]. (B–D) Enlarged ranges
of (A). (E) Diagram of DC8-CB[6]. (F) 2D NOESY NMR spectrum (600 MHz,
acetic acid-d4/D2O = 1:1) of CB[6] and DC8.
(A) Sections of 1H NMR spectra (500 MHz, acetic acid-d6/D2O = 1:1)
of DC8 and DC8-CB[6]. (B–D) Enlarged ranges
of (A). (E) Diagram of DC8-CB[6]. (F) 2D NOESY NMR spectrum (600 MHz,
acetic acid-d4/D2O = 1:1) of CB[6] and DC8.
Structures of BPEB, DC8, DC12, and DC16
Schematic diagrams
of the supramolecular
host–guest assembly (DC8-CB[6]), its intracellular disassembly,
and forming fluorescent DC8 solid in mitochondria.
Crystallization of DC8 and Its Fluorescence
Feature
The crystallization of DC8 and its solid fluorescence
were investigated by changing solvents with different ethanol-to-water
ratios, in which ethanol and water are the excellent and poor solvents
for DC8. With the water ratio increasing, we can observe the microcrystals
produced, exhibiting solid-state photoluminescence (PL). Figure a displays the fluorescence
image of DC8 in ethanol, showing that solid DC8 emitted bright fluorescence.
The fluorescence spectra indicate that the emission band is located
at about 635 nm. For DC8-CB[6], they show relatively weak fluorescence
in this range under the excitation of 473 nm. If 365 nm light was
used for excitation, DC8-CB[6] will emit 472 nm light (Figure S3). We also measured the quantum yield
of the DC8 solid as 4.50%.
Figure 2
(a) Fluorescence image of the DC8 under the
excitation wavelength
of 458 nm. (b) Fluorescence spectra of DC8 solid (in ethanol) and
DC8-CB[6] (in water) under the excitation wavelength of 473 nm. The
concentration is 1.0 μM. The pH value was controlled at 5.3.
(a) Fluorescence image of the DC8 under the
excitation wavelength
of 458 nm. (b) Fluorescence spectra of DC8 solid (in ethanol) and
DC8-CB[6] (in water) under the excitation wavelength of 473 nm. The
concentration is 1.0 μM. The pH value was controlled at 5.3.DC8 is the N-alkyl pyridine salt
of BPEB. Since
alkyl has eight carbons and BPEB is hydrophobic, DC8 has poor water
solubility. DC8 can emit green fluorescence under an excitation light
of 365 nm in a solution state. However, when the solution environment
changes, the aggregation form will appear, and the fluorescence property
of the solid state will be displayed. It emits orange–yellow
fluorescence at 400–500 nm excitation light. In order to change
the solubility of DC8, we assembled it with CB[6]. When the assembly
is swallowed into the mitochondria of the cell, DC8 is released because
the long alkyl chain in the mitochondria is assembled with CB[6].
Due to its hydrophobic nature, DC8 precipitates and the DC8 solid
emits fluorescence at a central wavelength of 600 nm under an excitation
light of 400–500 nm, thus achieving fluorescence imaging of
mitochondria.
Biocomparability of the Probes
To
apply DC8-CB[6] for cellular experiments, its cellular toxicity was
first assessed (Figures S4 and S5). Figure S4 shows the cellular viabilities of MCF-7
cells after they were incubated with different concentrations of DC8(a),
DC12(b), DC16(c), DC8-CB[6](d), DC12-CB[6](e), and DC16-CB[6](f) at
different concentrations for 15 min, assessed by the WST-1 assay.
It can be seen that the cells in 1.0 μM DC8-CB[6] have high
viability (Figure S4d). For higher concentrations
above 1.0 μM, more dead cells will be obtained. We also assessed
the cellular viabilities of MCF-7 cells for individual DC8. As shown
in Figure S4a, the acceptable concentration
of DC8 for MCF-7 cells was 1.0 μM. We also assessed the cell
survival rates of MCF-7 (human breast cancer cell line) and HEK-293T
(human embryonic kidney cell line) cells incubated with DC8-CB[6]
at different concentrations for 24 h (Figure S5). It can be observed that 1.0 μM DC8-CB[6] shows low toxicity
for cancer and normal cells. Thus, we chose the DC8-CB[6] concentration
of 1.0 μM for further cell imaging experiments. This concentration
(1.0 μM) is also a safe dosage for DC12, DC16, DC12-CB[6], and
DC16-CB[6] (Figure S4).
Bioimaging of Mitochondria by the Supramolecular
Probes
The fluorescent images of MCF-7 cells incubated with
DC8-CB[6] (1.0 μM) and individual DC8 (1.0 μM) were obtained
and compared. It can be observed in Figure a that the hydrophobic DC8 tends to form
precipitates in water solutions, which is not conducive to cell internalization
and gives a weak imaging contrast. In the case of using DC8-CB[6],
its water solubility has been improved (Figure b). After internalizing them in cells, the
phospholipid in mitochondria causes them to disassemble. Phospholipids
contain alkyl chains of different lengths, with different binding
constants with CB[6].[6] with a series
of 1-alkyl-3-methylimidazolium ionic liquids in an aqueous system. Chem.—Asian J.. 2010 ">47] The length of the
alkyl chain does not depend linearly on binding constants. Hence,
we guess that the phospholipid may lead DC8-CB[6] to disassembly by
replacing the DC8 from DC8-CB[6]. The released DC8 molecules further
form solid precipitates, which exhibit brighter PL under the excitation
wavelength of 473 nm (458 nm also). Similar phenomena were also observed
for the DC12-CB[6]- and DC16-CB[6]-incubated cells. When DC12 or DC16
was used for imaging, they provided low imaging contrast and showed
gloom (Figure S6). The toxicity of the
compound decreases with the increase of the alkyl chain. Excessively
long alkyl chains cause compounds to be collected, which is not conducive
to cell internalization. The imaging quality can be improved when
DC12-CB[6] and DC16-CB[6] were used instead of DC12 and DC16 (Figure S7).
Figure 3
Bright-field (left), fluorescent (middle),
and merged (right) images
of MCF-7 after they were incubated with DC8 (a) or DC8-CB[6] (b);
λex = 458 nm, λem = 600 nm. The
concentration of DC8 was 1.0 × 10–6 mol/L.
DC8-CB[6] was achieved at a DC8:CB[6] ratio of 1:4.
Bright-field (left), fluorescent (middle),
and merged (right) images
of MCF-7 after they were incubated with DC8 (a) or DC8-CB[6] (b);
λex = 458 nm, λem = 600 nm. The
concentration of DC8 was 1.0 × 10–6 mol/L.
DC8-CB[6] was achieved at a DC8:CB[6] ratio of 1:4.To evidence the disassembly of DC8-CB[6] and the
DC8 solid formation
in cells, we employed the laser scanning confocal fluorescence imaging
(Leica, STELLARIS 8) equipped with a HyD-X detector to evidence the
formation of aggregation form or host–guest assembles by using
the FALCON function, which allows the FLIM (Figure a) and quantitative analysis of lifetime
of our probe. It can be observed in Figure S8 that three different lifetimes 0.348, 0.851, and 4.979 ns (χ2 = 2.627) were fitted from the ROI of the images, which can
be assigned to the DC8 solid, free DC8, and DC8-CB[6], respectively.
Three lifetimes are further proven by TauSense imaging and TauSeparation
function (Figure b). Figure shows the distributions
of three different lifetime components. From the left panel, we can
identify the remaining DC8-CB[6] in the dish after washing, and some
of them adhered to the cell membrane. The middle panel shows the mitochondria
highlighted with the DC8 solid. The right panel presents the DC8 molecules,
which display the longest lifetime (about 5 ns). They exhibited a
distinct spatial distribution compared to the DC8 solid. Owing to
their alkyl chain of DC8, individual DC8 molecules prefer to embed
in the hydrophobic and phospholipid-rich regions, for example, cell
membranes and nuclear membranes. These data indicate our probe DC8-CB[6],
its disassembly, and DC8 solid coexisting in living cells, and three
forms in a cell have different spatial distributions.
Figure 4
FLIM image (a) of MCF-7
cells incubated with DC8-CB[6]; the image
can be fitted as three lifetimes (b) obtained by TauSeparation functions
of Leica STELLERIS 8 confocal microscope.
Figure 5
Three lifetime component distributions (red, green, and
sapphire)
of the DC8-CB[6] incubated MCF-7 cells, obtained by the FALCON function
of Leica STELLERIS 8 confocal microscope. Images from left to right
correspond to DC8-CB[6], DC8 solid, and DC8 molecules, corresponding
to 4.979, 0.348, and 0.851 ns, respectively.
FLIM image (a) of MCF-7
cells incubated with DC8-CB[6]; the image
can be fitted as three lifetimes (b) obtained by TauSeparation functions
of Leica STELLERIS 8 confocal microscope.Three lifetime component distributions (red, green, and
sapphire)
of the DC8-CB[6] incubated MCF-7 cells, obtained by the FALCON function
of Leica STELLERIS 8 confocal microscope. Images from left to right
correspond to DC8-CB[6], DC8 solid, and DC8 molecules, corresponding
to 4.979, 0.348, and 0.851 ns, respectively.The fluorescence colocalization imaging confirmed
the intracellular
locations of DC8-CB[6]. We stained the cells with MitoTracker Green
(mitochondrial green fluorescent probe) for DC8-CB[6] incubated with
MCF-7, and the fluorescence confocal images at two channels were obtained
(Figure A). Under
the excitation light of 543 nm, orange fluorescence derived from DC8
was excited, while the excitation light of 488 nm illuminated the
green fluorescence for the MitoTracker Green (mitochondria locations).
These two channels show a large overlapping extent, and the Pearson
correlation coefficient is calculated as 0.81396, indicating that
most DC8-CB[6] have been internalized in mitochondria and showing
the mitochondrion-targeting feature.[48,49]
Figure 6
(A–C)
Bright-field, laser scanning confocal fluorescence,
merged images, and (D) colocalized scatter diagrams of MCF-7 cells
after they were, respectively, incubated with DC8-CB[6], DC12-CB[6],
and DC16-CB[6] (red channel, λex = 543 nm, λem = 610 nm) and then stained with MitoTracker Green (green
channel, λex = 488 nm and λem =
500 nm), from ROIs. Pearson’s correlation coefficients are
calculated from (D) and marked on the scatter graphs. The overlap
indices are listed on the bottom panel.
(A–C)
Bright-field, laser scanning confocal fluorescence,
merged images, and (D) colocalized scatter diagrams of MCF-7 cells
after they were, respectively, incubated with DC8-CB[6], DC12-CB[6],
and DC16-CB[6] (red channel, λex = 543 nm, λem = 610 nm) and then stained with MitoTracker Green (green
channel, λex = 488 nm and λem =
500 nm), from ROIs. Pearson’s correlation coefficients are
calculated from (D) and marked on the scatter graphs. The overlap
indices are listed on the bottom panel.Also, from the high-magnification images (Figure S9) and the FLIM images (Figure a), we can identify that the illuminated regions are
typical mitochondria. The mitochondrial cristae and their morphology
can be distinguished, indicating the excellent targeting feature of
our probe for mitochondria.Besides DC8-CB[6], the question
of whether DC12-CB[6] and DC16-CB[6]
exhibit a mitochondrion-targeting feature needs to be answered (Figure B,C). The allowed
doses of DC12-CB[6] and DC16-CB[6] for MCF-7 cells were assessed to
be 1.0 μM according to the WST-1 test (Figure S4). The Pearson correlation coefficients of DC12-CB[6] and
DC16-CB[6] toward MitoTracker Green are 0.69789 and 0.43168 (Figure D), respectively.
A decreasing trend in the mitochondrion-targeting feature (from 0.81396
to 0.43168) can be explained by the weakened dissociation ability
with the alkyl chain length. As the length of the alkyl chain increases,
CB[6] tends to locate in the middle of the dipyridium compound, which
causes DCn to dissociate difficultly.[6]uril
and cucurbit[7]uril with a series of bis-pyridinium compounds. J. Inclusion Phenom. Macrocyclic Chem.. 2012 ">44] Moreover, the potential of the series of N-alkyl pyridine bromide salt will decrease with the increase
of the alkyl chain length.[30] Thus, DC8-CB[6]
has a larger Pearson correlation coefficient than those of DC12-CB[6]
and DC16-CB[6]. We also measured the mitochondrion-targeting feature
of DC8-CB[6] in other cell lines, and the results indicate that this
probe is available for enlightening the mitochondria of HepG2 cells
(Figures S10 and S11).
Conclusions
In summary, we developed
several novel supramolecular fluorescent
turn-on probes composed of DCn (n = 8, 12, and 16) and CB[6]. DC8 is hydrophobic and tends to aggregate.
Assembled with CB[6], the supramolecular probe shows increased dispersity
and is conducive to passing through cell membranes, improving cell
internalization. Interestingly, they especially exhibit mitochondrion
targeting due to the positive charges of the disassembled probe. Owing
to the adverse solution for DC8, they will form solid precipitates,
exhibiting strong fluorescence. The supramolecular disassembly and
the solid form of DC8 in cells were evidenced by FLIM analysis. Our
developed supramolecular probes achieve mitochondrion-specific imaging,
and they are available for the investigation of the structures and
functions of mitochondria.
Scheme 1
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6