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Towards cancer cell-specific phototoxic organometallic rhenium(I) complexes.
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Cite this: Dalton Trans., 2014, 43,
4287
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Towards cancer cell-specific phototoxic
organometallic rhenium(I) complexes†
Anna Leonidova,‡a Vanessa Pierroz,‡a,b Riccardo Rubbiani,a Jakob Heier,c
Stefano Ferrarib and Gilles Gasser*a
Over the recent years, several Re(I) organometallic compounds have been shown to be toxic to various
cancer cell lines. However, these compounds lacked sufficient selectivity towards cancer tissues to be
used as novel chemotherapeutic agents. In this study, we probe the potential of two known N,N-bis(quinolinoyl) Re(I) tricarbonyl complex derivatives, namely Re(I) tricarbonyl [N,N-bis(quinolin-2-ylmethyl)amino]-4-butane-1-amine (Re–NH2) and Re(I) tricarbonyl [N,N-bis(quinolin-2-ylmethyl)amino]-5-valeric
acid (Re–COOH), as photodynamic therapy (PDT) photosensitizers. Re–NH2 and Re–COOH proved to be
excellent singlet oxygen generators in a lipophilic environment with quantum yields of about 75%. Furthermore, we envisaged to improve the selectivity of Re–COOH via conjugation to two types of peptides,
namely a nuclear localization signal (NLS) and a derivative of the neuropeptide bombesin, to form
Re–NLS and Re–Bombesin, respectively. Fluorescent microscopy on cervical cancer cells (HeLa) showed
that the conjugation of Re–COOH to NLS significantly enhanced the compound’s accumulation into the
Received 5th July 2013,
Accepted 31st July 2013
DOI: 10.1039/c3dt51817e
www.rsc.org/dalton
cell nucleus and more specifically into its nucleoli. Importantly, in view of PDT applications, the cytotoxicity of the Re complexes and their bioconjugates increased significantly upon light irradiation. In particular, Re–Bombesin was found to be at least 20-fold more toxic after light irradiation. DNA photocleavage studies demonstrated that all compounds damaged DNA via singlet oxygen and, to a minor
extent, superoxide production.
Introduction
Over the last few years, an impressive amount of organometallic compounds has been screened for cytotoxicity to various
cancer cell lines.1–6 Among them, several organometallic
rhenium complexes have been reported to possess an antiproliferative activity comparable to or even exceeding that of
cisplatin.7–13 However, to avoid the severe side-effects afflicting
patients during chemotherapy, high cytotoxicity is not enough
– an improved selectivity towards cancer cells is required.14
One of the possible strategies to overcome this important
problem is to identify a target specific to cancer cells – e.g. an
overexpressed receptor – and to conjugate the active compound to a moiety recognized by that target. Rhenium
a
Institute of Inorganic Chemistry, University of Zurich, Winterthurerstrasse 190, CH
8057 Zurich, Switzerland. E-mail: gilles.gasser@aci.uzh.ch; Fax: +41 44 635 46 03;
Tel: +41 44 635 46 30
b
Institute of Molecular Cancer Research, Winterthurerstrasse 190, CH 8057 Zurich,
Switzerland
c
Laboratory for Functional Polymers, Empa. Swiss Federal Laboratories for Material
Science and Technology, Uberlandstrasse 129, CH 8600 Dübendorf, Switzerland
† Electronic supplementary information (ESI) available. See DOI:
10.1039/c3dt51817e
‡ These authors have contributed equally to the work.
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compounds such as Re(I) tricarbonyl N,N-bis(quinolinoyl)
complex derivatives can easily be coupled to potential targeting vectors, as previously reported by Valliant, Zubieta, Doyle,
Metzler-Nolte and our group.15–23 Due to their long lifetimes,
polarized emission and large Stokes shifts, these organometallic complexes have been initially developed as luminescent
probes24–28 and proven themselves particularly useful to study
the behaviour of bioconjugates in cells. As mentioned earlier,
these probes have been coupled to numerous biologically relevant molecules, such as formyl peptide receptor targeting
peptide,15 biotin,16 glucose,17 β-breaker peptide derivatives,18
folate,19 cell permeation peptides,20 vitamin B12,21 and peptide
nucleic acids.22,23 In addition to their imaging properties,
some of the conjugates have shown therapeutic potential. For
instance, the Re–β-breaker peptides inhibit amyloid plaque formation associated with Alzheimer’s disease.18 The Re–B12
derivative showed only a moderate cytotoxicity to the choriocarcinoma cell line (BeWo),21 but the Re–folate conjugate was
found to be strongly toxic to human multidrug-resistant
ovarian carcinoma (A2780/AD) and Chinese hamster ovary
(CHO) cell lines.19 Of note, the Re(I) complexes used in
these studies also possess a certain anti-proliferative activity
on their own. Importantly, due to the isostructurality of Re(I)
with Tc(I), the 99mTc bioconjugate analogues could be prepared
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in a few of these studies allowing radioimaging to be
performed.15,16,18,29
Another approach to specifically kill cancer cells is to use
an external trigger to select the area where an initially inactive
compound can be activated. A good example of such an
approach is photodynamic therapy (PDT). This medical technique is based on the ability of certain molecules called photosensitizers (PS) to generate highly reactive singlet oxygen (1O2)
upon light irradiation. Although some PS, such as certain
porphyrin derivatives, tend to accumulate more in tumour
tissues,30 other PS often lack selectivity for cancer cells. This
can lead to accumulation of PS in healthy tissues rendering
patients photosensitive, in some cases, up to several weeks
after the end of the treatment.31 Although many Re complexes
are known to be efficient triplet PS,32–35 so far, most of them
have been applied in photocatalysis and, to the best of our
knowledge, the first anti-cancer application of rhenium(I) complexes with light was only recently reported by the group of
Meggers.36 This is very surprising since, given their high
activity as triplet PS in photocatalysis, such compounds should
be excellent 1O2 generators in cells.
In this article, we present the characterization of 1O2 production of two Re(I) organometallic complexes, the preparation
of nuclear and bombesin receptor targeting peptide conjugates
of a Re(I) tricarbonyl N,N-bis(quinolinoyl) complex, as well as
the biological activity to human cancer cells (HeLa) and fibroblasts (MRC-5) of the Re(I) complexes and conjugates thereof.
Results and discussion
Synthesis and characterization
Re(I) tricarbonyl [N,N-bis(quinolin-2-ylmethyl)amino]-4-butane1-amine (Re–NH2) and Re(I) tricarbonyl [N,N-bis(quinolin2-ylmethyl)amino]-5-valeric acid (Re–COOH) complexes (Fig. 1)
were prepared via reductive amination of quinoline-2-carboxyaldehyde with the corresponding amine, followed by
complexation
with
[Re(CO)3Br3][NEt3],
as
previously
reported.19,21 Re–COOH was then successfully coupled to two
different targeting peptides on the solid phase using a similar
experiment described by Metzler-Nolte et al.37,38 to obtain the
bioconjugates Re–NLS and Re–Bombesin, respectively (Fig. 1).
Re–NLS contains a short nuclear localization signal (NLS)
peptide39 in order to bring the Re complex to the nucleus in
close proximity of DNA. Most approved PS localize in other
organelles rather than the nucleus (e.g. membranes, mitochondria, lysosomes, endoplasmic reticulum and Golgi apparatus).40 However, many PS have long been known to damage
DNA upon light irradiation.41,42 The second conjugate,
Re–Bombesin, holds a derivative of the neuropeptide bombesin, known for its excellent in vivo stability and biodistribution.43,44 The purpose of this peptide is to selectively transport
the complex to cancer cells (over healthy cells), as it targets a
receptor overexpressed in certain types of cancer. Both Re–NLS
and Re–Bombesin were purified by preparative reverse phase
HPLC and lyophilized to obtain light-yellow powders. The presence of the two expected bioconjugates was ascertained by HR
ESI-MS and MALDI-TOF (Fig. S8, S10, S12, S13†). Several
charge states, namely at m/z 342.69 [M + 3H]4+, 456.85
[M + 2H]3+ and 684.78 [M + H]2+, were observed by HR ESI-MS
for Re–NLS, as can be expected for such a highly positively
charged peptide conjugate. By contrast, only charge state
929.88 [M + H]2+ was detected for the less charged Re–Bombesin conjugate. Characteristic Re isotopic pattern was present in
both HR ESI-MS and MALDI-TOF spectra. The purity of
Re–NLS and Re–Bombesin was further confirmed by LC-MS
(Fig. S9 and S14†) and elemental analysis.
Singlet oxygen production
In order to assess the phototoxic potential of our Re(I) organometallic complexes, Re–NH2 and Re–COOH were assayed in
water and acetonitrile for 1O2 production using both an indirect method – an N,N-dimethyl-4-nitrosoaniline (RNO)/histidine
test45 – and a direct detection by near-infrared luminescence.46
In the first assay, histidine quenches 1O2 and the resulting
trans-annular peroxide bleaches RNO absorbance at 440 nm
(Fig. S15 and S16†). In acetonitrile, imidazole instead of histidine was used due to the poor solubility of histidine in this
solvent. To verify the indirect method results, direct measurements of characteristic 1O2 near-IR luminescence at 1270 nm
were performed (Fig. S17†). For both methods, 1O2 quantum
yields were then calculated using phenalenone as the
reference.47–49 As can be seen in Table 1, the two methods
yielded similar results. The nature of the solvent strongly
affected the 1O2 quantum yields of the Re complexes. Although
they are mediocre PS in water (quantum yields of about 25%),
these compounds are excellent 1O2 producers in more lipophilic solvents such as acetonitrile with quantum yields of
about 75%. Since cells provide not only polar, but also lipophilic environments, our compounds could prove to be efficient
PS in vitro as well.
Table 1
Singlet oxygen production
Compound
Re–NH2
Re–COOH
Fig. 1
Structures of Re complexes and their derivatives.
4288 | Dalton Trans., 2014, 43, 4287–4294
a
Water
a
Acetonitrile
b
24% , 26%
20%a, 24%b
77%a, 75%b
79%a, 72%b
Measured by the RNO/histidine assay. b Measured by luminescence.
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Intracellular localization
To understand the behaviour of the organometallic complexes
Re–NH2 and Re–COOH and of the bioconjugates Re–NLS and
Re–Bombesin, their cellular localization was evaluated in HeLa
cells. For this purpose, the cells were incubated with the compounds, fixed with formaldehyde and imaged by fluorescence
microscopy. As shown in Fig. 2, Re–NH2 alone is observed
exclusively in the cytoplasm and Re–COOH is homogeneously
distributed throughout the cell. Conjugation to an NLS
peptide greatly enhances Re complex accumulation in the
nucleoli. These subnuclear domains mainly house ribosomal
RNA transcription, processing and assembly, but they have
other important functions, such as cell cycle and mitosis regulation, stress response and assembly of non-ribosomal ribonucleoprotein particles.50 Multifunctional, nucleoli contain
both DNA (mostly ribosomal) and RNA, as well as proteins,
which are either dynamic or immobilized. Re–NLS could potentially interact with one or several of these components. While
NLS sequences have been well characterized, nucleolar localisation signals (NoLS) have been far less defined.51 They do seem
to share structural motifs with NLS, such as the presence of Arg
and Lys residues, and are even sometimes part of NLS.52–54
Hence, it is also possible that the combination of NLS with the
Paper
Re complex is recognized as a NoLS. Of note, a Ru complex
conjugated to an octaarginine peptide with fluorescein has
been found to be mainly localized in nucleoli.55 On the other
hand, some proteins are only captured by nucleoli as part of
the cellular stress response that can be caused by toxins.56
Thus, it cannot be excluded that the compound initially interacts with one of these proteins and is later transported with
them to nucleoli. Overall, given the importance of nucleoli
in proper cell function, the production of singlet oxygen by
Re–NLS should severely affect cell health. Since it has been
reported that the nucleoli localization could sometimes be
observed as an artefact of cell fixation,12 the results were confirmed in living cells (Fig. S22†). Re–Bombesin gave a very
weak luminescence signal and therefore could not be localized. This could either be due to its poor uptake by cells or
the quenching of the fluorescence inside the cell. Indeed, the
luminescence of similar complexes has already been reported
to be quenched by vitamin B12 57 or in living cells.22
Cytotoxicity studies
With this information in hand, we then assessed the cytotoxicity of the Re complexes Re–NH2 and Re–COOH and of
bioconjugates Re–NLS and Re–Bombesin on two different cell
lines, namely the cervical cancer (HeLa) and human fibroblast
(MRC-5) cell lines. As shown in Table 2, Re–NH2 and
Re–COOH alone only affected HeLa and MRC-5 cells at concentrations higher than 100 μM. Conjugation of the bombesin
derivative to Re–COOH did not affect its toxicity to HeLa cells,
but made Re–Bombesin moderately toxic to MRC-5 cells. The
latter have already been reported to be slightly affected by
bombesin derivatives, albeit less than the cancer cells.58 The
difference in Re–Bombesin cytotoxicity to HeLa and MRC-5
could also be due to the fact that the bombesin derivative used
in this study has been optimized on the androgen-independent human prostate cancer (PC-3) cell line.43,44 PC-3 cells
mainly overexpress gastrin-releasing peptide (GRP) receptor of
the bombesin receptor family.59 HeLa, on the other hand,
mostly express bombesin receptor subtype 3 (BRS-3). Although
BRS-3 can interact with the same ligands as GRP receptor, its
affinity for them is lower.59 In any case, the cytotoxicity of our
Re–Bombesin to MRC-5 is lower compared to bombesin-
Table 2 Cytotoxicity to on HeLa and MRC-5 cell lines after 4 h
treatment
Compound
Fig. 2 Fluorescence microscopy images showing HeLa cells fixed after
treatment with: (a) Re–NH2 100 μM 2 h; (b) Re–COOH 2.5 μM 2 h; (c)
Re–NLS 100 μM 1 h; (d) Re–Bombesin 50 μM 2 h.
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NLS
Bombesin
Re–NH2
Re–COOH
Re–NLS
Re–
Bombesin
Cisplatin
a
HeLa dark IC50
(μM)
HeLa UV IC50
(μM)
MRC-5 dark IC50
(μM)
>100a
>100a
187.1 ± 17.9a
>100
35.1 ± 1.8
>100
—
—
17.3 ± 2.9
9.3 ± 2.2
18.3 ± 1.4
5.3 ± 1.0
>100a
>100a
>100a
>100a
17.8 ± 1.8a
44.1 ± 9.9a
9.2 ± 0.6a
—
10.5 ± 2.8a
IC50 after 48 h treatment incubation.
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mitochondria-disrupting peptide derivative.58 Coupling of the
NLS peptide increased dark toxicity of Re–NLS to both HeLa
and MRC-5, probably due to the compound’s interactions with
nucleoli. Of note, both peptides, namely NLS and Bombesin
alone, were found to be non-toxic to cells at concentrations up
to 100 μM. To probe the light toxicity, HeLa cells incubated
with our compounds were irradiated with UVA light (emission
maximum at 350 nm, 2.58 J cm−2). Little changes were
observed for Re–NLS that was already cytotoxic in the dark. All
other compounds became more cytotoxic upon light
irradiation. The most pronounced increase (20-fold) was
observed for the Re–Bombesin derivative that had a cytotoxicity comparable to cisplatin after a 2.58 J cm−2 irradiation
dose – an amount smaller than or comparable to that normally
used for UVA activated compounds, such as certain platinum
complexes.60–65
DNA photo-cleavage
Encouraged by the promising results obtained on cancer cells,
we decided to obtain more insight into the potential mode of
action of our compounds by evaluating the possible damage
induced by Re–NH2, Re–NLS, Re–COOH and Re–Bombesin to
nucleic acids. DNA photo-cleavage experiments were performed on closed circular plasmid DNA ( pcDNA3) as previously reported by Barton et al.66 pcDNA3 was incubated with
various concentrations of our compounds and irradiated for
10 min (2.58 J cm−2) at 350 nm. Upon light irradiation, all
compounds converted the supercoiled DNA form to circular/
nicked forms, albeit at different concentrations (Fig. S18 and
S20†). While Re–NH2, Re–COOH and Re–Bombesin displayed
an effect for high concentration (50 μM–100 μM), Re–NLS, for
instance, already extensively damaged DNA at a concentration
of 5 μM (Fig. 3), 5–10-fold lower than the other compounds.
Such a strong effect is possibly due to its high positive charge
(5+) at physiological pH that allows a stronger interaction of
Re–NLS with the negatively charged DNA backbone. Interestingly though, Re–NLS has the lowest photo-toxicity of all compounds. Further investigation on pcDNA3 treated with Re–NLS
and reactive oxygen species quenchers, namely KI (superoxide:
O2−), NaN3 (1O2) and mannitol (hydroxyl radical: OH•),
revealed a major involvement of 1O2 and, to a lesser extent,
O2− in DNA photo-cleavage (Fig. S19†). DNA incubated with
our compounds in the dark did not show a significant effect
up to the highest concentration used.
Fig. 3 Electrophoresis experiment of DNA photo-cleavage of pcDNA3
plasmid treated with different concentrations of the complex Re–NLS;
+UV = untreated DNA irradiated (lane 1); probes irradiated for
10 minutes at 350 nm (lanes 2–5); −UV = untreated DNA not irradiated
(lane 6); probes not irradiated (lane 7).
4290 | Dalton Trans., 2014, 43, 4287–4294
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Conclusions
In this article, we present one of the first studies on the use of
Re(I) organometallic complexes as photosensitizers for PDT
purposes. We demonstrated that Re(I) tricarbonyl N,N-bis(quinolinoyl) complexes could efficiently produce 1O2 in lipophilic environments and induce DNA damage. Importantly,
the localization or cellular uptake of the organometallic complexes could be controlled by attachment to targeting molecules. Although the irradiation wavelengths used in this study
are not ideal since they only slightly penetrate through the
skin, this work opens new avenues for the search for metalcontaining photosensitizers. Indeed, of the 14 PDT agents
accepted by the FDA, two already contain a metal ion (lutetium
and tin) and another one containing a palladium ion (Tookad)
is in clinical trial phase III.40,67 We believe that the specific
physico-chemical properties of metal complexes and in particular of organometallic complexes will have an important
role to play in this field of research. In addition, since 99mTc
analogues of Re(I) tricarbonyl N,N-bis(quinolinoyl) complexes
can be easily prepared, in vivo imaging studies could be performed, shedding light on important biodistribution data.
Experimental section
Materials
Chemicals and solvents were of reagent grade or better and
were purchased from commercial suppliers. They were used
without further purification unless otherwise specified. The
plasmid pcDNA3 was obtained from Invitrogen.
Instrumentation and methods
1
H and 13C NMR spectra were recorded using Bruker 400 and
500 spectrometers. Elemental microanalyses were obtained on
a LecoCHNS-932 elemental analyser. High-resolution accurate
mass spectra were performed on a Bruker maXis QTOF highresolution mass spectrometer (Bruker Daltonics, Bremen,
Germany). UV spectra were recorded using a Carry 50 Scan
Varian spectrophotometer. ESI-MS and LC-MS spectra were
obtained using a Bruker Daltonics HCT 6000 mass spectrometer. LC-MS spectra were measured using an Acquity™ from
Waters system equipped with a PDA detector and an auto
sampler using an Agilent Zorbax 300SB-C18 analytical column
(3.5 μm particle size, 300 Å pore size, 150 × 4.6 mm). The LC
run (flow rate: 0.5 mL min−1) was performed with a linear gradient of A (double distilled water containing 0.1% v/v formic
acid) and B (acetonitrile containing 0.1% v/v formic acid); t =
0 min, 5% B; t = 3 min, 5% B; t = 17 min, 100% B; t = 20 min,
100% B; t = 25 min, 5% B. HPLC purification was performed
using a Varian ProStar system and an Agilent Zorbax 300
SB-C18 prep column (5 μm particle size, 300 Å pore size, 150 ×
21.1 mm; flow rate: 20 mL min−1). The runs were carried out
with a linear gradient of A (double distilled water containing
0.1% v/v TFA) and B (acetonitrile containing 0.1% v/v TFA,
Sigma-Aldrich HPLC-grade). Preparative runs: t = 0 min, 5% B;
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t = 25 min, 100% B; t = 30 min, 100% B; t = 32 min, 5% B. For
singlet oxygen indirect detection and cell culture irradiation, a
Rayonet RPR-200 photochemical reactor with 6 bulbs (14 W
each) with maximum intensity output at 350 nm was used.
Samples were irradiated in a fluorescence quartz cuvette
(width 1 cm) placed at the centre of the reactor. The light
intensity on that spot measured with an X11 optometer
(Gigahertz-Optik) was 42 W m−2. The temperature inside the
reactor was 30 °C. Singlet oxygen near-IR luminescence was
recorded using a Fluorolog-3 spectrofluorometer (Jobin Yvon
Horiba, model FL3-11) with a 450 W xenon lamp light source
and single-grating excitation and emission spectrometers. To
reach high beam intensity, the excitation slits were set to a
maximum value of 29.4 nm. The emission was recorded at
right angle to the excitation path with an IR-sensitive liquid
nitrogen cooled germanium diode detector (bias −160 V, Edinburgh Instruments, model EI-L). The signal-to-noise ratio of
the Ge-diode was improved with a lock-in amplifier (Stanford
Research Systems, model SR510) referenced to the chopper frequency of 126 Hz. Data-acquisition was done using DataMax.
Paper
Characterization data for Bombesin. ESI-MS m/z 403 [M +
3H]3+, 604 [M + 2H]2+, 1207 [M + H]+. HR ESI-MS found m/z
604.3241, calcd for [C56H86N16O12S] m/z 604.3245. MALDI-TOF
m/z 1207.6 [M + H]+. Anal. Found: C, 50.02; H, 5.99; N, 15.33.
Calc. for [C60H86F6N16O16S]: C, 50.27; H, 6.05; N, 15.63.
Re–NLS and Re–Bombesin
Re–COOH was coupled to NLS or bombesin derivative peptide
by solid-phase synthesis prior to peptide cleavage as described
above. Characterization data for Re–NLS. ESI-MS m/z 342.9
[M + 3H]4+, 456.8 [M + 2H]3+, 684.6 [M + H]2+. HR ESI-MS found
m/z 342.8947, 456.8573, 684.7820, calcd for [C55H79N19O9ReS]
m/z 342.8956, 456.8582, 684.7832. MALDI-TOF m/z 1368.4 [M]+.
Characterization data for Re–Bombesin: ESI-MS m/z 620.3
[M + 2H]3+, 929.8 [M + H]2+. HR ESI-MS found m/z 929.8817,
calcd for [C84H109N19O16ReS] m/z 929.8825. MALDI-TOF m/z
1858.04 [M]+. Anal. Found: C, 49.41; H, 5.09; N, 12.03. Calc. for
[C90H109F9N19O22ReS]: C, 49.17; H, 5.00; N, 12.11.
Singlet oxygen production
Synthesis and characterization
Re–NH2. The complex was synthesised by following a previously published procedure. The analytical data matched
those previously reported.21
Re–COOH. The complex was synthesised by following a previously published procedure. The analytical data matched
those previously reported.19
Peptide synthesis
The peptide synthesis was performed similarly to a procedure
reported by Metzler-Nolte.37 More specifically, the peptides
with C-terminal amide were prepared manually in one-way
polypropylene syringes (5 or 10 mL) equipped with a frit using
a standard solid-phase peptide synthesis procedure. All reactions were carried out using a mechanical shaker. Polystyrene
resin beads of TentaGel S RAM Lys(Boc)Fmoc (capacity
0.23 mmol g−1) or TentaGel S RAM (capacity 0.24 mmol g−1)
were swollen in DMF for 1 hour before use. The resin was
deprotected with piperidine (20% v/v in DMF) for 2 + 10 min.
The resin was then washed with DMF (5×), DCM (5×), and
DMF (5×). A Fmoc-protected amino acid was first pre-activated
(4.5 equiv. amino acid, 4 equiv. TBTU, 8 equiv. DIPEA in DMF)
for 2 min and then reacted with the resin for 30 min. Afterwards, the resin beads were washed with DMF (5×) and DCM
(5×), and a Kaiser test was performed to check if the coupling
was complete. Prior to cleavage, the resin was shrunk
in methanol and dried. The peptides were cleaved using a
mixture of trifluoroacetic acid–water–triisopropylsilane,
38 : 1 : 1 v/v/v (3 × 1 mL, for 1.5 h each). The collected solutions
were combined and dried and the crude peptides were precipitated with cold ether. They were then purified by preparative
HPLC.
Characterization data for NLS. ESI-MS m/z 359.2 [M + 2H]2+,
717.4 [M + H]+.
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N,N-Dimethyl-4-nitrosoaniline/histidine assay. The singlet
oxygen production was measured by the N,N-dimethyl-4-nitrosoaniline/histidine assay based on the oxidation of histidine
by singlet oxygen and the subsequent reaction of the oxidised
histidine with N,N-dimethyl-4-nitrosoaniline as previously
described.45,68 The absorbance of the compound was adjusted
to approximately 0.2 at the irradiation wavelength. In practice,
20 mM DMSO stock solution of compound to measure were
diluted in 4 mL PBS solution ( pH 7.4) containing N,Ndimethyl-4-nitrosoaniline (25 μM) and histidine (0.01 M) and
irradiated in fluorescence quartz cuvettes (width 1 cm). Bleaching of N,N-dimethyl-4-nitrosoaniline was followed by monitoring of the absorption at 440 nm. Negative control experiments
were run by repeating the measurements in the absence of histidine. The same conditions were also used for singlet oxygen
detection in acetonitrile, except that imidazole was used
instead of histidine due to the low solubility of histidine in
this solvent. In addition, the absorbance peak of N,Ndimethyl-4-nitrosoaniline shifts to 415 nm in acetonitrile. The
absorbance at 440/415 nm was then plotted as a function of
irradiation time and the quantum yields of singlet oxygen
formation (Φsample) were calculated using phenalenone as the
standard (Φreference) with the following formula:
Φsample ¼ Φreference
Ssample I reference
Sreference I sample
where S is the slope of the absorbance vs. irradiation time and
I is the rate of light absorption calculated as the overlap of the
lamp emission spectra and the absorption spectra of the compound according to the following formula:
ð
I ¼ I 0 ½1 � 10�AðλÞ �dλ
λ
where I0 is the light-flux intensity of the lamp and A is the
absorbance of the compound.
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Near-infrared luminescence
Cytotoxicity studies
A 20 mM stock solution in DMSO of the compound to
measure was diluted in D2O or acetonitrile to reach
approximately 0.2 absorbance at the irradiation wavelength.
This solution was then irradiated in fluorescence quartz cuvettes (width 1 cm) using a UV lamp (350 nm, slit 29.4 nm).
Singlet oxygen near-IR luminescence at 1271 nm was
measured by recording spectra from 1200 to 1350 nm (emission slit 5 nm, detector sensitivity 100, integration 3 (1)). The
intensity of irradiation was varied via neutral density filters.
Singlet oxygen luminescence peaks at different irradiation
intensities were integrated and the resulting areas were plotted
vs. irradiation intensities. The quantum yields were then calculated by applying the same formulas as those for the N,Ndimethyl-4-nitrosoaniline/histidine assay.
The cytotoxicity of the rhenium complexes and their bioconjugates non-UV-irradiated or UV-irradiated to HeLa cells was
measured by a fluorometric cell viability assay using Resazurin
(Promocell GmbH). Cells were seeded in triplicates in 96-well
plates at a density of 4 × 103 cells per well in 100 μL 24 h prior
to treatment. To assess the cytotoxicity, cells were treated with
increasing concentrations of compounds for 48 h. For phototoxicity studies, cells were treated with increasing concentrations of the compounds for 4 h only. After that, the medium
was removed and replaced by complete medium prior to
10 min UV-A irradiation (30 kJ m−2). Cells were then returned
to the incubator for 48 h. After incubation, the medium was
replaced by 100 μL complete medium containing resazurin
(0.2 mg mL−1 final concentration). Upon 4 h of incubation at
37 °C, the fluorescence of the highly red fluorescent resorufin
product was quantified at 590 nm emission with 540 nm excitation wavelength using a SpectraMax M5 microplate reader.
DNA photo-cleavage
The DNA photo-cleavage effect provoked by complexes Re–NH2,
Re–NLS, Re–COOH and Re–Bombesin was investigated by
electrophoresis. Supercoiled pcDNA3 plasmid (0.10 μg) was
treated with increasing concentrations of the rhenium compound in a buffer (50 mM Tris/HCl, 18 mM NaCl, pH 7.2),
incubated 20 minutes at 25 °C and irradiated at 350 nm for
10 minutes (Rayonet Chamber Reactor Complex, 2.58 J cm−2).
Moreover, a further series of positive controls of pcDNA3
plasmid treated with 2 in the presence of mannitol (15 mM, to
quench •OH), NaN3 (15 mM, to quench 1O2) and KI (15 mM, to
quench O2−) was also performed (see Fig. S19†). A series of
negative controls of the plasmid treated with different concentrations of Re–NH2, Re–NLS, Re–COOH and Re–Bombesin in
the dark was used for comparative purposes. The cleavage of
the target plasmid not photo-mediated was also studied at
different incubation temperatures and in the presence of the
restriction enzyme BstXI (1 h incubation at 37 °C) which linearized pcDNA3 (see Fig. S20†). Upon irradiation, loading
buffer (2.5% Bromophenol Blue, 1% SDS, 0.1 M EDTA, 20%
Ficoll 400 in 100 mL of H2O) was added to samples and they
were analyzed by electrophoresis in 0.8% agarose in TBE 1×
(diluted from a 10× solution of 108 g of Tris/HCl, and 55 g of
H3BO3 in 900 mL of H2O) at 70 V (BioRad Powerpack 1000,
BioRad) for 2 h. The gel was prestained with 0.5 μg mL−1
ethidium bromide, photographed and worked out with an
AlphaDigiDoc 1000 CCD camera (Buchner Biotec AG) and
AlphaImager software.
Cell culture
Human cervical carcinoma cells (HeLa) were cultured in DMEM
(Gibco) with 5% fetal calf serum (FCS, Gibco), 100 U mL−1
penicillin, and 100 μg mL−1 streptomycin at 37 °C and 5%
CO2. Normal lung fibroblasts (MRC-5) were maintained in
F-10 medium (Gibco) supplemented with 10% fetal calf serum
(FCS, Gibco), 100 U mL−1 penicillin, and 100 μg mL−1 streptomycin at 37 °C and 5% CO2.
4292 | Dalton Trans., 2014, 43, 4287–4294
In vitro fluorescence evaluation
Cellular localization of the luminescent rhenium complexes
and bioconjugates was assessed by fluorescence microscopy.
HeLa cells were grown on 18 mm Menzel-Glaser coverslips in
2 mL complete medium at a density of 1 × 105 cells per mL
and incubated for 1 or 2 h with Rhenium complexes at their
IC50 or at 100 μM for nontoxic complexes. Cells were fixed in a
4% formaldehyde solution in PBS and mounted on slides
for viewing by confocal microscopy using a CLSM Leica
SP5 microscope. The rhenium complexes were excited at
405 nm and the emission above 420 nm was recorded. For
living cell imaging, cells were grown on 35 mm Cellview glass
bottom dishes (Greiner), washed and kept in 1× PBS prior to
imaging using an Olympus IX 81 motorized inverted microscope (Olympus, Hamburg, Germany) equipped with a 60× oilimmersion lens and a digital camera. The Rhenium complex
was visualized using the Cy3 filter set of the Olympus microscope (ex., 550 nm; em., 570 nm).
Acknowledgements
This work was supported by the Swiss National Science
Foundation ( professorship no. PP00P2_133568 and research
grant no. 200021_129910 to G.G.), the University of Zurich
(G.G. and S.F.), the Stiftung für Wissenschaftliche Forschung
of the University of Zurich (G.G. and S.F.), the Novartis Jubilee
Foundation (G.G. and R.R.), the Stiftung zur Krebsbekämpfung
(S.F.), the Huggenberger-Bischoff Stiftung (S.F.) and the
University of Zurich Priority Program (S.F.).
Notes and references
1 G. Gasser, I. Ott and N. Metzler-Nolte, J. Med. Chem., 2010,
54, 3–25 and references therein.
This journal is © The Royal Society of Chemistry 2014
�View Article Online
Open Access Article. Published on 01 August 2013. Downloaded on 5/2/2026 3:00:31 AM.
This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence.
Dalton Transactions
2 C. G. Hartinger, N. Metzler-Nolte and P. J. Dyson,
Organometallics, 2012, 31, 5677–5685 and references
therein.
3 P. C. A. Bruijincx and P. J. Sadler, Curr. Opin. Chem. Biol.,
2008, 12, 197–206 and references therein.
4 G. Gasser and N. Metzler-Nolte, Curr. Opin. Chem. Biol.,
2012, 16, 84–91 and references therein.
5 C. G. Hartinger and P. J. Dyson, Chem. Soc. Rev., 2009, 38,
391–401 and references therein.
6 G. Jaouen and N. Metzler-Nolte, Medicinal Organometallic
Chemistry, Springer-Verlag, 2010.
7 J. Zhang, J. J. Vittal, W. Henderson, J. R. Wheaton,
I. H. Hall, T. S. A. Hor and Y. K. Yan, J. Organomet. Chem.,
2002, 650, 123–132.
8 W. Wang, Y. K. Yan, T. S. A. Hor, J. J. Vittal, J. R. Wheaton
and I. H. Hall, Polyhedron, 2002, 21, 1991–1999.
9 M. D. Bartholoma, A. R. Vortherms, S. Hillier, B. Ploier,
J. Joyal, J. Babich, R. P. Doyle and J. Zubieta, ChemMedChem, 2010, 5, 1513–1529.
10 D. Can, H. W. Peindy N’Dongo, B. Spingler, P. Schmutz,
P. Raposinho, I. Santos and R. Alberto, Chem. Biodiversity,
2012, 9, 1849–1866.
11 A. W.-T. Choi, M.-W. Louie, S. P.-Y. Li, H.-W. Liu,
B. T.-N. Chan, T. C.-Y. Lam, A. C.-C. Lin, S.-H. Cheng and
K. K.-W. Lo, Inorg. Chem., 2012, 51, 13289–13302.
12 M.-W. Louie, A. W.-T. Choi, H.-W. Liu, B. T.-N. Chan and
K. K.-W. Lo, Organometallics, 2012, 31, 5844–5855.
13 J. Ho, W. Y. Lee, K. J. T. Koh, P. P. F. Lee and Y.-K. Yan,
J. Inorg. Biochem., 2013, 119, 10–20.
14 S. Dhar and S. J. Lippard, in Bioinorganic Medicinal
Chemistry, ed. E. Alessio, Wiley-VCH Verlag GmbH & Co.
KGaA, Weinheim, 2011, pp. 79–95.
15 K. A. Stephenson, S. R. Banerjee, T. Besanger,
O. O. Sogbein, M. K. Levadala, N. McFarlane, J. A. Lemon,
D. R. Boreham, K. P. Maresca, J. D. Brennan, J. W. Babich,
J. Zubieta and J. F. Valliant, J. Am. Chem. Soc., 2004, 126,
8598–8599.
16 S. James, K. P. Maresca, J. W. Babich, J. F. Valliant,
L. Doering and J. Zubieta, Bioconjugate Chem., 2006, 17,
590–596.
17 S. R. Banerjee, J. W. Babich and J. Zubieta, Inorg. Chim.
Acta, 2006, 359, 1603–1612.
18 K. A. Stephenson, L. C. Reid, J. Zubieta, J. W. Babich,
M.-P. Kung, H. F. Kung and J. F. Valliant, Bioconjugate
Chem., 2008, 19, 1087–1094.
19 N. Viola-Villegas, A. E. Rabideau, J. Cesnavicious, J. Zubieta
and R. P. Doyle, ChemMedChem, 2008, 3, 1387–1394.
20 P. Schaffer, J. A. Gleave, J. A. Lemon, L. C. Reid,
L. K. K. Pacey, T. H. Farncombe, D. R. Boreham, J. Zubieta,
J. W. Babich, L. C. Doering and J. F. Valliant, Nucl. Med.
Biol., 2008, 35, 159–169.
21 N. Viola-Villegas, A. E. Rabideau, M. Bartholoma, J. Zubieta
and R. P. Doyle, J. Med. Chem., 2009, 52, 5253–5261.
22 G. Gasser, A. Pinto, S. Neumann, A. M. Sosniak, M. Seitz,
K. Merz, R. Heumann and N. Metzler-Nolte, Dalton Trans.,
2012, 41, 2304–2313.
This journal is © The Royal Society of Chemistry 2014
Paper
23 G. Gasser, S. Neumann, I. Ott, M. Seitz, R. Heumann
and N. Metzler-Nolte, Eur. J. Inorg. Chem., 2011, 36,
5471–5478.
24 A. J. Amoroso, M. P. Coogan, J. E. Dunne, V. FernandezMoreira, J. B. Hess, A. J. Hayes, D. Lloyd, C. Millet,
S. J. A. Pope and C. Williams, Chem. Commun., 2007, 3066–
3068.
25 K. K.-W. Lo, K. Y. Zhang and S. P.-Y. Li, Eur. J. Inorg. Chem.,
2011, 3551–3568.
26 K. K.-W. Lo, A. W.-T. Choi and W. H.-T. Law, Dalton Trans.,
2012, 41, 6021–6047.
27 M. Patra and G. Gasser, ChemBioChem, 2012, 13, 1232–
1252 and references therein.
28 F. L. Thorp-Greenwood, R. G. Balasingham and
M. P. Coogan, J. Organomet. Chem., 2012, 714, 12–21.
29 S. R. Banerjee, P. Schaffer, J. W. Babich, J. F. Valliant and
J. Zubieta, Dalton Trans., 2005, 3886–3897.
30 J. P. Celli, B. Q. Spring, I. Rizvi, C. L. Evans, K. S. Samkoe,
S. Verma, B. W. Pogue and T. Hasan, Chem. Rev., 2010, 110,
2795–2838 and references therein.
31 A. E. O’Connor, W. M. Gallagher and A. T. Byrne, Photochem. Photobiol., 2009, 85, 1053–1074.
32 Y. Gao, S. Sun and K. Han, Spectrochim. Acta, Part A, 2009,
71, 2016–2022.
33 J. Liu and W. Jiang, Dalton Trans., 2012, 41, 9700–
9707.
34 Y. Zhao, G. M. Roberts, S. E. Greenough, N. J. Farrer,
M. J. Paterson, W. H. Powell, V. G. Stavros and P. J. Sadler,
Angew. Chem., Int. Ed., 2012, 51, 11263–11266.
35 A. A. Abdel-Shafi, J. L. Bourdelandeb and S. S. Ali, Dalton
Trans., 2007, 2510–2516.
36 A. Kastl, S. Dieckmann, K. Wähler, T. Völker, L. Kastl,
A. L. Merkel, A. Vultur, B. Shannan, K. Harms, M. Ocker,
W. J. Parak, M. Herlyn and E. Meggers, ChemMedChem,
2013, 8, 924–927.
37 L. Raszeja, A. Maghnouj, S. Hahn and N. Metzler-Nolte,
ChemBioChem, 2011, 12, 371–376.
38 A cysteine amino acid was added to the N-terminus of the
peptide to allow further coupling with different biomolecules. This work will be reported in due course.
Importantly, no S–S bridge formation was observed by
LC-MS in this study.
39 D. Kalderon, B. L. Kalderon, W. Roberts, A. Richardson and
D. Smith, Cell, 1984, 39, 499–509.
40 R. R. Allison and K. Moghissi, Photodiagn. Photodyn. Ther.,
2013, DOI: 10.1016/j.pdpdt.2013.1003.1011 and references
therein.
41 R. J. Fiel, N. Datta-Gupta, E. H. Mark and J. C. Howard,
Cancer Res., 1981, 41, 3543–3545.
42 J. Cadet, M. Berger, C. Decarroz, J. R. Wagner, J. E. van
Lier, Y. M. Ginot and P. Vigny, Biochimie, 1986, 68, 813–
834.
43 E. Garcìa Garayoa, D. Rüegg, P. Bläuenstein, M. Zwimpfer,
I. U. Khan, V. Maes, A. Blanc, A. G. Beck-Sickinger,
D. A. Tourwé and P. A. Schubiger, Nucl. Med. Biol., 2007,
34, 17–28.
Dalton Trans., 2014, 43, 4287–4294 | 4293
�View Article Online
Open Access Article. Published on 01 August 2013. Downloaded on 5/2/2026 3:00:31 AM.
This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence.
Paper
44 E. Garcia Garayoa, C. Schweinsberg, V. Maes, D. Rüegg,
A. Blanc, P. Bläuenstein, D. A. Tourwé, A. G. Beck-Sickinger
and P. A. Schubiger, J. Nucl. Med. Mol. Imaging, 2007, 51,
42–50.
45 I. Kraljić and S. E. Mohsni, Photochem. Photobiol., 1978, 28,
577–581.
46 A. A. Krasnovsky Jr., Membr. Cell. Biol., 1998, 12, 665–
690.
47 E. Oliveros, P. Suardi Murasecco, T. Aminian-Saghafi,
A. M. Braun and H.-J. Hansen, Helv. Chim. Acta, 1991, 74,
79–90.
48 S. Nonell, Afinidad, 1993, 50, 445–448.
49 C. Marti, O. Jürgens, O. Cuenca, M. Casals and S. Nonell,
J. Photochem. Photobiol., A, 1996, 97, 11–18.
50 F.-M. Boisvert, J. van Koningsbruggen, A. Navascués and
A. Lamond, Nat. Rev. Mol. Cell Biol., 2007, 8, 574–585 and
references therein.
51 E. Emmott and J. A. Hiscox, EMBO Rep., 2009, 10, 231–238
and references therein.
52 Z. Sheng, J. A. Lewis and W. J. Chirico, J. Biol. Chem., 2004,
279, 40153–40160.
53 J. Boyne and A. Whitehouse, Proc. Natl. Acad. Sci. U. S. A.,
2006, 103, 15190–15195.
54 M. A. Hahn and D. J. Marsh, FEBS Lett., 2007, 581, 5070–
5074.
55 C. A. Puckett and J. K. Barton, J. Am. Chem. Soc., 2009, 131,
8738–8739.
56 S. Boulon, B. J. Westman, S. Hutten, F. M. Boisvert and
A. I. Lamond, Mol. Cell, 2010, 40, 216–227 and references
therein.
4294 | Dalton Trans., 2014, 43, 4287–4294
Dalton Transactions
57 A. R. Vortherms, A. R. Kahkoska, A. E. Rabideau, J. Zubieta,
L. L. Andersen, M. Madsen and R. P. Doyle, Chem.
Commun., 2011, 47, 9792–9794.
58 H. Yang, H. Cai, L. Wan, S. Liu, S. Li, J. Cheng and X. Lu,
PLoS One, 2013, 8, e57358.
59 R. T. Jensen, J. F. Battey, E. R. Spindel and R. V. Benya,
Pharmacol. Rev., 2008, 60, 1–60 and references therein.
60 P. Bednarski, R. Bednarski, M. Grünert, A. Zielzki,
F. Wellner, P. Mackay and P. Sadler, Chem. Biol., 2006, 13,
61–67.
61 P. Heringova, J. Woods, F. S. Mackay, J. Kasparkova,
P. J. Sadler and V. Brabec, J. Med. Chem., 2006, 49, 7792–
7798.
62 N. J. Farrer, J. A. Woods, L. Salassa, Y. Zhao,
K. S. Robinson, G. Clarkson, F. S. Mackay and P. J. Sadler,
Angew. Chem., Int. Ed., 2010, 49, 8905–8908.
63 K. L. Ciesienski, L. M. Hyman, D. T. Yang, K. L. Haas,
M. G. Dickens, R. J. Holbrook and K. J. Franz, Eur. J. Inorg.
Chem., 2010, 2010, 2224–2228.
64 J. Mlcouskova, J. Stepankova and V. Brabec, J. Biol. Inorg.
Chem., 2012, 17, 891–898.
65 J. S. Butler, J. A. Woods, N. J. Farrer, M. E. Newton
and P. J. Sadler, J. Am. Chem. Soc., 2012, 134, 16508–16511.
66 J. K. Barton and A. L. Raphael, J. Am. Chem. Soc., 1984, 106,
2466–2468.
67 D. E. J. G. J. Dolmans, D. Fukumura and R. K. Jain, Nat.
Rev. Cancer, 2003, 3, 380–387 and references therein.
68 I. E. Kochevar and R. W. Redmond, in Methods in Enzymology, ed. L. Packer and H. Sies, Academic Press, 2000,
vol. 319, ch. 2, pp. 20–28.
This journal is © The Royal Society of Chemistry 2014
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