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Organometallic anticancer complexes of lapachol: metal centre-dependent formation of reactive oxygen species and correlation with cytotoxicity.
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COMMUNICATION
Cite this: Chem. Commun., 2013,
49, 3348
Received 18th January 2013,
Accepted 6th March 2013
DOI: 10.1039/c3cc40432c
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Organometallic anticancer complexes of lapachol:
metal centre-dependent formation of reactive oxygen
species and correlation with cytotoxicity†
Wolfgang Kandioller,*ab Evelyn Balsano,a Samuel M. Meier,ab Ute Jungwirth,bc
Simone Göschl,a Alexander Roller,a Michael A. Jakupec,ab Walter Berger,bc
Bernhard K. Kepplerab and Christian G. Hartinger*d
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Organometallic RuII, OsII and RhIII complexes of lapachol induce
apoptosis in human tumour cell lines in the low lM range by a
mode of action involving oxidative stress, especially in the case of
the ruthenium compound.
Multi-targeted drugs are molecules whose different components
impact multiple separate biotargets.1 In cancer chemotherapy this
approach provides a means of overcoming major disadvantages of
currently applied drugs by influencing pharmacological properties,
metabolism and resistance development, enabling tuneable antitumour activity, ‘‘intramolecular combination therapy’’, and introduction of more selective targeted properties.1 One approach to
multi-targeted compounds is the combination of anticancer metal
complexes with bioactive ligands, as reported for ethacrynic acid,
flavonol derivatives and other compound classes.2–4 Lapachol
(2-hydroxy-3-(3-methylbut-2-en-1-yl)naphthalene-1,4-dione) and
flavonols share with hydroxypyr(id)ones used in medicinal
chemistry the same 5-membered ring coordination motif of
O,O-bidentate anionic ligands.5 Furthermore, lapachol has antibiotic
and anticancer properties and was investigated in clinical trials as an
anticancer agent.6,7 Its mode of action is supposed to be related to
the generation of reactive oxygen species (ROS), which harm DNA
and subsequently induce apoptosis, and biologically active Bi and
Sb complexes were reported recently.8,9 Active organometallic
a
University of Vienna, Institute of Inorganic Chemistry, Währinger Str. 42,
1090 Vienna, Austria. E-mail: wolfgang.kandioller@univie.ac.at;
Fax: +43 1 4277 9526; Tel: +43 1 4277 52609
b
University of Vienna, Research Platform ‘‘Translational Cancer Therapy Research’’,
Währinger Str. 42, A-1090 Vienna, Austria
c
Medical University Vienna, Institute of Cancer Research and Comprehensive
Cancer Center, Department of Medicine I, A-1090, Borschkegasse 8a, Vienna,
Austria
d
The University of Auckland, School of Chemical Sciences, Private Bag 92019,
Auckland 1142, New Zealand. E-mail: c.hartinger@auckland.ac.nz;
Tel: +64 9 373 7955 ext. 83220
† Electronic supplementary information (ESI) available: Synthetic procedures,
X-ray diffraction data, experimental procedures to mass spectrometry and biological investigations. CCDC 918728 and 918729. For ESI and crystallographic
data in CIF or other electronic format see DOI: 10.1039/c3cc40432c
3348
Chem. Commun., 2013, 49, 3348--3350
RuII(arene) complexes have clearly emerged as highly promising
candidates to overcome the disadvantages of clinically-used
platinum drugs.10 The RAPTA family and ethylenediamine complexes are the most prominent representatives of this compound
class and are at an advanced preclinical development stage.11
Therefore, the combination of bioactive lapachol with an organometallic moiety is a promising strategy, with the metal centre
altering the chemical and biological properties of the ligand.
The organometallic complexes 1a–c were synthesised by deprotonating commercially available lapachol L with NaOMe followed
by conversion with the respective dimer [MCl2(arene)]2 (M = RuII
1a, OsII 1b, RhIII 1c; arene = Z6-p-cymene for RuII, OsII and
Z5-pentamethylcyclopentadiene for RhIII) to the corresponding
organometallics 1a–c in good to excellent yields (75–96%). The
complexes were characterised by NMR, ESI-MS and elemental
analysis, confirming the proposed structure of the compounds. In
addition, single crystals of 1a and 1b suitable for X-ray diffraction
analysis (Table S1, ESI†) were obtained from dichloromethane/
n-hexane by using the slow diffusion method. Complexes 1a and
1b crystallise in the monoclinic space group P21/n and adopt the
pseudo-octahedral ‘‘piano-stool’’ configuration (Fig. 1,‡), which is
typical for this class of organometallic compounds. Lapachol acts as
an anionic bidentate O,O-chelating ligand leading to the formation
of a five-membered, non-planar ring with envelope conformation.
The M–O2 distances were slightly shorter (2.0764(10) Å for 1a,
2.077(2) Å for 1b) than the corresponding M–O1 bond lengths
(2.1072(11) Å for 1a, 2.128(2) Å for 1b), which is in good agreement
with data obtained for related organometallic complexes.
The coordination of the keto group to the metal centre
induces an elongation of the C–O bond length of the coordinated carbonyl group (1.259(4) Å for 1b) as compared to the
uncoordinated carbonyl in para-position (1.240(4) Å for 1b),
which confirms the [1,4]-dioxo form of the attached ligand.
The aqueous chemistry of the lapachol-containing organometallics 1a–c was studied by ESI-IT-MS (Scheme 1). In all cases,
aquation gave the respective aqua complexes (2a–c; Scheme 1),
accompanied by ligand release and resulting in the formation of
chlorido-bridged (2c) or hydroxido-bridged (2a, 2b) dimers.
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Fig. 1 Molecular structure of the MII(Z6-p-cymene) complexes 1a (M = Ru) and
1b (M = Os) drawn at 50% probability level. The hydrogen atoms were omitted
for clarity.
Fig. 2 Ultra-high resolution ESI-TOF mass spectra of 2 : 1 reaction mixtures
containing 1a (A), 1b (B) or 1c (C) and after 24 h (left). ISCID top-down signals of
the respective mono-adduct revealed Met1 as the primary metallation site (right).
Scheme 1 Synthesis of the organometallic lapachol (L) complexes 1a–c and their
subsequent aquation to the aqua complexes 2a–c: (i) NaOMe, [MCl2(arene)]2
(a M = RuII, b M = OsII, arene = Z6-p-cymene; c M = RhIII; arene =
Z5-pentamethylcyclopentadiene).
The extent of ligand release followed the order 2c o 2a o 2b,
i.e. compound 2c is largely stable for at least 24 h, while ligand
release was most pronounced for 2b as determined by analysis of
relative abundances of ions in mass spectra (see Fig. S1, ESI†).
The reactivity of metal complexes towards biomolecules is a
crucial parameter for their biological activity. Therefore, 1a–c were
exposed to a mixture containing the DNA model 9-ethylguanine
(EtG) and the amino acids glycine (Gly), L-cysteine (Cys), L-histidine
(His) and L-methionine (Met). EtG adducts were only transiently
formed during the first hour and were only observed for 1a and 1b,
while Gly adducts were not detected. Compounds 1a–c formed
structurally similar products, i.e., His and mainly Met adducts
detected as [M(aa) H]+ ions (M = (Cp*)Rh, (cym)Ru or (cym)Os;
aa = His or Met). Interestingly, different reaction pathways were
observed for 1a–c. 1c transiently formed Cys adducts, which
disappeared again after 24 h. A two-step binding process of amino
acids was detected involving initial mono-dentate coordination of
an amino acid which induces the labilisation of the O,O-chelate
and leads ultimately to cleavage of lapachol. In contrast to 1c, 1a
directly formed His and Met adducts and no other adducts were
detected. For 1b, Cys adducts are stable for more than 24 h and
were observed besides His and Met adducts (Table S2, ESI†). The
extent of His or Met adduct formation seems to be pH dependent
(Fig. S2, ESI†), which is of relevance in certain slightly more acidic
solid tumours due to hypoxia or upregulated glycolysis.12 In such
an environment, the organometallic RhIII, RuII and OsII compounds seem to favour thioether over imine binding. In addition,
the reactivity of 1a–c toward the model protein ubiquitin (ub) was
investigated using ESI-TOF-MS. Incubation of 1a–c with ub (2 : 1)
for 24 h yielded primarily monoadducts accompanied by lapachol
release from the metal centre (Fig. 2; Table S3, ESI†). These
monoadducts were then subjected to in-source collision-induced
dissociation (ISCID), in order to obtain information on the binding
This journal is c The Royal Society of Chemistry 2013
site of the metal ion on the protein. Detection of Ru(cym)A1 and
B1 fragments suggest Met1 as the primary binding site for
2a and 2b, as did the fragment (Cp*)RhB3 for 2c (Table S4, ESI†).
To the best of our knowledge, this is the first report on binding
site determination of a Rh-metallodrug on a protein in a topdown approach.
The cytotoxicity of the organometallic complexes 1a–c was determined by means of the colorimetric MTT assay in the human cancer
cell lines CH1 (ovarian carcinoma), SW480 (colon carcinoma), A549
(non-small cell lung carcinoma), HCT-116 (colon carcinoma) and
HL60 (acute promyelocytic leukemia) and was compared to lapachol
and cisplatin (Table 1 and Fig. S3, ESI†). Complexes 1a–c exhibit
antitumour activity in the low mM range. In general, the activity of 1b
was widely similar to that of lapachol (L), indicating that the ligand
was the cytotoxicity-determining moiety of the compound. This may
be related to ligand release in the presence of biomolecules as shown
by the MS studies. The rhodium complex 1c was less cytotoxic than
lapachol and more stable under physiological conditions. The
organoruthenium compound 1a was the most potent compound
of the series, especially in the otherwise less sensitive A549 and
HCT-116 cells, where IC50 values suggest a synergistic effect of
the metal ion. The complexes induced moderate but significant
levels of apoptosis as determined by means of the annexin V
assay in SW480 cells. The amount of annexin V/PI positive cells
increased significantly after addition especially of 1a and 1c,
where a more than 2-fold increase of apoptotic cells compared
to the control was observed. In the cases of 1a and 1c but not 1b
Os(cym)
Table 1 In vitro anticancer activity (IC50 values in mM) of 1a–c in CH1, SW480,
A549, HCT-116 and HL60 cells compared to cisplatin and lapachol (L)a
IC50/mM
CH1
SW480
A549
HCT-116
HL60
L
3.3 � 0.2
5.5 � 0.6
42 � 14
92 � 1.0
18 � 5
1a
4.1 � 0.6
4.1 � 1.5
20 � 5
19 � 0.1 25 � 0.3
1b
4.2 � 0.8
9.0 � 1.1
46 � 8
>100
18 � 2.4
1c
7.3 � 1.5
39 � 12
91 � 19
93 � 0.1 32 � 0.5
b
b
b
c
—
Cisplatin 0.14 � 0.03 3.3 � 0.4 1.3 � 0.4 2.7 � 0.7
a
96 h exposure. b Taken from ref. 13. c Taken from ref. 14.
Chem. Commun., 2013, 49, 3348--3350
3349
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Fig. 3 Determination of the ROS level induced by lapachol and 1a–c by the
DCFH-DA-assay.
apoptosis induction was significantly enhanced as compared to
L (Fig. S4, ESI†).
The cytotoxic activity of lapachol is related to the generation
of ROS and interaction with nucleic acids.7,15 Thus the
potential of 1a–c to induce oxidative stress through ROS was
investigated by means of the DCFH-DA assay in HL60 cells. 1a
was found to generate ROS to a higher extent than the free
ligand and the Os and Rh compounds (Fig. 3). The induction of
oxidative stress and apoptosis was accompanied by increased
phosphorylation of the stress kinase p38 and enhanced levels
of p53 in HCT-116 cells (Fig. 4). These observations confirm a
synergistic effect of the organoruthenium coordination to the
bioactive quinone. In addition, the impact of L and 1a–c on the
cell cycle was investigated by FACS analysis in CH1, SW480 and
HCT-116 cells (Fig. S5 and S6, ESI†). Treatment of the more
resistant HCT-116 cells caused a significant arrest in the G2/M
phase, especially for the ruthenium complex 1a. In the case of
CH1 and SW480 cells, a substantial S phase arrest was observed
in the IC50 range (Fig. S5 and S6, ESI†). The G1/S checkpoint is
partially regulated by p53 in response to DNA damage.16 SW480
cells have a mutated p53 in contrast to HCT-116 cells, explaining
the different cell cycle arrests after treatment with L and 1a–c.
Furthermore, our data are comparable with lapachone induced
S phase arrest in p53 mutated cell models.17 As a consequence of
the cell cycle data, the dose-dependent expression changes in
cyclins and the phosphorylation of cdc2 after 24 hours were
elucidated by Western blot analyses in HCT-116 cells (Fig. 4). The
G2/M arrest was accompanied by expression changes of cell
cycle-related proteins, such as an increase in p21, cyclin B1
and E, while cyclin D1 expression was especially enhanced at
Fig. 4 Western blot analysis of HCT-116 cells incubated with 1a and lapachol (L)
for 24 h.
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Chem. Commun., 2013, 49, 3348--3350
Communication
lower drug concentrations. These data indicate that 1a interferes with cell cycle progression and induces apoptosis involving a p53 response.
In summary, organometallic lapachol complexes were prepared in high yields, which are activated by fast hydrolysis to the
corresponding aqua species in aqueous solution. They are able to
interact with biomolecules and show antiproliferative activity in
the low mM range in human tumour cell lines. The first investigations of the underlying mechanisms showed an enhanced anticancer activity, especially in case of 1a, based on ROS-induced
apoptosis and cell cycle arrest. Further investigations will elucidate the mode of action in more detail. Overall, the Ru complex
1a induced apoptosis to a higher degree compared to lapachol
and its Rh and Os analogues, demonstrating a synergistic effect
of the Ru centre and the bioactive ligand.
We thank the University of Vienna, the Austrian Science
Fund (FWF), the Johanna Mahlke née Obermann Foundation,
COST D39, CM0902 and CM1105 for financial support. We
gratefully acknowledge Prof. Vladimir B. Arion for the refinement of the X-ray diffraction data and Anton A. Legin for
instructions to the ROS assay.
Notes and references
‡ Crystallographic details: 1a: C25H27ClO3Ru, Mr = 511.19, 0.60 � 0.10 �
0.10 mm, monoclinic, P21/n, a = 12.8956(5) Å, b = 11.8913(4) Å, c =
14.2756(5) Å, a = 901, b = 98.504(2)1, g = 901, V = 2165.05(13) Å3, Z = 4,
rcalcd = 1.571 mg m 3, m = 0.872 mm 1, T = 150(2) K, 50 326 measured
independent reflections, Rint = 0.0382, R1 = 0.0225, wR2 = 0.0595, GOF =
1.000; 1b: C25H27ClO3Os, Mr = 601.12, 0.12 � 0.10 � 0.02 mm, monoclinic, P21/n, a = 13.4764(4) Å, b = 8.4120(2) Å, c = 21.0225(5) Å, a = 901,
b = 107.9860(10)1, g = 901, V = 2266.72(10) Å3, Z = 4, rcalcd = 1.761 mg m 3,
m = 5.767 mm 1, T = 150(2) K, 17 682 measured independent reflections,
Rint = 0.0426, R1 = 0.0247, wR2 = 0.0507, GOF = 0.997; description of data
collection and refinement see ESI;† CCDC 918728 and 918729.
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