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Ruthenium(ii) p-cymene complexes of a benzimidazole-based ligand capable of VEGFR2 inhibition: hydrolysis, reactivity and cytotoxicity studies.
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Cite this: Dalton Trans., 2017, 46,
8539
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Ruthenium(II) p-cymene complexes of a
benzimidazole-based ligand capable of VEGFR2
inhibition: hydrolysis, reactivity and cytotoxicity
studies†
Sudipta Bhattacharyya,
Kallol Purkait and Arindam Mukherjee
*
The design of Ru or other metal-based anticancer agents may achieve better and faster optimization if
the ligands used are also designed to have standalone functions. In this scenario, even after dissociation
from the metal complex under adverse conditions, the ligand would have anti-cancer properties. In our
work, we have generated a bispyrazole-containing benzimidazole ligand with potency against vascular
endothelial growth factor receptor 2 (VEGFR2), which is known to have roles in vasculogenesis/angiogenesis. This ligand was used to obtain ternary Ru(II) p-cymene complexes with the formulations [(η6-pcymene)Ru(HL)(Cl)](Cl) (1), [(η6-p-cymene)Ru(HL)(Br)](Br) (2) and [(η6-p-cymene)Ru(HL)(I)](I) (3). 1H NMR
data supports that hydrolysis of the complex is governed by halide substitution, and the extent of hydrolysis
followed the trend 3 > 1 > 2. All the complexes have low affinity towards DNA bases (average Kb ∼ 103 M−1
for CT DNA); however, all the complexes are cytotoxic in nature, with IC50 values less than 15 μM. The presence of excess glutathione (GSH) liberates HL from the complexes in solution. The ability of the Ru
complex to impair mitochondrial function and reduce the cellular GSH pool is thought to be the reason
that it retains activity in the presence of GSH despite the ability of GSH to degrade the complexes. The
chloride analogue 1 shows the best in vitro cytotoxicity against a prostate cancer cell line (LNCaP), with an
Received 15th March 2017,
Accepted 3rd June 2017
IC50 of 6.4 μM. The complexes show anti-proliferative activity by the mitochondria-mediated intrinsic apop-
DOI: 10.1039/c7dt00938k
totic pathway. Docking studies showed that HL has high affinity towards vascular endothelial growth factor
receptor 2 (VEGFR2). The complexes show anti-metastatic activity (in vitro) at almost non-toxic dosages,
rsc.li/dalton
and the effect is sustained even 48 h after removal of the complexes from the culture media.
Introduction
RuII complexes are well-investigated anticancer agents whose
mechanism of action is being probed.1 Research on Ru(II/III)
complexes has disseminated much important information
regarding the cytotoxicity of these complexes, viz. (i) inter-
Department of Chemical Sciences, Indian Institute of Science Education and
Research Kolkata, Mohanpur Campus, Mohanpur, Nadia-741246, West Bengal,
India. E-mail: a.mukherjee@iiserkol.ac.in
† Electronic supplementary information (ESI) available: Experimental details of
interaction with CT DNA, plasmid DNA interaction, cell lines and culture conditions, cell viability assay (MTT), determination of intracellular reactive oxygen
species (ROS), DNA ladder assay for apoptosis detection, detection of Caspase
activation, ruthenium accumulation inside cancer cells by ICP-MS analysis, in
ovo assay, western blotting, selected bond angle and bond distances of HL, 1
and 2 obtained from X-ray crystallography, NMR characterization spectra (1H,
13
C, HMQC), UV-vis and 1H NMR spectra showing solution stability of complexes, detailed procedure of biological experiments. CCDC 1507224–1507226.
For ESI and crystallographic data in CIF or other electronic format see DOI:
10.1039/c7dt00938k
This journal is © The Royal Society of Chemistry 2017
ference of Ru with Fe metabolism,2–4 (ii) availability of
different oxidation states, (iii) slow kinetics of various RuII/III
complexes with different biological targets (viz. DNA, protein,
etc.), and (iv) tuning of reactivity and mechanistic pathways by
varying the bidentate ligands, arenes and halides. A few Ru(III)
compounds, [ImH]trans-[RuCl4(Im)(dmso-S)] (NAMI-A, Im =
imidazole), [IndH]trans-[RuCl4(Ind)2] (KP1019, Ind = 1H-indazole), and [Na]trans-[RuCl4(Ind)2] (NKP1339), have progressed
to clinical trials.5–10 The ruthenium arene PTA (RAPTA)
complexes (where PTA = 1,3,5-triaza-7-phosphatricyclo-[3.3.1.1]
decane) are a potent class of complexes that have been studied
in detail and exhibit excellent activity against metastasis and
angiogenesis.11–13 Among other Ru(II) organometallic halfsandwich ternary complexes, Ru(II)-p-cymene complexes are
targeted by many research groups because of their high cytotoxicity, photoactivity, and resistance to glutathione
(GSH);8,11,14–34 also, these compounds enable the introduction
of new bidentate ligands while retaining a labile halide
attached to the metal centre. In addition, in few cases, changing the halide also alters the pathway of action.35,36
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Thus, the design of a bidentate ligand that would promote
therapeutic effects may be of great benefit for better and
quicker optimization of such compounds. In addition, even if
the complex dissociates in the cell under adverse conditions,
the ligand would exhibit the potential to open up multiple
pathways of action against cancer.37–39 From this standpoint,
we investigated bispyrazole-benzimidazole-based ligands to
design a ligand that would inhibit vascular endothelial growth
factor receptor 2 (VEGFR2).
Cancer becomes a greater threat when it spreads from its
origin to various areas of the body by the lymph system or the
bloodstream (metastasis). The spread is followed by the
growth and development of blood and lymphatic vessels,
known as vasculogenesis/angiogenesis. Vascular endothelial
growth factors (VEGFs) stimulate vasculogenesis/angiogenesis.
VEGFs bind to three types of VEGF receptors (VEGFR1-3) in
their tyrosine kinase domains. Among these, inhibition of
VEGFR2 is a prime target to inhibit angiogenesis; a successful
clinical drug in this regard is axitinib. There are many molecules in clinical trials, viz. Rumacinib (NCT00627042),
Foretinib (NCT00725764) and Lucitanib (NCT02109016), with
the same mechanism.
The above idea provided us with the impetus to design Ru(II)
complexes (Chart 1) with the formulations [(η6-p-cymene)
Ru(HL)(Cl)](Cl) (1), [(η6-p-cymene)Ru(HL)(Br)](Br) (2) and [(η6p-cymene)Ru(HL)(I)](I) (3) using a bispyrazole-benzimidazole
ligand (HL) with potential to inhibit VEGFR2. The design of
the benzimidazole-containing bispyrazole ligand (HL) was
inspired by the known VEGFR2 inhibitor SU5416,40 as demonstrated in Scheme 1. Bis-pyrazole Ru(II) complexes are seldom
studied for their anticancer activity. Recent studies have shown
their potential against topoisomerase-II41 and demonstrated
their cytotoxicity against cancer.42 Ru(II) p-cymene complexes
of benzimidazole-containing ligands are active anti-cancer
agents.28,29,43–48 However, the detailed mechanism of action
has been probed for only a few Ru(II) p-cymene complexes
bearing benzimidazole ligands.28,48–51 The well-characterized
complexes (1–3) were studied for their hydrolytic behaviour,
the effects of their halides, and their reactivities in the presence and absence of glutathione. The cytotoxicities and the
pathways of action of the complexes were probed.
Results and discussion
Syntheses
The benzimidazole-based ligand (HL) was synthesized using a
literature procedure.52 Because o-phenylenediamine is one of
the synthetic precursors, special care was taken to protect it
from photo-degradation. It must be noted that during the last
step of ligand synthesis, while extracting the ligand from
excess hexane containing toluene, the ligand adhered to the
surface of the vessel; however, allowing the mixture to stand
for an hour with stirring allowed the microcrystalline compound to be readily isolated. After that, further washing with
hexane followed by vacuum drying afforded ligand that was
sufficiently pure for the syntheses of the complexes and other
analytical purposes.
The Ru(II) complexes were prepared from HL using different
halide-based Ru(II)( p-cymene) salts prepared from the [(η6-pcymene)2RuCl2]2 precursor (Scheme 2).18 The reactions were
performed in dry dichloromethane under reflux conditions
with ligand and metal precursor in a 1 : 1 mole ratio. The
respective obtained complexes were dried and washed successively with hexane and diethyl ether to eliminate any excess
ligand. The complexes were then re-dissolved in DCM and
again precipitated by addition of hexane. The microcrystalline
complexes thus obtained were pure enough for all studies, as
per the characterization data. Hence, in the respective complexes, the coordinated halide and the counter anion are the
same.
Characterizations
The ligand (HL) and the metal complexes (1–3) were analysed
extensively using 1H and 13C NMR experiments (Fig. S1–S11†).
The change in chemical environment upon complexation was
Chart 1 A general representation of the design of Ru(II) metal
complexes.
Scheme 1
Representative structure of SU5416 and our ligand (HL).
8540 | Dalton Trans., 2017, 46, 8539–8554
Scheme 2
Synthetic scheme of the ligand and its metal complexes.
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evident from their chemical shift values (tabulated in Tables
S1 and S2† for 1–3). A significant change in the chemical shift
of the proton signal of the non-coordinated benzimidazole
–NH was found upon complexation because the –NH proton is
deshielded due to the coordination of the neighbouring nitrogen with Ru(II). The complexation with Ru(II) and the difference in proximity of the p-cymene moiety to the ring protons
of benzimidazole and pyrazole altered the symmetry of HL.
This was evident from the new 1H signals arising from the
benzene and pyrazole rings. The C5 methyl protons of the pyrazole ring appeared to be more deshielded than the C6 methyl
protons due to their proximity to Ru(II) (Table S1†). Asymmetry
in the complex is reflected in the proton signals of the
p-cymene aromatic –CH protons, which appeared as four
doublets.53 Apart from that, the downfield shift of the aromatic pyrazole –CH (H3, H15) protons suggests a decrease in
electron density upon coordination. The appearance of H3 at a
lower ppm is indicative of coordinated pyrazole in the metal
complexes (Fig. 1). Aromatic H10 and H11 share almost equal
electron density; therefore, they appear in the same position
with their respective multiplicities. The effect of metal coordination is again evident from the lower field shift of H12 and is
Paper
in proximity to the bound nitrogen of the benzimidazole ring.
The H9 of the aromatic ring is involved in H-bonding with the
counter halide; thus, it shows halide dependency in its chemical shift. The decrease in the electronegativity of the halide on
moving from 1 to 3 resulted in upfield shifts of the p-cymene
aromatic –CH protons. The shift of the –CH proton of H1
seems quite ambiguous because from 1 to 2, the peak shifts to
a low field but suddenly moves upfield again in the case of 3.
This phenomenon may be explained by both the stereoelectronic and H-bonding factors governing the geometry of the complexes. The twisting of the –CH proton at C1 is basically driven
by the extent of electron donation from the ruthenium centre
and the twisting around C1. Therefore, we observed a upfield
peak shift of H1 from 8.01 to 7.91 ppm from 1 to 2; however,
in the case of 3, there is an almost negligible downfield shift
from 2 due to this twisting and the electronegativity of iodide
(Tables S1, S4 and S8†).
Both the ligand and the metal complexes were characterized by other analytical techniques to check their purity (see
the Experimental section). The ligand in ESI (+ve) appeared as
[M + Na]+ along with one pyrazole-removed species; this speciation has been previously reported in similar compounds
(Fig. S12†).54 For the metal complexes, the molecular ion and
halide-free complexes were observed in all cases
(Fig. S13–15†). The electronic spectra of 1–3 in methanol were
interesting, where the metal-centered band at ca. 430 nm red
shifted by ca. 36 nm as the halides changed from Cl− to I−
(Fig. S16†). This may be attributed to the increase in electron
density on Ru(II) upon changes in electronegativity and to the
Ru–X (X = halide) bond distances.
X-ray crystallography
Fig. 1 Comparison of the 1H NMR spectral traces in DMSO-d6, showing
the changes in chemical shifts in HL and 1–3. The aromatic regions of
the spectra show the effects of halide coordination on the metal complexes. Numbering refers to the drawing in Scheme 2.
Single crystals suitable for X-ray diffraction were obtained by
layering hexane over dichloromethane solutions of the compounds for HL, 1 and 2. ORTEP diagrams with 50% probability
thermal ellipsoids are shown in Fig. 2, and selected crystallographic parameters are tabulated in the ESI (Table S3†). HL,
1 and 2 crystallize as monoclinic crystal systems in C2/c (HL)
and P21/n, respectively. The diffraction data showed the
expected increases of the Ru–X bond distance by ca. 0.13 Å
when the coordinated halide changed from –Cl to –Br. The
Fig. 2 ORTEP diagrams for HL, 1 and 2 with selective labelling. Hydrogen atoms and counter anions have been omitted for clarity. Thermal ellipsoids are shown at 50% probability.
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chelating coordination was satisfied by one nitrogen from the
benzimidazole and another from a pyrazole of the heteroscorpionate (Scheme 2).
In 1 and 2, the counter anion Cl−/Br− formed hydrogen
bonds with the benzimidazole –NH within the same asymmetric unit (2.99(2) Å for 1, 3.14(2) Å for 2). The ligand HL
exhibited both intra- and inter-molecular H-bonding involving
the benzimidazole –NH and pyrazole nitrogen. It was found
from single crystal X-ray data that in HL, intramolecular
H-bonding occurs between –Nε–H⋯Npz. However, the ∠ –Nε–
H⋯Npz is 117.48(6)°, showing that although the bond distance
between the donor and acceptor is only 2.778 Å, the angular
nature weakens the H-bonding. In complex 1 and 2, ∠ –Nε–
H⋯X− (X = Cl, Br) is ca. 160°, although the distance ranges
from 2.994 Å in 1 to 3.145 Å in 2. The p-cymene group is connected to the Ru(II) centre by distances ranging from 2.173 Å to
2.238 Å through η6 bonding. The coordination of the ligand
induces a change in the torsion angle of C7–C1–N2–N1 (HL =
42.35°, 1 = 45.29°, 2 = 43.67°) due to binding of the metal with
N1. The bond angle of N(1)–N(2)–C(1) also increases from
120.27° in HL to 123.2 (2)° and 123.6 (2)° in 1 and 2, respectively. Selected bond angles and distances in HL, 1 and 2 have
been tabulated in Table S4.†
Solution stability
It was necessary to check the stability and retention of the
parent species in 1–3 before we studied the cytotoxicities of
these complexes. Because the stock solutions of the complexes
for cytotoxicity tests are made in DMSO, the integrities of the
complexes were checked for 2 h in DMSO (by 1H NMR)
(Fig. S18†); all the metal complexes were found to be stable.55
However, the stock solutions for cellular studies were freshly
made and were utilized within 10 min.
The ligand (HL) was found to be stable up to 48 h in
DMSO–PBS (2 : 8 v/v) containing 4 mM NaCl, pD = 7.4
(Fig. S17†); beyond this time, the stability was not monitored.
The metal complexes were examined for 24 h in a 2 : 8 v/v
Dalton Transactions
DMSO–PBS mixture by 1H NMR. Complex 1 and 3 readily
hydrolysed (denoted by ‘*’, Fig. 3) in a DMSO–PBS (2 : 8 v/v)
mixture containing 4 mM NaCl, pD = 7.4, upon immediate dissolution; this effect was less in the case of 2. However, in the
cases of 2 and 3, we observed exchanges of chloride from the
buffer solution to replace bromide and iodide (denoted by ‘o’,
Fig. 3) in 2 and 3. The extent of halide exchange is greater in 3
compared to 2, which is expected due to the weaker Ru–I bond
in 3 and is well known in the literature.38 The rate of aquation
is also higher for 3 (iodide complex) in comparison to 1 (chloride complex); however, for 2, the rate of aquation is lower even
than that of 1. This may be because the rate of aquation of 2 is
competitive with that of the chloride exchange. Thus, the
hydrolysis of the complexes is also regulated by the halide
exchange in solution. Over a period of 24 h, 2 allowed only ca.
30% halide exchange to form the chloro species (1); remarkably, it became stable in the 4 mM NaCl environment, unlike
1. The above result suggests that the halide exchange may be
governed by an equilibrium which inhibits the hydrolysis of
the complex in that environment. It is worth mentioning here
that halide exchange in all Ru(II) complexes does not necessarily follow a common trend.38,56
In contrast to the NMR data, upon injecting an aliquot of
the NMR sample, after necessary dilution with methanol, no
m/z peak was observed in the ESI-MS for the halide-exchanged
species in 2 and 3. Only the dehalogenated species [(η6-pcymene)RuII(L)]+ was found as the major peak in ESI-MS (obs.
m/z = 555.18; calcd 555.18) for all three complexes. The relative
intensity showed that the m/z peak of 555.18 became more
intense compared to the native complex peak (1, obs. m/z =
591.16; calcd 591.16, 2, obs. m/z = 635.11; calcd 635.10, 3, obs.
m/z = 683.09; calcd 683.09) in one-day-old solution when compared with fresh solution (Fig. S19–S21†). The stability order of
the complexes is 2 > 1 > 3. All of the possible speciations found
by ESI-MS initially and after 24 h are tabulated in Table S5.†
During the NMR hydrolysis studies, it was observed that all
the complexes immediately showed ca. 2% to 3% free
Fig. 3 Stability of 1–3 in DMSO-d6 and PBS containing 4 mM NaCl in D2O (2 : 8 v/v), pD = 7.4, monitored by 1H NMR. Spectra recorded after 24 h at
25 °C, where ‘*’ is hydrolysed; ‘o’ is chloride exchange; ‘@’ is free p-cymene; ‘‡’ is [Ru2(η6-p-cymene)2(OH)3]+ (ii) and ‘†’ is [Ru2(η6-pcymene)2(HL)2Cl]+ (iii) peaks in solution.
8542 | Dalton Trans., 2017, 46, 8539–8554
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p-cymene (2.18, 1.15 and 7.22 ppm), even in recrystallized
complex solutions (Fig. 3). However, there was no further
ligand dissociation during the next 24 h, which suggests that
the miniscule initial dissociation may be due to a temperature
change during solution mixing. However, this is not completely understood. EPR studies of 1 mM solutions of 1 and 3 in
MeCN–H2O (1 : 1 v/v) suggest that we may exclude the formation of any Ru(III) (data not shown). The ESI-MS data also
does not show any m/z that matches well with any Ru(III)
species. Hence, the contribution towards the spectral broadening is due to the 4 mM NaCl phosphate buffer ( pH 7.4). The
1
H NMR data of the iodo complex 3 initially showed the formation of a minute amount of ruthenium(II) hydroxo dimer
([Ru2( p-cymene)2(OH)3]+) (iii in Scheme 3, ‘†’ in Fig. 3), displaying two signature peaks at 5.1 and 5.5 ppm for two
different aromatic protons.57 Another set of peaks was
observed in the spectra that may be assigned to the formation
of a dimer bearing the ligand and p-cymene by binding of the
N-donor site of non-coordinated pyrazole with another metal
centre via replacement of chloride (ii in Scheme 3),
([Ru2(HL)2( p-cymene)2Cl]+, denoted by ‘‡’ in Scheme 3).
Complex 3 also shows a higher degree of aquation (denoted by
‘ ’).57 The dimer of the formulation [Ru2(HL)2( p-cymene)2Cl]+
was also found by ESI-MS using the same solution from the
NMR studies; it shows a peak at m/z 1145.33 (calc. 1145.33),
and the isotopic distribution for this m/z matches well with
the simulated distribution (Fig. S22†). The NMR data supported that dimer formation is favoured only in the iodo
complex (3). Unlike the 1H NMR spectra, in ESI-MS, dimer formation occurred for all three complexes (Fig. S22†); this
suggests that dimers may also form during MS.
We also performed conductivity studies on the complexes
to support our hydrolysis/halide exchange results. In a 1 : 1
Scheme 3 Interaction of complexes with DMSO and GSH in a DMSO–
phosphate buffer (2 : 8, v/v) solution mixture.
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acetonitrile–water mixture, 1 mM solutions of all the complexes show an increase in conductance over time up to 6 h;
after, almost no change is observed up to 24 h (Fig. S23†). This
indicates that there may be an equilibrium in solution after
this period of time. The initial increase in conductivity is
attributed to both the liberation of halide and coordination to
water. Hydrolysis of the complexes increases their positive
charge, thus increasing their ionic mobility.58 In 4 mM NaCl,
the rate of increase in the conductance value was relatively
slow (Fig. S23†). This may be because the 4 mM chloride ion
concentration favours halide exchange, leading to coordination of a chloride and liberation of a bromide and, hence, a
relatively low increase in conductance. The saturation point
was reached on average after ca. 4 h for 2 and 3; however, 1
required more time because of the common anion present in
solution. It must be noted here that aquation means the
( partial or complete) exchange of chloride with water. The rate
of change in conductance follows the trend of 3 > 2 > 1.
Therefore, 3 is less stable with respect to the other complexes.
Hence, the conductivity experiments show that complex 3 is
the least stable and that 2 undergoes halide exchange in the
presence of 4 mM chloride solution.
Interaction with glutathione and model nucleobase
9-ethylguanine
Glutathione is a major detoxifying agent in the presence of
glutathione S-transferase (GST)40 in cells. Many cancer cells
become resistant to different drugs by increasing their cellular
glutathione levels.59 Therefore, the stabilities of the complexes
were studied in the presence of excess (10 eq.) glutathione
(GSH) by 1H NMR spectroscopy. The experimental conditions
were similar to those used for solution stability studies of 1–3
by 1H NMR. It was found that the compounds lost their integrity in the presence of glutathione (Fig. 4). A similar phenomenon is known for many Ru(II) complexes when interacting
with sulphur-rich amino acids (viz. cysteine).60,61 1–3 began to
dissociate upon addition of 10 eq. of GSH. After 24 h, more
than 60% ligand dissociation occurred in all the metal complexes (ca. 63% in 1, 72% in 2 and 84% in 3 after 24 h). The
entire hydrolyzed and intact complexes rapidly bind to GSH,
forming GSH adducts, through sulphur coordination by replacement of a halide or water from the intact or aquated species,
respectively. We continued the kinetic studies up to 24 h. For
1, all the intact and hydrolyzed peaks shifted towards lower
ppm upon coordination with GSH. The 1H peaks corresponding to glutathione protons also showed chemical shifts,
indicating strong binding of GSH to the metal complex. The
GSH peak at 2.70 ppm for Cys-CH2 shifted to 2.76 ppm. The
proton integration of that peak over time suggested the degradation of GSH to form [Ru(η6-p-cymene)(H2O)(GS(O))](v) and
oxidized glutathione (GSSG) (Scheme 3).
The binding of GSH is supported by the downfield shift
(Δδ) of the Gly-CH2 and Cys-CH protons by 0.08 and ca.
0.05 ppm.62 The chemical shift of the Cys-CH proton merges
with the residual water peak; hence, we could not obtain the
exact chemical shift. Other peaks of GSH (Glu-CH, Glu-(β)CH2
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Fig. 4 Stability and interaction of 1 with GSH (10 eq.) in 2 : 8 (v/v) DMSO-d6 and 10 mM phosphate buffer containing 4 mM NaCl ( pD = 7.4) by 1H
NMR at 25 °C. ‘$’ is GSH-bound complex; ‘#’ is free ligand; ‘@’ is free p-cymene; ‘+’ is GSSG and ‘Δ’ is [Ru(η6-p-cymene)(H2O)(GS(O))](v) peaks in
solution.
and Glu-(γ)CH2) do not show significant shifts over time for
binding (Fig. 4). Following binding, ligand ( HL) dissociation
from the GSH-bound complex is observed (indicated by ‘#’)
(also observed by ESI-MS, obs. m/z = 321.26, calcd 321.26),
while the GSH may have undergone chelated binding with
Ru(II) with the aid of another Gly-NH. It must be noted here that
the binding mode cannot be confirmed; a formulation is proposed from the ESI-MS data (Fig. 4 and Fig. S24†) to explain
the 1H NMR chemical shifts. The GSH adduct formation gave
a peak at m/z = 862.27 (calc. 862.26), as shown in Fig. S24 and
S25.† ESI-MS also supported the formation of halide and
ligand-eliminated glutathione sulfenate-bound ruthenium
(v in Scheme 3) adduct ([Ru(η6-p-cymene)(H2O/Cl)(GS(O))]) in
solution. The sulfenate adduct peaks continued to increase
with time in the 1H NMR spectrum. The sulfenate adduct (v)
species was stable up to 24 h and was also identified under
mass spectral conditions ([Ru(η6-p-cymene)(H2O)(GS(O))]); obs.
m/z = 592.17, calc. 592.16) (Fig. S24 and S25†). In the ESI-MS
after 24 h, the major species observed were the free ligand and
GSSG. The possible speciations of GSH interaction, as
obtained by ESI-MS, are tabulated in Table S6.† This observation is indicative of the operation of a concerted associative
mechanism during GSH interaction. 1H NMR studies of the
interaction of the model nucleobase 9-ethylguanine (9-EtG)
with the metal complexes showed an insignificant downfield
shift ca. 0.01 ppm of H8 (9-EtG) with respect to free 9-EtG
alone. We did not observe any new peak for the p-cymene aromatic protons, which confirms that no direct coordination of
the metal centre occurs with N7 of 9-EtG.38,44,46 However, a
newly generated peak was immediately observed at 6.3 ppm for
the aromatic C–H of non-coordinated pyrazole (around 20% to
30%) along with the original peak at 6.2 ppm (Fig. 5). This
indicates that the free pyrazole ring may be involved in C–H⋯π
interaction with the six-membered ring of 9-EtG. This C–H⋯π
interaction causes the pyrazole C–H to appear at 6.3 ppm.
On the other side, where the benzimidazole –NH proton interacts with guanine N7, the close proximity of the N–H of benzimidazole with the lone pair of N7 of 9-EtG causes an upfield
shift in the benzimidazole aromatic protons (Δδ = 0.06 ppm).
8544 | Dalton Trans., 2017, 46, 8539–8554
Fig. 5 Interaction of 1 with 9-EtG in DMSO-d6 and 10 mM phosphate
buffer containing 4 mM NaCl ( pD = 7.4) 2 : 8 (v/v) by 1H NMR at 25 °C.
Only the guanine interaction peaks are assigned. Peaks with blue diamonds are formed on interaction between 9-EtG and the complex.
Simultaneously, due to the decrease in electron density
over the guanine N7, a new guanine H8 signal appears at
7.87 ppm.
We also observed that hydrolysis of the complexes is significantly suppressed in the presence of 9-EtG. However, two new
peaks (in addition to the hydrolysis and native compound
peaks) at 6.48 and 6.24 ppm for the two pyrazole C–H protons
appeared; this may be due to a change in the conformation of
the free pyrazole, which is in equilibrium with the native conformation, but cannot be assigned definitely. After 24 h of
reaction, we did not observe any significant changes in the
spectra compared to the initial spectra, which indicates that
the reaction may be in equilibrium.
The model nucleobase 9-EtG did not show any strong interaction with the complexes as per the NMR data, and the CT
DNA binding constant is also low (103 M−1 for 1–3, Table S7†).
The binding constant values are in agreement with the trend
of hydrolysis in solution: 1 > 3 > 2. However, we observed retardation of pBR322 plasmid DNA upon incubation of 1 with
various ratios of complex : DNA (with respect to base pairs)
starting from rb = 0 to 1.66 within 4 h (Fig. 6 and Fig. S26†).
This signifies that the complexes have the potential to bind
with DNA, although the binding is weak.
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Fig. 6 Agarose gel electrophoresis bands of pBR322 plasmid DNA
showing unwinding; incubation time = 4 h at 37 °C in the dark, [DNA] =
30 µM (base pair concentration); DNA was incubated with 1 with rb =
0 to 1.66 (lanes 1–7, respectively).
Theoretical studies
The energy-optimised structures of all the metal complexes
and ligand showed good agreement with their single crystal
X-ray structures (Fig. S27 and Table S8†). From calculations, it
was found that the increments of metal halide distance were
in parity with the electronegativity and stability. There was an
increase in electron density on the metal centre on moving
from 1 to 3. This may be a contributing factor to their susceptibility to potential nucleophiles, viz. water, DMSO and GSH.
There was a decrease in the HOMO–LUMO energy gap from 1
to 3, which suggests increased reactivity moving from 1 to 3
(Fig. S28†). The HOMO stability order is 1 > 2 > 3. The FMO
energy ordering of 1 to 3 suggests that there is a possibility of
halide exchange to form the chloro complex first in the cases
of 2 and 3, which is followed by aquation. The aqua complex
shows a lower HOMO energy in comparison to all the complexes. The decrease in LUMO energy from 1 to 3 indicates
more facile nucleophilic attack on the metal centre as we move
from chloro to the iodo complex.
In vitro cytotoxicity
The in vitro cytotoxicities of HL and 1–3 were probed against a
selected panel of cell lines, viz. MCF-7 (human breast carcinoma), LNCaP (human metastatic prostate carcinoma), MIA
PaCa-2 (human pancreatic carcinoma), HepG2 (human hepatocarcinoma), and human foreskin fibroblast (HFF-1). The
ligand alone has relatively poor solubility, and the solubility
increases upon complexation. 1 is the most active complex of
the three, while the ligand itself does not show any toxicity up
to 50 µM. The IC50 ranges of all the complexes are within
15 µM. The cytotoxicities of the complexes showed minimal or
Table 1
no effects upon changing the halide in the studied cell lines.
In HepG2, the IC50 values were 10.6 ± 0.9 for 1, 9.8 ± 1.4 for 2,
and 11.0 ± 1.6 for 3. The cytotoxicities of 1 and 2 were very
similar in MCF-7 (6.9 ± 1.0 for 1 and 7.8 ± 1.0 for 2) and MIA
PaCa-2 (11.7 ± 1.2 for 1 and 12.3 ± 1.4 for 2). All the complexes
show comparable cytotoxicities against the primary cell line
HFF-1 (Table 1).
The solvation/dissociation differed greatly for 1 and 2;
however, this trend was not reflected to a similar order of magnitude in their toxicity profiles.63 In the cases of 2 and 3, the
formation of 1 occurs by halide exchange. This exchange is followed by hydrolysis of the compounds. Therefore, 1 shows
higher toxicity than 2, as the latter exchanged halides slowly.
In the case of 3, the halide exchange is faster than that of
bromide; however, the cytotoxicity decreases due to formation
of some amounts of inactive side products [viz. ([Ru2( pcymene)2(OH)3]+)] (Table 1).
All the complexes show loss of activity in the presence of
externally added GSH in the culture media; however, the deactivation is low. This may be explained in two ways: (i) the Ru
complexes may have higher affinity to serum albumin, which
is well known.64,65 Hence, the albumin binds to the Ru(II) complexes, protecting them from deactivation by GSH and aiding
their delivery to the target site; (ii) the GSH reacts competitively with oxygen; hence, the deactivation of the Ru(II) complexes is low. In intracellular conditions, the amount of metal
complex that interacts with GSH dissociates. The intracellular
concentration of GSH in the probed cells would not be high
enough to deactivate all the complex delivered; hence, the cytotoxicity pattern does not change greatly. We also found that
the complexes have the ability to reduce the intracellular GSH
pool by impairing mitochondrial function, as discussed later.
Inductively coupled plasma mass spectrometry (ICP-MS)
analysis of the Ru(II) complexes showed that the cellular Ru
accumulation trend was 1 > 2 > 3 (Fig. 7). However, the difference between 1 and 2 is small. The accumulation correlates
with the hydrolysis trend. Due to more side reactions and the
formation of dimeric adducts, 3 accumulates less inside the
cells. This accumulation trend is also in harmony with the
cytotoxicity profiles (Fig. 7).
The ruthenium anti-cancer agent NKP1339 is in clinical
trials against different solid tumors,66 whereas NAMI-A is
known to interfere with metastasis (cell migration) of cancer
cells.6 The excellent toxicity profile against metastatic cancer
In vitro cytotoxicities (µM) ± SDa
HL
1
2
3
Cis-platin
MCF-7
MIA PaCa-2
LNCaP
HepG2
HFF-1
MCF-7 + GSHb
>50
6.9 ± 1.0
7.8 ± 1.0
10.5 ± 2.0
12.0 ± 2.0
>50
11.7 ± 1.2
12.3 ± 1.4
15.1 ± 1.2
31.8 ± 4.8
>50
6.4 ± 0.8
9.5 ± 1.0
10.9 ± 1.8
5.1 ± 1.5
>50
10.6 ± 0.9
9.8 ± 1.4
11.0 ± 1.6
14.3 ± 1.0
>50
6.6 ± 0.5
7.2 ± 0.2
7.4 ± 0.2
9.7 ± 0.4
>50
7.9 ± 0.8
9.0 ± 0.9
11.0 ± 2.0
29.0 ± 1.1
a
The data reported are the mean of at least two independent experiments. b GSH = reduced glutathione (1 mM); the statistical significances
(p value) of all data reported are ≤0.05.
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Fig. 7 Ruthenium content inside MCF-7 cells treated with 1–3 (5 µM)
for 24 h. Data obtained from ICP-MS analysis. Error bar shows the standard error of the data.
cells (LNcaP) (Table 1) led us to probe the anti-metastatic
activity against MCF-7 monolayer using the wound healing
(scratch) assay. It was found that 1–3 can prevent healing of
wounds, i.e. they are effective against cell migration activity
even at 500 nM concentration, although the complexes did not
exhibit any detectable cell toxicity at 500 nM concentration
(Fig. 8). Encouragingly, this antimigratory activity was retained
even 48 h after removal of the complexes from the cell culture.
These preliminary experiments are highly encouraging in
demonstrating the anti-metastatic effects (Fig. S29†) of the
complexes.
Possible mechanism of in vitro cytotoxicity
The in vitro cytotoxicity and the results from the speciation
studies were encouraging; thus, we proceeded to check the
possible mechanisms of action of the metal complexes (1–3).
The possibility of ROS involvement in cytotoxicity was determined by DCFH-DA assay using both FACS and fluorescencebased multi-well assays. It was found that although complex 1
was the most potent (Fig. S30 and S31†), all the complexes
were effective in producing ROS. The ROS experiments were
performed in MCF-7, and the trend of ROS generation followed
the trend of the IC50 values of the complexes against MCF-7.
The generation of ROS gave us an impetus to study the
mitochondrial health inside the cells. It was found that the
complexes were able to change the mitochondrial transmembrane potential (MMP), as evident from JC-1 staining data
(Fig. S31†). This can help explain our cytotoxicity data in the
presence of GSH despite the fact that GSH degrades our complexes. The ability of the complexes to change the mitochondrial membrane potential signifies that the mitochondria
would malfunction, and this would lead to less production of
cellular GSH67 and hence to less deactivation of the
complexes.
There was evidence of sub G1 phase arrest for all the complexes (1–3) upon flow cytometric analysis of MCF-7 cells
treated with 1–3 at two different concentrations (for 24 h). In
addition, concentration-dependent S phase arrest was
8546 | Dalton Trans., 2017, 46, 8539–8554
Fig. 8 Wound healing (scratch) assay (A) showing the effects of 1–3 on
the healing of artificial wounds on monolayers of treated MCF-7 cells
for 48 h with sub-micromolar concentrations (500 nM) of the complexes; (B) quantitative data showing the healing trends of the wound
areas. The white dashed lines indicate the edges of the monolayers.
observed in 1. However, in complexes 2 and 3, the growth
arrest was mostly observed in G2/M phase but was also concentration dependent (Fig. S32†). Hence, the cell cycle arrest
differs between the chloro complex (1) and the other two complexes (2, 3); this signifies that different pathways of action
may be reasons for the above. Similar results are rare for Ru(II)
complexes; however, this is known to occur due to variations
in halides, as reported by Sadler et al.35,36 They found that the
change in the mechanism of action is due to changes in the
rate of hydrolysis and in the mechanism of transport inside
the cells.35,36 In our case, the difference is caspase 8 activation
for 1–3, in comparison to caspase 7; this suggests that the
complexes may operate through multiple pathways initially,
but after caspase 8 activation, they follow the mitochondriamediated intrinsic pathway of apoptosis.35,68,69
For earlier reported Ru(II) p-cymene benzimidazole-based
complexes where detailed mechanistic studies have been
explored in the literature, most studies suggest that DNA
binding is the major cause of cell death through cell cycle
arrest, mostly in G2/M phase28,29,47,48 and S phase.43,47 These
Ru(II) complexes are known to inhibit cyclin-dependent
kinases (cdk1/cdk2)28,44 and downregulate ribosomal proteins
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(RPS21) and cytokines, such as β-actin.70 However, for complexes 1–3, the model nucleobase studies using 9-EtG and the
DNA binding studies suggest that DNA binding is not the
major pathway of action. Hence, the inhibition of the cell cycle
at S-phase and G2/M phase may occur through interactions
with proteins responsible for proper propagation and completion of these phases.
Apoptotic cell death is supported for 1–3 because the formation of fragmented bands of the isolated genomic DNA of
the metal complex-treated MCF-7 cells (DNA ladder; Fig. S33†)
was observed.71 Involvement of caspase 7 was found, which
further confirmed the apoptotic pathway of cell death for 1–3.
The highest amount of caspase 7 was activated by 1, and the
order is 1 > 2 > 3 (Fig. S34†). One point to note here is that the
activation of caspase 8 was lower for all the complexes. The
change in the mitochondrial membrane potential and the
lower activation of caspase 8 suggested that a mostly intrinsic
pathway of apoptosis may be favoured compared to an extrinsic pathway. One point to note here is that despite the caspase
8 activation, the intrinsic mitochondria-mediated pathway of
apoptosis may still be favoured.72,73 Hence, our proposed
mechanism of action is depicted in Scheme 4.
Molecular docking with VEGFR2
The ligand was docked against VEGFR2 to investigate its
ability to inhibit the tyrosine kinase domain of VEGFR2. The
docking score, which is an indication of the efficiency, was
compared against the clinical inhibitor axitinib and the inhibitor that inspired our design, i.e. SU5416.74 We obtained the
crystal structure of 1YWN from the PDB database because it is
widely used for this purpose. 1YWN contains an inhibitor crystallized with VEGFR2, which was removed before performing
our docking studies.75
In one method, upon removal of the native inhibitor, we
docked the clinically used axitinib, SU5416, HL and complexes
1–3 with the protein. In another method, the protein structure
was optimized after removal of the native inhibitor using the
OPLS2005 force field, and the resulting optimized structure
Paper
was used for further docking studies with HL, 1–3, axitinib
and SU5416. The docking results gave better GOLD score
values with the native structure. However, the optimized
protein structure gave better docking scores with SU5416 and
the clinical inhibitor axitinib; hence, to remove bias, we
present the results obtained from both docking studies
because it was felt that this would provide a better representation (Table 2 and Table S9†). A higher GOLD score was taken
as a better fit because this is known to indicate better binding
interactions. Both the methods show that axitinib (IC50 = 0.1
to 0.3 nM) is the best molecule against VEGFR2 (58.67); after
that, the affinity of HL is the second highest (50.87), even
better than that of SU5416 (41.25) and close to that of axitinib.
The complexes are moderate inhibitors of VEGFR2 in their
native [(η6-p-cymene)RuII(HL)(X)]+ and aquated [(η6-p-cymene)
RuII(HL)(H2O)]+ forms. The docking score of [(η6-p-cymene)
RuII(HL)(H2O)]+ is close to that of SU5416 when docked
against the native structure (Table 2) and less when the
docking is performed with the optimized protein structure.
It is known that Glu883 and Asp1044 are the common residues that bind effectively with potential inhibitors in the
kinase binding active site, which causes VEGFR2 to lose its
activity.75,76 As per the docking studies presented here with the
optimized structure, the best molecule, axitinib, showed
H-bonding interactions with Phe843, Lys866, Glu883, and
Asp1044; also, the two terminals of axitinib are in hydrophobic
pockets consisting of Leu838, Val846, Ala864, Ile866, Glu883,
Cys1043 and His1024 (Fig. 9F). For SU5416, Glu883 and Asp
1044 formed H-bonding interactions. However, the hydrophobic interactions are fewer (Fig. 9G). In the case of the Ru(II)
complexes, 2 and 3, the halides were found to interact with
Val846 by the formation of strong H-bonds [2, Val846 C–H⋯Br
(ca. 3.25 Å, ∠ 154.86°)] and [3, Val846 C–H⋯I (ca. 3.26 Å,
∠ 116.31°)]; this was absent in 1 (Fig. 9B and C). Other than
Val846 in the case of 3, Lys866 forms a more potent bond with
the halide [Lys866 C–H⋯I (ca. 3.66 Å, ∠ 160.93°)]. In the case
of 1 and the aqua complex, the interactions are relatively fewer
(Fig. 9A and D). For the ligand (HL), we found similar interactions to axitinib. HL forms strong H-bonds with Glu883 and
Asp1044, which enables the molecule to fit into the cavity
Table 2 Molecular docking fitting parameters for interactions with
VEGFR2 (PDB: 1YWN)a
Scheme 4 Plausible cellular pathways of the anti-cancer activities of
benzimidazole-based Ru(II) p-cymene complexes available in the literature (blue arrows) and our complexes (red arrows).
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1
2
3
Aqua complex
HL
Axitinib
SU5416
Inhibitor-extracted
structure
Native structure
GOLD score
RMSD
GOLD score
RMSD
34.27
40.54
38.78
32.35
50.87
58.67
41.25
5.2
6.4
5.2
6.1
4.7
0.3
3.34
44.37
43.49
44.85
41.57
50.40
56.03
37.59
6.7
6.8
5.9
6.4
2.6
0.3
6.2
a
All structures were optimized using the OPLS2005 force field in
Schrodinger Suite 2016-1.
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Fig. 9 Representative docking interactions of compounds in the tyrosine kinase binding domain of VEGFR2 (PDB ID: 1YWN, inhibitor-extracted
structure). (A–C) 1–3, (D) aqua complex, (E) HL, (F) axitinib, (G) SU5416, and cumulative docking structures: (H) 1 (green), axitinib (red), SU5416
(blue); (i) 1 (green), aqua complex (orange), HL (violet), axitinib (red).
where axitinib sits (Fig. 9E and I). It was found that Glu883
forms H-bonds with the metal complexes and axitinib.
Additionally, Asp1044, Cys1043, Asn1031, Arg1030, and Val846
are involved in either H-bonding or hydrophobic interactions
with axitinib, 2 and 3. Val846 is H-bonded with coordinated
halides/water except in the case of 1. Hence, many of the interacting residues were same for the complexes, axitinib or SU
5416 (Table S9†). The docking results using the native PDB
structure, after removal of the inhibitor, showed even better
results with our complexes than what is discussed above (see
comparisons of the docking scores in Table 2, Fig. S35 and
Table S10†).
with 1. There was a 1.5-fold decrease in Akt using 10 µM of 1
and a ca. 1.3-fold decrease for 50 µM of HL. However, in
addition to the VEGFR2 inhibition predicted by molecular
Western blot analysis
In order to probe the effects of HL and the complexes on
VEGFR2, we performed western blotting analysis with HepG2.
HepG2 and LNCaP are known to have good expression of
VEGFR2.77,78 The experiments were performed with two
different concentrations of HL and 1 to probe the effects. It
was found that both the ligand and 1 have the ability to
decrease Ras. The decrease of Ras was greater in cells treated
8548 | Dalton Trans., 2017, 46, 8539–8554
Fig. 10 Effects of ligand and 1 on VEGFR2, Akt and Ras expression in
HepG2 cells (western blot). β-Actin was used as the loading standard. All
normalisations were performed with respect to β-actin.
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docking, we also observed a 1.5 to 2.5-fold decrease of VEGFR2
using HL (30 µM) and 1 (10 µM) (Fig. 10). The in vitro cytotoxicity data in the cancer cell lines are in good agreement
with the known expression levels of VEGFR2 for the probed
cell lines.79 LNCaP and HepG2 have high levels of VEGFR2
expression,77 whereas it is relatively less in MIA PaCa-2.80,81
However, VEGFR2 is not the sole target, because VEGFR2
decreased and the complexes are equally cytotoxic to the
primary cell line HFF-1. Encouragingly, an in ovo assay to
probe the abilities of HL and 1 to reduce newer blood vessel
formation shows that treatment with 30 ng of HL or 1 exhibits
a decrease in new blood vessel formation (Fig. S36†). The
above result is suggestive of the anti-vascular properties of the
ligand and the complexes.
Conclusions
In summary, ternary benzimidazole-based Ru(II) p-cymene
complexes with different halide co-ligands showed that varying
the halide exchange rate and aquation by changing the halides
influences the pathways of cytotoxicity and the stabilities of
the complexes. The hydrolysis of 2 was slower and competed
with halide exchange. Complex 2 showed the least caspase 8
activation and 3 showed the most caspase 8 activation,
suggesting that the pathways of action are different for 1–3.
The changes in mitochondrial membrane potential for 1–3
suggest that although the caspase 8 activation pathways may
be different, the complexes ultimately lead to intrinsic pathways of apoptosis involving the mitochondria. The intact or
aquated complexes are moderate inhibitors of the tyrosine
kinase domain of VEGFR2; however, the ligand is a better
inhibitor, as suggested by comparative docking studies. The
complexes are less stable in the presence of excess GSH.
Complex 1 and HL also have the ability to downregulate
VEGFR2. The abilities of the complexes to impair mitochondrial function by changing the transmembrane potential may
lower cellular GSH production, thus preventing massive deactivation by intracellular GSH. The complexes show excellent
anti-cell migratory activities and anti-vascular properties at
almost non-toxic dosages in vitro.
Experimental
General
All chemicals and solvents were purchased from commercial
sources. Solvents were distilled and dried prior to use by standard procedures.82 The starting material [(η6-p-cymene)RuCl2]2
was prepared by the reaction of RuCl3·xH2O with
α-phellandrene,17 and the corresponding bromo and iododimers were synthesized from [(η6-p-cymene)RuCl2]2 with excess
KBr or KI.18 All the solvents were degassed, and the reactions
were carried out under an atmosphere of dry nitrogen by following standard Schlenk techniques. MTT [(3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide)] (USB) and all
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Paper
cell growth media and their supplements were purchased from
Gibco. All the solvents used for spectroscopy and lipophilicity
measurements were of spectroscopy grade and were purchased
from Merck. The melting points of the compounds were
measured in triplicate with one-end sealed capillaries using a
SECOR (India) melting point apparatus, and the uncorrected
values are reported. UV-Visible measurements were performed
using either an Agilent Technologies Cary 300 Bio or
PerkinElmer Lambda 35 spectrophotometer. FT-IR spectra
were recorded using a PerkinElmer SPECTRUM RX I spectrometer in KBr pellets. NMR spectra were recorded using either
a JEOL ECS 400 MHz or Bruker Avance III 500 MHz spectrometer at ambient temperature and were calibrated using
residual undeuterated solvents as an internal reference. All 13C
spectra reported are proton decoupled. The chemical shifts (δ)
are reported in parts per million ( ppm). Elemental analyses
were performed on a PerkinElmer CHN analyzer (Model 2400).
Electro-spray ionization mass spectra of the complexes (+ve
mode electrospray ionization) were obtained from Maxis
Impact UHR (Bruker Daltonics); for the ligand, a Q-Tof Micro
(WATERS) mass spectrometer was used. EPR spectra were
recorded on a Bruker Biospin EMXmicro X-band ESR spectrometer at room temperature. The ruthenium content was analysed on a Thermo Scientific XSERIES 2 ICP-MS instrument.
The synthetic yields are reported for the isolated analytically
pure compounds. The synthesized ligands and complexes were
dried in vacuum and stored in a desiccator. Human blood was
collected from a volunteer, and all work was performed following institute ethical guidelines.
Synthesis and characterization
Synthesis of bis(3,5-dimethyl pyrazole)carboxylic acid
(bdmpza). The compound was synthesized using a modified
literature procedure.83 Yield = 57%.
Synthesis of (bis(3,5-dimethyl-1H-pyrazol-1-yl)methyl)-1Hbenzo[d]imidazole (HL). The ligand was prepared following a
literature procedure.52 A mixture of o-phenylenediamine
(1 mmol) and bdmpza (1.0 mmol) was boiled in dry toluene
(100 mL) using a Dean–Stark apparatus for 10 min. Next,
10 mol% of boric acid powder was added, and the reflux was
continued overnight. The next day, the entire hot solution was
poured into a large excess of cooled hexane. A rapid formation
of turbidity was observed in the solution, and the entire
mixture was maintained at 4 °C for another 2 h. After that, the
solution mixture was filtered, and the precipitate was collected
on filter paper. The precipitate was the desired ligand;
however, due to the prolonged heating, a small amount of
degraded o-phenylenediamine was found in the product.
Therefore, further purification of the product was performed
by active charcoal treatment of the solid dissolved in dichloromethane. Yield = 45%. Mp: 228 °C. Anal. calcd for C18H20N6:
C, 67.48; H, 6.29; N, 26.23. Found: C 67.40; H 6.31; N 26.15.
FT-IR (KBr Pellet): 3244sh, 3058m, 2920m, 2357w, 1566m,
1556m, 1434s, 1413s, 1446s, 1318m, 1276sh, 1232m, 1191sh,
1142m, 1027w, 854sh, 797m, 741sh, 660w. UV-vis in CH3OH
[λmax/nm (ε/dm3 mol−1 cm−1)]: 282 (7630), 275 (8370), 254
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(7800), 247 (8000). 1H NMR (400 MHz, DMSO-d6) δ 12.23 (s,
1H, NH), 7.92 (s, H1, CH), 7.61–7.22 (m, 2H, H9, H12, Ar),
7.22–7.17 (m, 2H, H10, H11, Ar), 5.93 (s, 2H, H3, H5, CHpz),
2.19 (s, 6H, H6, H17, CH3), 2.09 (s, 6H, H5, H18, CH3). 13C
NMR (400 MHz, DMSO-d6) δ 148.03 (C4), 147.32 (C16), 142.52
(C7), 140.58 (C2, C14), 134.60 (C8, C13), 122.71 (C11), 121.49
(C10), 119.05 (C12), 112.14 (C9), 106.70 (C3, C15), 68.51 (C1),
13.48 (C6, C18), 10.92 (C5, C17). ESI-MS (CH3OH) (m/z): 321.18
[M + H]+ (calcd 321.18), 343.18 [M + Na]+ (calcd 343.17).
Syntheses of 1–3
All the complexes were prepared using the same procedure.
The metal precursors for the different halide co-ordinations
were prepared following a previously reported literature procedure. [(η6-p-Cymene)2Ru(Cl)2] for 1, [(η6-p-cymene)2Ru(Br)2]
for 2 and [(η6-p-cymene)2Ru(I)2] for 3 were used. In general, HL
(1.0 mmol) was first dissolved in dry dichloromethane solution,
and the solution was maintained under N2 atmosphere after
degassing. Then, the respective ruthenium(II) precursors were
dissolved in the same solvent and added dropwise to the ligand
solution. The resulting solution was then allowed to stir at high
speed for an additional 8 h. After that, the whole solution was
filtered, and the filtrate was evaporated to dryness. The dried
mass was washed with hexane and diethyl ether several times.
Further purification was performed by layering between
DCM–hexane solvent mixtures. This purification step afforded
pure, shiny crystals of the respective metal complexes (1–3).
Caution! All the compounds reported in this work are suspected cancer-causing agents. Care should be exercised while
handling them.
[(η6-p-Cymene)2Ru(HL)(Cl)](Cl) (1). Yield = 60%. Mp.:
195 °C. Λm (acetonitrile: water, 1 : 1; 10−3 M): 40 S cm2 mol−1.
Anal. calcd for C28H34Cl2N6Ru: C, 53.67; H, 5.47; N, 13.41.
Found: C 53.40; H 5.51; N 13.22. FT-IR (KBr Pellet): 3432br,
3074m, 2979sh, 2923s, 2862, 2676m, 2415bs, 1728w, 1631m,
1556m, 1446sh, 1322sh, 1219sh, 1116m, 1061sh, 1026m,
889sh, 855m, 793w, 750s. UV-vis in CH3OH [λmax/nm (ε/dm3
mol−1 cm−1)]: 430 (560), 322 (1100), 282 (16 300), 273 (17 300).
1
H NMR (500 MHz, DMSO-d6) δ 14.26 (bs, 1H, –NH), 8.02 (s,
1H, H1, –CH), 7.91 (d, J = 8.11 Hz, 1H, H12, Ar), 7.79(d, J =
8.12 Hz, 1H, H9, Ar), 7.48–7.41 (m, 2H, H10, H11, Ar), 6.41 (s,
1H, H3, –CHpz), 6.14 (s, 1H, H15, –CHpz), 5.87 (d, J = 6.08 Hz,
1H, H21, p-cym), 5.79 (d, J = 6.08 Hz, 1H, H20, p-cym), 5.55 (d,
J = 5.98 Hz, 1H, H23, p-cym), 5.38 (d, J = 6.0 Hz, 1H, H24,
p-cym), 2.66 (s, 3H, H5, –CH3pz), 2.52 (s, 3H, H17, –CH3pz),
2.24–2.15 (m, 1H, H25, p-cym), 2.13 (s, 3H, 3H28, p-cym), 1.95
(s, 3H, H6, –CH3.Pz), 1.93 (s, 3H, H18, –CH3pz), 1.04 (d, J = 6.85
Hz, 3H, H26, p-cym), 0.97 (d, J = 6.85 Hz, 1H, H27, p-cym). 13C
NMR (500 MHz, DMSO-d6) δ 157.18 (C13), 148.18 (C16), 147.29
(C4), 144.06 (C7), 141.35 (C14), 140.50 (C2), 132.17 (C8), 125.04
(C10), 123.40 (C11), 120.29 (C12), 113.51 (C9), 109.64 (C3),
109.21 (C15), 104.60 (C19), 101.68 (C22), 83.44 (C21), 83.27
(C20), 82.26 (C23), 81.90 (C24), 64.07 (C1), 30.10 (C25), 22.48
(C27), 22.17 (C26), 17.66 (C18), 16.58 (C5), 13.04 (C28), 11.81
(C17), 10.65 (C6). ESI-MS (CH3OH) (m/z): 591.1632 [M]+ (calcd
591.1577).
8550 | Dalton Trans., 2017, 46, 8539–8554
Dalton Transactions
[(η6-p-Cymene)2Ru(HL)(Br)](Br) (2). Yield = 65%. Mp:
200 °C. Λm (acetonitrile : water, 1 : 1; 10−3 M): 44 S cm2 mol−1.
Anal. calcd for C28H34Br2N6Ru: C, 47.00; H, 4.79; N, 11.75.
Found: C 47.14; H 4.82; N 11.80. FT-IR (KBr Pellet): 3432br,
3061w, 2972s, 2923s, 2869s, 2697bs, 2614s, 2367sh, 2339m,
1624m, 1563m, 1435bs, 1322sh, 1274sh, 1212sh, 1109sh,
1082w, 1058sh, 1027sh, 924w, 896w, 868s, 807sh, 752sh. UVvis in CH3OH [λmax/nm (ε/dm3 mol−1 cm−1)]: 448 (575), 324
(1280), 282 (14 600), 272 (15 700). 1H NMR (500 MHz, DMSOd6) δ 13.98 (bs, 1H, –NH), 7.94 (d, J = 7.95 Hz, 1H, H12, Ar),
7.91 (s, 1H, H1, –CH), 7.81(d, J = 7.71 Hz, 1H, H9, Ar), 7.47 (td,
J = 15.12, 7.10 Hz, 2H, H10, H11, Ar), 6.48 (s, 1H, H3, –CHpz),
6.17 (s, 1H, H15, –CHpz), 5.92 (d, J = 6.21 Hz, 1H, H21, p-cym),
5.83 (d, J = 6.09 Hz, 1H, H20, p-cym), 5.63 (d, J = 6.37 Hz, 1H,
H23, p-cym), 5.57 (d, J = 6.01 Hz, 1H, H24, p-cym), 2.68 (s, 3H,
H5, –CH3pz), 2.17–2.12 (m, 1H, H25, p-cym), 2.12 (s, 3H, H28,
p-cym), 1.99 (s, 3H, H6, –CH3Pz), 1.95 (s, 3H, H18, –CH3pz),
1.04 (d, J = 6.85 Hz, 3H, H26, p-cym), 0.88 (d, J = 6.85 Hz, 1H,
H27, p-cym). 13C NMR (500 MHz, DMSO-d6) δ 158.02 (C13),
148.45 (C16), 147.59 (C4), 144.02 (C7), 142.24 (C14), 140.66
(C2), 125.17 (C10), 123.36 (C11), 121.04 (C12), 113.67 (C9),
110.01 (C3), 109.20 (C15), 106.65 (C8), 105.63 (C19), 101.32
(C22), 83.22 (C20), 82.82 (C21), 82.56 (C23, C24), 64.35 (C1),
30.15 (C25), 22.51 (C27), 22.09 (C26), 17.89 (C18), 17.71 (C5),
13.42 (C28), 11.84 (C17), 10.54 (C6), ESI-MS (CH3OH) (m/z):
635.1130 [M]+ (calcd 635.1072).
[(η6-p-Cymene)2Ru(HL)(I)](I) (3). Yield = 58%. Mp: 218 °C.
Λm (acetonitrile : water, 1 : 1; 10−3 M): 54 S cm2 mol−1. Anal.
calcd for C28H34I2N6Ru: C, 41.55; H, 4.23; N, 10.38. Found:
C 41.70; H 4.21; N 10.29. FT-IR (KBr Pellet): 3436br, 3054s,
2965s, 2962s, 2948s, 2914s, 2614w, 2367w, 1621m, 1535,
1453sh, 1413sh, 1378s, 1322sh, 1272sh, 1212sh, 1164w,
1109sh, 1061sh, 1031sh, 924w, 868sh, 807sh, 751sh. UV-vis in
CH3OH [λmax/nm (ε/dm3 mol−1 cm−1)]: 466 (760), 282 (10 890),
272 (11 090). 1H NMR (500 MHz, DMSO-d6) δ 13.94 (bs, 1H,
–NH), 7.94–7.91 (m, 2H, H1, –CH & H12, Ar), 7.79 (d, J = 8.22
Hz, 1H, H9, Ar), 7.52–7.42 (m, 2H, H10 & H11, Ar), 6.49 (s, 1H,
H3, –CHpz), 6.17 (s, 1H, H15, –CHpz), 5.92 (dd, J = 4.90, 8.11
Hz, 2H, H21 & H20, p-cym), 5.73 (d, J = 5.87 Hz, 1H, H23,
p-cym), 5.68 (d, J = 6.11 Hz, 1H, H24, p-cym), 2.67 (s, 3H, H5,
–CH3pz), 2.18–2.15 (m, 1H, H25, p-cym), 2.12 (s, 3H, H28,
p-cym), 2.09 (s, 3H, H18, –CH3pz), 1.98 (s, 3H, H6, –CH3Pz),
1.05 (d, J = 6.91 Hz, 3H, H26, p-cym), 0.81 (d, J = 6.84 Hz, 1H,
H27, p-cym). 13C NMR (500 MHz, DMSO-d6) δ 158.92 (C13),
148.55 (C16), 147.80 (C4), 143.86 (C7), 143.41 (C14), 140.63
(C2), 125.18 (C10), 123.09 (C11), 122.23 (C12), 113.62 (C9),
110.17 (C3), 109.02 (C15), 107.38 (C8), 106.66 (C19), 100.84
(C22), 83.23 (C20), 83.12 (C21), 83.09 (C23), 82.00 (C24), 64.31
(C1), 30.21 (C25), 22.85 (C27), 22.70 (C26), 19.65 (C5), 18.50
(C18), 13.16 (C28), 11.84 (C17), 10.53 (C6). ESI-MS (CH3OH)
(m/z): 683.1010 [M]+ (calcd 683.0933).
X-ray crystal structure determination
Single crystals of HL, 1 and 2 were obtained by layering a dichloromethane solution with hexane and were mounted using
loops on the goniometer head. The crystal structure of 1 was
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Dalton Transactions
determined using a Bruker Apex Kappa II diffractometer and
HL; the structure of 2 was determined using SuperNova, Dual,
Mo at zero, Eos diffractometer. The crystal was maintained at
100.01(11) K during data collection, and a Mo-Kα radiation
source was used. Appropriate software packages were used
to solve the crystal structures with ShelXS84,85 using Direct
Methods, and the structures were refined with the ShelXL85
refinement package using Least Squares minimisation.
The crystallographic data for the structures have been
deposited at the Cambridge Crystallographic Data Centre as a
supplementary publication: CCDC 1507224 (HL), 1507225 (1),
1507226 (2).†
Computational details
Theoretical calculations were performed using the Gaussian09
programme.86 Geometry-optimised structures of HL and 1–3
were derived by density functional theory (DFT) using the
B3LYP function87 with the Stuttgart/Dresden (SDD) effective
core potential (ECP) basis set for the Ru(II) centre88 and 6-31G
(d,p) for carbon and nitrogen. For the chloro and bromo analogues (1 and 2), 6-31G (2d,p) was used, and for the iodo analogue (3), the SDD basis set was used. The higher order basis
sets were used to compute the pseudopotentials on the metal.
In each calculation, methanol was used as the solvent with a
conductor-like polarizable continuum model (CPCM).89–91
Solution stabilities of the compounds
The stabilities of the compounds in solution were determined
using both UV-vis and 1H NMR spectroscopy. The solutions
were degassed prior to use and adjusted to the desired pD
using DCl or NaOD. The pD values reported in the current
study are uncorrected.92 The phosphate buffer solutions (PBS)
used for stability studies had the following composition: 8 mM
Na2HPO4 and 1.5 mM KH2PO4 in either H2O or D2O. Sodium
chloride was added as necessary, and the pH/pD was adjusted
to 7.4. The buffered solutions were degassed after the final pD
adjustment.
Compound interactions with glutathione and 9-ethylguanine
The interactions of the compounds with reduced glutathione
(GSH) were monitored using 1H NMR spectroscopy in DMSOd6–PBS (2 : 8 v/v) containing 4 mM NaCl, pD = 7.4. Excess GSH
(10 eq.) was first dissolved in phosphate-buffered solution in
D2O and was added to the DMSO-d6 solution of the complex to
maintain the desired solvent ratio. Data recording was started
after immediate addition and mixing with GSH. The spectra
were recorded at room temperature and plotted over time. In
the case of 9-ethylguanine (9-EtG), a similar protocol for the
solvent mixture was followed; however, only 2.5 equivalents of
9-EtG were added. In all cases, the spectra were recorded up to
24 h.
Statistical analysis
The cytotoxicity data are presented as statistical mean ± SD
(standard deviation). The cutoff p value for significance was
set at p = 0.05. Hence, *p ≤ 0.05 and **p ≤ 0.005 were con-
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Paper
sidered to be statistically significant. The statistical comparison analysis was performed using the one sample t-test.
GraphPad Prism® V5.04 was used to perform all statistical
analysis.
Molecular docking
Molecular modelling for prediction of the possible modes of
binding of the complexes was carried out using the GOLD
(Genetic Optimization for Ligand Docking) Suite (Version
5.4.1).93 GOLD generally adopts the genetic algorithm to dock
flexible molecules (ligands) into protein (macromolecule) sites.
The GOLD Score was used as a search algorithmic function for
more effective complexes; it has been reported to give superior
results to Chemscore in GOLD.94 A higher GOLD Score fitness
value indicates a better binding interaction in the binding site.
Inhibitor-bound vascular endothelial growth factor receptor-2
(VEGFR2) (PDB entry 1YWN)93 was used to dock our metal
complexes. All the metal complexes (see the previous section
for the methods), axitinib and SU5416 were optimized by
Gaussian09 using water as the solvent in the CPCM model.
Axitinib and SU5416 were optimized at the DFT level of theory
using the B3LYP/6-31G method. The PDB structure was optimized after removing the bound inhibitor and processed by
applying the OPLS 2005 force field by the protein preparation
utility in Maestro Suite 2016-1 in Maestro (Schrödinger Suite
2016-1 Protein Preparation Wizard; Epik, Schrödinger, LLC,
New York, NY, 2016; Impact, Schrödinger, LLC, New York, NY,
2016; Prime, Schrödinger, LLC, New York, NY, 2016). The
binding site for the protein was also determined using the
SiteMap utility in the same software (Schrödinger Release
2016-1: SiteMap, Schrödinger, LLC, New York, NY, 2016). The
coordinates of the best site (score 1.082) are as follows: X =
1.75, Y = 39.49, Z = 15.87. Then, the optimized protein structures were used in the GOLD docking wizard to add necessary
hydrogens. Water molecules that were not involved in binding
interactions with the inhibitor or the active site were eliminated. The binding site was defined by centering the predicted
site coordinates and the binding sphere, defined as a sphere
containing the active site residues within 6 Å from the centre.
The binding sphere was large enough to cover the ATP binding
site. GOLD Score was selected as the scoring function, leaving
other parameters as the defaults.
GOLD score:
Fitness ¼ Sðhbext Þ þ 1:3750 � SðvdWext Þ þ Sint þ Sintcor
where S(hbext) is the protein–ligand hydrogen bond score,
S(vdWext) is the protein–ligand van der Waals score, Sint is the
ligand internal vdW energy, and Sintcor is the ligand torsional
strain energy.
The fitness score is the negative of all the energy terms in
the equation.40 Therefore, a more positive score indicates
superior affinity of the entry.
For validation of the docking, we used the native PDB structure. In that case, the docking site was chosen as 6 Å within
the bound inhibitor after extraction.
Dalton Trans., 2017, 46, 8539–8554 | 8551
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Acknowledgements
We sincerely acknowledge SERB-India for financial support
(vide project no. SB/S1/IC-02/2014). We are also thankful to
IISER Kolkata for infrastructural support. S. B. wishes to thank
CSIR-India and K. P. wishes to thank UGC-India for providing
research fellowships.
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