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Transfer Hydrogenation and Antiproliferative Activity of Tethered Half-Sandwich Organoruthenium Catalysts.
We report the synthesis
and characterization of four neutral organometallic
tethered complexes, [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -R)Cl], where R = methanesulfonyl
(Ms, 1 ), toluenesulfonyl (Ts, 2 ), 4-trifluoromethylbenzenesulfonyl
(Tf, 3 ), and 4-nitrobenzenesulfonyl (Nb, 4 ), including their X-ray crystal structures. These complexes exhibit
moderate antiproliferative activity toward human ovarian, lung, hepatocellular,
and breast cancer cell lines. Complex 2 in particular
exhibits a low cross-resistance with cisplatin. The complexes show
potent catalytic activity in the transfer hydrogenation of NAD + to NADH with formate as hydride donor in aqueous solution
(310 K, pH 7). Substituents on the chelated ligand decreased the turnover
frequency in the order Nb > Tf > Ts > Ms. An enhancement
of antiproliferative
activity (up to 22%) was observed on coadministration with nontoxic
concentrations of sodium formate (0.5–2 mM). Complex 2 binds to nucleobase guanine (9-EtG), but DNA appears not
to be the target, as little binding to calf thymus DNA or bacterial
plasmid DNA was observed. In addition, complex 2 reacts
rapidly with glutathione (GSH), which might hamper transfer hydrogenation
reactions in cells. Complex 2 induced a dose-dependent
G 1 cell cycle arrest after 24 h exposure in A2780 human
ovarian cancer cells while promoting an increase in reactive oxygen
species (ROS), which is likely to contribute to its antiproliferative
activity.
## Introduction
Introduction The
clinical anticancer drug cisplatin arose from the serendipitous
discovery of its biological anticancer activity by Rosenberg et al.
about 50 years ago. 1 Since then, anticancer
complexes based on other platinum-group metals (Ru, 2 − 4 Rh, 5 − 8 Os, 9 − 11 Ir, 12 , 13 and Pd 14 − 17 ) have been studied. Ruthenium
complexes have shown promising potential with relatively low toxicity
and might provide alternatives to platinum drugs. These Ru complexes
also have the potential to overcome the severe side effects and drug
resistance which are problems with some platinum-based chemotherapeutics. 18 , 19 The two Ru III complexes NAMI-A and KP-1019 ( Figure 1 ) have entered phase II clinical trials, the former as an antimetastatic
agent. 20 − 22 The mode of action of NAMI-A and KP-1019 in cancer cells is not yet understood, but the reduction
of Ru III to Ru II is a plausible pathway for
their activation. 23 , 24 The Ru II complex [Ru(η 6 - p -cym)Cl 2 (PTA)] ( p -cym = para-cymene, PTA = 1,3,5-triaza-7-phosphatricyclo[3.3.1.1]decane; RAPTA in Figure 1 ) also exhibits promising antimetastatic effects in vitro and in
vivo 25 and has antiangiogenic activity
toward chicken chorioallantoic membranes with low dose-dependent antiproliferative
activity. 26 [(η 6 -biph)Ru(en)Cl]PF 6 (biph = biphenyl, en = ethylenediamine; RM175 in Figure 1 ) is believed
to target DNA and can bind to guanine bases accompanied by arene intercalation.
It can also induce oxidation of bound glutathione (GSH), which can
be displaced by guanine, providing a redox-mediated route to DNA binding. 27 , 28 Figure 1 Organometallic
half-sandwich Ru II and Ru III ( NAMI-A and KP-1019 ) anticancer agents
and catalytic transfer hydrogenation catalysts. Organometallic half-sandwich Ru II complexes also
exhibit
catalytic activity in transfer hydrogenation (TH) reactions using
a variety of reducing agents as a hydride source (e.g., H 2 , isopropyl alcohol, and sodium formate). 29 − 32 The Noyori-type Ru II complex [(η 6 - p -cym)Ru(TsDPEN)Cl]
(TsDPEN = ( R,R )- N -( p -toluenesulfonyl)-1,2-diphenylethylenediamine) is an efficient catalyst
for the asymmetric transfer hydrogenation of ketones and amines with
high yields and enantiomeric excesses using isopropyl alcohol or formic
acid as hydride source ( Figure 1 ). 33 , 34 The sulfonyl Ru II complex
[(η 6 -arene)Ru(TsEn)Cl] (TsEn = toluenesulfonylethylenediamine)
is a more water soluble catalyst and, under biologically relevant
conditions, can reduce the coenzyme nicotinamide adenine dinucleotide
(NAD + ) in vitro and in cells using nontoxic doses of sodium
formate as hydride donor ( JS2 in Figure 1 ). 35 − 37 Mammalian cells can often tolerate
millimolar levels of formate without observed toxicity. 35 , 37 Tethered Ru II half-sandwich compounds in which
the η 6 -arene ring and a diamine ligand are connected
through a three
(or four-)-atom chain have a “locked” arene ring, providing
control over the spatial positions of the substituents on the ethylenediamine
ligands, and have enhanced stability. 38 , 39 Wills et al.
have reported a series of tethered Ru II η 6 -arene complexes and used them as efficient catalysts in the transfer
hydrogenation reactions of ketones and amines. 40 , 41 However, there have been few investigations on the antiproliferative
activity of tethered Ru II complexes. Recently, chiral tethered
Ru II complexes (two enantiomers) were synthesized and found
to have potent antiproliferative activity toward a panel of NCI-60
cancer cell lines (IC 50 against A2780 ovarian cancer cells
as low as 1.1 μM; Figure 2 ). Interestingly, their potency increased by up to 25% upon
coincubation of the cancer cells with formate. 42 Figure 2 Enantiomers of chiral tethered Ru II TsDPEN complexes. Here we have synthesized and characterized
the water-soluble tethered
Ru II complexes [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -R)Cl], where R =
methanesulfonyl (Ms, 1 ), toluenesulfonyl (Ts, 2 ), 43 4-trifluoromethylbenzenesulfonyl
(Tf, 3 ), or 4-nitrobenzenesulfonyl (Nb, 4 ), including determination of their X-ray crystal structures, and
investigated their catalytic TH reduction of NAD + to NADH
using sodium formate as a hydride source under biologically relevant
conditions. The interaction of complex 2 with the abundant
intracellular tripeptide γ- l -Glu- l -Cys-Gly
(GSH) and the effect of GSH on catalytic TH reduction of NAD + were also studied. We also investigated the effect of nontoxic concentrations
of formate on the antiproliferative activity of these complexes in
several human cancer cell lines, the induction of reactive oxygen
species (ROS), and changes in integrity of their cell membranes.
## Results
Results Synthesis
and Characterization The four neutral tethered
Ru II complexes [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -R)Cl], where R =
Ms ( 1 ), Ts ( 2 ), Tf ( 3 ), and
Nb ( 4 ), were synthesized following a literature method
for related complexes ( Scheme 1 ). They were characterized by elemental analysis (CHN), high-resolution
mass spectrometry, and NMR ( 1 H, 13 C, and 19 F) spectroscopy ( Figures S1–S9 in the Supporting Information). Scheme 1 Synthesis Route for Tethered Ru II Complexes 1 – 4 DME = 1,2-dimethoxyethane. Crystals of complexes 1 – 4 suitable
for X-ray diffraction were obtained from a slow diffusion of diethyl
ether into methanol solutions of the complexes at ambient temperature.
The complexes adopt the expected pseudo-tetrahedral geometry with
η 6 -phenyl ring occupying three Ru coordination sites,
together with nitrogen atoms of the diamine ligand (bond lengths 2.11–2.15
Å) and a monodentate chloride; ethylenediamine ligands are deprotonated
and bound as monoanionic bidentate ligands. Generally, the Ru–N(H)
bond distance (range 2.140–2.149 Å) is slightly longer
than that of Ru–N( − ) (2.112–2.121
Å). The η 6 -phenyl ring and ethylenediamine are
linked by a three-carbon tether chain. The structures are shown in Figure 3 . Selected bond lengths
(Å) and bond angles (deg) are given in Table 1 and X-ray crystallographic data in Tables S1–S5 . Figure 3 ORTEP diagrams for Ru II complexes 1 – 4 . Thermal
ellipsoids are shown at the 50% probability level.
All hydrogen atoms have been omitted for clarity. Table 1 Selected Bond Lengths (Å) and
Angles (deg) for Complexes 1 – 4 1 2 3 4 Ru1–N( − ) a 2.121(2) 2.1181(14) 2.1202(16) 2.1124(18) Ru1–N(H) b 2.146(2) 2.1490(14) 2.1485(16) 2.140(2) Ru1–Cl1 2.4174(6) 2.4234(4) 2.4243(4) 2.4142(6) Ru1–arene (centroid) 1.654 1.657 1.658 1.653 N( − )–Ru1–N(H) 78.77(8) 78.87(5) 78.87(6) 78.54(7) N( − )–Ru1–Cl1 88.17(6) 88.29(4) 87.33(4) 87.24(5) N(H)–Ru1–Cl1 83.20(6) 83.02(4) 83.56(5) 83.43(6) a N( − ) corresponds
to N103(1), N9(2,3), and N8(4). b N(H) corresponds to N106(1), N12(2,3),
and N11(4). p K a * Determination and Interaction
with Guanine The p K a * value of
the aqua adduct 2a (from complex 2 ) in MeOD- d 4 /D 2 O (1/9, v/v) was determined by 1 H NMR at 310 K ( Figure S10A in
the Supporting Information) by titration over the pH* (meter reading)
range from 2 to 12 and plots of the chemical shift of a tosyl proton
as a function of pH* fitted to the Henderson–Hasselbalch equation.
The p K a * value of aqua complex 2a was found to be 9.52 ± 0.03; a second p K a * value of <2 was too low to be determined. The interaction
of complex 2 with the DNA nucleobase model 9-ethylguanine
(9-EtG; Figure S10B in the Supporting Information)
was studied by 1 H NMR spectroscopy. Complex 2 (2 mM in MeOD- d 4 /D 2 O, 1/9
(v/v)) reacted rapidly with 9-EtG (1 mM in D 2 O, within
10 min) at 310 K. The adduct 2 -9-EtG gave rise to a new
set of η 6 -arene peaks ( Figure S10B in the Supporting Information), with up to 90% yield of 2 -9-EtG when a 1.5 mol equiv 9-EtG solution was added. A preliminary 1 H NMR study indicated that histidine
can also displace the chloride ligand on 2 and form a
stable adduct ( Figure S10C in the Supporting
Information), as might be expected, since, like guanine, it also contains
an imidazole ring. Transfer Hydrogenation Reactions Catalytic transfer
hydrogenation reactions of complexes 1 – 4 and sodium formate as hydride donor for conversion of nicotinamide
adenine dinucleotide (NAD + ) to NADH were studied in aqueous
media by UV–visible spectroscopy by following the absorbance
at 340 nm for NADH and by 1 H NMR spectroscopy (20% DMSO- d 6 in D 2 O) by monitoring peaks corresponding
to 1,4-NADH. The reactions were performed in the mixed solvent DMSO- d 6 /D 2 O (1/4, v/v) to ensure the solubility
of these complexes, although it was found earlier that the rates of
such TH reactions are enhanced in methanol, which like DMSO is a solvent
of lower polarity in comparison to water. 36 All of the tethered Ru II complexes exhibited potent
catalytic activity, with TOFs by UV–vis and NMR spectroscopy
in the ranges 3.7–8.9 and 5.8–9.9 h –1 , respectively ( Table 2 ), following the order 1 < 2 < 3 < 4 , suggesting that more strongly electron
withdrawing groups on the ethylenediamine ligand facilitate hydride
transfer between formate and NAD + . Table 2 TOFs (h –1 ) for Transfer
Hydrogenation Reactions of NAD + to NADH using Complexes 1 – 4 as Catalysts and Formate as Hydride
Donor complex R TOF (NMR) TOF (UV–vis) 1 Ms 3.79 ± 0.05 5.8 ± 0.2 2 Ts 4.7 ± 0.1 8.3 ± 0.1 3 Tf 8.9 ± 0.3 8.69 ± 0.07 4 Nb 8.5 ± 0.2 9.9 ± 0.2 The TH reactions were
also studied by NMR in solutions with a higher
DMSO- d 6 /D 2 O ratio. Above 20%
DMSO, the rate increased markedly ( Figure S11 in the Supporting Information), and that with 80% DMSO was too fast
to follow by NMR. Interaction with Glutathione (GSH) The reaction of
complex 2 ([Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl]) with GSH was initially
monitored by 1 H NMR. As shown in Figure S2 in the Supporting Information, the low-field η 6 -phenyl peaks of complex 2 decreased gradually,
and a new set of triplets (H1′ and H2′) emerged when
0.2 and 0.5 mol equiv of GSH were added. The low-field resonances
of the tosyl protons of complex 2 (H1 and H2) disappeared
and a new set of peaks (H1′–H7′) appeared when
1 mol equiv or more of GSH was added ( Figure S12 in the Supporting Information). The reaction was confirmed by LC-MS,
which revealed that the 2 -SG adduct was formed rapidly
when 2 was mixed with GSH ( Figure S13 in the Supporting Information). The eluents are shown in Figure S14 in the Supporting Information. Next, the time dependence of the reaction of complex 2 with GSH was studied under similar conditions: 2 mM 2 in MeOD- d 4 /D 2 O (2/8 v/v)
with 20 mM GSH, monitored by 1 H NMR spectroscopy from 5
min to 24 h ( Figure 4 ). As in the above experiments, a new set of low-field resonances
appeared immediately (H1′–H6′) in the presence
of excess GSH (10 mol equiv), but with time, the low-field resonances
H1′–H6′ decreased gradually and disappeared after
24 h ( Figure 4 ); meanwhile,
another two new sets of peaks slowly appeared. The 2D NMR (COSY) spectrum
suggested that the 2 -SG adduct degraded with time to
release the neutral free ligand η 6 -Ph(CH 2 ) 3 -ethylenediamine- N (H)-Ts (assigned
to one of the two sets of low-field peaks, Figure S15 in the Supporting Information) with up to 70% of decomposition
observed within 5 h incubation at 310 K, as shown in Figure S16 in the Supporting Information. Such liberation
of free ligand was also detected by LC-MS at 333.21 m / z (calculated [ligand + H] + m / z 333.16, Figure S13 in the Supporting Information). Complex 1 (2
mM in MeOD- d 4 /D 2 O (1/4 v/v),
pH* 7) showed a behavior in reactions with GSH (10 mol equiv) similar
to that of complex 2 . 1 -SG adduct formed
rapidly but decomposed after 24 h incubation at 310 K. Complexes 3 and 4 (2 mM in DMSO- d 6 /D 2 O (1/4 v/v)) also reacted with GSH, but the
SG adduct appeared to be stable under these conditions, since the 1 H NMR spectra appeared to be unchanged after 24 h incubation
at 310 K (data not shown). Complexes 3 and 4 both have electron-withdrawing groups on the phenyl ring of the
sulfonamide substituent. Figure 4 Dependence on time of the interaction of complex 2 (2 mM in MeOD- d 4 /H 2 O (2/8
v/v)) with GSH (20 mM, in D 2 O, pH* adjusted to 7.2 ±
0.1), monitored by 1 H NMR (600 MHz) at 310 K. The two sets
of peaks for H1′–H7′ can be assigned to diastereomers;
free ligand resonances in the low-field region are shown in the dashed
red box. Reduction of NAD + by TH in the Presence of GSH Due to the thiophilic nature
and instability of complex 2 in the presence of GSH,
the influence of GSH on the conversion of
NAD + to NADH by TH from complex 2 with formate
as the hydride source was investigated. 1 H NMR spectra
(MeOD- d 4 /D 2 O (2/8 v/v)), at
pH* 7.2 and 310 K with complex 2 , NAD + , GSH,
and sodium formate in the mole ratio of 1/4/ X /25
(where X = 0.5, 1, 2 and 5, respectively) were recorded
every 5 min. The turnover frequency of NAD + to NADH decreased
slightly in the presence of 0.5 mol equiv of GSH (TOF 4.27 ±
0.05 h –1 ); however, the TOF decreased dramatically
to 1.35 h –1 when 1.0 mol equiv of GSH was present.
The hydride transfer reaction completely stopped when excess GSH was
added (2 or 5 mol equiv). Antiproliferative Activity The antiproliferative
activity
of tethered Ru II complexes 1 – 4 against human ovarian (A2780), lung (A549), hepatocellular
(HEPG2), breast (MCF7), and cisplatin-resistant ovarian (A2780Cis)
cancer cell lines and normal human lung fibroblast cells (MRC5) was
determined ( Table 3 ) and compared to that of the clinical drug cisplatin (CDDP). Complexes 1 – 4 exhibited good to moderate anticancer
activity against all of these cancer cell lines, with IC 50 values in the range of 7.3–>50 μM. Complex 2 displayed good anticancer activity against A2780 and cisplatin-resistant
A2780 cancer cells, with IC 50 values of 7.3 and 15 μM,
respectively. Remarkably, this complex exhibits a resistance index
(RI) of only 2 in comparison to 11 for cisplatin. The RI is the ratio
of the activity (IC 50 ) toward the resistant cell line in
comparison to the parental line and gives an indication of the capacity
of a complex to overcome platinum resistance. Furthermore, complex 4 exhibited anticancer activity against MCF7 cancer cells
similar to that of cisplatin, with an IC 50 value of 9.9
μM. The antiproliferative activity in A549 lung and HEPG2 hepatocellular
cancer cells has minimal variation among complexes 1 – 4 , with all IC 50 values averaging 32 and 25 μM,
respectively. Corresponding values for the normal fibroblast cell
line MRC5 are given in Table 3 . Table 3 In Vitro Anticancer Activity of Complexes 1 – 4 Against Various Cell Lines cell line a IC 50 (μM) complex A2780 A2780Cis A549 HEPG2 MCF 7 MRC 5 RI b 1 23 ± 1 >50 33 ± 1 27.8 ± 0.1 28.9 ± 0.9 31 ± 1 >2 2 7.3 ± 0.4 15 ± 1 37.6 ± 0.6 26 ± 4 33 ± 2 38 ± 1 2 3 >50 >50 31 ± 2 >50 24 ± 3 28 ± 3 n.d. 4 16.0 ± 0.3 >50 30 ± 1 23 ± 4 9.9 ± 0.5 26 ± 1 >3 CDDP 1.20 ± 0.02 13.4 ± 0.3 3.1 ± 0.1 5.7 ± 0.9 7.3 ± 0.2 12.8 ± 0.3 11 a Data are shown as means ± standard
deviations (STD), from duplicates of triplicates; cell viability was
assessed after 24 h drug exposure and 72 h recovery in drug-free medium.
Human cell lines: A2780, ovarian cancer; A2780Cis, cisplatin-resistant
ovarian cancer; A549, lung cancer; HEPG2, hepatocellular cancer; MCF7,
breast cancer; MRC5, normal lung fibroblasts. b RI denotes the resistance index
between A2780 ovarian cancer cells and its resistant derivative A2780Cis.
n.d. = not determined. Cellular
Accumulation of Ru Cellular Ru accumulation
from administration of the most promising complexes 2 and 4 in A2780 human ovarian cancer cells and A2780Cis
cells was determined. Complex 4 showed a higher cellular
Ru accumulation in comparison to complex 2 in both A2780
and A2780Cis ( Figure 5 ). The cellular Ru contents for complex 4 were 150 ±
38 ng per million A2780 cells and 241 ± 10 ng per million A2780Cis
cells, while the cellular Ru content from complex 2 was
much lower: 8.8 ± 0.9 and 7 ± 1 ng per million cells, respectively. Figure 5 Cellular
Ru accumulation in A2780 and A2780Cis ovarian cancer cells
exposed to equipotent IC 50 concentrations of complexes 2 and 4 . Cell Cycle Arrest Since complex 2 [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl] binds to the nucleobase guanine (9-EtG), it was possible
that DNA might be a target for anticancer activity. In order to investigate
this, the effects on the cell cycle of A2780 cells exposed to complex 2 at IC 50 and 2 × IC 50 concentrations
for 24 h were studied, using propidium iodide staining, and measured
using flow cytometry ( Figure 6 ). In comparison to negative control populations, a statistically
significant increase of the cell population in the G 1 phase
was observed, with percentages increasing to 75 ± 1% at IC 50 concentration and 85 ± 3% population at 2 × IC 50 concentration. This evidence of G 1 arrest with
lack of an accumulation of cells in the S phase might suggest that
DNA is not a major target and that complex 2 could have
a cytostatic effect on ovarian cancer cells. Nonetheless, studies
of the interaction of complex 2 with DNA were carried
out to investigate further (vide infra). Figure 6 Cell cycle arrest analysis
of A2780 human ovarian cancer cells
after 24 h of exposure to complex 2 at 310 K at IC 50 and 2 × IC 50 concentrations. Cell staining
for flow cytometry was carried out using PI/RNase. p Values were calculated after a t -test against the
negative control data: * p <0.05, ** p <0.01. ROS Induction in A2780
Human Ovarian Cancer Cells The
level of reactive oxygen species (ROS) in A2780 human ovarian cancer
cells induced by exposure to complex 2 was determined
at IC 50 concentration by flow cytometry fluorescence analysis
( Figure 7 ). The total
level of oxidative stress, including H 2 O 2 , peroxy
and hydroxyl radical, peroxynitrite, NO, and superoxide production,
was monitored using the green channel FL1 and orange channel FL2,
respectively. Increased ROS levels were detected in the majority of
the population of A2780 cells, with up to 82% of cells exhibiting
high fluorescence in the FL1-green channel. There is only a minimal
increase in the level of cellular superoxide ( Table S6 in the Supporting Information). Figure 7 ROS induction in A2780
cancer cells exposed to complex 2 . The FL1 channel detects
total oxidative stress, and the FL2 channel
detects superoxide production. Complex 2 is shown in
red and negative control in blue. p Values were calculated
after a t -test against the negative control data:
* p <0.05, ** p <0.01. Cell Membrane Integrity We further investigated the
effect of complex 2 on the cellular membrane integrity
of A2780 ovarian cancer cells using flow cytometry analysis of cells
exposed for 24 h to the ruthenium complex and stained in the dark
with propidium iodide. This experiment did not include fixation of
the cells prior to staining. The results show that there are no induced
changes in the membrane integrity of cancer cells, as there are no
statistical differences between the drug-exposed and negative control
cells ( Table S7 in the Supporting Information). Calf Thymus DNA and Bacterial Plasmid DNA The interaction
of complex 2 ([Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl]) with double-helical
calf thymus DNA (ct-DNA) and bacterial plasmid DNA was studied and
compared to that of nontethered [(η 6 - p -cym)Ru(TsEn)Cl] ( JS2 in Figure 1 ). 37 Double-helical
ct-DNA at a concentration of 32 μg mL –1 was
incubated with JS2 or complex 2 at r i values of 0.1 and 0.5 in 10 mM NaClO 4 at 310 K ( r i = the molar ratio of free
ruthenium complex to nucleotide phosphates at the onset of incubation
with DNA). The reaction was terminated after 24 h of incubation, and
samples were exhaustively dialyzed against water. The ruthenium content
in these samples was determined by flameless atomic absorption spectrometry
(FAAS) and the concentration of DNA by absorption spectrophotometry.
No detectable amount of ruthenium was found in samples of DNA treated
with JS2 or complex 2 , even at very high r i . Therefore, these compounds do not bind strongly
to high-molecular-mass DNA under the experimental conditions used. In further experiments, solutions containing plasmid DNA pBR322
(28 μg mL –1 ) and complex JS2 or
complex 2 in various molar ratios ( r i = 0.05–1) were incubated in 0.01 M NaClO 4 at 310 K for 24 h in the dark. Subsequently the samples were
directly mixed with the loading buffer and loaded onto a 1% agarose
gel running at 298 K in the dark with Tris-acetate-EDTA (TAE) buffer,
and the voltage was set at 25 V. There was no separation step before
the samples were loaded onto the gel to remove weakly bound complex,
if any. The gels were then stained with EtBr, followed by photography
with a transilluminator. As seen in Figure S17 , no significant
changes in the mobilities of supercoiled (SC) or open circle forms
(OC) were observed even at very high concentrations of Ru compounds
( r i = 1), indicating that these complexes
do not unwind DNA and do not form DNA adducts. No changes in intensities
of SC and OC forms also indicated that the Ru complexes do not cleave
DNA in the dark. Binding to Short Single- or Double-Stranded
Oligonucleotides Binding of complex 2 to short
single- or double-stranded
synthetic oligonucleotides was also investigated. A 50-mer oligonucleotide
(single- or double-stranded) was incubated with complex 2 or complex JS2 ( r i = 0.5,
concentration of oligonucleotide related to phosphates) in 0.05 M
NaClO 4 at 310 K in the dark. After 24 h the reaction was
stopped, and samples were exhaustively dialyzed against water. The
ruthenium contents in these samples were determined by FAAS, and the
concentrations of DNA were determined by absorption spectroscopy.
No Ru associated with single- or double-stranded oligonucleotides
treated with complex JS2 was found, whereas 3–4%
of Ru was bound to single-stranded oligonucleotide on incubation with
complex 2 , but no detectable amount of Ru was bound to
double-stranded oligonucleotide. Effect of Formate on Antiproliferative
Activity The
antiproliferative activity of tethered complexes 1 – 4 against A2780 human ovarian cancer cells in the presence
of sodium formate was determined ( Figure 8 ). Experiments included three sets of controls:
the first, negative controls, consisted of untreated cells (only vehicle
exposure), a second set was exposed to three concentrations of sodium
formate (0.5, 1, and 2 mM), and a third set was exposed to cisplatin
as positive controls. The results indicate that formate alone is not
toxic toward A2780 ovarian cancer cells under the conditions used,
as the statistical difference between the first two controls was never
significant ( Table S8 in the Supporting
Information). A2780 cancer cells were incubated with equipotent concentrations
of complexes 1 – 4 (1/3 × IC 50 ) and three concentrations of sodium formate (0.5, 1, and
2 mM) for 24 h. Following 72 h of recovery time in drug-free medium,
cell survival was evaluated using the Sulforhodamine B colorimetric
assay. A decrease in cell viability was observed, and importantly
this was greater with increasing concentrations of sodium formate.
Complex 4 showed the least effect on cell viability,
decreasing from 95% to 81%, while complex 1 exhibited
the highest changes, varying from 96% to 74% when 2 mM formate was
coadministered. Overall, the percentage of cell viability reduction
which accompanies formate coadministration follows the order 1 > 2 > 3 > 4 (percentages
of cell survival are given Table S8 in
the Supporting Information). Figure 8 Cell viability of A2780 ovarian cancer cells
on exposure for 24
h to complexes 1 – 4 (at equipotent
1/3 × IC 50 concentrations) and sodium formate at concentrations
of 0, 0.5, 1.0, and 2.0 mM. p Values were calculated
after a t -test against the negative control data:
* p <0.05, ** p <0.01.
## Synthesis
and Characterization
Synthesis
and Characterization The four neutral tethered
Ru II complexes [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -R)Cl], where R =
Ms ( 1 ), Ts ( 2 ), Tf ( 3 ), and
Nb ( 4 ), were synthesized following a literature method
for related complexes ( Scheme 1 ). They were characterized by elemental analysis (CHN), high-resolution
mass spectrometry, and NMR ( 1 H, 13 C, and 19 F) spectroscopy ( Figures S1–S9 in the Supporting Information). Scheme 1 Synthesis Route for Tethered Ru II Complexes 1 – 4 DME = 1,2-dimethoxyethane. Crystals of complexes 1 – 4 suitable
for X-ray diffraction were obtained from a slow diffusion of diethyl
ether into methanol solutions of the complexes at ambient temperature.
The complexes adopt the expected pseudo-tetrahedral geometry with
η 6 -phenyl ring occupying three Ru coordination sites,
together with nitrogen atoms of the diamine ligand (bond lengths 2.11–2.15
Å) and a monodentate chloride; ethylenediamine ligands are deprotonated
and bound as monoanionic bidentate ligands. Generally, the Ru–N(H)
bond distance (range 2.140–2.149 Å) is slightly longer
than that of Ru–N( − ) (2.112–2.121
Å). The η 6 -phenyl ring and ethylenediamine are
linked by a three-carbon tether chain. The structures are shown in Figure 3 . Selected bond lengths
(Å) and bond angles (deg) are given in Table 1 and X-ray crystallographic data in Tables S1–S5 . Figure 3 ORTEP diagrams for Ru II complexes 1 – 4 . Thermal
ellipsoids are shown at the 50% probability level.
All hydrogen atoms have been omitted for clarity. Table 1 Selected Bond Lengths (Å) and
Angles (deg) for Complexes 1 – 4 1 2 3 4 Ru1–N( − ) a 2.121(2) 2.1181(14) 2.1202(16) 2.1124(18) Ru1–N(H) b 2.146(2) 2.1490(14) 2.1485(16) 2.140(2) Ru1–Cl1 2.4174(6) 2.4234(4) 2.4243(4) 2.4142(6) Ru1–arene (centroid) 1.654 1.657 1.658 1.653 N( − )–Ru1–N(H) 78.77(8) 78.87(5) 78.87(6) 78.54(7) N( − )–Ru1–Cl1 88.17(6) 88.29(4) 87.33(4) 87.24(5) N(H)–Ru1–Cl1 83.20(6) 83.02(4) 83.56(5) 83.43(6) a N( − ) corresponds
to N103(1), N9(2,3), and N8(4). b N(H) corresponds to N106(1), N12(2,3),
and N11(4).
## p
p K a * Determination and Interaction
with Guanine The p K a * value of
the aqua adduct 2a (from complex 2 ) in MeOD- d 4 /D 2 O (1/9, v/v) was determined by 1 H NMR at 310 K ( Figure S10A in
the Supporting Information) by titration over the pH* (meter reading)
range from 2 to 12 and plots of the chemical shift of a tosyl proton
as a function of pH* fitted to the Henderson–Hasselbalch equation.
The p K a * value of aqua complex 2a was found to be 9.52 ± 0.03; a second p K a * value of <2 was too low to be determined. The interaction
of complex 2 with the DNA nucleobase model 9-ethylguanine
(9-EtG; Figure S10B in the Supporting Information)
was studied by 1 H NMR spectroscopy. Complex 2 (2 mM in MeOD- d 4 /D 2 O, 1/9
(v/v)) reacted rapidly with 9-EtG (1 mM in D 2 O, within
10 min) at 310 K. The adduct 2 -9-EtG gave rise to a new
set of η 6 -arene peaks ( Figure S10B in the Supporting Information), with up to 90% yield of 2 -9-EtG when a 1.5 mol equiv 9-EtG solution was added. A preliminary 1 H NMR study indicated that histidine
can also displace the chloride ligand on 2 and form a
stable adduct ( Figure S10C in the Supporting
Information), as might be expected, since, like guanine, it also contains
an imidazole ring.
## Transfer Hydrogenation Reactions
Transfer Hydrogenation Reactions Catalytic transfer
hydrogenation reactions of complexes 1 – 4 and sodium formate as hydride donor for conversion of nicotinamide
adenine dinucleotide (NAD + ) to NADH were studied in aqueous
media by UV–visible spectroscopy by following the absorbance
at 340 nm for NADH and by 1 H NMR spectroscopy (20% DMSO- d 6 in D 2 O) by monitoring peaks corresponding
to 1,4-NADH. The reactions were performed in the mixed solvent DMSO- d 6 /D 2 O (1/4, v/v) to ensure the solubility
of these complexes, although it was found earlier that the rates of
such TH reactions are enhanced in methanol, which like DMSO is a solvent
of lower polarity in comparison to water. 36 All of the tethered Ru II complexes exhibited potent
catalytic activity, with TOFs by UV–vis and NMR spectroscopy
in the ranges 3.7–8.9 and 5.8–9.9 h –1 , respectively ( Table 2 ), following the order 1 < 2 < 3 < 4 , suggesting that more strongly electron
withdrawing groups on the ethylenediamine ligand facilitate hydride
transfer between formate and NAD + . Table 2 TOFs (h –1 ) for Transfer
Hydrogenation Reactions of NAD + to NADH using Complexes 1 – 4 as Catalysts and Formate as Hydride
Donor complex R TOF (NMR) TOF (UV–vis) 1 Ms 3.79 ± 0.05 5.8 ± 0.2 2 Ts 4.7 ± 0.1 8.3 ± 0.1 3 Tf 8.9 ± 0.3 8.69 ± 0.07 4 Nb 8.5 ± 0.2 9.9 ± 0.2 The TH reactions were
also studied by NMR in solutions with a higher
DMSO- d 6 /D 2 O ratio. Above 20%
DMSO, the rate increased markedly ( Figure S11 in the Supporting Information), and that with 80% DMSO was too fast
to follow by NMR.
## Interaction with Glutathione (GSH)
Interaction with Glutathione (GSH) The reaction of
complex 2 ([Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl]) with GSH was initially
monitored by 1 H NMR. As shown in Figure S2 in the Supporting Information, the low-field η 6 -phenyl peaks of complex 2 decreased gradually,
and a new set of triplets (H1′ and H2′) emerged when
0.2 and 0.5 mol equiv of GSH were added. The low-field resonances
of the tosyl protons of complex 2 (H1 and H2) disappeared
and a new set of peaks (H1′–H7′) appeared when
1 mol equiv or more of GSH was added ( Figure S12 in the Supporting Information). The reaction was confirmed by LC-MS,
which revealed that the 2 -SG adduct was formed rapidly
when 2 was mixed with GSH ( Figure S13 in the Supporting Information). The eluents are shown in Figure S14 in the Supporting Information. Next, the time dependence of the reaction of complex 2 with GSH was studied under similar conditions: 2 mM 2 in MeOD- d 4 /D 2 O (2/8 v/v)
with 20 mM GSH, monitored by 1 H NMR spectroscopy from 5
min to 24 h ( Figure 4 ). As in the above experiments, a new set of low-field resonances
appeared immediately (H1′–H6′) in the presence
of excess GSH (10 mol equiv), but with time, the low-field resonances
H1′–H6′ decreased gradually and disappeared after
24 h ( Figure 4 ); meanwhile,
another two new sets of peaks slowly appeared. The 2D NMR (COSY) spectrum
suggested that the 2 -SG adduct degraded with time to
release the neutral free ligand η 6 -Ph(CH 2 ) 3 -ethylenediamine- N (H)-Ts (assigned
to one of the two sets of low-field peaks, Figure S15 in the Supporting Information) with up to 70% of decomposition
observed within 5 h incubation at 310 K, as shown in Figure S16 in the Supporting Information. Such liberation
of free ligand was also detected by LC-MS at 333.21 m / z (calculated [ligand + H] + m / z 333.16, Figure S13 in the Supporting Information). Complex 1 (2
mM in MeOD- d 4 /D 2 O (1/4 v/v),
pH* 7) showed a behavior in reactions with GSH (10 mol equiv) similar
to that of complex 2 . 1 -SG adduct formed
rapidly but decomposed after 24 h incubation at 310 K. Complexes 3 and 4 (2 mM in DMSO- d 6 /D 2 O (1/4 v/v)) also reacted with GSH, but the
SG adduct appeared to be stable under these conditions, since the 1 H NMR spectra appeared to be unchanged after 24 h incubation
at 310 K (data not shown). Complexes 3 and 4 both have electron-withdrawing groups on the phenyl ring of the
sulfonamide substituent. Figure 4 Dependence on time of the interaction of complex 2 (2 mM in MeOD- d 4 /H 2 O (2/8
v/v)) with GSH (20 mM, in D 2 O, pH* adjusted to 7.2 ±
0.1), monitored by 1 H NMR (600 MHz) at 310 K. The two sets
of peaks for H1′–H7′ can be assigned to diastereomers;
free ligand resonances in the low-field region are shown in the dashed
red box.
## Reduction of NAD
Reduction of NAD + by TH in the Presence of GSH Due to the thiophilic nature
and instability of complex 2 in the presence of GSH,
the influence of GSH on the conversion of
NAD + to NADH by TH from complex 2 with formate
as the hydride source was investigated. 1 H NMR spectra
(MeOD- d 4 /D 2 O (2/8 v/v)), at
pH* 7.2 and 310 K with complex 2 , NAD + , GSH,
and sodium formate in the mole ratio of 1/4/ X /25
(where X = 0.5, 1, 2 and 5, respectively) were recorded
every 5 min. The turnover frequency of NAD + to NADH decreased
slightly in the presence of 0.5 mol equiv of GSH (TOF 4.27 ±
0.05 h –1 ); however, the TOF decreased dramatically
to 1.35 h –1 when 1.0 mol equiv of GSH was present.
The hydride transfer reaction completely stopped when excess GSH was
added (2 or 5 mol equiv).
## Antiproliferative Activity
Antiproliferative Activity The antiproliferative
activity
of tethered Ru II complexes 1 – 4 against human ovarian (A2780), lung (A549), hepatocellular
(HEPG2), breast (MCF7), and cisplatin-resistant ovarian (A2780Cis)
cancer cell lines and normal human lung fibroblast cells (MRC5) was
determined ( Table 3 ) and compared to that of the clinical drug cisplatin (CDDP). Complexes 1 – 4 exhibited good to moderate anticancer
activity against all of these cancer cell lines, with IC 50 values in the range of 7.3–>50 μM. Complex 2 displayed good anticancer activity against A2780 and cisplatin-resistant
A2780 cancer cells, with IC 50 values of 7.3 and 15 μM,
respectively. Remarkably, this complex exhibits a resistance index
(RI) of only 2 in comparison to 11 for cisplatin. The RI is the ratio
of the activity (IC 50 ) toward the resistant cell line in
comparison to the parental line and gives an indication of the capacity
of a complex to overcome platinum resistance. Furthermore, complex 4 exhibited anticancer activity against MCF7 cancer cells
similar to that of cisplatin, with an IC 50 value of 9.9
μM. The antiproliferative activity in A549 lung and HEPG2 hepatocellular
cancer cells has minimal variation among complexes 1 – 4 , with all IC 50 values averaging 32 and 25 μM,
respectively. Corresponding values for the normal fibroblast cell
line MRC5 are given in Table 3 . Table 3 In Vitro Anticancer Activity of Complexes 1 – 4 Against Various Cell Lines cell line a IC 50 (μM) complex A2780 A2780Cis A549 HEPG2 MCF 7 MRC 5 RI b 1 23 ± 1 >50 33 ± 1 27.8 ± 0.1 28.9 ± 0.9 31 ± 1 >2 2 7.3 ± 0.4 15 ± 1 37.6 ± 0.6 26 ± 4 33 ± 2 38 ± 1 2 3 >50 >50 31 ± 2 >50 24 ± 3 28 ± 3 n.d. 4 16.0 ± 0.3 >50 30 ± 1 23 ± 4 9.9 ± 0.5 26 ± 1 >3 CDDP 1.20 ± 0.02 13.4 ± 0.3 3.1 ± 0.1 5.7 ± 0.9 7.3 ± 0.2 12.8 ± 0.3 11 a Data are shown as means ± standard
deviations (STD), from duplicates of triplicates; cell viability was
assessed after 24 h drug exposure and 72 h recovery in drug-free medium.
Human cell lines: A2780, ovarian cancer; A2780Cis, cisplatin-resistant
ovarian cancer; A549, lung cancer; HEPG2, hepatocellular cancer; MCF7,
breast cancer; MRC5, normal lung fibroblasts. b RI denotes the resistance index
between A2780 ovarian cancer cells and its resistant derivative A2780Cis.
n.d. = not determined.
## Cellular
Accumulation of Ru
Cellular
Accumulation of Ru Cellular Ru accumulation
from administration of the most promising complexes 2 and 4 in A2780 human ovarian cancer cells and A2780Cis
cells was determined. Complex 4 showed a higher cellular
Ru accumulation in comparison to complex 2 in both A2780
and A2780Cis ( Figure 5 ). The cellular Ru contents for complex 4 were 150 ±
38 ng per million A2780 cells and 241 ± 10 ng per million A2780Cis
cells, while the cellular Ru content from complex 2 was
much lower: 8.8 ± 0.9 and 7 ± 1 ng per million cells, respectively. Figure 5 Cellular
Ru accumulation in A2780 and A2780Cis ovarian cancer cells
exposed to equipotent IC 50 concentrations of complexes 2 and 4 .
## Cell Cycle Arrest
Cell Cycle Arrest Since complex 2 [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl] binds to the nucleobase guanine (9-EtG), it was possible
that DNA might be a target for anticancer activity. In order to investigate
this, the effects on the cell cycle of A2780 cells exposed to complex 2 at IC 50 and 2 × IC 50 concentrations
for 24 h were studied, using propidium iodide staining, and measured
using flow cytometry ( Figure 6 ). In comparison to negative control populations, a statistically
significant increase of the cell population in the G 1 phase
was observed, with percentages increasing to 75 ± 1% at IC 50 concentration and 85 ± 3% population at 2 × IC 50 concentration. This evidence of G 1 arrest with
lack of an accumulation of cells in the S phase might suggest that
DNA is not a major target and that complex 2 could have
a cytostatic effect on ovarian cancer cells. Nonetheless, studies
of the interaction of complex 2 with DNA were carried
out to investigate further (vide infra). Figure 6 Cell cycle arrest analysis
of A2780 human ovarian cancer cells
after 24 h of exposure to complex 2 at 310 K at IC 50 and 2 × IC 50 concentrations. Cell staining
for flow cytometry was carried out using PI/RNase. p Values were calculated after a t -test against the
negative control data: * p <0.05, ** p <0.01.
## ROS Induction in A2780
Human Ovarian Cancer Cells
ROS Induction in A2780
Human Ovarian Cancer Cells The
level of reactive oxygen species (ROS) in A2780 human ovarian cancer
cells induced by exposure to complex 2 was determined
at IC 50 concentration by flow cytometry fluorescence analysis
( Figure 7 ). The total
level of oxidative stress, including H 2 O 2 , peroxy
and hydroxyl radical, peroxynitrite, NO, and superoxide production,
was monitored using the green channel FL1 and orange channel FL2,
respectively. Increased ROS levels were detected in the majority of
the population of A2780 cells, with up to 82% of cells exhibiting
high fluorescence in the FL1-green channel. There is only a minimal
increase in the level of cellular superoxide ( Table S6 in the Supporting Information). Figure 7 ROS induction in A2780
cancer cells exposed to complex 2 . The FL1 channel detects
total oxidative stress, and the FL2 channel
detects superoxide production. Complex 2 is shown in
red and negative control in blue. p Values were calculated
after a t -test against the negative control data:
* p <0.05, ** p <0.01.
## Cell Membrane Integrity
Cell Membrane Integrity We further investigated the
effect of complex 2 on the cellular membrane integrity
of A2780 ovarian cancer cells using flow cytometry analysis of cells
exposed for 24 h to the ruthenium complex and stained in the dark
with propidium iodide. This experiment did not include fixation of
the cells prior to staining. The results show that there are no induced
changes in the membrane integrity of cancer cells, as there are no
statistical differences between the drug-exposed and negative control
cells ( Table S7 in the Supporting Information).
## Calf Thymus DNA and Bacterial Plasmid DNA
Calf Thymus DNA and Bacterial Plasmid DNA The interaction
of complex 2 ([Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl]) with double-helical
calf thymus DNA (ct-DNA) and bacterial plasmid DNA was studied and
compared to that of nontethered [(η 6 - p -cym)Ru(TsEn)Cl] ( JS2 in Figure 1 ). 37 Double-helical
ct-DNA at a concentration of 32 μg mL –1 was
incubated with JS2 or complex 2 at r i values of 0.1 and 0.5 in 10 mM NaClO 4 at 310 K ( r i = the molar ratio of free
ruthenium complex to nucleotide phosphates at the onset of incubation
with DNA). The reaction was terminated after 24 h of incubation, and
samples were exhaustively dialyzed against water. The ruthenium content
in these samples was determined by flameless atomic absorption spectrometry
(FAAS) and the concentration of DNA by absorption spectrophotometry.
No detectable amount of ruthenium was found in samples of DNA treated
with JS2 or complex 2 , even at very high r i . Therefore, these compounds do not bind strongly
to high-molecular-mass DNA under the experimental conditions used. In further experiments, solutions containing plasmid DNA pBR322
(28 μg mL –1 ) and complex JS2 or
complex 2 in various molar ratios ( r i = 0.05–1) were incubated in 0.01 M NaClO 4 at 310 K for 24 h in the dark. Subsequently the samples were
directly mixed with the loading buffer and loaded onto a 1% agarose
gel running at 298 K in the dark with Tris-acetate-EDTA (TAE) buffer,
and the voltage was set at 25 V. There was no separation step before
the samples were loaded onto the gel to remove weakly bound complex,
if any. The gels were then stained with EtBr, followed by photography
with a transilluminator. As seen in Figure S17 , no significant
changes in the mobilities of supercoiled (SC) or open circle forms
(OC) were observed even at very high concentrations of Ru compounds
( r i = 1), indicating that these complexes
do not unwind DNA and do not form DNA adducts. No changes in intensities
of SC and OC forms also indicated that the Ru complexes do not cleave
DNA in the dark.
## Binding to Short Single- or Double-Stranded
Oligonucleotides
Binding to Short Single- or Double-Stranded
Oligonucleotides Binding of complex 2 to short
single- or double-stranded
synthetic oligonucleotides was also investigated. A 50-mer oligonucleotide
(single- or double-stranded) was incubated with complex 2 or complex JS2 ( r i = 0.5,
concentration of oligonucleotide related to phosphates) in 0.05 M
NaClO 4 at 310 K in the dark. After 24 h the reaction was
stopped, and samples were exhaustively dialyzed against water. The
ruthenium contents in these samples were determined by FAAS, and the
concentrations of DNA were determined by absorption spectroscopy.
No Ru associated with single- or double-stranded oligonucleotides
treated with complex JS2 was found, whereas 3–4%
of Ru was bound to single-stranded oligonucleotide on incubation with
complex 2 , but no detectable amount of Ru was bound to
double-stranded oligonucleotide.
## Effect of Formate on Antiproliferative
Activity
Effect of Formate on Antiproliferative
Activity The
antiproliferative activity of tethered complexes 1 – 4 against A2780 human ovarian cancer cells in the presence
of sodium formate was determined ( Figure 8 ). Experiments included three sets of controls:
the first, negative controls, consisted of untreated cells (only vehicle
exposure), a second set was exposed to three concentrations of sodium
formate (0.5, 1, and 2 mM), and a third set was exposed to cisplatin
as positive controls. The results indicate that formate alone is not
toxic toward A2780 ovarian cancer cells under the conditions used,
as the statistical difference between the first two controls was never
significant ( Table S8 in the Supporting
Information). A2780 cancer cells were incubated with equipotent concentrations
of complexes 1 – 4 (1/3 × IC 50 ) and three concentrations of sodium formate (0.5, 1, and
2 mM) for 24 h. Following 72 h of recovery time in drug-free medium,
cell survival was evaluated using the Sulforhodamine B colorimetric
assay. A decrease in cell viability was observed, and importantly
this was greater with increasing concentrations of sodium formate.
Complex 4 showed the least effect on cell viability,
decreasing from 95% to 81%, while complex 1 exhibited
the highest changes, varying from 96% to 74% when 2 mM formate was
coadministered. Overall, the percentage of cell viability reduction
which accompanies formate coadministration follows the order 1 > 2 > 3 > 4 (percentages
of cell survival are given Table S8 in
the Supporting Information). Figure 8 Cell viability of A2780 ovarian cancer cells
on exposure for 24
h to complexes 1 – 4 (at equipotent
1/3 × IC 50 concentrations) and sodium formate at concentrations
of 0, 0.5, 1.0, and 2.0 mM. p Values were calculated
after a t -test against the negative control data:
* p <0.05, ** p <0.01.
## Discussion
Discussion The
X-ray crystal structures of complexes 1 – 4 show that they adopt the well-known “piano-stool”
geometry, with nitrogens of the diamine and a chloride bound to the
metal center forming the three legs and a phenyl ring forming the
seat, being linked to the ethylenediamine by a three-carbon tether. 44 , 45 Complexes 1 – 4 all have similar
tethered structures. The length of the bond between Ru and the deprotonated
N is within the range 2.112–2.121 Å, shorter than in the
chiral tethered complex ( R , R )-[Ru(η 6 -Ph(CH 2 ) 3 -TsDPEN- N (H))Cl]
(2.144(3) Å) and [(η 6 - p -cym)Ru(TsDPEN)Cl]
(2.139(6) Å), while the Ru–N(H) bond length is within
the range 2.140–2.149 Å, which is longer than those in
the latter two complexes (2.134(3) and 2.105(6) Å, respectively). 38 , 40 , 46 Complexes 1 – 4 have Ru–N( − ) and Ru–N(H)
bond lengths very similar to those in the complex [(η 6 -hmb)Ru(TsEn)Cl] (hmb = hexamethylbenzene, 2.129(3) and 2.141(3)
Å, respectively). 36 The N–Ru–N
angles are in the range 78.54–78.87°, close to those in
the chiral tethered Ru complex ( R , R )-[Ru(η 6 -Ph(CH 2 ) 3 -TsDPEN- N (H))Cl]. 38 The remaining bond
lengths and angles show no significant difference in comparison to
either tethered or nontethered Ru sulfonyl ethylenediamine complexes. Complex 2 reacted rapidly with guanine (9-EtG), as
studied by NMR at millimolar concentrations. 28 However, at lower concentrations (micromolar), little binding to
DNA was observed when calf thymus and bacterial plasma DNA were exposed
to complex 2 , consistent with results reported previously
for the nontethered Ru II complex [(η 6 - p -cym)Ru(TsEn)Cl] ( JS2 ), implying that DNA
is not likely to be a target for Ru sulfonamide complexes. 37 The binding to l -His (as well as l -Cys) suggests that proteins and enzymes may also be targets
for these complexes. Hydride transfer between coenzyme NAD + and NADH plays
a pivotal role in cell metabolism; 47 this
pair of coenzymes is believed to be involved in over 400 cellular
reactions. 48 Studies of TH reactions for
conversion of NAD + to NADH catalyzed by transition-metal
complexes were initiated by Fish and Steckhan. 49 − 51 The use of
Ru II catalysts to mimic the cellular reaction and achieve
TH reduction of NAD + under biologically relevant conditions
has been well studied. 52 , 53 The en complex RM175 showed strong DNA affinity but low catalytic efficiency toward TH
reduction of NAD + (TOF, 0.18 h –1 ); 35 whereas the introduction of a sulfonyl functional
group raised the TOF to 2.88 h –1 ( JS2 in Figure 1 ). 35 In this work, complexes 1 – 4 displayed more potent catalytic activity toward TH of NAD + to NADH. The reaction rate for tosylated complex 2 is ca. 25.8× and 1.6× faster than those for Ru-en and
Ru-TsEn complexes and is comparable to that of the Rh III complex [(η 5 -Cp*)Rh(bipy)Cl]PF 6 . 54 , 55 This may be facilitated by the longer Ru–N(H)
and shorter Ru–N( − ) bond lengths allowing
the tethered complex to approach NAD + more closely in the
TH catalytic cycle, together with the ease of hydrolysis of the tethered
complexes. In general, the TOF values determined by UV–vis
are similar to those determined by NMR spectroscopy ( Table 2 ), the small difference probably
arising from the mole ratios of formate used, since the TOF increases
with an increase in the molar ratio of formate. 36 It appears that the presence of the electron-withdrawing
sulfonamide on the chelating ligand gives rise to higher catalytic
activity, consistent with the previous reported TH reduction of aldehydes
and quinoxalines. 36 , 56 , 57 As a major peptide in cells, glutathione (γ- l -Glu- l -Cys-Gly, GSH) plays a significant role in cell metabolism:
e.g., in the maintenance of cellular redox state and signal transduction. 58 It functions as an important reducing agent
(GSH/GSSG couple) and has a high affinity for transition-metal complexes. 59 Acquired drug resistance in cancer cells is
often associated with overexpression of GSH, which can act as a detoxification
agent. 60 Complex 2 (2 mM,
MeOD- d 4 /H 2 O (1/4 v/v)) reacted
rapidly with GSH (0.5–10 mol equiv, pH* 7.1, 310 K; Figure S2 in the Supporting Information) to form
the adduct 2 -SG, but this decomposed within 24 h, as
shown in Figure 4 ,
at 310 K in aqueous solution with eventual loss of the chelated tethered
sulfonyl-ethylenediamine ligand ( Figure 4 and Figure S15 ). Complex 1 reacted with GSH similarly to complex 2 . Complexes 3 and 4 also reacted
rapidly under NMR conditions (millimolar concentrations) but appeared
to form more stable 3 -SG and 4 -SG complexes.
This high thiol affinity may mean that these tethered Ru complexes
bind rapidly to GSH on entering cells, blocking the approach of Ru
complex to DNA, and the decomposition of the adduct may lead to metabolites
that are toxic to cells. 59 This may partially
explain why TH reduction of NAD + was hampered in the presence
of GSH and only a limited increase in potency is observed in A2780
cancer cells exposed to complex 2 and sodium formate,
in comparison to the Ru complex [(η 6 - p -cym)Ru(TsEn)Cl], even though the TH reduction of NAD + was believed to be taking place in the cancer cells. 37 Cisplatin is frequently used clinically
in combination chemotherapy,
especially for ovarian and testicular cancers. 61 However, poor 5 year survival rates in ovarian cancer patients
are partly attributable to the development of drug resistance. 62 Complex 2 showed much lower cross-resistance
with cisplatin (resistance index ca. 2 versus 11 for cisplatin) despite
the low cell uptake in resistant human ovarian A2780Cis cancer cells.
Furthermore, the higher selectivity index between MRC5 normal cells
and A2780Cis cancer cells (2.6 for complex 2 versus 0.95
for cisplatin), indicates that complex 2 might be able
to overcome cisplatin resistance with fewer side effects. Cellular
accumulation is an important factor in drug cytotoxicity. 63 Cellular accumulation of Ru from complexes 2 and 4 in A2780 and A2780Cis cancer cells did
not correlate with their cytotoxicity (IC 50 ). The cellular
accumulation of Ru from complex 2 is similar in A2780
vs A2780 Cis cells, yet its IC 50 varies between 7.3 and
15 μM. In comparison, complex 4 loses its activity
in the resistant cell line, yet its cellular accumulation is notably
increased. TOFs for NAD + TH by formate for complexes 1 – 4 do not correlate with the reduction
of cell viability induced by 2 mM sodium formate, following the order 4 < 3 < 2 < 1 . This may imply that factors other than the catalytic conversion
of NAD + to NADH are also involved in the processes which
determine the cellular mechanism of antiproliferative activity. In contrast to the negative control (A2780 cells not treated, Figure 6 ), complex 2 can induce concentration-dependent G 1 cell cycle
arrest, which inhibits cell division. Previously, Ru II complexes
have been reported to induce G1 arrest, e.g., the Ru-Norharman complex
[Ru(bipy) 2 (9 H -pyrido-[3,4- b ]indole) 2 ] 2+ and [Ru(η 6 - p -cym)( p -Impy-NMe 2 )Cl]. 64 , 65 Clinical anticancer drugs, for instance clotrimazole and paclitaxel,
can also induce G 1 cell cycle arrest. 66 , 67 Paclitaxel can inhibit cell proliferation by activation of p53 tumor
suppressor gene. 67 Microtubules are also
potential targets. They are important cycloskeletal polymers, which
can form a constantly reorganized solid backbone that serves as a
polarity information source, to separate chromosomes through cell
division. 68 The recently reported Ru II complexes [Ru(η 6 -Ph(CH 2 ) 3 -TsDPEN- N (H))Cl] ( R , R or S , S ) distribute mainly
in the cycloskeleton and can effectively target and inhibit microtubule
polymerization. 42 In view of its structural
similarity, complex 2 might also potentially target microtubules
and subsequently trigger G1 cell arrest. ROS are important factors
in cell signaling and can control cell
survival, cell proliferation, and the maintenance of cell redox homeostasis. 69 A moderate level of intracellular ROS would
encourage the growth of cancer cells; however, higher levels will
cause damage and even induce apoptosis of cancer cells. 70 Complex 2 significantly increased
the ROS level in A2780 cancer cells at IC 50 concentrations,
giving over 80% of cancer cells total oxidative stress, which may
contribute to cell death.
## Conclusions
Conclusions The four tethered Ru II catalysts 1 – 4 have been
synthesized and their structures determined by
X-ray crystallography. All of the complexes exhibit potent reductive
catalytic transfer hydrogenation activity using formate as the hydride
source in aqueous media, as shown by the conversion of coenzyme NAD + to NADH, and follow the general reactivity trend 1 < 2 < 3 < 4 . Coincubation
of complexes 1 – 4 with A2780 cancer
cells in the presence of formate resulted in the dose-dependent reduction
of cell viability ( Figure 8 ). Formate alone under similar conditions had no effect on
cell viability. Such a combination of catalyst and nontoxic cocatalyst
may provide a promising strategy for the design of new drugs which
can be used at low concentrations and have new mechanisms of action
that are effective against resistant cancers. These complexes
exhibit moderate to good anticancer activity toward
A2780, A2780 Cis, A549, MCF7, and HEPG2 cancer cell lines. Some of
the complexes displayed cytotoxicity comparable to that of the clinically
used drug cisplatin. Complex 2 ([Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl]) in particular exhibits a low cross-resistance with cisplatin
toward A2780 human ovarian cancer cells and unlike cisplatin does
not appear to involve a DNA-targeting mechanism of action. Complex 2 reacts rapidly with GSH to form a 2 -SG adduct,
which can effectively block the TH reduction
of NAD + . At millimolar NMR concentrations, the chelated
tethered ligand was readily displaced by excess GSH, but such reactions
may be much slower in cells where the Ru concentration would be ca.
200× lower. It is possible that these TH reactions are faster
in cells if they take place in compartments where the dielectric constant
is lower than that of water, since higher percentages of DMSO increased
the rate ( Figure S11 in the Supporting
Information), as was found earlier for MeOH in related systems. 36 It is also possible that these tethered Ru II complexes can target proteins and enzymes in cells, binding
e.g., to histidine as well as the cysteine residues ( Figures S10 and S12 ). However, the contribution of such interactions
to the biological activity remains to be investigated. Concentration-dependent
G 1 cell cycle arrest was observed
on exposure of A2780 cells to complex 2 . In addition,
complex 2 can induce a high level of intracellular ROS,
which may provide a basis for killing cancer cells.
## Experimental Section
Experimental Section Materials Ruthenium trichloride
was purchased from
Precious Metals Online (PMO Pty Ltd.). β-Nicotinamide adenine
dinucleotide hydrate (NAD + ) was purchased from Sigma-Aldrich.
Methylsulfonyl chloride, toluenesulfonyl chloride, 4-trifluoromethylbenzenesulfonyl
chloride, and 4-nitrobenzenesulfonyl chloride were obtained from Fluka
and Sigma-Aldrich. Glutathione was obtained from Alfa Aesar. The A2780
ovarian, A2780 Cis ovarian, A549 lung, HEPG2 hepatocellular, and MCF7
breast human adenocarcinoma cell lines as well as MRC5 human fibroblast
cells were purchased from the European Collection of Animal Cell Culture
(ECACC, Salisbury, U.K.). Propidium iodide (>94%) and RNase A were
obtained from Sigma-Aldrich. Syntheses To a stirred solution
of 3-(1,4-cyclohexadien-1-yl)-1-propanol
(1.21 g, 9.18 mmol) in DCM (25 mL) was added NEt 3 (2.7
mL, 19.28 mmol), and the resulting solution was cooled to 273 K. A
solution of methanesulfonyl chloride (1.1 mL, 13.8 mmol) was added
over a period of 20 min, and the internal temperature was kept at
278 K. After 30 min, the solution was warmed to ambient temperature
and stirred overnight. The reaction solution was quenched with saturated
NaHCO 3 solution, washed with water and brine, and dried
over Mg 2 SO 4 . The mesylate product was carried
forward directly to the next step. A solution of the mesylate derivative
in 10 mL of 1,2-dimethoxyethane (DME) was added slowly over a period
of 5 min to a stirred solution of monosulfonated ethylenediamine (9.25
mmol) in 1,2-dimethoxyethane (20 mL) and NEt 3 (2.7 mL,
19.43 mmol) at 333 K. The resulting solution was heated to 353 K and
stirred overnight. The reaction was quenched with saturated NaHCO 3 solution. The reaction mixture was worked up with water and
brine and dried over Mg 2 SO 4 . The desired ligands
were isolated as yellow oils by silica column chromatography with
EtOAc and hexane as eluents. To a stirred solution of tethered
ethylenediamine ligands (0.808 mmol) in anhydrous EtOH (15 mL) was
added concentrated HCl (0.12 mL, 35%, 1.21 mmol) at 273 K. The solution
was heated at 333 K for 30 min. After this time the solution was heated
to 348 K and a solution of RuCl 3 (0.110 g, 0.533 mmol)
in EtOH (15 mL) and water (0.5 mL) was added dropwise over 20 min.
The solution was stirred at 348 K overnight and cooled, hexane (60
mL) added with vigorous stirring, and the resulting solid collected
by filtration. The solid (dimer precursor) was then washed with hexane
and dried under high vacuum to give a dark brown solid. The filtrate
was concentrated to give an orange powder. To a stirred solution
of dimer precursors (0.22 mmol) in DCM (50
mL) at 273 K was added N,N -diisopropylethylamine
(3.0 mL, 1.70 mmol), and the solution was stirred at ambient temperature
for 2 h. The solution was then filtered over Celite, and the DCM was
removed by rotary evaporation. EtOH was added to the resulting paste
and stored in the freezer for 3 h before the cold solution was filtered,
and the orange precipitate was collected. The precipitate was washed
with further portions of cold EtOH. The desired ruthenium complex
was isolated by silica column chromatography with MeOH and DCM (1/10
v/v). [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ms)Cl] ( 1 ) The general synthesis
of tethered Ru complexes followed a reported protocol. 43 Yield: 47 mg (60%). 1 H NMR (400 MHz,
MeOD- d 4 ): δ H 1.98–2.04
(m, 1H), 2.29–2.41 (m, 4H), 2.48–2.51 (m, 1H), 2.76
(s, 3H), 2.79–2.82 (m, 2H), 2.87 (d, 1H, J = 7.7 Hz), 3.24–3.28 (m, 1H), 5.14–5.20 (m, 2H), 5.71–5.72
(m, 1H), 5.83–5.88 (m, 2H). 13 C NMR (125.7 MHz,
DMSO- d 6 ): δ C 33.3, 43.8,
52.7, 56.8, 62.0, 78.5, 82.1, 82.9, 95.3, 98.0, 105.5. HR-MS: calcd
for [C 13 H 22 ClN 2 O 2 SRu] + m / z 357.0211, found m / z 357.0211. Anal. Calcd for [C 12 H 19 ClN 2 O 2 RuS(H 2 O) 0.6 ]: C, 35.79; H, 5.06; N, 6.96. Found: C, 35.83; H, 4.91;
N, 6.94. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl] ( 2 ) The synthesis of complex 2 ( but not its X-ray
structure) was reported previously by
one of us. 43 The method described above
for complex 1 was used. Recrystallization from methanol
resulted in a bright red solid. Yield: 63 mg (63%). 1 H
NMR (400 MHz, CDCl 3 ): δ H 7.73 (d, 2H, J = 8.2 Hz), 7.15 (d, 2H, J = 8.2 Hz),
6.36 (t, 1H, J = 5.6 Hz), 5.96 (t, 1H, J = 5.6 Hz), 5.83 (t, 1H, J = 5.8 Hz), 5.01 (d, 1H, J = 5.6 Hz), 4.91 (d, 1H, J = 5.8 Hz),
3.79 (s, 1H), 3.30–3.23 (m, 1H), 3.03 (dd, 1H, J = 11.5 Hz, 4.2 Hz), 2.79–2.71 (m, 1H), 2.66–2.62 (m,
1H), 2.43–2.36 (m, 3H), 2.34 (s, 3H), 2.27–2.19 (m,
2H), 2.08–1.99 (m, 1H). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 26.1, 33.2, 33.5, 52.2, 56.7, 62.0,
78.9, 82.1, 83.2, 94.5, 97.6, 104.9, 132.1, 133.6, 144.5, 146.9. HR-MS:
calcd for [C 18 H 23 N 2 O 2 RuS] + m / z 433.0524, found m / z 433.0522. Anal. Calcd for [C 18 H 23 ClN 2 O 2 RuS(H 2 O) 0.1 ]: C, 46.02; H, 4.98; N, 5.96. Found: C, 46.03; H, 4.92;
N, 5.93. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Tf)Cl] ( 3 ) Complex 3 was obtained following the method
described above for complex 1 . Recrystallization from
methanol resulted in a brownish-red
solid. Yield: 38 mg (36%). 1 H NMR (400 MHz, DMSO- d 6 ): δ H 1.84–1.86 (m,
1H), 2.10 (t, 1H, J = 11.2 Hz), 2.25 (t, 2H, J = 9.7 Hz), 2.33–2.46 (m, 2H), 2.64 (d, 1H, J = 8.9 Hz), 2.75 (q, 1H, J = 9.7 Hz, 21.9
Hz,), 2.85 (d, 1H, J = 8.0 Hz), 3.14 (s, 1H) (broad
single peak), 4.35 (s, 1H) (broad single peak), 5.27 (d, 1H, J = 4.9 Hz), 5.40 (d, 1H, J = 5.6 Hz),
5.83–5.89 (m, 2H), 5.97 (t, 1H, J = 5.1 Hz),
7.75 (d, 2H, J = 8.0 Hz), 7.93 (d, 2H, J = 8.0 Hz). 13 C NMR (125.7 MHz, DMSO- d 6 ): δ C 33.2, 33.4, 52.3, 56.7, 61.9,
79.2, 81.9, 83.6, 94.8, 97.8, 105.3, 130.1, 132.9, 134.8, 135.1, 135.0. 19 F NMR (376.4 MHz, DMSO- d 6 ): δ F −61.02. HR-MS: calcd for [C 18 H 20 N 2 F 3 O 2 SRu] + m / z 487.0241, found m / z 487.0240. Anal. Calcd for [C 18 H 20 ClF 3 N 2 O 2 RuS(H 2 O) 0.1 ]: C,
41.28; H, 3.89; N, 5.35. Found: C, 41.20; H, 3.65; N, 5.26. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Nb)Cl] ( 4 ) Complex 4 was obtained
following the method described above for complex 1 . Recrystallization
from methanol and diethyl ether resulted
in a bright red solid. Yield: 44 mg (43%). 1 H NMR (300
MHz, CDCl 3 ): δ H 2.00–2.08 (m, 1H),
2.14–2.58 (m, 2H), 2.34–2.50 (m, 3H), 2.69–2.82
(m, 2H), 3.12 (dd, 1H, J = 5.5 Hz, 14.8 Hz), 3.23–3.32
(m, 1H), 3.70 (s, 1H) broad single peak, 4.92 (d, 1H, J = 7.9 Hz), 5.00 (d, 1H, J = 7.6 Hz), 5.86 (t, 1H, J = 7.6 Hz,), 5.96 (t, 1H, J = 8.1 Hz),
6.30 (t, 1H, J = 7.3 Hz), 7.96 (d, 2H, J = 11.6 Hz), 8.18 (d, 2H, J = 11.8 Hz). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 33.1,
33.5, 52.4, 56.7, 61.8, 79.3, 81.9, 83.8, 94.8, 97.8, 105.5, 128.4,
133.4, 153.1, 155.0. HR-MS: calcd for [C 17 H 20 N 3 O 4 SRu] + m / z 464.0218, found m / z 464.0216.
Anal. Calcd for [C 17 H 20 ClN 3 O 2 RuS(H 2 O) 0.5 ]: C, 40.20; H, 4.17; N,
8.27. Found: C, 40.26; H, 3.89; N, 8.04. Instruments and Methods NMR Spectroscopy 1 H NMR spectra were obtained
on either a Bruker HD-400, or a AVIII 600 spectrometer at 298 or 310
K. Data were processed by Topspin-NMR version 3.5pl7 (Bruker U.K.
Ltd.), with NMR proton chemical shifts internally referenced to TMS
via 1,4-dioxane in D 2 O (δ 3.75) or residual MeOD- d 4 (δ 3.31 ppm), DMSO- d 6 (δ 2.50 ppm) or CDCl 3 (δ 7.26
ppm). 1D spectra were recorded using standard pulse sequences. NMR
spectra were acquired with 16 transients into 32 k data points over
a spectral width of 14 ppm and 32 transients into 32 k data points
over a spectral width of 30 ppm with 2 s relaxation delay for the
kinetic experiments. High-Resolution Mass Spectrometry (HRMS) All samples
were prepared in methanol. High-resolution mass spectrometry data
were obtained on a Bruker Maxis Plus Q-TOF instrument. Elemental Analysis Elemental analyses were performed
by Warwick Analytical Service using an Exeter Analytical elemental
analyzer (CE440). X-ray Crystallography Single crystals
of 1 – 4 were obtained from a slow
diffusion of diethyl
ether into methanol solutions of the complexes. Suitable crystals
were selected and mounted on a glass fiber with Fromblin oil and placed
on an Xcalibur Gemini diffractometer with a Ruby CCD area detector.
The crystals were kept at 150 ± 2 K during data collection. Using
Olex2, 71 the structure was solved with
the ShelXT 72 structure solution program
using direct methods and refined with the ShelXL 73 refinement package using least-squares minimization. The
data were processed by the modeling program Mercury 3.8. X-ray crystallographic
data for complexes 1 – 4 have been
deposited in the Cambridge Crystallographic Data Center (CCDC) under
the deposition numbers CCDC 1823316–1823319 (complexes 4 , 3 , 2 , and 1 , respectively). ICP-MS/-OES Determination ICP-MS and ICP-OES analyses
were carried out on Agilent Technologies 7500 series and PerkinElmer
Optima 5300 DV series instruments, respectively. The double-deionized
(DDW) water used for both analyses was from a Millipore Milli-Q water
purification system and a USF Elga UHQ water deionizer. The Ruthenium
Specpure plasma standard (ruthenium chloride, 1004 ± 5 μg/mL
in 10% v/v hydrochloric acid) was diluted with 3.6% v/v HNO 3 , and calibrants were prepared freshly at concentrations of 0.1–500
ppb for ICP-MS and 50–700 ppb for ICP-OES. In particular, calibration
standards for ICP-OES analysis were adjusted with standard sodium
chloride (TraceSELECT) solution to match the sample salinity. The
instrument was set to detect 101 Ru with typical detection
using no-gas mode for ICP-MS analysis. TOFs Determined by UV–Vis
Spectroscopy Complexes 1 – 4 were dissolved in DMSO/H 2 O (1/9 v/v) (84 μM) in
a glass vial. Solutions of sodium formate
(102 mM) and NAD + in H 2 O (510 μM) were
also prepared and then mixed at 310 K. In a typical experiment, an
aliquot of 330 μL from each solution was placed in a 1 mL cuvette
and the pH adjusted to 7.2 before the sample was introduced into the
UV–vis instrument, giving a total volume of 1 mL (final concentrations
were Ru complex 28 μM, NAD + 170 μM, NaHCO 2 34 mM, molar ratio 1/6/1200). UV spectra were recorded every
5 min until completion of the reaction. The spectrum was monitored
for an increase in the band at 340 nm, which corresponds to the absorption
of NADH. TOFs Determined by NMR Complexes 1 – 4 were dissolved in DMSO- d 6 /D 2 O (3/2 v/v; 1.4 mM) in a glass vial. Aliquots (200 μL)
of solutions of sodium formate (35 mM) and NAD + (5.6 mM)
in D 2 O were added, and the pH* was adjusted to 7.2 ±
0.1, for a final volume of 0.64 mL (Ru complex 0.44 mM, NAD + 1.75 mM, NaHCO 2 10.94 mM; molar ratio 1/4/25). The solution
was transferred to a 5 mm NMR tube, and a 1 H NMR spectrum
was recorded at 310 K every 162 s until the completion of the reaction.
Molar ratios of NAD + and NADH were determined by integrating
the peaks corresponding to resonances for NAD + (9.33 ppm)
and 1,4-NADH (6.96 ppm). The turnover number (TON) for the reaction
was calculated where I n is the integral of the signal
at n ppm and
[NAD + ] is the concentration of NAD + at the start
of the reaction. Reaction with GSH Reactions of complex 2 (2 mM, MeOD- d 4 /D 2 O (2/8 v/v))
and GSH (in D 2 O) in the mole ratio of 1/ X , where X = 0.2, 0.5, 1, 2, 5, and 10, were studied
by 1 H NMR (600 MHz) spectroscopy under conditions of MeOD- d 4 /D 2 O (1/9 v/v), pH* 7.2, and 310
K. Each reaction was complete within 10 min. A second set of experiments
investigated the time dependence of reactions of 2 with
GSH (20 mM) in the mole ratio of 1/20, monitored by 1 H
NMR (600 MHz) spectroscopy under conditions similar to those above
(pH* 7.2, 310 K), from 5 min to 24 h. Cell Culture A2780
and A2780Cis human ovarian, A549
human lung, HEPG 2 human hepatocellular, MCF 7 human breast cancer,
and MRC 5 human normal fibroblast cell lines were grown in Roswell
Park Memorial Institute medium (RPMI-1640) supplemented with 10% of
fetal calf serum, 1% of 2 mM glutamine, and 1% penicillin/streptomycin.
All cells were grown as adherent monolayers at 310 K with 5% CO 2 humidified, and all cells were passaged at ca. 80% confluency. IC 50 and in Vitro Cytotoxicity Determination The antiproliferative activity and cytotoxicity of complexes 1 – 4 were determined in five different
cancer cell lines and one human normal cell line. In general, about
5000 cells per well were seeded in 96-well plates. The plates were
preincubated with drug-free medium at 310 K for 48 h before adding
the tested compounds (various concentrations). Stock solutions of
complexes 1 – 4 were prepared in DMSO/cell
culture medium, and exact complex concentrations were determined by
ICP-OES. After 24 h drug exposure, supernatants were removed by suction
and each well was washed with PBS. A further cell recovery for 72
h was allowed in drug-free medium at 310 K. The sulforhodamine B (SRB)
assay was used to determine cell viability. IC 50 values,
as the concentration that causes 50% cell death, were determined as
duplicates of triplicates in two independent sets of experiments,
and their standard deviations were calculated. Cellular Ru
Accumulation Cellular Ru accumulations
for complexes 2 and 4 were determined on
A2780 ovarian and A2780 cisplatin-resistant ovarian cancer cells.
Approximately 2 × 10 6 cells were seeded in a six-well
plate and preincubated in drug-free medium at 310 K for 24 h, and
stock solutions of both complexes were prepared in a mixture of DMSO/cell
culture medium and their accurate Ru concentrations were determined
by ICP-OES. Working solutions were then obtained by dilution in cell
culture medium. Both cancer cell lines were exposed to complexes 2 and 4 for 24 h, at equipotent IC 50 concentrations. The experiment did not involve recovery time in
drug-free medium. After this time, cells were treated with trypsin
and counted and cell pellets were collected. Cell pellets were digested
overnight in 200 μL concentrated nitric acid (73%) at 353 K;
the resulting solutions were diluted with double-distilled water to
a final concentration of 3.6% HNO 3 (v/v), and the amount
of Ru taken up by the cells was determined by ICP-MS (Agilent technologies
7500 series). Data acquisition was carried out in ICP-MS top B.03.05
and processed on offline Data analysis B.03.05. These experiments
did not include any cell recovery time in drug-free media; they were
carried out in triplicate, and the standard deviations were calculated.
Statistical significances of variations were determined using Welch’s t -tests. Cell Cycle Analysis A2780 cells
at 1.5 × 10 6 cells per well were seeded in a six-well
plate. Cells were
preincubated in drug-free media at 310 K for 24 h, after which drugs
were added at equipotent concentration equal to the IC 50 value. After 24 h of drug exposure, supernatants were removed by
suction and cells were washed with PBS. Finally, cells were harvested
using trypsin-EDTA and fixed for 2 h using cold 70% ethanol. DNA staining
was achieved by resuspending the cell pellets in PBS containing propidium
iodide (PI) and RNase. Cell pellets were washed and resuspended in
PBS before being analyzed in a Becton Dickinson FACScan flow cytometer
using excitation of DNA-bound PI at 536 nm, with emission at 617 nm.
Data were processed with Flowjo software using a Watson (Pragmatic)
fitting model. Welch’s t -tests were carried
out to determine the statistical variations. ROS Determination Flow cytometry analysis of ROS/superoxide
generation in A2780 cells caused by exposure to complex 2 was carried out using the Total ROS/Superoxide detection kit (Enzo-Life
Sciences) according to the instructions. A total of 1.5 × 10 6 A2780 cells per well were seeded in a six-well plate. Cells
were preincubated in drug-free media at 310 K for 24 h in a 5% CO 2 humidified atmosphere, and then drugs were added to triplicates
at IC 50 concentration. After 24 h of drug exposure, supernatants
were removed by suction and cells were washed and harvested. Staining
was achieved by resuspending the cell pellets in buffer containing
the orange/green fluorescent reagents. Cells were analyzed in a Becton
Dickinson FACScan flow cytometer using FL1 channel Ex/Em 490/525 nm
for the oxidative stress and FL2 channel Ex/Em 550/620 nm for superoxide
detection. Positive controls were obtained by exposure of cells to
pyocyanin for 30 min. Data were processed using Flowjo software. At
all times, samples were kept under dark conditions to avoid light-induced
ROS production. Welch’s t -tests were carried
out to establish statistical significance of the variations. Cell
Membrane Integrity Determination Flow cytometry
analysis of the cellular membrane integrity of A2780 cells caused
by exposure to complex 2 was carried out using flow cytometry
and propidium iodide staining. Briefly, A2780 cells were seeded in
six-well plates (1.5 × 10 6 cells per well) and preincubated
for 24 h in drug-free media at 310 K, after which they were exposed
to complex 2 at IC 50 concentration. Cells
were harvested using trypsin and stained in the dark using a mixture
of propidium iodide and RNase without previous fixation of the cells.
After staining, cell pellets were analyzed in a Becton Dickinson FACScan
Flow Cytometer and the histograms were analyzed using Flowjo software
and their standard deviations were calculated. Coincubation
of Ru Complexes with Formate Cell viability
assays of complexes 1 – 4 were carried
out with A2780 ovarian cancer cells with sodium formate. These experiments
were performed with the following modifications: a fixed concentration
of each Ru complex equal to 1/3 × IC 50 was used in
coadministration with three different concentrations of sodium formate
(0.5, 1.0, and 2.0 mM). Drug stock solutions (ca. 100 μM) were
prepared as described for in vitro growth inhibition assays and then
further diluted with media until working concentrations were achieved.
Separately, a stock solution of sodium formate was prepared in saline.
The complex and formate solutions were added to each well independently
within 5 min of each other. All other experimental conditions were
kept unchanged (drug exposure, cell recovery time, and end point assay
used). The standard deviations were calculated.
## Materials
Materials Ruthenium trichloride
was purchased from
Precious Metals Online (PMO Pty Ltd.). β-Nicotinamide adenine
dinucleotide hydrate (NAD + ) was purchased from Sigma-Aldrich.
Methylsulfonyl chloride, toluenesulfonyl chloride, 4-trifluoromethylbenzenesulfonyl
chloride, and 4-nitrobenzenesulfonyl chloride were obtained from Fluka
and Sigma-Aldrich. Glutathione was obtained from Alfa Aesar. The A2780
ovarian, A2780 Cis ovarian, A549 lung, HEPG2 hepatocellular, and MCF7
breast human adenocarcinoma cell lines as well as MRC5 human fibroblast
cells were purchased from the European Collection of Animal Cell Culture
(ECACC, Salisbury, U.K.). Propidium iodide (>94%) and RNase A were
obtained from Sigma-Aldrich.
## Syntheses
Syntheses To a stirred solution
of 3-(1,4-cyclohexadien-1-yl)-1-propanol
(1.21 g, 9.18 mmol) in DCM (25 mL) was added NEt 3 (2.7
mL, 19.28 mmol), and the resulting solution was cooled to 273 K. A
solution of methanesulfonyl chloride (1.1 mL, 13.8 mmol) was added
over a period of 20 min, and the internal temperature was kept at
278 K. After 30 min, the solution was warmed to ambient temperature
and stirred overnight. The reaction solution was quenched with saturated
NaHCO 3 solution, washed with water and brine, and dried
over Mg 2 SO 4 . The mesylate product was carried
forward directly to the next step. A solution of the mesylate derivative
in 10 mL of 1,2-dimethoxyethane (DME) was added slowly over a period
of 5 min to a stirred solution of monosulfonated ethylenediamine (9.25
mmol) in 1,2-dimethoxyethane (20 mL) and NEt 3 (2.7 mL,
19.43 mmol) at 333 K. The resulting solution was heated to 353 K and
stirred overnight. The reaction was quenched with saturated NaHCO 3 solution. The reaction mixture was worked up with water and
brine and dried over Mg 2 SO 4 . The desired ligands
were isolated as yellow oils by silica column chromatography with
EtOAc and hexane as eluents. To a stirred solution of tethered
ethylenediamine ligands (0.808 mmol) in anhydrous EtOH (15 mL) was
added concentrated HCl (0.12 mL, 35%, 1.21 mmol) at 273 K. The solution
was heated at 333 K for 30 min. After this time the solution was heated
to 348 K and a solution of RuCl 3 (0.110 g, 0.533 mmol)
in EtOH (15 mL) and water (0.5 mL) was added dropwise over 20 min.
The solution was stirred at 348 K overnight and cooled, hexane (60
mL) added with vigorous stirring, and the resulting solid collected
by filtration. The solid (dimer precursor) was then washed with hexane
and dried under high vacuum to give a dark brown solid. The filtrate
was concentrated to give an orange powder. To a stirred solution
of dimer precursors (0.22 mmol) in DCM (50
mL) at 273 K was added N,N -diisopropylethylamine
(3.0 mL, 1.70 mmol), and the solution was stirred at ambient temperature
for 2 h. The solution was then filtered over Celite, and the DCM was
removed by rotary evaporation. EtOH was added to the resulting paste
and stored in the freezer for 3 h before the cold solution was filtered,
and the orange precipitate was collected. The precipitate was washed
with further portions of cold EtOH. The desired ruthenium complex
was isolated by silica column chromatography with MeOH and DCM (1/10
v/v). [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ms)Cl] ( 1 ) The general synthesis
of tethered Ru complexes followed a reported protocol. 43 Yield: 47 mg (60%). 1 H NMR (400 MHz,
MeOD- d 4 ): δ H 1.98–2.04
(m, 1H), 2.29–2.41 (m, 4H), 2.48–2.51 (m, 1H), 2.76
(s, 3H), 2.79–2.82 (m, 2H), 2.87 (d, 1H, J = 7.7 Hz), 3.24–3.28 (m, 1H), 5.14–5.20 (m, 2H), 5.71–5.72
(m, 1H), 5.83–5.88 (m, 2H). 13 C NMR (125.7 MHz,
DMSO- d 6 ): δ C 33.3, 43.8,
52.7, 56.8, 62.0, 78.5, 82.1, 82.9, 95.3, 98.0, 105.5. HR-MS: calcd
for [C 13 H 22 ClN 2 O 2 SRu] + m / z 357.0211, found m / z 357.0211. Anal. Calcd for [C 12 H 19 ClN 2 O 2 RuS(H 2 O) 0.6 ]: C, 35.79; H, 5.06; N, 6.96. Found: C, 35.83; H, 4.91;
N, 6.94. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl] ( 2 ) The synthesis of complex 2 ( but not its X-ray
structure) was reported previously by
one of us. 43 The method described above
for complex 1 was used. Recrystallization from methanol
resulted in a bright red solid. Yield: 63 mg (63%). 1 H
NMR (400 MHz, CDCl 3 ): δ H 7.73 (d, 2H, J = 8.2 Hz), 7.15 (d, 2H, J = 8.2 Hz),
6.36 (t, 1H, J = 5.6 Hz), 5.96 (t, 1H, J = 5.6 Hz), 5.83 (t, 1H, J = 5.8 Hz), 5.01 (d, 1H, J = 5.6 Hz), 4.91 (d, 1H, J = 5.8 Hz),
3.79 (s, 1H), 3.30–3.23 (m, 1H), 3.03 (dd, 1H, J = 11.5 Hz, 4.2 Hz), 2.79–2.71 (m, 1H), 2.66–2.62 (m,
1H), 2.43–2.36 (m, 3H), 2.34 (s, 3H), 2.27–2.19 (m,
2H), 2.08–1.99 (m, 1H). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 26.1, 33.2, 33.5, 52.2, 56.7, 62.0,
78.9, 82.1, 83.2, 94.5, 97.6, 104.9, 132.1, 133.6, 144.5, 146.9. HR-MS:
calcd for [C 18 H 23 N 2 O 2 RuS] + m / z 433.0524, found m / z 433.0522. Anal. Calcd for [C 18 H 23 ClN 2 O 2 RuS(H 2 O) 0.1 ]: C, 46.02; H, 4.98; N, 5.96. Found: C, 46.03; H, 4.92;
N, 5.93. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Tf)Cl] ( 3 ) Complex 3 was obtained following the method
described above for complex 1 . Recrystallization from
methanol resulted in a brownish-red
solid. Yield: 38 mg (36%). 1 H NMR (400 MHz, DMSO- d 6 ): δ H 1.84–1.86 (m,
1H), 2.10 (t, 1H, J = 11.2 Hz), 2.25 (t, 2H, J = 9.7 Hz), 2.33–2.46 (m, 2H), 2.64 (d, 1H, J = 8.9 Hz), 2.75 (q, 1H, J = 9.7 Hz, 21.9
Hz,), 2.85 (d, 1H, J = 8.0 Hz), 3.14 (s, 1H) (broad
single peak), 4.35 (s, 1H) (broad single peak), 5.27 (d, 1H, J = 4.9 Hz), 5.40 (d, 1H, J = 5.6 Hz),
5.83–5.89 (m, 2H), 5.97 (t, 1H, J = 5.1 Hz),
7.75 (d, 2H, J = 8.0 Hz), 7.93 (d, 2H, J = 8.0 Hz). 13 C NMR (125.7 MHz, DMSO- d 6 ): δ C 33.2, 33.4, 52.3, 56.7, 61.9,
79.2, 81.9, 83.6, 94.8, 97.8, 105.3, 130.1, 132.9, 134.8, 135.1, 135.0. 19 F NMR (376.4 MHz, DMSO- d 6 ): δ F −61.02. HR-MS: calcd for [C 18 H 20 N 2 F 3 O 2 SRu] + m / z 487.0241, found m / z 487.0240. Anal. Calcd for [C 18 H 20 ClF 3 N 2 O 2 RuS(H 2 O) 0.1 ]: C,
41.28; H, 3.89; N, 5.35. Found: C, 41.20; H, 3.65; N, 5.26. [Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Nb)Cl] ( 4 ) Complex 4 was obtained
following the method described above for complex 1 . Recrystallization
from methanol and diethyl ether resulted
in a bright red solid. Yield: 44 mg (43%). 1 H NMR (300
MHz, CDCl 3 ): δ H 2.00–2.08 (m, 1H),
2.14–2.58 (m, 2H), 2.34–2.50 (m, 3H), 2.69–2.82
(m, 2H), 3.12 (dd, 1H, J = 5.5 Hz, 14.8 Hz), 3.23–3.32
(m, 1H), 3.70 (s, 1H) broad single peak, 4.92 (d, 1H, J = 7.9 Hz), 5.00 (d, 1H, J = 7.6 Hz), 5.86 (t, 1H, J = 7.6 Hz,), 5.96 (t, 1H, J = 8.1 Hz),
6.30 (t, 1H, J = 7.3 Hz), 7.96 (d, 2H, J = 11.6 Hz), 8.18 (d, 2H, J = 11.8 Hz). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 33.1,
33.5, 52.4, 56.7, 61.8, 79.3, 81.9, 83.8, 94.8, 97.8, 105.5, 128.4,
133.4, 153.1, 155.0. HR-MS: calcd for [C 17 H 20 N 3 O 4 SRu] + m / z 464.0218, found m / z 464.0216.
Anal. Calcd for [C 17 H 20 ClN 3 O 2 RuS(H 2 O) 0.5 ]: C, 40.20; H, 4.17; N,
8.27. Found: C, 40.26; H, 3.89; N, 8.04.
## [Ru(η
[Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ms)Cl] ( 1 ) The general synthesis
of tethered Ru complexes followed a reported protocol. 43 Yield: 47 mg (60%). 1 H NMR (400 MHz,
MeOD- d 4 ): δ H 1.98–2.04
(m, 1H), 2.29–2.41 (m, 4H), 2.48–2.51 (m, 1H), 2.76
(s, 3H), 2.79–2.82 (m, 2H), 2.87 (d, 1H, J = 7.7 Hz), 3.24–3.28 (m, 1H), 5.14–5.20 (m, 2H), 5.71–5.72
(m, 1H), 5.83–5.88 (m, 2H). 13 C NMR (125.7 MHz,
DMSO- d 6 ): δ C 33.3, 43.8,
52.7, 56.8, 62.0, 78.5, 82.1, 82.9, 95.3, 98.0, 105.5. HR-MS: calcd
for [C 13 H 22 ClN 2 O 2 SRu] + m / z 357.0211, found m / z 357.0211. Anal. Calcd for [C 12 H 19 ClN 2 O 2 RuS(H 2 O) 0.6 ]: C, 35.79; H, 5.06; N, 6.96. Found: C, 35.83; H, 4.91;
N, 6.94.
## [Ru(η
[Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Ts)Cl] ( 2 ) The synthesis of complex 2 ( but not its X-ray
structure) was reported previously by
one of us. 43 The method described above
for complex 1 was used. Recrystallization from methanol
resulted in a bright red solid. Yield: 63 mg (63%). 1 H
NMR (400 MHz, CDCl 3 ): δ H 7.73 (d, 2H, J = 8.2 Hz), 7.15 (d, 2H, J = 8.2 Hz),
6.36 (t, 1H, J = 5.6 Hz), 5.96 (t, 1H, J = 5.6 Hz), 5.83 (t, 1H, J = 5.8 Hz), 5.01 (d, 1H, J = 5.6 Hz), 4.91 (d, 1H, J = 5.8 Hz),
3.79 (s, 1H), 3.30–3.23 (m, 1H), 3.03 (dd, 1H, J = 11.5 Hz, 4.2 Hz), 2.79–2.71 (m, 1H), 2.66–2.62 (m,
1H), 2.43–2.36 (m, 3H), 2.34 (s, 3H), 2.27–2.19 (m,
2H), 2.08–1.99 (m, 1H). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 26.1, 33.2, 33.5, 52.2, 56.7, 62.0,
78.9, 82.1, 83.2, 94.5, 97.6, 104.9, 132.1, 133.6, 144.5, 146.9. HR-MS:
calcd for [C 18 H 23 N 2 O 2 RuS] + m / z 433.0524, found m / z 433.0522. Anal. Calcd for [C 18 H 23 ClN 2 O 2 RuS(H 2 O) 0.1 ]: C, 46.02; H, 4.98; N, 5.96. Found: C, 46.03; H, 4.92;
N, 5.93.
## [Ru(η
[Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Tf)Cl] ( 3 ) Complex 3 was obtained following the method
described above for complex 1 . Recrystallization from
methanol resulted in a brownish-red
solid. Yield: 38 mg (36%). 1 H NMR (400 MHz, DMSO- d 6 ): δ H 1.84–1.86 (m,
1H), 2.10 (t, 1H, J = 11.2 Hz), 2.25 (t, 2H, J = 9.7 Hz), 2.33–2.46 (m, 2H), 2.64 (d, 1H, J = 8.9 Hz), 2.75 (q, 1H, J = 9.7 Hz, 21.9
Hz,), 2.85 (d, 1H, J = 8.0 Hz), 3.14 (s, 1H) (broad
single peak), 4.35 (s, 1H) (broad single peak), 5.27 (d, 1H, J = 4.9 Hz), 5.40 (d, 1H, J = 5.6 Hz),
5.83–5.89 (m, 2H), 5.97 (t, 1H, J = 5.1 Hz),
7.75 (d, 2H, J = 8.0 Hz), 7.93 (d, 2H, J = 8.0 Hz). 13 C NMR (125.7 MHz, DMSO- d 6 ): δ C 33.2, 33.4, 52.3, 56.7, 61.9,
79.2, 81.9, 83.6, 94.8, 97.8, 105.3, 130.1, 132.9, 134.8, 135.1, 135.0. 19 F NMR (376.4 MHz, DMSO- d 6 ): δ F −61.02. HR-MS: calcd for [C 18 H 20 N 2 F 3 O 2 SRu] + m / z 487.0241, found m / z 487.0240. Anal. Calcd for [C 18 H 20 ClF 3 N 2 O 2 RuS(H 2 O) 0.1 ]: C,
41.28; H, 3.89; N, 5.35. Found: C, 41.20; H, 3.65; N, 5.26.
## [Ru(η
[Ru(η 6 -Ph(CH 2 ) 3 -ethylenediamine- N -Nb)Cl] ( 4 ) Complex 4 was obtained
following the method described above for complex 1 . Recrystallization
from methanol and diethyl ether resulted
in a bright red solid. Yield: 44 mg (43%). 1 H NMR (300
MHz, CDCl 3 ): δ H 2.00–2.08 (m, 1H),
2.14–2.58 (m, 2H), 2.34–2.50 (m, 3H), 2.69–2.82
(m, 2H), 3.12 (dd, 1H, J = 5.5 Hz, 14.8 Hz), 3.23–3.32
(m, 1H), 3.70 (s, 1H) broad single peak, 4.92 (d, 1H, J = 7.9 Hz), 5.00 (d, 1H, J = 7.6 Hz), 5.86 (t, 1H, J = 7.6 Hz,), 5.96 (t, 1H, J = 8.1 Hz),
6.30 (t, 1H, J = 7.3 Hz), 7.96 (d, 2H, J = 11.6 Hz), 8.18 (d, 2H, J = 11.8 Hz). 13 C NMR (125.7 MHz, DMSO-d 6 ): δ C 33.1,
33.5, 52.4, 56.7, 61.8, 79.3, 81.9, 83.8, 94.8, 97.8, 105.5, 128.4,
133.4, 153.1, 155.0. HR-MS: calcd for [C 17 H 20 N 3 O 4 SRu] + m / z 464.0218, found m / z 464.0216.
Anal. Calcd for [C 17 H 20 ClN 3 O 2 RuS(H 2 O) 0.5 ]: C, 40.20; H, 4.17; N,
8.27. Found: C, 40.26; H, 3.89; N, 8.04.
## Instruments and Methods
Instruments and Methods NMR Spectroscopy 1 H NMR spectra were obtained
on either a Bruker HD-400, or a AVIII 600 spectrometer at 298 or 310
K. Data were processed by Topspin-NMR version 3.5pl7 (Bruker U.K.
Ltd.), with NMR proton chemical shifts internally referenced to TMS
via 1,4-dioxane in D 2 O (δ 3.75) or residual MeOD- d 4 (δ 3.31 ppm), DMSO- d 6 (δ 2.50 ppm) or CDCl 3 (δ 7.26
ppm). 1D spectra were recorded using standard pulse sequences. NMR
spectra were acquired with 16 transients into 32 k data points over
a spectral width of 14 ppm and 32 transients into 32 k data points
over a spectral width of 30 ppm with 2 s relaxation delay for the
kinetic experiments. High-Resolution Mass Spectrometry (HRMS) All samples
were prepared in methanol. High-resolution mass spectrometry data
were obtained on a Bruker Maxis Plus Q-TOF instrument. Elemental Analysis Elemental analyses were performed
by Warwick Analytical Service using an Exeter Analytical elemental
analyzer (CE440). X-ray Crystallography Single crystals
of 1 – 4 were obtained from a slow
diffusion of diethyl
ether into methanol solutions of the complexes. Suitable crystals
were selected and mounted on a glass fiber with Fromblin oil and placed
on an Xcalibur Gemini diffractometer with a Ruby CCD area detector.
The crystals were kept at 150 ± 2 K during data collection. Using
Olex2, 71 the structure was solved with
the ShelXT 72 structure solution program
using direct methods and refined with the ShelXL 73 refinement package using least-squares minimization. The
data were processed by the modeling program Mercury 3.8. X-ray crystallographic
data for complexes 1 – 4 have been
deposited in the Cambridge Crystallographic Data Center (CCDC) under
the deposition numbers CCDC 1823316–1823319 (complexes 4 , 3 , 2 , and 1 , respectively). ICP-MS/-OES Determination ICP-MS and ICP-OES analyses
were carried out on Agilent Technologies 7500 series and PerkinElmer
Optima 5300 DV series instruments, respectively. The double-deionized
(DDW) water used for both analyses was from a Millipore Milli-Q water
purification system and a USF Elga UHQ water deionizer. The Ruthenium
Specpure plasma standard (ruthenium chloride, 1004 ± 5 μg/mL
in 10% v/v hydrochloric acid) was diluted with 3.6% v/v HNO 3 , and calibrants were prepared freshly at concentrations of 0.1–500
ppb for ICP-MS and 50–700 ppb for ICP-OES. In particular, calibration
standards for ICP-OES analysis were adjusted with standard sodium
chloride (TraceSELECT) solution to match the sample salinity. The
instrument was set to detect 101 Ru with typical detection
using no-gas mode for ICP-MS analysis. TOFs Determined by UV–Vis
Spectroscopy Complexes 1 – 4 were dissolved in DMSO/H 2 O (1/9 v/v) (84 μM) in
a glass vial. Solutions of sodium formate
(102 mM) and NAD + in H 2 O (510 μM) were
also prepared and then mixed at 310 K. In a typical experiment, an
aliquot of 330 μL from each solution was placed in a 1 mL cuvette
and the pH adjusted to 7.2 before the sample was introduced into the
UV–vis instrument, giving a total volume of 1 mL (final concentrations
were Ru complex 28 μM, NAD + 170 μM, NaHCO 2 34 mM, molar ratio 1/6/1200). UV spectra were recorded every
5 min until completion of the reaction. The spectrum was monitored
for an increase in the band at 340 nm, which corresponds to the absorption
of NADH. TOFs Determined by NMR Complexes 1 – 4 were dissolved in DMSO- d 6 /D 2 O (3/2 v/v; 1.4 mM) in a glass vial. Aliquots (200 μL)
of solutions of sodium formate (35 mM) and NAD + (5.6 mM)
in D 2 O were added, and the pH* was adjusted to 7.2 ±
0.1, for a final volume of 0.64 mL (Ru complex 0.44 mM, NAD + 1.75 mM, NaHCO 2 10.94 mM; molar ratio 1/4/25). The solution
was transferred to a 5 mm NMR tube, and a 1 H NMR spectrum
was recorded at 310 K every 162 s until the completion of the reaction.
Molar ratios of NAD + and NADH were determined by integrating
the peaks corresponding to resonances for NAD + (9.33 ppm)
and 1,4-NADH (6.96 ppm). The turnover number (TON) for the reaction
was calculated where I n is the integral of the signal
at n ppm and
[NAD + ] is the concentration of NAD + at the start
of the reaction. Reaction with GSH Reactions of complex 2 (2 mM, MeOD- d 4 /D 2 O (2/8 v/v))
and GSH (in D 2 O) in the mole ratio of 1/ X , where X = 0.2, 0.5, 1, 2, 5, and 10, were studied
by 1 H NMR (600 MHz) spectroscopy under conditions of MeOD- d 4 /D 2 O (1/9 v/v), pH* 7.2, and 310
K. Each reaction was complete within 10 min. A second set of experiments
investigated the time dependence of reactions of 2 with
GSH (20 mM) in the mole ratio of 1/20, monitored by 1 H
NMR (600 MHz) spectroscopy under conditions similar to those above
(pH* 7.2, 310 K), from 5 min to 24 h. Cell Culture A2780
and A2780Cis human ovarian, A549
human lung, HEPG 2 human hepatocellular, MCF 7 human breast cancer,
and MRC 5 human normal fibroblast cell lines were grown in Roswell
Park Memorial Institute medium (RPMI-1640) supplemented with 10% of
fetal calf serum, 1% of 2 mM glutamine, and 1% penicillin/streptomycin.
All cells were grown as adherent monolayers at 310 K with 5% CO 2 humidified, and all cells were passaged at ca. 80% confluency. IC 50 and in Vitro Cytotoxicity Determination The antiproliferative activity and cytotoxicity of complexes 1 – 4 were determined in five different
cancer cell lines and one human normal cell line. In general, about
5000 cells per well were seeded in 96-well plates. The plates were
preincubated with drug-free medium at 310 K for 48 h before adding
the tested compounds (various concentrations). Stock solutions of
complexes 1 – 4 were prepared in DMSO/cell
culture medium, and exact complex concentrations were determined by
ICP-OES. After 24 h drug exposure, supernatants were removed by suction
and each well was washed with PBS. A further cell recovery for 72
h was allowed in drug-free medium at 310 K. The sulforhodamine B (SRB)
assay was used to determine cell viability. IC 50 values,
as the concentration that causes 50% cell death, were determined as
duplicates of triplicates in two independent sets of experiments,
and their standard deviations were calculated. Cellular Ru
Accumulation Cellular Ru accumulations
for complexes 2 and 4 were determined on
A2780 ovarian and A2780 cisplatin-resistant ovarian cancer cells.
Approximately 2 × 10 6 cells were seeded in a six-well
plate and preincubated in drug-free medium at 310 K for 24 h, and
stock solutions of both complexes were prepared in a mixture of DMSO/cell
culture medium and their accurate Ru concentrations were determined
by ICP-OES. Working solutions were then obtained by dilution in cell
culture medium. Both cancer cell lines were exposed to complexes 2 and 4 for 24 h, at equipotent IC 50 concentrations. The experiment did not involve recovery time in
drug-free medium. After this time, cells were treated with trypsin
and counted and cell pellets were collected. Cell pellets were digested
overnight in 200 μL concentrated nitric acid (73%) at 353 K;
the resulting solutions were diluted with double-distilled water to
a final concentration of 3.6% HNO 3 (v/v), and the amount
of Ru taken up by the cells was determined by ICP-MS (Agilent technologies
7500 series). Data acquisition was carried out in ICP-MS top B.03.05
and processed on offline Data analysis B.03.05. These experiments
did not include any cell recovery time in drug-free media; they were
carried out in triplicate, and the standard deviations were calculated.
Statistical significances of variations were determined using Welch’s t -tests. Cell Cycle Analysis A2780 cells
at 1.5 × 10 6 cells per well were seeded in a six-well
plate. Cells were
preincubated in drug-free media at 310 K for 24 h, after which drugs
were added at equipotent concentration equal to the IC 50 value. After 24 h of drug exposure, supernatants were removed by
suction and cells were washed with PBS. Finally, cells were harvested
using trypsin-EDTA and fixed for 2 h using cold 70% ethanol. DNA staining
was achieved by resuspending the cell pellets in PBS containing propidium
iodide (PI) and RNase. Cell pellets were washed and resuspended in
PBS before being analyzed in a Becton Dickinson FACScan flow cytometer
using excitation of DNA-bound PI at 536 nm, with emission at 617 nm.
Data were processed with Flowjo software using a Watson (Pragmatic)
fitting model. Welch’s t -tests were carried
out to determine the statistical variations. ROS Determination Flow cytometry analysis of ROS/superoxide
generation in A2780 cells caused by exposure to complex 2 was carried out using the Total ROS/Superoxide detection kit (Enzo-Life
Sciences) according to the instructions. A total of 1.5 × 10 6 A2780 cells per well were seeded in a six-well plate. Cells
were preincubated in drug-free media at 310 K for 24 h in a 5% CO 2 humidified atmosphere, and then drugs were added to triplicates
at IC 50 concentration. After 24 h of drug exposure, supernatants
were removed by suction and cells were washed and harvested. Staining
was achieved by resuspending the cell pellets in buffer containing
the orange/green fluorescent reagents. Cells were analyzed in a Becton
Dickinson FACScan flow cytometer using FL1 channel Ex/Em 490/525 nm
for the oxidative stress and FL2 channel Ex/Em 550/620 nm for superoxide
detection. Positive controls were obtained by exposure of cells to
pyocyanin for 30 min. Data were processed using Flowjo software. At
all times, samples were kept under dark conditions to avoid light-induced
ROS production. Welch’s t -tests were carried
out to establish statistical significance of the variations. Cell
Membrane Integrity Determination Flow cytometry
analysis of the cellular membrane integrity of A2780 cells caused
by exposure to complex 2 was carried out using flow cytometry
and propidium iodide staining. Briefly, A2780 cells were seeded in
six-well plates (1.5 × 10 6 cells per well) and preincubated
for 24 h in drug-free media at 310 K, after which they were exposed
to complex 2 at IC 50 concentration. Cells
were harvested using trypsin and stained in the dark using a mixture
of propidium iodide and RNase without previous fixation of the cells.
After staining, cell pellets were analyzed in a Becton Dickinson FACScan
Flow Cytometer and the histograms were analyzed using Flowjo software
and their standard deviations were calculated. Coincubation
of Ru Complexes with Formate Cell viability
assays of complexes 1 – 4 were carried
out with A2780 ovarian cancer cells with sodium formate. These experiments
were performed with the following modifications: a fixed concentration
of each Ru complex equal to 1/3 × IC 50 was used in
coadministration with three different concentrations of sodium formate
(0.5, 1.0, and 2.0 mM). Drug stock solutions (ca. 100 μM) were
prepared as described for in vitro growth inhibition assays and then
further diluted with media until working concentrations were achieved.
Separately, a stock solution of sodium formate was prepared in saline.
The complex and formate solutions were added to each well independently
within 5 min of each other. All other experimental conditions were
kept unchanged (drug exposure, cell recovery time, and end point assay
used). The standard deviations were calculated.
## NMR Spectroscopy
NMR Spectroscopy 1 H NMR spectra were obtained
on either a Bruker HD-400, or a AVIII 600 spectrometer at 298 or 310
K. Data were processed by Topspin-NMR version 3.5pl7 (Bruker U.K.
Ltd.), with NMR proton chemical shifts internally referenced to TMS
via 1,4-dioxane in D 2 O (δ 3.75) or residual MeOD- d 4 (δ 3.31 ppm), DMSO- d 6 (δ 2.50 ppm) or CDCl 3 (δ 7.26
ppm). 1D spectra were recorded using standard pulse sequences. NMR
spectra were acquired with 16 transients into 32 k data points over
a spectral width of 14 ppm and 32 transients into 32 k data points
over a spectral width of 30 ppm with 2 s relaxation delay for the
kinetic experiments.
## High-Resolution Mass Spectrometry (HRMS)
High-Resolution Mass Spectrometry (HRMS) All samples
were prepared in methanol. High-resolution mass spectrometry data
were obtained on a Bruker Maxis Plus Q-TOF instrument.
## Elemental Analysis
Elemental Analysis Elemental analyses were performed
by Warwick Analytical Service using an Exeter Analytical elemental
analyzer (CE440).
## X-ray Crystallography
X-ray Crystallography Single crystals
of 1 – 4 were obtained from a slow
diffusion of diethyl
ether into methanol solutions of the complexes. Suitable crystals
were selected and mounted on a glass fiber with Fromblin oil and placed
on an Xcalibur Gemini diffractometer with a Ruby CCD area detector.
The crystals were kept at 150 ± 2 K during data collection. Using
Olex2, 71 the structure was solved with
the ShelXT 72 structure solution program
using direct methods and refined with the ShelXL 73 refinement package using least-squares minimization. The
data were processed by the modeling program Mercury 3.8. X-ray crystallographic
data for complexes 1 – 4 have been
deposited in the Cambridge Crystallographic Data Center (CCDC) under
the deposition numbers CCDC 1823316–1823319 (complexes 4 , 3 , 2 , and 1 , respectively).
## ICP-MS/-OES Determination
ICP-MS/-OES Determination ICP-MS and ICP-OES analyses
were carried out on Agilent Technologies 7500 series and PerkinElmer
Optima 5300 DV series instruments, respectively. The double-deionized
(DDW) water used for both analyses was from a Millipore Milli-Q water
purification system and a USF Elga UHQ water deionizer. The Ruthenium
Specpure plasma standard (ruthenium chloride, 1004 ± 5 μg/mL
in 10% v/v hydrochloric acid) was diluted with 3.6% v/v HNO 3 , and calibrants were prepared freshly at concentrations of 0.1–500
ppb for ICP-MS and 50–700 ppb for ICP-OES. In particular, calibration
standards for ICP-OES analysis were adjusted with standard sodium
chloride (TraceSELECT) solution to match the sample salinity. The
instrument was set to detect 101 Ru with typical detection
using no-gas mode for ICP-MS analysis.
## TOFs Determined by UV–Vis
Spectroscopy
TOFs Determined by UV–Vis
Spectroscopy Complexes 1 – 4 were dissolved in DMSO/H 2 O (1/9 v/v) (84 μM) in
a glass vial. Solutions of sodium formate
(102 mM) and NAD + in H 2 O (510 μM) were
also prepared and then mixed at 310 K. In a typical experiment, an
aliquot of 330 μL from each solution was placed in a 1 mL cuvette
and the pH adjusted to 7.2 before the sample was introduced into the
UV–vis instrument, giving a total volume of 1 mL (final concentrations
were Ru complex 28 μM, NAD + 170 μM, NaHCO 2 34 mM, molar ratio 1/6/1200). UV spectra were recorded every
5 min until completion of the reaction. The spectrum was monitored
for an increase in the band at 340 nm, which corresponds to the absorption
of NADH.
## TOFs Determined by NMR
TOFs Determined by NMR Complexes 1 – 4 were dissolved in DMSO- d 6 /D 2 O (3/2 v/v; 1.4 mM) in a glass vial. Aliquots (200 μL)
of solutions of sodium formate (35 mM) and NAD + (5.6 mM)
in D 2 O were added, and the pH* was adjusted to 7.2 ±
0.1, for a final volume of 0.64 mL (Ru complex 0.44 mM, NAD + 1.75 mM, NaHCO 2 10.94 mM; molar ratio 1/4/25). The solution
was transferred to a 5 mm NMR tube, and a 1 H NMR spectrum
was recorded at 310 K every 162 s until the completion of the reaction.
Molar ratios of NAD + and NADH were determined by integrating
the peaks corresponding to resonances for NAD + (9.33 ppm)
and 1,4-NADH (6.96 ppm). The turnover number (TON) for the reaction
was calculated where I n is the integral of the signal
at n ppm and
[NAD + ] is the concentration of NAD + at the start
of the reaction.
## Reaction with GSH
Reaction with GSH Reactions of complex 2 (2 mM, MeOD- d 4 /D 2 O (2/8 v/v))
and GSH (in D 2 O) in the mole ratio of 1/ X , where X = 0.2, 0.5, 1, 2, 5, and 10, were studied
by 1 H NMR (600 MHz) spectroscopy under conditions of MeOD- d 4 /D 2 O (1/9 v/v), pH* 7.2, and 310
K. Each reaction was complete within 10 min. A second set of experiments
investigated the time dependence of reactions of 2 with
GSH (20 mM) in the mole ratio of 1/20, monitored by 1 H
NMR (600 MHz) spectroscopy under conditions similar to those above
(pH* 7.2, 310 K), from 5 min to 24 h.
## Cell Culture
Cell Culture A2780
and A2780Cis human ovarian, A549
human lung, HEPG 2 human hepatocellular, MCF 7 human breast cancer,
and MRC 5 human normal fibroblast cell lines were grown in Roswell
Park Memorial Institute medium (RPMI-1640) supplemented with 10% of
fetal calf serum, 1% of 2 mM glutamine, and 1% penicillin/streptomycin.
All cells were grown as adherent monolayers at 310 K with 5% CO 2 humidified, and all cells were passaged at ca. 80% confluency.
## IC
IC 50 and in Vitro Cytotoxicity Determination The antiproliferative activity and cytotoxicity of complexes 1 – 4 were determined in five different
cancer cell lines and one human normal cell line. In general, about
5000 cells per well were seeded in 96-well plates. The plates were
preincubated with drug-free medium at 310 K for 48 h before adding
the tested compounds (various concentrations). Stock solutions of
complexes 1 – 4 were prepared in DMSO/cell
culture medium, and exact complex concentrations were determined by
ICP-OES. After 24 h drug exposure, supernatants were removed by suction
and each well was washed with PBS. A further cell recovery for 72
h was allowed in drug-free medium at 310 K. The sulforhodamine B (SRB)
assay was used to determine cell viability. IC 50 values,
as the concentration that causes 50% cell death, were determined as
duplicates of triplicates in two independent sets of experiments,
and their standard deviations were calculated.
## Cellular Ru
Accumulation
Cellular Ru
Accumulation Cellular Ru accumulations
for complexes 2 and 4 were determined on
A2780 ovarian and A2780 cisplatin-resistant ovarian cancer cells.
Approximately 2 × 10 6 cells were seeded in a six-well
plate and preincubated in drug-free medium at 310 K for 24 h, and
stock solutions of both complexes were prepared in a mixture of DMSO/cell
culture medium and their accurate Ru concentrations were determined
by ICP-OES. Working solutions were then obtained by dilution in cell
culture medium. Both cancer cell lines were exposed to complexes 2 and 4 for 24 h, at equipotent IC 50 concentrations. The experiment did not involve recovery time in
drug-free medium. After this time, cells were treated with trypsin
and counted and cell pellets were collected. Cell pellets were digested
overnight in 200 μL concentrated nitric acid (73%) at 353 K;
the resulting solutions were diluted with double-distilled water to
a final concentration of 3.6% HNO 3 (v/v), and the amount
of Ru taken up by the cells was determined by ICP-MS (Agilent technologies
7500 series). Data acquisition was carried out in ICP-MS top B.03.05
and processed on offline Data analysis B.03.05. These experiments
did not include any cell recovery time in drug-free media; they were
carried out in triplicate, and the standard deviations were calculated.
Statistical significances of variations were determined using Welch’s t -tests.
## Cell Cycle Analysis
Cell Cycle Analysis A2780 cells
at 1.5 × 10 6 cells per well were seeded in a six-well
plate. Cells were
preincubated in drug-free media at 310 K for 24 h, after which drugs
were added at equipotent concentration equal to the IC 50 value. After 24 h of drug exposure, supernatants were removed by
suction and cells were washed with PBS. Finally, cells were harvested
using trypsin-EDTA and fixed for 2 h using cold 70% ethanol. DNA staining
was achieved by resuspending the cell pellets in PBS containing propidium
iodide (PI) and RNase. Cell pellets were washed and resuspended in
PBS before being analyzed in a Becton Dickinson FACScan flow cytometer
using excitation of DNA-bound PI at 536 nm, with emission at 617 nm.
Data were processed with Flowjo software using a Watson (Pragmatic)
fitting model. Welch’s t -tests were carried
out to determine the statistical variations.
## ROS Determination
ROS Determination Flow cytometry analysis of ROS/superoxide
generation in A2780 cells caused by exposure to complex 2 was carried out using the Total ROS/Superoxide detection kit (Enzo-Life
Sciences) according to the instructions. A total of 1.5 × 10 6 A2780 cells per well were seeded in a six-well plate. Cells
were preincubated in drug-free media at 310 K for 24 h in a 5% CO 2 humidified atmosphere, and then drugs were added to triplicates
at IC 50 concentration. After 24 h of drug exposure, supernatants
were removed by suction and cells were washed and harvested. Staining
was achieved by resuspending the cell pellets in buffer containing
the orange/green fluorescent reagents. Cells were analyzed in a Becton
Dickinson FACScan flow cytometer using FL1 channel Ex/Em 490/525 nm
for the oxidative stress and FL2 channel Ex/Em 550/620 nm for superoxide
detection. Positive controls were obtained by exposure of cells to
pyocyanin for 30 min. Data were processed using Flowjo software. At
all times, samples were kept under dark conditions to avoid light-induced
ROS production. Welch’s t -tests were carried
out to establish statistical significance of the variations.
## Cell
Membrane Integrity Determination
Cell
Membrane Integrity Determination Flow cytometry
analysis of the cellular membrane integrity of A2780 cells caused
by exposure to complex 2 was carried out using flow cytometry
and propidium iodide staining. Briefly, A2780 cells were seeded in
six-well plates (1.5 × 10 6 cells per well) and preincubated
for 24 h in drug-free media at 310 K, after which they were exposed
to complex 2 at IC 50 concentration. Cells
were harvested using trypsin and stained in the dark using a mixture
of propidium iodide and RNase without previous fixation of the cells.
After staining, cell pellets were analyzed in a Becton Dickinson FACScan
Flow Cytometer and the histograms were analyzed using Flowjo software
and their standard deviations were calculated.
## Coincubation
of Ru Complexes with Formate
Coincubation
of Ru Complexes with Formate Cell viability
assays of complexes 1 – 4 were carried
out with A2780 ovarian cancer cells with sodium formate. These experiments
were performed with the following modifications: a fixed concentration
of each Ru complex equal to 1/3 × IC 50 was used in
coadministration with three different concentrations of sodium formate
(0.5, 1.0, and 2.0 mM). Drug stock solutions (ca. 100 μM) were
prepared as described for in vitro growth inhibition assays and then
further diluted with media until working concentrations were achieved.
Separately, a stock solution of sodium formate was prepared in saline.
The complex and formate solutions were added to each well independently
within 5 min of each other. All other experimental conditions were
kept unchanged (drug exposure, cell recovery time, and end point assay
used). The standard deviations were calculated.