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Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene versus thiacrown face-cap
Interdisciplinary Journal of Chemistry
Review Article
Anticancer, biophysical and computational investigations
of half-sandwich ruthenium(II) thiosemicarbazone
complexes: The effect of arene versus thiacrown face-cap
Floyd A Beckford1*, Alyssa Stott1, P Canisius Mbarushimana1, Marc-Andre LeBlanc1, Kinsey Hall2, Samantha Smith2, Jimmie L Bullock3, Dennis
J Houghton3, Alvin A Holder3, Nikolay Gerasimchuk4, Antonio Gonzalez-Sarrías5 and Navindra P Seeram5
Science Division, Lyon College, Batesville, AR 72501, USA
The University of Virginia’s College at Wise, 1 College Avenue, Wise, VA 24293, USA
3
Department of Chemistry and Biochemistry Old Dominion University, 4541 Hampton Boulevard, Norfolk, VA 23529, USA
4
Department of Chemistry, Missouri State University, Springfield, MO 65897, USA
5
Department of Biomedical and Pharmaceutical Sciences, College of Pharmacy, University of Rhode Island, Kingston, RI 02881, USA
1
2
Abstract
A series of half-sandwich ruthenium complexes, two containing an arene face-cap and the other a thiacrown ether face-cap were synthesized to investigate the
necessity of the arene for anticancer activity in this class of compounds. The complexes are formulated as [(η6-p-cymene)Ru(dmabTSC)Cl]PF6, [(η6-benzene)
Ru(dmabTSC)Cl]PF6 (arene complexes), and [([9]aneS3(dmabTSC)Cl]PF6 (dmabTSC = dimethylaminobenzaldehye thiosemicarbazone). It was observed that none
of the complexes showed good anticancer activity in vitro against HCT-116 and Caco-2 (colon adenocarcinoma) cells. All three complexes can bind strongly to calfthymus DNA with binding constants on the order of 105 M-1. In addition they all bind strongly to human serum albumin with binding constants between 105 and
106 M-1. There appears to be a single binding site on the protein for these complexes. A computational investigation of these complexes and their hydrolysis products
was carried out by molecular docking with DNA and topoisomerase II. From this analysis it is noted that the type of face-capping ligand had different effects on the
two macromolecules. It is therefore noted that the knowledge gained from this study will be useful in identifying the type of complexes in this class that show useful
metallodrug potential.
Introduction
Over the last decade or so half-sandwich organometallic ruthenium
complexes of the type [(arene)Ru(LL)Cl][X] or [(arene)Ru(L)(L)Cl]
[X] (Figure 1), have been generating significant interest as potential
antitumor complexes [1-7]. These piano-stool complexes exhibit ligand
exchange kinetics and generally different chemical reactivity when
compared to the classical coordination complexes that are in various
phases of clinical trials [8,9]. They also offer a novel structural motif
which could prove useful in designing new drugs that have a wealth of
variety in structure and hopefully in biological activity.
Figure 1 suggest two obvious variations–the “seat” of the pianostool (or the arene) and the “legs” of the stool (or the ligand (LL)
system). In original reports it was proposed that a more hydrophobic
arene ligand and a single exchange site (the other two coordination sites
being occupied by a stable bidentate chelating ligand), are associated
with high in vitro cytotoxicity [4,10]. Complexes that lacked NH groups
on the coordinated ligand were often inactive. It was thought that the
stereospecific H-bonding could optimize DNA recognition [11].
Likewise, it was proposed that arenes with extended ring structures
were more carcinostatic as a result of being better able to intercalate
into DNA. So for a series of similar complexes cytotoxicity was in
the order benzene < p-cymene < biphenyl < dihydroanthracene <
tetrahydroanthracene. Through recent studies however, it has emerged
that the structure-activity relationship is more complex. A wide
variety of chelating ligand systems have been used to create cytotoxic
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
complexes [11]. Thiosemicarbazones [6,7,12], pyrones [13,14],
phenanthroimidazoles [15], and 1,3,5-triaza-7-phosphadamantane,
pta [3], are a small sample of such ligand systems. In fact the RAPTA
complexes [3] may be sufficiently distinctive from the other pianostool complexes as they have two potential ligand exchange sites. These
complexes have been considered as anti-metastatic agents [16,17] as
opposed to anticancer agents.
Variations in the types of face-caps for the complexes have not
Figure 1. General structure of the anticancer organometallic ruthenium(II) complexes
currently being studied.
Correspondence to: Floyd A Beckford, The University of Virginia’s College at
Wise, 1 College Avenue, Wise, VA 24293, USA, Tel: (276) 376-4657; Fax: (276)
307-7496; E-mail: fab5b@uvawise.edu
Key words: anticancer, computational, human serum albumin, protein binding,
ruthenium, thiosemicarbazone
Received: April 02, 2016; Accepted: May 06, 2016; Published: May 10, 2016
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
been as extensively studied. As mentioned above it is generally thought
that a more lipophilic arene enhances cytotoxicity. Using a non-arene
face-capping ligand has rarely been explored. Of the potential ligands,
1,4,7-trithiacyclononane ([9]aneS3) has been the most attractive.
Alessio [18-20] have developed a series of non-organometallic pianostool complexes based on this ligand. When compared to [(η6-biphenyl)
Ru(en)Cl]PF6 the one complex that showed any activity [([9]aneS3)
Ru(en)Cl][CF3SO3], was an order of magnitude less in terms of antiproliferative activity [18]. Still the authors suggest that the thiacrown
ligand would be a suitable substitute for the arene as a face-capping in
these piano-stool complexes.
an internal standard. The working electrode was polished before each
experiment with alumina slurry. Absorption spectra were recorded
on an Agilent 8453A spectrophotometer. Fluorescence spectra were
recorded on a Varian Cary Eclipse or on a Perkin Elmer LS-50B
spectrophotometer. One of the metal complexes was synthesized using
a Discover S-Class microwave reactor (CEM, Matthews, USA). ESI MS
spectra were acquired via positive electrospray ionization on a Bruker
12 Tesla APEX –Qe FTICR-MS with and Apollo II ion source. Samples
were first dissolved in methanol, and then the solution was introduced
by direct injection using a syringe pump with a flow rate of 2 µl s-1. The
data was processed using Bruker Daltonics Data Analysis Version 3.4.
In an effort to further investigate if the arene is required for
anticancer activity in these half-sandwich ruthenium complexes, we
have synthesized three complexes containing either an arene or [9]
aneS3 face-capping ligand and a bidentate thiosemicarbazone chelating
ligand (Figure 2).
X-ray single-crystal data was determined at room temperature
due to the crystal’s instability upon cooling in the cryo-stream flow. A
suitable clear dark red-brown plate-like single crystal of the compound
was selected and with the help of vacuum grease mounted on a thin
galls fiber attached to the copper-pin positioned on the goniometer
head of the Bruker APEX 2 diffractometer equipped with a SMART
CCD area detector. The intensity data were collected in ω scan mode
using the Mo tube (Kα radiation; λ = 0.71073 Å) with a highly oriented
graphite monochromator. Intensities were integrated from 4 series of
364 exposures, each covering 0.5o in ω at 20 seconds of acquisition
time, with the total data set being a sphere [21]. The space group
determination was done with the aid of XPREP software [21]. The
absorption correction was performed by the numerical method using
the set of images obtained from the video-microscope and using
the SADABS program from Bruker AXS software package [22]. The
structure was solved by direct methods and refined by least squares on
weighted F2 values for all reflections using the SHELXTL program.
Material and methods
Physical measurements
Analytical or reagent grade chemicals were used throughout. All
the chemicals including solvents were obtained from Sigma-Aldrich
or other commercial vendors and used as received. Microanalyses
(C, H, N) were performed by Columbia Analytical, (Tucson, AZ) or
by Galbraith Laboratories, (Knoxville, TN). The 1H and 13C NMR
spectra were acquired on a Varian Unity 400 MHz NMR. Samples
were dissolved in DMSO-d6 and spectra were acquired at 25° C. The
residual protons present in DMSO-d6 (2.50 ppm) were used as internal
references. Normal IR spectra in the range 4000–500 cm-1 were obtained
using KBr pellets or using the ATR accessory on a Nicolet 6700 FTIR
spectrophotometer. For the metal complex-HSA (HSA is human
serum albumin) interaction experiments, a Perkin-Elmer Spectrum
100 spectrometer with a UATR accessory containing a diamond-ZnSe
crystal was used. (Peaks are defined as w=weak and b=broad). Cyclic
voltammetric (CV) data were collected on a Bioanalytical Systems Inc.
Epsilon workstation on a C3 cell stand at 296 K. DMSO solutions (1
x 10-3 M) containing 0.1 M tetrabutylammonium hexafluorophosphate
were saturated with nitrogen for 15 minutes prior to each run. A
blanket of nitrogen gas was maintained throughout the measurements.
The measurements were carried out with a three-electrode system
consisting of a platinum working electrode, a platinum wire auxiliary
electrode and a Ag/AgCl reference electrode. Ferrocene was used as
Syntheses
The ligand (dmabTSC) was synthesized as previously described.[23]
The ruthenium dimers, [(η6-C6H6)RuCl2]2 and [(η6-C10H14)RuCl2]2,[24]
as well as [[9]aneS3)RuCl2(DMSO)],[25] were synthesized as described
in the literature.
Synthesis of [(C6H6)Ru(dmabTSC)Cl]PF6, 1. In a 35-mL microwave
reaction vessel, [(C6H6)RuCl2]2 (200 mg, 0.400 mmol) and dmabTSC
(183 mg, 0.823 mmol), was suspended in 15 cm3 of methanol.
The brown-orange suspension was degassed for 10 minutes using
argon. The reaction mixture was heated using the following method:
temperature = 67°C, power = 225 W, maximum pressure = 250 psi
and time = 10 minutes. At the end of the reaction time a blood-red
Figure 2. Proposed structure of the complexes synthesized in the study
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
mixture had formed. Addition of 5 cm3 of a saturated aqueous solution
of NH4PF6 produced an orange-brown suspension which was filtered.
The solid was washed with water and ether and air-dried to give a rustred solid (93%). Elemental analysis for C16H20ClF6N4PRuS (found/
calc.): C 32.57/33.02, H 3.34/3.46, N 9.65/9.63. IR (cm-1): 3307(b,w),
3179(b,w), 3088(w), 2982, 2883(w), 1630, 1570(w), 1547, 1440, 1246,
1004(b), 833, 711, 644. 1H NMR (400 MHz, DMSO-d6) δ ppm 9.67 (s,
1 H, NH), 8.68 (s, 1H, NH-C=S); 8.19 (3 H, m); 6.69(dd, 2H1,5, ArH);
6.55(d, 2H2,4, J = 9.4 Hz, CH) 6.08 and 6.27 (m, 6H11-16, CH); 6.69(dd,
2H1,5, ArH) 4.85 (br. s. 2 H, NH2); 3.04(s, 3H10, CH3); 3.02(s, 3H9, CH3).
13
C NMR (101MHz, DMSO-d6, δ ppm): 176.9, 173.0 (C-8), 158.0 (C-7),
151.8 (C-3), 134.7 (C-6), 121.5 (C-1, 5), 111.1 (C-10, 12), 92.4 and 89.8
(C-11-16), 29.32 (C-9, 10).
Synthesis of [(C10H14)Ru(dmabTSC)Cl]PF6, 2. The ruthenium dimer,
[(C10H14)RuCl2]2, 200 mg (0.326 mmol) was dissolved in 10 cm3 of
methanol and the solution degassed with argon for 15 minutes. The
solid dmabTSC (145 mg, 0.652 mmol) was added to the orange metal
solution and the reaction mixture stirred at room temperature for 2h.
To the resulting red solution, 10 cm3 of a saturated aqueous solution of
KPF6 was added and the reaction mixture stirred for a further 1½ h. The
orange-red suspension was filtered and the solid obtained was washed
with water and ether and air-dried to give an orange-red solid (77%).
Elemental analysis for C20H28ClF6N4PRuS (found/calc.): C 38.04/37.65,
H 3.99/4.42, N 8.66/8.78. IR (cm-1): 3634(w), 3562(w), 3472, 3368,
3296, 3166(b), 2971, 2931, 2875, 2811, 1733 (w,b), 1603, 1565, 1525,
1475, 1448, 1438, 1369, 1320, 1227, 1190, 1170, 1126, 1059(w), 1027,
945, 878, 833, 644. 1H NMR (400 MHz, DMSO-d6) δ ppm 9.67 (s, 1 H,
NH), 8.69 (s, 1H, H-C=N); 7.71 (d, 2H2,4, J = 8.6 Hz, CH), 7.66 (dd, 2H,
J = 8.9 Hz, J = 9.0 Hz, NH2); 6.72 (m, 2H1,5, CH); 6.14 (d, 1H11, J = 5.8
Hz, CH); 6.04 (d, 1H12, J = 5.8 Hz, CH); 5.90 (d, 1H14, J = 6.1 Hz, CH);
5.82 (d, 1H15, J = 5.8 Hz, CH), 3.03 (m, 6 H, (CH3)2), 2.75 (m, 1 H, CH),
2.29 (3 H, CH3), 1.19 (t, 3 H, J=6.5 Hz, CH3), 1.00 (t, 2 H, J=6.49 Hz,
CH3). 13C NMR (101 MHz, DMSO-d6, δ ppm): 176.9 (C-8), 157.0 (C7), 151.6 (C-6), 134.7 (C-3), 129.6 (C-4, C-5), 126.0 (C-1, C-2), 106.3
(C-13), 105.4 (C-16), 91.3 (C-15), 89.7 (C-11), 87.6 (C-14), 82.7 (C-12),
31.2 (C-17), 23.9 (C-18), 21.7 (C-19), 18.6 (C-20)
Synthesis of [([9]aneS3)Ru(dmabTSC)Cl]PF6⋅0.5C4H10O, 3. The
ruthenium starting compound [([9]aneS3)RuCl2(DMSO)] (100 mg,
0.232 mmol) and the dmabTSC (62 mg, 0.278 mmol) along with NH4PF6
(2 equivalents) was partially dissolved in 20 cm3 of methanol. Under
argon the reaction mixture was heated at reflux for 1½ h. The orangeyellow suspension that resulted was filtered and the solid washed with
water and ether and air-dried to give a yellow solid (66%). Elemental
analysis for C18H31ClF6N4O0.5PRuS4 (found/calc.): C 29.57/29.98, H
4.00/4.33, N 8.15/7.77. IR (cm-1): 3637(w), 3466(w), 3360(w), 3166(b),
2982, 2886, 2162, 2034(vw), 1973(vw), 1603, 1523, 1451, 1411(w),1366,
1318, 1187, 1169, 1128(w), 1075, 1025, 945, 910, 833, 644. 1H NMR (400
MHz, DMSO-d6, δ ppm): 12.03(s, 1H, NH); 8.93-8.88(m, 2H, NH2);
7.97(s, 1H, H-C=N); 7.65(dd, 2H10,14, J = 9.0 Hz, J = 8.9 Hz, CH); 6.716.82(m, 2H11,13, CH); 2.95-3.03(m, 6H15,16, CH3); 2.55-2.89(m, 12H1-6,
CH2). 13C NMR (100 MHz, DMSO-d6, δ ppm): 177.28 (C-7), 173.45
(C-7); 151.93 (C-12); 147.42 (C-8); 133.94 (C-9); 129.24; 120.11 (C-10,
C-14); 111.54 (C-11, C-13); 31.56 - 34.71 (C1-C6), 30.58 (C-15, C-16)
Cell culture
Cell lines included two human colon cancer cells: HCT116
(human colon carcinoma) and Caco-2 (human epithelial colorectal
adenocarcinoma). In addition, normal human colon cells CCD-18Co
(human colon fibroblasts), were included. All cell lines were obtained
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
from the American Type Culture Collection (ATCC, Rockville,
MD, USA) and maintained at the University of Rhode Island. Caco2 cells were grown in Eagle’s minimal essential medium (EMEM)
supplemented with 10% v/v fetal bovine serum, 1% v/v nonessential
amino acids, 1% v/v L-glutamine and 1% v/v antibiotic solution (Sigma).
HCT-116 cells were grown in McCoy’s 5a medium supplemented with
10% v/v fetal bovine serum, 1% v/v nonessential amino acids, 2% v/v
HEPES ((4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid) and 1%
v/v antibiotic solution. CCD-18Co cells were grown in EMEM medium
supplemented with 10% v/v foetal bovine serum, 1% v/v nonessential
amino acids, 1% v/v L-glutamine and 1% v/v antibiotic solution and
were used from population doubling levels (PDL) = 26 to PDL = 35 for
all experiments. Cells were maintained at 37ºC in an incubator under
a 5% CO2/95% air atmosphere at constant humidity and maintained
in the linear phase of growth. The pH of the culture medium was
determined using pH indicator paper (pHydrionTM Brilliant, pH 5.5-9.0,
Micro Essential Laboratory, NY, USA) inside the incubator. All of the
test samples were solubilized in DMSO (<0.5 % in the culture medium)
by sonication and were filter sterilized (0.2 μm) prior to addition to the
culture media. Control cells were also run in parallel and subjected to
the same changes in medium with 0.5 % DMSO.
Cytotoxicity assay: The assay was carried out as described
previously [26] to measure the IC50 values for samples. Briefly, the
in vitro cytotoxicity of samples were assessed in tumor cells by a
tetrazolium-based colorimetric assay, which takes advantage of the
metabolic conversion of MTS [3-(4,5-dimethylthiazol-2-yl)-5-(3carboxymethoxyphenyl)-2-(4-sulfenyl)-2H-tetrazolium, inner salt]
to a reduced form that absorbs light at 490 nm. Cells were counted
using a haemocytometer and were plated at 2,000 to 5,000 cells per
well, depending on the cell line, in a 96-well format for 24 h prior to
drug addition. Test samples and a positive control, etoposide 4 mg/ cm3
(Sigma), were solubilized in DMSO by sonication. All samples were
diluted with media to the desired treatment concentration and the
final DMSO concentration per well did not exceed 0.5%. Control wells
were also included on all plates. Following a 24 h, 48 h or 72 h drugincubation period at 37°C with serially diluted test compounds, MTS, in
combination with the electron coupling agent, phenazine methosulfate,
was added to the wells and cells were incubated at 37˚C in a humidified
incubator for 3 h. Absorbance at 490 nm (OD490) was monitored with
a spectrophotometer (SpectraMax M2, Molecular Devices Corp.,
operated by SoftmaxPro v.4.6 software, Sunnyvale, CA, USA) to obtain
the number of surviving cells relative to control populations. The results
are expressed as the median cytotoxic concentrations (IC50 values) and
were calculated from six-point dose response curves using 4-fold serial
dilutions. Each point on the curve was tested in triplicate. Data are
expressed as mean ± SE for three replicates on each cell line.
DNA-interaction studies
All the experiments involving the interaction of the complexes
with DNA were carried out in TRIS buffer (5 mM Tris, 50 mM NaCl,
pH 7.20). Stock solutions of ct-DNA were prepared by dissolving
commercial nucleic acids in buffer and stored at 4°C for 24 h. The
stock DNA solution was diluted appropriately and the concentration
of the diluted solutions (per nucleotide phosphate) was determined
spectrophotometrically using the molar absorption coefficient of 6600
M-1 cm-1 at 260 nm [27]. The purity of the solutions was checked by
observing a ratio of ≥ 1.8 [28]. The DNA stock solutions were stored
at 4°C and used within 4 days after their preparation. Doubly purified
water used in all experiment was from a Milli-Q system.
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
Absorbance titration experiments: Spectroscopic titrations were
carried out at room temperature to investigate the binding between
the complexes and ct-DNA. A constant concentration of the complexes
(1.0 x 10-5 M) was treated with aliquots of a stock concentrated solution
of the DNA in a 1-cm quartz cell. A reference cell without the metal
complexes was titrated in a similar manner simultaneously.
Fluorescence titration experiments: In the ethidium bromide (EB)
fluorescence displacement experiment, a buffered solution that is 10
µM DNA pre-treated with a saturating amount EB (0.33 µM, [29])
was titrated with a concentrated solution of the complex. After each
addition, the solution was stirred at the appropriate temperature for 5
minutes before the fluorescence measurement was taken by exciting
at 520 nm and measuring the emission spectra from 530-700 nm.
Temperature was controlled using a single-cell Peltier accessory.
Viscosity measurements: Viscosity studies were done using a
Cannon-Manning semi micro-dilution viscometer (type 75, Cannon
Instruments Co., State College, PA, USA) in a thermostatted water bath
maintained at 30.0 ± 0.1°C. The viscosity for a DNA solution (100) was
measured in the presence and absence of the metal complexes (0–80
µM). Data are presented as (η/η0)1/3 versus 1/R, where R = [DNA]/
[complex], η is the viscosity of DNA in the presence of the complex and
η0 is the relative viscosity of DNA alone. Relative viscosity values were
calculated using the expression η0 = (t–t0)/t0. In this expression, t is the
flow time of the DNA solution and t0 is the flow time of the buffer. The
flow time of each sample was measured three times and an average flow
time was used.
Chemical nuclease activity: The DNA unwinding and cleavage
ability of the complexes was evaluated by agarose gel electrophoresis
of supercoiled pBR322 DNA. Samples of pBR322 DNA (0.1 µg/
µL) were incubated with the complexes (10 to 200 µM) in TRIS
(Tris(hydroxymethyl)aminomethane) buffer (50 mM Tris, 18 mM
NaCl, pH 7.2) at room temperature for 1h in the dark or subjected to 365
nm light. The reactions were quenched by addition of 3 µL of loading
buffer (0.25% bromophenol blue and 15% Ficoll in water). Samples of
the reaction mixtures were then loaded onto a 1% agarose gel in TBE
buffer (89 mM Tris, 89 mM boric acid, 2 mM EDTA, pH 8.2). The gels
were subjected to electrophoresis for 1 h at 70 V, followed by staining
with 0.5 µg/ cm3 ethidium bromide for 30 minutes. The bands on the gel
were visualized under UV light and photographed using a GEL Logic
440 Imaging System with a Kodak Molecular Imaging Software.
Interaction with human serum albumin
Fluorescence titration: For the fluorescence titration experiments,
a 3 µM solution of HSA was titrated with various amounts of a
concentrated solution of the complex. The complex concentration
ranged from 0–30 µM. After each addition, the mixture was stirred
for 15 seconds and allowed to sit at the appropriate temperature for 5
minutes before measurement. The fluorescence spectra of the solutions
were obtained by exciting at 295 nm and measuring the emission
spectra from 300-450 nm. The measurements were done at ambient
temperature.
Infrared measurements: The HSA and the complex solutions, mixed
in a 1:1 molar ratio, were incubated for 48 h prior to measurement. The
infrared spectra of HSA, HSA plus the complex (1:1 molar ratio) and
the complex alone were recorded.
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Results and discussion
Synthesis and characterization
The thiosemicarbazone used in this study has been previously
reported [23]. Complex 1 was synthesized according to a novel
microwave-enhanced reaction from [Ru(benzene)Cl2]2 by reaction
with two equivalents of the thiosemicarbazone in methanol followed by
addition of an aqueous solution of ammonium hexafluorophosphate.
This complex was obtained as a rust-red solid. Complex 2 was
obtained as an orange-red solid from the room-temperature reaction
of the thiosemicarbazone with [Ru(cymene)Cl2]2 in methanol.
Based on elemental analysis and spectroscopic data we propose that
these complexes are best formulated as [(η6-arene)Ru(dmabTSC)
Cl]PF6 (Figure 2). Complex 3 with the proposed formula [(9aneS3)
Ru(dmabTSC)Cl]PF6 was obtained by refluxing [(9aneS3)RuCl2(dmso)]
with the thiosemicarbazone in ethanol. (Incidentally we could
synthesize [(9aneS3)Ru(dmabTSC)Cl]Cl, 3b, similarly without using
the hexafluorophosphate ion. To avoid the variation in counter-ion,
this particular compound was not studied and is included only for it’s
and mass spectrometric spectrum). Like 1 and 2, the yellow solid 3
was quite soluble in acetone, DMSO and CH2Cl2 but slightly less so in
alcohols. The stability of the complexes in methanol was investigated
by monitoring their UV-Vis spectra over time (Figure S1 ESI). The
complexes behave differently with only 3 showing distinct changes,
with shifting of spectral features, after 24 hours. Complexes 1 and 2
showed only hypochromic changes over this time period.
The 1H NMR spectra were acquired for 1, 2 and 3 in DMSO-d6 as
all complexes showed good solubility in this solvent. The complexes
show many similarities in the 1H NMR spectra attributed to the
conserved dmabTSC ligand, [23] with the major differences arising
from the variation of the coordinated arene moiety. Coordination of the
dmabTSC ligand to the metal center was confirmed due to the generally
observed upfield shift (∆ δ = 1.51 ppm for 1 and 2) of the resonance of
the azomethine proton, compared to the free uncoordinated ligand [23].
Complex 3 show a downfield shift of 0.85 ppm, possibly indicating that
the face-capping ligand have an impact on the spectroscopic properties
of the complexes. Additionally, the 13C NMR spectra for all compounds
show a general upfield shift for the two primary low-field signals
attributed to the thioketo (C=S) and azomethine (C=N) indicating
coordination via an N,S-binding mode [23]. While these features are
well conserved between the spectra of the presented compounds major
differences are visible due to the variation in the arene system utilized.
For instance, the 1H NMR spectrum of 1 shows resonances from the
benzene arene moiety at δ = 6.07–6.26 ppm, whereas the incorporation
of the p-cymene arene functionality in 2 leads to the loss of the twofold
symmetry of the arene ligand and the appearance of four sets of
doublets in the range of δ = 5.82–6.15 [30-32]. Additionally, 2 shows
resonances for two inequivalent methyl groups δ = 1.15 and 1.21 ppm,
a result previously observed by Halbach et al. [33]. The peaks for the
[9]aneS3 macrocyclic ring of 3 are second order, and thus it is difficult
to determine whether there are multiple sets of peaks for the thioether
group. Integration values indicate the chemical shifts for the [9]aneS3
ligand occurred between δ = 2.55 and 2.89 ppm, a similar shift range
was previously reported by Goodfellow et al. [25]. Additionally, this
complex exhibits a resonance for the hydrazinic proton downfield at
approximately δ = 12.0 ppm. Using the analysis by Afrasiabi [34], it can
be determined that the dmabTSC ligand under our conditions exists
in the Z form. Coupled with the lack of a resonance shift signal at δ =
4.0 attributable to –SH proton resonance, we can say the ligand in the
complexes exists in the thione form.
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
The proposal that the thiosemicarbazone ligand coordinates as
the thione tautomer in the solid state of all three complexes is also
suggested by the infrared spectroscopic data for the complexes. The
amine region (3400-3100 cm-1) shows three broad and weak peaks;
these of course correspond to the amine and hydrazinic hydrogens [23].
One would have expected the hydrazinic hydrogen (near 3150 cm-1)
would have been absent had the thiol tautomer (as the ionic form) been
the coordinated species. The coordination through the azomethine
nitrogen and the thione sulfur is also obvious in the infrared spectra as
the ν(C=N) and C-S bands of the thiosemicarbazone shifts (to higher
energies relative to the free ligand) on coordination.
High resolution electrospray ionization mass spectra were acquired
for 1, 2, and 3b (Figure S2, ESI). We have assigned M as the metal
complex in absence of any solvates in all the mass spectral analyses.
The results obtained correspond to the expected structural formulas.
The m/z value of 401.036654 which is detected for 1 in the mass
spectrometer indicates that during ionization, in combination with the
loss of the PF6- and Cl- counter-ions, deprotonation of a proton ensues
after the tautomerization of the coordinated thiosemicarbazone’s
hydrazinic N(2)-H proton (Fig. S3, ESI). This leads to the formation of
the anionic thiolate form of the thiosemicarbazone ligand coordinated
to the ruthenium (II) metal center of 1, where the calculated exact mass
of the singly charged cation = 401.037 g mol-1. Just like the 1 cation, 2
and 3b formed the singly charged cation which was detected as m/z =
457.099190 and 503.000116 respectively. The calculated exact mass of
the singly charged cations were 457.100 and 503.000 g mol-1 respectively.
The electrochemical (cyclic voltammetry) behavior of the complexes
has been studied in DMSO using a variety of scan rates ranging from
100 to 500 mV/s. Tetrabutylammonium hexafluorophosphate was used
as the supporting electrolyte. Complexes 1 and 2 with their somewhat
similar structures showed similar features in the investigated sweep
range (0–2.0 V). There is one irreversible oxidation wave (Epa = 1.09
V and 1.00 V for 1 and 2 respectively) (Fig. S4, ESI) corresponding to
the Ru(II)/Ru(III) couple. This peak becomes less pronounced as scan
rate is increased and moves to 1.11V concurrently. This Ru-centered
oxidation is irreversible even up to a scan rate of 500 mV s-1. This
pattern of behavior is similar to what we have observed for similar
complexes bearing a p-cymene or benzene arene cap [6,7,30,35]. For
such complexes Epa values range from 1.02 V to 1.11 V. Complex 3
had an irreversible oxidation at 0.91 V with an additional, though less
defined peak, at 1.34 V.
X-ray analysis
In an attempt to grow crystals of 2, the mother liquor from the
isolation step was left to slowly evaporate. The small crystals that resulted
were subjected to X-ray analysis resulting in a unique dimeric structure.
We propose that as the solvent evaporated from the mother liquor, the
concentration of the residual complex increased. Hydrolysis of the
complex resulted as a consequence of the large amount of water present
followed by tautomerization of the coordinated thiosemicarbazone
ligand to generate the thiol form. This tautomerization could be facilitated
by basic species in the medium (likely methoxide from methanol).
Dimerization then occurred to satisfy the valency requirements of the
metal center (Fig. S5, ESI). (The formation of a similar dimeric species
at high concentration has been previously reported [36].) This process
could be aided by the fact that the N,N’-diethylamino-group attached
to the thiosemicarbazide fragment is strongly electron-donating group.
So, electron density in the whole organic ligand is redistributed to favor
the thiol structure upon complexation. In such thiol structure there is
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
well known propensity to form dimers because there is an excess of
electron density at sulfur center. In addition the C-S distance is longer
which allows less steric repulsion.
The crystal structure of the dimeric Ru(II) complex was determined
at room temperature due to the crystal’s instability upon cooling in the
cryo-stream cold N2 flow. Crystal and refinement data are presented
in Table 1, while selected bond lengths and valence angles are shown
in the electronic supplementary information. Careful inspection
of crystalline specimen of the Ru(II) dimeric complex under the
microscope using polarized light did not indicate an obvious twinning.
Nevertheless, after data collection, a series of 160 frames obtained from
4 different orientation runs allowed harvesting of 702 strong reflections
with I>20σ(I), which were subjected to testing using the CELL_NOW
program [21]. The output produced the figure of merit (FOM) equal
to 0.932, with all 702 reflections nicely indexed in one monoclinic cell
with β=116.616(2)o. The XPREP suggested the centro-symmetric C2/m
space group #12 based on the analysis of 5946 unique reflections and
|ExE-1| = 0.962 at I/σ =5.67. The choice of the group was confirmed
using the PLATON program [37]. The crystal structure has been
deposited into the CCDC (#992015).
The structure solution was obtained, and it was apparent that there
is a significant overall disorder in the structure. Thus, there were several
parts of the complex in which functional groups had several orientations:
1) coordinated to Ru(II) atom η6-para-cymene group has isopropyland methyl- groups being severely disordered by two positions; 2) one
of the counter-anions–PF6-–was also disordered. A successful modeling
Table 1. Crystal data and structure refinement for [(C10H14)Ru(dmabTSC)]2(PF6)2.
Chemical formula
Formula weight
C40H54F12N8P2Ru2S2
1203.11
Temperature
296(2) K
Wavelength
0.71073 Å
Crystal size
0.196 x 0.222 x 0.432 mm
Crystal habit
clear dark red-brown plate
Crystal system
Monoclinic
Space group
C 1 2/m 1
Unit cell dimensions
a = 14.140(2) Å
b = 32.808(5) Å
c = 12.7477(18) Å
Volume
5287.0(13) Å3
Z
4
Density (calculated)
1.512 g/cm3
Absorption coefficient
0.789 mm-1
F(000)
2432
Theta range for data collection
1.2 to 27.2°
Index ranges
-18<=h<=18, -41<=k<=42, -16<=l<=16
Reflections collected
30125
Independent reflections
5946 [R(int) = 0.044]
α = 90°
β = 116.616(2)°
γ = 90°
Coverage of independent reflections 99.3%
Absorption correction
multi-scan
Max. and min. transmission
0.9600 and 0.8024
Function minimized
Σ w(Fo2 - Fc2)2
Data / restraints / parameters
5946 / 37 / 331
Goodness-of-fit on F2
1.03
Δ/σmax
0.42
Final R indices
3864 data; I>2σ(I)
all data
Weighting scheme
w=1/[σ2(Fo2)+(0.1640P)2+24.7678P]
where P=(Fo2+2Fc2)/3
Largest diff. peak and hole
3.49 and -1.47 eÅ-3
R.M.S. deviation from mean
0.16 eÅ-3
R1 = 0.083, wR2 = 0.236
R1 = 0.118, wR2 = 0.279
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�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
of the disorder of the organic groups was possible and H-atoms were
geometrically attached to their host carbon atoms (Fig. S6, ESI). At the
same time the disorder in one of the counter-anions (PF6-) was much
more difficult to handle. This anion is in a special position in the crystal
and the P2 atom is located on the C2 axis. The electron density from the
fluorine atoms was clearly seen on the map, but it was rather difficult to
model the proper geometry of the anion with two F atoms even being
refined isotropically. The overall shape of thermal ellipsoids of carbon
and nitrogen atoms of the aromatic moiety of the thiosemicarbazone as
well as that of the counter-anions indicate that there is a loose crystal
packing with the possibility to anions and coordinated to Ru organic
groups to adopt slightly different orientations. Indeed, the structure
occupies 3203.12 Å3 (60.6% only) with significant void and solvent
accessible volume. The unresolved disorder generated several A and
B-type errors in the checkCIF report by PLATON. (The PLATON
checkCIF reports are shown in the ESI.) It is important to note that
the disorder in both fragments is not affecting the core structure of the
molecule–Ru(II) coordination environment–which was the main scope
of our interest. Final residual electron densities or lack thereof was
observed at 0.83 Å from Ru1 (+1.14 e), and the hole at 0.64 Å from F1
atom (-0.82 e). The first one at the heavy metal site represents a typical
“ripple” of electron density and has no chemical meaning.
The molecular structure and numbering scheme in the [Ru2S2]
dimer is shown in Figure 3, together with a detailed picture of the
Ru(II) environment in the complex. The two halves of the dimer are
related through a C2 axis passing in the middle of the Ru2S2 rhomb
(Figure 3). Geometrical parameters of the p-cymene group and
thiosemicarbazone ligand are normal for these types of compounds. A
recent search of the Cambridge Structural Database pertaining to the
S,N ligand set and p-cymene-Ru fragment resulted in thirty-three hits.
Among these reported crystal structures there are five di- and polynuclear Ru-sulfides, four structures containing dinuclear Ru-complexes
with ligands acting as S-donor atoms bridges, and only four true dimers
in which two structures contain metal-ligated thiosemicarbazone
ligands [38]. The refcodes of the above-mentioned structures are given
in the ESI. Therefore, this work presents a crystal structure that is the
third known example of the formation of a centro-symmetric dimer
with N,S donor atoms. A comparison of our complex with the mostsimilar complexes found in the CDCC, showed that the key geometric
parameters are indeed comparable. The average Ru-S-Ru bond angle
for the three similar complexes of 97.20° is slightly less than the 99.36°
observed for our complex. Similarly, for the S-Ru-S angle, this complex
is 1.27° less than the average for the comparison complexes. It is also
observed that the Ru-S bonds in the [Ru2S2] core are not the same length
and that the difference in length is similar to that of the comparison
complexes. A comprehensive table of the geometric parameters is given
in the ESI.
Cytotoxicity assay
The cytotoxicity profiles of the complexes against two human
cancer cell lines, HCT-116 (colon carcinoma) and Caco-2 (epithelial
colorectal adenocarcinoma) and a non-cancerous cell line, CCD-18Co
(colon fibroblasts) was investigated using a tetrazolium-based (MTS)
colorimetric assay. Etoposide, a potent anti-neoplastic drug, was used as
a standard comparison treatment. The IC50 values, the median cytotoxic
concentrations, were determined after 24, 48, and 72 h of drug exposure.
None of the complexes showed any reasonable cytotoxicity. For instance,
complex 2 was the most active (against Caco-2) with IC50 of 318 ± 9 µM.
We did not determine a value for complex 3. By comparison, etoposide
had an IC50 value of 18.3 ± 1.4 µM for under similar experimental
conditions (72 h treatment). Still, a number of generalizations can be
made. Longer exposure times is indicated for more cytotoxic activity.
In addition, the HCT-116 cell line is less sensitive to the complexes than
the Caco-2 cell line. It should be noted that that there is a cytotoxic
selectivity as all the complexes are less cytotoxic to the normal CCD18Co cells relative to the cancer cells. Incidentally, while 3 is non-active
against the colon cancer cells it shows moderate activity against the
MCF-7 breast cancer cell line with IC50 of 95.6 ± 4.2 µM. The lack of
activity of 3 could be related to the lack of hydrogen bonding capability
on the thiosemicarbazone ligand. This factor, along with facile aquation
of the chloride ligand, has been identified as being important for good
anticancer activity.[19,20] While the complexes are not super-active,
they can still be investigated for further development. This is because it
is known that some ruthenium complexes have low in vitro toxicity but
show good in vivo characteristics. For example, complexes of the type
[(arene)Ru(PTA)Cl]+ exhibited low activity against cancer cells but had
very good anti-metastatic activity in vivo [39].
Reaction of the complexes with DNA
Figure 3. A–The asymmetric unit of the Ru-core dimer in the structure (two PF6- anions
are omitted for clarity) showing the numbering scheme of the most important atoms; an
ORTEP drawing at 50% thermal ellipsoids probability level. B and C - two views of the
ordered part of the [Ru2S2] dimer with part of the ligand and p-cymene groups in ball-&stick representation; green dot indicates how two ASU parts of the [Ru2S2] dimer are related
via a C2 axis. H-atoms in B and C are omitted for clarity as well as two PF6- anions.
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Electronic absorption spectroscopy: The structure of DNA presents
three structural features to which a small molecule can bind. The
major and minor grooves, with the abundance of hydrogen donors
and acceptors present, can accommodate a ligand. A ligand can also
intercalate between the base pairs if it possesses appropriate functional
groups. Finally, a charged ligand can interact with phosphate groups
via ionic interactions. As mentioned before, ruthenium piano-stool
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�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
complexes with an extended aromatic moiety, were found to enhance
cytotoxicity by facilitating DNA binding. Using UV-Vis spectroscopy
is typically part of a suite of spectroscopic methods used to examine
the strength of the binding interactions of metal complexes with DNA
[40-42]. Given the structure of the ligands in the complexes under
investigation, we examined whether the compounds are capable of
binding to DNA through intercalation. Complexes which adopt this
method of binding generally have electronic absorption bands that
show bathochromic changes relative to the free complex and also display
hypochromism. Absorption titration experiments in TRIS buffer were
performed by using solutions with a fixed complex concentration (10-4
M) to which aliquots of a concentrated solution of ct-DNA were added.
The changes in absorbance upon each addition were monitored at the
maximum wavelengths 386, 373 and 367 nm for 1, 2, and 3 respectively
(Figure 4). It can be seen from the figure that as the DNA concentration
is increased, there is notable hypochromism of the main absorption
bands, 27% for 1, 20% for 2 and 18% for 3. There was no wavelength
shift for compound 3 but the absorption spectra for 1 and 2 were blueshifted by 9 and 7 nm respectively. Consequently, we can suggest that
the complexes are minor intercalators into the DNA structure. To
quantify the binding strength, the intrinsic binding constant Kb can be
calculated from equation 1[40]:
[DNA] [DNA]
1
=
+
ε a − ε f ε b − ε f K b (ε b − ε f )
(1)
where εa, εf and εb correspond to the molar absorptivities of the metal
complex after each addition of ct-DNA, for the free metal complexes
and for the metal complexes in the completely bound form respectively.
the binding constants Kb are calculated from the plots of [DNA]/(εa - εf )
versus [DNA] (insets of Figure 4), The values are given in Table 2. From
the table, it is seen that the binding constant are on the order of 105 M-1
which characterizes them as moderate to strong binders. The nature
of the results suggests that the complexes do not interact with DNA
via intercalation or at least this type of interaction is weak. Also, given
the magnitude of these values, it is possible that the cationic nature of
the complexes could provide for electrostatic interactions as described
above.
Ethidium bromide competition experiment: We have investigated
the reaction of the complexes with calf-thymus DNA via a fluorescence
competition experiment. Both DNA and ethidium bromide (EB) are
non-emissive in aqueous solution; however when they interact, the
EB intercalates into the DNA molecule generating an adduct that is
fluorescent. This fluorescence may be quenched if an added compound
can displace the EB from the binding sites on the DNA (returning to the
non-emissive states). We can see from Figure 5 that all the complexes
reduced the fluorescence of the EB-DNA solution (indicated by the
arrow). By treating the data according to the Stern-Volmer equation
(equation 2), one calculate the quenching constant which estimates the
strength of the binding.
F0
= 1 + K SV [Ru] = 1 + K q ô0 [Ru]
F
(2)
In this equation F0 and F are the fluorescence intensities of the
reaction solution in the absence and presence of the metal compound.
KSV is the Stern-Volmer quenching constant. The expected linearity of
the plot (F0/F vs. [Ru]) was observed only for 2 and 3 with quenching
Figure 4. Electronic absorption spectral changes of complexes on titration with ct-DNA. [Ru] = 10 µM, [DNA] = 0, 1, 3, 5, 7, 9, 11, 13, 15, 17 and 19 µM. Arrow indicates the change upon
increasing DNA concentration. Inset: Plot of [DNA]/(εa –εf) vs. [DNA].
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
Table 2. Binding constants (M-1) for the interaction of 1, 2 and 3 with ct-DNA.
Experimental method
1
2
3
Absorption titrationa
(1.87 0.10) x 105
(1.42 ± 0.08) x 105
(4.28 ± 0.29) x 105
2.22 x 104
6.52 x 103
4.51 x 103
Ethidium bromide competitionb
a
at ambient temperature
b
apparent binding constant
Figure 5. Fluorescence spectra of the EB-DNA complex in the absence and presence of increasing amounts the complexes, λex = 520 nm, [EB] = 0.33 µM, [DNA] = 10 µM, [M] (µM): 0–50
in 5 µM increments. Temperature = 303 K. Arrow indicates the change upon increasing complex concentration.
constants of (1.49 ± 0.02) x 104 M-1 and (8.30 ± 0.15) x 103 M-1,
respectively. For complex 1 the Stern-Volmer plot was nonlinear
displaying a concave shape and a quenching constant could not be
calculated. In all cases, to assess the strength of the binding, equation 3
was employed to calculate the apparent binding constant.
K app =
K EB [EB]
[Ru]50%
(3)
In this equation KEB is the binding constant for ethidium bromide,
taken as 1.2 x 106 M-1 ,[43] and [Ru]50% is the concentration of the
complex that causes a 50% reduction of the initial fluorescence. These
values are shown in Table 2 and are on the order of 103 M-1 which
suggest that the complexes are weak binders.
We propose that in the reactions here, predominantly static
mechanism is operating (as opposed to dynamic quenching). In static
quenching, a quencher-fluorophore complex is formed. This is usually
inferred from the bimolecular quenching constant, (Kq in equation 1),
calculated by using τ0 = 22 ns [44] for the EB-DNA complex. Keq for the
reactions under investigation are on the order of 1011 M-1 s-1 which is
an order of magnitude larger than the limiting value of 1010 M-1 s-1.[45]
This value is considered the largest possible value in aqueous solution.
A typical intercalator like ethidium bromide has a binding constant
of 3.0 x 106 M-1 [46]. The calculated apparent binding constants are an
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
order or two of magnitude less than those obtained from the absorption
titrations the results confirm that the complexes are weak intercalators.
This is not unexpected as none of the complexes have the structural
characteristics, whether on the face-cap or the thiosemicarbazone
ligand, that are common for intercalators.
Viscosity: To further clarify the binding mode of the complexes
with DNA, we studied the interaction of the complexes with ct-DNA
by viscometry. This involves measuring the viscosity of DNA solutions
containing varying amount of added complex. Viscometry is considered
a definitive test of the classical intercalation model of binding in aqueous
solution. For a metal complex (or any ligand) to intercalate, the DNA
molecule must unwind to a certain degree in order to accommodate the
binder. One consequence of this structural change is a lengthening of
the strands. This should lead to more entanglement of the said strands
and an increase in the viscosity of a DNA solution containing a classical
intercalator [47]. In the current study, the viscosity of a 100 M DNA
solution containing 0–80 M of metal complexes were measured after
thermal equilibrium. We followed the protocol established by Cohen
and Eisenberg [48] where viscosity data were plotted as (η/η0)1/3 versus
the binding ratio ([Ru]/[DNA]) as shown in Figure 6. It was observed
that increasing the complex concentration led to an increase in the
viscosity of the DNA solution at lower complex:DNA ratios. In the case
of 1 however, at higher ratios there is a decrease in the viscosity of the
solutions. Therefore this supports the results from the EB displacement
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�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
the electrophoretic separation of the DNA after incubation with the
complexes in the dark and after irradiation with 365 nm light. With or
without irradiation, complexes 1 and 2 show no significant cleavage of
the DNA even at concentrations as high as 200 µM. Complex 3 show
some cleavage activity at all the concentration levels. This activity seems
to disappear when the reaction was irradiated.
Interaction with human serum albumin
Figure 6. Effect of increasing concentrations of complexes on the relative viscosity of ctDNA solutions at 303 K ± 1 K.
Figure 7. Agarose gel electrophoresis diagram for the cleavage of pBR322 DNA by the
complexes at ambient temperature with (A) and without (B) irradiation with 365 nm light
under aerobic conditions. Irradiation time was 1 h and incubation time was 1 h. Lane DNA:
DNA alone; Lane 1: DNA + solvent; Lane 2–8: DNA + 5, 10, 20, 30, 50, 100, and 200 µM
complexes; Lane 9: DNA ladder.
experiments, and we may conclude that the complexes are poor
intercalators. In general, the complexes with the arene face-cap had a
slightly quicker rate of change. This might suggest that the top face of
the complexes might be the initial entry point into the nucleic acid.
Cleavage of pBR322 DNA: Gel electrophoresis, particularly agarose
gel electrophoresis, is probably the most important biochemical
technique used to study DNA topology. This technique was used
to probe the chemical nuclease activity of the complexes. This was
accomplished by measuring their ability to convert supercoiled pBR322
DNA from the circular form to the nicked circular form in the dark as
well as after illumination by UV irradiation under aerobic conditions.
When circular plasmid DNA in the presence of metal complexes is
interrogated by electrophoresis, relatively fast migration through the
gel is normally observed for the intact, more compact supercoil (the socalled Form I). If nicking (a single-strand break) occurs, the supercoil
will relax to generate a slower-moving open circular form (Form II).
The linear Form III move at an intermediate rate. Figure 7 shows
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Fluorescence titration: Human serum albumin (HSA) is the most
abundant protein in blood plasma. It is a multifunctional protein
serving as a transport agent amongst other roles. This transport
function is important for drug action as HSA can reversibly bind drugs,
which necessarily affects pharmacokinetic behavior. HSA is a singlechain protein generating a secondary structure which contain three
structurally similar domains. It is generally accepted that the domains
present two major binding sites referred to as site I and II. Site I is much
bigger than site II; consequently a wide range of drugs can bind and
be transported. Despite the large amount of studies that have been
done on HSA, exact details of the nature of the potential interactions
is still debated and might logically be expected to depend on the drug
being studied. The site I binding pocket is hydrophobic in nature and
contains the single tryptophan amino acid residue [49]. (There is also
an emissive tyrosine residue (Tyr 411 in site II). As a result, binding
interactions between ligands and the protein can be probed by
fluorescence spectroscopy. The tryptophan exhibits the majority of the
inherent protein fluorescence. Groups binding at or near this residue
will quench the fluorescence from the protein. On excitation at 295 nm
HSA has strong fluorescence emission near 350 nm. It can be observed
from Figure 8 that titration of HSA with the complexes led to dramatic
decreases in the HSA fluorescence suggesting that binding occurs at
or near the tryptophan residue resulting in changes in the secondary
structure of the protein. It can also be observed that there is a blue shift
of about 10 nm to near 333 nm. We interpret this to mean that it is
likely that binding results in reduction of the tryptophan exposure to a
polar environment; emission in this region suggests that the tryptophan
residue is buried in a nonpolar hydrophobic pocket on the HSA. One
could therefore initially speculate that the complexes bind at site I on
the protein.
The insets of Figure 8 show the Stern-Volmer plots, which are
expected to be a straight line. For 1 and 2 it is obvious that there
are strong positive deviations in the plots. The concave-up nature of
these plots usually indicates that both dynamic and static quenching
is involved. For proteins the quenching constants is approximately the
same [50,51]. Alternatively, there may be more than one independent
binding site on the HSA that are not all equivalently accessible to the
complexes or the complexes bind to them to different extents. While it
is understood that there are the two main binding sites on the protein,
other sites are indeed possible. The situation is different for 3 where the
expected straight line is observed which suggest that the mechanism of
interaction with the protein is different when the face-cap is an arene
versus when it’s the thiacrown.
In order to examine quantitatively the complex–HSA binding,
equation (4) [52] has been used to calculate the binding constant.
log
(F0 − F)
F
= log K + n log[Ru]
(4)
In this equation K and n are the binding constant and the number
of binding sites on the albumin, respectively. The double-logarithm
curves log (F0-F)/F vs. log [Ru] gave log K as the intercept and n as the
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�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
Figure 8. (A, B, C): Emission spectra of HSA in the absence and presence of increasing amounts of the complexes. λex = 295 nm, [HSA] = 3.0 µM and [M]: 2.5, 7.5, 12.5, 17.5, 22.5, 27.5
µM. Temperature = ambient. Inset: Stern-Volmer plots. (D) Double-log plot of log (F0–F)/F vs. log [Ru].
slope. The results show that the binding between the complexes and
HSA was significant with binding constants of 2.74 x 105 M-1 and 1.96 x
106 M-1 for 1 and 3, respectively. The binding site n was approximately
equal to 1 (1.1 and 1.3) suggesting (though not definitively) that there
was one binding site for the complexes on HSA.
Infrared spectrophotometry: Infrared spectroscopy is a wellestablished experimental technique for the characterization of the
secondary structure of proteins [53]. A qualitative assessment of the
interaction of the three complexes with HSA was therefore undertaken
using infrared spectrophotometry. There are nine characteristic
infrared absorption bands for proteins. Of these, two are more generally
useful in studying ligand-protein interactions. The amide I band is
due to stretching of the C=O functional group of the peptide moiety
and occur between 1600 and 1700 cm-1. Since this band is closely
associated with the secondary structure (percent α and β content) of
the protein [54], changes in said structure on interaction with a metal
compound can provide information on the binding. The amide II band
(which shows around 1550 cm-1), by contrast, shows much less protein
conformational sensitivity compared to the amide I band. Unordered
structure can be observed in the 1640–1648 cm-1 region in water [55].
Figure 9 shows the infrared spectra before and after incubation 48 h
of HSA with the complexes. The infrared spectra of HSA, HSA plus
the complex (1:1 molar ratio) and the complex alone were recorded.
Then difference spectra were calculated using the instrument’s software
package. The free HSA shows the amide I absorption at 1653 cm-1.
When complexes 1 and 2 interact with the protein, this band shifts by
+3 and +2 cm-1 respectively. For complex 3, this amide I absorption is
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Figure 9. FTIR spectra of free HSA and the difference spectra (metal complex-HSA–metal
complex).
almost absent. Another noteworthy change is observed at 1647 cm-1.
This band, which can be attributed to unordered structure, is absent in
the free HSA but is quite prominent in the complex-protein adduct for
all three complexes. So in the case of 3 there appears to be significant
disruption of the secondary structure of the HSA. The same is true for
1 and 2 though to a lesser degree as there are still strong indicators
of significant α-helix content. As is expected, the amide II absorption
shows changes that are difficult to interpret meaningfully.
Computational studies
Though DNA is implicated as the main target for anticancer
ruthenium compounds, other information suggests that proteins such
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�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
as topoisomerase II may also be reasonable targets. We have previously
shown that complexes like those in this study can act as topo II
inhibitors [6]. In addition, it is generally accepted that organometallic
ruthenium compounds bearing a Ru-Cl bond is biologically
activated by hydrolysis of this bond. Therefore, we undertook a basic
computational investigation of the complexes in this study along with
their aquated counterparts pertaining to their interaction with DNA
and topoisomerase II.
Optimized structures: Density functional theory (DFT) calculations
are a well-established tool to describe the geometry in transitionmetal complexes. Consequently, the geometry of the complexes was
optimized at this level of theory with ωB97X-D/6-31G* using the
Spartan 14 software [56]. This combination of functional and basis set
equated to LANL2DZ on Ru and 6-31G* on all other atoms. Vibrational
frequencies calculation were carried out to verify the minimized
configuration of each species and to derive thermodynamic parameters.
The calculated structures were used along with the Autodock 4.2.6 (in
AutodockTools) software package [57] for the docking calculations on
the crystal structure of DNA (PDB code: 423D) and topoisomerase II
(PDB code: 2RGR). Grid boxes of 110 × 100 × 80 points and 100 × 100
× 126 points with a spacing of 0.375 Å between the grid points were
used for the DNA and protein respectively. The box was centered on the
macromolecule. One hundred docked structures (i.e., 100 runs) were
generated by using genetic algorithm searches. The protocol that was
applied had an initial population of 150 randomly placed individuals,
a maximum number of 2,500,000 energy evaluations, a maximum
number of 27000 generations, a mutation rate of 0.02, and a crossover
rate of 0.8. Docking input files for the complex and the macromolecule
were generated with the ADT software. The results were visualized
using the Discovery Studio 4 visualizer from Accelrys.
Figure 10 show the calculated structures for the six complexes using
DFT/ωB97X-D computations. Some selected geometrical parameters
are given in Table 3. In general, the complexes show the classical pianostool structure which is essentially a distorted octahedral geometry.
For complexes 1 and 2 the TSC ligand essentially coordinates in the
same fashion. The N(t)-Ru1-S(t) bite angles averages 81.93° for the
chloro complexes and 81.41 for the aqua complexes. The Ru1-S(t)
bond averages 2.363 Å and 2.380 Å in the chloro and aqua complexes
respectively. The Ru1-N(t) bond doesn’t really vary between the two
types of complexes. However this bond is 3 and 3-aq were noticeable
longer than in the other four complexes. This suggest that even in
the context of a general distortion of the octahedron, there could be
structural effects of the face-cap. Along the same lines it could be noted
that in 2 the calculated structures show that the p-cymene ring is not
“level” but is essentially sloping with the ring tilting away from the
thiosemicarbazone (TSC).
Interaction with the macromolecules: A close examination of
Table 4 provide some feel for if and how the nature of the face-cap on
the complexes affect binding to the macromolecule (MM). Generally
speaking the aqua complexes bind stronger to both DNA and topo II
than the chloro compounds even though it is only for complex 1 that
we observe a very large difference. It can also be noted that binding to
the protein as indicated by the dissociation constant kI, is significantly
stronger that binding to DNA. A look at the binding interactions of the
complexes with the MMs, (Figure 11), allow us to gain some insight
Figure 10. Calculated structures of the complexes synthesized in this study (left) and their aquated analogs (right).
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
Table 3. Selected calculated geometrical parameters for the complexes and their hydrolysis products.
Complexes
1
1-aq
2
2-aq
3
3-aq
Bond lengths
Ru1-Cl1
2.400
2.359
Ru1-O1
2.221
2.440
2.240
2.232
Ru1-S1
2.351
2.317
Ru1-S2
2.334
2.350
Ru1-S3
2.412
2.432
2.396
Ru1-S(t)
2.387
2.341
2.360
2.395
2.393
2.154
2.137
2.188
2.207
89.09
89.03
Ru1-N(t)
2.156
2.141
Ru-centroid
1.745
1.750
Bond Angles
S1-Ru1-S2
S1-Ru1-S3
S2-Ru1-S3
85.51
85.39
O1-Ru1-S(t)
84.09
O1-Ru1-N(t)
86.71
90.79
81.30
82.05
Cl1-Ru1-N(t)
84.54
91.95
93.07
Cl1-Ru1-S(t)
86.11
81.65
90.18
Lig-Ru1-S(t)
127.09
128.30
133.09
131.19
Lig-Ru1-Cl1
127.55
Lig-Ru1-O1
85.67
80.72
93.63
S(t)-Ru1-N(t)
Lig-Ru1-N(t)
84.91
84.37
82.08
82.21
129.52
(t) = thiosemicarbazone
Table 4. Calculated binding parameters for the complexes with DNA and topoisomerase II.
Macromolecular target →
DNA
Topoisomerase II
Compound ↓
Binding energy*
kI
1
- 6.06
36.18
- 7.18
5.43
1-aq
- 6.92
8.47
- 8.57
0.523
2
- 6.14
31.53
- 7.79
1.94
2-aq
- 7.30
4.47
- 8.83
0.783
3
- 6.49
17.59
- 8.01
1.36
3-aq
- 7.04
6.91
- 8.04
1.29
Binding energy*
kI
* Binding energy is in kJ/mol and dissociation constant (kI) is in micromolar units; aq implies the aquated complexes
into the trends in dissociation constants. (General pictograms of the
complexes with the MMs can be seen in the ESI). In both the chloro and
aqua complexes the –NH2 group of the TSC ligand plays an important
role in the binding to the MMs. In particular, it is involved in H-bonds
with a variety of groups on the nucleic acid or protein.
For instance, the phosphate groups on the DNA backbone are seen
to form bonds with this group. For the interaction of 1 with 423D it
is Cyt21 that has this interaction. In the other complexes various
nucleotides are involved: for 2 Gua7 is involved. The sugar unit of the
nucleic acid residues also feature in the hydrogen bonding interaction.
The –NH group of the TSC also participated in hydrogen bonding
interactions with similar groups. For example 2-aq interacts via H-bond
with the sugar units of Cyt9 in 423D. The –NH group also show chargecharge interactions with the phosphates of the backbone in both the
DNA and topo II. The benzene ring of the thiosemicarbazone ligand as
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
well as the –N(CH3)2 moiety also play in a role in binding the MM. For
complex 2-aq the ring participates in pi-pi interaction with Ade17 when
interacting with 423D; the same complex exhibit this type of interaction
with Tyr840 of 2RGR. In 3-aq this interaction is seen with Gua9. The
arene rings of the complexes also show this type of interaction. As
mentioned above the methyl groups of the –N(CH3)2 moiety are noninnocent in binding. In the binding to topo II this group in 1 show
a carbon-hydrogen-bond interaction with the hydroxyls of Asn974
and Thy10 as well with Glu831. The same group in 1-aq interacts with
Ade17 and the phosphate unit of Cyt18.
A possible reason for the aqua complexes binding stronger to
the MMs is the additional hydrogen-bonding interactions that these
complexes present. In almost all the docking runs this group forms
conventional hydrogen bonds with various acceptors on the MMs.
1-aq interacts with the sugar unit of Cyt11 as well as Thy10 of the topo
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
II-DNA cleavage complex, forming a ternary complex and act as topo
II poisons.
On the basis of molecular modeling analyses we suggest that these
complexes have one, two or three distinct binding domains. In the aqua
complexes of 1 and 2 the arene, TSC and water molecule can all bind to
the macromolecules. In 3 the thiacrown ligand doesn’t not bind directly
at all. The chloro complexes present two binding sites as the chloro
ligand doesn’t interact significantly with either macromolecule. (There
is one unfavorable negative-negative interaction with the phosphate
observed between 1 and Gua7 as well as 3 and Gua10 in DNA). We can
also see that the complexes are generally minor-groove binders. This is
not totally unexpected as there are no typical intercalative (large planar
aromatic) groups in the complexes.
Based on the results from the docking studies, it is difficult to fully
discern if there is a true effect of the face-cap on the interaction with
macromolecules. For the chloro compounds, the inorganic complex
bind stronger than the organometallic complexes to both DNA and
topo II. For the aquated complexes however, it is seen that the p-cymene
complex binds the strongest to both MMs.
Conclusion
Figure 11. Binding groups and the interactions of the complexes with the macromolecules:
A = chloro complexes: DNA top; topo II bottom. B = aquated complexes: DNA top; topo
II bottom
II target. For DNA the acceptor moiety is the sugar of Gua19 along
with Cyt19 in the interaction with the same complex. The same two
nucleotides are also the target for 2-aq and 3-aq.
As mentioned before, the complexes interact stronger with topo
II than DNA. For the aqua complexes Asn974 feature prominently in
the binding interactions. For 1-aq, 2, and 2-aq the –NH2 of the TSC
has a conventional H-bond with this group. Particularly noteworthy
are the interactions of the Tyr840. This residue of topo II interacts
in a variety of ways with the complexes. For 2 and 2-aq a pi-sigma
interaction is seen with the isopropyl group. In the case of 1-aq the
interaction is pi-pi with the benzene ring of the TSC. The tyrosine
residue of topoisomerase II is very important for its function. Topo II
is involved in DNA replication by facilitating the unwinding to relieve
strain during the replication process. Tyrosine residues in the enzyme
are involved in the chain breaking process. The hydroxyl group attacks
the phosphate units causing strand scission. The residues form covalent
bonds to DNA pulling the chains apart to create a gap. The intact strand
of DNA is passed through the gap before the break is resealed. Noncovalent interaction of protein with DNA is a key step in topoisomerase
II catalytic cycle. The fact that these complexes can bind to or interact
with the tyrosine residue would enable them stabilize the covalent topo
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
The three complexes synthesized in this study show a relatively
poor cytotoxicity profile in vitro colon cancer models. They are strong
binders of DNA as demonstrated by electronic absorption titrations
probably via an electrostatic binding mechanism. The organometallic
complexes do not photocleave pBR322 plasmid DNA. Based on the
results it can be suggested that the organometallic complexes a different
biophysical reactivity than the coordination compound. However we
can draw no hard conclusion as to whether the thiacrown enhances or
reduces the potential of half-sandwich ruthenium complexes to act as
anticancer agents. However based on results from the computational
studies which indicate that both DNA and topo II favors binding to this
complex in what is presumably the inactivated form. Altogether, the
information obtained from this study is interesting enough to suggest
that these complexes warrant further study towards their possible
development as metallodrugs.
Acknowledgements
This project was supported by grants from the National Center for
Research Resources (5P20RR016460-11) and the National Institute
of General Medical Sciences (8P20GM103429-11) from the National
Institutes of Health (USA) to FAB. The content is solely the responsibility
of the authors and does not necessarily represent the official views of
the National Center for Research Resources or the National Institutes
of Health. The funders had no input into the collection, analysis and
interpretation of the data, in the writing of the report or in the decision
to submit the article for publication.
Supplementary material
The crystallographic data for ruthenium complex reported in
this paper has been deposited with the Cambridge Crystallographic
Data Centre, CCDC #992015. One may obtain this information by
contacting the CCDC at 12 Union Road, Cambridge CB2 1EZ, United
Kingdom. (Fax: +44 1223 336 033] or via http://www.ccdc.cam.ac.uk/
data_request/cif .) Supplementary data associated with this article can
be found in the online version.
References
1. Mühlgassner G, Bartel C, Schmid WF, Jakupec MA, Arion VB, et al. (2012) Biological
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
activity of ruthenium and osmium arene complexes with modified paullones in human
cancer cells. J Inorg Biochem 116: 180-187.[Crossref]
21. Software Package for Crystal Structure Solution, APEX 2 suit. Bruker AXS, Madison,
WI, 2013.
2. Meier SM, Hanif M, Kandioller W, Keppler BK, Hartinger CG (2012) Biomolecule
binding vs. anticancer activity: reactions of Ru(arene)[(thio)pyr-(id)one] compounds
with amino acids and proteins. J Inorg Biochem 108: 91-95.[Crossref]
22. Sheldrick GM (1999) SADABS Area-detector. Absorption Correction, 2.03; University
of Göttingen, Göttingen, Germany.
3. Allardyce CS, Dyson PJ, Ellis DJ, Heath SL (2001) [Ru(?6-p-cymene)Cl2(pta)] (pta =
1,3,5-triaza-7-phosphatricyclo[3.3.1.1]decane): a water soluble compound that exhibits
pH dependent DNA binding providing selectivity for diseased cells. Chem Commun
1396–1397
4. Morris RE, Aird RE, Murdoch Pdel S, Chen H, Cummings J, et al. (2001) Inhibition
of cancer cell growth by ruthenium(II) arene complexes. J Med Chem 44: 3616-3621.
[Crossref]
5. Süss-Fink G1 (2010) Arene ruthenium complexes as anticancer agents. Dalton Trans
39: 1673-1688.[Crossref]
6. Beckford F, Thessing J, Woods J, Didion J, Gerasimchuk N, et al. (2011)
Synthesis and structure of [(?(6)-p-cymene)Ru(2-anthracen-9-ylmethylene-Nethylhydrazinecarbothioamide)Cl]Cl; biological evaluation, topoisomerase II inhibition
and reaction with DNA and human serum albumin. Metallomics 3: 491-502. [Crossref]
7. Beckford F, Dourth D, Shaloski M Jr, Didion J, Thessing J, et al. (2011) Half-sandwich
ruthenium–arene complexes with thiosemicarbazones: synthesis and biological
evaluation of [(ηâ¶-p-cymene)Ru(piperonal thiosemicarbazones)Cl]Cl complexes. J
Inorg Biochem 105: 1019-1029.[Crossref]
8. Hartinger CG, Zorbas-Seifried S, Jakupec MA, Kynast B, Zorbas H, et al. (2006) From
bench to bedside--preclinical and early clinical development of the anticancer agent
indazolium trans-[tetrachlorobis(1H-indazole)ruthenate(III)] (KP1019 or FFC14A). J
Inorg Biochem 100: 891-904.[Crossref]
9. Antonarakis ES, Emadi A (2010) Ruthenium-based chemotherapeutics: are they ready
for prime time? Cancer Chemother Pharmacol 66: 1-9.[Crossref]
10. Chen H, Parkinson JA, Parsons S, Coxall RA, Gould RO, et al. (2002) Organometallic
ruthenium(II) diamine anticancer complexes: arene-nucleobase stacking and
stereospecific hydrogen-bonding in guanine adducts. J Am Chem Soc 124: 3064-3082.
[Crossref]
11. Fernández R, Melchart M, Habtemariam A, Parsons S, Sadler PJ (2004) Use of
chelating ligands to tune the reactive site of half-sandwich ruthenium(II)-arene
anticancer complexes. Chemistry 10: 5173-5179.[Crossref]
12. Ivanovic I, Gligorijevic N, Arandelovic S, Radulovic S, Roller A, et al. (2013) New
ruthenium(II)-arene complexes bearing hydrazides and the corresponding (thio)
semicarbazones of 3- and 4-acetylpyridine: Synthesis, characterization, crystal
structure determination and antiproliferative activity. Polyhedron 61: 112-118.
13. Kandioller W, Kurzwernhart A, Hanif M, Meier SM, Henke H, et al. (2011) Pyrone
derivatives and metals: From natural products to metal-based drugs. J Organomet
Chem 696: 999-1010.
14. Hanif M, Meier SM, Kandioller W, Bytzek A, Hejl M, et al. (2011) From hydrolytically
labile to hydrolytically stable Ru(II)-arene anticancer complexes with carbohydratederived co-ligands. J Inorg Biochem 105: 224-231.[Crossref]
15. Wu Q, Fan C, Chen T, Liu C, Mei W, et al. (2013) Microwave-assisted synthesis of
arene ruthenium(II) complexes that induce S-phase arrest in cancer cells by DNA
damage-mediated p53 phosphorylation. Eur J Med Chem 63: 57-63.[Crossref]
16. Gligorijević N, Aranđelović S, Filipović L, Jakovljević K, Janković R, et
al. (2012) Picolinate ruthenium(II)-arene complex with in vitro antiproliferative and
antimetastatic properties: comparison to a series of ruthenium(II)-arene complexes with
similar structure. J Inorg Biochem 108: 53-61.[Crossref]
17. Dyson PJ (2007) Systematic Design of a Targeted Organometallic Antitumour Drug in
Pre-clinical Development. Chemia 61: 698-703.
18. Bratsos I, Jedner S, Bergamo A, Sava G, Gianferrara T, et al. (2008) Half-sandwich
Ru II[9]aneS3 complexes structurally similar to antitumor-active organometallic pianostool compounds: preparation, structural characterization and in vitro cytotoxic activity.
J Inorg Biochem 102: 1120-1133.[Crossref]
19. Bratsos I, Mitri E, Ravalico F, Zangrando E, Gianferrara T, et al. (2012) New half
sandwich Ru(II) coordination compounds for anticancer activity. Dalton Trans 41:
7358-7371.[Crossref]
20. Rilak A, Bratsos I, Zangrando E, Kljun J, Turel I, et al. (2012) Factors that influence the
antiproliferative activity of half sandwich Ru(II)-[9]aneS3 coordination compounds:
activation kinetics and interaction with guanine derivatives. Dalton Trans 41: 1160811618.[Crossref]
Interdiscip J Chem, 2016
doi: 10.15761/IJC.1000101
23. Beckford F, Robertson C, Harness R (2008) Thiosemicarbazone Complexes
of Group 12 elements. 1. An Investigation of the Thiosemicarbazone From
p-Dimethylaminobenzaldehyde1. J Undergrad Chem Res 7: 92-97.
24. Bennett MA, Smith AK (1974) Arene ruthenium(II) complexes formed by
dehydrogenation of cyclohexadienes with ruthenium(III) trichloride. Dalton Trans
233–241.
25. Goodfellow BJ, Felix V, Pacheo SMD, de Jesus JP, Drew MG (1997) Structural
characterisation of RuII [9]aneS3 polypyridyl complexes by NMR spectroscopy and
single crystal X-ray diffraction. Polyhedron 16: 393-401.
26. Cory AH, Owen TC, Barltrop JA, Cory JG (1991) Use of an aqueous soluble
tetrazolium/formazan assay for cell growth assays in culture. Cancer Commun 3: 207212.[Crossref]
27. Reichmann ME, Rice SA, Thomas CA, Doty PJ (1954) A Further Examination of the
Molecular Weight and Size of Desoxypentose Nucleic Acid. J Am Chem Soc 76: 30473053.
28. Vijayalakshmi R, Kanthimathi M, Subramanian V, Nair BU (2000) Interaction of
DNA with [Cr(Schiff base)(H(2)O)(2)]ClO(4). Biochim Biophys Acta 1475: 157-162.
[Crossref]
29. Barton JK, Goldberg JM, Kumar CV, Turro NJ (1986) Binding modes and base
specificity of tris(phenanthroline)ruthenium(II) enantiomers with nucleic acids: tuning
the stereoselectivity. J Am Chem Soc 108: 2081-2088.
30. Beckford FA, Leblanc G, Thessing J, Shaloski M, Frost BJ, et al. (2009) Organometallic
ruthenium complexes with thiosemicarbazone ligands: Synthesis, structure and
cytotoxicity of [(eta-p-cymene)Ru(NS)Cl] (NS = 9-anthraldehyde thiosemicarbazones).
Inorg Chem Commun 12: 1094-1098.[Crossref]
31. Hamaker CG, Halbach DP (2006) Synthesis, structure, and characterization of
some ruthenium arene complexes of N-(arylmethylene)-2-(methylthio)anilines and
2-(methylthio)aniline. Inorg Chim Acta 359: 846-852.
32. Mai JF, Yamamoto Y (1998) Preparations and structures of (ETA(6)-ARENE)
ruthenium(II) complexes bearing 1,1’-Bis(Diphenylphosphinomethyl)Ferrocene OR
1,1’-Bis(Diphenylphosphino)Ferrocene. J Organomet Chem 560: 223-232.
33. Halbach DP, Hamaker CG (2006) Synthesis, characterization, and X-Ray structural
analysis of some half-sandwich ruthenium(II) arene complexes with new N,S-donor
Schiff base ligands. J Organomet Chem 691: 3349–3361.
34. Afrasiabi Z, Sinn E, Kulkarni PP, Ambike V, Padhye S, et al. (2005) Synthesis and
characterization of copper(II) complexes of 4-alkyl/aryl-1,2-naphthoquinones
thiosemicarbazones derivatives as potent DNA cleaving agents. Inorg Chim Acta 358:
2023–2030.
35. Beckford FA, Stott A, Gonzalez-Sarrías A, Seeram NP (2013) Novel microwave
synthesis of half-sandwich [(?6-C6H6)Ru] complexes and an evaluation of the
biological activity and biochemical reactivity. Appl Organometal Chem 27: 425-434.
36. Mitra R, Das S, Shinde SV, Sinha S, Somasundaram K, et al. (2012) Anticancer activity
of hydrogen-bond-stabilized half-sandwich Ru(II) complexes with heterocycles.
Chemistry 18: 12278-12291.[Crossref]
37. Platon: crystallographic software package at http://www.cryst.chem.uu.nl/spek/platon/
38. Demoro B, Sarniguet C, Sánchez-Delgado R, Rossi M, Liebowitz D, et al. (2012)
New organoruthenium complexes with bioactive thiosemicarbazones as co-ligands:
potential anti-trypanosomal agents. Dalton Trans 41: 1534-1543.[Crossref]
39. Scolaro C, Bergamo A, Brescacin L, Delfino R, Cocchietto M, et al. (2005) In vitro and
in vivo evaluation of ruthenium(II)-arene PTA complexes. J Med Chem 48: 4161-4171.
[Crossref]
40. Ambroise A, Maiya BG (2000) Ruthenium(II) complexes of redox-related, modified
dipyridophenazine ligands: synthesis, characterization, and DNA interaction. Inorg
Chem 39: 4256-4263.[Crossref]
41. Jiang M, Li YT, Wu ZY, Liu ZQ, Yan CW (2009) Synthesis, crystal structure, cytotoxic
activities and DNA-binding properties of new binuclear copper(II) complexes bridged
by N,N’-bis(N-hydroxyethylaminoethyl)oxamide. J Inorg Biochem 103: 833-844.
[Crossref]
42. Liu Q, Zhang J, Wang MQ, Zhang DW, Lu QS, et al. (2010) Synthesis, DNA binding
and cleavage activity of macrocyclic polyamines bearing mono- or bis-acridine
Volume 1(1): 1-15
�Beckford FA (2016) Anticancer, biophysical and computational investigations of half-sandwich ruthenium(II) thiosemicarbazone complexes: The effect of arene
versus thiacrown face-cap
moieties. Eur J Med Chem 45: 5302-5308.[Crossref]
43. Peberdy JC, Malina J, Khalid S, Hannon MJ, Rodger A (2007) Influence of surface
shape on DNA binding of bimetallo helicates. J Inorg Biochem 101: 1937-1945.
[Crossref]
44. Ghosh KS, Sahoo BK, Jana D, Dasgupta S (2008) Studies on the interaction of copper
complexes of (-)-epicatechin gallate and (-)-epigallocatechin gallate with calf thymus
DNA. J Inorg Biochem 102: 1711-1718.[Crossref]
45. Lacowicz JR (2006) Principles of Fluorescence Spectroscopy, (3rd Edn). Springer,
New York.
46. Baldini M, Belicchi-Ferrari M, Bisceglie F, Pelosi G, Pinelli S, et al. (2003) Cu(II)
complexes with heterocyclic substituted thiosemicarbazones: the case of 5-formyluracil.
Synthesis, characterization, x-ray structures, DNA interaction studies, and biological
activity. Inorg Chem 42: 2049-2055.[Crossref]
50. Privat JP, Charlier M (1978) Photochemical modifications of the tryptophan residues
of wheat-germ agglutinin in the presence of trichloroethanol. Eur J Biochem 84: 79-85.
[Crossref]
51. Eftink MR, Ghiron CA (1981) Fluorescence quenching studies with proteins. Anal
Biochem 114: 199-227.[Crossref]
52. Sandhya B, Hegde AH, Kalanur SS, Katrahalli U, Seetharamappa J (2011) Interaction
of triprolidine hydrochloride with serum albumins: thermodynamic and binding
characteristics, and influence of site probes. J Pharm Biomed Anal 54: 1180-1186.
[Crossref]
53. Jackson M, Mantsch HH (1995) The use and misuse of FTIR spectroscopy in the
determination of protein structure. Crit Rev Biochem Mol Biol 30: 95-120.[Crossref]
54. Byler DM, Susi H (1986) Examination of the secondary structure of proteins by
deconvolved FTIR spectra. Biopolymers 25: 469-487. [Crossref]
47. Long EC, Barton JK (1990) On demonstrating DNA intercalation. Acc Chem Res 23:
271–273.
55. Olchowicz JC, Coles DR, Kain LE, MacDonald G (2002) Using Infrared Spectroscopy
to Investigate Protein Structure. Journal of Chemical Education 79: 369-371
48. Cohen G, Eisenberg H (1969) Viscosity and sedimentation study of sonicated DNA–
proflavine complexes. Biopolymers 8: 45-55.
56. Spartan’14, Wavefunction, Inc., Irvine, CA
49. Sugio S, Kashima A, Mochizuki S, Noda M, Kobayashi K (1999) Crystal structure of
human serum albumin at 2.5 A resolution. Protein Eng 12: 439-446.[Crossref]
57. Morris GM, Huey R, Lindstrom W, Sanner MF, Belew RK, et al. (2009) AutoDock4
and AutoDockTools4: Automated docking with selective receptor flexibility. J Comput
Chem 30: 2785-2791.[Crossref]
Copyright: ©2016 Beckford FA. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted
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doi: 10.15761/IJC.1000101
Volume 1(1): 1-15
�