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Vol. 58, Issue 5, 920-927, November 2000
Cancer Therapy and Research Center, Institute for Drug Development, San Antonio, Texas (J.M.W., S.F., M.C.S.H., B.A., W.G.C., E.R., A.V.T.); Department of Biochemistry and Biophysics, The University of North Carolina at Chapel Hill, Chapel Hill, North Carolina (A.V., M.V., S.G.C.); and Sanofi-Synthelabo Research, Malvern, Pennsylvania (P.E.J.)
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Abstract |
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 Top
 Abstract
 Introduction
Materials and Methods
Results
Discussion
References
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Damage to cellular DNA is believed to determine the antiproliferative properties of platinum (Pt) drugs. This study characterized DNA damage by oxaliplatin, a diaminocyclohexane Pt drug with clinical antitumor activity. Compared with cisplatin, oxaliplatin formed significantly fewer Pt-DNA adducts (e.g., 0.86 ± 0.04 versus 1.36 ± 0.01 adducts/106 base pairs/10 µM drug/1 h, respectively, in CEM cells, P < .01). Oxaliplatin was found to induce potentially lethal bifunctional lesions, such as interstrand DNA cross-links (ISC) and DNA-protein cross-links (DPC) in CEM cells. As with total adducts, however, oxaliplatin produced fewer (P < .05) bifunctional lesions than did cisplatin: 0.7 ± 0.2 and 1.8 ± 0.3 ISC and 0.8 ± 0.1 and 1.5 ± 0.3 DPC/106 base pairs/10 µM drug, respectively, after a 4-h treatment. Extended postincubation (up to 12 h) did not compensate the lower DPC and ISC levels by oxaliplatin. ISC and DPC determinations in isolated CEM nuclei unequivocally verified that oxaliplatin is inherently less able than cisplatin to form these lesions. Reactivation of drug-treated plasmids, observed in four cell lines, suggests that oxaliplatin adducts are repaired with similar kinetics as cisplatin adducts. Oxaliplatin, however, was more efficient than cisplatin per equal number of DNA adducts in inhibiting DNA chain elongation (~7-fold in CEM cells). Despite lower DNA reactivity, oxaliplatin exhibited similar or greater cytotoxicity in several other human tumor cell lines (50% growth inhibition in CEM cells at 1.1/1.2 µM, respectively). The results demonstrate that oxaliplatin-induced DNA lesions, including ISC and DPC, are likely to contribute to the drug's biological properties. However, oxaliplatin requires fewer DNA lesions than does cisplatin to achieve cell growth inhibition.
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Introduction |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Oxaliplatin
[l-OHP,
oxalato(trans-l-1,2-diaminocyclohexane)platinum(II)]
is a third generation platinum (Pt) antitumor compound in which
diaminocyclohexane (DACH) ligand replaces the amine groups present in cisplatin (Fig. 1) (Chaney,
1995
; Raymond et al., 1998). Oxaliplatin has demonstrated a broad
spectrum of antitumor activity (Rixe et al., 1996) with a partial or a
non-cross-resistance with cisplatin in a wide range of human tumors in
vitro and in vivo (Weiss and Christian, 1993; Kelland and McKeage,
1994; Chaney, 1995; Raymond et al., 1998). Ongoing clinical European
phase II trials have reported encouraging activity and manageable
toxicity in a variety of tumors usually resistant to cisplatin (for
review, see Cvitkovic, 1998). Oxaliplatin is now approved, in
combination with 5-fluouracil, for the treatment of advanced colorectal
cancer in Europe.
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The critical role of DNA-Pt adducts in the antiproliferative effects,
well documented for cisplatin, is generally accepted for all antitumor
Pt drugs (for review, see Sanderson et al., 1996). The knowledge of
oxaliplatin-induced DNA lesions is largely based on extrapolation of
findings for cisplatin and DACH compounds other than oxaliplatin.
However, the analogy between oxaliplatin and cisplatin should not be
overinterpreted. Oxaliplatin is typically at least as potent as
cisplatin in inhibiting the growth of cancer cells (Rixe et al., 1996).
Thus, oxaliplatin would be expected to damage DNA to a similar extent
as cisplatin. However, various methodologies suggested that oxaliplatin
induced fewer lesions in naked and cellular DNA than did equimolar
cisplatin (Saris et al., 1996; Woynarowski et al., 1998).
These paradoxical findings suggest that oxaliplatin-induced DNA damage
may differ in various aspects from that of cisplatin. Although the
structures of diaminocyclohexane (DACH)-Pt DNA adducts formed by
oxaliplatin and cis-diammine-Pt DNA adducts (formed by
cisplatin) are similar, the bulky DACH moiety that protrudes into the
minor groove (Scheeff et al., 1999) may possibly lead to different
biological properties of DACH-Pt-DNA adducts (Chaney, 1995; Scheeff et
al., 1999). DACH-Pt adducts, for instance, appear to be more effective
at inhibiting DNA synthesis (Gibbons et al., 1990, 1991; Schmidt and
Chaney, 1993). On the other hand, the possibility that DACH moiety in
oxaliplatin affects the localization of drug adducts in DNA has been
ruled out because sequence and region specificities of oxaliplatin
adducts are similar to those of cisplatin (Woynarowski et al., 1998).
Another unstudied possibility is that oxaliplatin might generate a
greater proportion of highly lethal lesions, compensating in that way
for the lower overall DNA adduction compared with cisplatin. Whereas
intrastrand cross-links are probably the main type of oxaliplatin
adducts, infrequent interstrand cross-links (ISC) were also detected
with naked DNA (Woynarowski et al., 1998). ISC are regarded as lethal
DNA lesions for cisplatin (Bedford et al., 1987; Roberts and Friedlos,
1987; Roberts et al., 1988). However, ISC induction by oxaliplatin in
cellular DNA has never been reported. Also, the ability of oxaliplatin
to form another likely lesion, DNA-protein cross-links (DPC), remains unknown.
Our current study explored the leads suggesting that oxaliplatin could differ from cisplatin in the ability to damage DNA. The results verify that oxaliplatin, like cisplatin, forms ISC and DPC in tumor cells. However, oxaliplatin-induced total Pt-adducts, ISC, and DPC are significantly lower than the respective lesions induced by equimolar concentrations of cisplatin, despite a similar or greater cytotoxicity of oxaliplatin.
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Materials and Methods |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Drugs, Cell Culture, and Cytotoxic Activity.
Oxaliplatin was
obtained from Sanofi-Synthelabo Research (Great Valley, PA). Cisplatin
was purchased from Sigma Chemical Co. (St. Louis, MO). Drug stock
solutions were made in water (oxaliplatin) or in saline (cisplatin) and
stored at 
20°C.
) in minimal essential medium Eagle, Joklik's
modification (Sigma). Human ovarian carcinoma A2780 and its
cisplatin-resistant clone A2780PR were cultured in RPMI 1640 (Life
Technologies, Gaithersburg, MD; Mamenta et al., 1994). Human colon
adenocarcinoma HT29 cells were purchased from and were cultured as
recommended by the American Type Culture Collection (Rockville, MD).
Human colon carcinoma HCT 116 cells were kindly provided by Dr. R. Boland (University of California, La Jolla, CA) and were cultured in
Iscove's modified Dulbecco's medium (Life Technologies). All
media were supplemented with 10% fetal bovine serum. All cell lines
were grown in humidified 5% CO2 at 37°C and
were regularly screened for mycoplasma.
Growth inhibitory activity against CEM cells was assayed based on cell
counting with an electronic counter after a 48-h continuous treatment
(approximately 3 × generation time) with drugs at 0.01 to 100 µM or a 1-h treatment followed by a 48-h postincubation. Cytotoxicity
against other cell lines was determined by standard MTT
(3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay
(Woynarowski et al., 1997) after 72 h of continuous drug treatment
(approximately 3 × generation time). The results are expressed as
drug concentrations that inhibit net cell growth by 50%
(GI50).
Cellular Pt-DNA Adducts.
Platination levels were monitored
by atomic absorption as previously described (Gibbons et al., 1990;
Schmidt and Chaney, 1993). Pilot studies had shown that the Pt-DNA
levels were proportional to the drug concentration used over the range
of 50 to 250 µM. For each experiment, cells
(106/10 ml medium in replicate 100-mm dishes)
were exposed to 100 µM cisplatin or oxaliplatin as indicated in Fig.
2 and Table 2. DNA was purified from each
dish separately using the Wizard Genomic DNA Purification Kit (Promega,
Madison, WI) and analyzed for Pt levels by AA in triplicate on a
Perkin Elmer (Norwalk, CT) Cetus model 560 atomic absorption
spectrophotometer with an HGA 500 graphite furnace and an AS-1
autosampler. DNA preparations from different culture dishes and on
different days were considered repeats and were as follows:
n = 4 for 15/45 min, n = 6 for 1 h, and n = 3 for 4 h. The data for Pt adducts were
normalized per 106 base pairs (bp)/10 µM drug,
to allow the comparison with other types of DNA lesions (Table 2).
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DNA Repair and Host Cell Reactivation Assay.
Plasmid
reactivation assays were performed using a strategy similar to that
described by others (Chao et al., 1991; Ali-Osman et al., 1994). Two
plasmids from Promega were used: pGL3 control vector containing the
luciferase construct was used as the drug damage reporter, whereas pSV
-galactosidase control vector served as an internal control for
transfection efficiency. Plasmids were prepared and purified as
recommended by Promega. The pGL3 control vector (100 µg/ml) in TE
buffer (10 mM Tris, 0.5 mM EDTA, pH 7.4) was treated with 0.25 to 5 µM cisplatin or 0.5 to 50 µM oxaliplatin for 22.5 h at 37°C.
For oxaliplatin treatment, the reactions were supplemented with NaCl
(100 mM final concentration) to accelerate formation of drug active
species. After ethanol precipitation to remove unreacted drug, plasmid
DNA was redissolved in TE buffer, and its concentration was quantitated
by standard Hoechst 33258 fluorescence assay. Platination levels
were also directly assessed in drug-treated plasmids by atomic
absorption as described for cellular Pt adducts. One batch of
drug-treated plasmids was used in all the transfection experiments.
20°C until use.
Reporter detection was based on chemiluminescence and used a
Packard (Meridian, CT) TopCount scintillation counter as a
luminescence counter. Detection of luciferase used Steady-Glo
Luciferase Assay System from Promega, and -galactosidase was
detected using the Galacto-Star -Galactosidase Chemiluminescent
Reporter Gene Assay System detection kit from Tropix (Bedford, MA). For
each transfection, mock-transfected cells were used as background
controls, and non-drug-treated plasmids were used as a positive control.
ISC by Alkaline Sucrose Gradient Sedimentation.
The
procedure for sedimentation analysis of cellular DNA was used
essentially as described elsewhere (Woynarowski et al., 1999). Briefly,
cells prelabeled with [14C]thymidine were
treated with drugs and, in some experiments, postincubated in drug-free
medium as indicated. Aliquots of 105 harvested
cells in 50 mM Tris-HCl, pH 7.5, 10 mM EDTA, 0.2% Triton X-100 were
loaded onto preformed alkaline sucrose gradients composed of 0.5 ml of
60% sucrose cushion, 10 ml of 5 to 20% sucrose, and 0.4 ml of lysing
layer (1% Sarkosyl, 2.5% sucrose). All the solutions were in a
gradient buffer (0.7 M NaCl, 0.3 M NaOH, 0.01 M EDTA). After the sample
was applied, an additional volume (200 µl) of lysing solution was
laid on the top, and lysis was allowed to proceed for 20 h.
Sedimentation was carried out in an SW41 rotor (Beckman Instruments,
Fullerton, CA) at 20°C for 20 h at 10,000 rpm (A2780
cells) and 9200 rpm (CEM cells). Gradients were fractionated and the
fractions processed as described previously (Woynarowski et al., 1995).
:
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(1) |
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(2) |
) was modified in that
only gradient fractions corresponding to the area of cross-linked DNA
(bottom portion of the gradients, where the signal for drug-treated samples was equal to or greater than for control samples) were included
in FD calculations.
DPC.
DPC were assayed using the K+/SDS
precipitation technique. For DPC determinations in intact cells,
[14C]thymidine-prelabeled cells were incubated
with drugs as indicated. After drug treatment, cells were lysed, and
DNA coprecipitable with proteins was determined as described previously
(Woynarowski et al., 1989, 1997). For DPC determination in isolated
nuclei, prelabeled cells were lysed in nuclei isolation buffer (2 mM
KH2PO4, 5 mM
MgCl2, 150 mM NaCl, 1 mM EGTA, pH 6.9)
supplemented with 0.3% (v/v) Triton X-100 for 20 min at 4°C, and
then centrifuged for 13 min at 300g. The nuclear pellets
were resuspended in the isolation buffer at 0.3 to 0.5 × 106 nuclei/ml and incubated with drugs, followed
by DPC determination as for intact cells (Woynarowski et al., 1989).
). Next, the frequency of DPC
(f) was estimated based on a Poisson distribution analogous to ISC frequency:
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(3) |
) of DNA in cell and nuclear
lysates sheared by vortexing and processed in the same way as in the
K+/SDS assay (not shown). Molecular weights of
DNA in gradient fractions and the MWn values
were calculated as described previously (Woynarowski et al., 1995)
using parameters for neutral sedimentation conditions. Assuming the
MWn value of 5 × 107
Da, 1.35 and 2.86 DPC/106 bp correspond to a
fraction of protein-bound DNA (FP) equal to 10 or 20% of total
cellular DNA, respectively.
Chain Elongation Assay.
The size distribution of
radiolabeled nascent DNA was determined by velocity sedimentation
analysis as described previously (Gibbons et al., 1991; Mamenta et al.,
1994). Briefly, CEM or A2780 cells were plated on 60-mm dishes at an
initial concentration of 5 × 105 cells/dish
and uniformly labeled with [14C]thymidine for
48 h. The old medium was then replaced with a medium containing
various concentrations of oxaliplatin or cisplatin followed by a 15-min
incubation. The drug-medium was then removed and replaced with a
drug-free medium followed by a 30-min incubation. The cells were then
pulsed for 15 min with 6 µCi/ml [3H]thymidine
(specific activity, 85 Ci/mmol). The radioactive medium was removed,
and the cells were harvested into 1 ml of ice-cold harvest buffer (0.1 M NaCl-0.01 M EDTA, pH 8.0). Cells were harvested and lysed and the
lysates subjected to sedimentation in alkaline sucrose gradients. The
gradients were fractionated, and acid-precipitable 3H counts were determined and normalized to the
total amount of proteins in each sample. The percentage of chain
elongation (relative to control) was calculated from the areas under
the curve in the region of the profiles corresponding to the chain elongation.
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Results |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Cytotoxic Activities.
The cytotoxic activities
(GI50 values, drug concentration inhibiting cell
growth by 50%) of oxaliplatin and cisplatin against various cell lines
differing in cisplatin sensitivity, p53, and mismatch repair status are
summarized in Table 1. Oxaliplatin and
cisplatin showed similar levels of growth inhibition in CEM cells with
mutated p53 with the GI50 ~ 1.1/1.2 and 11/11
µM after continuous drug treatment and a 1-h pulse treatment,
respectively. A2780 cells (with wild-type p53) were more sensitive to
both drugs than CEM cells, with oxaliplatin being nearly 2-fold more
cytotoxic than cisplatin. Furthermore, oxaliplatin was ~2-fold more
cytotoxic than cisplatin against the cisplatin-resistant subline
A2780PR and 6- to 7-fold more cytotoxic against a mismatch
repair-deficient line, HCT116, and against a generally drug-resistant
line, HT-29 (Table 1).
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Total DNA Platination.
Platination levels were used as an
overall measure of adduct formation after various incubation conditions
in CEM cells (Fig. 2). Oxaliplatin consistently formed significantly
fewer adducts than cisplatin at equimolar external concentrations (Fig.
2 and Table 2). For instance, after a 1-h
treatment, oxaliplatin and cisplatin formed 0.86 and 1.36 Pt
adducts/106bp/10 µM, respectively (Fig. 2 and
Table 2). The difference between both drugs remained significant after
a 4-h incubation, with the respective platination values of 2.4 versus
3.18 Pt adducts/106 bp/10 µM. Similar
differences in oxaliplatin and cisplatin adduct levels were observed in
A2780 cells (data not shown).
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Repair of Oxaliplatin Lesions-Host Cell Reactivation Assay.
To
address the possibility that oxaliplatin adducts are less prone to
removal by repair processes, we analyzed the reactivation of
drug-treated plasmids in several cell lines. The initial levels of
plasmid platination showed a good dependence on drug concentration during plasmid treatment ranging from 1.3 ± 0.1 up to 180 ± 2.3 Pt atoms/kbp for 0.5 to 50 µM oxaliplatin and from 1.6 ± 0.1 up to 36.9 ± 0.7 Pt atoms/kbp for 0.25 to 5 µM cisplatin.
The detected cisplatin platination levels are in reasonable agreement
with literature data for similar treatment conditions (Chao et al., 1991).
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ISC in Intact Cells.
Induction of ISC by oxaliplatin and
cisplatin was examined to assess whether the lower total Pt adducts
formed by oxaliplatin might be compensated by a greater proportion of
highly lethal lesions such as ISC. Sedimentation analysis after a 4-h
incubation of CEM cells with 25 µM cisplatin produced the
characteristic pattern for interstrand cross-links indicated as shifts
in DNA sedimentation profiles toward the bottom of the gradients
(fractions 19-24, brackets in Fig. 4).
DNA from oxaliplatin-treated cells also revealed fast-sedimenting
material, although less prominent than for cisplatin. A similar pattern
was observed in A2780 cells (data not shown). These results confirm
that oxaliplatin forms interstrand cross-links but at markedly lower
levels than equimolar cisplatin.
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), affect the size distribution of DNA fragments. Thus, the quantitation of ISC may not be
accurate, particularly after longer incubation times. Still, additional
experiments with a 1-h pulse drug treatment followed by a 6-h
postincubation in drug-free medium suggested that oxaliplatin forms
similar or lower levels of ISC than does cisplatin (0.14 and 0.35 ISC/106 bp/10 µM, respectively, Table 2).
DPC in Intact Cells.
DPC are another type of previously
unstudied DNA lesion, in which oxaliplatin might possibly compensate
for its lower overall reactivity with DNA, compared with cisplatin. The
induction of DPC was analyzed based on direct physical separation of
protein-bound and protein-free DNA by the K+/SDS
precipitation technique (Woynarowski et al., 1989, 1997). After a
continuous 4-h treatment, oxaliplatin formed significantly fewer DPC
than did cisplatin (Fig. 5A). Normalized
per 10 µM drug, oxaliplatin and cisplatin formed an estimated
0.8 ± 0.1 and 1.5 ± 0.3 DPC/106 bp,
respectively (Table 2). The difference between two drugs was diminished
but still noticeable in A2780 cells (data not shown).
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ISC and DPC in Isolated Nuclei.
To unequivocally establish
whether oxaliplatin is inherently less efficient than cisplatin in the
formation of both ISC and DPC, these lesions were measured in isolated
nuclei from CEM cells. In this system, the drugs react with intact
nuclear chromatin but the induction of secondary effects, including
strand breaks, which affect the determinations in intact cells, was
unlikely. Also, potential differences in drug uptake can be ruled out
in the nuclear system. The results provide a clear-cut answer that there are markedly fewer ISC and DPC induced by oxaliplatin than cisplatin (Fig. 6). Sedimentation
profiles observed at 25 µM drugs (Fig. 6A) correspond to 5.5 and 15.6 ISC/106 bp, for oxaliplatin and cisplatin,
respectively. Similarly, oxaliplatin remained less efficient in DPC
induction than did cisplatin (Fig. 6B). For instance, 10 µM
oxaliplatin and cisplatin produced ~8 and ~20
DPC/106 bp, respectively, in the nuclear system.
Moreover, the DPC induction reached a plateau for both drugs after ~4
h (data not shown), but the levels of oxaliplatin-induced DPC were
significantly lower than cisplatin-induced DPC in their steady state.
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Inhibition of DNA Chain Elongation.
To assess the potential
consequences of DNA damage, additional experiments explored the
relationship between drug adducts and DNA chain elongation. The short
time of drug treatment needed for these determinations necessitates the
use of relatively high drug concentrations (Gibbons et al., 1991;
Mamenta et al., 1994). However, the parallel determinations of the
platination levels (cf. Fig. 2) allowed us to express drug effects on
chain elongation as a function of adduct frequency (Fig.
7). Oxaliplatin adducts seemed to be
approximately 7-fold more effective in inhibiting DNA chain elongation
than cisplatin adducts in CEM cells, considering the number of Pt-DNA
adducts per 106 bp (Fig. 7). Somewhat less
profound (approximately 2-fold) difference in the adduct inhibitory
efficiency was found in A2780 cells (data not shown).
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Discussion |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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In contrast to extensive studies of DNA damage by cisplatin,
little is known about damage to cellular DNA by oxaliplatin. It is
commonly accepted that DNA damage by antitumor Pt drugs is responsible
for their cytotoxic properties. According to this central paradigm,
oxaliplatin should be more proficient in damaging DNA than cisplatin,
given that oxaliplatin is at least equally cytotoxic or frequently more
cytotoxic than cisplatin (Table 1) (Rixe et al., 1996). Systematic
characterization of oxaliplatin-induced DNA lesions in this study
suggests that oxaliplatin declines from the predictions of the central
paradigm. In addition to total platination, we quantified
oxaliplatin-induced ISC and DPC in comparison to analogous effects of
cisplatin. The results demonstrate that oxaliplatin is undoubtedly a
DNA-reactive drug in cellular systems and resembles closely cisplatin
with regard to the types and proportions of specific DNA lesions. Yet,
oxaliplatin consistently forms markedly fewer total adducts and
specific type of cross-links than cisplatin, despite at least equal or
greater cytotoxicity.
The determinations of the total levels of DNA platination demonstrate
that oxaliplatin formed significantly fewer adducts with cellular DNA
than did cisplatin (Fig. 2 and Table 2). This observation that
platination levels produced by oxaliplatin are consistently lower than
those induced by cisplatin is in agreement with the determinations by
other researchers (Saris et al., 1996), who found a 10-fold lower level
of oxaliplatin adducts, compared with cisplatin adducts, in A2780 cells
by immunochemical detection. Also, our recent studies showed that the
level of Pt adducts induced by oxaliplatin in specific regions of DNA
from drug-treated A2780 cells was 2 to 6 times lower than that of
cisplatin (Woynarowski et al., 1998). Clearly, in various systems,
oxaliplatin needs to form fewer adducts than cisplatin for comparable cytotoxicity.
The lower overall DNA adduction by oxaliplatin might still be
reconciled with the equal or higher cytotoxic activities, if oxaliplatin-DNA adducts were considerably more difficult to repair compared with cisplatin adducts. Adduct repair is an important factor
in Pt drug action (Petersen et al., 1996; Damia et al., 1998; Hibino et
al., 1999; Koeberle et al., 1999). However, oxaliplatin-induced DNA
damage appears to be no more difficult to repair than cisplatin-induced damage as judged by plasmid reactivation in several cell lines (Fig.
3), which reflects mainly excision repair processes. This result is
consistent with the observation that both cisplatin and oxaliplatin
adducts are similarly removed in a cell-free excision repair system
(Reardon et al., 1999). Thus, the lower total platination in the case
of oxaliplatin is unlikely to be compensated, compared with cisplatin,
by impeded adduct removal.
Oxaliplatin cytotoxicity might possibly result from proportionately more highly lethal lesions, such as interstrand cross-links, or other previously uncharacterized lesions, such as DPC. Oxaliplatin forms both types of lesions in cellular DNA (Figs. 4 and 5 and Table 2). These results document for the first time that oxaliplatin is able to induce ISC and DPC in cellular DNA. Although ISC and DPC constitute a minor fraction of total adducts for either oxaliplatin or cisplatin, these lesions may contribute to oxaliplatin effects. However, the absolute levels of ISC and DPC induced by oxaliplatin were markedly lower than those induced by cisplatin, after the reduced total platination levels (Table 2). Thus, it seems unlikely that these lesion types may compensate for the overall reduction of oxaliplatin adducts.
Inherently lower reactivity of oxaliplatin compared with cisplatin is
corroborated in a clear-cut way in isolated nuclei (Fig. 6). Thus,
potential differences in cellular uptake of the two drugs can be ruled
out as a simple explanation for the lower levels of oxaliplatin adducts
in intact cells. Markedly lower reactivity of oxaliplatin was shown
also with naked DNA (Woynarowski et al., 1998). Although the details of
intracellular oxaliplatin activation remain unknown, the slow
dissociation of the oxalate ligand may be the bottleneck in
oxaliplatin-DNA reactivity (Luo et al., 1998, 1999a,b).
Our data suggest that oxaliplatin-DNA adducts may be more lethal than
cisplatin adducts. In CEM cells, GI50 values for
oxaliplatin and cisplatin are virtually identical, even though
oxaliplatin treatment results in significantly fewer lesions than
cisplatin treatment at equimolar concentrations. The greater lethality
of oxaliplatin adducts is consistent with their greater inhibition of
DNA chain elongation (Fig. 7). Similar differences in replicative bypass have been noted between DACH adducts and cisplatin adducts in
other cell lines (Gibbons et al., 1991; Mamenta et al., 1994). Processing of oxaliplatin and cisplatin adducts may also elicit different downstream responses. For instance, cisplatin depends on
intact mismatch repair for its maximal cytotoxicity (Aebi et al., 1996;
Fink et al., 1996; Vaisman et al., 1998; Ferry et al., 1999). In
contrast, oxaliplatin adducts are poorly recognized by mismatch repair
proteins (Fink et al., 1996) and do not activate JNK and c-Abl (Nehme
et al., 1999), and oxaliplatin retains a high cytotoxicity in mismatch
repair-deficient cells (Fink et al., 1997; Vaisman et al., 1998).
Finally, it is important to recognize that DNA damage, although
probably crucial, represents only one aspect of the pleiotropic effects
of Pt drugs. Only 5 to 10% of covalently bound cell-associated cisplatin is found in the DNA fraction, whereas cisplatin binding to
proteins is 1 order of magnitude greater (~75-85%; Akaboshi et al.,
1992, 1994). An intriguing possibility is that functional protein
damage (interference with enzymatic, receptor, and/or structural
functions) may play a greater role in the effects of oxaliplatin than
other Pt drugs. The hydrophobic DACH moiety in oxaliplatin may shift
drug reactivity toward a subset of cellular proteins with hydrophobic
binding pockets (Chaney, 1995). These proteins might well be different
from those that react with cisplatin. Thus, enhanced and/or different
protein binding might also be a factor in the disproportionately potent
apoptosis induction by oxaliplatin (Faivre and Woynarowski, 1998),
given the drug's modest DNA reactivity. Studies are under way to
elucidate whether protein damage, in addition to DNA damage,
contributes to the cytotoxic and proapoptotic properties of
oxaliplatin.
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Acknowledgments |
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We thank Drs. Esteban Cvitkovic and James Rake for encouragement and valuable comments, Dr. Gokul Das for pertinent methodological suggestions, and Dr. James Quada for critical reading of the manuscript.
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Footnotes |
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Received February 17, 2000; Accepted July 11, 2000
1 Present address: Departement de Medecine, Institut Gustave-Roussy, 39, rue Camille-Desmoulins 94800 Villejuif, France.
This study was supported in part by a grant from Sanofi-Synthelabo Research and by the National Institutes of Health Grant CA78706. E.R. was a recipient of fellowships from the Association pour la Recherche contre le Cancer (France) and from the Assistance Publique des Hôpitaux de Paris. A preliminary account of this study was presented in part at the 88th Annual Meeting of the American Association for Cancer Research, San Diego, CA, April 12 to 16, 1997, Proceedings, p 311, and the 90th Annual Meeting of the American Association for Cancer Research, Philadelphia, PA, April 10 to 14, 1999, Proceedings, p 294.
Send reprint requests to: Jan M. Woynarowski, Ph.D., Cancer Therapy and Research Center, Institute for Drug Development, 14960 Omicron Dr., San Antonio, TX. E-mail: jmw1{at}saci.org
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Abbreviations |
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DACH, diaminocyclohexane; oxaliplatin, l-OHP, oxalato (trans-l-1,2-diaminocyclohexane)platinum(II); Pt, platinum; GI50, drug concentration inhibiting cell growth by 50%; ISC, interstrand DNA cross-links; DPC, DNA protein cross-links; (k)bp, (kilo)base pair.
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References |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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)-(R)-2-aminomethylpyrrolidine(1,1-cyclobutanedicarboxylato)-2-pla in um(II) to DNA, RNA and protein molecules in HeLa cells and its lethal effect: Comparison with cis- and trans-diamminedichloroplatinums(II).
Jpn J Cancer Res
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) or
cisplatin-treated (
) plasmids in A2780 (A) and HT29 (B) cells. The
luciferase reporter plasmid was treated with various concentrations of
drugs as described under Materials and Methods, followed
by the determinations of platination levels (abscissa). Cells were
cotransfected with the drug-damaged luciferase plasmids and undamaged
) and cells treated with oxaliplatin at 25 µM
(
