This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Voland, C. Articles by Casellas, P. Search for Related Content PubMed PubMed Citation Articles by Voland, C. Articles by Casellas, P.

Research Articles: Therapeutics

Repression of cell cycle–related proteins by oxaliplatin but not cisplatin in human colon cancer cells

¹ Oncology Department, Sanofi-Synthelabo Recherche, Montpellier, France and ² Hôpital Saint Louis (Assistance Publique Hospitaux de Paris), Paris, France

Requests for reprints: Pierre Casellas, Sanofi-Synthelabo Recherche, 371 rue du Professeur Joseph Blayac, F-34184 Montpellier Cedex 04, France. Phone: 33-4-67-10-62-90; Fax: 33-4-67-10-60-00. E-mail: pierre.casellas{at}sanofi-aventis.com

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Oxaliplatin (Eloxatin) is a third-generation platinum derivative with an in vitro and in vivo spectrum of activity distinct from that of cisplatin, especially in colon cancer cells. Here, we studied the molecular basis of this difference on the HCT-116 human colon carcinoma cell line (mismatch repair-deficient, wild-type functional p53). Oxaliplatin inhibited HCT-116 cell proliferation with greater efficacy than cisplatin. At comparable concentrations, cisplatin slowed down the replication phase and activated the G₂-M checkpoint, whereas oxaliplatin activated the G₁-S checkpoint and completely blocked the G₂-M transition. With the aim of finding oxaliplatin-specific target genes and mechanisms differing from those of cisplatin, we established the transcriptional signatures of both products on HCT-116 cells using microarray technology. Based on hierarchical clustering, we found that (a) many more genes were modulated by oxaliplatin compared with cisplatin and (b) among the 117 modulated genes, 79 were regulated similarly by both drugs and, in sharp contrast, 38 genes were dose dependently down-regulated by oxaliplatin and, conversely, up-regulated or unaffected by cisplatin. Interestingly, several cell cycle–related genes encoding proteins involved in DNA replication and G₂-M progression belong to this latter group. RNA modulations, confirmed at the protein level, were in accordance with oxaliplatin- and cisplatin-induced cell cycle variations. Beyond the identification of genes affected by both drugs, the identified oxaliplatin-specific target genes could be useful as predictive markers for evaluating and comparing the efficacy and molecular pharmacology of platinum drugs. [Mol Cancer Ther 2006;5(9):2149–57]

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Platinum drugs are among the most widely used compounds in cancer chemotherapy. The cytotoxicity of platinum derivatives is characterized by the formation of platinum adducts on DNA, with Pt-GG and Pt-AG intrastrand crosslinks being the major lesions (1, 2). Oxaliplatin (cis-[(1R,2R)-1,2-cyclohexanediamine-N,N'] oxalato (2-)-O,O' platinum; Eloxatin) is a third-generation platinum derivative bearing a 1,2-diaminocyclohexane carrier ligand and is now approved, in combination with 5-fluorouracil, for the treatment of advanced colorectal cancer (3). In vitro comparisons of oxaliplatin with cisplatin showed that oxaliplatin requires fewer DNA lesions than cisplatin to inhibit cell growth (1, 2, 4) and it has a broad potent antiproliferative activity, especially in cisplatin-resistant colon cancer cell lines (5, 6). In line with this, preclinical studies using tumor models and clinical data showed that oxaliplatin is therapeutically beneficial in cisplatin resistant tumors that are common in colorectal cancer (7, 8). Altogether, these data suggest that oxaliplatin might have different cellular targets and mechanisms of action compared with those of cisplatin, which have yet to be established.

DNA damage resulting from exposure to cytotoxic agents induces cell cycle arrest, which mainly occurs at the G₁-S or/and G₂-M transition via activation of checkpoint proteins that inhibit cyclin-dependent kinase (CDK) activities (9). For example, inhibition of CDK4/cyclin D and/or CDK2/cyclin E activity leads to G₁-phase arrest, inhibition of CDK2/cyclin A activity delays S-phase progression, and the inhibition of CDK1/cyclin B, a key regulator of the G₂-M transition, induces G₂ arrest. CDK1 activation is controlled by dephosphorylation at Tyr¹⁵ by CDC25C phosphatase and CDC25C phosphatase is inactivated by phosphorylation via Chk1 after DNA damage. Most studies on the effects of platinum drugs on cell cycle progression have been done with cisplatin and showed that it reduces the DNA synthesis rate (10, 11) with a subsequent S-phase slowdown (12) followed by G₂-M arrest (12, 13). Although it has not yet been clearly established whether cisplatin-treated cells are arrested in the G₂ or M phase, cisplatin-induced G₂-M arrest is consistent with the inhibition of the CDK1/cyclin B activity by cisplatin (13).

The effects of oxaliplatin on the cell cycle have been reported similar to the effects of cisplatin. However, contrasting results on the effects of 1,2-diaminocyclohexane-platinum compounds on cell cycle progression have been reported (14). For example, on OVCA-429 ovarian cancer cells, cisplatin arrests both wild-type p53 and mutant p53 cells in G₂-M, whereas 1,2-diaminocyclohexane-acetato-Pt arrests wild-type p53 cells in G₁ and mutant p53 cells in G₂-M (14).

In this context, further investigations on the effects of oxaliplatin on cell cycle progression and on identification of cell cycle–related target genes and mechanisms of action are essential.

The aim of this study was to investigate the effects of oxaliplatin on cell cycle progression and to identify cell cycle–related oxaliplatin-specific target genes and mechanisms that would explain the higher efficacy of oxaliplatin compared with cisplatin, especially in colon carcinoma cells. To this aim, the effects of both oxaliplatin and cisplatin were investigated on the HCT-116 colon carcinoma cell cycle. HCT-116 cells are deficient in DNA mismatch repair because of a genetic defect in the hMLH1 gene, which is located on chromosome 3 (15). This deficiency is a common etiologic factor for colon cancer (16) and, interestingly, is a key factor for cisplatin and carboplatin resistance (6). HCT-116 cells express a functional p53 protein and have mostly intact DNA damage–dependent checkpoints, thus allowing cell cycle investigations. Furthermore, HCT-116 cells have already been used in analyses on the mechanism of action of platinum compounds (6, 17). Until recently, the only key differentiating variable between 1,2-diaminocyclohexane platinum and other platinum compounds [which present a very different profile in the National Cancer Institute COMPARE program (6) and a differential clinical activity profile], both as a single agent and notably in combination (7) was mismatch repair status (18).

Using a global gene expression approach, we examined transcriptional modulations induced by both drugs and identified cell cycle–related genes that are inversely regulated by oxaliplatin and cisplatin. RNA modulations were confirmed at the protein level. These target genes that we identified here may be important mediators of specific tumor cell response to oxaliplatin treatment.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Cell Culture
The HCT-116 human colon cancer cell line was from the American Type Culture Collection (Rockville, MD). Cells were grown as monolayers in McCoy's medium supplemented with 10% FCS at 37°C in a humidified atmosphere containing 5% CO₂.

Proliferation Assays
HCT-116 cells were plated (5,000 per well) in 96-well Cytostar-T scintillating microplates (Amersham Pharmacia, Little Chalfont, United Kingdom) in the presence of oxaliplatin (supplied by Sanofi-Synthelabo Recherche, Montpellier, France), cisplatin [commercially available from Sigma (St. Louis, MO) as a lyophilized powder in 50-mg vial], or solvent. Proliferation was measured by the incorporation of [¹⁴C]thymidine (Amersham Pharmacia). Cells were pulsed with [¹⁴C]thymidine (0.5 µCi/mL) for 12 hours and then counted using a Microbeta 1450 Trilux scintillation counter (Wallac, Wellesley, MA). Each experimental point is done in quadruplicate. The proliferation assay has been done thrice.

Cell Cycle Analysis
HCT-116 cells were plated (0.5 x 10⁶ per well) in six-well plates. Twenty-four hours later, cells were cultured for 24 hours in the presence of drug or solvent. Cells were harvested by trypsinization, washed twice with PBS, and resuspended in 70% ethanol in PBS and kept at 4°C overnight. After washing, cells were incubated for 5 minutes with PBS containing 0.25% Triton X-100, washed twice, resuspended in PBS-fetal bovine serum (1%), and labeled with MPM-2 antibody (1 µg final concentration; Upstate Biotechnology, Charlottesville, VA) for 45 minutes at room temperature. Cells were rinsed twice with PBS and incubated with Alexa Fluor 633–conjugated goat anti-mouse antibody (10 µg/mL final concentration; Molecular Probes, Eugene, OR) for 30 minutes at room temperature. After washing twice with PBS, cells were resuspended in FITC-conjugated mouse IgG anti-cyclin B1 antibody solution (20 µL/test; BD PharMingen, San Diego, CA). Before analysis, cells were washed twice and stained with propidium iodide (PI) solution (5 µg/mL PI in PBS containing 0.1% Triton X-100 and 0.2 mg/mL RNase A). Samples were analyzed on a Becton Dickinson (Heidelberg, Germany) FACScan, and the data were analyzed using CellQuest software. Each experimental point is done in duplicate and the results have been confirmed at least in three independent experiments.

RNA Preparation
For each collection point, the cell monolayer (15 x 10⁶ cells) was washed twice with PBS at 4°C and total RNAs were extracted using the RNeasy Midi kit (Qiagen, Valencia, CA) according to the manufacturer's instructions.

Microarray Assay
RNA targets (biotin-labeled RNA fragments) were produced from 5 µg total RNAs by first synthesizing double-stranded cDNA followed by an in vitro transcription reaction and a fragmentation reaction. An hybridization mixture containing the cRNA fragments, probe array controls (Affymetrix, Inc., Santa Clara, CA), bovine serum albumin, and herring sperm DNA was prepared and hybridized to human cancer G110 arrays, containing 1,700 cancer-associated genes (Affymetrix) at 45°C for 16 hours. The hybridized probe array was then washed. Bound biotin-labeled cRNA was detected with a streptavidin-phycoerythrin conjugate. Subsequent signal amplification was done with a biotinylated anti-streptavidin antibody. The washing and staining procedures were automated using the Affymetrix fluidics station. Each human cancer G110 array was scanned once using a Hewlett-Packard (Palo Alto, CA) GeneArray scanner. Each RNA preparation was hybridized to duplicate chips.

Microarray Data Analysis
Low-level data analysis was done using MAS version 5.0 software (Affymetrix.) by running absolute analyses on each array and comparative analyses between pairs of arrays hybridized with control and treated cells, respectively. All arrays were scaled to a mean gene expression intensity of 300. Detailed descriptions of the analysis algorithms have been published (19, 20). Briefly, absolute analyses provide an estimate of the expression intensity ("signal") of each gene as well as a variable, called "detection," which determines whether the gene can be considered as expressed ("P" for "present" and "M" for "marginal") or not ("A" for "absent"). Comparative analyses identify modulated genes ("change" variable set at "I" or "MI" for up-regulation and at "D" or "MD" for down-regulation associated with significant "change Ps"). Comparative analyses also provide estimates of the expression intensity ratios for each gene studied between the pairs of hybridized arrays being compared. The ratios are expressed in base 2 logarithmic scale and are called "signal log ratios."

For cluster analysis, only genes whose expression was significantly modulated in at least one of the conditions studied were retained. The following criteria were used: expression modulations (as determined by the "change" variable) had to be reproduced in at least one comparative analysis, and the signal log ratios had to be above 1 in at least one comparison. In addition, only genes whose normalized expression intensity was at least 20 in one sample were considered. Finally, genes whose expression was undetected ("detection" equal to "A") in both treated and control samples in >75% of the comparisons were excluded. Cluster analysis was done on signal log ratios values weighed by the associated "change P." Hierarchical clustering was obtained by calculating similarity between genes as the Jaccard correlation and grouping following the average linkage algorithm (unweighted pair group method with arithmetic mean) using the GeneMaths software package (Applied Maths, Inc., Austin, TX).

Western Blot Analysis
Cells (5 x 10⁶) were washed with ice-cold PBS and incubated with 750 µL cold lysis buffer (50 mmol/L Tris, 120 mmol/L NaCl, 0.5% NP40, protease inhibitor cocktail) for 10 minutes on ice. Whole-cell lysates were clarified by centrifugation at 4,000 rpm for 15 minutes at 4°C. Samples (50 µg/condition) were heated in SDS sample buffer for 5 minutes at 95°C, run on 4% to 20% Tris-glycine gel (Novex, Invitrogen, Carlsbad, CA), and transferred to polyvinylidene difluoride membranes (Amersham Biosciences, Little Chalfont, United Kingdom) using the Mini-Gel blot module (Invitrogen). Membranes were blocked for 1 hour at room temperature with 5% bovine serum albumin in TBS [10 mmol/L Tris (pH 7.6) and 150 mmol/L NaCl] and then probed with anti-cyclin A (Neomarkers, Fremont, CA), anti-cyclin B1 (Neomarkers), anti-CDK1 (Cell Signaling, Beverly, MA), anti-phosphorylated CDK1 (Cell Signaling), anti-CDC25C (Cell Signaling), or anti-actin (Santa Cruz Biotechnology, Santa Cruz, CA) antibodies overnight at 4°C. Incubation with the appropriate peroxidase-coupled secondary antibody and subsequent detection by enhanced chemiluminescence were done as recommended by the manufacturer (New England Biolabs, Ipswich, MA). Protein levels were quantified using GeneTools analysis software (Syngene, Inc., Frederick, MD).

Immunofluorescence Staining
Cells were fixed in 70% ethanol for 15 minutes at 4°C and rinsed twice with PBS. Cells were then permeabilized for 10 minutes at 4°C in PBS containing 0.25% Triton X-100, washed twice with PBS, and incubated with PBS containing 1% bovine serum albumin. Primary antibodies were added for 1 hour at room temperature. After washing twice with PBS, cells were incubated with Alexa Fluor 633–conjugated goat anti-mouse antibody (10 µg/mL final concentration) for 30 minutes at room temperature. Before analysis, cells were washed twice and stained for 20 minutes at room temperature with PI solution (5 µg/mL PI in PBS containing 0.1% Triton X-100 and 0.2 mg/mL RNase A). After washing twice with PBS, slides were analyzed with a Zeiss (Thornwood, NY) LSM410 confocal laser scanning microscope.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Cell Cycle Phase Distribution following Oxaliplatin or Cisplatin Treatment
To determine the effective drug concentrations, HCT-116 cells were treated with various concentrations of oxaliplatin and cisplatin for 24 hours before a 12 h-thymidine pulse. In agreement with previously published data (6), both drugs inhibited HCT-116 proliferation with oxaliplatin more potent than cisplatin (i.e., its IC₅₀ was 0.4 versus 1.2 µmol/L for cisplatin). Cell growth inhibition by oxaliplatin remained almost the same from 1 to 5 µmol/L (90% of inhibition), whereas the inhibition induced by cisplatin only reached that high level at 5 µmol/L (data not shown). This indicated that oxaliplatin was 5-fold more potent in inhibiting DNA synthesis than was cisplatin. Doses from 1 to 10 µmol/L of both drugs have been used to study the effects of cisplatin and oxaliplatin on the cell cycle and the comparison between the two drugs has been done with 1 µmol/L oxaliplatin and 5 µmol/L cisplatin.

To investigate the effects of oxaliplatin and cisplatin on cell cycle progression, HCT-116 cells were treated for 24 hours and analyzed by flow cytometry. The profiles (Fig. 1A ) show correlated dual-variable plots of cell count versus PI uptake after 24 h of treatment with 1 and 5 µmol/L of each drug. They indicated that 1 µmol/L oxaliplatin slightly increased the relative number of cells in the G₂-M phase (28% versus 22% for control cells) and decreased the relative number of cells in the S phase (4% for 1 µmol/L oxaliplatin versus 20% for control cells), although it had little effect on the cell population in G₁ (68% for 1 µmol/L oxaliplatin versus 58% for control cells). Under the same conditions, 5 µmol/L cisplatin increased the relative number of cells in G₂-M (43% for 5 µmol/L cisplatin versus 22% for control cells) but, contrary to oxaliplatin, it increased the relative number of cells in the S phase (36% for 5 µmol/L cisplatin versus 20% for control cells) and decreased the number of cells in G₁ (19% for 5 µmol/L cisplatin versus 58% for control cells).

View larger version (41K): [in this window] [in a new window]   Figure 1. Effects of 24 h of oxaliplatin and cisplatin (1 and 5 µmol/L) treatment on the cell cycle of asynchronously growing HCT-116 cells assessed by fluorescence-activated cell sorting analysis. A, correlated dual-variable plots of cell counts versus PI uptake. G1, S, and G2-M cell populations. B, correlated dual-variable plots of MPM-2 versus PI uptake. Green, mitotic cells; framed, cells in the S phase. C, immunofluorescence staining of the nuclear membrane after 24 h of oxaliplatin or cisplatin (1 and 5 µmol/L) treatment. After treatment, cells were stained with PI (red fluorescence) and lamin B2 antibody plus Alexa Fluor 633–conjugated secondary antibody (green fluorescence) to visualize the nuclear integrity and nuclear membrane, respectively. Arrows, mitotic cells; asterisks, abnormal G1 cells.

Taken together, these data showed that cisplatin slowed down the replication phase and partially blocked cells in the G₂ phase, probably allowing aberrant mitosis. More interestingly, they showed that oxaliplatin strongly blocked cells in the G₁ and G₂ phases. Although they are close compounds, cisplatin and oxaliplatin did not alter cell cycle progression to the same extent, which suggests that oxaliplatin and cisplatin may have common and distinct mechanisms of action.

Oxaliplatin and Cisplatin Gene Expression Profiles
A global gene expression approach was used to identify cisplatin- and oxaliplatin-specific target genes. Using DNA chips containing 1,700 human cancer-related genes, we identified genes whose expression was dose dependently affected by oxaliplatin and cisplatin after 48 hours of treatment (shorter treatments did not give significant results). We compared gene expression profiles of HCT-116 cells treated for 48 hours with oxaliplatin and cisplatin concentrations ranging from 0.5 to 10 µmol/L. Below 0.5 µmol/L drug, we did not detect any RNA modulations. Gene expression profiles were analyzed using hierarchical clustering (Fig. 2 ). Of these genes, 117 were significantly modulated (see Materials and Methods for the selection criteria). Modulated genes can be subgrouped within three subclusters: (A) 37 genes dose dependently up-regulated by both drugs, (B) 42 genes dose-dependently down-regulated by both drugs, (C) and 38 drug-specific gene modulations. Tables 1 , 2 and 3 show the major significantly modulated genes from subclusters A, B, and C, respectively, and their functional assignments. Subcluster A contained proapoptotic genes, such as Bax, Bak, and Fas/Apo-1. Among these genes, oxaliplatin-induced modulations of Bax and Bak have already been reported (17). This subcluster also contained the WAF-1/p21 gene, which is involved in cell cycle progression and has already been described as up-regulated in response to cisplatin treatment (22). Subcluster B included histone H1, retinoblastoma 1, and catenin 1. Histone H1 is necessary for the condensation of nucleosome chains into higher order structures; retinoblastoma 1, a nuclear protein, is a potent inhibitor of E2F-mediated transactivation; and catenin 1 associates with the cytoplasmic domain of a variety of cadherins. Subcluster C revealed that cisplatin and oxaliplatin induced distinct gene modulation patterns. It contained genes strongly down-regulated by oxaliplatin, whereas they were either up-regulated or unaffected by cisplatin. What really matters is that the pattern of inverse response remained valid for the 1 µmol/L oxaliplatin versus 5 µmol/L cisplatin comparison (Fig. 2, framed). From this subcluster C, some cell cycle–related genes were involved in the G₂-M transition (i.e., cyclin B, CDC25C, and CDK1) or in the duplication phase (i.e., CDC6, cyclin A, replication protein A, replication factor C, and primase). Ki-67, the nucleolar proliferation marker, also belonged to subcluster C, such as B-Myb, another nuclear protein involved in cell proliferation. Several genes involved in the DNA replication (i.e., P1-Cdc21, Cdc7-related kinase, and thymidine kinase) were also inversely regulated by cisplatin and oxaliplatin. In addition, we observed modulation of centromere protein A and nucleosome assembly protein 1. Centromere protein A is a histone H3-like protein that is an essential component of centromeres and specifies the mitotic behavior of chromosomes, and the nucleosome assembly protein 1, a histone chaperone that mediates assembly proteins, participates in DNA replication and contributes to regulation of cell proliferation.

View larger version (42K): [in this window] [in a new window]   Figure 2. Hierarchical clustering of gene expression data measured after 48 h of oxaliplatin and cisplatin treatment. The single-dimension clustered gene expression measured from G110 array analyses using Jaccard correlation and algorithm unweighted pair group method with arithmetic mean. Row, a separate gene; column, a treated sample hybridized onto an array. Green scale, down-regulation; red scale, up-regulation; white scale, no change. Data are relative to untreated cells. Right, subclusters A, B, and C. Underlined, comparison of 1 µmol/L oxaliplatin versus 5 µmol/L cisplatin.

Protein Expression in HCT-116 Cells following Oxaliplatin or Cisplatin Treatment
Cell cycle–related gene modulations were further investigated at the protein level. As shown in Fig. 3A and Table 4 , the protein levels were correlated with the mRNA modulations: the cyclin A, cyclin B, CDK1, and CDC25C protein expressions were unchanged or slightly repressed by 24 hours of oxaliplatin (1 µmol/L) treatment, strongly repressed after 48 hours of oxaliplatin (1 µmol/L) treatment, and either unaffected or slightly enhanced by 24 and 48 hours of cisplatin (5 µmol/L) treatment. As CDK1 activity is regulated by phosphorylation, we used an antibody targeting the CDK1 phosphorylated form (Tyr¹⁵). The results showed that expression of the phosphorylated form was down-regulated by 48 hours of oxaliplatin treatment (P-CDK1/actin ratio of 0.16 for 1 µmol/L oxaliplatin; Table 4) and slightly up-regulated by 48 hours of cisplatin treatment (P-CDK1/actin ratio of 1.59 for 5 µmol/L cisplatin; Table 4). As cyclin B is one of the key proteins in the G₂-M transition, we measured its expression by flow cytometry (Fig. 3B). Figure 3B shows a significant decrease in cyclin B expression following treatment with 1 µmol/L oxaliplatin compared with untreated cells. By contrast, in the same conditions, 5 µmol/L cisplatin increased cyclin B expression of cells in the G₂-M phase. These results are visible after 24 hours of treatment but stronger after 48 hours.

View larger version (29K): [in this window] [in a new window]   Figure 3. Protein expression of cell cycle–related genes. A, Western-blotting. Cyclin B, cyclin A, CDK1, P-CDK1, CDC25C, and actin protein levels in HCT-116 cells after 24 and 48 h of treatment with 1 and 5 µmol/L oxaliplatin or cisplatin and control (C). B, flow cytometry. Correlated dual-variable plots of cyclin B versus PI uptake. HCT-116 cells were treated for 24 and 48 h with 1 and 5 µmol/L oxaliplatin and cisplatin.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Activation of cell cycle checkpoints is a general cellular response following exposure to cytotoxic agents. These checkpoints arrest cells at the G₁-S or G₂-M transitions. Previous studies indicated that cisplatin and other platinum agents predominantly reduce the rate of DNA synthesis (10, 12) and inhibit cell cycle progression at the G₁-S and/or G₂-M phases (12, 25). Here, we show, in agreement with previously published data (10, 12, 25), that cisplatin slowed down cells in the S phase and disturbed the G₂-M transition. More interestingly, our results indicated that in HCT-116 cells, oxaliplatin strongly blocked cells in the G₁ and G₂ phases. The fact that cisplatin and oxaliplatin had different effects on cell cycle progression suggests that the two drugs do not have the same mechanism of action.

In this study, we analyzed the effects of cisplatin and oxaliplatin at the gene expression level. We have an anticancer drug transcriptional signature database with several cytotoxic agents, including antimetabolite agents (methothrexate and 5-fluorouracil), alkylating agents (melphalan, oxaliplatin, and cisplatin), and topoisomerase inhibitors (camptothecin, doxorubicin, and etoposide). Hierarchical clustering of anticancer drugs showed that cisplatin and oxaliplatin were grouped together, close to the alkylating agent melphalan (data not shown). This was in accordance with the fact that cisplatin and oxaliplatin belong to the same drug family and are also alkylating agents. As expected, the signatures of cisplatin and oxaliplatin had common features (Fig. 2). Modulations of genes involved in the apoptosis response, such as Bax and Fas, are part of this platinum signature, indicating a common cell death mechanism. The hierarchical clustering elicited a cluster of 38 genes that could help to differentiate the effects of oxaliplatin and cisplatin as they are specifically modulated by cisplatin or oxaliplatin. Cell cycle–related genes are included in this cluster. Previous studies showed that these cell cycle–related genes share common sequences in their promoters: the CDE and CHR promoter elements (26). Moreover, these sequences have already been described as common regulators of these genes and involved in G₂-M arrest (26). Considering that this sequence is very rich in GC bases, altogether these data highly suggested that this promoter sequence has a key role in oxaliplatin-specific transcriptional signature and that these genes may be modulated by oxaliplatin.

The transcriptional study results and their validation at the protein level suggested that two different mechanisms are responsible for oxaliplatin- and cisplatin-induced G₂ transition control. Oxaliplatin induced a strong inhibition of CDK1 and cyclin B protein expression. It is now widely accepted that the G₂-M transition is partly governed by the CDK1-cyclin B complex. G₂ arrest associated with cyclin B repression has already been reported on treatment with adriamycin, etoposide, and irinotecan (27), suggesting that cyclin B repression is involved in the G₂ arrest mechanism induced by anticancer drugs. p21^waf1/cip1 exerts a key role in controlling the G₂ arrest by inhibiting the CDK1-cyclin B complex. Microarray analysis showed that, under oxaliplatin treatment, p21^waf1/cip1 RNA expression was up-regulated by 4.8-fold (only 1.6-fold activation with cisplatin treatment) as early as 6 hours of treatment (data not shown). We hypothesize that the p21^waf1/cip1 pathway may be involved in early events of the oxaliplatin-induced G₂ block. Absence of cyclin B and CDK1 after 48 hours of oxaliplatin treatment may be involved as late events in the establishment of a very strong arrest of cells in G₂ phase by oxaliplatin. Cisplatin treatment did not decrease the CDK1 or cyclin B protein level, rather cisplatin-induced G₂ arrest was correlated with a slight accumulation of both proteins. It has been widely shown that the phosphorylation of CDK1 on Tyr¹⁵ by CDC25C (28) inactivates the CDK1-cyclin B complex, which blocks M-phase entry. Considering the total amount of CDK1 (P-CDK1 and CDK1) in our study, the CDK1 phosphorylated form was not increased by cisplatin, suggesting that the CDK1 activity is not responsible for the G₂ blockage induced by cisplatin.

The results of the gene and protein expression analysis also enabled us to gain insight into the mechanism of action involved in the oxaliplatin-induced G₁ checkpoint. It is well known that the inhibition of cyclin A/CDK2 activity delays or prevents S-phase progression. In our experiments, the expression of cyclin A and CDK2 RNAs drastically decreased only after 48 hours of treatment, suggesting that inhibition of cyclin A and CDK2 RNA expression may be a consequence of the G₁ arrest. The absence of cyclin A and CDK1 proteins after 48 hours of oxaliplatin treatment could contribute to maintain the G₁ arrest. Oxaliplatin also down-regulated genes encoding proteins involved in the initiation of DNA replication, such as CDC6 and primase, or in the progression of the DNA replication process, such as replication protein A and replication factor C, and this may also contribute to late blockage at the S phase entry.

A checkpoint response induced by cytotoxic agents can have both positive and negative effects on apoptosis (9, 29). It has been shown that disruption of the G₂ checkpoint control response elicited by cytotoxic agents often increases the cellular sensitivity to these drugs (9, 29, 30) because unbridled cell cycle progression in the presence of DNA damage is usually lethal. For this reason, components of the G₂ checkpoint response are potential targets for new chemotherapeutic agents. The relationship between the checkpoint response of the other phases of the cell cycle and the induction of apoptosis is less established (9, 29). It has been shown that G₁ checkpoint abrogation decreases drug sensitivity (31). This was supported by our results that showed that the G₁ checkpoint response was associated with increased sensitivity. Further studies should be carried out to examine whether the effect of oxaliplatin on the G₁ checkpoint is linked with the ability of oxaliplatin to bypass cisplatin resistance and/or how does it may increase the apoptotic consequences of its combination with other agents.

The greater efficacy of oxaliplatin compared with cisplatin (i.e., isocytotoxicity with fewer DNA/platinum adducts) does not always translate into clinical settings. Indeed, oxaliplatin at recommended doses shows only marginal clinical activity as a single agent in most human cancers, and this is seriously in cancers with known prevalent somatic or epigenetic mismatch repair deficiency (e.g., colon, ovarian, or endometrial cancers). Interestingly, in such tumors, mismatch repair-deficient phenotype is increasingly prevalent with tumor progression, although prospective clinical translational work has never been implemented to completely validate this insight (7).

An intriguing and positive characteristic of oxaliplatin is its marked preclinical and clinical synergy with a wide variety of anticancer agents, mainly antimetabolites, such as fluorouracil (32) or gemcitabine (33), but also with cisplatin (6). In most cases, these oxaliplatin-based combinations are superior to cisplatin-based combinations. This superiority is seen above and beyond the mismatch repair prevalence as it is the case with taxanes (34) or Vinca alkaloids (35). Preliminary work suggests that DNA synthesis (via the thymidylate synthase) and repair mechanisms (via the excision repair cross complementing 1) are also implicated in the synergy observed with 5-fluorouracil (36). The current data have been obtained in a wild-type functional p53 cell line. Our study has been extended to the p53-proficient A2780 cell line and the p53-deficient HT-29 cell line. Our results on the p53-proficient A2780 cell line confirmed the oxaliplatin-specific transcriptional signature. Our results also indicated that there was no oxaliplatin-specific transcriptional signature with the p53-deficient HT-29 cell line. These data support the fact that the G₂ cell cycle arrest associated with a decrease in cyclin A and B level is p53 dependent (26). The G₂ checkpoint activity seems to be a new and major differentiating factor between 1,2-diaminocyclohexane platinums and the other DNA alkylators, and it is probably linked to the nonrepairability of transcriptional gene sites associated with the G₂-M-related cyclins cascade. It could also explain the enhanced drug sensitivity to other anticancer agents acting on DNA or other targets when combined with oxaliplatin, such as 5-fluorouracil, gemcitabine, taxanes, etc., which act through cell cycle arrests at the G₁-S and/or M phases.

In summary, we showed for the first time that cells treated with cisplatin and oxaliplatin respond differently with regard to the genes that are modulated, suggesting two different mechanisms of action. We also showed that oxaliplatin was a strong and specific cyclin cascade G₂-M transition blocker and, to our knowledge, the first agent with such blocking specificity. Using a DNA array technology, we established the oxaliplatin and cisplatin transcriptional signatures in the HCT-116 human colon carcinoma cell line. We noted a platinum transcriptional signature and, in parallel and for the first time, observed cell cycle–related genes that were conversely regulated by oxaliplatin and cisplatin. These modulations were confirmed at the protein level. These results highly suggest that the cell cycle modifications induced by cisplatin and oxaliplatin are the result of distinct cellular mechanisms. Finally, the oxaliplatin-specific target genes that have been identified give clues for the mechanism of action of oxaliplatin. In addition, these genes could also be useful for evaluating and comparing the efficacy and molecular pharmacology of new platinum drugs. In this respect, the oxaliplatin-specific signature could be used to discriminate in vitro between cisplatin-like and oxaliplatin-like molecules. Further analysis are necessary to determine if these genes mediate the higher efficacy of oxaliplatin in combination with other agents compared with cisplatin based combinations.

	Acknowledgments

 
We thank Vjekoslav Dulic (CRBM-CNRS FRE2593, Montpellier, France) for interesting discussion.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 6/27/05; revised 6/30/06; accepted 7/12/06.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Woynarowski JM, Chapman WG, Napier C, et al. Sequence- and region-specificity of oxaliplatin adducts in naked and cellular DNA. Mol Pharmacol 1998;54:770–7.[Abstract/Free Full Text]
2. Saris CP, van de Vaart PJ, Rietbroek RC, Blommaert FA. In vitro formation of DNA adducts by cisplatin, lobaplatin, and oxaliplatin in calf thymus DNA in solution and in cultured human cells. Carcinogenesis 1996;17:2763–9.[Abstract/Free Full Text]
3. Rothenberg ML, Oza AM, Bigelow RH, et al. Superiority of oxaliplatin and fluorouracil-leucovorin compared with either therapy alone in patients with progressive colorectal cancer after irinotecan and fluorouracil-leucovorin: interim results of a phase III trial. J Clin Oncol 2003;21:2059–69.[Abstract/Free Full Text]
4. Woynarowski JM, Faivre S, Herzig MC, et al. Oxaliplatin-induced damage of cellular DNA. Mol Pharmacol 2000;58:920–7.[Abstract/Free Full Text]
5. Raymond E, Lawrence R, Izbicka E, et al. Activity of oxaliplatin against human tumor colony-forming units. Clin Cancer Res 1998;4:1021–9.[Abstract]
6. Rixe O, Ortuzar W, Alvarez M, et al. Oxaliplatin, tetraplatin, cisplatin, and carboplatin: spectrum of activity in drug-resistant cell lines and in the cell lines of the National Cancer Institute's Anticancer Drug Screen panel. Biochem Pharmacol 1996;52:1855–65.[CrossRef][Medline]
7. Raymond E, Chaney SG, Taamma A, Cvitkovic E. Oxaliplatin: a review of preclinical and clinical studies. Ann Oncol 1998;9:1053–71.[Abstract/Free Full Text]
8. Louvet C, de Gramont A. Role and value of oxaliplatin in metastatic colorectal cancers. Rev Med Interne 1997;18 Suppl 4:368–71s.
9. O'Connor PM, Fan S. DNA damage checkpoints: implications for cancer therapy. Prog Cell Cycle Res 1996;2:165–73.[Medline]
10. Salles B, Butour JL, Lesca C, Macquet JP. cis-Pt(NH3)2Cl2 and trans-Pt(NH3)2Cl2 inhibit DNA synthesis in cultured L1210 leukemia cells. Biochem Biophys Res Commun 1983;112:555–63.[CrossRef][Medline]
11. Sorenson CM, Eastman A. Influence of cis-diamminedichloroplatinum(II) on DNA synthesis and cell cycle progression in excision repair proficient and deficient Chinese hamster ovary cells. Cancer Res 1988;48:6703–7.[Abstract/Free Full Text]
12. Ormerod MG, Orr RM, Peacock JH. The role of apoptosis in cell killing by ciplatin: a flow cytometric study. Br J Cancer 1994;69:93–100.[Medline]
13. Nishio K, Fujiwara Y, Miyahara Y, et al. cis-Diamminedichloroplatinum(II) inhibits p34cdc2 protein kinase in human lung-cancer cells. Int J Cancer 1993;55:616–22.[Medline]
14. Hagopian GS, Mills GB, Khokhar AR, et al. Expression of p53 in cisplatin-resistant ovarian cancer cell lines: modulation with the novel platinum analogue (1R, 2R-diaminocyclohexane)(trans-diacetato)(dichloro)-platinum(IV). Clin Cancer Res 1999;5:655–63.[Abstract/Free Full Text]
15. De Las Alas MM, Aebi S, Fink D, et al. Loss of DNA mismatch repair: effects on the rate of mutation to drug resistance. J Natl Cancer Inst 1997;89:1537–41.[Abstract/Free Full Text]
16. Peltomaki P. Deficient DNA mismatch repair: a common etiologic factor for colon cancer. Hum Mol Genet 2001;10:735–40.[Abstract/Free Full Text]
17. Gourdier I, Del Rio M, Crabbe L, et al. Drug specific resistance to oxaliplatin is associated with apoptosis defect in a cellular model of colon carcinoma. FEBS Lett 2002;529:232–6.[CrossRef][Medline]
18. Fink D, Zheng H, Nebel S, et al. In vitro and in vivo resistance to cisplatin in cells that have lost DNA mismatch repair. Cancer Res 1997;57:1841–5.[Abstract/Free Full Text]
19. Liu WM, Mei R, Di X, et al. Analysis of high density expression microarrays with signed-rank call algorithms. Bioinformatics 2002;18:1593–9.[Abstract/Free Full Text]
20. Hubbell E, Liu WM, Mei R. Robust estimators for expression analysis. Bioinformatics 2002;18:1585–92.[Abstract/Free Full Text]
21. Vandre DD, Borisy GG. Anaphase onset and dephosphorylation of mitotic phosphoproteins occur concomitantly. J Cell Sci 1989;94:245–58.[Abstract/Free Full Text]
22. Burger H, Nooter K, Boersma AW, et al. Expression of p53, Bcl-2, and Bax in cisplatin-induced apoptosis in testicular germ cell tumour cell lines. Br J Cancer 1998;77:1562–7.[Medline]
23. Roberts JJ, Thomson AJ. The mechanism of action of antitumor platinum compounds. Prog Nucleic Acid Res Mol Biol 1979;22:71–133.[Medline]
24. Roberts JJ, Friedlos F. Quantitative estimation of cisplatin-induced DNA interstrand cross-links and their repair in mammalian cells: relationship to toxicity. Pharmacol Ther 1987;34:215–46.[CrossRef][Medline]
25. Nguyen HN, Sevin BU, Averette HE, et al. Cell cycle perturbations of platinum derivatives on two ovarian cancer cell lines. Cancer Invest 1993;11:264–75.[Medline]
26. Badie C, Itzhaki JE, Sullivan MJ, et al. Repression of CDK1 an other genes with CDE an CHR promoter elements during DNA damage-induced G₂/M arrest in human cells. Mol Cell Biol 2000;20:2358–66.[Abstract/Free Full Text]
27. Dan S, Yamori T. Repression of cyclin B1 expression after treatment with Adriamycin, but not cisplatin in human lung cancer A549 cells. Biochem Biophys Res Commun 2001;280:861–7.[CrossRef][Medline]
28. Nurse P. Universal control mechanism regulating onset of M-phase. Nature 1990;344:503–8.[CrossRef][Medline]
29. Shapiro GI, Harper JW. Anticancer drug targets: cell cycle and checkpoint control. J Clin Invest 1999;104:1645–53.[Medline]
30. Garber K. New checkpoint blockers begin human trials. J Natl Cancer Inst 2005;97:1026–8.[Free Full Text]
31. Siddik ZH, Hagopian GS, Thai G, et al. Role of p53 in the ability of 1,2-diaminocyclohexane-diacetato-dichloro-Pt(IV) to circumvent cisplatin resistance. J Inorg Biochem 1999;77:65–70.[CrossRef][Medline]
32. Raymond E, Buquet-Fagot C, Djelloul S, et al. Antitumor activity of oxaliplatin in combination with 5-fluorouracil and the thymidylate synthase inhibitor AG337 in human colon, breast, and ovarian cancers. Anticancer Drugs 1997;8:876–85.[Medline]
33. Faivre S, Raymond E, Woynarowski JM, Cvitkovic E. Supraadditive effect of 2',2'-difluorodeoxycytidine (gemcitabine) in combination with oxaliplatin in human cancer cell lines. Cancer Chemother Pharmacol 1999;44:117–23.[CrossRef][Medline]
34. Faivre S, Kalla S, Cvitkovic E, et al. Oxaliplatin and paclitaxel combination in patients with platinum-pretreated ovarian carcinoma: an investigator-originated compassionate-use experience. Ann Oncol 1999;10:1125–8.[Abstract/Free Full Text]
35. Monnet I, de Cremoux H, Soulie P, et al. Oxaliplatin plus vinorelbine in advanced non-small-cell lung cancer: final results of a multicenter phase II study. Ann Oncol 2002;13:103–7.[Abstract/Free Full Text]
36. Smith PF, Pendyala L, Leichman CG, et al. Concentration dependent oxaliplatin (OXA) modulation of ERCC-1 and XPA mRNA expression in oesophageal cancer patients. Proc Am Assoc Cancer Res 2002;43:922.

This article has been cited by other articles:

				R. I. Sharma and T. A.D. Smith Colorectal Tumor Cells Treated with 5-FU, Oxaliplatin, Irinotecan, and Cetuximab Exhibit Changes in 18F-FDG Incorporation Corresponding to Hexokinase Activity and Glucose Transport J. Nucl. Med., August 1, 2008; 49(8): 1386 - 1394. [Abstract] [Full Text] [PDF]

				N. Van Driessche, H. Alexander, J. Min, A. Kuspa, S. Alexander, and G. Shaulsky Global transcriptional responses to cisplatin in Dictyostelium discoideum identify potential drug targets PNAS, September 25, 2007; 104(39): 15406 - 15411. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Voland, C. Articles by Casellas, P. Search for Related Content PubMed PubMed Citation Articles by Voland, C. Articles by Casellas, P.