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Genome-Wide Screen Identifies Genes Whose Inactivation Confer Resistance to Cisplatin in Saccharomyces cerevisiae

Department of Cancer Genetics, Roswell Park Cancer Institute, Buffalo, New York

Requests for reprints: Ruea-Yea Huang, Department of Cancer Genetics, Roswell Park Cancer Institute, Elm and Carlton Streets, Buffalo, NY 14263. Phone: 716-845-4454; Fax: 716-845-1968; E-mail: raya.huang{at}roswellpark.org.

	Abstract

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To identify novel genes that mediate cellular resistance to cisplatin, we have screened the collection of Saccharomyces cerevisiae deletion strains. We have found reproducibly 22 genes/open reading frames (ORF), which when deleted, confer resistance to cisplatin at a concentration that is lethal to wild-type cells. Complementation of individual deletion strains with the corresponding wild-type gene abolished cisplatin resistance, confirming that specific gene deletions caused the resistance. Twenty of the genes/ORFs identified have not been previously linked to cisplatin resistance and belong to several distinct functional groups. Major functional groups encode proteins involved in nucleotide metabolism, mRNA catabolism, RNA-polymerase-II–dependent gene regulation and vacuolar transport systems. In addition, proteins that function in ubiquitination, sphingolipid biogenesis, cyclic AMP–dependent signaling, DNA repair, and genome stability are also associated with cisplatin resistance. More than half of the identified genes are known to have sequences or functional homology to mammalian counterparts. Some deletion strains are cross-resistant to selected cytotoxic agents whereas hypersensitive to others. The sensitivity of certain resistant strains to other cytotoxic agents suggests that our findings may point to particular drug combinations that can overcome resistance caused by inactivation of specific genes.

	Introduction

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Cisplatin is one of the most widely used anticancer drugs. The basis for the therapeutic effectiveness of cisplatin is not fully clear, but it is believed that cisplatin exerts its cytotoxic action by the formation of platinum-DNA adducts (1). Intrinsic and acquired resistance to cisplatin treatment is a major obstacle for the clinical use of this drug. This is particularly true for colorectal cancer, with fewer than 20% clinical responses when used alone or in combination with other agents (2, 3). Multiple mechanisms have been identified in vitro through biochemical studies (1, 4) to account for the development of resistance to cisplatin. These include decreased intracellular drug accumulation, inactivation by glutathione or metallothioneins, increased DNA repair, enhanced tolerance, enhanced replicative bypass, and defects in pathways modulating cell death. These in vitro mechanisms of cisplatin resistance, however, do not fully account for the observed clinical unresponsiveness of particular tumors to platinum-based chemotherapy (1). This may be due to the genomic instability of tumors, which gives rise to mutations or defects in multiple molecular pathways. Both gain-of-function and loss-of-function mutations can confer resistance to platinum compounds. The best known examples are the loss of DNA mismatch repair (MMR) genes, hMLH1, hMSH2, or hPMS2 (1, 4). MMR proteins function in recognition of damaged DNA adducts. Previous studies indicate that mutation or methylation-mediated silencing of these genes results in failure to recognize the adduct and propagate a signal to the apoptotic machinery, thereby producing low-level resistance to cisplatin (5). In addition, cisplatin treatment can enrich for malignant populations of cells that have lost DNA mismatch repair both in vitro and in vivo (4).

Gene knockout studies in Saccharomyces cerevisiae, Dictyostelium discoideum, and mammalian cells have identified several genes whose disruption results in resistance to cisplatin (4, 6–10). Some of the genes are conserved among different organisms. In addition to the MMR genes, defects in the steady-state levels of intracellular second messengers such as Ca²⁺, cyclic AMP (cAMP), cyclic guanosine 3',5'-monophosphate, sphingosine 1-phosphate/ceramide, and inositol polyphosphates may contribute to resistance (4). These studies have broadened our knowledge to include previously unsuspected mechanisms that control cisplatin sensitivity; however, a full description of the biochemical pathways that mediate the cisplatin-resistant phenotype is still needed. It is our goal to identify and characterize novel genes and/or molecular pathways that may contribute to cisplatin resistance.

Thus far, five of the MMR genes and six other genes (IXR1, PHR1, SKY1, MAC1, CTR1, and NPR2) have been identified as genes which, when deleted, contribute to cisplatin resistance in S. cerevisiae (7–10). The MAC1, CTR1 (9), and the NPR2 (10) genes were identified quite recently from two different transposon-insertional libraries, suggesting that additional genes remain to be found. The complete set of 4,637 viable gene deletion mutants generated by the Saccharomyces Gene Deletion Project (11) has been successfully used in several genome-scale studies to identify many new genes/pathways important for survival to various cellular insults (12–15). In this study, we screened the pool of deletion strains to identify additional genes that may contribute to cisplatin resistance. We have identified 20 genes not previously reported to modulate cisplatin resistance, as well as two previously reported to be involved in this process.

	Materials and Methods

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Yeast strains and media. Homozygous diploid deletion pool strains and individual haploid deletion strains (MATa met15-1 his3-11, 15 leu2-3, 112 lys1-1 ura3-1) generated by the Saccharomyces Gene Deletion Project (11) were obtained from Invitrogen (Carlsbad, CA) or EUROSCARF (Frankfurt, Germany). Standard yeast media and growth conditions were used (16). Yeast cultures were seeded from single colonies grown on yeast extract-peptone-dextrose (YPD) plates or synthetic defined yeast nitrogen base medium (SDM) supplemented with appropriate amino acids for the strain background at 30°C.

Chemicals. Yeast nitrogen base, yeast extract, peptone, and dextrose were purchased from Difco Laboratories (Detroit, MI). Cisplatin, doxorubicin, 5-fluorouracil (5-FU), camptothecin, and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) were obtained from Sigma-Aldrich (St. Louis, MO) or LKB laboratory (St. Paul, MN). Stock solutions were prepared as follows. Cisplatin was prepared in DMSO (330 mmol/L), stored as aliquots at –20°C, and used within 2 weeks. This was further diluted in 0.9% NaCl (3.3 mmol/L) before adding to the medium. Doxorubin (10 mg/mL), camptothecin (15 mmol/L), and MNNG (10 µg/mL) were in DMSO and 5-FU (10 mg/mL) in water and were stored at –20°C. All plates were made in SDM and stored in the dark and used within 24 hours.

High throughput cisplatin resistance screen. A one-step selection method was used to screen the pool of deletion strains to isolate mutants that grew on SDM plates containing high concentrations of cisplatin. A lethal concentration of cisplatin to the parental strain, BY4743, was first determined as 160 µmol/L using a colony formation assay on SDM plates. Subsequently, 1 x 10⁵ cells in the pool of deletion strains were screened twice. Resistant colonies with various sizes were observed after 3 days of growth at 30°C.

Confirmation of cisplatin resistance by semiquantitative spot assay. Putative cisplatin-resistant colonies were picked and grown overnight in liquid YPD at 30°C. Cultures were then diluted to a concentration of 5 x 10⁶ cells/mL, and additional 5-fold dilutions were made. One microliter of each dilution was spotted onto SDM plates containing no cisplatin or 80 to 160 µmol/L of cisplatin and grown at 30°C for 3 days. The spot intensity for each strain was determined using densitometry (Alpha imager, Alpha Innotech, Sanleandro, CA) and was divided by the spot intensity of the corresponding untreated strain to determine the percent survival. The fold resistance relative to the wild-type parental cells was calculated using the percent cell survival in each spot at a drug concentration that the wild-type cells retained 30% survival. Colonies that exhibited at least 1.5-fold resistance to cisplatin were subjected to clone identification. Two to three independent spot assays were done.

Clone identification. Genomic DNA from the candidate colonies that passed the retest were isolated and subjected to sequencing for their barcode identity. To obtain barcode sequences, the region containing the UPTAG and a portion of the KanMX cassette was amplified by PCR using the common primer U1 and a KanMX primer. The identity of each clone was identified by matching to the open reading frame (ORF) deletion primer sequences from the Saccharomyces Genome Deletion Project.¹

Complementation test. The low-copy yeast vector pRS416 containing centromere and the URA3 auxotrophic marker was used to carry the wild-type genes to complement the deletion strains. The region of the chromosome containing the gene and an upstream region (500 bp) including the endogenous promoter were PCR amplified from BY4743 genomic DNA. The sequences of the primers used will be made available upon request. The PCR products were cloned into pRS416 vector using the primer restriction sites and sequenced to ensure correct gene insertion. The constructs and the empty vector were introduced into the yeast deletion strains using the EZ transformation kit (Epicenter, Madison, WI) and plated on SDM plates without uracil. To test for cisplatin sensitivity, transformants were grown overnight in SDM without uracil and serial dilutions were spotted on plates with or without cisplatin.

Cross-sensitivity to cytotoxic agents. The approximate concentrations of each drug to obtain 30% survival relative to untreated cells was determined for wild-type strain, BY4741, and used for comparison with the haploid deletion strains. Diluted cultures were spotted in duplicate on plates with or without drugs as described above. Percentage cell survival for each drug is expressed relative to untreated cells (100%).

	Results and Discussion

Top Abstract Introduction Materials and Methods Results and Discussion Conclusions References

 
Identification of novel yeast genes that, when deleted, confer resistance to cisplatin. To identify novel genes that may contribute to cisplatin resistance, we did two genome-wide screens of the pooled set of 4637 Saccharomyces cerevisiae diploid gene deletion mutants. We used a one-step selection method, which selected for strains that grew on plates containing a concentration of cisplatin that is lethal to wild-type cells. Colonies of various sizes were observed and arbitrary grouped into large, medium, and small; 133 and 137 of the large and medium size colonies were recovered in the first and second screens, respectively. In addition, >200 small colonies were also found in each of the screens. All of the large, medium, and 60 of the small colonies from each screen were retested for resistance to cisplatin by spotting diluted cells onto medium containing 80 to 160 µmol/L cisplatin. The relative survival of each clone compared with that of the wild-type strain was determined (Material and Methods). Figure 1 shows an example of a plate in which most colonies passed the retest (i.e., R2-R7). We found that 353 of 390 colonies retested were at least 1.5-fold resistant to cisplatin compared with wild-type cells. A cutoff of 1.5-fold was chosen because 1.5- to 3-fold resistance is frequently seen clinically and is sufficient to reduce tumor responsiveness to cisplatin in vivo (17).

View larger version (68K): [in this window] [in a new window]   Figure 1. Retest of cisplatin sensitivity. Parental strain (WT, BY4743) and several putative cisplatin resistant colonies (R1-R7) were grown in YPD overnight at 30°C. Dilutions of the cultures (a, 1 x 104 and b, 1 x 103) were spotted in duplicate (bracket) on SDM plates with or without 160 µmol/L of cisplatin and incubated at 30°C. Map of the strains corresponding to the spots on the plates. Photographs were taken 3 days after spotting. The test was repeated twice for each colony.

snf6

bul1

esc2

View larger version (73K): [in this window] [in a new window]   Figure 2. Confirmation of cisplatin resistance of individual deletion strains. A, exponentially growing deletion strains were diluted to an A600 nm of 0.25. Cells were then serially diluted, and 5,000 (cell # a) and 1,000 (cell # b) cells were spotted onto SDM plates without or with 100 to 160 µmol/L of cisplatin. A total of 42 deletion mutants and the parental wild-type strain (WT, BY4741) were tested. Plates were photographed after 48 hours of incubation at 30°C. Representative pictures from plates with 140 µmol/L of cisplatin. B, percentage survival (%) of strains shown in (A) is expressed relative to untreated cells. Columns, densitometry measurements of the cell # a and averages of at least three independent experiments; bars, SD.

fcy2, hpt1, nmd2

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View larger version (54K): [in this window] [in a new window]   Figure 3. Complementation of selected deletion strains resistant to cisplatin. The haploid deletion strains were transformed with pRS416 carrying the corresponding wild-type gene or with empty pRS416 vector. Five-fold serial dilutions of 6 x 104 log-phase cells were spotted in duplicate on SDM plates without (– cisplatin) or with (+ cisplatin) 140 µmol/L of cisplatin. For expressing the wild-type genes in the deletion mutants, uracil was omitted in plates for selection of the URA3 gene in pRS416 (– uracil). Plates were incubated at 30°C for 48 hours. Representative of three independent tests.

Among the genes identified, deletion of the FCY2 gene, a purine-cytosine permease, which also transports protons through the plasma membrane (19), was found most frequently. A related gene, HPT1, encoding the hypoxanthine guanine phosphoribosyl transferase (19) was also identified multiple times (Table 1). Both Fcy2p and Hpt1p function in nucleotide metabolism, which involves de novo biosynthesis and the salvage of intracellular and extracellular nucleobases or nucleosides. The reasons that deletion of FCY2 or HPT1 genes confers cellular resistance to cisplatin are not readily apparent. It has been shown that mutation in the FCY2 gene results in resistance to purine and cytosine analogues and this was attributed to a defect in analogue transport. It is tantalizing to suggest that cisplatin resistance in fcy2 may result from a defect in cisplatin transport. Alternatively, the cisplatin resistant phenotype of fcy2 and hpt1 cells may be a result of deregulation of the de novo AMP biosynthesis pathway.

Another major group of genes identified comprises pathways involved in mRNA catabolism. These include the NMD2/UPF2 and UPF3 genes in the nonsense mRNA decay (NMD) pathway which degrades transcripts harboring premature signals for translation termination (20) and the SKI3 gene in a family of exosome-associated proteins which degrades mRNAs without translation termination codons (nonstop decay; ref. 21). Deletion of other genes (UPF1 and SKI8) in this pathway also confers resistance to cisplatin (Fig. 2). mRNA degradation controls an important aspect of gene expression and often serves as a surveillance mechanism that eliminates aberrant mRNAs and deleterious proteins in all eukaryotic cells (22). These genes also regulate normal transcripts (23, 24). It should be interesting to investigate how accumulated nonsense or nonstop transcripts and/or altered regulation of normal transcripts in these deletion strains contribute to their cisplatin resistant phenotypes.

Several of the genes identified encode proteins belonging to a network of transcription factors (YIL038C/NOT3, YDR463W/STP1, YHL025W/SNF6, YDR006C/SOK1, and YJL175W). The Not3p is a subunit of the CCR4-NOT complex (19), which is a global transcriptional regulator with roles in transcription initiation and elongation and in mRNA degradation. STP1 encodes a transcription factor (19), which is activated by proteolytic processing in response to signals from the plasma membrane sensor SPS (SSY1, PTR3, and SSY5) system for external amino acids (25). It regulates amino acid permease genes and may have a role in tRNA processing (26). SNF6 is involved in global regulation of transcription and is part of the SNF/SWI chromatin remodeling complex (19). YJL175W is a dubious ORF that overlaps the SWI3 gene which interact with SNF6. In addition, SPT20 (Supplementary Table S1) is a member of the SAGA (Spt/Ada/Gcn5 acetyltransferase) complex (19). These transcriptional complexes form a network in which some members of each complex interact genetically or physically in many cellular processes. SOK1 is a suppressor of protein kinase A, functioning in cAMP-dependent signaling (19). Protein kinase A activity has been related to cisplatin cytotoxicity in human cells (27). Interestingly, knockout of the RegA cAMP-phosphodiesterase in D. discoideum (28) has been found to result in cisplatin resistance. Another 13 genes involved in RNA processing, mainly of RNA-polymerase-II-mediated transcripts, were also found to contribute weakly to cisplatin resistance (Supplementary Table S1). Transcription factors such as SNF/SWI chromatin modifiers have been shown to facilitate DNA accessibility and repair in different pathways leading to the maintenance of genome integrity (29). It is possible that defects in genes involved in RNA-polymerase-II transcription result in deregulation of repairing the cisplatin-DNA adducts and consequently lead to increased genome instability and altered drug sensitivity.

The largest group of genes identified is involved in vacuolar and membrane transport (Table 1; Supplementary Table S1). These include YDR497C/ITR1, YHR012W/VPS29, YDR363W-A/SEM1, and YMR216C/SKY1. Transcriptional regulation of ITR1, a member of the sugar permease family, depends on the INO4 gene (30), which also confers resistance to cisplatin when deleted (Supplementary Table S1). VPS29 functions in vacuolar protein sorting and is involved in retrograde transport of proteins from endosomes to the trans-Golgi network (31). SEM1 encodes a regulator of exocytosis which also functions as a subunit of the 26 S proteasome (32). In addition, deletions of another 28 genes involved in vacuolar transport or membrane-trafficking pathways also exhibited low levels of resistance to cisplatin (Supplementary Table S1). These data suggest that both the Golgi-to-endosome and endosome-to-vacuole stages of transport play major roles in cisplatin cytotoxicity. Indeed, it has been shown that cisplatin-accumulating vesicles are associated with the Golgi apparatus (33, 34). Consistent with our findings, deletion of Golvesin, a Golgi-associated protein that putatively functions in vesicular membrane trafficking, results in cisplatin resistance in D. discoideum (28). The previously identified copper transporter CTR1 gene (9, 35) was not identified under our conditions, but one of the copper transporters, YLR214W/FRE1, encoding ferric reductase was detected in one of our screens (Supplementary Table S1). We have also found that deletion of genes encoding for regulators of various transporters confers resistance to cisplatin. These include the SKY1, PTK2, and NPR2 genes (Table 1; Supplementary Table S1). Sky1p and Ptk2p are members of two different kinase families and are involved in regulating polyamine transport (36). Other studies have shown that disruptions of the SKY1 and NPR2 (nitrogen permease regulator) genes confer resistance to cisplatin and doxorubicin (10, 37), and resistance to both drugs was confirmed here for the SKY1 mutant. However, it was shown that neither Sky1p nor Npr2p is directly involved in the accumulation of cisplatin and doxorubicin (10, 37). It is possible that these regulators of transporters mediate intracellular drug transport to DNA.

Genes from several other pathways, such as ubiquitination (YMR275C/BUL1), cell wall biogenesis and architecture (YLR436C/ECM30), and DNA repair (IXR1) and genome stability (YOR144C/ELG1) also contribute to cisplatin resistance when deleted. Although only one gene from each of these pathways was found repeatedly in both screens, at least one other gene in the same pathway was identified in one of the screens. For example, BUL1, encoding a protein involved in mono-ubiquitination (19), was identified in both screens, whereas UBP13, UMP1, and UBI4, which also function in ubiquitination, were found in one of the screens (Supplementary Table S1). In addition, five ORFs with unknown function were also found in both screens and some of these ORFs reside within or overlap genes with known function. The cisplatin resistant phenotype of these mutants could be derived from the mutations of the known genes. For example, YGL214W overlaps with the SKI8 gene (19), which functions in mRNA catabolism, and deletion of SKI8 gene also confers cisplatin resistance (Fig. 2). In addition, YJL135W overlaps with YJL134W/LCB3, which functions in sphingolipid metabolism. Six other genes involved in lipid biogenesis were also identified in one of the two screens (Supplementary Table S1) suggesting that sphingolipid metabolism also plays an important role in cisplatin resistance. Studies in D. discoideum also found that disruption of sphingosine-1 phosphate (S1P) lyase confers resistance to cisplatin (28). Finally, the YDL173W protein has been found in the yeast two hybrid assay to interact with proteins, Sec17p and Sec4p, which function in vesicular transport (19). Deletion of the SEC4 gene was also found in one of the cisplatin resistance screens (Supplementary Table S1).

Whether the other gene products in these functional groups are also involved in cisplatin cytotoxicity remains to be determined. We expect that many more genes can be identified because more than two thirds of the small colonies found in the screens have not been tested. It is also possible that only a subset of genes in each pathway is required for cisplatin sensitivity. Very recently, Wu et al. (38) have used the oligonucleotide array approach to screen the same set of deletion mutants and found that deletions of 130 genes involved in diverse DNA repair pathways result in hypersensitivity to cisplatin. The same study also reported 100 strains that seemed resistant to cisplatin (Supplementary Data in ref. 38); however, the resistance of the individual strains has not been confirmed. Of these 100 deletion strains, only two were identified in our study. Different screening methods and cisplatin treatment procedures likely account for the discrepancy. Our method uses drug at a lethal concentration for the wild-type cells and screens for gene deletion strains that show enhanced resistance to the drug. Whereas this method can only, and maybe better, be used to identify genes whose deletion confers resistance to drugs, the oligonucleotide-array approach was optimized to identify sensitive strains. Our approach is straightforward and does not rely on the availability of the oligonucleotide arrays and special software for the analysis. Others have also used robot-aided screen of arrays of individual deletion strains to identify both bleomycin-hypersensitive and bleomycin-resistant mutants (39); however, this requires expensive instrumentation and resources.

	Conclusions

Top Abstract Introduction Materials and Methods Results and Discussion Conclusions References

 
It is well known that tumors may harbor many mutations or deletions. These alterations may result in low-level resistance where the survival and expansion of the malignant cell population occur during treatment. We have shown that a cisplatin resistance phenotype can be produced from defects in many different genes, some of which are quite specific for cisplatin among the agents tested, others of which also exhibit resistance to other agents. The genes identified here constitute novel components of a cisplatin resistance phenotype. Although some of the genes (or genes with related function) whose disruption have been found to mediate cisplatin resistance in D. discoideum, most of these have not been previously reported to mediate cisplatin resistance in yeast or humans. With RNA interference technology, it should be possible to determine whether knockdown of any of the human functional orthologues confers cisplatin resistance. In addition, future studies to investigate whether these genes are mutated or down-regulated in cisplatin-resistant tumor cells may also provide indications regarding the role that these genes play in cisplatin cytotoxicity in human cancers.

	Acknowledgments

 
Grant support: Roswell Park Alliance Foundation (R-Y. Huang) and NIH grants CA 107303-01 (R-Y. Huang) and GM30614 (D. Kowalski).

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.

We thank Dr. Joel Huberman for critical comments on the article and Wen-Qing Guo for technical help.

	Footnotes

 
Note: Supplementary data for this article are available at Cancer Research Online (http://cancerres.aacrjournals.org/).

¹ http://www-sequence.standford.edu/group/yeast_deletion_project/deletions3.html.

Received 11/15/04. Revised 4/14/05. Accepted 4/21/05.

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