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Persistent Genetic Instability in Cancer Cells Induced by Non-DNA-damaging Stress Exposures¹

Department of Radiation Oncology, Duke University Medical Center, Durham, North Carolina 27710 [C-Y. L., K. H., W. Z., L. Z., M. W. D., Q. H.], and Department of Cancer Biology, Harvard School of Public Health, Boston, Massachusetts 02115 [J. B. L.]

	ABSTRACT

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A hallmark of cancer cells is their pronounced genetic instability, which has been implicated in both tumor development and negative treatment outcomes. Recently, it has been reported that ionizing radiation may induce a persistent state of hypermutability in mammalian cells that lasts for many (>30) cell divisions. In this study, we examined whether other stress signals (both DNA-damaging non-DNA-damaging) can initiate a similar process. We show that persistent genetic instability was induced by nongenotoxic stress exposures such as heat treatment, serum starvation, or the tumor microenvironment, as well as genotoxic stresses such as ionizing radiation and exposure to hydrogen peroxide. Progeny of 10–20% of surviving cells exhibited persistent and pronounced genetic instability at both an artificially transfected gene and a genomic minisatellite locus 23 cell divisions after the initial exposure. Stress-induced persistent genetic instability may be a general response of tumor cells to a wide range of genotoxic or nongenotoxic stress conditions.

	Introduction

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Genetic instability has been implicated prominently in tumor development. The main evidence comes initially from the discovery of chromosomal aberrations and later from the identification of numerous mutations in key genes, oncogenes, or tumor suppressor genes, among almost all types of cancer. A tremendous amount of progress in the past 30 years has shed much light on how these mutations can affect a normal cell biochemically and/or genetically and render it carcinogenic. However, no definitive explanation is available as to how the mutations occur. It has been generally attributed to cellular exposure to chemical or physical agents that can damage DNA or random errors committed by the cellular DNA replication machinery (1) . According to this theory, the errors induced by the DNA-damaging agents or replication errors cause the cells to accumulate the "right" set of mutations in key genes over time to become carcinogenic eventually.

Although there is clear evidence that supports the prominent roles DNA-damaging agents play in carcinogenesis, a careful examination by authors of several earlier reports (2, 3, 4) led to a major dilemma: the mutation rate of cancer cells (10^-7–10^-5 cells/division; Ref. 1 ) cannot account for the multiple (seven to eight in the case of colon cancer) mutations that are required to occur in a single cell for the cell to become tumorigenic (5) . A "mutator" phenotype, therefore, has been proposed to be necessary for cancer development. The recent discovery that both sporadic and genetically predisposed colon cancer cells harbor as many as 10⁵ mutations individually further reinforces this idea. However, there is no direct evidence for the existence of a hypermutable state in cancer cells. The only exception occurs in cells that are deficient in mismatch repair (6) , although most cancer cells exhibit normal repair capacity when examined.

Recently, it has been observed that ionizing radiation can induce a persistent state of hypermutability in mammalian cells that lasts for many cell divisions after initial exposure (7 , 8) . Because of the potential importance of this discovery, we examined whether other stress signals, especially those that are non-DNA-damaging, can initiate a similar process in a murine tumor cell line. Our results indicate that stress-induced persistent genetic instability may be a general response of cancer cells surviving environmental stress exposure, whether genotoxic or nongenotoxic.

	Materials and Methods

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Cell Line and Tissue Culture Condition.
The 4T1 cell line used in this study was kindly provided by Dr. Fred Miller of the Michigan Cancer Foundation. It is derived from a spontaneously arising mammary carcinoma in a Balb/c mouse (9) . The cells were grown in DMEM with 10% heat-inactivated fetal bovine serum and penicillin (50 units/ml), and streptomycin (50 µg/ml).

EGFP⁴ Transduction and Selection for Stable Clones.
The 4T1 cells were transfected with a plasmid, pEGFP-N1, that constitutively expresses an enhanced version of the green fluorescence protein (Clontech, Palo Alto, CA; Ref. 10 ). The liposome DMRIE from Life Technologies, Inc. (Gaithersburg, MD) was used. A protocol recommended by the manufacturer was followed. G418 selection at 400 µmg/ml started 2 days after transfection. Two to 3 weeks later, colonies that grew out in Petri dish cultures were examined for GFP expression under a fluorescence microscope. Those that appeared to have robust GFP expression were picked, trypsinized, and expanded for Southern blot analysis. A single subclone with a single copy of GFP inserted at one site in the 4T1 genome was selected for subsequent experiments.

Stress Exposure of the Cells.
For ionizing radiation exposure, 10,000 tumor cells were plated in each 10-cm Petri dish 1 day before treatment. The dishes were then irradiated with 12 Gy of -rays at a dose rate of 8 Gy/min by use of a Cs-137 irradiator (J. L. Shepard and Associates). Surviving colonies were then selected for subsequent expansion and analysis. For heat exposure, 10,000 cells were plated into each 10-cm Petri dish 1 day before the treatment. The plates were completely wrapped with Parafilm before immersion. Only one-third of the whole dish was submerged, because there was only 5 ml of medium in the P-100 dish. The dishes remained submerged in the water bath with temperature controlled at 45°C for 30 min. Afterward, the dishes were thoroughly wiped in 70% ethanol and removed from Parafilm and then placed back into the incubator. The surviving colonies were then selected for subsequent expansion and analysis. For H₂O₂ exposure, 10,000 cells were plated into each Petri dish to be treated 24 h before treatment. H₂O₂ was then added to the dish at a concentration of 500 µM. The cells were exposed for 4 h, and H₂O₂ was removed together with the medium. The surviving colonies were then selected for expansion and analysis. For serum starvation treatment, cells grown to 80% confluence were incubated in serum-free medium for 7–8 days until >95% of the cells were killed. Normal fetal bovine serum-complemented medium was then added, and surviving colonies were selected for expansion and analysis. For growth in vivo, 10⁶ 4T1-GFP cells were injected s.c. into the right hind leg of syngeneic mice. Two to 3 weeks later, tumors with diameters of 1.0–1.5 cm formed and were excised. Tumors were then minced and digested with collagenase and plated out at low density. GFP-expressing clones were then selected for expansion and analysis.

Fluorescence Microscopy.
Visualization of GFP expression was carried out on a Zeiss Axioscope equipped with a 3CCD color camera. A computer equipped with a frame grabber was connected to the camera to capture images on-line. To visualize GFP-expressing cells, epifluorescence (xenon arc source and FITC filter) with or without concomitant trans-illumination (with a 40-W tungsten source) was used.

Isolation of Genomic DNA and Southern Blot Analysis.
Isolation of genomic DNA and Southern blot analysis was carried out according to an established protocol (11) . To carry out analysis for the inserted GFP gene, 10 µg of each sample were digested with BamHI (New England Biolabs, Inc. Beverly, MA) and electrophoresed at 3.3 V/cm for 6 h in 1% agarose gel. To conduct minisatellite analysis, 10 µg of each sample of DNA were digested with HinfI and separated in 0.8% agarose gels at 3.3 V/cm for 32 h. Then the gels for both GFP and minisatellite analysis were soaked in 0.25 M HCl for 20 min. Afterward, the DNA was transferred onto Nytran nylon membranes (Schleicher & Schull). The membranes were then UV irradiated and prehybridized for 3 h at 65°C in 6x SSC, 5x Denhardt’s solution, and 1% SDS. They were then hybridized with ³²P-labeled probes. For EGFP, the GFP encoding fragment from the pEGFP-N1 was used as the probe. For minisatellite analysis, a minisatellite probe, M, derived from the mouse MHC sequences (12) , was used. After hybridization, the membranes were washed three times in 6x SSC for 15 min at room temperature and then autoradiographed.

	Results

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Visualization of Persistent Genetic Instability at an Artificially Inserted GFP Gene Locus.
To monitor genetic instability in a direct and accurate manner, a murine mammary adenocarcinoma cell line, 4T1, was transduced with the EGFP-N1 plasmid, which encodes the EGFP gene under the control of the cytomegalovirus immediate-early promoter. After selection for stable expression of the GFP gene, a subclone was obtained that expresses GFP constitutively. All of the cells appeared uniformly green under a fluorescence microscope (Fig. 1a) . Southern blot analysis indicated that a single copy of the plasmid had integrated into the host genome (Fig. 1b) . Therefore, a loss of green fluorescence in any cells from this subclone would indicate a loss of gene expression, which in turn would indicate a potential mutation at the integrated GFP gene. The exact nature of the mutation can easily be determined by Southern blot analysis. Cells were subjected to exposure to various genotoxic and nongenotoxic stress conditions. There were six experimental groups: (a) a control group with no exposure; (b) two groups subjected to genotoxic exposures: ionizing radiation, 12 Gy, which kills >95% of the cells; and hydrogen peroxide exposure, 0.5 mM for 24 h, which kills >95% of the cells; and (c) three groups subjected to nongenotoxic exposures: hyperthermia, 45°C for 30 min, which kills over 95% of the cells; serum starvation, which deprives serum for 8–10 days and kills >95% of the cells; and growth as a tumor in vivo for 14–21 days and subsequent growth in cell culture.

View larger version (93K): [in this window] [in a new window]   Fig. 1. Stable transduction of the GFP gene into the 4T1 cell line. a, fluorescence photomicrograph of stably transduced 4T1 cells. b, Southern blot analysis of the transduced GFP gene. A single band was observed to be present on the Southern blot. Laser densitometry analysis indicate a single copy was inserted into the genome of the 4T1 cell.

View larger version (27K): [in this window] [in a new window]   Fig. 2. A selection scheme for clones of 4T1-GFP cells that have survived different exposure treatments.

View larger version (54K): [in this window] [in a new window]   Fig. 3. Fluorescent photomicrographs of 4T1-GFP clones with various GFP expression patterns. a and b, clones with no loss of GFP expression. c–f, "chimeric" clones with partial loss of GFP expression.

Another important question is whether there is any dosage threshold for the observed genetic instability. Although we did not carry out experiments to systemically determine the minimal dosage that was required to induce persistent genetic instability, we did treat the cells with lower doses of ionizing radiation (4 and 6 Gy, which kills about 60 and 80% of the cells, respectively) and heat (44°C for 30 min, which kills only 50% of the cells). Under these less lethal conditions, genetic instability at the GFP locus was still observed. There did not appear to exist a linear relationship between dose and the percentage of genetically unstable clones. Both 4 and 6 Gy of ionizing radiation produced a similar percentage (10–20%) of genetically unstable cells among the progeny cells. Both the lack of linearity and the percentage of genetically unstable clones are similar to what has been reported in an earlier study (15) . Heating at 44°C for 30 min produced a much lower (0.8%) frequency of mutation.

Persistent Genetic Instability at an Endogenous Minisatellite Locus.
To determine whether the observed genetic instability is present only at the artificially inserted GFP gene, a minisatellite probe, M, derived from the mouse MHC sequences (12) , was used to probe a subset of the colonies that showed a loss of the GFP gene from the stress-exposed cells. Such minisatellite probes, which detect multiple repetitive sequences at the same time, are a powerful tool for the determination of gross DNA changes at multiple loci (11 , 16 , 17) . Again, significant DNA rearrangements at the minisatellite loci detected by the M probe were observed among both the genotoxic and nongenotoxic stress-exposed groups (Table 3 and Fig. 4 ). The most common changes were deletions of certain fragments (Fig. 4 , Lanes 2, 3, 8, and 11). There are also new bands (Fig. 4 , Lane 6). Table 3 is summary of detected minisatellite rearrangements among different subclones from different groups. The prevalence of the minisatellite mutations is significant, with 16–30% of the randomly picked colonies possessing them. This rate of mutation is substantially higher than that observed for genes in conventional mutagenesis studies, although it is similar to what has been observed for radiation-induced, persistently hypermutable mammalian cells (15) .

View larger version (126K): [in this window] [in a new window]   Fig. 4. Minisatellite analysis of stress-exposed clones. Lane 1, a control clone. Lanes 2 and 3, two radiation-treated clones. Lanes 4 and 5, two heat-treated clones. Lanes 6 and 7, two H2O2-exposed clones. Lanes 8 and 9, two serum-starved clones. Lanes 10 and 11, two clones derived from in vivo grown tumors. Arrows, loss of a band. *, appearance of a new allele.

	Discussion

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The mechanisms involved in causing such persistently increased frequencies of mutations at the DNA level are unclear, although a checkpoint gene hBUB1 has been implicated for chromosomal instabilities (25) . The sporadic, random accumulation of mutations through defects or errors in repair mechanisms (generally yielding mutation rates ranging from 10^-7 to 10^-5/cell/division; Ref. 1 ) could not account for the occurrence of seven to eight oncogene/tumor suppressor mutations in the same cell, such as has been observed in many tumor types (2 , 5 , 22 , 26) . Furthermore, it is unlikely that the high frequency of genetically unstable clines (10–20%; Tables 1 and 3 ) we have observed could be explained by the induction of mutations in a specific mutator gene or set of genes in the cells surviving exposure to stress. The persistently increased mutation rate resulting from a stress-inducible state of persistent genetic instability similar to that reported in this study could, however, account for the accumulation of multiple mutations in cancer cells. Perhaps triggered by exposure to environmental mutagens or abnormal physiological conditions, this hypermutable state could cause mutations at many genomic loci in a normal cell. Because it can persist for many generations, critical mutations will emerge in a Darwinian fashion (25) over time to render the cell tumorigenic. That such a phenomenon may be involved in the early stages of carcinogenesis is evidenced by the occurrence of multiple mutations in colonic polyps early in tumor progression (23) . It is also very possible that this highly mutagenic process is active during the later stages of tumor development, perhaps even being perpetuated and sustained by the tumor microenvironment, which can be much harsher than the normal physiological conditions. An earlier report (13) and results from this study demonstrate this possibility. Finally, it is possible that the high rate of genomic deletion we observed for the GFP gene and the endogenous minisatellite locus are attributable to the fact that they are located in regions of the genome that is especially susceptible to DNA insertion or deletions (this may be the reason why GFP was inserted there in the first place). Our present experiments cannot determine whether this is true. However, examination of transgenic cells where the GFP gene is inserted at known loci with normal mutation rates (e.g., the HPRT gene; Ref. 27 ) may help answer these questions.

In summary, we have documented the existence of a general, stress-inducible genetic instability in cancer cells. Although the precise molecular mechanism is not clear, it is likely that the process is involved in the development of cancer.

	ACKNOWLEDGMENTS

 
We thank Dr. Fred Miller of the Michigan Cancer Foundation for providing the 4T1 cell line and Dr. Benoit Paquette of University of Sherbrooke, Sherbrooke, Quebec, Canada, for providing the plasmid encoding the M mouse minisatellite sequence.

	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.

¹ Supported in part by a start-up grant from the Department of Radiation Oncology, Duke University Medical Center, Grant CA81512 from the National Cancer Institute, and a grant from the Komen Foundation for Breast Cancer Research (to C-Y. L.). Q. H. was a Raychem/Duane/Roger/John Morris Fellow at the Duke Comprehensive Cancer Center.

² To whom requests for reprints should be addressed, at Department of Radiation Oncology, Box 3455, Duke University Medical Center, Durham, NC 27710. Phone: (919) 681-4721; Fax: (919) 684-8718; E-mail: cyli{at}radonc.duke.edu

³ Present address: No. 1 People’s Hospital, Shanghai, People’s Republic of China.

⁴ The abbreviation used is: EGFP, enhanced green fluorescent protein.

Received 8/14/00. Accepted 11/28/00.

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