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Telomere Length Abnormalities in Mammalian Radiosensitive Cells¹

Department of Biological Sciences, Brunel University, Kingston Lane, Uxbridge, Middlesex, UB8 3PH, United Kingdom [J. M., A. C., R. F. N., P. S.]; Radiation Effects Department, National Radiological Protection Board, Chilton, Didcot, Oxon, OX11 0RQ, United Kingdom [S. D. B.]; Department of Immunology and Oncology, Centro Nacional de Biotecnología- Consejo Superior de Investigaciones Cientificas, Madrid E-28049, Spain [E. S., M. A. B.]; Institute of Nuclear Chemistry and Technology, Department of Radiobiology and Health Protection, Dorodna 16, 03-195 Warszawa, Poland [A. W., I. S.]; School of Biology, St. Andrews University, St. Andrews, Fife, KY16 9TS, United Kingdom [P. E. B., A. C. R.]; and Ninewells Hospital, Dundee University, Dundee, Tayside, DD1 9SY, United Kingdom [A. T.]

	ABSTRACT

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Telomere lengths in radiosensitive murine lymphoma cells L5178Y-S and parental radioresistant L5178Y cells were measured by quantitative fluorescence in situ hybridization. Results revealed a 7-fold reduction in telomere length in radiosensitive cells (7 kb) in comparison with radioresistant cells (48 kb). Therefore, it was reasoned that telomere length might be used as a marker for chromosomal radiosensitivity. In agreement with this hypothesis, a significant inverse correlation between telomere length and chromosomal radiosensitivity was observed in lymphocytes from 24 breast cancer patients and 5 normal individuals. In contrast, no chromosomal radiosensitivity was observed in mouse cell lines that showed shortened telomeres, possibly reflecting differences in radiation responses between primary cells and established cell lines. Telomere length abnormalities observed in radiosensitive cells suggest that these two phenotypes may be linked.

	Introduction

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Telomeres are essential functional elements of the eukaryotic chromosomes responsible for chromosome stability maintenance (1) . In yeast, telomeres play a role in cellular responses to DNA-damaging agents such as IR,³ a potent inducer of DNA DSBs. DSB repair proteins, including Ku, are permanently present at yeast telomeres (2) , and they relocate to the site of DSB after exposure to IR (3 , 4) . Although it is not clear whether telomeres have the same role in other organisms, several lines of evidence indirectly link telomere maintenance and cellular response to IR in organisms as diverse as Caenorhabditis elegans and humans (see below). The first line of evidence is provided by the studies involving the human genetic disorders AT and NBS. AT patients show sensitivity to IR, a high incidence of cancer (5) , and a number of telomere-associated defects (6, 7, 8) . Similarly, NBS cells are radiosensitive, and the NBS protein is present at telomeres (9) . The second line of evidence is provided by mouse studies. Radiosensitive severe combined immunodeficiency mice deficient in DNA-PK, an enzyme complex consisting of Ku and DNA-PK catalytic subunit that is involved in V(D)J recombination and DSB repair, have abnormally long telomeres and a high frequency of TFs (10 , 11) . Similarly, radiosensitive Ku-deficient mice have a defect in telomere function as shown by high incidence of TF (12) . In addition, mice deficient in PARP are radiosensitive (13) and show telomere shortening accompanied by TF (14) . The third line of evidence is provided by a study of the C. elegans cell cycle checkpoint mutant, mrt-2. This mutant has critically short telomeres and high levels of TF, and it is hypersensitive to IR (15) . Taken together, these observations point to the possibility that telomeres may play a role in cellular, or even organismal, responses to IR. To test this possibility more directly, we examined chromosomal radiosensitivity and telomere length in normal mouse cells, in mouse lymphoma cell lines, and in human lymphocytes originating from breast cancer patients.

	Materials and Methods

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Tissue Culture.
All cells were grown under standard tissue culture conditions. LY-R and LY-S cells were grown in the Fischer’s medium, CB17 in Waymouth’s medium, and 3T3 in DMEM. All media were supplemented with FCS (10%) and antibiotics. Mouse splenocytes were obtained from BALB/c and SWR mice, and mitogen-stimulated (2 µg/ml^-1 concanavalin A and 25 µg/ml¹ lipopolysacchaide) cultures in RPMI 1640/20% FCS were set up as described (16) . Human lymphocytes were stimulated with phytohemagglutinin and grown for 72 h in RPMI 1640.

Chromosome Radiosensitivity Tests.
Four different tests were used: (a) chromosome painting for scoring translocations; (b) classical cytogenetic analysis for scoring dicentric chromosomes; (c) the MN test; and (d) the G₂ assay for scoring chromatid breaks and gaps induced in the G₂ phase of the cell cycle. For the first three tests, dose-response relationships were established using doses of 1.0, 2.0, and 4.0 Gy of rays. For the G₂ assay, doses varying from 0.2 Gy to 1.0 Gy were used, depending upon the cell type used. Chromosome painting was performed according to the instructions supplied by the manufacturer of mouse chromosome paints, Cambio. A Leica fluorescence microscope was used to observe painted chromosomes. Classical cytogenetic analysis involved the staining of metaphase figures with Giemsa and scoring dicentric chromosomes using light microscopy. Similarly, for the G₂ assay, chromosomes were stained with Giemsa and observed by using light microscopy. The MN test was performed according to the original protocol (17) , and micronuclei were scored using light microscopy. Irradiation was carried out either with a ¹³⁷Cs irradiator (CIS International) for the G₂ assay on human lymphocytes, or a ⁶⁰Co source for the tests involving mouse cells. Dose rates were 4.0 Gy/min and 0.25 Gy/min, respectively.

Q-FISH and Telomerase Detection.
Metaphase spreads were hybridized with the PNA telomeric oligonucleotide (CCCTTA)₃ labeled with Cy3 (PE Biosystems) as described (18) . Digital images were acquired using a Leica fluorescence microscope coupled with a Photometrics cooled CCD camera and Smart Capture software (Vysis). Telomere fluorescence intensity was analyzed using TFL-Telo software provided by Dr. Peter Lansdorp and Dr. Steven S. S. Poon (Terry Fox Laboratory, Vancouver, British Columbia, Canada). Telomere fluorescence intensity was expressed in TFUs according to a procedure described previously (18) . One TFU corresponds to 1 kb of telomere length (18) . At least 15 metaphase cells/sample were analyzed in Q-FISH experiments. Telomerase activity was measured using the telomeric repeat amplification protocol assay.

	Results

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Chromosomal Radiosensitivity and Telomere Length in Mouse Lymphoma Cells.
The mouse lymphoma LY-S cell strain was the first reported mammalian strain exhibiting a marked sensitivity to IR (19) . This strain was isolated from the parental radio-resistant lymphoma strain, LY-R, after spontaneous transformation in vitro (19) . The radiosensitivity of LY-S cells results from a deficiency in DSB repair (20) . However, the major mammalian DSB repair protein, DNA-PK, is functional in both strains⁴ , and the exact nature of DSB repair deficiency in LY-S cells remains unknown.

The aim of this study was to explore the relationship between cellular response to IR and telomere length. To monitor cellular response to IR, four chromosomal radiosensitivity tests were used (see "Materials and Methods"). In agreement with results published previously (21) , all tests confirmed that LY-S cells are significantly more radiosensitive than parental LY-R cells (not shown).

To analyze telomere length in these cells, Q-FISH (10 , 18) was used because conventional telomere measurements by Southern analysis may not be reliable in mouse cells (22) . The average telomere length in DBA mice from which LY-R cells had been isolated is 40 kb (18) . Telomeres in parental radio-resistant LY-R cells were 48 kb long (Fig. 1A and C) . In contrast, telomeres in radiosensitive LY-S cells were severely shortened, exhibiting an average length of 7.1 kb (Fig. 1, B and C) . Some chromosomes in LY-S cells lacked telomeric signals (see below), suggesting that telomeric sequences have been completely lost or are below the resolution of Q-FISH, i.e., 200 bp.

View larger version (109K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Telomere length and telomerase activity in mouse lymphoma cells. A, metaphase chromosomes from an LY-R cell (counterstain DAPI; telomere signal Cy3). B, metaphase chromosomes from an LY-S cell. C, average telomere length in LY-R and LY-S cells determined by Q-FISH. The difference in telomere length between LY-R and LY-S is statistically significant (t test; P < 0.001). D, telomerase activity in LY-R and LY-S cells. Mouse embryonic fibroblasts (MEFs) were used as control. Cell extracts were pretreated (+) or not (-) with RNase. Protein concentration used is indicated. An internal control (IC) for PCR efficiency was included.

Telomere Length and Chromosomal Radiosensitivity in Lymphocytes from Breast Cancer Patients.
The above results, together with observations of shortened telomeres in yku80 mutants, human AT cells, PARP-deficient mice, or C. elegans mrt2 mutant (see "Introduction"), suggest that short telomeres may be associated with cellular and/or chromosomal radiosensitivity. To investigate this possibility further, chromosomal radiosensitivity was assessed in lymphocytes from 24 breast cancer patients and 5 normal donors using the G₂ assay. Lymphocytes were exposed to 0.4 Gy rays, and frequencies of chromatid breaks and gaps, generated in the G₂ phase of the cell cycle, were determined. Telomere length was measured by Q-FISH in control nonirradiated samples from the same donors. The data (Fig. 2) show an inverse correlation between telomere length and chromosomal radiosensitivity in this group of patients. The correlation is statistically significant (r = 0.503; see Fig. 2 legend). A similar correlation has also been observed between telomere length and patient age⁵ . However, this correlation is weaker than the correlation between telomere length and chromosomal radiosensitivity. There was no correlation between radiosensitivity and donor age (not shown).

View larger version (12K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. G2 chromosomal radiosensitivity in 24 breast cancer patients and 5 normal individuals (expressed as numbers of breaks and gaps/100 cells; sampling time, 3 h after irradiation; dose, 0.4 Gy) and telomere length, estimated by Q-FISH, expressed in TFUs. The difference in average telomere length between the 24 breast cancer cases and the 5 normal individuals was not statistically significant, and consequently all samples were pooled together. A correlation analysis revealed a significant inverse correlation between chromosomal radiosensitivity and telomere length (Pearson 2 test, P < 0.01; Kendall’s test, P < 0.05; and Spearman’s test, P < 0.05). Donors’ ranged between 26 and 87 years of age. The age range of normal individuals was similar to that of breast cancer patients.

An earlier study has revealed shortened telomeres in the CB17 cell line (10) . The CB17 inbred strain from which this cell line originated is essentially BALB/c in its characteristics and genetic composition, although a small element of C57BL is present in the strain’s genome (23) . This cell line expresses telomerase⁶ and has no obvious phenotypic defect. Q-FISH revealed that telomere length in this cell line is, on average, 11 kb (Fig. 3A) . Some chromosomes in CB17 cells lacked telomeric signals completely (Fig. 3B) and were involved in TF (10) . The proportion of chromosomes lacking telomeric signals was comparable with that in LY-S cells (Fig. 3B) . BALB/c mouse splenocytes were selected as corresponding primary control cells because of their suitability for obtaining the metaphase spreads required for Q-FISH as well as subsequent radiation experiments that require short term in vitro culture (see "Materials and Methods"). The analysis of telomere length in primary splenocytes obtained from a BALB/c mouse revealed a normal telomere length of 50 kb (Fig. 3A) . As expected, all chromosomes in BALB/c splenocytes showed strong telomeric signals (Fig. 3B) and lacked TFs (not shown).

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Telomere length (A) and frequencies of chromosomes without detectable telomeric signal (B) in mouse cell lines. C/M, chromosomes/metaphase lacking telomeric signals. At least 10 metaphases/cell line were analyzed for determining C/M.

Chromosomal Radiosensitivity of Mouse Cells with Differing Telomere Length.
The response to IR was monitored in the above cell lines and in corresponding primary splenocytes using four chromosome radiosensitivity tests (Fig. 4) . None of the tests revealed statistically significant differences in response to IR between mouse cells with short telomeres and corresponding genetically normal cells (Fig. 4) . In some cases, frequencies of chromosome damage were slightly higher in cells with longer telomeres (Fig. 4C) . Comparison of sensitivity to IR in BALB/c and SWR cells did not reveal any statistically significant difference either (Fig. 4) , although these two types of mice are genetically different and have different telomere lengths (Fig. 3A) . Therefore, these results suggest that short telomeres and chromosomal radiosensitivity are not always associated.

View larger version (30K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Chromosome radiosensitivity in mouse cell lines and corresponding primary cells from the same genetic backgrounds. A, frequencies of dicentric (Dic) chromosomes. B, frequencies of translocations (T) involving chromosomes 2 and 11, identified by chromosome painting. C, G2 assay. Note that in the G2 assay, the frequency of chromatid breaks and gaps (B/G) declines with time after irradiation (dose used was 1.0 Gy). D, MN test. In all cases, at least two independent experiments were performed. In each experiment, at least 100 cells/point were analyzed. Results presented are the means from two experiments and are expressed on a per-cell basis. Statistical analysis did not reveal significant differences in response to IR between different cell types.

	Discussion

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On the basis of these observations, it was reasoned that telomere length might be used as a marker for chromosomal radiosensitivity. An inverse significant correlation between telomere length and chromosomal radiosensitivity in lymphocytes from breast cancer patients (Fig. 2) seems to support this hypothesis. Taken together, these data suggest that telomere length may be used as a potential diagnostic marker for detecting chromosomal radiosensitivity. There is a good correlation between G₂ chromosomal radiosensitivity and predisposition to breast cancer (24) . It will be of interest to analyze telomere length and telomere maintenance mechanisms in a larger number of breast cancer cases and in other types of cancer with the purpose of testing the above hypothesis more rigorously.

However, the analysis of mouse cell lines with short telomeres as the only obvious defect failed to confirm the correlation between telomere length and chromosomal radiosensitivity. Thus, short telomeres in themselves may not necessarily confer chromosomal radiosensitivity in vitro, at least in the case of acute -radiation exposure. Alternatively, telomeres in CB17 and 3T3 cells may not have been sufficiently shortened to significantly affect cellular response to IR. However, judging by similar frequencies of chromosomes without telomeres in LY-S, CB17, and 3T3 cells and subsequent formation of TF, indicative of the impairment of telomere function, this seems unlikely (Fig. 2) . Also, it is possible that in established cell lines, mechanisms that confer radiosensitivity may be different from those in normal primary cells. For, example, severe telomere shortening causes a p53-mediated apoptotic response (25) . Established mouse cell lines usually lose either p53 or p19^ARF (26) , and this could affect cellular radiation response by tolerating short telomeres. In addition, it should be noted that cell type (splenocyte/fibroblast) also may be influencing chromosomal radiosensitivity.

In conclusion, the observations presented here suggest that telomere length and chromosomal radiosensitivity are inversely correlated in some cases. This may reflect common pathways in DNA metabolism that affect both phenotypes. Additional research is required to exploit the potential clinical application of our finding.

	Note Added in Proof

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Two recent papers show the link between telomeres and radiosensitivity. Wong et al. Nat. Genet., 26:85–88, 2000 and Goytisolo et al. J. Exp. Med., 192: 1625–1636, 2000.

	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 by grants from the United Kingdom Coordinating Committee for Cancer Research (radiation program) and EUROATOM Grants FIGH-CT1999-00011 and FIGH-CT1999-00009 from the European Union (to P. S.). M. A. B.’s laboratory is funded by the Swiss Bridge Award 2000, Grants PM97-0133 from the Ministry of Science and Technology, Spain, 08.1/0030/98 from CAM, EURATOM/991/0201, and FIGH-CT-1999-00002 from the European Union and the Department of Immunology and Oncology. A. W. and I. S. are supported by a grant from the Stiftung fuer Deutsch-Polnische Zusammenarbeit.

² To whom requests for reprints should be addressed, at Department of Biological Sciences, Brunel University, Kingston Lane, Uxbridge, Middlesex, UB8 3PH, United Kingdom. Phone: 44 1895 274 000, extension 2109; Fax: 44 1895 274 348; E-mail: predrag.Slijepcevic{at}brunel.ac.uk

³ The abbreviations used are: IR, ionizing radiation; DSB, double-strand breaks; AT, ataxia telangiectasia; NBS, Nijmegen breakage syndrome; TF, telomeric fusion; PARP, poly(ADP-ribose) polymerase; LY-R, L5178Y cells; LY-S, L5178Y-S; MN, micronucleus test; Q-FISH, quantitative fluorescence in situ hybridization; TFU, telomere fluorescence unit.

⁴ Sochanowich and Szumiel, manuscript in preparation

⁵ J. McIlrath and P. Slijepcevic, unpublished observations.

⁶ P. Slijepcevic, unpublished results.

⁷ Sochanowicz and I. Szumiel, manuscript in preparation.

Received 9/ 8/00. Accepted 12/11/00.

	REFERENCES

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