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Polymorphisms in ER- Gene Interact with Estrogen Receptor Status in Breast Cancer Survival

¹ Division of General Internal Medicine, Department of Medicine, Center for Health Services Research, Vanderbilt Ingram Cancer Center, Vanderbilt University School of Medicine, Nashville, Tennessee; and ² Department of Epidemiology, Shanghai Cancer Institute, Shanghai, China

Requests for reprints: Xiao-Ou Shu, Center for Health Service Research, Vanderbilt University, Medical Center East, Suite 6000, Nashville, TN 37232-8300. Phone: 615-936-0713; Fax: 615-936-1269; E-mail: Xiao-Ou.Shu{at}venderbilt.edu.

	ABSTRACT

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Purpose: The effects of estrogens are mediated primarily through estrogen receptor (ER) in breast tissue, and polymorphisms in the ER genes may alter the functions of these receptors. Polymorphisms in the ER- gene have been reported to be associated with breast cancer risk. However, to our knowledge, no study has been published on the relation between ER- gene polymorphisms and breast cancer survival.

Experimental Design: To determine whether three common polymorphisms in the ER- gene, PvuII, XbaI, and GT dinucleotide repeats are associated with breast cancer survival, we evaluated data from a cohort of 1,069 breast cancer patients who participated in the Shanghai Breast Cancer Study between 1996 and 1998. The median follow-up time for this cohort of women was 5.2 years.

Results: No overall association was observed between ER gene polymorphisms and breast cancer survival. The genotype associations, however, were modified by ER status in breast cancer tissues. Comparing those with the PP genotype to the pp genotype of the PvuII polymorphism, the hazard ratios (HR) of dying were 3.30 [95% confidence interval (95% CI), 1.42-7.69] and 0.54 (95% CI, 0.24-1.23), respectively, for participants with ER-negative breast cancer and ER-positive breast cancer. Similarly, compared with those with no (GT)₂₃ alleles, carrying one or two (GT)₂₃ alleles of the GT repeat polymorphism was related to a HR of 1.48 (95% CI, 0.77-2.87) for ER-negative breast cancer and a HR of 0.25 (95% CI, 0.09-0.69) for ER-positive cancer. The effect of ER on breast cancer survival was also modified by genotypes of ER- gene. Tests for multiplicative interaction were highly significant.

Conclusions: These data suggest that the ER- gene polymorphisms and ER status may have an interactive effect on breast cancer survival.

Key Words: breast cancer • estrogen • progesterone • receptor • polymorphisms • survival

	INTRODUCTION

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Estrogens play a crucial role in the pathogenesis and progression of breast cancer. The effects of estrogens are mediated primarily through intracellular estrogen receptors (ER). To date, there are two known ERs, ER- and ER-ß. Both are nuclear receptor proteins that act as ligand-inducible transcription factors (1). ER- expression has been used in clinical practice as an indicator for selecting hormone therapy and loss of ER- expression is often associated with poor survival (2).

There are several known polymorphisms in the ER- gene, some of which alter the function of the receptor (1). Of the known polymorphisms, PvuII, XbaI, and the recently identified (GT)_n polymorphisms have been reported to be associated with breast cancer risk (3-8). PvuII and XbaI are located on intron 1, whereas the (GT)_n repeats polymorphism is located at 2.8 kb 5' to exon 1D (9). To our knowledge, no study has been published on the relation between ER- polymorphisms and breast cancer survival. The association of ER polymorphisms with breast cancer risk suggests that these polymorphisms may also affect breast cancer survival. However, it is difficult to extrapolate the findings from etiologic research to cancer prognosis for several reasons: (a) there is not enough evidence to conclusively determine the direction of the polymorphism association with breast cancer risk and (b) even if the associations with breast cancer risk were conclusive, it is not certain whether the polymorphisms would play the same role in breast cancer risk as breast cancer survival. In this report, we evaluated the association of three common polymorphisms in the ER- gene, PvuII, XbaI, and GT dinucleotide repeats with breast cancer survival in a cohort of breast cancer patients who were recruited as part of the Shanghai Breast Cancer Study, a population-based case-control study.

	MATERIALS AND METHODS

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Participants and Study Design. Through a rapid case ascertainment system and supplemented by the population-based Shanghai Cancer Registry, we identified 1,602 women who were between the ages of 25 to 64 years and were diagnosed with a primary breast cancer between August 1996 and March 1998. Of them, 1,459 (91.1%) completed an in-person interview and were included as cases in the Shanghai Breast Cancer Study. Reasons for nonparticipation included refusal (109 cases, 6.8%), death before interview (17 cases, 1.1%), and inability to locate (17 cases, 1.1%). The median time interval between diagnosis and interview was 66 days. The initial institutional cancer diagnoses were confirmed by independent review of pathologic slides by two senior pathologists. Blood samples (10 mL from each woman) were obtained from 1,193 (82%) cases who participated in the study. These samples were typically processed within 6 hours of collection and were stored at –70°C until the relevant bioassays were conducted. Information on cancer diagnosis, disease stage (tumor-node-metastasis stage), cancer treatments, and ER/progesterone receptor (PR) status was abstracted from medical charts using a standard protocol.

Patients were followed up through January 2003 with a combination of active follow-up and record linkage to the death certificates kept by the Vital Statistics Unit of the Shanghai Center for Disease Control and Prevention. Of the 1,459 patients included in the original study, 1,290 (88.4%) were successfully contacted either by home visit (n = 1,241, 85.0%) or by telephone (n = 49, 3.4%) from March 2000 to December 2002. Among them, 200 patients were deceased. Through interview of patients, or next of kin for deceased patients, we obtained information on disease progress, recurrence, quality of life, and cause of death (if deceased). Survival status for the remaining 169 participants who could not be contacted through a home visit or by telephone call was established in June 2003 by linkage to the mortality registry. Of them, 40 deaths were identified; information on the date of death and cause of death was obtained. Subjects (n = 126) had no match in the mortality registry and were assumed to be still living. Their censoring date was assigned to be December 31, 2002, 6 months before our search of the vital statistics registry, to allow for a possible delay of entry of the death certificates into the registry. Three subjects had insufficient information for the record linkage and were excluded from the current analysis. This study was approved by the Institutional Review Board of all participating institutes.

Laboratory Protocols. Determination of PvuII and XbaI Polymorphisms. Genomic DNA was extracted from buffy coat fractions. PvuII and XbaI genotypes were determined with PCR-RFLP method described previously (7). Briefly, the primers for analysis were 5'-CTGCCACCCTATCTGTATCTTTTCCTATTCTCC-3' (forward) and 5'-TCTTTCTCTGCCACCCTGGCGTCGATTATCTGA-3' (reverse). These primers generated a 1.3-kb fragment, and contain a part of intron 1 and exon 2 of the ER-gene. The PCR products were digested by the PvuII and XbaI restriction endonucleases, respectively. The DNA fragments were then separated using 1.5% agarose gel and detected by ethidium bromide staining. PP and XX, signifying the absence of restriction sites, gave one 1.3-kb fragment. pp, signifying the presence of PvuII restriction sites on both alleles, was digested into two fragments (0.85 and 0.45 kb). The xx genotype was revealed by XbaI digestion into two fragments (0.9 and 0.4 kb).

Determination of (GT)_n Polymorphism. Genotyping for the (GT)_n polymorphism was done by detection of fluorescent amplimers on an ABI PRISM 3700 automated DNA analyzer. Details of genotyping method have been described elsewhere (8). Briefly, the primers were forward 5'-gtgtCTGCTCAAATCTCCTCTG-3' and reverse 5'-GTTAAGAAGGGCCTTTAC-3'. The forward primer was labeled with 6-carboxyfluorescein. Allele fragment size estimation was accomplished using the internal size standard Genescan 400HD ROX and the Local Southern algorithm of GENESCAN software. Allele binding and adjustment of run mobility according to control alleles of Centre d'Etude du Polymorphisme Humain 1347-02 were accomplished by custom software. The number of (GT)_n repeats were confirmed by direct sequencing using BigDye Terminator Chemistry on an ABI PRISM 3700 automated DNA Analyzer.

The laboratory staff was blind to the identity of the subject. QC samples were included in genotyping assays. Each 96-well plate contains one water, two Centre d'Etude du Polymorphisme Humain 1347-02 DNA, two blinded QC DNA, and two unblinded QC DNA samples. The blinded QC samples were taken from the second tube of study samples included in the study.

Genotyping data for the (GT)_n polymorphism were obtained from 947 cases who gave blood samples. For the PvuII and XbaI polymorphisms, genotyping data were obtained from 1,069 cases who gave blood samples. The major reasons for incomplete genotyping were insufficient DNA used in the particular assays and unsuccessful PCR amplification.

Statistical Analysis. The primary outcome for this study was overall survival. Survival time was calculated as the time from cancer diagnosis to death, censoring at the date of last contact. The Kaplan-Meier method was used to compute 5-year survival rates, and the log-rank test was applied to test the differences in survival across different genotypes. The proportional hazard assumption was checked by log (–log) plots. The Cox regression model was applied to evaluate the effect of the ER- genotype on overall survival with adjustments for age at diagnosis and known prognostic factors for breast cancer, including tumor-node-metastasis status and cancer treatment. Stratified analyses by ER status and traditional breast cancer prognostic factors were done to examine potential interactive effects of these variables on the association between ER- genotype and breast cancer survival. Test for multiplicative interaction was conducted by including the main term and product of two study variables in the Cox regression model. All statistical tests are based on a two-sided probability.

	RESULTS

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Among subjects with genotype data (n = 1,063), ER status was obtained from 739 breast cancer cases. Of these, 62.4% were ER+ and 37.6% were ER–. Approximately 30.5% of cases were missing information on ER status. ER status was not significantly associated with 5-year survival in this study population. As expected, stage at diagnosis was an important predictor for overall survival (Table 1). Having radiotherapy was related to a higher mortality. Patients who received radiotherapy had a more advanced cancer; however, the inverse association persisted even after adjustment for stage of disease. Nearly all subjects received surgery, six subjects with missing surgery information were excluded from the subsequent analyses. The vast majority (95%) of participants received chemotherapy. Older age at diagnosis was related to lower but not statistically significant survival. Clinical prognostic factors were found to be similar for all subjects as well as those who were included in the genotyping analyses (data not shown).

View this table: [in this window] [in a new window]   Table 2 Association of breast cancer survival with PVUII, XbaI, and (GT)n polymorphisms in the ER- gene: Shanghai Breast Cancer Study

View this table: [in this window] [in a new window]   Table 3 Association of breast cancer survival with PVUII, XbaI, and (GT)n polymorphisms in the ER- gene stratified by ER status: Shanghai Breast Cancer Study

View this table: [in this window] [in a new window]   Table 4 Association of breast cancer survival with ER status stratified by PVUII, XbaI, and (GT)n polymorphisms in the ER- gene: Shanghai Breast Cancer Study

	DISCUSSION

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In this study, we found a multiplicative interaction between PvuII and (GT)₂₃ polymorphisms in the ER- gene and ER status of the breast cancer on breast cancer survival. Although ER status is known to modify the outcome of hormonal treatment for breast cancer (10), the biological mechanism behind its interaction with ER- genotypes remains to be clarified. To our knowledge, no previous study has investigated the association between polymorphisms in the ER- gene and breast cancer survival alone or with ER status.

The three polymorphisms investigated in this study are located in different areas of the ER- gene. The GT repeat polymorphism is located at 2.8 kb 5' to exon 1D, and PvuII and XbaI are located on intron 1. These polymorphisms are not in close linkage disequilibrium in the Chinese population (7, 8).

Although polymorphisms in the ER gene have been linked to altered tissue responsiveness to estrogens, the functional impact of these ER- polymorphisms is not well understood (11). Noncoding short tandem repeats may act as protein binding sites. It has been reported that protein binding may depend on the ability of short tandem repeats to form specific DNA structures and an increasing number of short tandem repeats in the promoter region or introns may interfere with transcription processes by their effect on secondary DNA structure (9). Previous studies investigating ER polymorphisms and breast cancer risk have produced mixed results, which may be explained by ethnicity of the populations under study (3-8). We have linked presence of the (GT)₁₇ or (GT)₁₈ allele of GT polymorphism, or PP allele of Pvull polymorphism to an reduced risk of breast cancer (7, 8) in Chinese population. We did not find that the associations between ER- genotypes and breast cancer risk vary according to ER/PR status (7, 8).

Previous studies have shown that common ER- polymorphisms, including the one found at the PvuII restriction site, are associated with cardiovascular disease risk (13) and possibly modify the effects of estrogens on HDL cholesterol level (14) and changes in bone mineral density and vertebral fractures (15). The latter two studies showed that women with the pp genotype who received hormone replacement therapy had a significantly more pronounced response in outcome than women with other genotypes (i.e., a greater increase in HDL cholesterol levels and bone mineral density; refs. 14, 15), suggesting that this polymorphism may have an interactive effect with hormones.

ER status is the main determinant for tamoxifen use and modulates its effect. According to an ongoing study of Chinese breast cancer patients conducted by our group, we found that 83% of ER-positive breast cancer versus 28% of ER-negative breast cancer patients used tamoxifen up to 18 months post-diagnosis. The interaction between genotype and ER status on breast cancer prognosis found in the current study, therefore, could reflect a differential effect of tamoxifen by genotype. Unfortunately, information regarding tamoxifen use in the current study was collected 3 to 4 years after cancer diagnosis. This information was missing for most of the deceased cases and subjects whose survival status was established via linkage to the death registry. Therefore, direct evaluation of the interaction between ER- gene polymorphism and tamoxifen use was not possible. Nevertheless, we did include tamoxifen use in the model that evaluated the interaction between genotype and ER status, treating those with missing tamoxifen information as a subgroup. We found that patterns of interactive effect remained but the point estimates attenuated (data not shown), suggesting tamoxifen use may play a role in the ER genotype and breast cancer survival association. Future studies are needed to evaluate the possible interactive effect between ER genotype and tamoxifen use on breast cancer survival.

Our study has several strengths that should be considered in interpreting its results, including (a) a population-based patient cohort, (b) the relatively long follow-up period of 5.2 years, (c) a large sample size, (d) relatively homogeneous genetic background (98% of the study population are Han Chinese), and (e) detailed information on ER/PR status, disease stage, and treatment information.

There are also a few limitations that must be considered in evaluating these results. As mentioned above, information regarding tamoxifen use was only collected for a subset of the women participating in this study, making the evaluation of the interaction of ER genotype and tamoxifen impossible. In addition, ER status was abstracted from hospital record and missing for 30% of the study participants, thus compromising the statistical power of this study to evaluate interactions between genotype and ER status.

In summary, our findings of an interaction between ER status and ER- polymorphisms on breast cancer survival are new and need to be confirmed in future studies. If confirmed, these findings could have important clinical implications in breast cancer treatment.

	ACKNOWLEDGMENTS

 
We thank the patients and research staff who participated in the Shanghai Breast Cancer Study.

	FOOTNOTES

 
Grand support: National Cancer Institute USPHS grants RO1CA64277 and RO1CA90899 and U.S. Army Medical Research and Material Command contract DAMD17-03-1-0507 (Dr. S.M. Boyapati).

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 5/ 5/04; revised 10/22/04; accepted 11/ 9/04.

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