A total of 304 breast cancer cases were systematically ascertained through Imam Khomeini Hospital Complex (Tehran University of Medical Sciences, Tehran, Iran). Of these cases, 50% (152) were selected on the basis of a family history of breast cancer (defined as ≥2 cases of breast cancer in a first- or second-degree female relative). Blood was taken from all recruits who consented to molecular analysis for breast cancer predisposition genes at the Central Laboratory of Imam Khomeini Hospital Complex hospital. The age range of the all breast cancer participants was 28–74 with a mean age of 49.41±10.44 years (familial and non-familial breast cancer). The controls were selected from the same population from which the cases arose and consisted of 295 healthy female volunteers who were attending the Cancer Institute of Imam Khomeini Hospital Complex for a checkup. The age range of the controls was 28–74 with a mean age of 49.28±10.48 years. None of the control individuals had any history of breast cancer or any other neoplastic diseases, and had no family history of breast cancer diagnosed at the same clinics. Women with hysterectomy and artificial menopause, or who had been exposed to any kind of radiation, including X-rays, or chemotherapy in their life time were excluded from the study. Control and cancer groups were drawn from the same geographical area. Demographical and epidemiological risk factor data was collected from a short, structured questionnaire, which included information on age at menarche, age at menopause, marriage status, race, age at breast cancer onset, number of pregnancies and children, age at first child birth and average lactation term. An ongoing protocol to collect and store blood samples for future genomic tests was approved by the institutional review board and appropriate ethics committee. Peripheral blood was collected and genotyping analysis was performed for selected regions in the FANCA gene.

The study was approved by the Research Ethics Committee for Tehran University of Medical Sciences (IR.TUMS.REC.1395.2500). Informed consent for testing and publication was obtained from all participants prior to participation in the present study (or their parents/legal guardians).

DNA for genotyping was prepared from the peripheral blood sample of patients and controls. The DNA promoter region containing the duplication (164 bp) was amplified using primers designed by Primer3 (version 0.4.0) software and positive control primers were used to amplify estrogen receptor 1 gene exon 4 (329 bp), as published elsewhere (18). Primer sequences are presented in Table I.

DNA was isolated using AccuPrep^® (high pure phenol-chloroform) Genomic DNA extraction kit (Bioneer Corporation; Takapouzist Co., Tehran, Iran). Lysis buffer (200 µl) was added to 200 µl whole blood and incubated at 60°C for 10 min, 500 µl phenol was then added and centrifuged at 12,000 × g at 4°C for 5 min. Chloroform (500 µl) was added to the upper phase and centrifuged for 5 min at 12,000 × g at 4°C. Sodium Acetate (1:10) plus cold 100% ethanol (2:1) was added to the upper phase, frozen for 20 min at −20°C and centrifuged for 10 min at 12,000 × g and 4°C. To precipitate DNA, 70% ethanol was added and centrifugation was performed for 15 min at 12,000 × g and 4°C. The DNA was measured using a spectrophotometer; the amount of DNA was calculated in µg/ml (85 µg/ml) by absorbance at 260 nm and the purity was tested by determining the 260/280 nm ratio (a ratio of 1.7 was detected).

The following was added to each 50 µl PCR reaction tube: 43.5 µl master mix (5X HOT FIREPol^® Blend; TAG Copenhagen A/S, Frederiksberg, Denmark); 2 µl (200 nM) primers synthesized by TAG Copenhagen A/S; 2 µl (50 ng) DNA template (extracted genomic DNA); and 2.52 µl Taq DNA polymerase (0.5 U Super Taq enzymes; Cambridge Bioscience, Ltd., Cambridge, UK) and PCR was performed in an Eppendorf thermo-cycler following the protocol in Table II. The first set of PCR primers amplified a 151-base pair product for allele 0 (normal) and a 164 base pair product for allele 1 (duplication). The DNA ladder (Biotium) was also purchased from Cambridge Bioscience, Ltd. The products were separated by electrophoresis on 3% agarose gel and stained by 1% ethidium bromide (Cambridge Bioscience, Ltd.). PCR products from the three genotypes were sequenced on the 96-capillary ABI 3730xl (Applied Biosystems; Thermo Fisher Scientific, Inc., Waltham, MA, USA) by the Sanger sequencing technique.

The Hardy-Weinberg equilibrium was assessed by the standard methods (19). The data were considered using normal (00; women without a copy of the duplication allele), heterozygotes (01; women with 1 copy of the duplication allele) and homozygotes (11; women with 2 duplication alleles). Data was analyzed using SPSS, version 17.0 (SPSS, Inc., Chicago, IL, USA). Stratification with respect to demographics and risk factors was performed and post-stratification Pearson's χ² analysis was used to calculate the significance and odds ratio (OR) with a 95% confidence interval. All tests were two-sided and P<0.05 was considered to indicate a statistically significant difference.

Variation in the FANCA gene promoter region (NCBI reference sequence, NM_000135.2) was screened using PCR analysis. Variant bands were purified and sequenced directly with forward and reverse primers. The comparison of band sequences and the sequence of the FANCA promoter demonstrated that a 13-base pair sequence (5′-GGCCACGACGCAA-3′) located from −98 to −110 bases upstream of the transcription start point, which was present either as a single or double copy, causes variation in patterns observed on the agarose gel. In the present study, allele 0 is defined as having has a single copy of the sequence (5′-GGCCACGACGCAA-3′), whilst allele 1 has 2 tandem copies of this sequence. Notably, the sequence directly adjacent to (in the downstream direction) the 13-base pair sequence shares homology with the duplicate sequence.

A single set of primers was used to amplify both alleles by PCR in the promoter region (Fig. 1). The frequency of the polymorphism was determined in patients with breast cancer and controls to assess if the presence of either allele was associated with a predisposition to breast cancer. Table III presents the genotypic frequency distribution in patients with breast cancer and controls. The distribution of the genotypes within overall breast cancer and familial breast cancer groups deviated significantly from those expected under Hardy-Weinberg equilibrium with a P-value of 0.001. In patients with familial breast cancer, the estimated risk was 1.3 fold higher for individuals who were 01 heterozygote duplication (OR, 1.27; 95% CI, 0.825–1.955) or 1.5 fold higher for those who were 11 homozygote duplication (OR, 1.511; 95% CI, 0.73–3.131) compared with 00 homozygotes. Therefore, the results indicated that a higher frequency of allele 1 may be associated with an increased risk of developing familial breast cancer. However, the genotypic frequency did not show significant (P=0.365) elevation among the-non family history group. Furthermore, the frequency of the duplication allele (allele 1) in all breast cancer patients and familial breast cancer patients only was significantly higher compared with controls (P=0.001), with exception of non-familiar breast cancer patients (P=0.131; Table IV). Promoter duplication genotypes were compared with selected clinical breast cancer features, including age at menarche, age at breast cancer onset, age at menopause and lymph node metastasis in patients with breast cancer. The only significant association was for age at menarche, as indicated by the ORs presented in Table V. Genotype frequencies exhibited significantly different distributions in age at menarche (<12 years old vs. ≥12; P=0.001). The estimated risk was higher for individuals who were 11 homozygotes for the duplication (OR 0.148, 95% CI: 0.069–0.316) compared with the corresponding 01 heterozygotes (OR, 0.775; 95% CI, 0.428–1.405). Furthermore, the estimated risk of developing breast cancer (familiar breast cancer vs. non-familiar breast cancer) was 4-fold higher for those who were 11 homozygotes (OR 4.093, 95%; CI, 1.957–8.561) or 3-fold higher for those who were 01 heterozygotes (OR, 3.315; 95% CI, 1.996–5.506) compared with the corresponding 00 homozygotes. The results suggest that the higher the frequency of allele 1, the greater the risk of developing breast cancer.