Abstract
Background
Mutated BRCA1/2 genes are associated with hereditary breast and ovarian cancer (HBOC). So far most of the identified BRCA1/2 pathogenic variants are single nucleotide variants (SNVs) or insertions/deletions (Indels). However, large genomic rearrangements (LGRs) such as copy number variants (CNVs) are also playing an important role in HBOC predisposition. Their frequency and spectrum have been well studied in western populations but remain largely unknown for Chinese population.
Methods
Peripheral blood samples were collected from 218 unrelated familial breast and/or ovarian cancer (FBOC) patients living in Eastern China. PCR-based Sanger sequencing and panel-based next-generation sequencing (NGS) were performed to detect pathogenic SNVs and Indels in BRCA1/2 genes. For the patients lacking small pathogenic variants, multiplex ligation dependent probe amplification (MLPA) assay was conducted to screen for LGRs.
Results
In total, we identified 44 samples (20.1%) carrying small pathogenic variants (26 in BRCA1 and 18 in BRCA2, respectively). Among the rest of 174 samples, five were found carrying novel deleterious LGRs in BRCA1 which are exon5-7dup (1 patient), exon13-14dup (2 patients), and exon1-22del (2 patients). No LGR was found in BRCA2. Overall, LGRs accounted for 16.1% (5/31) of BRCA1 pathogenic variants, and were detected in 2.3% (5/218) of all FBOC patients.,
Conclusions
LGR variants in BRCA1 gene play a significant role in Chinese HBOC patients. MLPA or other similar LGR-detecting methods should be recommended along with nucleotide sequencing as the initial screening approach for Chinese HBOC women.
Electronic supplementary material
The online version of this article (10.1186/s12885-019-5765-3) contains supplementary material, which is available to authorized users.
Keywords: Chinese, Familial breast cancer, Familial ovarian cancer, BRCA1, BRCA2, Rearrangement
Background
According to National Central Cancer Registry of China, breast cancer ranks No.1 in cancer incidence and sixth in cancer-associated death for Chinese women, with over 250,000 newly diagnosed cases and 70,000 breast cancer-associated death in 2015 [1]. The average onset age of breast cancer is 45–55 years old for Chinese women, which is also younger than observed for Caucasian women [2]. While majority of breast cancer cases are sporadic, patients with familial history or other risk factors such as early onset age have been frequently observed in clinic, suggesting an important role of genetic factors in the disease development. Indeed, germline pathogenic variants in the two major breast cancer susceptibility genes BRCA1/2 have been detected within Chinese patients [3–9].
Studying BRCA1/2 pathogenic variants requires accurate and comprehensive testing methods. Short-read DNA sequencing methods, including both Sanger and next-generation sequencing (NGS), are only capable of reliably detecting small variants such as single nucleotide variants (SNVs) or insertion/ deletion (Indels), but not suitable for detecting large genomic rearrangements (LGRs), which involve deletions or duplications of multiple exons [i.e. copy number variants (CNVs)]. Therefore, sequencing alone may lead to underestimated frequency of pathogenic variants. Southern blotting could be used to detect LGRs [10], but is labor intensive and generally low-throughput. SNP or CGH arrays can detect copy number variants but their unit cost is high and resolution is usually over hundreds of Kb. Several multiplex PCR-based techniques have been recently developed to achieve higher processing and cost efficiency. For instance, multiplex ligation dependent probe amplification (MLPA) assay and multiplex amplicon quantification (MAQ) have been developed as fast and reproducible methods for CNV detection [11]. At the present, MLPA remains to be the most commonly used method for LGRs, and has detected 82.7 and 53% LGRs in BRCA1 and BRCA2, respectively [12].
As of today BRCA1/2 LGR studies have been mostly conducted in western countries, showing different prevalence with ethnicity and geography. For example, there was no BRCA1/2 LGR variants detected in Ashkenazi Jewish familial breast cancer patients [13, 14], but in non-Ashkenazi Jewish, the frequency of LGRs was 6% [14]. Very limited research has been conducted for Chinese, and only 12 BRCA1/2 LGRs have been so far reported. Those studies were conducted in Hong Kong [15], Singapore [16] and Malaysian [17]. The frequency and spectrum of BRCA1/2 LGRs in familial breast cancer patients from China mainland remain largely unknown.
Methods
Patient subjects
A total of 218 unrelated familial breast cancer patients were enrolled into this study between 2008 and 2017. All patients were diagnosed in Zhejiang Cancer Hospital in Eastern China and had a family history of at least one first- or second-degree relatives affected with breast cancer and/or ovarian cancer, regardless of age. Peripheral blood samples from the patients were collected in EDTA tubes and stored at − 80 °C. SNVs and Indels variants of BRCA1/2 were firstly determined for all patients using sequencing methods (PCR-based Sanger sequencing and panel-based NGS). The patients with negative sequencing finding were further screened for LGRs by MLPA. The written informed consents were obtained from all participating patients prior to clinical data and peripheral blood collection. This study was approved by the Research and Ethical Committee of Zhejiang Cancer Hospital, China. All experiments were performed in accordance with the approved guidelines.
DNA extraction
Genomic DNA was extracted from peripheral blood samples using QIAamp DNA Blood Mini kit (Qiagen, Hilden, Germany) by following the manufacture’s manual. DNA purity and concentration were measured by NanoDrop 2000 Spectrophotometer and Qubit 3.0 (Thermo Fisher Scientific, Waltham, USA), and DNA integrity was determined by agrose gel electrophoresis.
Nucleotide sequencing
The present study used both PCR-based Sanger sequencing and panel-based NGS to interrogate small nucleotide variants including SNVs and Indels. In the first phase of the project, Sanger sequencing was performed on 133 unrelated FBOC cases using a total of 72 pairs of oligos to cover all coding exons and intron-exon boundaries of BRCA1/2. The primer oligo sequences were listed in Additional file 1: Table S1 and Additional file 2: Table S2. In the second phase of the project, in order to achieve high-throughput and cost-effective sequencing, we designed a NGS panel by adopting the NEBNext Direct sequencing technology developed by New England Biolabs (Ipswich, MA). The panel contains BRCA1/2 genes as well as other 96 known cancer risk-associated genes. We performed panel NGS on all of the 133 Sanger cases along with 85 new cases newly collected. Individually prepared libraries were pooled for Hiseq X sequencing (Illumina, CA, USA) to achieve a minimum 500x mean coverage for the included panel genes. Raw FASTQ data run through in house bioinformatic pipeline with variant calling generated for BRCA1/2 genes. Variant filtering and final interpretation were conducted by following the ACMG Standards and Guideline for the Interpretation of Sequence Variants [18] and based on a set of criteria such as allele frequency as well as information from clinical genome databases including ClinVar (https://www.ncbi.nlm.nih.gov/clinvar/), Online Mendelian Inheritance in Man (OMIM) (http://www.omim.org/) and Human Gene and Mutation Database (HGMD) (http://www.hgmd.cf.ac.uk/ac/index.php).
LGRs analysis
BRCA1/2 LGRs was screened by (Multiplex ligation dependent probe assay) MLPA assay using the SALSA P002 kit and P045 kit for BRCA1 and BRCA2 genes, respectively (MRC-Holland, Amsterdam, the Netherlands). The MLPA reactions were performed according to the manufacturer’s instruction. Five normal control samples were included as reference within each MLPA run. Fragment analysis of the PCR products were performed on an ABI 3130xl Genetic Analyzer (Applied Biosystems, Foster City, CA). The data was analyzed by using the Coffalyser software v.9 (Applied Biosystems, Foster City, CA). All of the peak heights were normalized, and the ratio value between 0.7–1.3 was considered as normal. A ratio value ≤0.7 or ≥ 1.3 was threshold suggestive of a deletion or duplication, respectively. All patients with a value ≤0.7 or ≥ 1.3 were confirmed by independent experiments.
Two primer oligos were designed to validate BRCA1 Exon 5–7 duplication. The forward primer sequence was CCGTGCCAAAAGACTTCTACA (Exon 7) and the reverse primer sequence was TTGCTTCCAACCTAGCATCA (Exon 5). Long range PCR amplification was performed with Takara LA Taq DNA polymerase (Takara Bio, USA) by following the manufacturer’s manual. The amplified product was run on 0.8% Agrose gel electrophoresis with EB (i.e. ethidium bromide) and visualized under UV light. The purified amplicons were subjected to Sanger sequencing to confirm amplification fidelity.
Results
Small pathogenic variants in BRCA1/2 genes
Overall, we identified a total of 31 BRCA1 or BRCA2 pathogenic SNVs and Indels in 44 unrelated patients by combining Sanger sequencing and the 98-gene panel NGS assay. Table 1 lists all these small variants. In summary, nearly 59% (26 of 44) of patients had BRCA1 pathogenic variants, and 41% (18 of 44) had BRCA2 pathogenic variants. Two recurrent pathogenic variants (c.5154G > A and c.5468-1_5474del GCAATTGG) in BRCA1 were reported as putative founder mutations [19]. In total, frequency of BRCA1/2 small pathogenic variants was 20.2% (44/218) in the studied cohort.
Table 1.
Gene | Mutation | AA change | ClinVar | No. of patient | Tumor type (age Dx) | IHC of BC | History of BC and OC (age Dx) | Other cancers in the family (age Dx) |
---|---|---|---|---|---|---|---|---|
BRCA1 | c.223G > T | p.Glu75Ter | No | 1 | IDC (R 44, L 54) | ER−/PR−/HER2- | S OC(52) | PA EC, PA LC, MU GC |
c.1209delT | p.Glu404Asnfs | No | 1 | IDC (47), OC, TC | ER+/PR+/HER2- | M OC(52), MA OC(54) | ||
c.1465G > T | p.Glu489Ter | Yes | 1 | IDC (51) | ER−/PR−/HER2- | S OC(52) and BC(58) | ||
c.1945G > T | p.Glu649Ter | Yes | 1 | IDC (36) | ER−/PR−/HER2- | M BC(58) | ||
c.2110_2111delAA | p.Asn704Cysfs | Yes | 2 | IDC (55) | ER−/PR−/HER2- | M BC(57) | ||
IDC (68) | ER−/PR−/HER2- | S OC, D OC(40) | ||||||
c.3266delA | p.Leu1089Cysfs | Yes | 1 | IDC (62) | ER−/PR−/HER2- | S OC(45) | S LC(65), | |
c.3295delC | p.Pro1099Leufs0 | No | 1 | IDC (29) | ER−/PR−/HER2- | S BC(40) | ||
c.3780_3781delAG | p.Leu1260Phefs | No | 2 | OC (57) | ND | M BC(58) | S GbC(70) | |
IDC (39), OC (44) | NA | MA BC(42), MA BC(33) | ||||||
c.4063_4066delAATC | p.Asn1355Lysfs | No | 1 | IDC (40) | ER+/PR+/HER2- | M BC(46) | ||
c.4065_4068delTCAA | p.Asn1355Lysfs | Yes | 2 | IDC (38), OC (45) | ER−/PR−/HER2- | M BC (69) | MA EC | |
IDC (50) | ER−/PR−/HER2- | S BC | P GC | |||||
c.5154G > A | p.Trp1718Ter | Yes | 2 | IDC(35) | ER−/PR−/HER2- | S BC(40) | F BT | |
IDC (41) | ER−/PR−/HER2- | S BC(45) | M EC(69), MA RC | |||||
c.5161C > T | p.Gln1721Ter | Yes | 1 | IDC (32) | ER−/PR−/HER2- | S BC(L 35, R 37), M OC(47) | ||
c.5173insA | p.Glu1725Argfs | Yes | 1 | IDC (42) | ER−/PR−/HER2- | S BC(48), MA BC(48) | M LC(51) | |
c.5251C > T | p.Arg1751Ter | Yes | 1 | IDC (47) | ND | S DCIS(57) | ||
c.5467 + 1G > A | – | Yes | 1 | IDC (31) | ER+/PR+/HER2+ | S BC(41), S BC(45), MA BC(51) | ||
c.5468-1_5474del GCAATTGG | – | No | 2 | IDC (41) | ER−/PR−/HER2- | S BC(52), S OC(47) | M EC(77), F LuC(81) | |
IDC (36) | ER−/PR−/HER2- | S BC(L 38, R 44), MA BC(48) | MA EC(50) | |||||
c.5470_5477del ATTGGGCA | p.Ile1824Aspfs | Yes | 5 | IDC (36) | ER−/PR−/HER2- | S BC (L 37, R 39) | ||
IDC (40) | ER−/PR−/HER2- | M BC(44) | ||||||
IDC (58) | ER−/PR−/HER2- | M OC(55), MA BC(56) | ||||||
IDC (L 22, R 33), TC (22) | ER−/PR−/HER2- | M BC(47), MGM BC(49), MA BC(33), MA OC(42) | MA RC(47) | |||||
IDC (49) | ER−/PR−/HER2- | S BC(52), PA BC | ||||||
BRCA2 | c.-39-1_-39delGA | – | Yes | 1 | IDC (46) | ER+/PR+/HER2+ | S BC(48) | |
c.469_473delAAGTC | p.Lys157Serfs | No | 1 | IDC (46) | ER−/PR+/HER2- | S BC(L 47, R 49) | S CC(50), F EsC(51), B EsC(64) | |
c.470_474del AGTCA | p.Lys157Serfs | Yes | 1 | ILC (31) | ER+/PR+/HER2- | M BC(58) | ||
c.755_758delACAG | p.Asp252Valfs | Yes | 1 | IDC (48) | ER+/PR+/HER2- | M OC(68) | ||
c.784delG | p.Ala262Glnfs | No | 1 | IDC (43) | ER+/PR+/HER2- | S BC(43), PA BC(50) | F EsC(57), FU PC(56) | |
c.3109C>T | p.Gln1037Ter | Yes | 2 | IDC (L 39, R 47) | ER+/PR+/HER2- | M BC (39) | ||
IDC (34) | ER+/PR+/HER2- | PA BC(51) | PA GC(70), PU EsC (59) | |||||
c.3189_3192delGTCA | p.Ser1064Leufs | Yes | 1 | IDC (55) | ER+/PR+/HER2- | S BC(55) | ||
c.3596_3599delACTG | p.Asp1199Valfs | Yes | 1 | IDC (44) | NA | S BC(46), M BC(60) | ||
c.4487delC | p.Pro1496Glnfs | No | 1 | IDC (37) | ER−/PR+/HER2- | S BC(47), MS BC(41) | MA TC(51), MA TC(55), MS TC(36) | |
c.5495delC | p.Ser1832Leufs | No | 1 | IDC (41) | ER−/PR+/HER2- | S BC(43) | ||
c.5682C > G | p.Tyr1894Ter | Yes | 4 | ILC (32) | ER+/PR+/HER2- | PA BC(45), PA BC(R 42, L 46) | ||
MBC (42) | NA | PGF BC(66) | ||||||
ILC (68) | ER+/PR+/HER2- | PA BC(60) | ||||||
ILC (61) | ER+/PR+/HER2- | S BC(51) | ||||||
c.6141 T > A | p.Tyr2047Ter | No | 1 | IDC (35) | NA | S BC(39), MGM BC(61), MS BC(50) | S LuC (52), MU LC(66) | |
c.6359C > G | p.Ser2120Ter | Yes | 1 | ILC (R 36, L 51), EC (55) | ER+/PR+/HER2- | M OC(76), MA BC(70) | ||
c.7588C > T | p.Gln2530Ter | No | 1 | IDC (43) | ER+/PR+/HER2+ | M BC(63) |
AA amino acid, Dx diagnosis, IHC immunohistochemistry, IDC invasive ductal carcinoma, ILC invasive lobular carcinoma, MBC medullary breast carcinoma, L left, R right, BC breast cancer, OC ovarian cancer, LC liver cancer, EC endometrial carcinoma, LuC lung cancer, BT brain tumor, RC rectal cancer, DCIS ductal carcinoma in situ, GbC Gallbladder cancer, GC gastric cancer, TC thyroid cancer, CC Colon cancer, EsC Esophagus cancer, PA prostate cancer, M mother, S sister, MS maternal sister, PA paternal aunt, MGM maternal grandmother, F father, MU maternal uncle, FU father uncle, MA maternal aunt, D daughter, PGF paternal grandfather, B brother, PU paternal uncle, ND not done, NA not available
Novel LGRs identified in BRCA1
Among the 174 patients lacking BRCA1/2 small pathogenic variants, three unique BRCA1 LGRs were detected in 5 (2.9%) cases by MLPA assay (Fig. 1a, b, c, d). These include one case with exon5-7dup, two cases with exon13-14dup, and two cases with exon1-22del (Table 2). To our knowledge, these three LGRs have not been reported in Chinese HBOC patients. To confirm MLPA results, we validated exon 5-7dup by designing oligo primers surrounding the putative junction. We obtained a clear and strong 6-8Kb PCR amplicon (Fig. 1e), whose sequence identity was confirmed by Sanger sequencing (data not shown) supporting a tandem duplication event. Overall, BRCA1 LGRs accounted for 16.1% (5/31) of all patients with BRCA1 pathogenic variants. No LGR was identified in BRCA2. Combining small nucleotide variants and LGRs, we obtained a frequency of 22.5% (49/218) for this cohort, with BRCA1 LGRs accounting for 10.2% (5/49) of all BRCA1/2 pathogenic variants.
Table 2.
Family ID | Mutation | Sex of proband | Phenotype proband (age Dx) | Tumor type | IHC | Familial history of breast cancer and ovarian cancer (age Dx) | Other cancers in the family (age Dx) |
---|---|---|---|---|---|---|---|
147 | Exon5-7dup | Female | 43 | IDC | ER−/PR−/HER2- | S OC (48) | None |
10 | Exon13-14dup | Female | 29 | MpBC | ER−/PR−/HER2- | M BC(57), PGM BC | None |
213 | Exon13-14dup | female | 33 | IDC | ER+/PR−/HER2- | PA OC(53) and BC(56), MGM BC (52) | None |
113 | Exon1-22del | Female | 45 (R), 50 (L) | BMC (R), IDC (L) |
R: ER−/PR−/HER2+ L: NA |
S BC (42) and OC (45) | F EC (71), MU BlaC (71), MB Leu |
203 | Exon1–24(part)del | Female | 39 | MBC | ER−/PR−/HER2- | M BC (50), MS BC (43) | None |
LGRs Large genomic rearrangements, Dx diagnosis, IHC immunohistochemistry, dup duplication, del deletion, R right, L left, MpBC micropapillary breast cancer, BMC breast mucinous carcinoma, IDC invasive ductal carcinoma, MBC medullary breast carcinoma, BC breast cancer, OC ovarian cancer, EC esophageal carcinoma, BlaC bladder carcinoma, Leu leukemia, M mother, PGM paternal grandmother, S sister, MS maternal sister, PA paternal aunt, MGM maternal grandmother, F father, MU maternal uncle, MB maternal brother
Disease pathology associated with BRCA1 LGRs
The characteristics and familial cancer history of patients with BRCA1 LGRs were listed in Table 2 and their family pedigrees were shown in Fig. 2. In the five breast cancer patients with BRCA1 LGRs, the most common tumor type was invasive ductal carcinoma. Moreover, Micropapillary carcinoma, mucinous carcinoma as well as medullary carcinoma was found in these patients with BRCA1 LGRs. Although triple negative (ER−/PR−/HER2-) subtype was the most common subtype, luminal subtype (ER+) and HER2-overexpression subtype (ER−/PR−/HER2+) were also exited in patients with BRCA1 LGRs.
Discussion
In this study, we performed nucleotide sequencing for 218 unrelated FBOC patients living in Eastern China and observed a 20.2% overall pathogenic variant frequency for BRCA1/2 genes. MLPA assay on the patients lacking small pathogenic variants (174 of 218) further identified 3 unique LCRs in 5 patients, increasing the total BRCA1/2 pathogenic variant frequency to 22.5%. All of the three BRCA1 LGRs were not previously reported by Chinese population studies [15–17]. Interestingly, no LGR was identified in BRCA2 gene within our cohort, consistent to the knowledge that LGRs are more frequently observed in BRCA1 than BRCA2. It was revealed that Alu-mediated unequal homologous recombination could be the most common mechanism of LGRs found in BRCA1/2, as 72.84% (59/81) and 52.94% (9/17) LGRs in BRCA1 and BRCA2 respectively were mediated by this manner [20]. The reason behind higher LGRs frequency in BRCA1 than in BRCA2 might be due to the higher Alu density (41.5%) in the BRCA1 gene than in the BRCA2 gene [21].
It has been reported that frequency of LGRs ranges from approximately 6–27% of all detected BRCA1 pathogenic variants, and BRCA2 LGRs play a less role in hereditary breast cancer patients [20]. Thirty five out of three hundreds (12%) of BRCA1/2-sequencing negative familial breast cancer patients from non-Ashkenazi Jewish in US were found carrying BRCA LCRs, with 10% (31/300) LCRs detected in BRCA1 and 1% (4/300) detected in BRCA2, respectively [22]. A nationwide study conducted in South Korea showed that LGRs were detected in 3.7% (3/81) of patients bearing BRCA1/2 pathogenic variants and 7.5% (3/40) of patients bearing only BRCA1 pathogenic variants [23]. A large sample screening of high-risk breast cancer patients from Hong Kong showed that LGRs accounted for 6.67% (8/120) of all BRCA1/2 pathogenic variants, involving 8.77% (5/57) of BRCA1 and 4.76% (3/63) of BRCA2, respectively [15]. In our present study, BRCA1 LGRs account for 16.1% (5/31) of all BRCA1 pathogenic variants and 10.2% (5/49) of all BRCA1/2 pathogenic variants. For 174 cases with negative sequencing results, five (2.9%) were identified with BRCA1 LCRs.
Conclusions
To conclude, our study has provided evidence that BRCA1/2 LGRs contribute significantly to the development of HBOC in Chinese mainland population and LGRs screening should be taken into consideration in hereditary breast cancer consulting. It is imperative that the frequency and spectrum of BRCA1/2 should be investigated in the context of both small nucleotide variants and LGRs.
Additional files
Acknowledgements
Not applicable.
Abbreviations
- BC
Breast cancer
- IHC
Immunohistochemistry
- LGRs
Large genomic rearrangements
- MAQ
Multiplex amplicon quantification
- MLPA
Multiplex ligation dependent probe amplification
- NGS
Next generation sequencing
- OC
Ovarian cancer
- PCR
Polymerase chain reaction
Authors’ contributions
WMC: designed the study, analyzed the MLPA analysis data and drafted the manuscript. YBZ: performed the analysis of MLPA. YG and ZWP: extracted DNA and performed PCR. XWD, YS, YH and CJL: contributed samples and patient information. GP: reviewed the data and drafted the manuscript. XJW: conceived of the study, participated in its design and coordination and helped to draft the manuscript. All authors read and approved the final manuscript.
Funding
This research was supported by the grants from National Natural Science Foundation of China (grant number: 81672597), Natural Science Foundation of Zhejiang Province, China (grant number: LY17H160038), Key Research-Development Program of Zhejiang Province (grant number: 2017C03013, 2019C04001), Science and Technology Program offered by Health Bureau of Zhejiang Province, China (2012RCB006 and 2014KYA006). The funding bodies had no role in study design, collection, analysis, or interpretation of data, or in writing the manuscript.
Availability of data and materials
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
Ethics approval and consent to participate
This study was approved by the Research and Ethical Committee of Zhejiang Cancer Hospital, China. The written informed consents were obtained from all of the participating patients prior to clinical data and peripheral blood collection.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Footnotes
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Wen-Ming Cao and Ya-Bing Zheng contributed equally to this work.
Contributor Information
Wen-Ming Cao, Email: caowm@zjcc.org.cn.
Ya-Bing Zheng, Email: zhengyb@zjcc.org.cn.
Yun Gao, Email: gaoyun@zjcc.org.cn.
Xiao-Wen Ding, Email: dingxw@zjcc.org.cn.
Yan Sun, Email: sunyan@zjcc.org.cn.
Yuan Huang, Email: huangyuan@zjcc.org.cn.
Cai-Jin Lou, Email: loucj@zjcc.org.cn.
Zhi-Wen Pan, Email: panzw@zjcc.org.cn.
Guang Peng, Email: gpeng@mdanderson.org.
Xiao-Jia Wang, Phone: +86 571-88122072, Email: wxiaojia@yahoo.com.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.