Europe PMC
Nothing Special   »   [go: up one dir, main page]

Europe PMC requires Javascript to function effectively.

Either your web browser doesn't support Javascript or it is currently turned off. In the latter case, please turn on Javascript support in your web browser and reload this page.

This website requires cookies, and the limited processing of your personal data in order to function. By using the site you are agreeing to this as outlined in our privacy notice and cookie policy.

Abstract 


The identification of founder mutations in cancer predisposing genes is important to improve risk assessment in geographically defined populations, since it may provide specific targets resulting in cost-effective genetic testing. Here, we report the characterization of the BRCA1 c.190T>C (p.Cys64Arg) mutation, mapped to the RING-finger domain coding region, that we detected in 43 hereditary breast/ovarian cancer (HBOC) families, for the large part originating from the province of Bergamo (Northern Italy). Haplotype analysis was performed in 21 families, and led to the identification of a shared haplotype extending over three BRCA1-associated marker loci (0.4 cM). Using the DMLE+2.2 software program and regional population demographic data, we were able to estimate the age of the mutation to vary between 3,100 and 3,350 years old. Functional characterization of the mutation was carried out at both transcript and protein level. Reverse transcriptase-PCR analysis on lymphoblastoid cells revealed expression of full length mRNA from the mutant allele. A green fluorescent protein (GFP)-fragment reassembly assay showed that the p.Cys64Arg substitution prevents the binding of the BRCA1 protein to the interacting protein BARD1, in a similar way as proven deleterious mutations in the RING-domain. Overall, 55 of 83 (66%) female mutation carriers had a diagnosis of breast and/or ovarian cancer. Our observations indicate that the BRCA1 c.190T>C is a pathogenic founder mutation present in the Italian population. Further analyses will evaluate whether screening for this mutation can be suggested as an effective strategy for the rapid identification of at-risk individuals in the Bergamo area.

Free full text 


Logo of plosoneLink to Publisher's site
PLoS One. 2014; 9(2): e86924.
PMCID: PMC3916327
PMID: 24516540

Characterization of an Italian Founder Mutation in the RING-Finger Domain of BRCA1

Klaus Brusgaard, Editor

Abstract

The identification of founder mutations in cancer predisposing genes is important to improve risk assessment in geographically defined populations, since it may provide specific targets resulting in cost-effective genetic testing. Here, we report the characterization of the BRCA1 c.190T>C (p.Cys64Arg) mutation, mapped to the RING-finger domain coding region, that we detected in 43 hereditary breast/ovarian cancer (HBOC) families, for the large part originating from the province of Bergamo (Northern Italy). Haplotype analysis was performed in 21 families, and led to the identification of a shared haplotype extending over three BRCA1-associated marker loci (0.4 cM). Using the DMLE+2.2 software program and regional population demographic data, we were able to estimate the age of the mutation to vary between 3,100 and 3,350 years old. Functional characterization of the mutation was carried out at both transcript and protein level. Reverse transcriptase-PCR analysis on lymphoblastoid cells revealed expression of full length mRNA from the mutant allele. A green fluorescent protein (GFP)-fragment reassembly assay showed that the p.Cys64Arg substitution prevents the binding of the BRCA1 protein to the interacting protein BARD1, in a similar way as proven deleterious mutations in the RING-domain. Overall, 55 of 83 (66%) female mutation carriers had a diagnosis of breast and/or ovarian cancer. Our observations indicate that the BRCA1 c.190T>C is a pathogenic founder mutation present in the Italian population. Further analyses will evaluate whether screening for this mutation can be suggested as an effective strategy for the rapid identification of at-risk individuals in the Bergamo area.

Introduction

Inactivating germline mutations of BRCA1 and BRCA2 genes account for approximately 15% to 20% of hereditary breast and/or ovarian cancer (HBOC) cases [1], [2]. The majority of alterations identified throughout the whole sequence of both genes are private or detected in few families only [3], but a number of specific mutations that appear repeatedly in ethnically defined groups or in populations enriched with genetic isolates, because of a shared common ancestry (founder mutations), have been reported [4].

The identification of founder mutations in various ethnic groups and their geographical distribution has important implications for designing mutational screening. For example, three founder mutations in the Ashkenazi Jewish (BRCA1 c.68_69delAG, BRCA1 c.5266dupC, BRCA2 c.5946delT) and one in the Icelanders (BRCA2 c.771_775del5), account for virtually all HBOC families linked to BRCA genes in these populations [5][8], where, therefore, it is worthwhile to test high-risk patients specifically for these mutations, before considering the more expensive complete sequence analysis of both genes. Furthermore, the identification of recurrent genomic rearrangements of the BRCA1 and BRCA2 genes, due to founder effects, has provided a strong rational for including the screening for these alterations in the diagnostic setting. For instance, in the Dutch population two distinct deletions involving exons 13 and 22 account for approximately 25% of all BRCA1-positive families [9], while approximately 9% of BRCA1-positive families in the United Kingdom carry a common exon 13 duplication [10]. As a result, in these populations screening for specific BRCA1 rearrangements is now part of routine genetic testing of HBOC families. Notably, the knowledge of founder BRCA1 or BRCA2 mutations may provide more precise estimates of the prior probability of carrying a mutation in either genes and of the likelihood of a mutation carrier developing cancer [11].

To date, a few BRCA founder mutations have been reported also in the Italian population, where they appear to be limited to geographically restricted areas (reviewed in ref. 4).

Here, we report the characterization of the BRCA1 c.190T>C missense mutation (p.Cys64Arg), located in the gene region coding for the RING-finger motif of the protein, which segregates with the disease in Italian HBOC families, mostly originating from the province of Bergamo (Northern Italy).

Materials and Methods

Ethics Statement

All subjects included in the study received genetic counseling and provided a written informed consent for BRCA gene mutation testing and for the use of their biological samples for research purposes: This study was approved by the ethical committee of the Fondazione IRCCS Istituto Nazionale dei Tumori (INT) of Milan.

Case Material

The study includes 43 apparently unrelated families carrying the c.190T>C (p.Cys64Arg) mutation in BRCA1 exon 5, identified among those referred for BRCA gene testing from December 1995 to December 2012 by the following institutions: Fondazione IRCCS Istituto Nazionale dei Tumori (INT) and Istituto Oncologico Europeo (IEO) of Milan, Azienda Ospedaliera Papa Giovanni XXIII of Bergamo (AO-BG) and University of Florence (Department of Biomedical, Experimental and Clinical Sciences). The presence of the mutation was ascertained in family probands by either denaturing high performance liquid chromatography (DHPLC) and/or direct sequencing of all coding exons and adjacent intronic regions of the BRCA1 and BRCA2 genes. Sequencing of BRCA1 exon 5 was performed to identify additional mutation carriers among the probands' relatives.

Microsatellite analysis

A total of 76 individuals, including 43 mutation carriers and 33 non carriers, from 21 of the above families were genotyped at the BRCA1 locus as previously described [12].

Haplotyping and estimate of mutation age

Haplotypes were constructed manually from microsatellite analyses, assuming the least number of possible recombinations. Age estimate of the BRCA1 c.190T>C mutation was carried out with the DMLE+2.2 software program (URL: http://www.dmle.org) [13]. The DMLE input file included the full haplotypes of mutations carriers and of non-carriers, used as controls from the general population, for the 6 examined markers, chromosome map distances derived from the Marshfield and/or Genéthon sex-average genetic maps (URL: http://www.ncbi.nlm.nih.gov/mapview/), an estimate of population growth rate per generation and an estimate of the proportion of sampled mutation-carrying chromosomes. The population growth rates per generation (r) were estimated as described [12], based on available demographic data (Italian National Statistics Institute, ISTAT; URL: http://www.istat.it) and assuming a time interval of 25 years per generation. The r value for the province of Bergamo from the year 1300 to present was estimated to be 0,0526. This index was subsequently used for mutation age estimates. Three separate analyses were then performed, each using a different estimate for the proportion of sampled mutation-carrying chromosomes: 0.015, 0.01, and 0.005.

Transcript analysis

Epstein-Barr virus (EBV)-immortalized human lymphoblastoid cell lines (LCLs) were established and cultured as described [14]. Four BRCA1 mutant and six wild-type LCLs were grown in the absence and in the presence of cycloheximide (CHX) (100 µg/ml) for 4 hours to account for potential degradation of unstable transcripts via nonsense mediated mRNA decay. Total RNA was purified and reverse transcribed into cDNA as described [14]. The PCR reaction was performed with a forward primer in BRCA1 exon 5 (5′-GCATGCTGAAACTTCTCAAC-3′), and a reverse primer in exon 6 (5′-TCCAAACCTGTGTCAAGCTG-3′). The reverse primer was labeled with 6-carboxyfluorescein (6-FAM). The fluorescent amplification products were run on a 3130 Genetic Analyzer (Applied Biosystems) using the GeneScan 500 ROX Size Standard (Applied Biosystems) as internal marker. Size calling and quantification of peak areas were performed with GeneMapper Software v4.0 (Applied Biosystems). The molecular nature of the peaks was confirmed by sequencing.

Statistical Analysis

The ratios of the peak areas of the BRCA1 Δexon5q and full-length mRNA isoforms in different samples were compared by two-tailed Student t test using GraphPad Prism version 5.0 software and 95% confidence interval (CI).

Plasmid construction

The pET11a-NfrGFP-Z and pMRBAD-Z-CfrGFP expression vectors, encoding anti-parallel leucine zipper motifs (Z) fused to the N-terminal or C-terminal fragment of Green Fluorescent Protein (NfrGFP, CfrGFP, respectively) and the plasmids encoding N-terminal RING domains of BARD1 (amino acids 26–140) and BRCA1 (amino acids 1–109) attached via a linker sequences to the NfrGFP (pET11a-NfrGFP-BARD1) or CfrGFP (pMRBAD-BRCA1-CfrGFP), were created as described [15]. The pET11a-NfrGFP-Z and pET11a-NfrGFP-BARD1 vectors also encode a hexahistidine (H6)-tag at the N-terminus of the NfrGFP useful for rapid purification of the H6-tagged protein. The pMRBAD-Z-CfrGFP and pMRBAD-BRCA1-CfrGFP (both as wild-type and mutant forms) bear an HA epitope at the C-terminus of the CfrGFP as a detection tag. The BRCA1 c.190T>C (p.Cys64Arg), c.199G>T (p.Asp67Tyr) and c.181T>G (p.Cys61Gly) mutants were obtained by direct mutagenesis of pMRBAD-BRCA1-CfrGFP using the QuikChange XL Site-directed Mutagenesis Kit (Stratagene) according to the manufacturer's instruction. Recombinant clones were checked by DNA sequencing.

GFP-fragment reassembly screening

Compatible pairs of plasmids [pET11a-NfrGFP-Z and pMRBAD-Z-CfrGFP; pET11a-NfrGFP-BARD1 and pMRBAD-BRCA1-CfrGFP (both as wild-type or mutant forms)] were co-transformed into BL21-(DE3) E. coli competent cells by electroporation. Single colonies were screened for the occurrence of GFP-fragment reassembly as previously described [15].Fluorescence was observed after excitation with long-wave (365 nm) UV light in combination with the short pass (SP) emission filter using a Syngene image capture system (SYNGENE) as specified by the manufacturer.

Purification of the reassembled GFP complexes

The H6-NfrGFP-Z/Z-CfrGFP-HA and H6-NfrGFP-BARD1/BRCA1-CfrGFP-HA (both as wild-type or mutant forms) complexes were purified from the soluble fraction of co-transformed E. coli strain BL21-(DE3) by Immobilized Metal Affinity Chromatography (IMAC) using nickel nitrilotriacetic (Ni-NTA) agarose resin (QIAGEN), following the protocol described [15]. The protein complexes were subjected to 13% SDS-PAGE and visualized by Western blotting using a polyclonal anti-GFP antibody (# 600-101-215; Rockland). Unpurified cell lysates from induced E. coli BL21-(DE3) bacteria were similarly resolved and visualized to detect expression levels of both NfrGFP-BARD1 and CfrGFP-BRCA1 recombinant proteins.

Clinical and pathological characteristics

Clinical and pathological data of affected mutation carriers were collected at genetic counseling and from medical records. Loss of heterozygosity (LOH) at BRCA1 locus in tumor DNA was performed as previously described [16].

Results

Geographical distribution and frequency of the BRCA1 c.190T>C families

The birth places of the probands of the 43 BRCA1 c.190T>C positive families are shown in Figure 1. The majority were from the city of Bergamo and its province (n = 23) or from neighboring provinces of the Lombardy region (n = 16). The frequencies of c.190T>C positive families on the total number of families tested for BRCA1 and BRCA2 mutations and on the total number of BRCA-positive families were 8.7% and 30.2%, respectively, in cases recruited in Bergamo and 0.8% and 3.2%, respectively, in cases recruited in Milan (Table 1).

An external file that holds a picture, illustration, etc.
Object name is pone.0086924.g001.jpg
Geographical distribution of BRCA1 c.190T>C (p.Cys64Arg) mutation carriers.

Symbol (“•”) indicates the birth places of index case from families segregating the mutation.

Table 1

Number and frequencies of BRCA1 c.190T>C positive families among those recruited at three Italian institutions and tested for BRCA mutations.
InstitutionNo. identified% on total tested families* % on BRCA1/2 families
INT 221,03 (22/2140)3,98 (22/553)
IEO 40,39 (4/1013)1,54 (4/260)
INT+IEO 260,82 (26/3153)3,20 (26/813)
AO-BG 168,74 (16/183)30,19 (16/53)
*Intake criteria for BRCA testing are described in Manoukian et al [38].

Haplotype analysis

Fragment analysis of 6 microsatellite marker loci intragenic and flanking BRCA1 identified a shared haplotype extending over 3 marker loci (0.4 cM) in carriers of the BRCA1 c.190T>C from 20 families for which DNA of more than one member was available (Figure 2). In one additional mutated family with only one individual available for the analysis, the observed genotypes were compatible with the shared haplotype.

An external file that holds a picture, illustration, etc.
Object name is pone.0086924.g002.jpg
Haplotype branching trees in families segregating the BRCA1 c.190T>C (p.Cys64Arg).

The six short tandem repeat markers analyzed are shown together with their position in the Marshfield genetic map. Family haplotypes are indicated with the corresponding family ID codes. The most common haplotype is indicated in bold numbers.

Age estimate of the BRCA1 c.190T>C mutation

The DMLE+2.2 program was used to estimate the age of the BRCA1 c.190T>C mutation based on haplotype data from mutation carriers and non carriers.

Three separate analyses were performed, using a population growth rate per generation of 0.052 and different estimates of the proportion of sampled mutation-carrying chromosomes (0.015, 0.01 and 0.005). The resulting age estimates were 124 generations (95% credible set: 79–170), 130 generations (95% credible set: 91–170) and 134 generations (95% credible set: 97–171), respectively (data not shown). Assuming an interval of 25 years per generation, this corresponds to the mutation being 3,100, 3,250 and 3,350 years old, respectively. Thus, age estimates were only slightly affected by the actual proportion of sampled mutation-carrying chromosomes.

Evaluation of the effect of the BRCA1 c.190T>C variant on mRNA transcripts

The BRCA1 c.190T>C variant is mapped to an alternatively used donor splice site. The usage of this site leads to the synthesis of a naturally occurring isoform missing 22 bp at the 3′-end of exon 5 (Δexon5q) [17], [18]. To evaluate the putative effect of the mutation on Δexon5q and full-length transcription levels, the cDNA region encompassing the mutation site was amplified and analyzed by capillary electrophoresis. The ratio between the peak areas of the Δexon5q and the full-length isoforms in LCLs carrying the c.190T>C, cultured in the presence and in the absence of cycloheximide, was calculated and compared with those of wild-type LCLs (Figure 3). The LCL carrying the BRCA1 c.212G>A mutation previously reported to up-regulate the Δexon5q isoform [14] was used as internal control. A significant decrease in the ratio of the Δexon5q vs. full length expression levels was observed in the c.190T>C LCLs compared to normal controls (0,45, 95% CI = 0.44–0.46 and 0.52, 95%, CI = 0.50–0.54, for the CHX-untreated and treated samples, respectively). Sequence analyses detected the presence of the mutation in the full length cDNA (data not shown). These results indicate that the c.190T>C mutation does not impair the synthesis of full-length mRNA and are consistent with a sustained expression of the mutated protein.

An external file that holds a picture, illustration, etc.
Object name is pone.0086924.g003.jpg
Semi-quantitative fragment analysis of the Δexon5q isoform.

The upper panel shows the capillary electrophoresis patterns of the cDNA fragments spanning BRCA1 exons 5 and 6 observed in LCLs from a BRCA1 wild type individual, and from carriers of the c.190T>C and c.212G>A, which causes the up-regulation of the Δexon5q transcript, mutations. The Δexon5q and full-length (FL) isoforms are indicated. The lower panel shows the ratio between the peak areas of the Δexon5q and full-length isoforms. The LCLs were cultured in the presence (dark grey bars) and in the absence (light grey bar) of cycloheximide. Control bars represent the average value observed in six wild-type LCLs. c.190T>C bars represent the average value observed in four mutant LCLs. The error bars represent standard deviation.

Evaluation of the effect of the c.190T>C mutation on the interaction of BRCA1 with BARD1

The BRCA1 protein displays an E3 ubiquitin ligase activity mediated by the interaction with BARD1 through its N-terminal RING-finger domain [19], [20], where the c.190T>C (p.Cys64Arg) is located.

To assess whether the mutation affects the BRCA1/BARD1 complex formation, we carried out a GFP-fragment reassembly screening, a Bimolecular Fluorescence Complementation-based assay (BiFC) [21]. In this assay, the GFP is dissected into two fragments (NfrGFP and CfrGFP) that, when expressed together in E. coli cells, do not spontaneously reassemble into a fluorescence protein. However, if the two fragments of GFP are each individually fused to two interacting proteins, this interaction can mediate reassembly of the GFP in co-transformed bacteria with consequent cellular fluorescence [22].

Under inducing conditions (0.2% L-arabinose and 20 µM IPTG; Fig. 4A, left column), bright fluorescence was observed in bacterial cells co-expressing BARD1-NfrGFP together with BRCA1-wild type/CfrGFP or BRCA1-D67Y/CfrGFP carrying the variant p.Asp67Tyr, previously classified as clinically neutral [3] and the strong interacting anti-parallel Z-NfrGFP/Z-CfrGFP fusion peptides. No fluorescence was observed in bacteria co-expressing the following fusion peptides: non cognate BARD1 NfrGFP/CfrGFP-Z, BARD1-NfrGFP/BRCA1-C61G-CfrGFP carrying the p.Cys61Gly disease-causing mutation [23], and BARD1-NfrGFP/BRCA1-C64R-CfrGFP carrying the p.Cys64Arg mutation. In addition, IMAC purified reassembled complexes from the soluble fraction of co-transformed cells E. coli BL21-(DE3) were analyzed by Western blotting (Figure 4B). Using a polyclonal anti-GFP antibody, two strong bands corresponding to the components of the GFP reassembled complexes were detected in lysates of bacterial cells co-expressing Z-NfrGFP/CfrGFP-Z and BARD1-NfrGFP together with BRCA1-wild type/CfrGFP or BRCA1-Asp67Tyr. Much more reduced bands were observed in cell lysates co-expressing BARD1-NfrGFP and BRCA1-Cys61Gly/CfrGFP or BRCA1-Cys64Arg/CfrGFP. Since unassembled GFP fusion fragments are unfolded and less soluble [24], these results indicate GFP reassembly and, therefore, BRCA1/BARD1 binding for the BRCA1-wt and BRCA1-Asp67Tyr constructs, but not for the BRCA1-Cys61Gly and BRCA1-Cys64Arg constructs. These observations are consistent with those obtained by fluorescence complementation assay. Unpurified cell lysates from co-transformed E. coli BL21-(DE3) bacteria, were visualized by Western blotting with a polyclonal anti-GFP antibody, revealing that all the fusion peptides were expressed to a similar extent (Figure 4C). This demonstrates that the lack of co-purification of CfrGFP-BRCA1-HA fragments for the Cys61Gly and Cys64Arg constructs is attributable to the lack of binding to BARD1 and not to poor expression of the BRCA1 mutants.

An external file that holds a picture, illustration, etc.
Object name is pone.0086924.g004.jpg
Detection of BRCA1/BARD1 interaction by GFP-fragment reassembly screening.

(a) Fluorescence was observed after 24 h of growth at 30°C followed by 2 days of incubation at RT. No fluorescence is observed under non-inducing condition (right column). [L-ara, L-arabinose; IPTG, Isopropyl β-D-1-tiogalattopiranoside, IPTG]. (b) SDS-PAGE of purified, reassembled complexes by IMAC methods. The expected molecular masses are indicated on the left. [*Non-specific band. BN, H6-NfrGFPBARD1; ZN, H6-ZNfrGFP; ZC, ZCfrGFP-HA]. (c) Expression of NfrGFP-BARD1 and CfrGFP-BRCA1 wild-type and mutant forms.

Clinical and pathological features of BRCA1 c.190T>C carriers

Overall, a total of 86 ascertained mutation carriers and of 7 obligate carriers were identified in the families recruited in the study, including 83 females and 10 males. Among female carriers, 55 (66%) reported a diagnosis of breast carcinoma (n = 38), ovarian carcinoma (n = 12) or both breast and ovarian carcinomas (n = 5).

Available clinical and pathological features of the affected female carriers are reported in Table 2 and and3.3. The median ages of breast cancer and ovarian cancer diagnosis were 39.6 and 48.2 years, respectively. The large majority of breast cancers were of high grade (23/28 = 82.1%). The prevalent histological type was ductal (32/38 = 84.2%), being the remaining cases mostly of the medullary type (4/38 = 10.5%). The frequencies of cancers positive for estrogen receptor (ER), progesterone receptor (PR) and human epidermal growth factor receptor 2 (HER2/Neu) were 4/31 (12.9%), 6/31 (19.4%) and 3/22 (13.6%), respectively. The information for all the above tumor markers was available in 23 cases, and the majority (15 = 65.2%) displayed a triple-negative (TN) phenotype (lack of the expression of ER, PR and HER2/Neu). The frequencies of contralateral breast cancer were 8/18 (44.4%) and 12/15 (80%) 5 and 10 years after the first diagnosis of breast cancer, respectively. Three patients were diagnosed with additional cancers, including one malignant mixed mullerian tumor (MMMT) of the endometrium, one endometrial carcinoma, and one basal cell carcinoma. As for ovarian cancers, the large majority were of high grade (10/11 = 90.9%) and of the serous type (9/11 = 81.8%). Of the remaining female carriers, one reported a pheochromocytoma at 27 years, and 27 were cancer-free at the time of last contact (mean age = 41 years).

Table 2

Clinical and pathological features of BRCA1 c.190T>C related breast cancer cases.
Breast Cancers (n = 43)
n%
Age at first diagnosis (years)
<361534.9
362251.2
>50614.0
Median39.6
Behaviour
Invasive40100
In situ--
Not available3
Histological types
Ductal3284.2
Lobular--
Medullary410.5
Combineda 12.6
Other12.6
Not available5
Histological grade
127.1
2310.7
32382.1
Not available15
ER
Positive412.9
Negative2787.1
Not available12
PR
Positive619.4
Negative2580.6
Not available12
Her2/Neu
Positive313.6
Negative1986.4
Not available21
Triple Negative
Yes1565.2
Not834.8
Not available20
aDuctal and lobular type.

Table 3

Clinical and pathological features of BRCA1 c.190T>C related ovarian cancer cases.
Ovarian cancers (n = 17)
n%
Age at first diagnosis (years)
<36--
361270.6
>50529.4
Median48.2
Behaviour
Invasive13100
In situ--
Not available4
Histological types
Serous981.8
Mucinous--
Endometroid218.2
Clear Cell--
Other--
Not available6
Histological grade
1--
219.1
31090.9
Not available6

Three cancer diagnoses were reported in male carriers, one prostate carcinoma, one tumor of the central nervous system and one leukemia.

LOH at BRCA1 locus was investigated in two tumors, one breast carcinoma and the MMMT. In both cases, the loss of the constitutional wild-type allele was observed (data not shown).

Discussion

The BRCA1 c.190T>C mutation was firstly described in a large Polish cancer family [25]. Subsequently, it was reported in an Italian family characterized by high prevalence of ovarian and breast cancer cases by Willems and co-authors [26]. These authors showed by molecular modeling that the mutation may induce profound modifications in the structure of the BRCA1 RING finger motif, without affecting the normal splicing pattern of the transcripts.

A total of 43 apparently unrelated Italian families carrying the same mutations were referred by four different Italian clinical and university centers. The observation that a large part (23/43 = 53%) were from the same geographic area, the province of Bergamo in Northern Italy, strongly suggested an origin of the mutation from a common ancestor. Consistently, the frequencies of c.190T>C families on the total number of those that underwent BRCA gene testing and of those carrying pathogenic BRCA1 and BRCA2 mutations were approximately 10-fold higher in cases recruited in Bergamo, around 85% of whom referred to be born in the local area, compared to those observed in families recruited in two large cancer centers in Milan, which attract patients from all over Italy. The analysis of microsatellite marker loci revealed a shared haplotype in 21 typed families, confirming the founder effect hypothesis. In addition, we estimated the origin of this mutation within a time interval ranging from 3100 to 3350 years ago.

Interestingly, the c.190T>C affects the same nucleotide of another mutation (c.190T>G) that strengthen an alternatively used donor splice site in exon 5 and also disrupts a putative exonic splicing enhancer motif. This leads the loss of the natural donor splice site, resulting in the lack of full length expression and the up-regulation of the naturally occurring Δexon5q isoform, predicted to lead to the synthesis of a truncated protein [17], [18]. In agreement with previous observations [26], no such effect was observed for the c.190T>C. Conversely, in the LCL carrying this mutation a reduction in the relative amount of Δexon5q compared to full length was observed. This finding and the detection of the c.190T>C in the full-length cDNA is consistent with a stable expression of the Cys64Arg protein in mutation carriers.

The BRCA1 p.Cys64Arg mutation is located to the gene region coding for the RING-finger motif of the protein. The RING-finger motif is defined by a conserved pattern of seven cysteine and one histidine residues arranged in an interleaved fashion forming two distinct Zn2+-binding sites termed Site I and Site II [27]. Approximately 10% of the clinically relevant mutations of BRCA1 currently reported in the Breast Cancer Information Core (BIC) database (URL: http://research.nhgri.nih.gov/bic/) map within the N-terminal 100 residues-RING domain, which contain the RING motif (residues 23–76). Functional analyses have shown that these mutations abrogate the ubiquitin-ligase activity of BRCA1 by interfering with both the heterodimerization between BRCA1 and BARD1 and the binding of E2 protein UbcH5c to the BRCA1/BARD1 complex [28], [29].

Presently, the BRCA1 p.Cys64Arg mutation is reported in the BIC database as a variant of unknown clinical relevance. However, in silico analysis using SIFT (URL: http://sift.jcvi.org/), Polyphen-2 (URL: http://genetics.bwh.harvard.edu/pph2/) and Align-GVGD (URL: http://agvgd.iarc.fr/) bioinformatics tools unanimously predicted the BRCA1 p.Cys64Arg to be deleterious. This is consistent with the notion that Cys64Arg disrupts a critical cysteine residue required for the ubiquitin-ligase activity of BRCA1, through its binding to BARD1 [30]. In fact, the analysis of the three-dimensional Nuclear Magnetic Resonance (NMR) structure of the BRCA1/BARD1 heterodimer showed that p.Cys64Arg substitution determines a profound rearrangement of the BRCA1 39–41 amino acid residues, predicted to result into the impairment of the BRCA1/BARD1 interaction [26].

The result of our GFP-fragment reassembly assay provided experimental evidence that the p.Cys64Arg actually abrogates BRCA1/BARD1 binding as the proven disease causing mutation p.Cys61Gly [31], thus further supporting the pathogenic role of this variant. Interestingly, another mutation affecting the same amino acid residue (p.Cys64Gly) was previously reported to have a similar effect [32]. In addition, our study indicates that this functional approach might be applied to the assessment of the clinical significance of a number of variants in cancer-predisposing genes, implementing currently used strategies.

The median age of breast cancer diagnosis in carriers of the c.190T>C mutation (39.7 years) was similar to that observed in 425 breast cancer patients with other pathogenic BRCA1 mutations ascertained at the institutions participating in this study (40.1 years). Conversely, among c.190T>C carriers the median age of ovarian cancer onset (48.2 years) was lower than that observed in 192 BRCA1-positive ovarian cancer patients from the same institutions (51.9 years), suggesting a possible higher risk of ovarian cancer in carriers of the c.190T>C compared to carriers of other BRCA1 mutations.

Breast cancers arising in BRCA1 c.190T>C mutation carriers showed the peculiar histopathological features of the BRCA1-related breast tumor [33], [34], with a propensity to be high grade invasive ductal or medullary carcinomas. In addition, the majority displayed a TN phenotype. The clinical relevance of the TN breast cancers is highlighted by the distinctive poor prognosis and no clear options for receptor targeted treatment [35], [36]. In agreement with other reports on BRCA1 associated ovarian carcinomas [37], [38], invasive epithelial cancer of serous histology was found to be the most common histological subtype among BRCA1 c.190T>C mutation carriers. Although these observations might be biased by the relative small number of ascertained individuals and by the preferential selection of high risk subjects referred to genetic testing, they are consistent (together with the findings that in two examined tumors the wild type BRCA1 allele was lost) with the c.190T>C behaving as other BRCA1 pathogenic variants.

In conclusion, our data show that the BRCA1 c.190 T>C missense mutation (p.Cys64Arg) is a founder mutation of clinical relevance recurrent in high-risk families from the province of Bergamo, accounting for a significant fraction (ca. 9%) of those ascertained at the local city hospital. Additional studies are needed to assess the actual proportion of carriers of this mutation in this district and its frequency in unselected breast/ovarian cancer patients. This will allow evaluating whether screening for the c.190T>C mutation can be suggested as a cost-effective strategy for the rapid identification of at-risk individuals in the Bergamo area. In addition, they will provide a measure of associated cancer risks, thus improving decision-making regarding clinical management of mutation carriers.

Acknowledgments

We thank Giulietta Scuvera, Donata Penso, Maria Teresa Radice, Massimo Moro, Antonio Fiorino of INT and the personnel of the Cogentech Cancer Genetic Testing laboratory.

Funding Statement

This study was partially supported by funds from the Italian Association for Cancer Research (AIRC, http://www.airc.it/), grant no. 11897. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. No additional external funding was received for this study.

References

1. Peto J, Collins R, Barfoot R, Seal S, Warren W, et al. (1991) Prevalence of BRCA1 and BRCA2 Gene Mutations in Patients with Early-Onset Breast Cancer. J Natl Cancer I 91: 943–949. [Abstract] [Google Scholar]
2. Fackenthal JD, Olopade OI (2007) Breast cancer risk associated with BRCA1 and BRCA2 in diverse populations. Nat Rev 7: 937–948. [Abstract] [Google Scholar]
3. Easton DF, Deffenbaugh AM, Pruss D, Frye C, Wenstrup RJ, et al. (2007) A Systematic Genetic Assessment of 1,433 Sequence Variants of Unknown Clinical Significance in the BRCA1 and BRCA2 Breast Cancer–Predisposition Genes. Am J Hum Genet 81: 873–883. [Europe PMC free article] [Abstract] [Google Scholar]
4. Janavičius R (2010) Founder BRCA1/2 mutations in the Europe: implications for hereditary breast-ovarian cancer prevention and control. EPMA J 1: 397–412. [Europe PMC free article] [Abstract] [Google Scholar]
5. Tonin P, Weber B, Offit K, Couch F, Rebbeck TR, et al. (1996) Frequency of recurrent BRCA1 and BRCA2 mutations in Ashkenazi Jewish breast cancer families. Nat Med 2: 1179–1183. [Abstract] [Google Scholar]
6. Johannesdottir G, Gudmundsson J, Bergthorsson JT, Arason A, Agnarsson AB, et al. (1996) High Prevalence of the 999del5 Mutation in Icelandic Breast and Ovarian Cancer Patients. Cancer Res 56: 3663–3665. [Abstract] [Google Scholar]
7. Struewing JP, Hartge P, Wacholder S, Baker SM, Berlin M, et al. (1997) The risk of cancer associated with specific mutations of BRCA1 and BRCA2 among Ashkenazi Jews. New Engl J Med 336: 1401–1408. [Abstract] [Google Scholar]
8. Warner E, Foulkes W, Goodwin P, Meschino W, Blondal J, et al. (1999) Prevalence and penetrance of BRCA1 and BRCA2 gene mutations in unselected in Ashkenazi Jewish woman with breast cancer. J Natl Cancer Inst 9: 1241–1247. [Abstract] [Google Scholar]
9. Petrij-Bosch A, Peelen T, van Vliet M, van Eijk R, Olmer R, et al. (1997) BRCA1 genomic deletions are major founder mutations in Dutch breast cancer patients. Nat Genet 17: 341–345. [Abstract] [Google Scholar]
10. Puget N, Sinilnikova OM, Stoppa-Lyonnet D, Audoynaud C, Pagèes S, et al. (1999) An Alu-mediated 6-kb duplication in the BRCA1 gene: a new founder mutation? Am J Hum Genet 64: 300–302. [Europe PMC free article] [Abstract] [Google Scholar]
11. Neuhausen SL (2000) Founder populations and their uses for breast cancer genetics. Breast Cancer Res 2: 77–81. [Europe PMC free article] [Abstract] [Google Scholar]
12. Papi L, Putignano AL, Congregati C, ZannaI, Sera F, et al. (2009) Founder mutations account for the majority of BRCA1-attributable hereditary breast/ovarian cancer cases in a population from Tuscany, Central Italy. Breast Cancer Res Treat 117: 497–504. [Abstract] [Google Scholar]
13. Reeve JP, Rannala B (2002) DMLE+ Bayesan linkage disequilibrum gene mapping. Bioinforma Appl Note 18: 894–895. [Abstract] [Google Scholar]
14. Colombo M, De Vecchi G, Caleca L, Foglia C, Ripamonti CB, et al. (2013) Comparative In Vitro and In Silico Analyses of Variants in Splicing Regions of BRCA1 and BRCA2 Genes and Characterization of Novel Pathogenic Mutations. PLOS ONE 8 2: e57173 10.1371/journal.pone.0057173 [Europe PMC free article] [Abstract] [CrossRef] [Google Scholar]
15. Sarkar M, Magliery TJ (2008) Re-engineering a split-GFP reassembly screen to examine RING-domain interactions between BARD1 and BRCA1 mutants observed in cancer patients. Mol Biosyst 4: 599–605. [Abstract] [Google Scholar]
16. Ripamonti CB, Colombo M, Mondini P, Siranoush M, Peissel B, et al. (2013) First description of an acinic cell carcinoma of the breast in a BRCA1 mutation carrier: a case report. BMC Cancer 13 1: 46 10.1186/1471-2407-13-46 [Europe PMC free article] [Abstract] [CrossRef] [Google Scholar]
17. Claes K, Vandesompele J, Poppe B, Dahan K, Coene I, et al. (2002) Pathological splice mutations outside the invariant AG/GT splice sites of BRCA1 exon 5 increase alternative transcript levels in the 5′ end of the BRCA1 gene. Oncogene 21: 4171–5. [Abstract] [Google Scholar]
18. Yang Y, Swaminathan S, Martin BK, Sharan SK (2003) Aberrant splicing induced by missense mutations in BRCA1: Clues from a humanized mouse model. Hum Mol Genet 12: 2121–2131. [Abstract] [Google Scholar]
19. Hashizume R, Fukuda M, Maeda I, Nishikawa H, Oyake D, et al. (2001) The RING Heterodimer BRCA1-BARD1 Is a Ubiquitin Ligase Inactivated by a Breast Cancer-derived Mutation. J Biol Chem 276: 14537–14540. [Abstract] [Google Scholar]
20. Brzovic PS, Keeffe JR, Nishikawa H, Miyamoto K, Fox D III, et al. (2003) Binding and recognition in the assembly of an active BRCA1/BARD1 ubiquitin-ligase complex. Proc Natl Acad Sci U S A 2003; 100: 5646–5651. [Europe PMC free article] [Abstract] [Google Scholar]
21. Ghosh I, Hamilton AD, Regan L (2000) Antiparallel leucine zipper-directed protein reassembly: application to the green fluorescent protein. J Am Chem Soc 122: 5658–5659. [Google Scholar]
22. Magliery TJ, Regan L (2006) Reassembled GFP: detecting protein-protein interactions and protein expression patterns. Methods Biochem Anal 47: 391–405. [Abstract] [Google Scholar]
23. Brzovic PS, Meza J, King MC, Klevit RE (1998) The Cancer-predisposing Mutation C61G Disrupts Homodimer Formation in the NH2-terminal BRCA1 RING Finger Domain. J Biol Chem 273: 7795–7799. [Abstract] [Google Scholar]
24. Magliery TJ, Wilson CGM, Pan W, Mishler D, Ghosh I, et al. (2005) Detecting protein-protein interactions with a green fluorescent protein fragment reassembly trap: scope and mechanism. J Am Chem Soc 127: 146–157. [Abstract] [Google Scholar]
25. Jakubowska A, Gòrski B, Byrski T, Huzarski T, Gronwald J, et al. (2001) Detection of germline mutations in the BRCA1 gene by RNA-based sequencing. Hum Mutat 18: 943–949. [Abstract] [Google Scholar]
27. Xia Y, Pao GM, Chen HW, Verma IM, Hunter T (2003) Enhancement of BRCA1 E3 Ubiquitin Ligase Activity through Direct Interaction with the BARD1 Protein. J Biol Chem 278: 5255–5263. [Abstract] [Google Scholar]
28. Ruffner H, Joazeiro CAP, Hemmati D, Hunter T, Verma IM (2001) Cancer-predisposing mutations within the RING domain of BRCA1: Loss of ubiquitin protein ligase activity and protection from radiation hypersensitivity. PNAS 98: 5134–5139. [Europe PMC free article] [Abstract] [Google Scholar]
29. Morris JR, Pangon L, Boutell C, Katagiri T, Keep NH, et al. (2006) Genetic analysis of BRCA1 ubiquitin ligase activity and its relationship to breast cancer susceptibility. Hum Mol Genet 15: 599–606 10.1093/hmg/ddi476 [Abstract] [CrossRef] [Google Scholar]
30. Brzovic PS, Meza JE, King MC, Klevit RE (2001) BRCA1 RING Domain Cancer-predisposing mutations structural consequences and effects on protein-protein interactions. J Biol Chem 276: 41399–41406. [Abstract] [Google Scholar]
31. Spearman AD, Sweet K, Zhou XP, McLennan J, Couch FJ, et al. (2008) Clinically Applicable Models to Characterize BRCA1 and BRCA2 Variants of Uncertain Significance. J Clin Oncol 26: 5393–5400. [Europe PMC free article] [Abstract] [Google Scholar]
32. Wu LC, Wang ZW, Tsan TJ, Spillman MA, Phung A, et al. (1996) Identification of a RING protein that can interact in vivo with the BRCA1 gene product. Nat Genet 14: 430–440. [Abstract] [Google Scholar]
33. Lakhani SR, van de Vijver MJ, Jacquemier J, Anderson TJ, Osin PP, et al. (2002) The Pathology of Familial Breast Cancer: Predictive Value of Immunohistochemical Markers Estrogen Receptor, Progesterone Receptor, HER-2, and p53 in Patients With Mutations in BRCA1 and BRCA2. J Clin Oncol 20: 2310–2318 10.1200/JCO.2002.09.023 [Abstract] [CrossRef] [Google Scholar]
34. Mavaddat N, Barrowdale D, Andrulis IL, Domchek SM, Eccles D, et al. (2012) Pathology of Breast and Ovarian Cancers among BRCA1 and BRCA2 Mutation Carriers: Results from the Consortium of Investigators of Modifiers of BRCA1/2 (CIMBA). Cancer Epidemiol Biomarkers Prev 21: 134–147 10.1158/1055-9965.EPI-11-0775 [Europe PMC free article] [Abstract] [CrossRef] [Google Scholar]
35. Kennecke H, Yerushalmi R, Woods R, Cheang MCU, Voduc D, et al. (2010) Metastatic Behavior of Breast Cancer Subtypes. J Clin Oncol 20: 3271–3277. [Abstract] [Google Scholar]
36. Carey LA (2011) Directed Therapy of Subtypes of Triple-Negative Breast Cancer. The Oncologist 16 suppl 1: 71–78. [Abstract] [Google Scholar]
37. Shaw PA, McLaughlin JR, Zweemer RP, Narod SA, Risch H, et al. (2002) Histopathologic Features of Genetically Determined Ovarian Cancer. Int J Gynecol Pathol 21: 407–411. [Abstract] [Google Scholar]
38. Manoukian S, Peissel B, Pensotti V, Barile M, Cortesi L, et al. (2007) Germline mutations of TP53 and BRCA2 genes in breast cancer/sarcoma families. Eur J Cancer 43: 601–606. [Abstract] [Google Scholar]

Articles from PLOS ONE are provided here courtesy of PLOS

Citations & impact 


Impact metrics

Jump to Citations
Jump to Data

Citations of article over time

Smart citations by scite.ai
Smart citations by scite.ai include citation statements extracted from the full text of the citing article. The number of the statements may be higher than the number of citations provided by EuropePMC if one paper cites another multiple times or lower if scite has not yet processed some of the citing articles.
Explore citation contexts and check if this article has been supported or disputed.
https://scite.ai/reports/10.1371/journal.pone.0086924

Supporting
Mentioning
Contrasting
0
25
0

Article citations


Go to all (18) article citations

Data 


Similar Articles 


To arrive at the top five similar articles we use a word-weighted algorithm to compare words from the Title and Abstract of each citation.