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In our previously published article by Brandão et al. [1], we reported that the unclassified variant (UV) BRCA1 c.4987-3C>G gives rise to BRCA1Δ17. However, since we could not exclude residual expression of the full-length transcript from the variant allele, we have classified the variant as likely pathogenic. We now have evidence that the variant is indeed pathogenic.
Allele-specific PCRs are useful to determine the relative contribution of each allele to the synthesis of full-length or alternative transcripts. This can be achieved with, for instance, Sanger sequencing of the RT-PCR products and the use of a heterozygous variant to establish allelic expression ratios [1]. Unfortunately, in this family neither the proband nor the relatives tested for the BRCA1 c.4987-3C>G variant were heterozygous for a polymorphism in the region of the spliced exon. Since the UV is not exonic, it could not be used to determine allelic expression. Consequently, in our previously published article, using RT-PCRs on RNA isolated from primary cultured lymphocytes, we failed to determine whether the UV allele was still giving rise to some full-length BRCA1 transcript. To establish the pathogenicity of this variant, we performed an additional study using an ex vivo assay based on a splicing reporter minigene. We selected the exon-trapping vector pSPL3b [2] (a kind gift from Dr. R Sedlmeier, Ingenium Pharmaceuticals GmbH), previously used for similar studies [3–5]. Initially, BRCA1 exon 17 was amplified including the surrounding intronic regions from the proband’s DNA and one additional control, using primers that contained restriction sites XhoI and EcoRV in their 5′ ends. PCR products and vector were digested with the two enzymes and subsequently used in a ligation reaction, after purification with QIAquick PCR Purification Kit (QIAGEN). The structure of the minigenes is shown in Fig. 1a. After transformation of competent E. coli DH5α (Invitrogen), independent colonies were selected with minigenes containing the variant allele from the patient, WT alleles from the patient and from the controls. All constructs were verified by sequence analysis and confirmed the absence of changes in the constructs. These minigenes and the empty vector were transfected into HeLa cells. Transfection was performed in duplicate with FuGENE HD transfection reagent (Promega) according to the manufacturer’s protocol.
After RNA extraction from the transfected HeLa cells and reverse transcription, the cDNA was amplified using primers in each of the flanking exons of the vector pSPL3b, which we named A and B for clarity (Fig. 1a). The results obtained are shown in Fig. 1b. The WT allele of the patient and of a healthy control show only one band in the agarose gel, with a larger size than that observed for the empty vector. Sequencing confirmed that the RT-PCR products contain exon 17 (Fig. 2). The variant allele of the patient shows a prominent lower band of the same size as the empty vector indicating exon 17 skipping, which was confirmed by sequencing. In addition, a faint unexpected upper band can be observed for the variant allele. Sequencing of the two bands separately, by excision of the bands from the gel, revealed this to be a transcript containing part of intron 17. In Fig. 2, the sequence of this transcript is shown but it contains a background sequence of the transcript lacking exon 17 (the lower band on the gel). This is due to heteroduplex formation between the two fragments, which occurs due to the high similarity between them as both contain exons A and B. The intron 17 retention starts at the beginning of intron 17, position c.5074+1, and the donor splice site is at position c.5074+153. This is possible since the original donor splice site of exon 17 is also predicted to be a strong acceptor splice site (AG|GTATAC, 76% score) by the Splice Site Finder-like algorithm and Human Splice Finder (recently added to the Alamut software), as observed using Alamut (Interactive Biosoftware), which integrates several splice site prediction algorithms. The c.5074+153 is predicted to be a weak donor splice site by two algorithms (5 and 11% by MaxEntScan and GeneSplicer, respectively) but strongly predicted by the Human Splice Finder algorithm (79%). This intronic region is not observed in the WT alleles used in the ex vivo assay, neither in the previous results from the IL2/PHA stimulated lymphocytes. We conclude that the intron retention is an artefact in the in vitro system caused by skipping of exon 17 and activation of cryptic splice sites.
Summarising, using an ex vivo assay to complement the previous RT-PCR analysis on RNA from IL2/PHA stimulated lymphocyte cultures [1], we were able to show that the variant allele from the patient results only in exon 17 skipping since a transcript containing exon 17 was not detected. The deletion of BRCA1 exon 17 is a frameshift event that leads to a truncated protein: p.Val1665SerdelfsX9. In combination with the results from the previously reported RT-PCR analysis, we are now confident that the BRCA1 c.4987-3C>G variant is pathogenic and can be genetically counselled as such.
References
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Acknowledgments
Rita D. Brandão was supported by Portuguese grants: Fundação Calouste Gulbenkian (79117), and Fundação para a Ciência e Tecnologia (SFRH/BD/32386/2006). We would also like to thank Alberto Acedo for the helpful discussion about the ex vivo assay.
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The authors declare that they have no conflict of interest.
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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Brandão, R.D., van Roozendaal, K.E.P., Tserpelis, D. et al. BRCA1 c.4987-3C>G is a pathogenic mutation. Breast Cancer Res Treat 131, 723–725 (2012). https://doi.org/10.1007/s10549-011-1878-3
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DOI: https://doi.org/10.1007/s10549-011-1878-3