Summary

METHODS
Containing 26 genes in 2016-2017 variants of patients with pathogenic/likely pathogenic/VUS detected in the Hereditary Cancer Panel were analyzed again in 2022 on Clinvar (https://www.ncbi.nlm.nih.gov/ clinvar/) and other databases.

RESULTS
The results of a total of 137 patients, 137 women and 2 men, were evaluated. While no pathogenic/ likely pathogenic/VUS variant was detected in the results of 95 patients, at least 1 variant was detected in 42 female patients. A total of 58 variants were detected in 42 patients, and we found that 24 variants among them fell into a different class. While 12 more variants were included in the lower pathogenicity subgroup, 5 of them were higher in pathogenicity. We saw that 6 variants that were not yet identified in 2016-2017 were identified, except for 1 of them.

CONCLUSION
We have seen that the pathogenicity of the variants written in patient reports, which can cause serious changes in the patient"s life, can change over time. While giving genetic counseling about these variants, it should be stated that much more comprehensive research and information should be given to the patient, this information was given to the patient under the current conditions and that there may be a possibility of change in the future.

Introduction

Multigene panel tests have become increasingly widespread as a result of developing Next Generation Sequencing Systems, and genetic tests have become cost-effective for especially hereditary cancers.[2]

The National Comprehensive Cancer Network has expanded testing criteria for high-penetrance breast and/or ovarian cancer susceptibility genes including BRCA1, BRCA2, CDH1, PALB2, PTEN, and TP53, among others that have found to be associated with hereditary risk.[3] Some are part of rare highpenetrance cancer predisposing syndromes (e.g. BRCA1, BRCA2, TP53, CDH1, PTEN, STK11, and PALB2),[4,5] while others are moderate-penetrance genes (e.g. ATM, NBN, CHEK2, and BARD1).[6] Pathogenic variants in PALB2, ATM, CHEK2, NBN, BRIP1, RAD51C, and RAD51D are associated with a ywo-fold to five-fold increase in relative risk for certain cancers. However, because of cancer syndrome heterogenity, it is often difficult for providers to determine which cancer predisposition genes to test in a patient whose family or personal history is suggestive of a hereditary cancer syndrome.[7,8]

The most effective way to identify germline mutations of different clinical significance is to analyze hereditary cancer susceptibility genes that increase the risk with the NGS method. ACMG/AMP 2015 was the first guide to variant interpretation classifying a variant as "pathogenic," "probably pathogenic," "benign," "probably benign" and "VUS."[9] Some of the databases used for variant analysis and clinical significance are:

• ClinVar (https://www.ncbi.nlm.nih.gov/clinvar/)

• Human Gene Mutation Database (HGMD) (license required for professional version) (http://www. hgmd.org/).[10]

• Leiden Open Variation Database (LOVD) (https:// www.lovd.nl/).[11]

• Simple ClinVar (http://simple-clinvar.broadinstitute. org/).[12]

VUS is a term used to describe a class of variables of uncertain clinical significance that does not provide any useful information for clinical decision making.

In recent years, the number of studies related to hereditary cancer susceptibility genes has been increasing. With updated information, reevaluation of the VUS of these genes may reveal new clinical information. This information may require changes in diagnosis and treatment protocols in hereditary cancer patients.

Indeed, some recent studies in USA, China and Korea show that there have been changes in the clinical significance of BRCA variants over the years.

How to treat cancer in pathogenic and benign variants in hereditary cancer genes is certain. However, VUSs are in the gray zone and clinicians remain undecided about how to treat that cancer. In this study, we investigated the change in clinical significance of VUSs over time (2022) in patients whose hereditary cancer panel was studied in 2016-2017. As a result, the approach to the uncertain situation in VUS carriers will be evaluated.

Methods

A total of 137 female and two male breast cancer patients were included in the study. The mean age for women was 37.8. Men's ages were 48 and 56.

All patients selected according to these criteria were informed about the test, and consent forms were signed. DNA isolation was performed with automated systems and standard protocols from peripheral blood samples collected in EDTA tubes. As part of the test, genes were sequenced with the Multiplicom BRCA hereditary MASTR Plus kit. Next generation sequencing was done with Illumina MiSeq platform, variant calling and bioinformatics analysis were done with genomize- Seq (http://seq.genomize.com) (Analysis Version = BWA-Freebayes-Trimmomatic primer trim (v.9), Annotation Version= Ensembl).

In the panel analyzed within the scope of hereditary breast cancer, 6 were high (BRCA1, BRCA2, TP53, STK11, PTEN, and CDH1) and 9 were moderate (ATM, NBN, MUTYH, CHEK2, BLM, MLH1, MSH2, MSH6, and PMS2), and 11 were low risk (BARD1, BRIP1, RAD50, RAD51C, RAD51D, MRE11A, EPCAM, FAM175A, PALB2, MEN1, and XRCC2), a total of 26 genes are sequenced.

Only "Pathogenic (P)," "Likely Pathogenic (LP)" and "Variant of Unknown Significance (VUS)" have been reported. During the analysis, changes other than these variants were not reported according to the current scientific information in 2016-2017.

In January 2022, the variants of these patients were re-controlled from Clinvar (https://www.ncbi.nlm.nih. gov/clinvar/), ACMG, and other databases, (https:// search.ngscloud.com/) and the changings were recorded. The changing of variants was evaluated in the approximately 5-year period between the two dates.

Results

Table 1: Hereditary cancer panel variants of all patients included in the study

Table 1 Cont:

A total of 58 different gene variants were found in 42 patients. The number of genes with clinical significance changes was 24/58 (41.37%) between the mentioned years (Table 1).

Of the Variants (5) detected as Benign in 2022, 4 were previously identified as VUS and one was Undefined in 2016. In 2022, 2 Likely Benign Variant were detected. BRCA1:c.3541G>A was previously VUS but was defined as Likely Benign in 2022. NBN:c.415A>G was previously likely pathogenic interestingly it is defined as Likely Benign in 2022.

When variant changes were evaluated without gene discrimination, 13 of the 24 changes were downgrade, 5 were upgrade, and 6 were new variants that were not yet defined in the variant databases in 2016 (Table 1).

Table 2 shows the variant's clinical significance changes between 2016 and 2022. The remarkable thing in this table was that all but 1 of the previously undefined variants were identified. (4 VUS, 1 LP, 1 Benign). This shows the speed with which the clinical significance of novel variants is interpreted.

Table 2: Comparison of the classification of pathogenicity of 58 variants we detected in 42 patients in 2016-2017 compared to 2022

Discussion

About two-thirds of VUSs in the KOHBRA study by Kim et al.[15] were reclassified as benign or likely benign [193/278] BRCA1 patients (69.42%), BRCA2 patients 328/453 (72.41%), and all patients 471/676 (69.67%). One-third of the mutation types classified as VUS in the KOHBRA study were downgraded as benign or likely benign (20/58 mutations in BRCA1 and 25/91 mutations in BRCA2).

Mighton et al.[16] identified 1209 BRCA1 and BRCA2 variants between 2012 and 2017. During this period, 12.4% (150/1209) of variants were reclassified. The majority of reclassified variants were downgraded (74.7%). Of the reclassified variants, 63.3% (95/150) were reclassified to benign, 20.7% to likely benign, 10.0% to variant of uncertain significance, 2.0% to likely pathogenic, and 4.0% to pathogenic. Discordant ClinVar submissions were found for 40.4% (488/1209) of variants. In our study, the 14/24 (33.6%) variant was changed to downgrade and the 5/24 (20.83%) variant to upgrade, as in other studies. In addition, 6 novel variants that were not previously available in databases were identified. Macklin et al.[17] also reported that over the years, most of the VUSs (29/40) were converted to benign or LB variants, just like in our study.

As seen in all reclassification studies, including ours, most VUSs transform into B or LB variants over time. Therefore, treating VUSs as pathogenic variants may increase the rate of unnecessary bilateral mastectomy. Re-analysis of this variant at regular intervals in patients with VUS will be important in terms of monitoring and guiding the treatment.

Conclusion

This study represents relatively few variants and consists of data from one laboratory whose policies may differ from other laboratories, limiting the generalizability of these results. Despite these limitations, this study provides inspiration about the speed and importance of ClinVar variants reassortment in genes that increase breast cancer risk. This should be taken into account when arranging the treatment of patients, and overly aggressive attitudes in prophylaxis and treatments should be avoided. Future research should consider more broadly the impact of variant reclassifications on patients and the healthcare system.

Peer-review: Externally peer-reviewed.

Conflict of Interest: All authors declared no conflict of interest.

Ethics Committee Approval: The study was approved by the Memorial Şişli Hospital Non-interventional Clinical Research Ethics Committee (no: 005, date: 09/08/2022).

Financial Support: None declared.

Authorship contributions: Concept - Y.Özdemir; Design - Y.Özdemir, M.D.; Supervision - Y.Özkul; Funding - None; Materials - Y.Özkul, M.Ç.; Data collection and/ or processing - Y.Özdemir, S.S.; Data analysis and/or interpretation - Y.Özdemir, A.K.; Literature search - M.Ç., A.K., S.S.; Writing - Y.Özdemir, M.Ç., S.S.; Critical review - M.D, Y.Özkul

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