Abstract
In tumor-only next-generation sequencing (NGS), identified variants have the potential to be secondary findings (SFs), but they require verification through additional germline testing. In the present study, 194 patients with advanced cancer who underwent tumor-only NGS between April 2015 and March 2018 were enrolled, and the incidences of possible and true SFs were evaluated. Among them, 120 patients (61.9%) harbored at least one possible SF. TP53 was the most frequent gene in which 97 variants were found in 91 patients (49.5%). Nine patients provided informed consent to undergo additional germline testing, and a total of 14 variants (BRCA1, n = 1; BRCA2, n = 2; PTEN, n = 2; RB1, n = 1; SMAD4, n = 1; STK11, n = 1; TP53, n = 6) were analyzed. Three variants (BRCA1, n = 1; BRCA2, n = 2) were confirmed to be SFs, whereas TP53 variants were confirmed to be somatic variants. To confirm the low prevalence of SFs in TP53, we analyzed 24 patients with TP53 variants who underwent a paired tumor–normal NGS assay. As expected, all TP53 variants were confirmed to be somatic variants. A total of 30 patients were tested for germline variants in TP53, but none of them resulted in true SFs, suggesting the low prevalence of SFs in this gene. Therefore, the significance of additional germline testing for TP53 variants appears to be relatively low in daily clinical practice using a tumor-only NGS assay, unless patients have any relevant medical or family history.
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Introduction
Next-generation sequencing (NGS)-based multiplex gene assays are utilized to identify variants that predict the response or resistance to a specific drug in patients with cancer, and its use is rapidly increasing in daily clinical practice [1,2,3,4,5,6]. In addition, NGS assays can potentially uncover pathogenic germline variants, referred to as incidental or secondary findings (SFs) [7, 8]. The American College of Medical Genetics and Genomics (ACMG) has issued recommendations for the reporting of SFs to patients relating to 59 genes responsible for several hereditary diseases [8, 9]. The French Society of Predictive and Personalized Medicine has also published guidelines for the reporting of SFs relating to 60 cancer-related genes [9].
In a paired tumor–normal NGS assay, germline variants can be identified independently. Previous studies have reported that the prevalence of SFs in paired tumor–normal sequencing assays ranged between 3.3 and 17.5% [10,11,12,13,14,15]. NGS assays using only tumor DNA (tumor-only sequencing) are more commonly used in clinical practice to search for somatic mutations in tumor tissues, but they can also identify possible germline variants that can lead to SFs [1, 3, 6, 16]. However, to confirm the presence of true SFs, additional genetic testing using a matched germline DNA is necessary, and this verification process requires additional informed consent, cost, time and effort [16, 17].
The tumor suppressor TP53 is the most commonly mutated gene in several types of cancer. Germline mutations in this gene are also known to be responsible for a rare hereditary disease, Li–Fraumeni syndrome (LFS). In tumor-only NGS assays, numerous TP53 mutations can be identified; however, their origins are not always confirmed by additional germline analysis, as it requires substantial time and effort. Therefore, the clinical significance of this germline verification has not been evaluated in detail.
In the present study, we evaluated the incidence of possible SFs in ACMG-recommended genes in a tumor-only NGS assay and the clinical significance of additional germline testing to verify true SFs. Furthermore, we analyzed the data of 50 patients who underwent tumor–normal NGS assays and integrated data to assess the prevalence of germline variants in TP53.
Methods
Patient population
Between April 2015 and March 2018, a total of 194 patients with histopathologically confirmed solid tumors underwent a tumor-only NGS-based multiplex gene assay (OncoPrime™) at Kyoto University Hospital (Kyoto, Japan). In addition, a total of 50 patients underwent a paired tumor-only NGS assay, of which 30 patients also underwent the tumor-only NGS assay mentioned above (Supplementary Fig. 1). These assays were performed in patients with cancer of unknown primary site, rare tumors, and solid tumors refractory to standard chemotherapy. The present study was approved by the Ethics Committee of the Kyoto University Graduate School of Medicine (Kyoto, Japan; G692 and G1005). All patients provided written informed consent for the use of genomic and clinical data for research purposes.
Patient medical and family history
Definite information regarding patient medical history and family histories of cancer were used to characterize the patients. Medical and family histories of LFS were assessed for patients with possible germline variants in TP53 in accordance with either the classical LFS criteria or the Chompret criteria [18]. LFS-related cancer was defined as including sarcoma, breast cancer, brain cancer, adrenocortical carcinoma, leukemia, and lung cancer. Medical and family histories of hereditary breast and ovarian cancer (HBOC) were assessed for patients with possible germline variants in BRCA1 or BRCA2 in accordance with the genetic risk criteria, which were based on the National Comprehensive Cancer Network (NCCN) Clinical Practice Guidelines in Oncology, Genetic/Familial High-Risk Assessment: Breast and Ovarian, version 1, 2018. HBOC-related cancers were defined as including breast cancer, ovarian cancer, prostate cancer, and pancreatic cancer.
Tumor-only NGS assay
OncoPrime™ is a tumor-only NGS-based multiplex gene assay, which uses only tumor DNA for sequencing [6]. This assay is designed to scan mutations and small insertions and deletions in 215 cancer-related genes and structural rearrangements in 17 genes with clinical or preclinical relevance in human solid tumors (Supplementary Table 1). NGS and data analysis were performed as previously described [6]. After the NGS assay was ordered by the treating physician, 5–10 slices of 10 μm sections of archival formalin-fixed paraffin-embedded (FFPE) tumor tissue (tumor content ≥20%) were sent to a Clinical Laboratory Improvement Amendment (CLIA)-certified Laboratory of EA Genomics (Morrisville, NC, USA) and DNA extraction was performed by EA Genomics. The DNA extracted from fresh-frozen tumor tissues at our institution was sent to the Laboratory of EA Genomics. Solution hybridization targeted 3861 exons of 215 cancer-related genes and 59 introns of 17 genes commonly rearranged in human cancers using SureSelect XT reagent (Agilent Technologies, Santa Clara, CA, USA). Sequencing was performed using the Illumina HiSeq 2500 system.
Paired tumor–normal NGS assay
The NGS-based analysis of matched tumor–normal pairs utilized the National Cancer Center oncopanel v4, which analyzed 114 cancer-associated genes (Supplementary Table 2) [19]. The NGS assay and data analysis were performed in the CLIA-certified and College of American Pathologist-accredited Laboratory of Riken Genesis Co., Ltd. (Tokyo, Japan). Sections of archival FFPE tumor tissue (tumor content ≥20%) and matched blood sample were sent to the Laboratory of Riken Genesis, where DNA extraction was performed. The DNA extracted from FFPE or fresh-frozen tumor tissues at our institution was sent to the Laboratory of Riken Genesis. NGS libraries were prepared using SureSelect XT reagent (Agilent Technologies, Santa Clara, CA, USA) and the KAPA Hyper Prep kit (KAPA Biosystems, Wilmington, MA, USA). Sequencing was performed using MiSeq or NextSeq platform (Illumina, San Diego, CA, USA). Sequencing data were analyzed to detect somatic and germline variants independently, as described previously [19].
Determination of the pathogenicity of variants
The pathogenicity of variants was determined predominantly on the basis of the clinical data reported in ClinVar (http://www.ncbi.nlm.nih.gov/clinvar/). Nonsense and frameshift mutations that were not registered in ClinVar were determined as pathogenic if there were one or more known pathogenic truncated variants in the posterior region to the sites. Variants in a splice site that were not registered in ClinVar were determined as likely pathogenic if there were known pathogenic variants in the same splice site. Variants registered as uncertain significance (VUS) or conflicting interpretations of pathogenicity were classified as likely pathogenic if pathogenic or likely pathogenic reports were predominant in ClinVar. If there was no significant information on the pathogenicity of variants in ClinVar, the following public databases were also referred to: Catalog of Somatic Mutations in Cancer (COSMIC) (http://cancer.sanger.ac.uk/cosmic), Insight (https://www.insight-group.org), Leiden Open Variation Database (LOVD) (http://www.lovd.nl/3.0/home), and the University of Utah Department of Pathology and ARUP Laboratories database (http://arup.utah.edu/database/BRCA/). For TP53 variants, a functional classification based on its translational activity in the International Agency for Research on Cancer (IARC) TP53 Database (http://p53.iarc.fr/) was also referred to.
Germline analysis using Sanger sequencing
Following the tumor-only NGS assay, germline analyses were performed in patients meeting the following criteria: (1) harboring at least one possible germline variant, including pathogenic or likely pathogenic variants, VUSs and unknown variants in ACMG-recommended genes (Fig. 1a), (2) having suspected medical and family histories of cancer, and (3) agreeing with and providing written informed consent for additional germline analysis (Fig. 1b).
Germline DNA was extracted from the peripheral blood of patients using the GENE PREP STAR NA-480 system (KURABO Industries, Ltd., Osaka, Japan) in the Cancer BioBank of Kyoto University Hospital. The genomic fragments comprising the region of the variant were amplified by polymerase chain reaction using PrimeSTAR MAX (Takara Bio, Inc., Tokyo, Japan) and were used as templates for Sanger sequencing, which was performed by Eurofins Genomics Co., Ltd. (Tokyo, Japan).
Molecular tumor board
Our institutional molecular tumor board comprises several medical professionals, including medical oncologists, pathologists, medical geneticists, genetic counselors, genomic researchers, bioinformaticians, pharmacists, nurses, and clinical research coordinators. The molecular tumor board meets weekly to discuss genetically informed treatment options and the possibility of SFs.
Variant database analysis
The pathogenic and likely-pathogenic variants downloaded from the ClinVar database were filtered to eliminate structural variants, variants with ambiguous information, and variants mapped on minor transcripts. Variants that were registered only as somatic in ClinVar were classified as “somatic-only” variants, whereas those that were registered only as germline in ClinVar and were not registered in COSMIC were classified as “germline-only” variants. The remaining variants were classified as “intermediate” variants, which included the following: (a) variants that were registered both as somatic and germline in ClinVar or (b) variants that were registered as germline in ClinVar and also registered as somatic in COSMIC. Data on the variants were independently analyzed for each ACMG gene.
Results
Incidence of possible germline variants in the tumor-only NGS assay
Of the 194 patients who underwent the tumor-only NGS assay, OncoPrime™, 120 patients (61.9%) were found to harbor at least one pathogenic or likely pathogenic variant in ACMG-recommended genes, which could be classified as possible SFs (Fig. 1). The characteristics of patients with possible SFs are summarized in Table 1, in which colorectal cancer (n = 24) was the most common type of cancer and pancreatic cancer (n = 21) was the second most common. The most commonly mutated gene in these possible SFs was TP53 (n = 97), followed by APC (n = 38) and PTEN (n = 11) (Table 2). There was a total of 13 possible SFs in BRCA1 (n = 5) and BRCA2 (n = 8) combined. The medical and family histories of LFS- and HBOC-related cancer were summarized for patients carrying possible SFs in TP53 and BRCA1/2, respectively (Table 3). None of the patients had a medical or family history suggestive of LFS, although 91 patients (46.9%) were identified to have one or more possible SFs in TP53.
Verification of SFs
As shown in Fig. 1, 9 patients agreed to the additional germline testing, and a total of 14 possible germline variants were examined by Sanger sequencing using the germline DNA samples. Following this verification, SFs were confirmed in three patients, in which pathogenic germline variants in BRCA1 (Q934*) or BRCA2 (R2318* and Q3026*) were confirmed (Table 4 and Supplementary Fig. 2), although these patients had no evident medical or family history of HBOC (Table 3). In accordance with the recommendations of the ACMG, the patients were carefully informed of these SFs in BRCA1 and BRCA2 by medical experts in genetic counseling. By contrast, all six variants tested in TP53 were confirmed as somatic variants (Tables 2 and 4 and Supplementary Fig. 1).
Variant findings in TP53 using paired tumor–normal sequencing
To confirm the low prevalence of true SFs in TP53, we analyzed data from 50 cases of paired tumor–normal NGS assay, of which 30 patients underwent a tumor-only NGS assay in parallel (Supplementary Fig. 1). In those 50 patients, 24 pathogenic or likely pathogenic variants in TP53 were identified; however, none of them were germline variants (Table 2, Supplementary Fig. 1 and Supplementary Table 3). Taken together with results of Sanger sequencing, a total of 30 variants in TP53 were confirmed as somatic variants (Table 2 and Supplementary Tables 3 and 4). These results indicate that the incidence of true SFs in TP53 is low, despite being the most commonly detected possible germline variant in the tumor-only NGS assay.
Classification of known variants in ACMG-recommended genes
Subsequently, we examined the proportion of somatic and germline variants registered in the ClinVar database for TP53 and another 20 ACMG-recommended genes that were included in our tumor-only NGS panel. All variants were classified into somatic-only, germline-only, and intermediate, and their numbers were counted for each gene to compare them (Fig. 2a). The proportion of somatic variants in TP53 was 77.6%, and the majority of these overlapped with germline variants (intermediate variants, 72.1%; Fig. 2b). By contrast, somatic-only or intermediate variants were rare in BRCA1 and BRCA2 (4.0% and 3.8%, respectively; Fig. 2b).
Discussion
In the present study, 120 patients (61.9%) harbored at least one possible germline variant; of these patients, nine underwent additional germline testing to determine whether these variants were true SFs. The results confirmed that three patients had SFs, the proportion of which was equivalent to 1.5% of total patients and 33% of germline-verified patients. The possible reasons for many patients not undergoing additional germline testing were as follows: (1) deterioration in their physical conditions, preventing sufficient time for either patients or physicians to discuss the issue of SFs; (2) poor accessibility of the patients to our hospital to participate in the germline testing; and (3) the burden of undergoing additional germline testing to patients, despite them being concerned about possible SFs.
Considering the confirmation of SFs, a paired tumor–normal NGS assay has a substantial advantage over a tumor-only NGS assay, as the former assay does not require additional germline testing [16]. A previous study using a paired tumor–normal NGS assay revealed that the prevalence of SFs was between 3.3 and 17.5% [10,11,12,13,14,15]. Because only 7.5% of cases with possible germline variants actually underwent additional germline testing, it is likely that the prevalence of SFs is underestimated in the present study.
The NCCN guidelines of HBOC recommend a genetic testing of BRCAs for patients who meet the criteria such as medical history of bilateral breast cancer, triple-negative breast cancers or ovarian cancer and family history of related cancers. However, in the three patients confirmed to have SFs in BRCA1/2 in our present study, none reported a typical medical and family history of HBOC. This suggested that consideration of medical and family histories is insufficient for the prediction of germline findings in BRCA1/2. We also emphasize that the majority of the known variants in BRCA1 and BRCA2 have been registered as germline variants only (96% each) (Fig. 2). In addition, previous genome profiling study against advanced cancers indicated that more than 75% of pathogenic BRCA1/2 variants identified in tumors were originated from germline variants [11]. Based on these data, if any pathogenic or likely pathogenic variant is found in BRCA1/2 using a tumor-only NGS assay, additional germline testing is recommended.
In contrast to the above, the prevalence of true SFs in TP53 appears to be low, despite being the most commonly detected possible SF (75.8%) in the tumor-only NGS assay. Although just 6.6% (6/91) of possible SFs in TP53 were verified in Sanger sequencing of germline samples, none of them were found to be true SFs (Tables 2 and 4). In addition, no SFs were identified in TP53 using the paired tumor–normal NGS assays in 50 patients, whereas 24 patients were identified to have pathogenic or likely pathogenic somatic variants in TP53 (Table 2 and Supplementary Table 3). Supporting our observations, the incidence of SFs in TP53 has been reported to be 0–1% using paired tumor–normal assays [10,11,12,13,14,15].
It has been reported that somatic hotspot mutations in TP53 identified in various types of tumor overlap with those in germline variants [20]. We performed analysis using a public database and revealed that >70% of pathogenic or likely pathogenic variants in TP53 were registered as both somatic and germline variants, which was the highest coincidence among the 21 genes recommended by the ACMG in our tumor-only NGS panel (Fig. 2). This coincidence of somatic and germline mutations appears to increase the difficulty in distinguishing true SFs in TP53 from the numerous somatic variants when they were identified in the tumor-only NGS assay.
TP53 has been known as the gene causing LFS, a rare hereditary cancer syndrome characterized by the early onset of various types of cancer, including sarcoma, adrenocortical carcinoma, breast cancer, leukemia, and brain tumors [20, 21]. It is reported that >80% of TP53 mutation carriers meet the diagnostic criteria for LFS or Li–Fraumeni-like criteria, having a family history suggestive of and/or early onset of LFS-related cancer [18, 22]. It has also been reported that there are de novo mutations in TP53, which are relatively frequent in patients who have early onset LFS-related cancer in the absence of family history [23, 24]. Therefore, the medical and family histories of a patient serve an important role in determining whether to proceed with additional germline testing when possible SFs in TP53 are identified using a tumor-only NGS assay. This is consistent with a recent publication by the European Society of Medical Oncology Precision Medicine Working Group, which recommends germline testing for patients with suspected TP53 germline mutations only if those associated tumors arise at <30 years of age [25].
In conclusion, the tumor-only NGS assay yielded a number of possible SFs in TP53; however, the significance of additional germline testing for TP53 variants appears fairly low in daily clinical practice using a tumor-only NGS assay, unless patients report any relevant medical or family histories.
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Acknowledgements
We thank Y. Furuya, F. Masuda, M. Imano, E. Sasaki, K. Ashida, and M. Funakoshi for their technical secretarial assistance. This study was supported by the Japan Agency for Medical Research and Development, AMED, under Grant number 17kk0305006h0001.
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MK: TheraBioPharma Inc. (Consulting/advisory relationship and Stock ownership); MM: Mitsui Knowledge Industry, Sysmex and Riken Genesis (Research funding).
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Yamamoto, Y., Kanai, M., Kou, T. et al. Clinical significance of TP53 variants as possible secondary findings in tumor-only next-generation sequencing. J Hum Genet 65, 125–132 (2020). https://doi.org/10.1038/s10038-019-0681-6
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DOI: https://doi.org/10.1038/s10038-019-0681-6