KR20230146139A - Next generation sequencing (ngs)-based hybrid diagnostic panel for analyzing variation of cancer gene and anticancer drug-related gene - Google Patents

Abstract

The present invention provides a composition for use in detecting mutations in the genomic DNA of cancer cells and genetic mutations that predict drug response to anticancer agents, a next-generation sequencing (NGS)-based mixed diagnostic panel comprising the composition, and use of the panel. It relates to a method for diagnosing and detecting the genetic mutation.
The method for detecting and diagnosing mutations in genomic DNA and drug response genes of cancer cells of the present invention can detect various genetic mutations in major cancer-related genes and drug metabolism genes through a single experiment, so that each genome It is very economical and efficient than conventional methods that use different platforms for each variant. In addition, by securing high resolution by sequencing key genes related to cancer induction, progression, and drug metabolism with high coverage, it is possible to identify low-frequency genomic mutations that were not detected by existing methods. Therefore, using the method of the present invention, various genetic mutations can be analyzed simultaneously with high sensitivity and accuracy in samples containing mutations in the genomic DNA of cancer cells and genetic mutations that predict drug response, and based on these analysis results, You can efficiently search for patient-specific cancer treatments.

Description

Next-generation sequencing (NGS)-BASED HYBRID DIAGNOSTIC PANEL FOR ANALYZING VARIATION OF CANCER GENE AND ANTICANCER DRUG-RELATED GENE}

The present invention provides a composition for use in detecting mutations in the genomic DNA of cancer cells and genetic mutations that predict drug response to anticancer agents, a next-generation sequencing (NGS)-based mixed diagnostic panel comprising the composition, and use of the panel. It relates to a method for diagnosing and detecting the genetic mutation.

The content described below simply provides background information related to the present invention and does not constitute prior art.

Cancer can occur in any tissue in the body, and cancer cells typically infiltrate and destroy adjacent tissues, gradually invade the circulatory system, and metastasize to other parts of the body distant from the cancer site, eventually killing the host (e.g., a person). cause death Cancer cells divide abnormally, and when observed under a microscope, they resemble normal tissues, but they lose their cell shape and display abnormal functions. Cancer can be accompanied by various genetic mutations depending on the type of tumor, and it has been reported that cell mutations have a significant impact on the occurrence and progression of cancer.

Therefore, various methods for detecting genetic mutations from cancer cells are being studied, and the detected mutation information can be of great help in diagnosing cancer patients and selecting precision-tailored anticancer drugs.

Existing genomic mutation detection methods use amplicons and probes designed to detect only one genomic mutation, so in order to detect various somatic mutations that cause cancer, detection of other genomic mutations is necessary. It requires additional experiments and has the disadvantage of not being able to discover new mutations other than those already identified.

In addition, because existing methods perform separate detection methods (e.g., SNV: real-time PCR, CNV: CGH array; or translocation: FISH; etc.) according to each type of genomic mutation, all types of cancer tissue can be targeted at one person. Detecting mutations takes a lot of time and incurs large costs.

Recently, with the introduction of next-generation sequencing (NGS) technology, it has become possible to analyze multiple cancer-related genes simultaneously, but when diagnostic panels are mainly developed in foreign countries, their application is limited to Koreans. In addition, not only the cancer genome for cancer diagnosis and targeted anticancer drugs, but also the genotype of metabolic enzymes that metabolize anticancer drugs need to be tested to prevent drug side effects. To this end, genetic mutations including various drug metabolism genes that occur in cancer patients are tested for sensitivity and A method for simple and rapid detection with high accuracy is needed.

For example, in the case of UGT1A1, which is involved in the metabolism of irinotecan, UGT1A1*28 is known to be an important genetic indicator of anticancer drug side effects in Western people, but UGT1A1*6 (18% of Koreans) is more frequent in Koreans and Japanese. This should be taken into consideration, and in the case of CYP2D6, which is involved in tamoxifen metabolism, the CYP2D6*52 (1%) and CYP2D6*60 (1%) genotypes, which show a Korean-specific frequency, should also be considered.

Therefore, there is an urgent need to develop a customized cancer diagnostic panel for Koreans that can detect and analyze mutations in prevalent cancer genes in Koreans and genes that predict drug response related to anticancer drug metabolism.

Accordingly, while researching the development of a cancer diagnostic panel customized for Koreans, the present inventors discovered that by using next-generation sequencing (NGS)-based technology, they can quickly and effectively target cancer genes prevalent in Koreans and drug responses related to anticancer drug metabolism by targeting all relevant genes. The present invention was completed by confirming that prediction and detection were possible.

Therefore, the purpose of the present invention is to provide a composition for detecting mutations in genomic DNA and drug response genes of cancer cells.

In addition, another object of the present invention is to provide a next-generation sequencing (NGS)-based mixed diagnostic panel including the composition.

Additionally, an object of the present invention relates to a method for diagnosing and detecting the genetic mutation using the panel.

In order to achieve the above-mentioned purpose,

The present invention includes the steps of amplifying a target region from the DNA of a sample using primers capable of amplifying the target region of a cancer gene or an anticancer drug metabolism-related gene;

Attaching an adapter to the amplified product;

Preparing a final product by amplifying the product to which the adapter is attached; and

Analyzing the sequence of the final product and detecting genetic mutations by comparing it with the sequence of the amplicon for the target site

It provides a next-generation sequencing (NGS) method for analyzing genetic mutations related to cancer genes and anticancer drug metabolism, characterized in that it includes.

In the present invention, the cancer gene or anticancer drug metabolism-related gene may be one or more types selected from the genes listed in Table 1.

In the present invention, the target site may be one or more types selected from the target sites listed in Table 1.

In the present invention, the primer may be selected from the primers of SEQ ID NOs: 1 to 96 listed in Table 2.

In the present invention, the amplicon may be selected from the sequences of SEQ ID NOs: 97 to 128 shown in Table 3.

In the present invention, a step of purifying the amplified product may be further included.

Additionally, the present invention provides a composition for amplifying a target site from the DNA of a sample, which includes primers capable of amplifying the target site of a cancer gene or an anticancer drug metabolism-related gene.

In the present invention, the cancer gene or anticancer drug metabolism-related gene may be one or more types selected from the genes listed in Table 1.

In the present invention, the target site may be one or more types selected from the target sites listed in Table 1.

In the present invention, the primer may be selected from the primers of SEQ ID NOs: 1 to 96 listed in Table 2.

The present invention also provides a diagnostic panel for genetic mutations related to cancer genes and anticancer drug metabolism, comprising the composition, adapter, and barcode primer.

The method for detecting and diagnosing mutations in genomic DNA and drug response genes of cancer cells of the present invention can detect various genetic mutations in major cancer-related genes and drug metabolism genes through a single experiment, so that each genome It is very economical and efficient than conventional methods that use different platforms for each variant. In addition, by securing high resolution by sequencing key genes related to cancer induction, progression, and drug metabolism with high coverage, it is possible to identify low-frequency genomic mutations that were not detected by existing methods. Therefore, using the method of the present invention, various genetic mutations can be analyzed simultaneously with high sensitivity and accuracy in samples containing mutations in the genomic DNA of cancer cells and genetic mutations that predict drug response, and based on these analysis results, the patient Customized cancer treatments can be searched efficiently.

Figure 1 is a diagram briefly showing a method for detecting a mutant gene from a sample using the primers and amplicons produced in Example 1 of the present invention.
Figure 2 is a diagram showing the process of analyzing the data obtained in Example 2 using Illumina VariantStudio, a commercial data analysis software.
Figure 3 is a diagram showing the results of analyzing the data obtained in Example 2 using Illumina VariantStudio, a commercial data analysis software.
Figure 4 is a diagram showing the results of analyzing the data obtained in Example 2 using annotation & classification.

The present invention provides a next-generation sequencing (NGS) method for analyzing genetic mutations related to cancer genes and anticancer drug metabolism.

Specifically, the method may include the following steps:

Amplifying a target region from the DNA of a sample using primers capable of amplifying the target region of a cancer gene or an anticancer drug metabolism-related gene;

Attaching an adapter to the amplified product;

Preparing a final product by amplifying the product to which the adapter is attached; and

Analyzing the sequence of the final product and detecting genetic mutations by comparing it with the sequence of the amplicon for the target site.

In the present invention, the cancer gene or anticancer drug metabolism-related gene may preferably be a cancer gene prevalent in Koreans and a gene that acts on the metabolic process of an anticancer drug for treating the cancer, and more preferably, the genes in Table 1 below. It may be one or more types selected from the genes described in .

gene name associated carcinoma related drugs target area AKT1 breast cancer - E17K BRAF Melanoma, colon cancer, lung cancer, ovarian cancer Vemurafenib V600E/K/R/M EGFR lung cancer Elotinib, gefitinib Exon18,19,20,21 ERBB2 breast cancer, lung cancer trastuzumab, neratinib, lapatinib A775_G776YVMA FOXL2 ovarian cancer - C123W KIT Stomach cancer, melanoma Imatinib, nilotinib, sorafenib Exon8-11,13.14,17,18 KRAS Colon cancer, stomach cancer, lung cancer Cetuximab, panitumumab Exon2, 3,4 MET Lung cancer, colon cancer, stomach cancer Trametinib Focal Amplification BRCA1 breast cancer Olabarib, veliparib, iniparib Full CDS BRCA2 breast cancer Full CDS NRAS Colon cancer, stomach cancer, lung cancer binimetinib, palbociclib, sorafenib Exons 2, 3 PDGFRA Stomach cancer, melanoma Sorafenib Exon12,14,18 PIK3CA Lung cancer, breast cancer, prostate cancer Idelisinib Exon9,20 RET lung cancer Vandetanib, Sorafenib M918T TP53 Lung cancer, melanoma, ovarian cancer, colon cancer - Full CDS UGT1A1 colon cancer Irinotecan *6,*28 CYP2D6 breast cancer Tamoxifen Full CDS TPMT blood cancer Mercaptopurine, azatioprine *2 *3B, *3C, *6 MTHFR blood cancer Thiopurin 677C>T 1298A>C DPYD stomach cancer 5'-Fluorouracil Full CDS

In the present invention, the target site may be one or more types selected from the target sites listed in Table 1 above.

In the present invention, the primer is for amplifying the target region of the gene and may be selected from the primers listed in Table 2 below, and preferably may be selected from the primers of SEQ ID NOs: 1 to 96.

Forward primer name sequence number Primer sequence Reverse primer name sequence number Primer sequence >520999_MTHFR_01_FOR One GGGCACAGGATGGGGAAGTCACAGC >520999_MTHFR_01_REV 2 CGGGAGAACCAAACCGGAATGGTCAC >520999_MTHFR_02_FOR 3 GAACCAGGGTCCCCACTCCAGCATC >520999_MTHFR_02_REV 4 TGGGGAGCTGAAGGACTACTACCTCTTC >520999_MTHFR_03_FOR 5 ACATCTTCAGCAGCTCCTCCTTGGG >520999_MTHFR_03_REV 6 TACAGGAATGGCCTCCTGGGCATGTG >520999_MTHFR_04_FOR 7 TCAGCGAACTCAGCACTCCACCCCAGAG >520999_MTHFR_04_REV 8 CTTCCGCTTTGTGAAGGCATGCACCGA >520999_MTHFR_05_FOR 9 GAGGGAGCTTATGGGCTCTCCTGG >520999_MTHFR_05_REV 10 CTGAAGCACTTGAAGGGAGAAGGTGTCTGC >520999_MTHFR_06_FOR 11 ATGTGTCAGCCTCAAAGAAAAGCTGC >520999_MTHFR_06_REV 12 CTCTCCTGACTGTCATCCCTATTGGCAG >520999_MTHFR_07_FOR 13 TTCAAGTGCTTCAGGTCAGCCTCAAAAG >520999_MTHFR_07_REV 14 TGGTCTCTTCATCCCTCGCCTTGAACA >520999_DPYD_01_FOR GCAGAAGAGCAATATTTGGCACCACTGG >520999_DPYD_01_REV GTGTATCAACTGTGGTAAATGCTACATGACCTG >520999_DPYD_02_FOR CATGTCTCATAGCATTCTAATTCCAGCAGG >520999_DPYD_02_REV AGCACTGCAGTACCTTGGAACATTTGGT >520999_DPYD_03_FOR TTCTTCATCAATCATAGCCACAACTTGCTC >520999_DPYD_03_REV GGAATGAGCTTGCTAAGTAATTCAGTGGC >520999_DPYD_04_FOR GGTACTGCAGTGCTTTTCCTATTACATCC >520999_DPYD_04_REV GCAACATTGTATAAAAACAGGAAAATGCTGAGTG >520999_DPYD_05_FOR GATCTGAAATAGAAACCAAGGCTGAGTTCTC >520999_DPYD_05_REV CAGAGTCCAGCTACTGTGAGTCACCAG >520999_DPYD_06_FOR TGTCCATGAGTTCAGCTATACGTGGAACTG >520999_DPYD_06_REV CTAGGTATGCAGTGCCATTCAGAATCAGG >520999_DPYD_07_FOR GCTTTGAGGCCAGTGCAGTAGTCTTCG >520999_DPYD_07_REV GTGAATTTGTTTGGAGAATTATCTCTTGGTTTGACAC >520999_DPYD_08_FOR GGGCACAAAACTCTTGCAACATGACCTTC >520999_DPYD_08_REV GTCTCAGGTCTGATGGGATTAAAATCTGATGGC >520999_DPYD_09_FOR GTTCGCTTTGCAATCCCCCACTGCTG >520999_DPYD_09_REV GGGTTTTAACTATCGTGTCTTATAAGAGCTGC >520999_DPYD_10_FOR GGCATTCACCAACTTATGCCAATTCTCTTG >520999_DPYD_10_REV GTATGGCCCTGGACAAAGCTCCTTTC >520999_DPYD_11_FOR CCAATATGCAGCCGTTTTTCTCACTGATG >520999_DPYD_11_REV GGGGCTTTTCTTTGTCAAAAGGAGACTC >520999_DPYD_12_FOR GGAGGGGACATTTCTATATGACTTCAATAATATTTTC >520999_DPYD_12_REV GGACATTAGTGTAGAAATGGCCGGATTGAAG >520999_DPYD_13_FOR GGAGTTGCGCTAGCAAGACCAAAAGG >520999_DPYD_13_REV GGAGGGGATGTAATATGAAACCAAGTATTGG >520999_DPYD_14_FOR GAAGGCAGTCATTCTTCTGGATATTGCTAGG >520999_DPYD_14_REV GCGGTAAAAGCCTTTCAGTGAATGAAATGAC >520999_DPYD_15_FOR CCTATTCCAATGAAAGCAGCTTTGTAGCC >520999_DPYD_15_REV GGGGAATCTCATAGAATTTTTGGCTGAC >520999_DPYD_16_FOR GCATGACATTTGCTGTTTAATCTTTAGTGTAGAGC >520999_DPYD_16_REV TCTTTTCAGTACTTCTGAAATTCCTCAGTTCC >520999_DPYD_17_FOR GCACCAAGGTCCTTCATTAGCTCAATCTC >520999_DPYD_17_REV GGTCAAAGATTGGTCATTTTTCTACTGATGCC >520999_DPYD_18_FOR AAGATTTTGTGCATGGTGATGGTAGTGGGG >520999_DPYD_18_REV CACTTGGTCTGACTTGTGGAATGGTATG >520999_DPYD_19_FOR GGTTGCATCCACCTACACAAAGATCAG >520999_DPYD_19_REV GGGAAGAAATAATGTTTGTCGTAATTTGGCTG >520999_DPYD_20_FOR GCTAAGACAAGCTGTATTCTGTACCCACAG >520999_DPYD_20_REV CCTAGATGCCTGAAATGTGCAGATGC >520999_DPYD_21_FOR GGCCTTTGTTTGCAATACTTGTGATGAATG >520999_DPYD_21_REV GGACACGGACTCTGAATGAGTATAAGGTAG >520999_DPYD_22_FOR CTTGCTTACAATGTGTGGAGTGAGG >520999_DPYD_22_REV TCCTGGCTTTAAATCCTCGAACACAAACT >520999_DPYD_23_FOR GTTTCTTGTCTAATTTCTTGGCCGAAGTGG >520999_DPYD_23_REV CTGGGAGTTTAAACAAATGCCAACATATTTCC >520999_NRAS_01_FOR CCAGAGTTAATCAACTGATGCAAACTCTTGC >520999_NRAS_01_REV GGTGCTAGTGGGAAACAAGTGTTGATTTG >520999_NRAS_02_FOR CAGTTCGTGGGCTTGTTTTTGTATCAACTG >520999_NRAS_02_REV GCCCAGCCTAATCTTGTTTTTCTTATGTTCTG >520999_NRAS_03_FOR CCCCATAAAGATTCAGAACACAAAGATCATCC >520999_NRAS_03_REV GATACAGCTGGACAAGAAGAGTACAGTGC >520999_NRAS_04_FOR CAAATACACAGAGGAAGCCTTTCGCCTG >520999_NRAS_04_REV CCCCCAGGATTCTTACAGAAAACAAGTGG >520999_NRAS_05_FOR GCTGTATCCAGTATGTCCAACAAACAGGTTTCA >520999_NRAS_05_REV GGGATGCTTATTTAACCTTGGCAATAGCATTG >520999_NRAS_06_FOR AAGATGATCCGACAAGTGAGAGACAGG >520999_NRAS_06_REV GAAATGACTGAGTACAAACTGGTGGTGG >520999_NRAS_07_FOR GGATTGTCAGTGCGCTTTTTCCCAACAC >520999_NRAS_07_REV GGGAAAGCTTTAAAGTACTGTAGATTGTGGCTC >520999_UGT1A1_01_FOR GAAATTCCAGCCAGTTCAACTGTTGTTGCC >520999_UGT1A1_01_REV CCAAGTTAATGTTTGACTGTGTCACGTGAC >520999_UGT1A1_02_FOR GAACTCCCTGCTACCTTTGTGGACTGAC >520999_UGT1A1_02_REV TGACGACTTTGCTCCTGCCAGAGGTTC >520999_UGT1A1_03_FOR TGACACAGTCAAACATTAACTTGGTGTATCG >520999_UGT1A1_03_REV GTATCTTCCCAGCATGGGACACCACTG >520999_UGT1A1_04_FOR GAAGCAAAGACGCCATGGCTGTGGAGTC >520999_UGT1A1_04_REV CAACTATTTCATGTCCCCCTCTGCTGCAGC >520999_UGT1A1_05_FOR GATGACAGACACTGGCTGAGCATGCTTGG >520999_UGT1A1_05_REV GGAATGGCACAGGGTACGTCTTCAAGG >520999_UGT1A1_06_FOR CACCTGACCGCCTCGTTGTACATCAGAG >520999_UGT1A1_06_REV CTTGTATGTTTTGATCACACGCTGCAGG >520999_UGT1A1_07_FOR GGGAGTCTTTTGTTAGTCTCGGGCATAATG >520999_UGT1A1_07_REV CATGACATCAAAGCTGCTTTCTGCCAG >520999_UGT1A1_08_FOR CTGTTCCCACTTACTGCACAACAAGGAGC >520999_UGT1A1_08_REV GCACTGGGTAGCCTCAAATTCCAGGC >520999_UGT1A1_09_FOR CTCTGCCCACTGTATTCTTCTTGCATGC >520999_UGT1A1_09_REV CAGAAAGTTCTGTGAAAGGCAATGAGCATG >520999_UGT1A1_10_FOR CTCATTCAGATCACATGACCTTCCTGCAGC >520999_UGT1A1_10_REV CAGCCAGACAGATGCAGAGCTCAATAGG >520999_UGT1A1_11_FOR CGTATGCAACCCTTGCCTCAGAATTCC >520999_UGT1A1_11_REV GGATTTTGGTGAAGGCAGTTGATTCCACC >520999_UGT1A1_12_FOR GTGAAGGATTACCCTAGGCCCATCATGC >520999_UGT1A1_12_REV CTCAGCATATATCTGGGGCTAGTTAATCGATCC >520999_FOXL2_01_FOR CTAGCTGCTGACTAAGGAGCGCAG >520999_FOXL2_01_REV CCATAGACCTGGTTGTACTGTAGCTTGTTG >520999_FOXL2_02_FOR GGCACAACAAAAGTGCTCTAGTTCTCTCTAG >520999_FOXL2_02_REV CAACCTCCTGCTTTCTCCCACCTTGG >520999_FOXL2_03_FOR CAGAGACACAAGACCGCCTAGGTCGG >520999_FOXL2_03_REV TGCAAGTCCTGGAGGCAGGGAGATC >520999_FOXL2_04_FOR CAAAAAGCAGGGAGGACGAGCCGTCC >520999_FOXL2_04_REV GGGATGGTTTCGTCTACCAATTGGGGAAG >520999_FOXL2_05_FOR CCAGGACTTGCATCGAAAGATCCG >520999_FOXL2_05_REV GGGCTCTCTGGAAGATTTGCGTTAGAG >520999_FOXL2_06_FOR GCCATCTTTTATTGGATATATTCTCCTAACTCTGAAC >520999_FOXL2_06_REV GGAAGTATTGTGGCCTTGGAGTTTTGC >520999_FOXL2_07_FOR GGGCTAAAGCTTTTGATTTTCATATTTGG >520999_FOXL2_07_REV GGGTTTTGTTTGAAAGATCGGTGGAAC >520999_FOXL2_08_FOR CAAGGCCACAATACTTCCCCGGGTTGC >520999_FOXL2_08_REV GTTTCCTCCGCTATCAGTCCCGTCGC >520999_FOXL2_09_FOR CGATTCTTTCAAACAAAACATTAGCCAGCC >520999_FOXL2_09_REV CGAACCCTCTTGAAGCTGTTCAGAAGC >520999_FOXL2_10_FOR CAGAATACAGGCCGTGGAGCCAGGCTG >520999_FOXL2_10_REV GCCCGAGAAAGGGACGGACCAATAC >520999_FOXL2_11_FOR GAACAGCTTCAAGAGGGTTCGCGGAG >520999_FOXL2_11_REV CAGACCTCTTGGCCTTCTCTCACAGGTC >520999_FOXL2_12_FOR CTAGCCATGGACTGCACGGCAGTC >520999_FOXL2_12_REV CACAAGCGTCTCCTGCCCAAATTCACC >520999_FOXL2_13_FOR GAGAGAAGGCCAAGAGGTCTGCGCTG >520999_FOXL2_13_REV CCTGTGCTCACCTCCCTGACCTCTG >520999_FOXL2_14_FOR GAAAGAGACGAGCCCAGTAGAAAGCGC >520999_FOXL2_14_REV GGGTCCCTCTGTGCTTTTTCGCTTTCC >520999_FOXL2_15_FOR GACATAAACTGAGGGGACAAAGAGGAGC >520999_FOXL2_15_REV GTGCAGACGGATGCGAGGATGCAG >520999_FOXL2_16_FOR GAGACAAGAGGGTGTGAGGTCAGGCTG >520999_FOXL2_16_REV CTCTTACTGGGACCACGACAGCAAGAC >520999_FOXL2_17_FOR GCATGCGGTGGGCTCTCAGAGATCGAG >520999_FOXL2_17_REV CAACTCAGACCTGCCAGCCCAGCCAC >520999_FOXL2_18_FOR CAATGCATCATGGCGAGCTCGGGCTG >520999_FOXL2_18_REV CATCAGCACGCACACCATCTGCACGC >520999_FOXL2_19_FOR GAGGACAAGTGGTGCGGTGGGGCAG >520999_FOXL2_19_REV GTACAGACCGTACACACGCGTGCAGAGCATG >520999_FOXL2_20_FOR GCCTCCCAGGCCATTGTACGAGTTCACTACG >520999_FOXL2_20_REV CAGAGACTGAAGCAGCTGGCGGCTGCAG >520999_FOXL2_21_FOR CAGACACGCCAGCCCCTTGACCACAG >520999_FOXL2_21_REV CCCAAGTACCTGCAGTCTGGCTTCCTC >520999_FOXL2_22_FOR CATTCTGGCAGGAGGCATAGGGCATG >520999_FOXL2_22_REV CACTTCCAGCACGGCAAGGGGCTCT >520999_FOXL2_23_FOR GTTGAGGAAGCCAGACTGCAGGTACTTG >520999_FOXL2_23_REV CGAAGACATGTTCGAGAAGGGCAACTACCG >520999_FOXL2_24_FOR GAGACAGACGGAAGGGCCTCTTCATGC >520999_FOXL2_24_REV GGCAAAATAGCATCCGCCACAACCTCAGC >520999_FOXL2_25_FOR CAGAGTCCAGTAGTTGCCCTTGCGCTC >520999_FOXL2_25_REV GAGAGAGGAGAAGAGGCTCACGCTGTC >520999_FOXL2_26_FOR GAACGGGAACTTCGCGATGATGTACTGG >520999_FOXL2_26_REV GACAGAACAGACCCGGAGAAGCCGGAC >520999_FOXL2_27_FOR GCGATGAGCGCCACGTACGAGTACG >520999_FOXL2_27_REV CTTTGTCATGATGGCCAGCTACCCCGAGC >520999_FOXL2_28_FOR CTCCTTGACTGTGCGACCGGTCTCTG >520999_FOXL2_28_REV GACTCGTGCGCCCCAACTCTTTGCC >520999_FOXL2_29_FOR GGGTAGCTGGCCATCATGACAAAGCC >520999_FOXL2_29_REV CAGCGACAGGGCTCTCAGCAAGCAAG >520999_FOXL2_30_FOR GGGTCTCAAACTTCTGGAGACTGCGGATG >520999_FOXL2_30_REV GACAAGGCCGGAGCCCCTCTCTGTTG >520999_FOXL2_31_FOR GAGTGGAGCTCAGCCTCTGGCCATG >520999_FOXL2_31_REV GAGACACGGGTCGTGCTTCGGGAAAC >520999_FOXL2_32_FOR CTTGGTGGGTTTTCTTTTCTGCGCTCTTCC >520999_FOXL2_32_REV CATGACGCAAGCGGAACTCGGTGGAG >520999_PIK3CA_01_FOR GGTGGCAGTCAAACCTTCTCTCTTATGTA >520999_PIK3CA_01_REV GCTAAATCCTGCTTCTCGGGATACAGACC >520999_PIK3CA_02_FOR GCAGTGTGGTAAAGTTCCCAGATATGTCAG >520999_PIK3CA_02_REV GGGCCTTTTCCATAGAGAAAGTATCTACCTAAATCC >520999_PIK3CA_03_FOR GCATGGTGAAAGACGATGGACAAGTAATGG >520999_PIK3CA_03_REV GCGGTGATCCAAAAAGTGTCCAAAATCTATATG >520999_PIK3CA_04_FOR CGGGCAAGACATTTTGTATCTGCATATATCAAAC >520999_PIK3CA_04_REV GGTGGGCTCCTTTACTAATCACTATTAAGAAATCC >520999_PIK3CA_05_FOR GGGTTATAAACGAGAACGTGTGCCATTTG >520999_PIK3CA_05_REV GGGGATTGTTTCTAATAGAGCAGCCAGAAC >520999_PDGFRA_01_FOR CTTCAGTGAAGCTCTGGTGCACTGGGA >520999_PDGFRA_01_REV GAGTCATAAGGCAGCTGCATCGGGTCC >520999_PDGFRA_02_FOR GCTGGAGGGTCATTGAATCAATCAGCC >520999_PDGFRA_02_REV GGCCTATAAATTGTAAAGTTGTGTGCAAGGG >520999_PDGFRA_03_FOR TGAGAACAGGAAGTTGGTAGCTCAGCT >520999_PDGFRA_03_REV GTGGCCCCAGGTGAGGTCATTATCTTCA >520999_PDGFRA_04_FOR GGCCAGATCCAGTGAAAAAACAAGCTC >520999_PDGFRA_04_REV AAGCCTGATTGAACAGTTTTCACAACC >520999_PDGFRA_05_FOR CAGCTACAGATGGCTTGATCCTGAGTC >520999_PDGFRA_05_REV CACTGCCTTTCGACACATAGTTCGAATC >520999_PDGFRA_06_FOR GTGAAGATTCTGTGACTTTGGCCTGGC >520999_PDGFRA_06_REV GCACCGAATCTCTAGAAGCAACACCTGAC >520999_KIT_01_FOR GAATGTTGCTGAGGTTTTCCAGCACTC >520999_KIT_01_REV CATCTCACCTCTGCTCAGTTCCTGGAC >520999_KIT_02_FOR GCAGGATTCCCAGAGCCCACAATAG >520999_KIT_02_REV GGGAAATTCAAGTGAATTGCAGTCCTTCCC >520999_KIT_03_FOR GGGTATGCCACATCCCAAGTGTTTTATG >520999_KIT_03_REV GCACTAGAATCTATAGAACTCTGAACCACTAGC >520999_KIT_04_FOR CAGTGGATGTGCAGACACTAAACTCATCTG >520999_KIT_04_REV GCAGAAGTCTTGCCCACATCGTTGTAAG >520999_KIT_05_FOR GTGCATTCAAGCACAATGGCACGGTTG >520999_KIT_05_REV GGATCATGACTGATATGGTAGACAGAGCC >520999_KIT_06_FOR GTGGTAGAGATCCCCATCCTGCCAAAGT >520999_KIT_06_REV CACATCATGCCAGCTACGATTACGAAACC >520999_KIT_07_FOR CAAATCCATCCCCACACCCTGTTCAC >520999_KIT_07_REV GTCTCAGTCATTAGAGCACTCTGGAGAG >520999_KIT_08_FOR GTTCTCTCTCCAGAGTGCTCTAATGACTG >520999_KIT_08_REV GTGATCATAAGGAAGTTGTGTTGGGTCTATG >520999_KIT_09_FOR TATGAAGTACAGTGGAAGGTTGTTGAGGAG >520999_KIT_09_REV GAGTTCCTTAAAGTCACTGTTATGTGTACCC >520999_KIT_10_FOR TGCAAAATGGTCCTTCAATTCCACC >520999_KIT_10_REV CTTGAGCATCTTTACAGCGACAGTCATGG >520999_KIT_11_FOR GGAAGGTTTGTTGAGGCAACTGCTTATGG >520999_KIT_11_REV CATGCATTTTAGCAAAAAGCACAACTGGC

>520999_KIT_12_FOR GTACTGCATGCGCTTGACATCAGTTTG >520999_KIT_12_REV CAATGGTGCAGGCTCCAAGTAGATTCAC >520999_KIT_13_FOR GTCTGAACTCAAAGTCCTGAGTTACCTTGG >520999_KIT_13_REV GGCTTCCAAGCAGTTTATAATCTAGCATTGCC >520999_KIT_14_FOR GCTGAATATAAATGGCCATGACCACCCTTG >520999_KIT_14_REV GGATCACCATAGCAACAATATTCTGTAATGACC >520999_KIT_15_FOR GGCTCACCTTCTTTCTAACCTTTTCTTATGTGC >520999_KIT_15_REV GCAGCTTCTGCATGATCTTCCTGCTTTG >520999_KIT_16_FOR GGGCTTTTGAATTTTTTGAGAAGAAAACGTGATTC >520999_KIT_16_REV CCTTATGACCCCATGAACTGCCTGTC >520999_KIT_17_FOR GGGGAATTTAAATGGTTTTCTTTTCTCCTCCAACC >520999_KIT_17_REV GGAATCATTCTTGATGTCTCTGGCTAGACC >520999_KIT_18_FOR GCTCCTTACTCATGGTCGGATCACAAAG >520999_KIT_18_REV GGCACAGGAAACAATTTTTATCGAAAGTTGAAAC >520999_KIT_19_FOR CTCCACATTTCAGCAACAGCAGCATC >520999_KIT_19_REV CCCATAGGACCAGACGTCACTTTCAAACG >520999_KIT_20_FOR CTGTGAAGTGGATGGCACCTGAAAAG >520999_KIT_20_REV CAATGAAAACTTCAAGAAGATGCTCTGAGTC >520999_TPMT_01_FOR 15 GGGCAATTCCTCAAAAACATGTCAGTGTG >520999_TPMT_01_REV 16 GCAATATACGTTGTCTTGAGAAGGTTGATGC >520999_TPMT_02_FOR 17 GCTTTTCAAAAAGACAGTCAATTCCCCAAC >520999_TPMT_02_REV 18 GGGAGAATCCCTGATGTGCATTCTTCATAG >520999_TPMT_03_FOR 19 GGGATCAAGAAACTAGGCAACTGGTAAAAG >520999_TPMT_03_REV 20 CCTTCTTGTGTTCTTTGTAGCTATGCAGATAC >520999_TPMT_04_FOR 21 GTTGGATCATAAGAAAGAACACACAGGAGATAC >520999_TPMT_04_REV 22 CAGCGAAAGTAACTTCTGGCTTCCTTCC >520999_TPMT_05_FOR 23 GGGAAGTCTAAGCTGATTTTCTAGAACCCAG >520999_TPMT_05_REV 24 GGGCAAATTTGACATGATTTGGGATAGAGG >520999_TPMT_06_FOR 25 GGGTTACTTACCATTTGGCGATCACCTGG >520999_TPMT_06_REV 26 GATTGTTGAAGTACCAGCATGCACCATG >520999_TPMT_07_FOR 27 GGCTGAGAAAAACTTTTGTGGGGATATGGATAC >520999_TPMT_07_REV 28 GTGTAGTTGGTGTGGGAAATCAGTGAACTTGG >520999_TPMT_08_FOR 29 GGTTCTTCTGAGTAAGAAAGATTCTGCTCTG >520999_TPMT_08_REV 30 GAGGGTGCTTACTCTAATATAACCCTCTATTTAGTC >520999_EGFR_01_FOR TTTCCAGCATGGTGAGGGCTGAGGTGA >520999_EGFR_01_REV GCACCGGAGCCCAGCACTTTGATC >520999_EGFR_02_FOR CCAAGCTCTCTTGAGGATCTTGAAGGAAAC >520999_EGFR_02_REV GGAAATATACAGCTTGCAAGGACTCTGGG >520999_EGFR_03_FOR GCATGTGGCACATCTCACAATTGCCA >520999_EGFR_03_REV CCACACAGCAAAGCAGAAACTCACATC >520999_EGFR_04_FOR GAGAAAGTTAAAATTCCCGTCGCTATCAAGG >520999_EGFR_04_REV GAGAAAAGGTGGGCCTGAGGTTCAGAG >520999_EGFR_05_FOR CCTCCTTCTGGCCACCACATGCGAAGC >520999_EGFR_05_REV CGAAGGGCATGAGCTGCTGATGAG >520999_EGFR_06_FOR GACTGCTGGGCATCTGCCTCACCTC >520999_EGFR_06_REV CCGTATCTCCCTTCCCTGATTACCTTTGC >520999_EGFR_07_FOR CTGGACTATGTCCGGGAACAAAAGAC >520999_EGFR_07_REV CATGGCAAACTCTTTGCTATCCCAGGAG >520999_EGFR_08_FOR GATGCAGAGCTTCTTCCCATGATGATCTG >520999_EGFR_08_REV CAGTTTGGCCAGCCCAAAATCTGTGATC >520999_EGFR_09_FOR GCAGCCAGGAACGTACTGGTGAAAAC >520999_EGFR_09_REV CAGCTAGTGGGAAGGCAGCTGGTC >520999_MET_01_FOR CACAATCATACTGCTGACATACAGTCGGAG >520999_MET_01_REV CGGGAAATAAGAAGAATTTATGGTATTGCCTACAAAAG >520999_MET_02_FOR GAGCCAAAGTCCTTTCATCTGTAAAGGACC >520999_MET_02_REV GGTAAAACATCAATGTAGGACTGGTCCGTC >520999_MET_03_FOR CAGCTTGCTAGACAAATAGGAGCCAGC >520999_MET_03_REV TCCGTAAAAATGCTGGAGACATCTCACATTG >520999_MET_04_FOR CAATGGATCGATCTGCCATGTGTGCATTC >520999_MET_04_REV CCTCACAGTTTAAGTGGGGAACTGATGTG >520999_MET_05_FOR GCATTTTTACGGACCCAATCATGAGCACTG >520999_MET_05_REV GGGCAACTATTTTGGATAAACACCATTTACAAAG >520999_MET_06_FOR GGGTAAGTCACATCAGTTCCCCACTTATAAACTG >520999_MET_06_REV CGGGTAGGTGTAAATGAAGATTCAATTCCTC >520999_MET_07_FOR GCCAGGTGTTTATCCAAAAATAGTTGCAG >520999_MET_07_REV GGCTGAAATGTCACGAACATGCAAATCTG >520999_MET_08_FOR ACTGTGCCTCTGACCTGTAATCAGTGC >520999_MET_08_REV CTAACTGAATTCAGGTTTTTCCCAACACCTG >520999_MET_09_FOR CTATTTTGCTTTGCCAGTGGTGGGGAGC >520999_MET_09_REV GGTTAGAGGCAAAGATGCAGAGCTCTG >520999_MET_10_FOR CGGGAACACTGGAGCATAATTGAGGAATCTC >520999_MET_10_REV GGCGAAAAGTCAGCATTTAGCCATGATAG >520999_MET_11_FOR GGGACCCAAAGTGCTACAACCTGTGTAG >520999_MET_11_REV CTGGTTGAACTATTACTTTTCCAAGGACGG >520999_MET_12_FOR CCATGAGTTCTGGGCACTGGGTCAAAG >520999_MET_12_REV CTTACACTTCGGGCACTTACAAGCCTATC >520999_MET_13_FOR GCAGTGAATTAGTTCGCTACGATGCAAGAG >520999_MET_13_REV CCTTCTGGAAAAGTAGCTCGGTAGTCTACAG >520999_MET_14_FOR GTAAGTGCCCGAAGTGTAAGCCCCAACTAC >520999_MET_14_REV GCAATGTCACACCCACTGAGGTATATGTATAGG >520999_MET_15_FOR GGGTGGTTTACCATTTCATTGCTCTTCCTATC >520999_MET_15_REV GGCTTTCATGATGATTCCCTCGGTCAG >520999_MET_16_FOR CCACCACTGGATTTCTCAGGAATCACTGAC >520999_MET_16_REV CTCCATGTTTCATGTATGGTAGGACCACC >520999_MET_17_FOR CCTGGGAATCTGCCTGCGAAGTGAAG >520999_MET_17_REV CCTATTTTGAAGGGATGGCTGGCTTACAGC >520999_BRAF_01_FOR CTTTCTAGTAACTCAGCAGCATCTCAGGG >520999_BRAF_01_REV GGTGATTTTGGTCTAGCTACAGTGAAATCTCG >520999_BRAF_02_FOR GGATCCAGACAACTGTTCAAACTGATGG >520999_BRAF_02_REV GCCTAAACTCTTCATAATGCTTGCTCTGATAGG >520999_RET_01_FOR CCTGGCTTCTCCTTTACCCCTCCTTC >520999_RET_01_REV CCCACACTTACACATCACTTTGCGTGG >520999_RET_02_FOR GATTCCAGTTAAATGGATGGCAATTGAATCCC >520999_RET_02_REV CGTGGCCCCACTACATGTATAAGGG >520999_BRCA2_24_FOR CTGAAGTGGAACCCAAATGATACTGATCC >520999_BRCA2_24_REV AAGGGTTAGTTGAGACCATTCACAG >520999_BRCA2_25_FOR GTAGCAAATCAGAAGCCCTTTGAGAG >520999_BRCA2_25_REV GGTCACATGAAGAAATATGCAATAGGGG >520999_BRCA2_26_FOR GGTCTCAACTAACCCTTTCAGGTC >520999_BRCA2_26_REV CTTTTCTTTCTTTTGTTCTCTGTGTCTAATAGGTC >520999_BRCA2_27_FOR CCCTATTGCATATTTCTTCATGTGACC >520999_BRCA2_27_REV CCACTGTTTCCTCATTTAATGGGCTTCT >520999_BRCA2_28_FOR GAGAATTCTTTGCCACGTATTTCTAGCC >520999_BRCA2_28_REV TGGAGAAGTTCCAGATATTGCCTGC >520999_BRCA2_29_FOR GAGAGATGAAGAGCAGCATCTTGAAT >520999_BRCA2_29_REV CTTGCATTGAAAGTCTCTTTAGGTGATTCTC >520999_BRCA2_30_FOR TGGAACTTCTCCAGTGGCTTTCTTC >520999_BRCA2_30_REV GTCCACTTTCAGAGGCTTCAGTTTC >520999_BRCA2_31_FOR GAGACTTTCAATGCAAGTTTTTCAGGTC >520999_BRCA2_31_REV GGCTGGCCAGCTTCCATTATCAATTAA >520999_BRCA2_32_FOR CATACTGTTTGCTCCACAGAAGGAGG >520999_BRCA2_32_REV AACTTATTTGTTTTTCTTTTTCAAAGTGGATATTAAAC >520999_BRCA2_33_FOR AAGCTGGCCAGCCACCACCACAC >520999_BRCA2_33_REV CAGTTAATTAGTTCTGATTTTTGGTCTTTCGG >520999_BRCA2_34_FOR GCTTTGAAGAATGCAGGTTTAATATCCAC >520999_BRCA2_34_REV GCATTTGCTTCAAACTGGGCTGAACAG >520999_BRCA2_35_FOR GAAACATCTTATAAAAGGAAAAAAAATACCGAAAGACC >520999_BRCA2_35_REV CACAGAAGGAATCGTCATCTATAAAACTATATGTAC >520999_BRCA2_36_FOR GTGATTGATGGTACTTTAATTTTGTCACTTTGTG >520999_BRCA2_36_REV CTAGAACATTTCCTCAGAATTGTCCC >520999_BRCA2_37_FOR GAATGATTCTGAAGAACCAACTTTGTCC >520999_BRCA2_37_REV GCTTCTTTATAATCAAGATCCTGAGAG >520999_BRCA2_38_FOR CTGAGGAAATGTTCTAGAAATGAAACATGTTC >520999_BRCA2_38_REV GCTTTTTGGATCATTTTCACACTGTCC >520999_BRCA2_39_FOR CCCAGAAGCTGATTCTCTGTCATG >520999_BRCA2_39_REV GGATTGAAAGTCAGTATCACTGTATTCC >520999_BRCA2_40_FOR GCAGCATGTCACCCAGTACAAC >520999_BRCA2_40_REV GACTAGGTTTGACAGAACATCCTTGG >520999_BRCA2_41_FOR GTCTTTTATATGATCATGAAAATGCCAGCACTC >520999_BRCA2_41_REV CATAATTGTTACCTTTGAGCTTGTCTGAC >520999_BRCA2_42_FOR CCTAGTCATGATTTCTAGAGGCAAAG >520999_BRCA2_42_REV GCACATACATCTTGATTCTTTTCCATGGG >520999_BRCA2_43_FOR CAAATGTCAGACAAGCTCAAAGGTAAC >520999_BRCA2_43_REV TTCAGGTGGCAACAGCTCAACG >520999_BRCA2_44_FOR CCCATGGAAAAGAATCAAGATGTATGTGGC >520999_BRCA2_44_REV CTCTTAGATTTGTGTTTTGGTTGAATTGTACC >520999_BRCA2_45_FOR CCTGAAAAATACATGAGAGTAGCATCACC >520999_BRCA2_45_REV GAGAAAAGTTCTTCAGAGTCTGGATTGACAG >520999_BRCA2_46_FOR GTACAATTCAACCAAAACACAAATCTAAGAGTAATCC >520999_BRCA2_46_REV GCAAGATTATTCCTTTCATTAGCTACTTGG >520999_BRCA2_47_FOR CTCTGAAGAACTTTTCTCAGACAATGAG >520999_BRCA2_47_REV CATGGTAGAGTTCTTGAAAATGGGTTCG >520999_BRCA2_48_FOR CTAAGGAACTTCATGAAACAGACTTGAC >520999_BRCA2_48_REV GTTCTCCTCTGCAAGAACATAAACCAAATC >520999_BRCA2_49_FOR TATGGAGACACAGGTGATAAACAAGCAACC >520999_BRCA2_49_REV CTGGTATTTTATCTATATTCAAGGAGATGTCCG >520999_BRCA2_50_FOR GCAGCATATAAAAATGACTCTAGGTCAAG >520999_BRCA2_50_REV ATTTCCTTATTTGAAGCTTGTTCTGAAGC >520999_BRCA2_51_FOR CAAATGGCAGGACTCTTAGGTCC >520999_BRCA2_51_REV CAACACAAGCTAAACTAGTAGGATATTGTTCTTC >520999_BRCA2_52_FOR CAAGCTCTCTGAACATAACATTAAGAAGAGCA >520999_BRCA2_52_REV CAACTACACTACTCTGTAAATGTGCAGATACAG >520999_BRCA2_53_FOR CAAAAGAAACTGAGCAAGCTCAG >520999_BRCA2_53_REV CTGTAATTTCTGCCTTTTTGGCTAGGTG >520999_KRAS_01_FOR 31 GGGGACATAACAGTTATGATTTTGCAGAAAACAG >520999_KRAS_01_REV 32 GCCTTCTAGAACAGTAGACACAAAACAGGC >520999_KRAS_02_FOR 33 GGCTTACCTGTCTTGTCTTTGCTGATGTTTC >520999_KRAS_02_REV 34 GTTAAGGACTCTGAAGATGTACCTATGGTCC >520999_KRAS_03_FOR 35 GTTTTGTGTCTACTGTTCTAGAAGGCAAATCAC >520999_KRAS_03_REV 36 GGGAACAAAAGTTGTGGACAGGTTTTGAAAG >520999_KRAS_04_FOR 37 CCAGAGGACTATAATTACTCCTTAATGTCAGC >520999_KRAS_04_REV 38 GAGTACAGTGCAATGAGGGACCAGTAC >520999_KRAS_05_FOR 39 GGCAAATACACAAAGAAAGCCCTCCC >520999_KRAS_05_REV 40 GGGTGCACTGTAATAATCCAGACTGTG >520999_KRAS_06_FOR 41 CCTTTATCTGTATCAAAGAATGGTCCTGCAC >520999_KRAS_06_REV 42 GACTGAATATAAACTTGTGGTAGTTGGAGCTGG >520999_KRAS_07_FOR 43 CTGAATTAGCTTGTATCGTCAAGGCACTC >520999_KRAS_07_REV 44 GGGAAGGTACTGGTGGAGTATTTGATAGTG >520999_BRCA2_01_FOR ATTTTCCAGCGCTTCTGAGTTTTACC >520999_BRCA2_01_REV GCCTCTCTTTGGATCCAATAGGCA >520999_BRCA2_02_FOR ACTTATTTACCAAGCATGGAGGAATATCG >520999_BRCA2_02_REV GCATTTTTTAGAAAACACTTTCTCGGTGT >520999_BRCA2_03_FOR TTTTTTCCTTATGATCTTTAACTGTTCTGGGTC >520999_BRCA2_03_REV CAGGTTCAGAATTATAGGGTGGGAGC >520999_BRCA2_04_FOR GGACCAATAAGTCTTAATTGGTTTGAAGAAC >520999_BRCA2_04_REV GTTGAAGCCAGCTGATTATAAGATGGT >520999_BRCA2_05_FOR AACAACAATTACGAACCAAACCTATTTAAAACTC >520999_BRCA2_05_REV TGCATTACTTACCTAAGTCTAATTTGAATTTATCT >520999_BRCA2_06_FOR AAAGAGCAAGGGCTGACTCTGC >520999_BRCA2_06_REV GAGCTAAGATTTTAACACAGGTTTGCC >520999_BRCA2_07_FOR AGAATGCAAATTTATAATCCAGAGTATATACATTCTCACTGA >520999_BRCA2_07_REV TAATAGCTTCATCATACCTTTCACTAAGAC >520999_BRCA2_08_FOR GATCAAGCAGATGATGTTTCCTGTCCAC >520999_BRCA2_08_REV TGTAAGATCTTCTACCAGGGCTCTTAGCC >520999_BRCA2_09_FOR GCCAGTTTTTAAAATAACCTAAGGGATTTGCTTTG >520999_BRCA2_09_REV ACATTTCTAGTATTCTAAGAATAAAAAGCATTG >520999_BRCA2_10_FOR CACATGTAACACCACAAAGAGATAAGTCAGGT >520999_BRCA2_10_REV ACCAGGTAGAATATTTACCTTCACAAACTTTGGTGT >520999_BRCA2_11_FOR CCCCAGTGGTATGTGGGAGTT >520999_BRCA2_11_REV GCTAGGTACAGATTTGTAAATCTCAGGG >520999_BRCA2_12_FOR TCAGTAAACGTTAAGTGAAATAAAGAGTGAATG >520999_BRCA2_12_REV AAGACATATCAGGATCCACCTCAGCTCCCTAGAC >520999_BRCA2_13_FOR CTATTTTCTTTCCTCCCAGGGTCG >520999_BRCA2_13_REV CCTATGAGCACAGTAGAACTAAGGG >520999_BRCA2_14_FOR GAGCTGAGGTGGATCCTGATATGT >520999_BRCA2_14_REV GAGATGACAATTATCAACCTCATCTGCTC >520999_BRCA2_15_FOR TCAAATGTGTCATGTAATCAAATAGTAGATGTGC >520999_BRCA2_15_REV GTCATATTTACTTACAGCAGTAGTATCATGAGG >520999_BRCA2_16_FOR TCTTACAGTCAGAAATGAAGAAGCATCTG >520999_BRCA2_16_REV GAGACTTTCTCAAAGGCTTAGATAAATTACAGATTAGG >520999_BRCA2_17_FOR GGGACTACTACTATATGGTGCATTGAGAGT >520999_BRCA2_17_REV GTGTTTTCACTGTCTTGTCACAGAAGCGA >520999_BRCA2_18_FOR GCTATTTTTTCCAATCATGATGAAAGTCTGAAG >520999_BRCA2_18_REV AACCTGTAGTTCAACTAAACAGAGGAC >520999_BRCA2_19_FOR ACAAATCAAAGAGAAGCTGCAAGTC >520999_BRCA2_19_REV AACCGAGATCACGGGTGACAG >520999_BRCA2_20_FOR CATAAACTGTTTTCTATGAGAAAGGTTGTTGAG >520999_BRCA2_20_REV GACTTTCCAATGTGGTCTTTGCAGC >520999_BRCA2_21_FOR CAGGATTTGGAAAAACATCAGGGAATTC >520999_BRCA2_21_REV CTATCTTCTTCAGAGGTATCTACAACTG >520999_BRCA2_22_FOR GTCAATGCCAAATGTCCTAGAAGATGAAG >520999_BRCA2_22_REV CTTGGTTTTTAGATTTTTCACATTCATCAGCG >520999_BRCA2_23_FOR CTACAAAAAGTAAGAACTAGCAAGACTAGG >520999_BRCA2_23_REV CTTCCACTCTCAAAGGGCTTCTG >520999_BRCA2_54_FOR CCTCAGATGTTATTTTCCAAGCAGG >520999_BRCA2_54_REV GTACTCTTCTGCAATATGTAGCTTGG >520999_BRCA2_55_FOR ACTTTCTACTATAATTAGAAGAATCAGGAAGTCAG >520999_BRCA2_55_REV GACATGAAGATCAGCATCTCTGCATTCC >520999_BRCA2_56_FOR CCTGAAAACCAGATGACTATCTTAAAAGACC >520999_BRCA2_56_REV CATTTTTCAACAGGCCAGCAAACTTCCG >520999_BRCA2_57_FOR CATCGATTGGTCAGGGTAGACAGC >520999_BRCA2_57_REV GAAACATTCAGTTTTGTGCCATGAGCAG >520999_BRCA2_58_FOR CAGATGAAAATGAAGTGGGTTTAGG >520999_BRCA2_58_REV GGATGTACTCTCTGCAGAAGTTTCCTCAC >520999_BRCA2_59_FOR CTGAATGTTTCTACTGAAGCTCTGC >520999_BRCA2_59_REV CACTTACAGTTTTATCATTATGATTTTCTATCTTAAACATTGAAAC >520999_BRCA2_60_FOR GAAACTTCTGCAGAGGTACATCC >520999_BRCA2_60_REV CAGTAGTCATTTCAATATTATTTTGTAATATCAGTTGGC >520999_BRCA2_61_FOR CCAATAAGTTTATCTTCAAGTAAATGTCATGATTCTG >520999_BRCA2_61_REV CAGTAATTTCTTCAACAAAAGTGCCAGTAGTC >520999_BRCA2_62_FOR GTTTCAATGTTTAAGATAGAAAATCATAATGATAAAACTGTAAGTG >520999_BRCA2_62_REV CTAAGTTATGAGAATTTCTACTGGCAGCAG >520999_BRCA2_63_FOR GAAATGACTACTGGCACTTTTGTTGAAG >520999_BRCA2_63_REV GCAAGTCCGTTTCATCTTTATGAATACAAAC >520999_BRCA2_64_FOR GTAGAAATTCTCATAACTTAGAATTTGATGGCAGTG >520999_BRCA2_64_REV CTTCTTTAATCTGAGTGTTTCCCTCC >520999_BRCA2_65_FOR GCTATTTACTGATCAGCACAACATATGTC >520999_BRCA2_65_REV CCATGACATGCTTCTTGAGCTTTCG >520999_BRCA2_66_FOR GGAAACACTCAGATTAAAGAAGATTTGTCAG >520999_BRCA2_66_REV GCAGTCTGAAAAAATGTATCAGAAGTCTC >520999_BRCA2_67_FOR GAACAGTTAACTGCTACTAAAACGGAGC >520999_BRCA2_67_REV GGAAAGTTATGCAATTCTTCTGGTTTCTGATC >520999_BRCA2_68_FOR GGGAAAAATATTAGTGTCGCCAAAGAGTC >520999_BRCA2_68_REV CTATGTCTGTTTCCTCATAACTTAGAATGTCC >520999_BRCA2_69_FOR GATCAGAAACCAGAAGAATTGCATAACTTTTCC >520999_BRCA2_69_REV GATTTCCAGTACCAACTGGGACAC >520999_BRCA2_70_FOR GGACATTCTAAGTTATGAGGAAACAGACATAG >520999_BRCA2_70_REV TTCCGCTAGCTGTATGAAACC >520999_BRCA2_71_FOR CAGGGACAACCCGAACGTGATG >520999_BRCA2_71_REV CTGGTGATTTCACTAGTACCTTGCTC >520999_BRCA2_72_FOR GTTAAAATTGCAAAGGAATCTTTGGACAAAGTG >520999_BRCA2_72_REV CTGTGATCTCAATGGTCTCACATGC >520999_BRCA2_73_FOR CCTAAAGTACAGAGAGGCCTG >520999_BRCA2_73_REV CTTAGGTGGCACCACAGTCTC >520999_BRCA2_74_FOR CCAAAGTGTAAAGAAATGCAGAATTCTCTC >520999_BRCA2_74_REV GACTTTTTGCTGTTTCTTTTTCTACATTTTCATGTAC >520999_BRCA2_75_FOR GTGCCACCTAAGCTCTTAAGTG >520999_BRCA2_75_REV GACTGAATAAGGGGACTGATTTGTGTAAC >520999_BRCA2_76_FOR GAAAGTTAAAGTACATGAAAATGTAGAAAAAGAAACAGC >520999_BRCA2_76_REV CTTCAAGTAATGAAGTCTGACTCACAGAAG >520999_BRCA2_77_FOR CCTTATTCAGTCATTGAAAATTCAGCCTTAGC >520999_BRCA2_77_REV CTGCAGTATTTATTCTTTCTGGTTGACCATC >520999_BRCA2_78_FOR CTGTGAGTCAGACTTCATTACTTGAAGC >520999_BRCA2_78_REV GAGATGATTTTTGTCATTTTCAGCTATAGTACTG >520999_BRCA2_79_FOR CCAGAAAGAATAAATACTGCAGATTATGTAGG >520999_BRCA2_79_REV CCTCATCAGAATGGTAGGAATAGC >520999_BRCA2_80_FOR CCGAAAAAACAAGATACTTATTTAAGTAACAGTAGC >520999_BRCA2_80_REV GATCTTCAACATTCTTCAATACTGGCTC >520999_BRCA2_81_FOR CTGATGAGGTATATAATGATTCAGGATATCTCTC >520999_BRCA2_81_REV CAGTTTGTGGGTATGCATTTGCATC >520999_BRCA2_82_FOR GAGCCAGTATTGAAGAATGTTGAAGATC >520999_BRCA2_82_REV GGTGAAGAGCTAGTCACAAGTTCC

>520999_BRCA2_83_FOR GATGCAATGCATACCCACAAACTG >520999_BRCA2_83_REV CGATTTTACCACTGGCTATCTCTAAATGCAGG >520999_BRCA2_84_FOR GGAACTTGTGACTAGCTCTTTCACCCTGC >520999_BRCA2_84_REV GTCTTTCACTTTTTTAATTGTTTCATGTGAAACAC >520999_BRCA2_85_FOR CCTGCATTTAGGATAGCCAGTGG >520999_BRCA2_85_REV CAACCTGCCATAATTTTCGTTTGGC >520999_BRCA2_86_FOR CAGTTTCAGTAAAGTAATTAAGGAAAACAACGAG >520999_BRCA2_86_REV CCTTATGTGAATGCGTGCTACATTCATC >520999_BRCA2_87_FOR CGAGGCATTGGATGATTCAGAGG >520999_BRCA2_87_REV GGTGATATTTTAGAAACTTTCTCCAATCCAGAC >520999_BRCA2_88_FOR GGTTTTTGCTGACATTCAGAGTGAAG >520999_BRCA2_88_REV GATGAGACTGACTTATGAAGCTCCC >520999_BRCA2_89_FOR CCTTGTGATGTTAGTTTGGAAACTTCAG >520999_BRCA2_89_REV GCGTTTTGTAATGAAGCATCTGATACC >520999_BRCA2_90_FOR GTGGGATTTTTAGCACAGCAAGTGG >520999_BRCA2_90_REV CTCTTGTGAGCTGGTCTGAATGTTC >520999_BRCA2_91_FOR CTGAAATAGAAGATAGTACCAAGCAAGTC >520999_BRCA2_91_REV CCAGAGAAAGCAGATGAATTTACCAC >520999_BRCA2_92_FOR GAAAATACTGCTATACGTACTCCAGAAC >520999_BRCA2_92_REV CTCTAACACTCCCTTAACTTTGTGTAAGG >520999_BRCA2_93_FOR CAGCAAGTGGAAAGCAAGTTTCC >520999_BRCA2_93_REV GGGTTTCTCTTATCAACACGAGG >520999_BRCA2_94_FOR CTTCACTATTCACCTACGTCTAGACA >520999_BRCA2_94_REV GTGATTATTTTCTGAAGAACCACCTTCAAC >520999_BRCA2_95_FOR GAGCACTGTGTAAACTCAGAAATGG >520999_BRCA2_95_REV CCTAATACCAACTGTTGTTTGTCTTGTTG >520999_BRCA2_96_FOR GAAGGTGGTTCTTCAGAAAATAATCACTC >520999_BRCA2_96_REV CGTTTTTAGGTGAAGCCTGTTC >520999_BRCA2_97_FOR GAACCAAAGTGTCACTTGTTGAGAAC >520999_BRCA2_97_REV GTAGTTTTCTGAATCTTTGGAGTAAGTAGAAC >520999_BRCA2_98_FOR CTGAAACTTTTTCTGATGTTCCTGTG >520999_BRCA2_98_REV GAATGTGTGGCATGACTTGGCAG >520999_BRCA2_99_FOR GCTTTTATGGAAGATGATGAACTGAC >520999_BRCA2_99_REV AAATGAACACTTACCCACTAAGATAAGG >520999_BRCA2_100_FOR CATGTCCCGAAAATGAGGAAATGG >520999_BRCA2_100_REV CACTTTAAAAATAGTGATTGGCAACACGAAAGG >520999_BRCA2_101_FOR GGTCTATAGACTTTTGAGAAATAAAACTGATATTATTTGCC >520999_BRCA2_101_REV TGGAGTGCTTTTTGAAGCCTTTAAG >520999_BRCA2_102_FOR CCTCAATCAAAAGAAAACTTATTAAATGAATTTGACAGG >520999_BRCA2_102_REV CAGAATATTATATACCATACCTATAGAGGGAGAACAG >520999_BRCA2_103_FOR ATTGTCTCAAATTTTTTGTGTATTTACAGTAACA >520999_BRCA2_103_REV GGTAATCGGGCTCTAAAGAAACATGATGC >520999_BRCA2_104_FOR CTAATATGTAATATAAAATAATTGTTCCTAGGCAC >520999_BRCA2_104_REV AACGAGACTTTTCTCATACTGTATTAGAATTTAG >520999_BRCA2_105_FOR ATGTAGCAAATGAGGGTCTGCAACAA >520999_BRCA2_105_REV GACAGAAATTTCTTGACCAGGTGCG >520999_BRCA2_106_FOR ACTAAGGAACGTCAAGAGATACAGAATCC >520999_BRCA2_106_REV GAAACTTGATAAAATGGATGTCCTGAAACTGC >520999_BRCA2_107_FOR CTAAATCTCATTTGTATGAACATCTGACTTTGG >520999_BRCA2_107_REV GGAAAAAGACTTTGGTTGGTCTGCCTGTAG >520999_BRCA2_108_FOR GTTTCTGCTACAAGAAATGAAAAAATGAGACAC >520999_BRCA2_108_REV CAGAGCCATGTCCATCAATGTTTTGC >520999_BRCA2_109_FOR TCACAGAGTTGAACAGTGTGTTAGGAATAT >520999_BRCA2_109_REV CAGCTACTGCTTGATTGGAGTTG >520999_BRCA2_110_FOR GCTCTGATGATAGTAAAAATAAGATTAATGACAATGAG >520999_BRCA2_110_REV GACATTATTTAACAACGGAAATATCTAACTGAAAGGC >520999_BRCA2_111_FOR GGTTGTGCTTTTTAAATTTCAATTTTATTTTTTGCTAAG >520999_BRCA2_111_REV CAGACTGCCTGGCTGTGGAAAGACG >520999_BRCA2_112_FOR GATTTAATTACAAGTCTTCAGAATGCCAGAG >520999_BRCA2_112_REV GATTCGAGGGCAGAGTGGATGTTTTT >520999_BRCA2_113_FOR AACAAAGGCAACGCGTCTTTCC >520999_BRCA2_113_REV CCATCAGTATTGTAGACAAACACATACCTG >520999_BRCA2_114_FOR GCCAAGTTCCCTCTGCGTGTT >520999_BRCA2_114_REV TGTGTTCATTCTTTAAACAAAGCCATTTGT >520999_BRCA2_115_FOR TCAGTTTTGGTTTGTTATAATTGTTTTTATTGTGT >520999_BRCA2_115_REV AGACTCTGCATTTTTGCTGTTAATTTTTATGCAA >520999_BRCA2_116_FOR TTTATTTTGTGTAGCTGTATACGTATGGCG >520999_BRCA2_116_REV CCATCCACCATCAGCCAACTGTATT >520999_BRCA2_117_FOR AAGATTATTTTGGTAAGGAAAGTTTATGGACTGG >520999_BRCA2_117_REV GGGATGAGGGAATACATAAAAGTTAACAC >520999_BRCA2_118_FOR GTTGTAGTTGTTGAATTCAGTATCATCCTATGTGG >520999_BRCA2_118_REV GCTGCCAGTTTCCATATGATCCATCTATAGTG >520999_BRCA2_119_FOR TTATTTGTTCAGGGCTCTGTGTGACACTCC >520999_BRCA2_119_REV GGGCTTAGGCATCTATTAGCAAATTCC >520999_BRCA2_120_FOR TATAGATGGATCATATGGAAACTGGCAGC >520999_BRCA2_120_REV CCGTATATGATTACGTAATGTAATGCTTTAAACT >520999_BRCA2_121_FOR TGCTAATAGATGCCTAAGCCCAGA >520999_BRCA2_121_REV CTGGCTTGTGCAACATTTTGACATGG >520999_BRCA2_122_FOR AGTTTTTATTCTCAGTTATTCAGTGACTTGTT >520999_BRCA2_122_REV CATTATCTTTTTTATAGCCGATCTTCTGCTTC >520999_BRCA2_123_FOR GCATTTTTGTTTTCACTTTTAGATATGATACGG >520999_BRCA2_123_REV GCTAGAAGTTTCAGATATATTTGCGCTC >520999_BRCA2_124_FOR GGATGACACAGCTGCAAAAACAC >520999_BRCA2_124_REV CAGCATACCACCCATCTGTAAGTTC >520999_BRCA2_125_FOR GCAATAAAACTAGTAGTGCAGATACCCA >520999_BRCA2_125_REV CTGCTCCATGAAGAATAATCTTTCTGACC >520999_BRCA2_126_FOR GCCCAGTTAGATCCTCCCCCTCT >520999_BRCA2_126_REV ACCTTTAACATAAGAGATTCTGGGGGC >520999_BRCA2_127_FOR GGGCTCCTCCTGATGCCTGTAC >520999_BRCA2_127_REV AAATTGAGCATCCTTAGTAAGCATTTAAAATTTAA >520999_BRCA2_128_FOR GCAGTTCTAGAAGAATGAAAACTCTTATGATATCTG >520999_BRCA2_128_REV GGAAAGAATCCAAGTTTGGTATACCAGCGAG >520999_BRCA2_129_FOR TATTAATTTGTCCAGATTTCTGCTAACAGTACTC >520999_BRCA2_129_REV CATCATACCTGTATAGGGTATGCTC >520999_BRCA2_130_FOR CCTTATCATCGCTTTTCAGTGATGGAG >520999_BRCA2_130_REV GAGACCGAAACTCCATCTCAAACAAAC >520999_BRCA2_131_FOR GAATGTTATATATGTGACTTTTTTGTGTGTGTAACAC >520999_BRCA2_131_REV CAAATTCCTCCTGAATTTTAGTGAATAAGGCTTC >520999_BRCA2_132_FOR CAATGAAAGAGAGGAAGAAAAAGGAAGCAGC >520999_BRCA2_132_REV CTTTGTTCTCATATTAGAAATAACAATGTGTACC >520999_BRCA2_133_FOR CCTTCTTTGGGTGTTTTATGCTTGG >520999_BRCA2_133_REV GCACGAACTTGCTGTCTTGTTAG >520999_BRCA2_134_FOR CTTAGAAAACACAACAAAACCATATTTACCATC >520999_BRCA2_134_REV CATCAAGCCTCATTATATGTCCTCTTACTC >520999_BRCA2_135_FOR GTTCGTGCTTTGCAAGATGGTG >520999_BRCA2_135_REV GGCCAGAGAGTCTAAAACAGCTTC >520999_BRCA2_136_FOR CTAGTACAATAGATGGAACTTTTTTGTTCTGATTGC >520999_BRCA2_136_REV GAGCTTGTTTCTTATCATTCAACATTTGCC >520999_BRCA2_137_FOR GTCACAGGGTTATTTCAGTGAAGAGC >520999_BRCA2_137_REV GTGACATCCCTTGATAAACCTTGTTCC >520999_BRCA2_138_FOR AAGCTCAGATCCAGTTGGAAATTAGGAAG >520999_BRCA2_138_REV CTGATAAAAACAAAGCATTTACATACTTACCTG >520999_BRCA2_139_FOR GTTTATCAAGGGATGTCACAACCGT >520999_BRCA2_139_REV TCTGGATTTATAATCATTTTGTTAGTAAGGTCATT >520999_BRCA2_140_FOR AAAAGAGGATCTGTATTTATTTTGAAACAAACAT >520999_BRCA2_140_REV GCAAGATGATAAATTCTGTATCTCTTTCCTTCTG >520999_BRCA2_141_FOR GGCGTCCATCATCAGATTTATATTCTCTG >520999_BRCA2_141_REV TGTACCGGTAGTTGTTGATACTGAG >520999_BRCA2_142_FOR AAAGTAAATCTGAAAGAGCTAACATACAGTTAGC >520999_BRCA2_142_REV TGAAACCTACAGAAAACAAAACAAAAATTCAAC >520999_BRCA2_143_FOR TCAGTTTGATAAGTGCTTTGTTAGTTTATGG >520999_BRCA2_143_REV CAAGATGGCTGAAAGTCTGGATCTAAA >520999_BRCA2_144_FOR AAATTTTATTTCAGATTTACCAGCCACGG >520999_BRCA2_144_REV GTGCATTACCTGTTTTTTTCACAACAG >520999_BRCA2_145_FOR CCATCTTGTTCTGAGGTGGACCTAA >520999_BRCA2_145_REV GCCAACTGGTAGCTCCAACTAATCA >520999_BRCA2_146_FOR TAGGCATATTAGAGTTTCCTTTCTTGCATC >520999_BRCA2_146_REV AGGTCTATCCAAAACTTTATTGCCAGT >520999_BRCA2_147_FOR ATTCTAGGACTTGCCCCTTTCGTC >520999_BRCA2_147_REV ATTTGGATTCTGGTCGCCACTGGA >520999_BRCA2_148_FOR GACCTTAATGAGGACATTATTAAGCCTCA >520999_BRCA2_148_REV TGTCTCTTGAAAGTGGCCCTCTTT >520999_BRCA2_149_FOR TCAGGCCTTCTTACTTTATTTGCTGG >520999_BRCA2_149_REV GAAAAATACCAAAATGTGTGGTGATGCTG >520999_BRCA2_150_FOR GGTCCAAACTTTTCATTTCTGCTTTTTAAAGG >520999_BRCA2_150_REV TTGCATGCAGTATATGCATAAGCTTGT >520999_BRCA2_151_FOR TTTTCTTAGAATATTGACATACTTTGCAATGAAGC >520999_BRCA2_151_REV ACCAGAAGCTTGTTTCCTGTACC >520999_BRCA2_152_FOR TCCACCCCAACTAAAGACTGTACT >520999_BRCA2_152_REV CTAGGTATACAACAGAATATACGATGGCC >520999_BRCA2_153_FOR TTGCGTGCTTAAATATTTTCAATGAAAAGTTACTT >520999_BRCA2_153_REV CAGGTGTGGAAAACAGACTTCCTTT >520999_BRCA2_154_FOR CTTCTCCTAATTGTGAGATATATTATCAAAGTCC >520999_BRCA2_154_REV AGGCTCTTCTCTTTTTGCAGTTCTT >520999_BRCA2_155_FOR TCAGCCCAGATGACTTCAAAGTCT >520999_BRCA2_155_REV GCAGCCGGAGAAACAAATGTACAA >520999_BRCA2_156_FOR TCTTGAGTAGACTGCCTTTACCTCCA >520999_BRCA2_156_REV GGAGTCATCTGAGGAGAATTCAGTTCT >520999_BRCA2_157_FOR ATTTCAGCCACCAAGGAGTTGTG >520999_BRCA2_157_REV CAATGCAAGTTCTTCGTCAGCTATTG >520999_BRCA2_158_FOR CTCAGATGACTCCATTTAAAAAATTCAATGAAAATT >520999_BRCA2_158_REV GAGCAGTCCTAGTGGATTCACTGA >520999_BRCA2_159_FOR CAAGCTCTTTTGTCTGGTTCAACAGG >520999_BRCA2_159_REV GCCTGGGAACTCTCCTGTTCTTT >520999_BRCA2_160_FOR CTCAGACTGAAACGACGTTGTACTACATC >520999_BRCA2_160_REV CCAGTCTTATAAACTGGAAAGGTTAAGCGTC >520999_BRCA2_161_FOR GTACGGAAGAATGTGAGAAAAATAAGCAGG >520999_BRCA2_161_REV TGTGCAACATAAGTACTAATGTGTGGT >520999_AKT1_01_FOR GAGTGAGGATGGCTACAGGGCAGAGGTG >520999_AKT1_01_REV CCTGCATGGACCACTGTCATCGAAC >520999_AKT1_02_FOR CACGTACCGCTCTCCAGGAGTTTCTCAC >520999_AKT1_02_REV AGTGCCAGCTGATGAAGACGGAGCG >520999_AKT1_03_FOR GCAGGCAGCGGATGATGAAGGGTGTTG >520999_AKT1_03_REV GGTATGCAAGGGGAGCTGGCTGGTG >520999_AKT1_04_FOR GCTCCAGCCAACCCCCCAAATCTGAAT >520999_AKT1_04_REV CTCAAGAATGATGGCACCTTCATTGGCTAC >520999_AKT1_05_FOR ACAGAGAAGTTGTTGAGGGGAGCCTCA >520999_AKT1_05_REV GCACGTCTGTAGGGGAGTACATCAAGAC >520999_AKT1_06_FOR GTGCCATCATTCTTGAGGAGGAAGTAGCGTGG >520999_AKT1_06_REV CCTGGATGACTGGGCAGGGGTCTGACG >520999_TP53_01_FOR TCTGACGCACACCTATTGCAAGCAAG >520999_TP53_01_REV GGTCAGTCTACCTCCCGCCATAAAAAAAC >520999_TP53_02_FOR GTGGGGAACAAGAAGTGGAGAATGTCAG >520999_TP53_02_REV CACAGACCCTCTCACTCATGTGATGT >520999_TP53_03_FOR TCAGCTGCTTTGACCATGAAGGCA >520999_TP53_03_REV TGAATGAGGCCTTGGAACTCAAGGATGC >520999_TP53_04_FOR CTGAGGTCACTCACCTGGAGTGAG >520999_TP53_04_REV CTCCTCTGTTGCTGCAGATCCG >520999_TP53_05_FOR GGCATCCTTGAGTTCCAAGGCCTCA >520999_TP53_05_REV GCATGTTGCTTTTGTACCGTCATAAAGTC >520999_TP53_06_FOR GCAGGCTAGGCTAAGCTATGATGTTCC >520999_TP53_06_REV GCATGAAAATGGTTCTATGACTTTGCCTG >520999_TP53_07_FOR GGAAGTAACACCATCGTAAGTCAAG >520999_TP53_07_REV GTAGCTAACTAACTTCAGAACACCAACTT >520999_TP53_08_FOR ACGGCATTTTGAGTGTTAGACTGGA >520999_TP53_08_REV CTTTCCTAGCACTGCCCAACAACAC >520999_TP53_09_FOR CATCCAGTGGTTTCTTCTTTGGCTG >520999_TP53_09_REV GCACTAAGCGAGGTAAGCAAGCAGG >520999_TP53_10_FOR GGCATAACTGCACCCTTGGTCTCCTCCAC >520999_TP53_10_REV GGAACAGCTTTGAGGTGGCGTGTTTGT >520999_TP53_11_FOR CCTTTCTTGCGGAGATTCTTCTTCCTC >520999_TP53_11_REV GTAGGACCTGATTTCCTTACTGCCTC >520999_TP53_12_FOR GATGAGAGGTGGATGGGTAGTAGTATGG >520999_TP53_12_REV CCATCCTCACCATCATCACACTGGAA >520999_TP53_13_FOR CAGTGTGCAGGTGGCAAGTGGCTC >520999_TP53_13_REV ATCTCCTAGGTTGCTCTGACTGTAC >520999_TP53_14_FOR GGTTCATGCCGCCCATGCAGGAACTG >520999_TP53_14_REV CCTGCTTGCCACAGGTCTCCCCAAGG >520999_TP53_15_FOR ACTGACAACCACCCTTAACCCCTCCT >520999_TP53_15_REV CCCTCCTCAGCATCTTATCCGAGTG >520999_TP53_16_FOR CTGTCATCCAAATACTCCACACGCA >520999_TP53_16_REV CTCAGATAGCGATGGTGAGCAGCTG >520999_TP53_17_FOR GACCCTGGGCAACCAGCCCTGTC >520999_TP53_17_REV CGCGCCATGGCCATCTACAAGCAG >520999_TP53_18_FOR GGCAGCGCCTCACAACCTCCGTC >520999_TP53_18_REV CCCTGCCCTCAACAAGATGTTTTGCC >520999_TP53_19_FOR TGTGGAATCAACCCACAGCTGCACA >520999_TP53_19_REV TGCCGTCTTCCAGTTGCTTTATCTG >520999_TP53_20_FOR GATACGGCCAGGCATTGAAGTCTC >520999_TP53_20_REV GTCCCTTCCCAGAAAACCTACCAG >520999_TP53_21_FOR CAGAATGCAAGAAGCCCAGACGGAAAC >520999_TP53_21_REV AGATGAAGCTCCAGAATGCCAGAGG >520999_TP53_22_FOR GGTGTAGGAGCTGCTGGTGCAGG >520999_TP53_22_REV CCTTGCCGTCCCAAGCAATGGATG >520999_TP53_23_FOR GTTCTTCAGTGAACCATTGTTCAATATCGTCC >520999_TP53_23_REV TCTGACTGCTCTTTTCACCCATCTAC >520999_TP53_24_FOR CATCAAATCATCCATTGCTTGGGAC >520999_TP53_24_REV CTGACTTTCTGCTCTTGTTCTTTCAGACTTC >520999_TP53_25_FOR CCCAACCCTTGTCCTTACCAGAACG >520999_TP53_25_REV CCATTGGAAGGGCAGGCCCAC

>520999_TP53_26_FOR CAAGAGCAGAAAGTCAGTCCCATGG >520999_TP53_26_REV GTCGAGCCCCCTCTGAGTCAG >520999_TP53_27_FOR GGATCCACTCACAGTTTCCATAGGTCTG >520999_TP53_27_REV GATCCCCACTTTTCCTCTTGCAGCAG >520999_ERBB2_01_FOR TGTGGTCTCCCATACCCTCTCAGCGTAC >520999_ERBB2_01_REV GGTCTAAGAGGGCAGCCATAGGGCATAAGC >520999_ERBB2_02_FOR CATCTGCCTGACATCCACGGTGCAG >520999_ERBB2_02_REV GGACATAGGGGTTTGCTCCGGAGAGAC >520999_BRCA1_01_FOR GATTTCCAAGGGAGACTTCAAGCAG >520999_BRCA1_01_REV GAGCTTACAAAGTGGCTTTTCC >520999_BRCA1_02_FOR AGGACAGTAGAAGGACTGAAGAGGTGAGAGG >520999_BRCA1_02_REV GATACCCCAGATCCCCCACAGCCACTACTGAC >520999_BRCA1_03_FOR TCCTGTGGCTCTGTACCTGTG >520999_BRCA1_03_REV ATGTGTGAGGCACCTGTGTGGTGA >520999_BRCA1_04_FOR TCCTGGCACTGGTAGAGTGCT >520999_BRCA1_04_REV CGATTGATTAGAGCCTAGTCCAGGAG >520999_BRCA1_05_FOR CAAGAACTGTGCTACTCAAGCACC >520999_BRCA1_05_REV CAATTGTGGTTGTGCAGCCAGA >520999_BRCA1_06_FOR ACAGGTACATGCAGGGCACCTTAC >520999_BRCA1_06_REV GAAGTGACAGTTCCAGTAGTCCTAC >520999_BRCA1_07_FOR AGGCTACAGTAGGGGCATCCATA >520999_BRCA1_07_REV TGCTTCTGTGGTGAAGGAGCT >520999_BRCA1_08_FOR ACAGGGCACCCAATACTTACTGTG >520999_BRCA1_08_REV CCTGGGTTAAGTATGCAGATTACTGC >520999_BRCA1_09_FOR AGCAATCTGAGGAACCCCAT >520999_BRCA1_09_REV GGCTAGAAATCTGTTGCTATGGGGC >520999_BRCA1_10_FOR TGCTGGAACTCTGGGGTTTCTC >520999_BRCA1_10_REV ACTAGATTTTCCTTCTCTCCATTCCCC >520999_BRCA1_11_FOR CAAAATGAAGCGGCCCATCTCT >520999_BRCA1_11_REV GGTCAATGGAAGAAACCACCAAGG >520999_BRCA1_12_FOR CTTGAGGGAGGGAGCTTTACCTTT >520999_BRCA1_12_REV AGCTTCTCTTTCTCTTATCCTGATGGG >520999_BRCA1_13_FOR CATTGACCACATCTCCTCTGACTTC >520999_BRCA1_13_REV CGCCTGGCCTGAATGCTTAA >520999_BRCA1_14_FOR AGGAAAGTGGTGCATTGATGGAAG >520999_BRCA1_14_REV TGATCTCTTTAGGGGTGACCCAG >520999_BRCA1_15_FOR GTAACATCAAGTACTTACCTCATTCAGCA >520999_BRCA1_15_REV CTGTGCTCTTTTGTGAATCGCTGA >520999_BRCA1_16_FOR GTTAGGTGTAAAAATGCAATTCTGAGGTG >520999_BRCA1_16_REV GGACACTGAAATATTTTCTAGGAATTGCG >520999_BRCA1_17_FOR GAGGGGAGAAATAGTATTATACTTACAGAAATAGC >520999_BRCA1_17_REV CAGCACTTCCTGATTTTGTTTTCAACT >520999_BRCA1_18_FOR GCAGCAGATGCAAGGTATTCTGTAAAGG >520999_BRCA1_18_REV GATTTAATTTCAGATGCTCGTGTACAAGTTTGCC >520999_BRCA1_19_FOR CATGAGTAGTCTCTCTCAGTAATTAGATTAG >520999_BRCA1_19_REV GTATTCTGAGCTGGTGTGCTAGAGGTAACTC >520999_BRCA1_20_FOR TCTTCCTCTAGGTTATTAATTGACAATACCTAC >520999_BRCA1_20_REV CAACAGAAAGGGTCAACAAAAGAATGT >520999_BRCA1_21_FOR CACTCACAAATTCTTCTGGGTCAG >520999_BRCA1_21_REV GCTGCTGCTCATACTACTGATACTGC >520999_BRCA1_22_FOR CTTCTCCCTGGCTCACACTTTCTTC >520999_BRCA1_22_REV GCTCGTGTTGGCAACATACCATC >520999_BRCA1_23_FOR CTGGGCAGATTCTGCAACTTTC >520999_BRCA1_23_REV GGAATCTGGAATCAGCCTCTTCTCTG >520999_BRCA1_24_FOR TCTGGGGCTCTGTCTTCAGAAG >520999_BRCA1_24_REV ACAGAGACCAGAACTTTGTAATTCAACA >520999_BRCA1_25_FOR AGACTAGTACATCTAAAAGTTGGTTAACCAG >520999_BRCA1_25_REV AGTCTGGGCCACACGATTTGA >520999_BRCA1_26_FOR GATGAAATATTACCTAGATCTTGCCTTGGC >520999_BRCA1_26_REV AGTTGCTCTGGGAGTCTTCAGAATA >520999_BRCA1_27_FOR CACATCAACAACCTTAATGAGCTCCTC >520999_BRCA1_27_REV GTGGCGATGGTTTTCTCCTTCCATT >520999_BRCA1_28_FOR GTACCACCTATCATCTAATGATGGGC >520999_BRCA1_28_REV GCTGTTTCATTTATGCTTTGGCTGCC >520999_BRCA1_29_FOR GATGTCAGATACCACAGCATCTTTACATTGATG >520999_BRCA1_29_REV GAATACCCTATAAGCCAGAATCCAGAAGG >520999_BRCA1_30_FOR GAACTATCTGCAGACACCTCAAACTTGTC >520999_BRCA1_30_REV CTAACCTGAATTATCACTATCAGAACAAAGCAG >520999_BRCA1_31_FOR AGCAGAAAGGCCTTCTGGATTCT >520999_BRCA1_31_REV GATGCTTTTGAAAAAAATCAGTATTCTAACCTG >520999_BRCA1_32_FOR GCAGAGGGAAGGCTCAGATACAAACACAGC >520999_BRCA1_32_REV CTAAAAGGCCTAGAGAACATATATCAGG >520999_BRCA1_33_FOR ACCATCTTTCAGTAATTTGCCAAAATGACG >520999_BRCA1_33_REV GAACAGTACCCCGTTCCCTTGATGTCTACAATTTC >520999_BRCA1_34_FOR GAGCTAGGTCCTTACTCTTCAGAAGG >520999_BRCA1_34_REV CTACCCTTCCATCATAAGTGACTC >520999_BRCA1_35_FOR ACCTTTTTCTGATGTGCTTTGTTCTGG >520999_BRCA1_35_REV ACCTGATAAAGCTCAGCAGGAAAT >520999_BRCA1_36_FOR TAGCTGTAGAAGGCTGGCTCC >520999_BRCA1_36_REV GGAAAGCTTCTCAAAGTATTTCATTTTCTTGG >520999_BRCA1_37_FOR GTCAGCAAACCTAAGAATGTGGGA >520999_BRCA1_37_REV AGGCGTCTCTGAAGACTGCTCA >520999_BRCA1_38_FOR CACACACACGCTTTTTACCTGAGT >520999_BRCA1_38_REV AGTCTGCTTTTACATCTGAACCTTCTG >520999_BRCA1_39_FOR AGACGCTTTGTTTCACTCTCACAC >520999_BRCA1_39_REV GAAAGTAAATCCAGTCCTGCCAATGAG >520999_BRCA1_40_FOR TTGTAAAATGTGCTCCCCAAAAGC >520999_BRCA1_40_REV AAGAGGAACGGGCTTGGAAGA >520999_BRCA1_41_FOR CCTGGTTCCAATACCTAAGTTGAATCC >520999_BRCA1_41_REV GGTTCTTCCAAACAAATGAGGCATCAGT >520999_BRCA1_42_FOR AAACCAATTCCTTGTCACTCAGACC >520999_BRCA1_42_REV CTGCTAGCTTGTTTTCTTCACAGTG >520999_BRCA1_43_FOR AGGATCCTGGGTGTTTGTATTTGC >520999_BRCA1_43_REV GCTTAAATGACTGCAGTAACCAGGT >520999_BRCA1_44_FOR CTCACTAAGGTGATGTTCCTGAGATGC >520999_BRCA1_44_REV CACTTGTTATTTGGTAAAGTAAACAATATACCTTCTCAGTCTACT >520999_BRCA1_45_FOR TTAGACAGACACTCGGTAGCAACG >520999_BRCA1_45_REV GGGCCAAGAAATTAGAGTCTCTCAG >520999_BRCA1_46_FOR AACAAGTGTTGGAAGCAGGGAAG >520999_BRCA1_46_REV CAGAAAGGAGAGCTTAGCAGGAGT >520999_BRCA1_47_FOR GGTAACCCTGAGCCAAATGTGTATG >520999_BRCA1_47_REV CACCTGATGACCTGTTAGATGATGGTG >520999_BRCA1_48_FOR TGCTAAAAACAGCAGAACTTTCCTTAATGTCATTTTCAGCA >520999_BRCA1_48_REV AGAAGTAGTTCAGACTGTTAATACAGATTTCTCTCCA >520999_BRCA1_49_FOR CTTCCCATAGGCTGTTCTAAGTTATCTGA >520999_BRCA1_49_REV GGTTTTGCAACCTGAGGTCTATAAACA >520999_BRCA1_50_FOR TTTTATTTCAGGATGCTTACAATTACTTCCAGG >520999_BRCA1_50_REV TCCAGTATTAATGAAATAGGTTCCAGTGA >520999_BRCA1_51_FOR GGTTGCAAAACCCCTAATCTAAGCATAG >520999_BRCA1_51_REV GCCAGCTCAAGCAATATTAATGAAGTAGG >520999_BRCA1_52_FOR TGGAGCCCACTTCATTAGTACTGG >520999_BRCA1_52_REV CAATGTCACCTGAAAGAGAAATGGGA >520999_BRCA1_53_FOR TACGGCTAATTGTGCTCACTGTAC >520999_BRCA1_53_REV ACCACCACTTTTTCCCATCAAGTC >520999_BRCA1_54_FOR TGTTCCTCAAAGTTTTCCTCTAGCAG >520999_BRCA1_54_REV AGTTCAGAGGCAACGAAACTGG >520999_BRCA1_55_FOR AGTGGTGGTATACGATATGGGTTTTGT >520999_BRCA1_55_REV GGTTGGTCAGAAAGATAAGCCAGTTGATA >520999_BRCA1_56_FOR AACTGAGATGATAGACAAAACCTAGAGCC >520999_BRCA1_56_REV CAAAAGGAAGAAAATCAAGGAAAGAATGAGTC >520999_BRCA1_57_FOR CCACAGGAAAGCCTGCAGTGATA >520999_BRCA1_57_REV AACATTCTCTGCCCACTCTGGGT >520999_BRCA1_58_FOR TTGTTCACATTCAAAAGTGACTTTTGGAC >520999_BRCA1_58_REV TGCTCAGTATTTGCAGAATACATTCAAGG >520999_BRCA1_59_FOR GCACATTCCTCTTCTGCATTTCCTGG >520999_BRCA1_59_REV GAAGGCTTTAAGTATCCATTGGGGACATG >520999_BRCA1_60_FOR TCTTCCATTTCTATGCTTGTTTCCCG >520999_BRCA1_60_REV ATGTGTGAGTCAGTGTGCAGCA >520999_BRCA1_61_FOR CTTTGGAACACCATGAATTAGTCCC >520999_BRCA1_61_REV TGGTACCTGGTACTGATTATGGCA >520999_BRCA1_62_FOR CTTCCCTAGAGTGCTAACTTCCAGT >520999_BRCA1_62_REV TGCTGAAGACCCCAAAGATCTCATG >520999_BRCA1_63_FOR AATACTGCTACTCTCTACAGATCTTTCAGT >520999_BRCA1_63_REV TGAACTTAAAGAATTTGTCAATCCTAGCCTT >520999_BRCA1_64_FOR TCAGCATTATTAGACACTTTAACTGTTTCTAGTTTCTCT >520999_BRCA1_64_REV CAAGCCAAATGAACAGACAAGTAAAAGAC >520999_BRCA1_65_FOR TGCATTTGTTAACTTCAGCTCTGGGG >520999_BRCA1_65_REV AAATGCCAGTCAGGCACAGCA >520999_BRCA1_66_FOR CTTCTTGGCTCCAGTTGCAGGT >520999_BRCA1_66_REV AGCCCACCTAATTGTACTGAATTGC >520999_BRCA1_67_FOR TGTACTTTTTTTTCTTTATCTCTTCACTGCTAG >520999_BRCA1_67_REV TCAAAGCACCTAAAAAGAATAGGCTG >520999_BRCA1_68_FOR ACTAGTTCAAGCGCATGAATATGCC >520999_BRCA1_68_REV CTGCTTTCAAAACGAAAGCTGAACC >520999_BRCA1_69_FOR ATTTAATTCGAGTTTCCATATTGCTTATACTGCTG >520999_BRCA1_69_REV CAAGTGATGAATATTACTAATAGTGGTCATGAGA >520999_BRCA1_70_FOR GTTAGGATTTTTCTCATTCTGAATAGAATCACC >520999_BRCA1_70_REV GGATTTTATCAAGAAAGCAGATTTGGCAGT >520999_BRCA1_71_FOR TGCTCCGTTTGGTTAGTTCCCT >520999_BRCA1_71_REV ACAAGAGCGTCCCCCTCACAAAT >520999_BRCA1_72_FOR AAATCCTCAGGATGAAGGCCTGA >520999_BRCA1_72_REV AAGCCTCCCCAACTTAAGCCA >520999_BRCA1_73_FOR CTGTGCTCAGTAACAAATGCTCCTA >520999_BRCA1_73_REV GCTTTAATATGTAAAAGTGAAAGAGTTCACTCC >520999_BRCA1_74_FOR CTTCCGATAGGTTTTCCCAAATATTTTGTC >520999_BRCA1_74_REV GACGTTCTAAATGAGGTAGATGAATATTCTGG >520999_BRCA1_75_FOR AAGCCTCATGAGGATCACTGGCCAGTAAGTC >520999_BRCA1_75_REV GTGATGAACTGTTAGGTTCTGATGACTC >520999_BRCA1_76_FOR CGTCCAATACATCAGCTACTTTGGC >520999_BRCA1_76_REV CCTAGAGATACTGAAGATGTTCTTGG >520999_BRCA1_77_FOR ACCACTCATTAACTTTCTGAATGCTGC >520999_BRCA1_77_REV CCCAGCACAGAAAAAAAGGTAGATCTG >520999_BRCA1_78_FOR CTTATTCCATTCTTTTCTCTCACACAGG >520999_BRCA1_78_REV GGCTTAGCAAGGAGCCAACATAAC >520999_BRCA1_79_FOR TGGGAGTCCGCCTATCATTACATGT >520999_BRCA1_79_REV CAGCATGAGAACAGCAGTTTATTACTCAC >520999_BRCA1_80_FOR TATGTTGGCTCCTTGCTAAGCCAG >520999_BRCA1_80_REV TGTGGAGCCATGTGGCACAAAT >520999_BRCA1_81_FOR TGAGTAATAAACTGCTGTTCTCATGCTGTAATGAGCT >520999_BRCA1_81_REV GGATGTAACAAATACTGAACATCATCAACCCAGT >520999_BRCA1_82_FOR CTGCACGCTTTCTCAGTGTGTTCA >520999_BRCA1_82_REV TGATTTCCACCTCCAAGGTGTATGAAGTATGT >520999_BRCA1_83_FOR GTTACATCCGTTCTCAGAAAATTCACAAG >520999_BRCA1_83_REV TAGCCAGTTGGTTGATTTCCACC >520999_BRCA1_84_FOR GTAAAGGTCCCAAATGGTCTTCAGA >520999_BRCA1_84_REV ACCCCTCAAGGAACCAGGGATG >520999_BRCA1_85_FOR ACTTTGCCATTACCCTTTTTTGCAGA >520999_BRCA1_85_REV GGTCATTTGACAGTTCTGCATACATGTAAC >520999_BRCA1_86_FOR CCAGCTTCATAGACAAAGGTTCTC >520999_BRCA1_86_REV GAAAACTTTTATTGATTTATTTTTTGGGG >520999_BRCA1_87_FOR CCACAAATACAAATTATGACCAAGATTTTTGGC >520999_BRCA1_87_REV ACTCTGAGGACAAAGCAGCGG >520999_BRCA1_88_FOR CTTACCCAATTCAATGTAGACAGACGTC >520999_BRCA1_88_REV TGGCCAACAATTGCTTGACTGTTC >520999_BRCA1_89_FOR CAAGGTTAGAGAGTTGGACACTGAG >520999_BRCA1_89_REV GGTCAATTTATTTTGTCCATGGTGTCAAG >520999_BRCA1_90_FOR CTGGGCCACAGAGCAAGACTCCATCTC >520999_BRCA1_90_REV GATGAAGTTTCTATCATCCAAAGTATGGGGCTAC >520999_BRCA1_91_FOR GGTTCACTCTGTAGAAGTCTTTTGGC >520999_BRCA1_91_REV CATTTTTCTCTAACTGCAAACATAATGTTTTCCCTTG >520999_BRCA1_92_FOR ACCACGTCATAGAAAGTAATTGTGCAAAC >520999_BRCA1_92_REV CGAGATTTAGTCAACTTGTTGAAGAGCTA >520999_BRCA1_93_FOR GGGATATTCAACACTTACACTCCAAACC >520999_BRCA1_93_REV AGGTTGATAATCACTTGCTGAGTGTG >520999_BRCA1_94_FOR CTTTTTTCCTACTGTGGTTGCTTCCAACC >520999_BRCA1_94_REV GATTTTGCATGCTGAAACTTCTCAACCAG >520999_BRCA1_95_FOR CATTCTTACATAAAGGACACTGTGAAGGC >520999_BRCA1_95_REV GATTATTCTTTTCATGGCTATTTGCCTTTTGAGTATTC >520999_BRCA1_96_FOR AGCTTCTATAAAGTTAGGTGTTTCCTGGG >520999_BRCA1_96_REV TACCCTGCTAGTCTGGAGTTGA >520999_BRCA1_97_FOR CATTCAAACTTACTTGCAAATATGTGGTCAC >520999_BRCA1_97_REV ACAGCTCAAAGTTGAACTTATTCACTAAG >520999_BRCA1_98_FOR CATAGGAATCCCAAATTAATACACTCTTTGTGC >520999_BRCA1_98_REV CTAATGTGTTAAAGTTCATTGGAAACAGAAAGAAATGG >520999_BRCA1_99_FOR GACATTTTGTACTTCTTCAACGCGAAG >520999_BRCA1_99_REV GTTCTTTGGTTTGTATTATTCTAAAACCTTCCAAATC >520999_CYP2D6_01_FOR 45 GTACATTAGAGCCTCTGGCTAGGGAGCAG >520999_CYP2D6_01_REV 46 ACTTCAGCTTCTCGGTGCCACTGG >520999_CYP2D6_02_FOR 47 GCTCACCAGGAAAGCAAAGACACCATGG >520999_CYP2D6_02_REV 48 GTATCACCCAGGAGCCAGGCTCACTGAC >520999_CYP2D6_03_FOR 49 GCAAGACTCCACGGAAGGGGACAGG >520999_CYP2D6_03_REV 50 GCTGAAGGATGAGGCCGTCTGGGAG >520999_CYP2D6_04_FOR 51 CATCCAGGAAGTGTTCGGGGTGGAAG >520999_CYP2D6_04_REV 52 CCAGCATCCTAGAGTCCAGTCCCCAC >520999_CYP2D6_05_FOR 53 CTATCACCAGGTGCTGGTGCTGAGCTG >520999_CYP2D6_05_REV 54 ATGCCCTACACCACTGCCGTGATTCATG >520999_CYP2D6_06_FOR 55 TCATATGGGTCACACCCAGGGGGACG >520999_CYP2D6_06_REV 56 GTGAGGACGCATGTCTGTCCAGGCC >520999_CYP2D6_07_FOR 57 ACCTCATGAATCACGGCAGTGTGTAGG >520999_CYP2D6_07_REV 58 GCAAGAAGGAGTTGTCAGGGCCGGAC >520999_CYP2D6_08_FOR 59 CACGGGTGTCCCAGCAAAGTTCATGG >520999_CYP2D6_08_REV 60 CTGACAGGATGGTGACCACCTCGACC >520999_CYP2D6_09_FOR 61 GATGAGCTCACGCTGCACATCCGGATG >520999_CYP2D6_09_REV 62 CTCAGACATGCTCAGGCCAAGGGGAAC >520999_CYP2D6_10_FOR 63 CCATCCCGGCAGAGAACAGGTCAGC >520999_CYP2D6_10_REV 64 CTACCCCGTTCTGTCCCGAGTATGCTC >520999_CYP2D6_11_FOR 65 GACTACCCTCATTCCTCCTGGGAACGCTC >520999_CYP2D6_11_REV 66 GATGAGCTGCTAACTGAGCACAGGATGACC >520999_CYP2D6_12_FOR 67 CAGCCACTCTCACCTTCTCCATCTCTGC >520999_CYP2D6_12_REV 68 GAATGCTGTCCCCGTCTCTCCTGCATATC >520999_CYP2D6_13_FOR 69 GAAAGCCTTTTGGAAGCGTAGGACCTTGC >520999_CYP2D6_13_REV 70 GAGATGGCTGGGGCCTGAGACTTGTC >520999_CYP2D6_14_FOR 71 CTGCAGAGACTCCTCGGTCTCTCGC >520999_CYP2D6_14_REV 72 GAAGACCCTTTCGCCCCCAACGGTCTC >520999_CYP2D6_15_FOR 73 GAAGCGAGGGTCGTCGTACTCGAAGC >520999_CYP2D6_15_REV 74 GGAAGACAGAGGGACGGGGAAGGCGAC >520999_CYP2D6_16_FOR 75 GAGAGATGAGAGTAAGGGGGTCGCCTTCCC >520999_CYP2D6_16_REV 76 GACTGGGCAAGAAGTCGCTGGAGCAG >520999_CYP2D6_17_FOR 77 CTGACCATCACCCACCGGAGTGGTTG >520999_CYP2D6_17_REV 78 CACACACACAGGGGTGTTCCTGGCG >520999_CYP2D6_18_FOR 79 CACAGACCCAAGTTGCGCAAGGTGG >520999_CYP2D6_18_REV 80 GTGGGTGGTGGATGGTGGGGCTAATG >520999_CYP2D6_19_FOR 81 CCGGGTCCCACGGAAATCTGTCTCTG >520999_CYP2D6_19_REV 82 GACAGTGGTCGTGCTGCAATGGGCTG >520999_CYP2D6_20_FOR 83 CAACAGCTGCTTGCCTTGGGAACGC >520999_CYP2D6_20_REV 84 CTTCGGGGACGTGTTCAGCCTGCAG >520999_CYP2D6_21_FOR 85 CACATTGAGCACGACCACCGGCGTC >520999_CYP2D6_21_REV 86 GGTTCAAATAGGACTAGGACCTGTAGTCTGGGG >520999_CYP2D6_22_FOR 87 GCTTCTGGTCCAGCCTGTGGTTTCAC >520999_CYP2D6_22_REV 88 GCAACCTGCTGCATGTGGACTTCCAG >520999_CYP2D6_23_FOR 89 GACCTCCTCCCTCACCTGGTCGAAGC >520999_CYP2D6_23_REV 90 GCCATCTTCCTGCTCCTGGTGGACC >520999_CYP2D6_24_FOR 91 GATAGAGTGCAGCCAGCGTTTGGCG >520999_CYP2D6_24_REV 92 CCAGGTGTGTCCAGAGGAGCCCATTTG >520999_BRAF_01_FOR 93 CTTTCTAGTAACTCAGCAGCATCTCAGGG >520999_BRAF_01_REV 94 GGTGATTTTGGTCTAGCTACAGTGAAATCTCG >520999_BRAF_02_FOR 95 GGATCCAGACAACTGTTCAAACTGATGG >520999_BRAF_02_REV 96 GCCTAAACTCTTCATAATGCTTGCTCTGATAGG

In the present invention, the amplicon may be an amplification product obtained by amplifying a wild type of an unmutated cancer gene and an anticancer drug metabolism-related gene with the primers, and may preferably be selected from the sequences shown in Table 3 below, More preferably, it may be selected from the sequences of SEQ ID NOs: 97 to 128.

Amplicon name sequence number Amplicon sequence >520999_AKT1_01 CCAGCACCCCGCCATCCCCGTGTCCCTCCTAAGCGCTGGGGCTGCCCAAGTGCCTGGCCTGGCCGCCACAGCCCACGTACCGCTCCTCAGGAGTCTCCACATGGAAGGTGC >520999_AKT1_02 ATGGAAGGTGCGTTCGATGACAGTGGTCCACTGCAGGCAGCGGATGATGAAGGTGTTGGGCCGGGGC >520999_AKT1_03 GGCCGGGGCCGCTCCGTCTTCATCAGCTGGCACTCTGCGGGCAGGCAGAGCCTCTGTCTGCGTGCATCCCCCTGCCCCTCCCAGGGCCCTCACCACAGCCCCCGCTG >520999_AKT1_04 CCCGAGAGGCCAAGGGGATACTTACGCGCCACAGAGAAGTTGTTGAGGGGAGCCTCACGTTGGTCCACATCCTGCGGCCGCTCCTT >520999_AKT1_05 CGTTGGTCCACATCCTGCGGCCGCTCCTTGTAGCCAATGAAGGTGCCATCATTCTTGAGGAGGAAGTAGCGTGGCCGCCAG >520999_AKT1_06 CCGCCAGGTCTTGATGTACTCCCCTACAGACGTGCGGGTGTGTGAGAGCCACGCACACTCTACC >520999_BRAF_01 CCAAAAATTTAATCAGTGGAAAAATAGCCTCAATTCTTACCATCCACAAAATGGATCCAGACAACTGTTCAAACTGATGGGACCCACTCCAT >520999_BRAF_02 GACCCACTCCATCGAGATTTCACTGTAGCTAGACCAAAATCACCTATTTTTACTGTGAGGTCTTCATGAAGAAATATATCTGAGGTGTAGTAAGTAAAGGAAAACAGTAGATCTCATTTT >520999_BRCA1_01 AAAATCTTTAAGGGACCCTTGCATAGCCAGAAGTCCTTTTCAGGCTGATGTACATAAAATATTTAGTAGCCAGGACAGTAGAAGGACTGAAGAGTGAGAGGAGCTCCCAGGGCCT >520999_BRCA1_02 AGCTCCCAGGGCCTGGAAAGGCCACTTTGTAAGCTCATTCTTGGGGTCCTGTGGCTCTGTACCTGTGGCTGGCTGCA >520999_BRCA1_03 GCTGGCTGCAGTCAGTAGTGGCTGTGGGGGATCTGGGGTATCAGGTAGGTGTCCAGCTCCTGGCACTGGTAGAGTGCTACACTGTCCAACACCCACTCTCGGG >520999_BRCA1_04 ACACTGTCCAACACCCACTCTCGGGGTCACCACAGGTGCCTCACACATCTGCCCAATTGCTGGAGACAGAGAACACAAGCAGAGATTAGTGTCAATTCATT >520999_BRCA1_05 AGGTAATGAGTGATAAACCAAACCCATGCAAAAGGACCCCATATAGCACAGGTACATGCAGGCACCTTACCATGGAAGCCATTGTCCTCTGTCCAGGCA >520999_BRCA1_06 CATGGAAGCCATTGTCCTCTGTCCAGGCATCTGGCTGCACAACCACAATTGGGGTGGACACCCTGGATCCCCAGGAAGGAAAGAGCATTCAAAGTGTCAAA >520999_BRCA1_07 GGGACTGACAGGTGCCAGTCTTGCTCACAGGAGAGAATATTGTGTCCTCCCTCTCTGACAGGGCACCCAATACTTACTGTGCCAAGGGTGAATGATGAA >520999_BRCA1_08 CCAAGGGTGAATGATGAAAGCTCCTTCACCACAGAAGCACCACACAGCTGTACCATCCATTCCAGTTGATCTAAAATGGACATTTAGATGTAAAATCACT >520999_BRCA1_09 CGTGGGATCTTGCTTATAATACTCCACTATGTAAGACAAAGGCTGGTGCTGGAACTCTGGGGTTTCTCCCAGGCTCTTACCTGTGGGCATGTTGGTGAAGG >520999_BRCA1_10 CCAGGCTCTTACCTGTGGGCATGTTGGTGAAGGGCCCATAGCAACAGATTTCTAGCCCCCTGAAGATCTGGAAGAAGAGAGGAAGAGAGAGGGACA >520999_BRCA1_11 GCAAAGGGGAGTGGAATACAGAGTGGTGGGGTGAGATTTTTGTCAACTTGAGGGAGGGAGCTTTACCTTTCTGTCCTGGGATTCTCTTGCTCGCTTTGGA >520999_BRCA1_12 CTGTCCTGGGATTCTCTTGCTCGCTTTGGACCTTGGTGGTTTCTTCCATTGACCACATCTCCTCTGACTTCAAAATCATGCTGAAAGAAACCAAACACAA >520999_BRCA1_13 AAAATCATGCTGAAAGAAACCAAACACAACCCATCAGGATAAGAGAAAGAGAAGCTTCCTTTCAATGGAAGTGGAGCAGACACGTCATATAT >520999_BRCA1_14 GAAGCAAATACATTTTTAACTATATGACTGAATGAATATCTCTGGTTAGTTTGTAACATCAAGTACTTACCTCATTCAGCATTTTTCTTTCTTTAATAGA >520999_BRCA1_16 TTAAAGGGAGGAGGGGGAGAAATAGTATTATACTTACAGAAATAGCTAACTACCCATTTTCCTCC >520999_BRCA1_18 TTCTTGGTATACCTGTTTTCATAACAACATGAGTAGTCTCTTCAGTAATTAGATTAGTTAAAGTGATGTGGTGTTTTCT >520999_BRCA1_20 ATAAAACTCTTTCCAGAATGTTGTTAAGTCTTAGTCATTAGGGAGATACATATGGATACACTCACAAATTCTTCTGGGGTCAGGCCAGACACCACCATGG >520999_BRCA1_22 CATTGCATTATACCCAGCAGTATCAGTAGTATGAGAGCAGCAGCTGGACTCTGGGCAGATTCTGCAACTTTCAATTGGGGAACTTTCAATGCAGAGGTTGAA >520999_BRCA1_24 GATCAGATTCAGGGTCATCAGAGAAGAGGCTGATTCCAGATTCCAGGTAAGGGGTTCCCTCTGAAAGGAATGGGAGAAGTTTAATTTACACAACGATGAA >520999_BRCA1_26 AAGTAAGATGTTTCCGTCAAATCGTGTGGCCCAGACTCTTCCAGCTGTTGCTCCTCCACATCAACAACCTTAATGAGCTCCTCTTGAGATGGGTAGTTTC >520999_BRCA1_28 ATTTAGAAGGGGATGACCTAGAAAGATAATGGAAGGAGAAAACCATCGCCACCAATTGTGAAAGGACAAATCATACTTGCTG >520999_BRCA1_30 AGCAGAAAGGCCTTCTGGATTCTGGCTTATAGGGTATTCACTACTTTTCTGTGAAGTTAATACTGCTTTAAATGGAATGAGAAAACAAATCTACTTTA >520999_BRCA1_32 TATTAAAAAGTCATTCCTCCTTTTGGCCAGAACCACCATCTTTCAGTAATTTGCCAAAATGACGAACACAAAGGGAAAGAGGAGAGGCA >520999_BRCA1_34 AGATAAAGGGGAAGGAAAGAATTTTGCTTAAGATATCAGTGTTTGGCCAACAATACACACCTTTTTCTGATGTGCTTTGTTCTGGATTTCGCAGGTCCTCAAGGGCAGAA >520999_BRCA1_36 CATGCTGTTCTAACACAGCTTCTAGTTCAGCCATTTCCTGCTGGAGCTTTATCAGGTTATGTTGCATGGTATCCCTCTGGCTTCAAAAACGATAAATGGCA >520999_BRCA1_38 GGTTAAAATGTCACTCTGAGAGGATAGCCCTGAGCAGTCTTCAGAGACGCTTGTTTCACTCTCACACCCAGATGCTGCTTCACCTTAAATAACAAAAA >520999_BRCA1_40 ATAAACATTTAGCTCACTTCTATAAATAGACTGGGGCAAACACAAAAACCTGGTTCCAATACCTAAGTTTGAATCCATGCTTTGCTCTTCTTGATTATTATTT >520999_BRCA1_42 AACTCCCTGGGCTTTCAGACTGATGCCTCATTTGTTTGGAAGAACCAATCAAGAAAGGATCCTGGGTGTTTGTATTTGCAGTCAAGTCTTCCAATTCACTG >520999_BRCA1_44 CTTTGCCAATATTACCTGGTTACTGCAGTCATTTAAGCTATTCTTCAATGATAATAAATTCTCCTCTGTGTTCTTAGACAGACACTCGGTAGCAACGGTGCTATGCCT >520999_BRCA1_46 CTCTTCATCCTCACTAGATAAGTTCTCTTCTGAGGACTCTAATTTCTTGGCCCCTCTTCGGTAACCCTGAGCCAAATGTGTATGGGTGAAAGGGCTAGG >520999_BRCA1_48 AAACTAGTATCTTCCTTTATTTCACCATCATCTAACAGGTCATCAGGTGTCTCAGAACAAACCTGAGATGCATGACTACTTCCCATAGGCTGTTCTAAGTTATTCTGAAATCAGATA >520999_BRCA1_50 AAGACTTTGTTTATAGACCTCAGGTTGCAAAACCCCTAATCTAAGCATAGCATTCAATTTTGGCCCTTCTGTTTCTACCTAGTTCTGCTTGAATGTTTTCA >520999_BRCA1_52 AACCTACTTCATTAATATTGCTTGAGCTGGCTTCTTTAAAAAACATTTTCTCTAATGTTATTACGGCTAATTGTGCTCACTGTACTTGGAATGTTCTCATT >520999_BRCA1_54 ATTTTTCTTACATTTAGTTTTAACAAATGACTTGATGGGAAAAAGTGTGGTATACGATATGGGTTTTGTAAAAGTCCATGTTTATTTGGAGTAATGAGT >520999_BRCA1_56 TCCTTTGATACTACATTTGGCATTATCAACTGGCTTATCTTTCTGACCAACCACAGGAAAGCCTGCAGTGATATTAACTGTCTGTACAGGCTTGATATTA >520999_BRCA1_58 TTTGTTTCTTTAAGGACCCAGAGTGGGCAGAGAATGTTGCACATTCCTCTTCTGCATTTCCTGGATTTGAAAACGGAGCAAATGACTGGGCGCTTTGAAA >520999_BRCA1_60 ACTGTGGTTAACTTCATGTCCCAATGGATACTTAAAGCCTTCTGTGTCATTTCTATTATCTTTGGAACAACCATGAATTAGTCCCTTGGGGTTTTTCAAA >520999_BRCA1_62 AACGAGATACTTTCCTGAGTGCCATAATCAGTACCAGGTACCAATGAAATACTGCTACTCTCTACAGATCTTTCAGTTTGCAAAACCCTTTCTCCACTTAA >520999_BRCA1_64 TCTTTTTCTTCTCTTGGAAGGCTAGGATTGACAAATTCTTTAAGTTCACTGGTATTTGAACACTTAGTAAAAGAACCAGGTGCATTTGTTAACTTCAGCTCTGGGAAAGTATCGCTGTCAT >520999_BRCA1_66 TCTTTACCTTCCATGAGTTGTAGGTTTCTGCTGTGCCTGACTGGCATTTGGTTGTACTTTTTTTTCTTTATCTCTTCACTGCTAGAACAACTATCAATTT >520999_BRCA1_68 TGGTAGAAGACTTCCTCCTCAGCCTATTCTTTTTAGGTGCTTTTGAATTGTGGATATTTAATTCGAGTTCCATATTGCTTATACTGCTGCTTATA >520999_BRCA1_70 TTTTGTTTTATTCTCATGACCACTATTAGTAATATTCATCACTTGACCATTCTGCTCCGTTTTGGTTAGTTCCCTGATTTATCATTTCAGGAGTCTTTTGA >520999_BRCA1_72 TGTAGGTCTCCTTTTACGCTTTAATTTATTTGTGAGGGGACGCTCTTGTATTATCTGTGGCTCAGTAACAAATGCTCCTATAATTAGATTTTCAGTTACA >520999_BRCA1_74 TTCAATATTACTCTCTACTGATTTGGAGTGAACTCTTTCACTTTTACATATTAAAGCCTCATGAGGATCACTGGCCAGTAAGTCTATTTTCTCTGAAGAA >520999_BRCA1_76 ATTTGATTCAGACTCCCCATCATGTGAGTCATCAGAACCTAACAGTTCATCACTTCTGGAAAACCACTCATTAACTTTCTGAATGCTGCTATTTAGTGTTAT >520999_BRCA1_78 GGATCAGCATTCAGATCTACCTTTTTTTCTGTGCTGGGAGTCCGCCTATCATTACATGTTTCCTTACTTCCAGCCCATCT >520999_BRCA1_80 GCTGTTTGCTTTTATTACAGAATTCAGCCTTTTCTACATTCATTCTGTCTTTAGTGAGTAATAAACTGCTGTTCTCATGCTGTAATGAGCTGGCATGAGT >520999_BRCA1_82 AATCATTATTACTGGGTTGATGATGTTCAGTATTTGTTACATCCGTCTCAGAAAATTCACAAGCAGCTGAAAATATACAAAAATAACAAGGTACTCAAAAACTGAATTGTCATTAAAAAAAT >520999_BRCA1_84 ATAATCTAATTACAGTACTGTATCTACCCACTCTCTTTTCAGTGCCTGTTAAGTTGGCAAACTTTGCCATTACCCTTTTTTGCAGAATCCAAACTGATTT >520999_BRCA1_86 TTTGACTCACCTGCAATAAGTTGCCTTATTAACGGTATCTTCAGAAGAATCAGATCCTAAAAAATTTCC >520999_BRCA1_88 TTTTGAGGTTGTATCCGCTGCTTTGTCCTCAGAGTTCTCACAGTTCCAAGGTTAGAGAGTTGGACACTGAGACTGGTTTCCTGCTAAACAGTATGGTAAA >520999_BRCA1_90 AAAAAAAAAAAAGAAAAAAAAAAGAAAAGAAGAAGAAGAAGAAGAAGAAAACAAATGGTTTTACCAAGGAAGGATTTTCGGGTTCACTCTGTAGAAGTCTTTTGGCACGGTTTCT >520999_BRCA1_92 TTCCTGAGTTTTCATGGACAGCACTTGAGTGTCATTCTTGGGATATTCAACACTTACACTCCAAACCTGTGTCAAGCTGAAAAGCACAAATGATTTTCAA >520999_BRCA1_94 TAGCATCATTACCAAATTATATACCTTTTGGTTATATCATTCTTACATAAAGGACACTGTGAAGGCCCTTTCTT >520999_BRCA1_96 TTATGAAGGACAAAAACAAAAGCTAATAATGGAGCCACATAACACATTCAAACTTACTTGCAAAATATGTGGTCACACTTTGTGGAGACAGGTTCCTTGA >520999_BRCA1_97 ACTTTGTGGAGACAGGTTCCTTGATCAACTCCAGACTAGCAGGGTAGGGGGGGAGAAAAAGAAAATAAATGAGGCTCAATAATTTATTTAAAAATAAAGCTATT >520999_BRCA1_98 TGACTTACCAGATGGGACACTCTAAGATTTTCTGCATAGCATTAATGACATTTTGTACTTCTTCAACGCGAAGAGCAGATAAAT >520999_BRCA1_99 AGCAGATAAATCCATTTCTTTCTGTTCCAATGAACTTTAACACATTAGAAAAACATATATATATATCTTTTTAAAAGGTTTAAAATGACAACTTCATTTTATCATTTTAAAATAAAGTAAATTTAA >520999_BRCA2_01 TCAGTCACATAATAAGGAATGCATCCCTGTGTAAGTGCATTTTGGTCTTCTGTTTTGCAGACTTATTTACCAAGCATTGGAGGAATATCGTAGGTAAAAA >520999_BRCA2_02 TAGGTAAAAATGCCTATTGGATCCAAAGAGAGGCCAACATTTTTTGAAATTTTTAAGACACGCTGCAACAAAGCAGGTATTGACAAATTTTATATAACTTTATAAATT >520999_BRCA2_03 ACAAATTTGTCTGTCACTGGTTAAAACTAAGGTGGGATTTTTTTTTTAAATAGATTTAGGACCAATAAGTCTTAATTGGTTTGAAGAACTTTCTTCAGAA >520999_BRCA2_04 TTTCTTCAGAAGCTCCACCCTATAATTCTGAACCTGCAGAAGAATCTGAACATAAAAACAACAATTACGAACCAAACCTATTTAAAACTCCACAAAGGAA >520999_BRCA2_05 CACAAAGGAAACCATCTTATAATCAGCTGGCTTCAACTCCAATAATATTCAAAGAGCAAGGGCTGACTCTGCCGCTGTACCAATCTCCTGTAAAAGAATT >520999_BRCA2_06 CGCTGTACCAATCTCCTGTAAAAGAATTAGATAAATTCAAATTAGACTTAGGTAAGTAATGCAATATGGTAGACTGGGGAGAACTACAAACTAGGAATTTA >520999_BRCA2_07 ATTATTGTACTGTTTCAGGAAGGAATGTTCCCAATAGTAGACATAAAAGTCTTCGCACAGTGAAAACTAAAATGGATCAAGCAGATGATGTTTCCTGTCCACTTCTAAATTCTT >520999_BRCA2_08 TTCTAAATTCTTGTCTTAGTGAAAGGTATGATGAAGCTATTATATTAAAATATTTAAATGAAACATTTTCCTACATATATTTGTTCTATAAAGATGAATCTGATTTTTATGCTAATATTTT >520999_BRCA2_09 TTTTATTTTAGTCCTGTTGTTCTACAATGTACACATGTAACACCACAAAGAGATAAGTCAGGTATGATTAAAAA >520999_BRCA2_10 ATGATTAAAAAACAATGCTTTTTATTCTTAGAATACTAGAAATGTTAATAAAAATAAAACTTAACAATTTTCCCCTTTTTTTTTACCCCCAGTGGTATGTGGGAGTTTTGTTTCAT >520999_BRCA2_100 TTTTGTCAAATTCAAGAATTGGAAAAAGAAGAGGAGAGCCCCTTATCTTAGTGGGTAAGTGTTCATTTTTA >520999_BRCA2_101 TTAAAAAACATATATGAAATATTTCTTTTTAGGAGAACCCTCAATCAAAAGAAACTTATTAAATGAATTTGACAGGATAATAGAAAATCAAGAAAAATC >520999_BRCA2_102 ATAATAGAAAATCAAGAAAAATCCTTAAAGGCTTCAAAAAGCACTCCAGATGGTAAAATTAGCTTTTTATTTATAT >520999_BRCA2_103 TGGATATTCTCTTAGATTTTAACTAATATGTAATATAAAATAATTGTTTCCTAGGCACAATAAAAGATCGAAGATTGTTTAT >520999_BRCA2_104 AATAAAAGATCGAAGATTGTTTTATGCATCATGTTTCTTTAGAGCCGATTACCTGTGTACCCTTTCGGTAAGACATGTTTAAATTTTT >520999_BRCA2_105 AGGCATATTCCTAAATATTTATATGTGTACTAGTCAATAAACTTATATATTTTCTCCCCATTGCAGCACAACTAAGGAACGTCAAGAGATACAGAATCCAAATTTTAC >520999_BRCA2_106 AAATTTTACCGCACCTGGTCAAGAATTTCTGTCTAAATCTCATTTGTATGAACATCTGACTTTGGAAAAATCTTCAAGCAATTTA >520999_BRCA2_107 AAAAATCTTCAAGCAATTTAGCAGTTTCAGGACATCCATTTTATCAAGTTTCTGCTACAAGAAATGAAAAAATGAGACACTTGATTA >520999_BRCA2_108 TTGATTACTACAGGCAGACCAACCAAAGTCTTTGTTCCACCTTTTAAAACTAAATCACATTTTCACAGAGTTGAACAGTGTGTTAGGAATATTAACTTGGAGGAAAACAGACAAAA >520999_BRCA2_109 TAACTTGGAGGAAAACAGACAAAAGCAAAACATTGATGGACATGGCTCTGATGATAGTAAAAATAAGATTAATGACAATGAGATTCATCAGTTTAACAAAAA >520999_BRCA2_11 TGTTTCATACACCAAAGTTTGTGAAGGTAAATATTCTACCTGGTTTATTTTTATGACTTAGTAATTGAGAATTTGACAATAGCGTTATACCTTTG >520999_BRCA2_110 ATTCATCAGTTTAACAAAAACAACTCCAATCAAGCAGTAGCTGTAACTTTCACAAAGTGTGAAGAAGAACCTTTAGGTATTGTATGACAATTTGTGTGATGAATTTTT >520999_BRCA2_111 TATTTATTCTTTGATAGATTTAATTACAAGTCTTCAGAATGCCAGAGATATACAGGATATGCGAATTAAGAAGAAACAAAGGCAACG >520999_BRCA2_112 ATATACAGGATATGCGAATTAAGAAGAAACAAAGGCAACGCGTCTTTCCACAGCCAGGCAGTCTGTATCTTGC >520999_BRCA2_113 ACAGCCAGGCAGTCTGTATCTTGCAAAAACATCCACTCTGCCTCGAATCTCTCTGAAAGCAGCAGTAGGAGGCCAAGTTCCCTCTGCGTGTTCTCATAAA >520999_BRCA2_114 CTCATAAACAGGTATGTGTTTGTCTACAATACTGATGGCTTTTATGACAGAGTGTAATTTTATTTCATTAACTAGTATCT >520999_BRCA2_115 GATACATGTTTACTTTAAATTGTTTTTCTTTTTTGTGTGTGTTTATTTTGTGTAGCTGTATACGTATGGCGTTTCTAAACA >520999_BRCA2_116 TTTCTAAACATTGCATAAAAATTAACAGCAAAAATGCAGAGTCTTTTCAGTTTCACACTGAAGATTATTTTGGTAAGGAAAGTTTATGGACTGGAAAAGG >520999_BRCA2_117 AAAAGGAATACAGTTGGCTGATGGTGGATGGCTCATACCCTCCAATGATGGAAAGGCTGGAAAAGAAGAATTTTATAGGTACTCTATGCAAAAAGATTGT >520999_BRCA2_118 TTTTTATGATAATATTCTACTTTTATTTGTTCAGGGCTCTGTGTGACACTCCAGGGTGTGGATCCAAAGCTTATTTCTAGAATTTGGGTTTAATAAT >520999_BRCA2_119 AGGTGTGGATCCAAAGCTTATTTCTAGAATTTGGGTTTAATCACTATAGATGGATCATATGGAAACTGGCAGCTATGGAATGTGCCTTTCCTAA >520999_BRCA2_12 AAAAAATAATATCCTTAATGATCAGGGCATTTCTATAAAAAATAAACTATTTTCTTTCCTCCCAGGGTCGTCAGACACCAAAACATATTTCTGAAA >520999_BRCA2_120 TATGGAATGTGCCTTTCCTAAGGAATTTGCTAATAGATGCCTAAGCCCAGAAAGGGTGCTTTCTTCAACTAAAATACAGGCA >520999_BRCA2_121 AAGGTGCTTCTTCAACTAAAATACAGGCAAGTTTAAAGCATTACATTACGTAATCATATACGGCAGTATGGTTAAGGTTTCTGTGTAGTCTGTGACTT >520999_BRCA2_122 TAAACAGTGGAATTCTAGAGTCACACTTCCTAAAATATGCATTTTTGTTTTCACTTTTAGATATGATACGGAAATTGATA >520999_BRCA2_123 AAATTGATAGAAGCAGAAGATCGGCTATAAAAAAAGATAATGGAAAGGGATGACACAGCTGCAAAAACACTTGTTCTCTGTGTTTCTGACATAATTTCATT >520999_BRCA2_124 TTGTTCTCTGTGTTTCTGACATAATTTCATTGAGCGCAAATATATCTGAAACTTCTAGCAATAAAACTAGTAGTGCAGATACCCAAAAAGTGGCCATTATT >520999_BRCA2_125 AAAAGTGGCCATTATTGAACTTACAGATGGGGTGGTATGCTGTTAAGGCCCAGTTAGATCCTCCCCTCTTAGCTGTCTTAAAGAATGGCAGACTGACAGTT >520999_BRCA2_126 TAGCTGTCTTAAAGAATGGCAGACTGACAGTTGGTCAGAAGATTATTCTTCATGGAGCAGAACTGGTGGGCTCTCCTGATGCCTGTACACCTCTTGAA >520999_BRCA2_127 ACCTCTTGAAGCCCCAGAATCTCTTATGTTAAAGGTAAATTAATTTGCACTCTTGGTAAAAATCAGTCATTGATTCAGTTAAATTCTAGAAGTTTTACAT >520999_BRCA2_128 TAATAGAATTGAATACATATTTAACTACTAAATCAATATATTTATTAATTTGTCCAGATTTCTGCTAACAGTACTCGGCCTG >520999_BRCA2_129 GGCCTGCTCGCTGGTATACCAAACTTGGATTCTTTCCTGACCCTAGACCTTTTCCTCTGCCCTTATCATCGCTTTTCAGTGATGGAGGAAATGTTGGTTGTGTTGATGTAATTATTCAAA >520999_BRCA2_13 TCAGACACCAAAACATATTTCTGAAAGTCTAGGAGCTGAGGTGGATCCTGATATGTCTTGGTCAAGTTCTTTAGCTACACCACCCA >520999_BRCA2_130 GAAATGTTGGTTGTGTGATGTAATTATTCAAAGAGCATACCCTATACAGGTATGATGTATTCTTGAAACTTACCATATATTTCTTTCTTTTGATACAATTAATTTGTTT >520999_BRCA2_131 ATTATTACAGTGGATGGAGAAGACATCATCTGGATTATACATATTTCGCAATGAAAGAGAGGAAGAAAAGGAAGCAGCAAAATATGTGGAGGCCCAACAAAAGAGACTA >520999_BRCA2_132 AAAATATGTGGAGGCCCAACAAAAGAGACTAGAAGCCTTATTCACTAAAATTCAGGAGGAATTTGAAGAACATGAAGGTAAAATTAGTTATAT >520999_BRCA2_133 TTCTTTAGTTTTAGTTGCTTTTGAATTTACAGTTTAGTGAATTAATAATCCTTTTGTTTTTCTTAGAAAACACAACAAAACCATATTTACCATCACGTGCA >520999_BRCA2_134 ACGTGCACTAACAAGACAGCAAGTTCGTGCTTTGCAAGATGGTGCAGAGCTTTATGAAGCAGTGAAGAATGCAGCAGACCCAGCTTACCTTGAGGTGAGA >520999_BRCA2_135 CAGAGCTTTATGAAGCAGTGAAGAATGCAGCAGACCCAGCTTACCTTGAGGTGAGAGAGTAAGAGGACATATAATGAGGCCTTGATGATTATTCAAGGTGA >520999_BRCA2_136 TTTTTATTCCAATATCTTAAATGGTCACAGGGTTATTTCAGGTGAAGAGCAGTTAAGAGCCTTGAATAATCACA >520999_BRCA2_137 AGTTAAGAGCCTTGAATAATCACAGGCAAATGTTGAATGATAAGAAACAAGCTCAGATCCAGTTGGAAATTAGGAAGGCCATGGAATCTGCTGAACAAAA >520999_BRCA2_138 GCCATGGAATCTGCTGAACAAAAGGAACAAGGTTTTATCAAGGGAATGTCACAACCGTGTGGAAGTTGCGTATTGTAAGCTATTCAAAAAAAGAAAAAGATT >520999_BRCA2_139 GTGGAAGTTGCGTATTGTAAGCTATTCAAAAAAAGAAAAAGATTCAGGTAAGTATGTAAATGCTTTGTTTTTTATCAGTTTTATTAACTTAAAA >520999_BRCA2_14 CTTGGTCAAGTTCTTTAGCTACACCACCCACCCTTAGTTCTACTGTGCTCATAGGTAATAATAGCAAATGTGTATTTACAAGAAA >520999_BRCA2_140 TTAAATGATAATCACTTCTTCCATTGCATCTTTCTCATCTTTCTCCAAACAGTTATACTGAGTATTTGGCGTCCATCATCAGATTTATATTCTCTGTTAA >520999_BRCA2_141 TTAACAGAAGGAAAGAGATACAGAATTTATCATCTTGCAACTTCAAAATCTAAAAGTAAATCTGAAAGAGCTAACATACAGTTAGCAGCGACAAAAAAAA >520999_BRCA2_142 AGCGACAAAAAAAACTCAGTATCAACAACTACCGGTACAAACCTTTCATTGTAATTTTTCAGTTTTGATAAGTGCTTGTTAGTTTATGGAATCTCCATAT >520999_BRCA2_143 AATCTCCATATGTTGAATTTTTGTTTTGTTTTCTGTAGGTTTCAGATGAAATTTTATTTCAGATTTACCAGCCACGGGAGCCCCTTCACTTCAGCAAATT >520999_BRCA2_144 GAGCCCCTTCACTTCAGCAAATTTTTAGATCCAGACTTTCAGCCATCTTGTTCTGAGGTGGACCTAATAGGATTTGTCGTTT >520999_BRCA2_145 TAGGATTTGTCGTTTCTGTTGTGAAAAAAACAGGTAATGCACAATATAGTTAATTTTTTTTATTGATTCTTTTTAAAAAACATTGTCTTTTAAAATCTCTTA >520999_BRCA2_146 TTAAAATTCATCTAACACATCTATAATAACATTCTTTTCTTTTTTTTCCATTCTAGGACTTGCCCCTTTCGTCTATTTGTCAGACGAATGTTACAATTT >520999_BRCA2_147 TATTTGTCAGACGAATGTTACAATTTACTGGCAATAAAGTTTTGGATAGACCTTAATGAGGACATTATTAAGCCTCATATGTTAATTGCTGCAAGCAACC >520999_BRCA2_148 TATGTTAATTGCTGCAAGCAACCTCCAGTGGCGACCAGAATCCAAATCAGGCCTTCTTACTTTATTTGCTGGAGATTTTTCTGTGTTTTCTGCTAGTCCA >520999_BRCA2_149 AGATTTTTCTGTGTTTTCTGCTAGTCCAAAAGAGGGCCACTTTCAAGAGAGACATTCAACAAAAATGAAAAATACTGTTGAGGTAAGGTTACTTTT >520999_BRCA2_15 TTTTTGATGTCTGACAAAAAATAAGTTTTTGCATTCTAGTGATAATATACAATACACATAAATTTTTATCTTACAGTCAGAAATGAAGAAGCATCTGAAACTGTATTT >520999_BRCA2_150 AAATACTTTTGGAAACATAAATATGTGGGTTTGCAATTTATAAAGCAGCTTTTCCACTTATTTTCTTAGAATATTGACATACTTTGCAATGAAGCAGAAA >520999_BRCA2_151 AGAAAACAAGCTTATGCATATACTGCATGCAAATGATCCCAAGTGGTCCACCCCAACTAAAGACTGTACTTCAGGGCCGTACACTGCTCAAATCATTCCT >520999_BRCA2_152 TCAGGGCCGTACACTGCTCAAATCATTCCTGGTACAGGAAACAAGCTTCTGGTAAGTTAATGTAAACTCAAGGAATATTATAAGAAGTATATATGGA >520999_BRCA2_153 TGATTTAGTTTTTTATGTTACTACATAATTATGATAGGCTACGTTTTCATTTTTTTATCAGATGTCTTCTCCTAATTGTGAGATATATTATCAAAGTCCTTTATCACTTTGTATGGCCA >520999_BRCA2_154 TTTATCACTTTGTATGGCCAAAAGGAAGTCTGTTTCCACACCTGTCTCAGCCCAGATGACTTCAAAGTCTTGTAAAGGGGAGAAAGAGATTGATGACCAA >520999_BRCA2_155 TGTAAAGGGGAGAAAGAGATTGATGACCAAAGAACTGCAAAAAGAGAAGAGCCTTGGATTTCTTGAGTAGACTGCCTTTACCTCCACCTGTTAGTCCCAT >520999_BRCA2_156 CCTGTTAGTCCCATTTGTACATTTGTTTTCTCCGGCTGCACAGAAGGCATTTCAGCCACCAAGGAGTTGTGGCACCAAATACGAAACACCCATAAAGAAAAA >520999_BRCA2_157 GCACCAAATACGAAACACCCATAAAGAAAAAAGAACTGAATTCTCCTCAGATGACTCCATTTAAAAAATTCAATGAAATTTCTCTTTTGGAAAGTAATT >520999_BRCA2_158 TCTCTTTTGGAAAGTAATTCAATAGCTGACGAAGAACTTGCATTGATAAATACCCAAGCTCTTTTGTCTGGTTCAACAGGAGAAAAACAATTTATATCTG >520999_BRCA2_159 AGAAAAACAATTTATATCTGTCAGTGAATCCACTAGGACTGCTCCCACCAGTTCAGAAGATTATCTCAGACTGAAACGACGTTGTACTACATCTCTGATC >520999_BRCA2_16 AAACTGTATTTCCTCATGATACTACTGCTGTAAGTAAATATGACATTGATTAGACTGTTGAAATTGCTAACAATTTTGGAATGCCTTGTTAAATTATTTATCTTACATTTTTAATTT >520999_BRCA2_160 TCTGATCAAAGAACAGGAGAGTTCCCAGGCCAGTACGGAAGAATGTGAGAAAAATAAGCAGGACACAATTACAACTAAAAAATATATCTAAGCATTTGCAAAGGCGACAATAAATTATT >520999_BRCA2_161 ACACAATTACAACTAAAAAATATATCTAAGCATTTGCAAAGGCGACAATAAATTATTGACGCTTAACCTTTCCAGTTTATAAGACTGGAATATAATTTCAA >520999_BRCA2_17 TTTTATACTAGTGATTTTAAAACTATAATTTTTGCAGAATGTGAAAAGCTATTTTTCCAATCATGATGAAAGTCTGAAGAAAAAATGATAGATTTA >520999_BRCA2_18 AAAAATGATAGATTTATCGCTTCTGTGACAGACAGTGAAAACACAAATCAAAGAGAAGCTGCAAGTCATGGTAA >520999_BRCA2_19 ATGGTAAGTCCTCTGTTTAGTTGAACTACAGGGTTTTTTTGTTGTTGTTGTTTTGATTTTTTTTTTTTGAGGTGGAGTCTTGCT >520999_BRCA2_20 AATAATATAAATTATATGGCTTATAAAATATTAATGTGCTTCTGTTTTATACTTTAACAGGATTTGGAAAAACATCAGGGAATTCATTTAAAGTAAATA >520999_BRCA2_21 ATTTAAAGTAAATAGCTGCAAAGACCACATTGGAAAGTCAATGCCAAATGTCCTAGAAGATGAAGTATATGAAA >520999_BRCA2_22 TATATGAAACAGTTGTAGATACCTCTGAAGAAGATAGTTTTTCATTATGTTTTTCTAAATGTAGAACAAAAAATCTACAAAAAGTAAGAACTAGCAAGACTAGGAAAAAAATTTTCCATGAAGCAAA >520999_BRCA2_23 AAAAAAATTTTCCATGAAGCAAACGCTGATGAATGTGAAAAATCTAAAAAACCAAGTGAAAGAAAAATACTCATTTGTATCTGAAGTGGAACCAAATGATACTGATCCATTAGATTCAAATGTAGCAAAT >520999_BRCA2_24 ATTAGATTCAAATGTAGCAAATCAGAAGCCCTTTGAGAGTGGAAGTGACAAAATCTCCAAGGAAGTTGTACCGTCTTTGGC >520999_BRCA2_25 TGGAAGTGACAAAATCTCCAAGGAAGTTGTACCGTCTTTGGCCTGTGAATGGTCTCAACTAACCCTTTCAGGTCTAAATGGAGCCCAGATGGAGAAAATA >520999_BRCA2_26 TAAATGGAGCCCAGATGGAGAAAATACCCCTATTGCATATTTCTTCATGTGACCAAAATATTTCAGAAAAA >520999_BRCA2_27 AAAATATTTCAGAAAAGACCTATTAGACACAGAGAACAAAAGAAAGAAAGATTTTCTTACTTCAGAGAATTCTTTGCCACGTATTTCTAGCCTACCAAAATCAG >520999_BRCA2_28 TACCAAAATCAGAGAAGCCATTAAATGAGGAAACAGTGGTAAATAAGAGAGATGAAGAGCAGCATCTTGAATCTCATACAGACTGCATTCTTGCAGTAAA >520999_BRCA2_29 CTCATACAGACTGCATTCTTGCAGTAAAGCAGGCAATATCTGGAACTTCTCCAGTGGCTTCTTCATTTCAGGGTATCAAAAAGTCTATATTCAGAATAA >520999_BRCA2_30 ATTTCAGGGTATCAAAAGTCTATATTCAGAATAAGAGAATCACCTAAAGAGACTTTCAATGCAAGTTTTTCAGGTCATATGACTGATCCAAACTTTAAAAAA >520999_BRCA2_31 ATATGACTGATCCAAACTTTAAAAAAGAAACTGAAGCCTCTGAAAGTGGACTGGAAATACATACTGTTGCTCACAGAAGGAGGACTCCTTATGTCCAAAT >520999_BRCA2_32 ACTCCTTATGTCCAAATTTAATTGATAATGGAAGCTGGCCAGCCACCACCACACAGAATTCTGTAGCTTTGAAGAATGCAG >520999_BRCA2_33 AGAATTCTGTAGCTTTGAAGAATGCAGGTTTAATATCCACTTTGAAAAAGAAAACAAATAAGTTTATTTATGCTATACATGATGAAACATCTTATAAAGGAAAAAAAATA >520999_BRCA2_34 TTTGAAAAGAAAACAAATAAGTTTATTTATGCTATACATGATGAAACATCTTATAAAGGAAAAAAAAATACCGAAAGACCAAAAATCAGAACTAATTAA >520999_BRCA2_35 AAAAATCAGAACTAATTAACTGTTCAGCCCAGTTTGAAGCAAATGCTTTTGAAGCACCACTTACATTTGCAAATGCTGATTCAGGTACCTCTGTCTTTTTTTTTTTGTAAATA >520999_BRCA2_36 TTTTTATGTTTAGGTTTATTGCATTCTTCTGTGAAAAGAAGCTGTTCACAGAATGATTCTGAAGAACCAACTTTGTCCTTAACTAGCTCTTTT

>520999_BRCA2_37 TTAACTAGCTCTTTTTGGGACAATTCTGAGGAAATGTTCTAGAAATGAAACATGTTCTAATAATACAGTAAT >520999_BRCA2_38 TAATAATACAGTAATCTCTCAGGATCTTGATTATAAAGAAGCAAAATGTAATAAGGAAAAACTACAGTTATTTATTACCCCAGAAGCTGATTCTCTGTCATGCCTGCAGGAA >520999_BRCA2_39 CCTGCAGGAAGGACAGTGTGAAAATGATCCAAAAAGCAAAAAAGTTTCAGATATAAAAGAAGAGGTCTTGGCTGCAGCATGTCACCCAGTACAACATTCAAAAGT >520999_BRCA2_40 ATTCAAAAGTGGAATACAGTGATACTGACTTTCAATCCCAGAAAAGTCTTTTATATGATCATGAAAATGCCAGCACTCTTATTTTAACTCCTACTT >520999_BRCA2_41 TTATTTTAACTCCTACTTCCAAGGATGTTCTGTCAAACCTAGTCATGATTTCTAGAGGCAAAAGAATCATACAAAAT >520999_BRCA2_42 AATCATACAAAATGTCAGACAAGCTCAAAGGTAACAATTATGAATCTGATGTTGAATTAACCAAAAATATT >520999_BRCA2_43 AATTATGAATCTGATGTTGAATTAACCAAAAATATTCCCATGGAAAAGAATCAAGATGTATGTGCTTTAAATGAAAATTATAAAAA >520999_BRCA2_44 TTTAAATGAAAATTATAAAAACGTTGAGCTGTTGCCACCTGAAAAATACATGAGAGTAGCATCACCTTCAAGAAA >520999_BRCA2_45 TTCAAGAAAGGTACAATTCAACCAAAACACAAATCTAAGAGTAATCCAAAAAAATCAAGAAGAAAACTACTTCAATTTCAAAAATAA >520999_BRCA2_46 AAAAAAATCAAGAAGAAAACTACTTCAATTTCAAAAATAACTGTCAATCCAGACTCTGAAGAACTTTTCTCAGACAATGAGAATAATTTTGTCTT >520999_BRCA2_47 AATAATTTTGTCTTCCAAGTAGCTAATGAAAGGAATAATCTTTGCTTTAGGAAATACTAAGGAACTTCATGAAACAGACTTGACTTGTGTAAA >520999_BRCA2_48 TTGTGTAAACGAACCCATTTTCAAGAACTCTACCATGGTTTTATATGGAGACACAGGTGATAAACAAGCAACCCAAGTGTCAATTAAAAAA >520999_BRCA2_49 CAAGTGTCAATTAAAAAAGATTTGGTTTATGTTCTTGCAGAGGAGAACAAAAATAGTGTAAAGCAGCATATAAAAATGACTCTAGGTCAAGATTTAAAAT >520999_BRCA2_50 ATTTAAAATCGGACATCTCCTTGAATATAGATAAAATACCAGAAAAAAATAATGATTACATGAACAAATGGGCAGGACTCTTAGGTCCAATTTCAAATCACAGTTTTGGAGGTA >520999_BRCA2_51 AATTTCAAATCACAGTTTTGGAGGTAGCTTCAGAACAGCTTCAAATAAGGAAATCAAGCTCTCTGAACATAACATTAAGAAGAGCAAAATGTTCTTCAAAGATATT >520999_BRCA2_52 AAATGTTCTTCAAAGATATTGAAGAACAATATCCTACTAGTTTAGCTTGTGTTGAAATTGTAAATACCTTGGCATTAGATAATCAAAAGAAACTGAGCAAGCCTCAGTCAATTAATA >520999_BRCA2_53 TCAATTAATACTGTATCTGCACATTTACAGAGTAGTGTAGTTGTTTCTGATTGTAAAAATAGTCATATAACCCCTCAGATGTTATTTTCCAAGCAGGATTTTAATTCAAACCATAATTTAA >520999_BRCA2_54 ATTTTAATTCAAACCATAATTTAACACCTAGCCAAAAGGCAGAAATTACAGAACTTTCTACTATATTAGAAGAATCAGGAAGTCAGTTTGAATTTACTCAGTTTAGAAAA >520999_BRCA2_55 TTTGAATTTACTCAGTTTAGAAAACCAAGCTACATATTGCAGAAGAGTACATTTGAAGTGCCTGAAAACCAGATGACTATCTTAAAGACCACTTCTGA >520999_BRCA2_56 ACTTCTGAGGAATGCAGAGATGCTGATCTTCATGTCATAATGAATGCCCCATCGATTGGTCAGGTAGACAGCAGCAAGCAATTTGAAGGTACAGTTGAAATTAAA >520999_BRCA2_57 AGCAAGCAATTTGAAGGTACAGTTGAAATTAAACGGAAGTTTGCTGGCCTGTTGAAAAATGACTGTAACAAAAGTGCTTCTGGTTATTTAACAGATGAAAATGAAGTGGGGTTTAGGGGCTTTTATT >520999_BRCA2_58 GGCTTTTATTCTGCTCATGGCACAAAAACTGAATGTTTCTACTGAAGCTTCTGCAAAAAGCTGTGAAACTGTTTAGTGATATTGAGAATATTA >520999_BRCA2_59 AAAAAGCTGTGAAACTGTTTAGTGATATTGAGAATATTAGTGAGGAAACTTCTGCAGAGGTACATCCAATAAGTTTATCTTCAAGTAAATGTCATGATTCTGTT >520999_BRCA2_60 AATAAGTTTATCTTCAAGTAAATGTCATGATTCTGTTGTTTCAATGTTTAAGATAGAAAATCATAATGATAAAACTGTAAGTGAAAAAAATAATAAAT >520999_BRCA2_61 TTGTTTCAATGTTTAAGATAGAAAATCATAATGATAAAACTGTAAGTGAAAAAAATAATAAAATGCCAACTGATATTACAAAATAATATTGAAAT >520999_BRCA2_62 AAAAAAATAATAAAATGCCAACTGATATTACAAAATAATATTGAAATGACTACTGGCACTTTTGTTGAAGAAAATTACTGAAAATTACAAGAGAAATACTGAAAATGAAGATAAAAATATA >520999_BRCA2_63 AAATTACTGAAAATTACAAGAGAAATACTGAAAATGAAGATAACAAATATACTGCTGCCAGTAGAAATTCTCATAACTTAGAATTTGATGGCAGTGATTCAAGTAAAAAATGATACT >520999_BRCA2_64 ATTCAAGTAAAAAATGATACTGTTTGTATTCATAAAGATGAAACGGACTTGCTATTTACTGATCAGCACAACATATGTCTTAAATTATCTGGCCAGTTTATGAA >520999_BRCA2_65 TTAAATTATCTGGCCAGTTTATGAAGGAGGGAAACACTCAGATTAAAGAAGATTTGTCAGATTTAACTTTTTTGGAAGTTG >520999_BRCA2_66 ATTTAACTTTTTTGGAAGTTGCGAAAGCTCAAGAAGCATGTCATGGTAATACTTCAAATAAAGAACAGTTAACTGCTACTAAAACGGAGCAAAATATAAAAGATTTT >520999_BRCA2_67 AAAATATAAAAGATTTTGAGACTTCTGATACATTTTTTCAGACTGCAAGTGGGAAAAATATTAGTGTCGCCAAAGAGTCATTTAATAAAATTGTAAATTTCTTT >520999_BRCA2_68 ATTTAATAAAATTGTAAATTTCTTTGATCAGAAACCAGAAGAATTGCATAACTTTTCCTTAAATTCTGAATTACATTCTGACATAAGAAAGAACAAAAT >520999_BRCA2_69 TTAAATTCTGAATTACATTCTGACATAAGAAAGAACAAAATGGACATTCTAAGTTATGAGGAAACAGACATAGTTAAACACAAAATACTGAAAGAAA >520999_BRCA2_70 TTAAACACAAAATACTGAAAGAAAGTGTCCCAGTTGGTACTGGAAATCAACTAGTGACCTTCCAGGGACAACCCGAACGTGATGAAAAGATCAAAGAACCTACTCTATTG >520999_BRCA2_71 AAAAGATCAAAGAACCTACTCTATTGGGTTTTCATACAGCTAGCGGGAAAAAAAGTTAAAATTGCAAAGGAATCTTTGGACAAAGTGAAAAACCTTTTTGATGAAAAA >520999_BRCA2_72 AAAAACCTTTTTGATGAAAAAGAGCAAGGTACTAGTGAAATCACCAGTTTTAGCCATCAATGGGGCAAAGACCCTAAAGTACAGAGAGGCCTGTAAAGACCTTGAATTA >520999_BRCA2_73 TAAAGACCTTGAATTAGCATGTGAGACCATTGAGATCACAGCTGCCCCAAAGTGTAAAGAAATGCAGAATTCTCTCAATAATGATAAAAACCTTGTTTCTATT >520999_BRCA2_74 AATAATGATAAAAACCTTGTTTCTATTGAGACTGTGGTGCCACCTAAGCTCTTAAGTGATAATTTATGTAGACAAACTGAAAATCTCAAAACATCAAAAAGTATCTTTTTGAAAGTTAAA >520999_BRCA2_75 ATAATTTATGTAGACAAACTGAAAATCTCAAAACATCAAAAAGTATCTTTTTGAAAGTTAAAGTACATGAAAATGTAGAAAAAGAAACAGCAAAAAGTCCTGCAACTT >520999_BRCA2_76 AAAAAGTCCTGCAACTTGTTACACAAATCAGTCCCCTTATTCAGTCATTGAAAATTCAGCCTTAGCTTTTTACACAAGTTGTAGTAGAAAAA >520999_BRCA2_77 TTTTTACACAAGTTGTAGTAGAAAAACTTCTGTGAGTCAGACTTCATTACTTGAAGCAAAAAAATGGCTTAGAGAAGGAATATTT >520999_BRCA2_78 AAAAAATGGCTTAGAGAAGGAATATTTGATGGTCAACCAGAAAGAATAAATACTGCAGATTATGTAGGAAAATTATTTGTATGAAAATAATTCAAA >520999_BRCA2_79 AAATTATTTGTATGAAAATAATTCAAACAGTACTATAGCTGAAAATGACAAAAATCATCTCTCCGAAAAACAAGATACTTATTTAAGTAACAGTAGCATGTCTAACA >520999_BRCA2_80 ATGTCTAACAGCTATTCCTACCATTCTGATGAGGTATATAATGATTCAGGATATCTCTCAAAAAATAAACTTGATTCTGGTATT >520999_BRCA2_81 AAAAAATAAACTTGATTCTGGTATTGAGCCAGTATTGAAGAATGTTGAAGATCAAAAAAACACTAGTTTTTCCAAAGTAATATCCAATGTAAAA >520999_BRCA2_82 AAAAAAACACTAGTTTTTCCAAAGTAATATCCAATGTAAAAGAATGCAAATGCATACCCACAAACTGTAAATGAAGATATTTGCGTTGA >520999_BRCA2_83 TAAATGAAGATATTTGCGTTGAGGAACTTGTGACTAGCTCTTCACCCTGCAAAAATAAAAATGCAGCCATTAAATTGTCCATATCTAATAGTAATAATTTTGAGGTAGGGCCA >520999_BRCA2_84 AAAAATAAAAATGCAGCCATTAAATTGTCCATATCTAATAGTAATAATTTTGAGGTAGGGCCACCTGCATTTAGGATAGCCAGTGGTAAAATCGTTT >520999_BRCA2_85 TAAAATCGTTTGTGTTTCACATGAAACAATTAAAAAAGTGAAAGACATATTTACAGACAGTTTCAGTAAAGTAATTAAGGAAAACAACGAGAATAAAATCAAAATTT >520999_BRCA2_86 AATAAAATCAAAATTTGCCAAACGAAAATTATGGCAGGTTGTTACGAGGCATTGGATGATTCAGAGGATATTCTTCATAACTCTCTAGATAAT >520999_BRCA2_87 ATATTCTTCATAACTCTCTAGATAATGATGAATGTAGCACGCATTCACATAAGGTTTTTGCTGACATTCAGAGTGAAGAAATTTTACAACATAACCAAAATAT >520999_BRCA2_88 AAATTTTACAACATAACCAAAATATGTCTGGATTGGAGAAAGTTTCTAAAATATCACCTTGTGATGTTAGTTTGGAAACTTCAGATATATGTAAATGTAGTATA >520999_BRCA2_89 ATATATGTAAATGTAGTATAGGGAAGCTTCATAAGTCAGTCTCATCTGCAAATACTTGTGGGATTTTTAGCACAGCAAGTGGAAAATCTGTCCA >520999_BRCA2_90 AAAATCTGTCCAGGTATCAGATGCTTCATTACAAAACGCAAGACAAGTGTTTTCTGAAATAGAAGATAGTACCAAGCAAGTCTTTTCCAAAGTATTGTTTAAAAGTAAC >520999_BRCA2_91 TTTTCCAAAGTATTGTTTAAAAGTAACGAACATTCAGACCAGCTCACAAGAGAAGAAAATACTGCTATACGTACTCCAGAACATTTAATATCCCAAAAAGGCTTTTCATATAAT >520999_BRCA2_92 ATTTAATATCCCAAAAAGGCTTTTCATATAATGTGGTAAATTCATCTGCTTTCTCTGGATTTAGTACAGCAAGTGGAAAGCAAGTTTCCATTTTAGAAAGTT >520999_BRCA2_93 ATTTTAGAAAGTTCCTTACACAAAGTTAAGGGAGTGTTAGAGGAATTTGATTTAATCAGAACTGAGCATAGTCTTCACTATTCACCTACGTCTAGACAAAATGTATCAAAAATACTT >520999_BRCA2_94 AAATGTATCAAAAATACTTCCTCGTGTTGATAAGAGAAACCCAGAGCACTGTGTAAACTCAGAAATGGAAAAAACCTGCAGTAAAGAATTTAAATTATCAAATAACTTAAAT >520999_BRCA2_95 AAAAAACCTGCAGTAAAGAATTTAAATTATCAAATAACTTAAATGTTGAAGGTGGTTCTTCAGAAAATAATCACTCTATTAAAGTTTCTCCATATCTCTCTCAATTT >520999_BRCA2_96 TATTAAAGTTTCTCCATATCTCTCTCAATTTCAACAAGACAAACAACAGTTGGTATTAGGAACCAAAGTGTCACTTGTTGAGAACATTCATGTTTTGGGAAAA >520999_BRCA2_97 ATTCATGTTTTGGGAAAAGAACAGGCTTCACCTAAAAACGTAAAAATGGAAATTGGTAAAACTGAAACTTTTTCTGATGTTTCCTGTGAAAACAAATATAGAAGTTT >520999_BRCA2_98 AAAACAAATATAGAAGTTTGTTCTACTTACTCCAAAGATTCAGAAAACTACTTTGAAACAGAAGCAGTAGAAATTGCTAAAGCTTTTATGGAAGATGATGAACTGACAGATTCTAAA >520999_BRCA2_99 AGATTCTAAACTGCCAAGTCATGCCACACATTCTCTTTTTACATGTCCCGAAAATGAGGAAATGGTTTTGTCAAATTCAAGAATTGGAAAAAGAAGAGGAGAGCC >520999_CYP2D6_01 97 GCTGGGGACTAGGTACCCCATTCTAGCGGGGCACAGCACAAAGCTCATAGGGGGATGGGGTCACCAGGAAAGCAAAGACACCATGGTGGCTGGGCCGGGGCTGT >520999_CYP2D6_02 98 TGGCTGGGCCGGGGCTGTCCAGTGGGCACCGAGAAGCTGAAGTGCTGCAGCAGGGAGGTGAAGAAGAGGAAGAGCTCCATGCGGGCCAGGGGCTCCCCGAGGCATGCACGGGCGGCCTGTGGGGAGGGGAGGGGC >520999_CYP2D6_03 99 GAGCCGGGCTCCCCACAGGCACCTGCTGAGAAAGGCAGGAAGGCCTCCGGCTTCACAAAGTGGCCCTGGGCATCCAGGAAGTGTTCGGGGTGGAAGCGGAAGGGCTT >520999_CYP2D6_04 100 CGGAAGGGCTTCTCCCAGACGGCCTCATCCTTCAGCACCGATGACAGGTTGGTGATGAGTGTCGTTCCCTGGGCAGAAGATGCAGGGTGAGA >520999_CYP2D6_05 101 GGGTGAGGAGGGCGCCAGGCCTACCTTAGGGATGCGGAAGCCTGTACTTCGATGTCACGGGATGTCATATGGGTCACACCCAGGGGGACGATGTCCCCAAAGCGCTGCACCT >520999_CYP2D6_06 102 ATGTCCCCAAAGCGCTGCACCTCATGAATCACGGCAGTGGTGTAGGGCATGTGAGCCTGGTCACCCATCTCTGGTCGCCGCACCTGCCCTATCACGTCGTCGATCTCCTGTTGGACAC >520999_CYP2D6_07 103 GCATGTGAGCCTGGTCACCCATCTCTGGTCGCCGCACCTGCCCTATCACGTCGTCGATCTCCTGTTGGACACGGCCTGGACAGACATGCGTCCCCACAATGGGTCAGCACCCAGGGG >520999_CYP2D6_08 104 GCCCCCGCCTGTACCCTTCCTCCCTCGGCCCCTGCACTGTTTCCCAGATGGGGCTCACGCTGCACATCCGGATGTAGGATCATGAGCAGGAGGCCCCAGGCCAGCGT >520999_CYP2D6_09 105 TAGGATCATGAGCAGGAGGCCCCAGGCCAGCGTGGTCGAGGTGGTCACCATCCCGGCAGAGAACAGGTCAGCCACCACTATGCACAGGTTCTCATCATTGAAGCTGCTCTCAGG >520999_CYP2D6_10 106 CACCACTATGCACAGGTTCTCATCATTGAAGCTGCTCTCAGGGTTCCCCTTGGCCTGAGCAGGGCCGA >520999_CYP2D6_11 107 AACCCACCACCCTTGCCCCCCACCGTGGCAGCCACTCTCACCTTCTCCATCTCTGCCAGGAAGGCCTCAGTCAGGTCTCGGGGGGGCTGGGCTGGGTCCCA >520999_CYP2D6_12 108 CAGGAAGGCCTCAGTCAGGTCTCGGGGGGGCTGGGCTGGGTCCCAGGTCATCCTGTGCTCAGTTAGCAGCTCATCCAGCTGGGTCAGGAAAGCCTTTTGGAAGCGTAGGACCTTGCCAGCCAGCGCTGG >520999_CYP2D6_13 109 CAGCCAGCGCTGGGATATGCAGGAGGACGGGGACAGCATTCAGCACCTACACCAGACAGAACGGGGTCTCAATCCCTCCTGTGCTCTGCGTTCACCTG >520999_CYP2D6_14 110 TCCGCACCTCGCGCAGAAAGCCCGACTCCTCCTTCAGTCCCTCCTGAGCTAGGTCCAGCAGCCTGAGGAAGCGAGGGTCGTCGTACTCGAAGCGGCGCCCGCAGGTGAGGGAGGCGATCACGTTGCTCACGGCTTTGTCCAA >520999_CYP2D6_15 111 GGCGCCCGCAGGTGAGGGAGGCGATCACGTTGCTCACGGCTTTGTCCAAGAGACCGTTGGGGCGAAAGGGGCGTCCTGGGGGTGGGAGATGCGGGTAAGGG >520999_CYP2D6_16 112 CGTCCCCCGCCTTCCCAGTTCCCGCTTTGTGCCCTTCTGCCCATCACCCACCGGAGTGGTTGGCGAAGGCGGCACAAAAGGCAGGCGGCCTCCTCGGTCACCCA >520999_CYP2D6_17 113 GCGAAGGCGGCACAAAGGCAGGCGGCCTCCTCGGTCACCCACTGCTCCAGCGACTTCTTGCCCAGGCCCAAGTTGCGCAAGGTGGAGACGGAGAAGCGCCTCTGCTCGCGCCACGCGGGCCCATAGCG >520999_CYP2D6_18 114 AGACGGAGAAGCGCCTCTGCTCGCGCCACGCGGGCCCATAGCGCGCCAGGAACACCCCTGGGGGTGGGACGGGCACGTGCGCGTGGCCATGAAGG >520999_CYP2D6_19 115 TCCCCACCGCTGCTTGCCTTGGGAACGCGGCCCGAAACCCAGGATCTGGGTGATGGGCACAGGCGGGCGGTCGGCGGTGTCCTCGCCGTGGGTCACCAGCGCCTCGCGCACGGCCGC >520999_CYP2D6_20 116 GGCCCGAAACCCAGGATCTGGGTGATGGGCACAGGCGGGCGGTCGGCGGTGTCCTCGCCGTGGGTCACCAGCGCCTCGCGCACGGCCGCCAGCCCATTGAGCACGACCACCGGCGTCCAGGCCAG >520999_CYP2D6_21 117 CAGGCCAGCTGCAGGCTGAACACGTCCCCGAAGCGGCGCCGCAACTGCAGAGGGAGGGTCAGGGCCTCTTGTCAAGCCAGGATCC >520999_CYP2D6_22 118 CCACCACCCATGTTTGCTGGTGGTGGGGCATCCTCAGGACCTCTGCCGCCCTCCAGGACCTCCTCCCTCACCTGGTCGAAGCAGTATGGTGTGTT >520999_CYP2D6_23 119 AGTATGGTGTGTTCTGGAAGTCCACATGCAGCAGGTTGCCCAGCCCGGGCAGTGGCAGGGGGCCTGGTGGGTAGCGTGCAGCCCAGCGTTGGCCGCCGGTGCATCA >520999_CYP2D6_24 120 CCGGTGCATCAGGTCCACCAGGAGCAGGAAGATGGCCACTATCACGGCCAGGGGCACCAGTGCTTCTAGCCCCATACCTGCCTCACTAC >520999_DPYD_01 TTTAAATTTCACACATAGCAACAGAAAATGCTTTCTGCCGTAAAAACAAGAAGAAACATGTCTCATAGCATTCTAATTCCAGCAGGATTCTTACCTGGTAGCCAGAATCATTA >520999_DPYD_02 ATTCTTACCTGGTAGCCAGAATCATTACAGGTCATGTAGCATTTACCACAGTTGATACACATTTCTTCATCAATCATAGCCACAACTTGCTCTACGTTGCTCAATTC >520999_DPYD_03 TACGTTGCTCAATTCACCAAATGTTCCAAGGTACTGCAGTGCTTTTCCTATTACATCCTAAAAATA >520999_DPYD_04 TAAAAATAGCCACTGAATTACTTAGCAAGCTCATTTTAAAACATTTTCATGTAATAATTAATAT >520999_DPYD_05 AAGAATAACACAGGAGATTTAAGCACATACCTTGTCCATGAGTTCAGCTATACGTGGAACTGGTTTCCCTTT >520999_DPYD_06 GTTTCCCTTTCTGGTGACTCACAGTAGCTGGACTCTGTCCATCCCAGTCTTGTAGTTCTTCAATGCTTTTCAGATAAAGCAGGGCTTTGAGGCCAGTGCAGTAGTCTTCGATCACAGTGAAAT >520999_DPYD_07 ATCACAGTGAAATCCTGATTCTGAATGGCACTGCATACCTAGAAAAGACAGAGCAGCAGTCAACCAA >520999_DPYD_08 TGATTTTTCAGCAACCTCCAAGAAAGCACAATGCAAGAAGTGGGCAACACCTACCAGACACTCCTCCATATGTAGTTCGCTTTGCAAATCCCCACTGCTGGCCCAAGGTGT >520999_DPYD_09 GCCAAGGTGTGCCATCAGATTTTAATCCCATCAGACCTGAGACAGTGTTGGTGGCTGTAACGCCATTGGCACCACCTATGCAAGACACATCAACATTTTCAT >520999_DPYD_10 TTTTAGATGTTAAATCACACTTACGTTGTCTGGAAAGTCAGCCTTTAGTTCAGTGACACTTTGACACCAATATGCAGCCGTTTTCTCACTGATGAGCTCAATATTCA >520999_DPYD_11 AGCTCAATATTCAGAAAGGAGCTTTGTCCAGGGCCATACATGGGGCCAGAGGTGGTTCCCCGGATGATTCTGGGGGAAACATTTGTCACAATGTCCTGATGAAAGAGTAAAGATATT >520999_DPYD_12 TTACCTTATCAAGAGAGAAAGTTTTGGTGAGGGCAAAACCCCATCCAGCTTCAAAAGCTCTTCGAATCATTGATGTGCTGGTGGCTGGAGTTGCGCTAGCAAGACCAAAAGGATTTATAAA >520999_DPYD_13 ATTTATAAACTTCAATCCGGCCATTTCTACACTAATGTCCACCAGATCAATAGGAGTGTAAAAGAGGGGTAGTTCAGGCTTGGCAGAAACGGAAGCTCCATATTGTGACTGCAAAATACAAA >520999_DPYD_14 AAATAAAAAAATACATTATAAATAAATATATTTAAGAGTAAACTACTCACCTATTCCAATGAAAGCAGCTTTGTAGCCTTTTTCTTTCAAAGTGCTAAGA >520999_DPYD_15 TTTTTCTTTCAAAGTGCTAAGAGTCATTTCATTCACTGAAAGGCTTTTACCGCAAATTATCTATAAGAAACAATATTTTGCATAAGAAAATTTGGCATATGATTAATTAAAATCTTAATAATTTAACATCAAAAAGAATGAAAA >520999_DPYD_16 TTACTCCTTTCTTTTTGAGCAGTACACAGATAGGTGTTTTTTTCATTTACCTTTACACCAAGGTCCTTCATTAGCTCAATCTCAAAATTCACTACATCATACGGCAGCC >520999_DPYD_17 AAAATTCACTACATCATACGGCAGCCGGAACTGAGGAATTTCAGAAGTACTGAAAAGAAAGGAGAAAGAAAAACA >520999_DPYD_18 GGGATGTCACGTGTATATCATACATACCTCAGTAGCAAATTGCTGCAATCCACCAATAATTAATGGGTCCCTCTTCAGTGGCATATAAATTGCATCCACCTACACAAAGATCAGAGGTTGGA >520999_DPYD_19 AGGTTGGACATACCATTCCACAAGTCAGACCAAGTGGGTTGTTCAGAAAATATCATCTTAGCAGCTCCATAATAGTTCTGCAAAATTAATACAAAATAAAATTTTACTACTTAAAAATATACTTTAAA >520999_DPYD_20 ATAATAGAGAACAAGATCAAATACTGTTATTTTCATTTGCAGAGTTAAATCTGAATTTACCTTGTTTGCAATACTTGTGATGAATGATTTAATATCAAGATTAGTTGGACAGCTCTTCTGACACGGG >520999_DPYD_21 ATTTAATATCAAGATTAGTTGGCAGAGCTCTCTGACACGGGGCATCTGCACATTTCAGGCATCTAGGAAATAAAATAACTATGTTAAGAAACTACAAGATAAGTGAGATAATCTATTTT >520999_DPYD_22 TAATTTTCAGCATGAAATAGTGTATCAGTGGTACTTACAAGCAGTCTTATCAGGATTTCTTTTCCAATGTTTCTTGTCTAATTTCTTGGCCGAAGTGGAACGCAGAGTTGCATG >520999_DPYD_23 AACGCAGAGTTGCATGAGTTTGTGTTCGAGGATTTAAAGCCAGGATACTCTAAAGACAGCATAAACAATGTGTAAATATAT >520999_EGFR_01 CCCTTGTCTCTGTGTTCTTGTCCCCCCCAGCTTGTGGAGCCTCTTACACCCAGTGGAGAAGCTCCCAACCAAGCTCTCTTGAGGATCTTGAAGGAAACTGAATTCAAAAA

>520999_EGFR_02 TGAATTCAAAAAGATCAAAGTGCTGGGCTCCGGTGCGTTCGGCACGGTGTATAAGGTAAGGTCCCTGGCACAGGCCTCTGGGCTGGGCCGCAGGGCCTCTCATGGTCTGGTGGGGAG >520999_EGFR_03 GTTAACGTCTTCCTTCTCTCTCTGTCATAGGGACTCTGGATCCCAGAAGGTGAGAAAGTTAAAATTCCCGTCGCTATCAAGGAATTAAGAGAAGCAACATCTCCGAAAGCCAACAAGGAAATCCTC >520999_EGFR_04 AATTAAGAGAAGCAACATCTCCGAAAGCCAACAAGGAAATCCTCGATGTGAGTTTTCTGCTTTGCTGTGTGGGGGTCCATGG >520999_EGFR_05 CACACTGACGTGCCTCTCCCTCCCTCCAGGAAGCCTACGTGATGGCCAGCGTGGACAACCCCCACGTGTGCCGCCTGCTGGGCATCTGCCTCACCTCCACCGTGCAG >520999_EGFR_06 CACCGTGCAGCTCATCACGCAGCTCATGCCCTTCGGCTGCCTCCTGGACTATGTCCGGGAACACAAAGACAATATTGGCTCCCAGTACCTGCTCAACTGGTGTGTGCAGATC >520999_EGFR_07 AATATTGGCTCCCAGTACCTGCTCAACTGGTGTGTGCAGATCGCAAAGGTAATCAGGGAAGGGAGATACGGGGAGGGGAGATAAGGAGCCAGGATCCTCACATGCGGTCTGCG >520999_EGFR_08 TCCCTCACAGCAGGGTCTTCTCTGTTTCAGGGCATGAACTACTTGGAGGACCGTCGCTTGGTGCACCGCGACCTGGCAGCCAGGAACGTACTGGTGAAAACACCGCAGCATGTCAA >520999_EGFR_09 ACCGCAGCATGTCAAGATCACAGATTTTGGGCTGGCCAAACTGCTGGGTGCGGAAGAGAAAGAATACCATGCAGAAGGAGGCAAAGTAAGGAGGTGGCTTTAGGTCAGCCAGCATTTTCCTGACACCAGG >520999_ERBB2_01 CCTTGTCCCCAGGAAGCATACGTGATGGCTGGTGTGGGCTCCCCATATGTCTCCCGCCTTCTGGGCATCTGCCTGACATCCACGGTGCAGCTGGTGACACA >520999_ERBB2_02 CTGGTGACACAGCTTATGCCCTATGGCTGCCTCTTAGACCATGTCCGGGAAAACCGCGGACGCCTGGGCTCCCAGGACCTGCTGAACTGGTGTATGCAGATTGCCAAGGTATGCACCTGGGCTCTTTGCAG >520999_FOXL2_01 AAATAAAGAAGTCCGTGTTAAAAGAAGGAACACAAAATTTATTCGGGAATCGACAAGGCAAAAAACAAAAACAAAACAAAAAAACACAACAAAAGTGCTCTAGTTCTCTCTAGAAAATTTGGTCCCCCAAA >520999_FOXL2_02 AAAATTTGGTCCCCCAAACAACAAGCTACAGTACAACCAGGTCTATGGTTTTCGGGCCGGGCCGGCTCCGGGCCACAAGACCGCCTAGGTCGGCCGCTGCCGGGTTTCACATTTCTCCTTC >520999_FOXL2_03 CCGCTGCCGGGTTTCACATTTCTCCTTCCCAAGGTGGGAGAAGCAGGAGGTTTGAAAAACAAAAAGCAGGGAGGACGAGCCGTCCCAGCAGCGTGGGCCAGGCAGGCAGT >520999_FOXL2_04 CAGCAGCGTGGGCCAGGCAGGCAGTGATCTCCCTGCCTCCAGGACTTGCATCGAAAGATCCGGGGACATTTGTTTTTTGATTTTTTTCTTCAGATAGGGAGAGGGTGAAA >520999_FOXL2_05 GGACATTTGTTTTTGATTTTTTTCTTCAGATAGGGAGAGGGTGAAACTTCCCCAATTGGTAGACGAAACCATCTTTTATTGGATATATTCTCCTAACTCTGAACACAGCTTTTTGAAGGCCCAACAAAAA >520999_FOXL2_06 ACAGCTTTTTGAAGGCCCAACAAAAACTCTAACGCAAATCTTCCAGAAGAGAAGATGAGGAATACTAAAGCTTTTGATTTTCATATTTGGATTTA >520999_FOXL2_07 ATTTAGCAAACTCCAAGGCCACAATACTTCCCCGGTTGCCCGGTGAATTTTTTTTTCCTTTTTTTTTTTTTAAATACTCTCTTAAAAA >520999_FOXL2_08 CCGGTGAATTTTTTTTTCCTTTTTTTTTTTTTAAATACTCTCTTAAAAAGTTCCACCGATCTTTCAAACAAAACATTAGCCAGCCGCCGGGGCCCGGAGGTGCCCGAA >520999_FOXL2_09 GCCGGGGCCCGGAGGTGCCCGAAGCGACGGGACTGATAGCGGAGGAAACGCAGCCTCCCTCCGCGCCCGCCCGCGGTTAAACCGAGTACAGGCCGTGGAGCCAGGCTGCCCCGGCTCCCGCTGGGTCCCAACCCCCGCCCCGCCTAGTGGGCCCCGCGGCAAGCG >520999_FOXL2_10 CCCCGGCTCCCGCTGGGTCCCAACCCCCGCCCCGCCTAGTGGGCCCCGCGGCAAGCGGCTTCTGAACAGCTTCAAGAGGGTTCGCGGAGCAAACACAC >520999_FOXL2_11 CAAACACACGTATTGGTCCGTCCCTTTCTCGGGCAGCGCGGTCCCGCCATCAGTCCTGTCCGGCGCGTCTAGCCATGGACTGCACGGCAGTCGGGCGGGGAACGCGGGAGAGCGAGCGCACC >520999_FOXL2_12 GGGCGGGGAACGCGGAGAGCGAGCGCACCGACCTGTGAGAGAAGGCCAAGAGGTCTGCGCTGCCGACGCCCGGTCGCACCTCCGCCCCGGGCCCTTTCCGC >520999_FOXL2_13 CCGACGCCCGGTCGCACCTCCGCCCCGGGCCCTTTCCGCGGTGAATTTGGGCAGGAGACGCTGGGGCTCCGGAAAGAGACGAGCCCAGTAGAAAGCGCGCAGAGAGGCAGCTTCAGGCCAGGGGAGTGCAAGGTCA >520999_FOXL2_14 GCAGAGAGGCAGCTTCAGGCCAGGGGAGTGCAAGGTCACAGAGGTCAGGGAGGTGAGCACAGGAGGACATAAACTGAGGGGACAAAGAGGAGCGACAGGAGCTTA >520999_FOXL2_15 GACAGGAGCTTAGGAAAGCGAAAAAGCACAGAGGGACCCTGGGCGCTGGCTCCAGAGGGCGGGCCCAGAGGGTGTGAGGTCAGGCTGGCGGCGGCGTCGTCGGCTGCGACCGGGGCCGGCGTCGCGCGTCC >520999_FOXL2_16 GCGGCGGCGTCGTCGGCTGCGACCGGGGCCGGCGTCGCGCGTCCCTGCATCCTCGCATCCGTCTGCACCGGCATGCGGTGGGCTCTCAGAGATCGAGGGCCGAATGCAGCGCGCCG >520999_FOXL2_17 GCGCGAATGCAGCGCGCCGGTCTTGCTGTCGTGGTCCCAGTAAGAGCAATGCATCATGGCGAGCTCGGGCTGCCGGGCACAAGCGAACTGCAGGCCCGGCGCACTGGTGGGCGCGGGCGCCGGGGGCGCGGCG >520999_FOXL2_18 CCGGGCACAAGCGAACTGCAGGCCCGGCGCACTGGTGGGGCCGGGCGCCGGGGGCGCGGCGGTGGCTGGGCTGGCAGGGCTGAGCTGGCCCGGCGGCGGCGCGGCGGCCCCGTGGTGCGGTGGGGCAGGCGGCGGTGCGGCGGCC >520999_FOXL2_19 GCGGCGGTGCGGCGGCCGCGTGCAGATGGTGTGCGTGCGGATGCGGGTGGGGGTGCGGCGGAGGCGGGGGTGCGGCCGGCGGGCCTCCCAGGCCATTGTACGAGTTCACTACGCCGGGGGGCAGCGC >520999_FOXL2_20 CCGGGGGGCAGCGCCATGCTCTGCACGCGTGTGTACGGCCCGTACGAGGCGGCCGGGCCCGCCAGCCCCTTGACCACAGCGGCCGCGCCAGGGCTACCGGGGCCGCGG >520999_FOXL2_21 CGGCCGCGCCAGGGCTACCGGGGCCCGCGGCTGCAGCCGCAGCTGCTGCAGCCGCTGCGGCTGCCGCCATCTGGCAGGAGGCATAGGGCATGGGTGAGGGAGGCTGCGGTAGCGGCCACGAGTTGTT >520999_FOXL2_22 GGTGAGGGAGGCTGCGGTAGCGGCCACGAGTTGTTGAGGAAGCCAGACTGCAGGTACTTGGGGGGCGCCAGGTAGCCGTAGCCGTCGGCCCCGGCGCCCGCCACGCCGCACCCGCCTGCGGGCGCCTCCGGCCCCGA >520999_FOXL2_23 GGGGGCGCCAGGTAGCCGTAGCCGTCGGCCCCGGCGCCCGCCACGCCGCACCCGCCTGCGGGCGCCTCCGGCCCCGAAGAGCCCCTTGCCGGGCTGGAAGTGCGCGGGCGGCGGCCGGAAGGGCCTCTTCATGCGGGCGGCGGCGC >520999_FOXL2_24 GGCGGCGGCGCCGGTAGTTGCCCTTCTCGAACATGTCTTCGCAGGCCGGGTCCAGCGTCCAGTAGTTGCCCTTGCGCTCGCCGCCGCCCTCGCGCGGCACCTTGATGAAGCACTCGTTGAG >520999_FOXL2_25 GCCGCCGCCCTCGCGCGGCACCTTGATGAAGCACTCGTTGAGGCTGAGGTTGTGGCGGATGCTATTTTGCCAGCCCTTCTTATTCTTCTCGTAGAACGGGAACTTCGCGATGATGTACTGGTAGATGCCG >520999_FOXL2_26 TAGATGCCGGACAGCGTGAGCCTCTTCTCCGCGCTCTCGCGGATCGCCATGGCGATGAGCGCCACGTACGAGTACGGGGGCTTCTGCGCCGG >520999_FOXL2_27 GGGGCTTCTGCGCCGGGTCCGGCTTCTCCGGGGCTGTCCCGCCGCCACCCCCACCGCCCTTGCCTGGGCTCGGCGGCGGCCCTTCTGGCTCCTTGACTGTGCGACCGGTCTCTGGGCCAGCAGGGCCCCCGCCGCGTCCTCGG >520999_FOXL2_28 GGGCCAGCAGGGCCCCCGCCGCGTCCTCGGGCTCGGGGTAGCTGGCCATCATGACAAAGCCGGCGCGCCGCGGCCGGGCCGCCTCTGCTCTCCGCTCCAGGGCGCTGGCGC >520999_FOXL2_29 GGCGCGCCGCGGCCGGGCCGCCTCTGCTCTCCGCTCCAGGCGCTGGCGCGGCAAAGAGTTGGGGCGCACGAGTCCGCTTACGGCCAAGTCTCAAACTTCTGGAGACTGCGGATGCCGCCCGCG >520999_FOXL2_30 CCGCCCGCGCTTGCTTGCTGGAGGCCTGTCGCTGCTCTCCCCTCTCCTTCCCCTTCCCCTAGGGAGCGGCCGGCGGGAGTGGAGCTCAGCCTCTGGCCATGGGGAGTCCGCC >520999_FOXL2_31 GGGAGTCCGCCCAACAGAGAGGGGCTCCGGCCTCGCCGCCCCTCCCCGCTCAGGCCAGTCCCCGCCTTGGTGGGTTTTCTTTTCTGCGCTCTTCCCCTCCCCCCGCCCCCCG >520999_FOXL2_32 CCTCCCCCCGCCCCCCGGTTTCCCGAAGCACGACCCGCGTCTCTGGCGGAGCTGCCTCCTGGAGTCCCTAGTGCGCCAGGAGCCTCGCTCTGTTCTGATTCGTATGGG >520999_KIT_01 TGACATATGGCCATTTCTGTTTTCCTGTAGCAAAACCAGAAATCCTGACTTACGACAGGCTCGTGAATGGCATGCTCCAATGTGTGGCAGCAGGATTCCCAGAGCCCACAATAGATTGGTATTTTT >520999_KIT_02 ATTGGTATTTTTGTCCAGGAACTGAGCAGAGGTGAGATGATTATTTTTGGCACTGCTTATAATGCAGAG >520999_KIT_03 TATTTATTTATTTTCCTAGAGTAAGCCAGGGCTTTTGTTTTTCTTCCCTTTAGATGCTCTGCTTCTGTACTGCCAGTGGATGTGCAGACACTAAACTCATCTGGGCCACCGTTTGGAAA >520999_KIT_04 GGCCACCGTTTGGAAAGCTAGTGGTTCAGAGTTCTATAGATTCTAGTGCATTCAAGCACAATGGCACGGTTGAATGTAAGG >520999_KIT_05 AATGTAAGGCTTACAACGATGTGGGCAAGACTTCTGCCTATTTTAACTTTGCATTTAAAGGTAACAACAAAGGTATATTTCTTTTTAATCCAATTTAAGGGGATGTTTA >520999_KIT_06 TTGTGATTCCACATTTCTCTTCCATTGTAGAGCAAATCCATCCCCACACCCTGTTCACTCCTTTGCTGATT >520999_KIT_07 TCCTTTGCTGATTGGTTTCGTAATCGTAGCTGGCATGAATGTGCATTATTGTGATGATTCTGACCTACAAATATTTACAGGTAACCATTTATTTGTTCT >520999_KIT_08 AGACAATAATTATTAAAAGGTGATCTATTTTTCCCTTTCTCCCCACAGAAACCCATGTATGAAGTACAGTGGAAGGTTGTTGAGGAGATAAATGGAAACAATTATGTTTA >520999_KIT_09 ATAAATGGAAACAATTATGTTTACATAGACCCAACACAACTTCCTTATGATCACAAATGGGAGTTTCCCAGAAACAGGCTGAGTTTTGGTCAGTATGAAACAGGGGCTTTCCATGTCACCTTTTT >520999_KIT_10 ACCAGCACCATCACCACTTACCTTGTTGTCTTCCTTCCTACAGGGAAAACCCTGGGTGCTGGAGCTTTCGGGAAGGTTGTTGAGGCAACTGCTTATGGCTTAATTAAGTCAGATGCGG >520999_KIT_11 CTTAATTAAGTCAGATGCGGCCATGACTGTCGCTGTAAAGATGCTCAAGCGTAAGTTCCTGTATGGTACTGCATGCGCTTGACATCAGTTT >520999_KIT_12 CCAGTTGTGCTTTTTGCTAAAATGCATGTTTCCAATTTTAGCGAGTGCCCATTTGACAGAACGGGAAGCCCTCATGTCTGAACTCAAAGTCCTGAGTTACCTTGGTAATCACATGAATATT >520999_KIT_13 TAATCACATGAATATTGTGAATCTACTTGGAGCCTGCACCATTGGAGGTAAAGCCGTGTCCAAGCTGCCTTTTATTGTCTGTCAGGTTATCAAAACATGACATTTTAATATGATTTT >520999_KIT_14 GGTATTTTTATGGGAGGGCAGAATTAATCTATATATCTCACCTTCTTTCTAACCTTTTCTTATGTGCTTTTTAGGGCCCACCCT >520999_KIT_15 TTTTAGGGCCCACCCTGGTCATTACAGAATATTGTTGCTATGGTGATCTTTTGAATTTTTTGAGAAGAAAACGTGATTCATTTATTTGTT >520999_KIT_16 ATTTATTTGTTCAAAGCAGGAAGATCATGCAGAAGCTGCACTTTATAAGAATCTTCTGCATTCAAAGGAGTCTTCCTGGTAAGACTGATTTACATAAATAGTTAGCTGTT >520999_KIT_17 TAATAGTGTATTCACAGAGACTTGGCAGCCAGAAATATCCTCCTTACTCATGGTCGGATCACAAAGATTTGTGATTTT >520999_KIT_18 ATTTGTGATTTTGGTCTAGCCAGAGACATCAAGAATGATTCTAATTATGTGGTTAAAGGAAACGTGAGTACCCATTCTCTGCTTGACAGTCCTGCAAAGGATTTTTA >520999_KIT_19 TATAAGAATATCTTCTGTTCAATTTTGTTGAGCTTCTGAATTAACATTATTGACTCTGTTGTGCTTCTATTACAGGCTCGACTACCTGTGAAGTGGATGGCACCTGAAAGCATTTTCAACTGTGTATACA >520999_KIT_20 CATTTTCAACTGTGTATACACGTTTGAAAGTGACGTCTGGTCCTATGGGATTTTTCTTTGGGAGCTGTTCTCTTTAGGTAAAATGATCCTTGCCAAAGACAACTTCATTA >520999_KRAS_01 ATCTGTATTTATTTCAGTGTTACTTACCTGTCTTGTCTTTGCTGATGTTTCAATAAAAGGAATTCCATAACTTCTTGCTAAGTCCTGA >520999_KRAS_02 AATAAAAGGAATTCCATAACTTCTTGCTAAGTCCTGAGCCTGTTTTGTGTCTACTGTTCTAGAAGGCAAATCACATTTATTTCCTACTA >520999_KRAS_03 ATTTATTTCCTACTAGGACCATAGGTACATCTTCAGAGTCCTTAACTCTTTTAATTTGTTCTCTGGGAAAGAAAAAAAAGTTATAGCACAGTCATTAGTAACACAAATAT >520999_KRAS_04 TTATTATATTCAATTTAAACCCACCTATAATGGTGAATATCTTCAAATGATTTAGTATTATTTATGGCAAATACACAAAGAAAGCCCTCCCCAGTCCTCAT >520999_KRAS_05 CAGTCCTCATGTACTGGTCCCTCATTGCACTGTACTCCTCTTGACCTGCTGTGTCGAGAATATCCAAGAGACAGGTTTCTCCATCAATTACTACTTGCTTCCTGTAGGAATCCTGAGAAGGGAGAAA >520999_KRAS_06 CAGTAATATGCATATTAAAACAAGATTTACCTCTATTGTTGGATCATATTCGTCCACAAAATGATTCTGAATTAGCTGTATCGTCAAGGCACTCTTGCCTACGCCA >520999_KRAS_07 TTGCCTACGCCACCAGCTCCAACTACCACAAGTTTATATTCAGTCATTTTCAGCAGGCCTTATAATAAAAATAATGAAAATGTGACTATATTAGAACATGTCACACATAAGGTTAATA >520999_MET_01 GTTCACTGCATATTCTCCCCACAGATAGAAGAGCCCAGCCAGTGTCCTGACTGTGTGGTGAGCGCCCTGGGAGCCAAAGTCCTTTCATCTGTAAAGGACCGGTTCATCAACTT >520999_MET_02 GGTTCATCAACTTCTTTGTAGGCAATACCATAAATTCTTCTTATTTCCCAGATCATCCATTGCATTCGATATCAGTGAGAAGGCTAAAGGAAACGAAAGATGGTTTTATGTTTTT >520999_MET_03 CTGAATGATGACATTCTTTTCGGGGTGTTCGCACAAAGCAAGCCAGATTCTGCCGAACCAATGGATCGATCTGCCATGTGTGCATTCCCTATCAAATATGTCAACGACTTCTTCAACAAGATCGTCAACAAAAA >520999_MET_04 CCTATCAAATATGTCAACGACTTCTTCAACAAGATCGTCAACAAAAACAATGTGAGATGTCTCCAGCATTTTTACGGACCCAATCATGAGCACTGCTTTAATAGGGTAAGT >520999_MET_05 CTTTAATAGGGTAAGTCACATCAGTTCCCCACTTATAAACTGTGAGGTATAAATTAGAAATAAGTATCAGTCTCAAAAAGAATATCCAGGGCTTCTTTTGTG >520999_MET_06 TGAGGTATAAATTAGAAATAAGTATCAGTCTCAAAAAGAATATCCAGGGCTTCTTTTGTGCTTTGTAAATGGTGTTTATCCAAAATAGTTGCAGATTTTTTCCAAGAAAATT >520999_MET_07 ATTTTTTCCAAGAAAATTGAGGAATTGAATCTTCATTTACACCTAAAATTATATCTTTAAAATGTAATGGTAACTAAAAGAAAAAATGTTTTTACAATT >520999_MET_08 AGGTGATTAAATTGAATCCCTCTCTTACAGTACTTGGTGGAAAGAACCTCTCAACATTGTCAGTTTTCTATTTTGCTTTGCCAGTGGTGGGAGCACAATAA >520999_MET_09 ACAATAACAGTGTTGGGAAAAACCTGAATTCAGTTAGTGTCCCGAGAATGGTCATAAATGTGCATGAAGCAGGAAGGAACTTTACAGTGGTAAGTCCTTTGAGCAAATGGTTCTACT >520999_MET_10 TTATTATCCTGAAGGCAGTTATGCCATTTGTAGAATGGTAATAACCAGTTGGTATTTGGGACCCAAAGTGCTACAACCTGTGTAGTACAAATAT >520999_MET_11 TACAAATATCTATCATGGCTAAATGCTGACTTTTCTTTATTTGTCATTTTTAGTGGAAGCAAGCAATTTCTTCAA >520999_MET_12 TCTCCTGGGGCCCATGATAGCCGTCTTTAACAAGCTCTTTCTTTCTCTCTGTTTTAAGATCTGGGCAGTGAATTAGTTCGCTACGATGCAAGAGTACACACTCCTCATTTG >520999_MET_13 TACACACTCCTCATTTGGATAGGCTTGTAAGTGCCCGAAGTGTAAGCCCAACTACAGAAATGGTTTCAAATGAAT >520999_MET_14 AGAAATGGTTTCAAATGAATCTGTAGACTACCGAGCTACTTTTCCAGAAGGTATATTTCAGTTTTATTGTTCTGAGAAATA >520999_MET_15 TAAATTTGACAAAGTATTCACTGTTCCATAATGAAGTTAATGTCTCCACCACTGGATTTCTCAGGAATCACTGACATAGGAGAAGTTTCCCAATTT >520999_MET_16 ATAGGAGAAGTTTCCCAATTTCTGACCGAGGGAATCATCATGAAAGATTTTAGTCATCCCAATGTCCTCTCGCTCCTGGGAATCTGCCTGCGAAGTGAAGGGTCTCCGCT >520999_MET_17 GGTCTCCGCTGGTGGTCCTACCATACATGAAACATGGAGATCTTCGAAATTTCATTCGAAATGAGACTCATGTAAGTTGACTGCCAAGCTTACTAACTGGCAAACTA >520999_MTHFR_01 CCCGCAGCCTGGCCTGCAGCTGGGGTCAGGCCAGGGGCAGGGGATGAACCAGGGTCCCCACTCCAGCATCACTCACTTT >520999_MTHFR_02 ACTCACTTTGTGACCATTCCGGTTTGGTTCTCCCGAGAGGTAAAGAACGAAGACTTCAAAGACACTTTCTTCACTGGTCAGCTCCTCCCCCCACATCTTCAGCAGCTCCTCCTTGGGGGACTTGCTCTTCAGGTA >520999_MTHFR_03 GGACTTGCTCTTCAGGTAGAAGAGGTAGTAGTCCTTCAGCTCCCCAAAGGCAGGGGAAGAGGAATTGCCCCTGGCAGAGGGGTGCCCAGAGGTCAGGGGCACACTCCTGACAGAGGGCAGTGCCAC >520999_MTHFR_04 CCCCCAGCCTGTGCGAGGACGGTGCGGTGAGAGTGGGGTGGAGGGAGCTTATGGGCTCTCCTGGGCCCCTCACCTGGATGGGAAAGATCCCGGGGACGATGGGGGCAAGTGATGCCCATG >520999_MTHFR_05 GCCCCTCACCTGGATGGGAAAGATCCCGGGGACGATGGGGCAAGTGATGCCCATGTCGGTGCATGCCTTCACAAAGCGGAAGAATGTGTCAGCCTCAAAGAAAAGCTGCGTGATGATGAAATCGGCTCCC >520999_MTHFR_06 GTGATGATGAAATCGGCTCCCGCAGACACCTTCTCCTTCAAGTGCTTCAGGTCAGCCTCAAAGCTCCCTGCTTCGGGGTGGCCTTTGGGGTAAC >520999_MTHFR_07 CTCCCTGCTTCGGGGTGGCCTTTGGGGTAACCTGCCAATAGGGATGACAGTCAGGAGAGGCTGGCCTCCACC >520999_NRAS_01 ACAAATGCTGAAAGCTGTACCATACCTGTCTGGTCTTGGCTGAGGTTTCAATGAATGGAATCCCGTAACTCTTGGCCAGTTCGTGGGCTTGTTTTTGTATCAACTGTCCTTGTTGG >520999_NRAS_02 TCCTTGTTGGCAAATCACACTTGTTTCCCACTAGCACCATAGGTACATCATCCGAGTCTTTTACTCGCTTAATCTGCTCCCTAAAAACGGGAATATATTAT >520999_NRAS_03 TTTCAGAGAAAATAATGCTCCTAGTACCTGTAGAGGTTAATATCCGCAATGACTTGCTATTATTGATGGCAAATACACAGAGGAAGCTTCGCCTGTCCTCATGTATTGGTCTCTCATG >520999_NRAS_04 TCCTCATGTATTGGTCTCTCATGGCACTGTACTCTTCTTGTCCAGCTGTATCCAGTATGTCCAACAAACAGGTTTCACCATCTATAA >520999_NRAS_05 CCATCTATAACCACTTGTTTTCTGTAAGAATCCTGGGGGTGTGGAGGGTAAGGGGGCAGGGAGGGAGGGAAGTTCAATTTTTATTAAAAACCACAGGGAATG >520999_NRAS_06 ATCAGGTCAGCGGGCTACCACTGGGCCTCACCTCTATGTGGGATCATATTCATCTACAAAGTGGTTCTGGATTAGCTGGATTGTCAGTGCGCTTTTCCCAACACCACCTGCTCCAA >520999_NRAS_07 CACCTGCTCAACCACCACCACCAGTTTGTACTCAGTCATTTCACACCAGCAAGAACCTTGTTGGAAACCAGTAATCAGGGTTAATTGGC >520999_PDGFRA_01 CTTTGGTAATTCACCAGTTACCTGTCCTGGTCATTTATAGAAACCGAGGTATGAAATTCGCTGGAGGGTCATTGAATCAATCAGCCCAGATGGACATGAATATATTTATGT >520999_PDGFRA_02 CAGATGGACATGAATATATTTATGTGGACCCGATGCAGCTGCCTTATGACTCAAGATGGGAGTTTCCAAGAGATGGACTAGTGCTTGGTAAGTTCCATGGGGTAACCTCCCAAGACTCCCTTTT >520999_PDGFRA_03 GGACTGATATGTGATTTATTCTTTCAACAGCCACGGCCAGATCCAGTGAAAAAACAAGCTCTCATGTCTGAAC >520999_PDGFRA_04 TCATGTCTGAACTGAAGATAATGACTCACCTGGGCCACATTTGAACATTGTAAAACTTGCTGGGAGCCTGCACCAAGTCAGGTGGGCTCACTGACCTGGAGTGAGGATTTTCACTGGACACATGT >520999_PDGFRA_05 ATTTCTTCCTTTTCCATGCAGTGTGTCCACCGTGATCTGGCTGCTCGCAACGTCTCTCCTGGCACAAGGAAAAATTGTGAAAGATCTGTGACTTTGGCCTGGCCAGAGACATCATGCAT >520999_PDGFRA_06 CAGAGACATCATGCATGATTCGAACTATGTGTCGAAAGGCAGTGTACGTCCTCACTTCCCTCACTGGTCAGGCTCATCCTCCTTCACTTTAATCTCTAAA >520999_PIK3CA_01 TATATAATAGCTTTTCTTCCATCTCTTAGGAAACTCCATGCTTAGAGTTGGAGTTTGACTGGTTCAGCAGTGTGGTAAAGTTCCCAGATATGTCAGTGATTGAAGAGCATGCCAATT >520999_PIK3CA_02 TGATTGAAGAGCATGCCAATTGGTCTGTATCCCGAGAAGCAGGATTTAGCTATTCCCACGCAGGACTGGTAAGGCAAATCACTGAGTTTATTAAGTATCAATTATAATCTGT >520999_PIK3CA_03 TTTTCTCTGTTTAAAATGTTTTGGTGTTCTTAATTTATTCAAGACATTTTGTATCTGCATATATCAAACTATAACATAATTTCTTATTTTTGAAAGCTGTTT >520999_PIK3CA_04 TATAACATAATTTCTTATTTTTGAAAGCTGTTCATATAGATTTTGGACACTTTTTGGATCACAAGAAGAAAAAATTTGGTTATAAACGAGAACGTGTGCCATTTGTTTTGACACA >520999_PIK3CA_05 TTTTGACACAGGATTTCTTAATAGTGATTAGTAAAGGAGCCCAAGAATGCACAAAGACAAGAGAATTTGAGAGGTGAGCTCGAGCAATTAAAAAACACAAAAATAAAGA >520999_RET_01 CTAGAGAGTTAGAGTAACTTCAATGTCTTATTCCATCTTCTCTTTAGGGTCGGATTCCAGTTAAATGGATGGCAATTGAATCCCTTTTTGATCATATCTACA >520999_RET_02 TTTTTGATCATATCTACACCACGCAAAGTGATGTGTAAGTGTGGGTGTTGCTCTCTTGGGGTGGAGGTTACAGAAACA >520999_TP53_01 GGTTCAAAGACCCAAAACCCAAAATGGCAGGGGAGGGAGAGATGGGGGTGGGAGGCTGTCAGTGGGGAACAAGAAGTGGAGAATGTCAGTCTGAGTCAGGCCCTTCTGTCTTGAACATGA >520999_TP53_02 TCTGAGTCAGGCCCTTCTGTCTTGAACATGAGTTTTTTATGGCGGGAGGTAGACTGACCCTTTTTGGACTTCAGGTGGCTGTAGGAGACAGAAGCAGGGAGGAGAGATG >520999_TP53_03 GGATGAGAATGGAATCCTATGGCTTTCCAACCTAGGAAGGCAGGGGAGTAGGGCCAGGAAGGGGCTGAGGTCACTCACCTGGAGTGAGCCCTGCTCCCCCCTGGCTCCTTCCCAGCCTGG >520999_TP53_04 CCCTGCTCCCCCCTGGCTCCTTCCCAGCCTGGGCATCCTTGAGTTCCAAGGCCTCATTCAGCTCTCGGAACATCTCGAAGCGCTCACGCCCA >520999_TP53_05 TTCAGCTCTCGGAACATCTCGAAGCGCTCACGCCCACGGATCTGCAGCAACAGAGGAGGGGGAGAAGTAAGTATATACACAGTACCTGAGTTAAAAGATGGTTCAAGTTACAATTGTTT >520999_TP53_06 TTAGATTAGGTGTATTAAATCCATTTTCAACTTACAATATTTTCAACTTACGACGAGTTTATCAGGAAGTAACACCATCGTAAGTCAAGTAGCATCTGTAT >520999_TP53_07 TAGCATCTGTATCAGGCAAAGTCATAGAACCATTTTCATGCTCTCTTTAACAATTTTCTTTTTGAAAGCTGGTCTGGTCCTTTAAAATATATATTATGGTAT >520999_TP53_08 AACTTTCCACTTGATAAGAGGTCCCAAGACTTAGTACCTGAAGGGTGAAATATTCTCCATCCAGTGGTTTCTTCTTTGGCTGGGGAGAGGAGCTG >520999_TP53_09 GGGAGAGGAGCTGGTGTTGTTGGGCAGTGCTAGGAAAGAGGCAAGGAAAGGTGATAAAAGTGAATCTGAGGCATAACTGCACCCTTGGTCTCCTCCACCGCTTCTTGT >520999_TP53_10 CGCTTCTTGTCCTGCTTGCTTACCTCGCTTAGTGCTCCCTGGGGGCAGCTCGTGGTGAGGCTCCCCTTTCTTGCGGAGATTCTCTTCCTCTGTGCGCCGGTCTCTCTCCCAGGACAGGC >520999_TP53_11 TGTGCGCCGGTCTCTCCCAGGACAGGCACAAACACGCACCTCAAAGCTGTTCCGTCCCAGTAGATTACCACTACTCAGGATAGGAAAAGAGAAGCAA >520999_TP53_12 AAGAAATCGGTAAGAGGTGGGCCCAGGGGTCAGAGGCAAGCAGAGGCTGGGGCACAGCAGGCCAGTGTGCAGGGTGGCAAGTGGCTCCTGACCTGGAGTC >520999_TP53_13 CTGACCTGGAGTCTTCCAGTGTGATGATGGTGAGGATGGGCCTCCGGTTCATGCCGCCCATGCAGGAACTGTTACACATGTAGTTGTAGTGGATGGTG >520999_TP53_14 TTACACATGTAGTTGTAGTGGATGGTGGTACAGTCAGAGCCAACCTAGGAGATAACACAGGCCCAAGATGAGGCCAGTGCG >520999_TP53_15 CCCAGAGACCCCAGTTGCAAACCAGACCTCAGGCGGCTCATAGGGCACCACCACACTATGTCGAAAAGTGTTTCTGTCATCCAAATACTCCACACGCAAATTTCCTTC >520999_TP53_16 AATTTCCTTCCACTCGGATAAGATGCTGAGGAGGGGCCAGACCTAAGAGCAATCAGTGAGGAATCAGAGGCCTGGGGACCCTGGGCAACCAGCCCTGTCGTCTCTCCAGCCC >520999_TP53_17 GTCTCTCCAGCCCCAGCTGCTCACCATCGCTATCTGAGCAGCGCTCATGGTGGGGGCAGCGCCTCACAACCTCCGTCATGTGCTGTGA >520999_TP53_18 ATGTGCTGTGACTGCTTGTAGATGGCCATGGCGCGGACGCGGGTGCCGGGCGGGGGTGTGGAATCAACCCACAGCTGCACAGGGCAGGTCTTGGCCAGTT >520999_TP53_19 GGGCAGGTCTTGGCCAGTTGGCAAAACATCTTGTTGAGGGCAGGGGAGTACTGTAGGAAGAGGAAGGAGACAGAGTTGAAAGTCAGGGCACAAGTGAA >520999_TP53_20 ATGGAAGCCAGCCCCTCAGGGCAACTGACCGTGCAAGTCACAGACTTGGCTGTCCCAGAATGCAAGAAGCCCAGACGGAAACCGTAGCTGCC >520999_TP53_21 CGTAGCTGCCCTGGTAGGTTTTCTGGGAAGGGACAGAAGATGACAGGGGCCAGGAGGGGGCTGGTGCAGGGGCCGCCGGTGTAGGAGCTGCTGGTGCAGGGGCCACGGGGGGAGCAG >520999_TP53_22 GGCCACGGGGGGAGCAGCCTCTGGCATTCTGGGAGCTTCATCTGGACCTGGGGTCTTCAGTGAACCATTGTTCAATATCGTCCGGGGACAGCATCAAAT >520999_TP53_23 GGGGACAGCATCAAATCATCCATTGCTTGGGAACGGCAAGGGGGACT >520999_TP53_24 GGCAAGGGGGACTGTAGATGGGTGAAAAGAGCAGTCAGAGGACCAGGTCCTCAGCCCCCCAGCCCCCCAGCCCTCCAGGTCCCCAGCCCTCCAGGTCCCCAGCCCAACCCTTGTCCTTACCAGAACGTTGTTTTCAG >520999_TP53_25 TTGTTTTCAGGAAGTCTGAAAGACAAGAGCAGAAAGTCAGTCCCATGGAATTTTCGCTTCCCACAGGTCTCTGCTAGGGGGCTGGGGTTGGGGTGGGGGTG >520999_TP53_26 AATTTTCGCTTCCCACAGGTCTCTGCTAGGGGGCTGGGGTTGGGGTGGGGGTGGTGGGCCTGCCCTTCCAATGGATCCACTCACAGTTTCCATAGGTCTGAAAATGTTTC >520999_TP53_27 AAAATGTTTCCTGACTCAGAGGGGGCTCGACGCTAGGATCTGACTGCGGCTCCTCCATGGCAGTGACCCGGAAGGCAGTCTGG >520999_TPMT_01 121 ATTTTATTTTATCTATGTCTCATTTACTTTTCTGTAAGTAGATATAACTTTTCAAAAAGACAGTCAATTCCCCAACTTTTATGTCGTTCTTCAAAA >520999_TPMT_02 122 TTTTATGTCGTTCTTCAAAAGCATCAACCTTCTCAAGACAACGTATATTGCATATTTTACCTGAAACAAGAAAGAGTAACATGTTAAAATA >520999_TPMT_03 123 AAAAAAAAAAAACCCAACAACTTTACCTGGATGTTTTAGTTGGATCATAAGAAAGAACACACAGGAGATACTGAAACTTCTTTCCCAGGAGGGAAAACATT >520999_TPMT_04 124 TGAAAACTTCTTTCCCAGGAGGGAAAACATTGTATCTGCATAGCTACAAAGAACACAAGAAGGTATTTGTTACATTTCTCTACACAGGCAAAGGCTGGAGGGACAAAAGGCAG >520999_TPMT_05 125 AAAAAGTATAGTATACTAAAAAATTAAGACAGCTAAACAAAAAAAGAAAAATTACTTACCATTTGGCGATCACCTGGATTGATGGCAACTAATGCT >520999_TPMT_06 126 ATTGATGGCAACTAATGCTCCTCTATCCCAAATCATGTCAAATTTGCCAATATTTGTCCTACCAGAAAGAGAAAAAACATTTTATGGGAGAAAAATCAAATCTTTAAGAAGATGAGCAGCGTCCCC >520999_TPMT_07 127 AATTATTTACCCAAATCAAAACAAACCTTAAATACTTTGGTTCCAGGAATTTCGGTGATTGGTTCTTCTGAGTAAGAAAGATTCTGCTCTGTAAAAAATTCTTGTATC >520999_TPMT_08 128 TAAAAAATTCTTGTATCCCAAGTTCACTGATTTCCACACCAACTACACTGTGTCCCCGGTCTGCAAACCTGCATAAAATCATACATTTACACTTAAATTATGTTTTCAAAT >520999_UGT1A1_01 TATTAAGAAACCTAATAAAGCTCCACCTTTCTTTATCTCTGAAAGTGAACTCCCTGCTACCTTTGTGACTGACAGCTTTTTATA >520999_UGT1A1_02 AGCTTTTTATAGTCACGTGACACAGTCAAACATTAACTTGGTGTATCGATTGGTTTTTTGCCATATATATATATATAAGTAGGAGAGGGC >520999_UGT1A1_03 ATTGGTTTTTGCCATATATATATATAAGTAGGAGAGGGCGAACCTCTGGCAGGAGCAAAGGCGCCATGGCTGTGGAGTCCCAGGGCGGACGCCCACTTGTCCTGGGCCTGCTGCTGTGTGTGCTGGGCC >520999_UGT1A1_04 CCAGGGCGGACGCCCACTTGTCCTGGGGCCTGCTGCTGTGTGTGCTGGGCCCAGTGGTGTCCCATGCTGGGAAGATACTGTTGATCCCAGTGGATGGCAGCCACTGGCTGAGCATGCTTGGGGCCATCCAGCA >520999_UGT1A1_05 GGCCATCCAGCAGCTGCAGCAGAGGGGACATGAAATAGTTGTCCTAGCACCTGACGCCTCGTTGTACATCAGAGACGGAGCATTTTACA >520999_UGT1A1_06 ACGGAGCATTTTACACCTTGAAGACGTACCCTGTGCCATTCCAAAGGGAGGATGTGAAAGAGTCTTTTGTTAGTCTCGGGCATAATGTTTTTGAGAATGATTCTTT >520999_UGT1A1_07 TTTTTGAGAATGATTCTTTCCTGCAGCGTGTGATCAAAACATACAAGAAAATAAAAAAGGACTCTGCTATGCTTTTGTCTGGCTGTTCCCACTTACTGCACAACAAGGAGCTCATGGCCTCC >520999_UGT1A1_08 TCATGGCCTCCCTGGCAGAAAGCAGCTTTGATGTCATGCTGACGGACCCTTTCCTTCCTTGCAGCCCCATCGTGGCCCAGTACCTGTCTCTGCCCACTGTATTCTTCTTGCATGCACTGCCATGCA >520999_UGT1A1_09 ACTGCCATGCAGCCTGGAATTTGAGGCTACCCAGTGCCCCAACCCATTCTCCTACGTGCCCAGGCCTCTCTCCTCTCATTCAGATCACATGACCTTCCTGCAGCGGGTGAAGAA >520999_UGT1A1_10 GGGTGAAGAACATGCTCATTGCCTTTTCACAGAACTTTCTGTGCGACGTGGTTTATTCCCCGTATGCAACCCTTGCCTCAGAATTCCTTCAGAGAGAGGTGACTGTCCAGGA >520999_UGT1A1_11 TTCAGAGAGAGGTGACTGTCCAGGACCTATTGAGCTCTGCATCTGTCTGGCTGTTTAGAAGTGACTTTGTGAAGGATTACCCTAGGCCCATCATGCCCAATATGGTTTTTGTT >520999_UGT1A1_12 CCAATATGGTTTTTGTTGGTGGAATCAACTGCCTTCACCAAAATCCACTATCCCAGGTGTGTATTGGAGTGGGACTTTTACATGCGTATATTCTTTCAGATGTATTACTTT

*In the present invention, the method may further include the step of purifying the amplified product, and the purification may be performed by a method commonly used in the art, preferably using beads. can do.

In addition, the present invention provides a composition for amplifying a target site from DNA of a sample, comprising the primer capable of amplifying the target site of a cancer gene or an anticancer drug metabolism-related gene.

The composition may further include components commonly used to amplify DNA with the primers.

In the present invention, the cancer gene or anticancer drug metabolism-related gene may be one or more types selected from the genes listed in Table 1 above.

In the present invention, the target site may be one or more types selected from the target sites listed in Table 1 above.

In the present invention, the primer may be selected from the primers of SEQ ID NOs: 1 to 96 listed in Table 2.

The present invention also provides a diagnostic panel for genetic mutations related to cancer genes and anticancer drug metabolism, comprising the composition, adapter, and barcode primer.

The adapter functions to bind to the barcode and may be composed of 10 to 20 arbitrary nucleic acids.

The barcode primer serves to assign a barcode to a single-stranded DNA fragment of the DNA to be analyzed, and may consist of 4 to 30 arbitrary nucleic acids.

In the present invention, the diagnostic panel may further include components necessary for attachment of the adapter and components necessary for amplifying the sequence with a barcode primer.

In the present invention, detecting genetic mutations by analyzing the sequence of the final product and comparing it with the sequence of the amplicon for the target region can be performed by a method used in a typical next-generation sequencing method.

For example, through mapping, which compares the sequence reads of the target sample with the reference genome, the differences between the target sample and the reference sequence are identified and appropriate selection criteria are determined to determine the reliability. Only identifiable nucleotide sequence variation information is extracted (Variant Calling). Then, the nucleotide sequence mutation information is compared with the existing database (dbSNP) to determine whether it is an already known mutation or a newly discovered mutation. Then, it is predicted whether the mutation will result in a change in the amino acid and what effect it will have on the protein structure. This process is called annotation. Information on extracted mutations can be registered in a database to further improve the quality of information, or research can be conducted to find disease-causing mutations through genome wild association study (GWAS) and integrated research.

The method for detecting and diagnosing mutations in the genomic DNA of cancer cells and mutations in drug response genes of the present invention can detect various genetic mutations in major cancer-related genes and drug metabolism genes through a single experiment, so that each genome It is very economical and efficient than conventional methods that use different platforms for each variant. In addition, by securing high resolution by sequencing key genes related to cancer induction, progression, and drug metabolism with high coverage, it is possible to identify low-frequency genomic mutations that were not detected by existing methods. Therefore, using the method of the present invention, various genetic mutations can be analyzed simultaneously with high sensitivity and accuracy in samples containing mutations in the genomic DNA of cancer cells and genetic mutations that predict drug response, and based on these analysis results, the patient Customized cancer treatments can be searched efficiently.

Hereinafter, the present invention will be described in more detail through examples. The following examples are merely for illustrating the present invention in more detail, and it will be apparent to those skilled in the art that the scope of the present invention is not limited to these examples.

<Example 1>

Preparation of primers and amplicons

Forward and reverse primers and amplicons for amplifying the prevalent cancer genes in Koreans shown in Table 1 above were produced by requesting Bioo Scientific.USA, and the primer name and primer sequence for each gene, and the amplicon name and amplicon sequence. are shown in Tables 2 and 3 above, respectively.

<Example 2>

Mutation detection from samples

Gene mutations were detected from cancer cell line DNA and FFPE DNA with known mutations using the panel developed in the steps shown in Figure 1.

Step 1: Target gene amplification

To analyze mutations in HCT15, HCT116, HT29, A549, SW480, LA174T, MCF7, PC3 cancer cell line DNA samples and 4 FFPE DNA, each was divided into two parts and a master mix was created to conduct the experiment.

1) Reactions 1 to 4

The concentration was adjusted so that 10 to 50 ng of FFPE (Formalin-fixed, paraffin-embedded) DNA could be contained in 20.4 μL of nuclease free water. Specifically, the composition of the reagents for reactions 1 to 4 is shown in Table 4 below, and each sample was prepared and dispensed into each well of a 96-well PCR plate.

ingredient volume FFPE DNA 10-50 ng/20.4μL Nuclease-free Water 20.4μL NEXTflex® BRCA Plus Amplicon FFPE Primer Mix 1, 2, 3 or 4 2.4 μL NEXTflex® Hot Start PCR I Master Mix 7.2 μL total volume 30 μL

After sufficiently mixing the reagents of the above composition with a pipette, PCR was performed using a thermocycler under the PCR conditions shown in Table 5 below.

1) 98℃, 2 minutes 1 cycle 2) 95℃, 20 seconds 21 cycle 3) 62℃, 4 minutes 4) 4℃ maintain

2) Reactions 5 to 8: The concentration was adjusted so that 10 to 50 ng of FFPE DNA could be contained in 15.6 μL of nuclease-free water. Specifically, the composition of the reagents for reactions 5 to 8 is shown in Table 6 below, and each sample was prepared and dispensed into each well of a 96-well PCR plate.

ingredient volume FFPE DNA 10-50 ng/15.6μL Nuclease-free Water 15.6μL NEXTflex® BRCA Plus Amplicon FFPE Primer Mix 5, 6, 7 or 8 2.4 μL NEXTflex® PCR Enhancer 1 0.6 μL NEXTflex® PCR Enhancer 2 1.8 μL NEXTflex® Hot Start PCR I Master Mix 7.2 μL total volume 30 μL

After sufficiently mixing the reagents of the above composition with a pipette, PCR was performed using a gene amplifier under the PCR conditions shown in Table 7 below.

1) 98℃, 2 minutes 1 cycle 2) 98℃, 30 seconds 2 cycle 3) 70℃, 4 minutes 4) 98℃, 30 seconds 4 cycles 5) 68℃, 4 minutes 6) 98℃, 30 seconds 4 cycles 7) 66℃, 4 minutes 8) 98℃, 30 seconds 4 cycles 9) 64℃, 4 minutes 10) 98℃, 30 seconds 8 cycles 11) 62℃, 4 minutes 12) 4℃ maintain

Step 2: To stop the PCR product purification reaction, 1 μL of NEXTflex® Stop Solution was dispensed into each of the eight products obtained in Step 1 and reacted for 30 seconds. In the above half, the products of reactions 1 to 4 were mixed in one well to make set 1, and the products of reactions 5 to 8 were mixed in one well to make set 2.

16 μL from Set 1 and 64 μL from Set 2 were each extracted and mixed in a new well. 48 μL of NEXTflex® Cleanup Beads were added and mixed, and then reacted for 5 minutes on a magnetic stand at room temperature. The supernatant was visible to the naked eye. If it was not sufficiently separated, the reaction was allowed until the supernatant became transparent. The clear supernatant was transferred to a new well, 72 μL of NEXTflex® Cleanup Beads were added, mixing and reaction were repeated to obtain a clear supernatant. The supernatant was removed, and 200 μL of 80% ethanol was slowly dispensed into the remaining beads. The reaction was repeated twice at room temperature for 30 seconds, and the ethanol was completely removed.

30 μL of resuspension buffer was added and mixed, reacted at room temperature for 3 minutes, and then reacted on a magnetic stand for 5 minutes to completely separate the supernatant. 28 μL of the separated supernatant was transferred to a new well, and this solution was named purified PCR I Reaction.

Step 3: Adapter ligation

The reaction product obtained in step 2 was mixed on ice with the ingredients and composition shown in Table 8 below, and a nuclease-free 96-well PCR plate was used.

ingredient volume Purified PCR I reaction 28 μL NEXTflex® Amplicon DNA Adapter 2.5 μL NEXTflex® Ligation Mix 42 μL total volume 72.5 μL

The PCR plate was completely sealed and reacted in a gene amplifier at 22°C for 15 minutes.

Step 4: Purification of adapter attachment product

58 μL of NEXTflex® Cleanup Beads was dispensed and mixed into the mixture of step 3, reacted at room temperature for 5 minutes, and further reacted at room temperature for 5 minutes on a magnetic stand to obtain a transparent supernatant.

Afterwards, the beads were washed with ethanol as in step 2 above, and resuspension buffer was added to the washed beads and reacted to obtain a clear supernatant (purified adapter-attached DNA). Samples not used in the next step were stored at -20°C.

Step 5: Final product amplification

38 μL of the supernatant obtained in step 4 was dispensed into a new well and mixed on ice with the ingredients and composition shown in Table 9 below, including barcode primers, and a nuclease-free 96-well PCR plate was used.

ingredient volume Purified adapter-attached DNA 38 μL NEXTflex® PCR II Barcoded Primer Mix 2 μL NEXTflex® PCR II Master Mix 10 μL total volume 50 μL

After sealing the PCR plate, PCR was performed using a gene amplifier under the PCR conditions shown in Table 10 below.

(1) 65℃, 20 minutes 1 cycle (2) 98℃, 2 minutes 1 cycle (3) 98℃, 30 seconds 14 cycles (4) 65℃, 30 seconds (5) 72℃, 60 seconds (6) 72℃, 4 minutes 1 cycle (7) 4℃ maintain

After PCR was completed, beads were added and purification was performed as in step 2 above to obtain the final product.

Step 6: Measure the concentration of the final product and run the Miseq NGS instrument.

The concentration of the final product was measured using a bioanalyzer, and if the minimum concentration was 20 ng/ul or more, next-generation sequencing (NGS) was performed using Miseq NGS equipment. If the minimum concentration was 20 ng/ul or less. , steps 1 to 5 were repeated.

The Miseq NGS equipment was operated according to the Miseq NGS equipment manual, and the results were analyzed according to the minifest file and the results were obtained as Bam and Vcf files (file name: NOVA-520999_ BRCA1-2_TP53_ Plus_FFPE_Manifest_v1.txt (Figure 2)

<Example 3>

Data analysis of NGS cancer-prone panel analysis results

The data obtained in Example 2 was analyzed using Illumina VariantStudio, a commercial data analysis software.

Specifically, access Illumina VariantStudio and upload the VCF file obtained in Example 2 above, remove it with a variant pass filter, and then set Qulity: 99, Read Death: Cancer Gene 4000 or more, and Drug Gene 2000 or more (Figure 3 ), gene mutation information was confirmed by linking information through gene annotation & classification (Figure 4).

As a result, it was confirmed that KRAS NM_033360.2:c.34G>A, NP_203524.1:p.Gly12Ser mutations were accurately detected in the A549 lung cancer cell line.

<Example 4>

NGS data comparison

The performance of the development panel was confirmed by comparing the data obtained in Example 3 with the data obtained through commercially available Illumina Tumour 15 and Sanger sequencing, and the results are shown in Table 11.

Test Sample AKT1 BRAF EGFR ERBB2 FOXL2 KIT development panel HCT15 N.D. N.D. N.D. N.D. N.D. N.D. HCT116 N.D. N.D. N.D. N.D. N.D. N.D. H1975 N.D. N.D. T790M hetro
L858R hetro N.D. N.D. N.D. HT29 N.D. V600E,hetero N.D. N.D. N.D. N.D. A549 N.D. N.D. N.D. N.D. N.D. N.D. SW480 N.D. N.D. N.D. N.D. N.D. N.D. lIlumina tumor 15 panal & Sanger Sequencingl HCT15 N.D. N.D. N.D. N.D. N.D. N.D. HCT116 N.D. N.D. N.D. N.D. N.D. N.D. H1975 N.D. N.D. T790M hetro
L858R hetro N.D. N.D. N.D. HT29 N.D. V600E, hetro N.D. N.D. N.D. N.D. A549 N.D. N.D. N.D. N.D. N.D. N.D. SW480 N.D. N.D. N.D. N.D. N.D. N.D. Test Sample KRAS MET NRAS PDGFRA PIK3CA RET Development
panel HCT15 G13D hetro N.D. N.D. N.D. N.D. N.D. HCT116 G13D homo
N.D. N.D. N.D. N.D. N.D. H1975 N.D. N.D. N.D. P567S hetero N.D. N.D. HT29 N.D. N.D. N.D. N.D. N.D. N.D. A549 G12S homo N.D. N.D. N.D. N.D. N.D. SW480 G12V homo N.D. N.D. N.D. N.D. N.D. lIlumina tumor 15 panal &Sanger Sequencingl HCT15 G13D hetro N.D. N.D. N.D. N.D. N.D. HCT116 G13D homo N.D. N.D. N.D. N.D. N.D. H1975 N.D. N.D. N.D. P567S hetero N.D. N.D. HT29 N.D. N.D. N.D. N.D. N.D. N.D. A549 G12S homo N.D. N.D. N.D. N.D. N.D. SW480 G12V homo
N.D. N.D. N.D. N.D. N.D. Test Sample TP53 UGT1A1 CYP2D6 TPMT MTHFR DPYD Development
panel HCT15 S241F *1/*1 *1/*1 *1/*1 1298A/C V815E HCT116 N.D. *1/*1 *1/*10B *1/*1 677C/T *1/*1 H1975 N.D. *1/*1 *1/*11B *1/*1 N.D. *1/1 HT29 R273H *1/*1 *1/*1 *1/*1 677C/T
1298A/C *1/*9 A549 N.D. *1/*1 *10B/*10B *1/*1 1298C/C *1/*1 SW480 R273H
P309S *1/*1 *1/*1 *1/*1 N.D. *1/1 lIlumina tumor 15 panal & Sanger Sequencingl HCT15 S241F *1/*1 *1/*1 *1/*1 1298A/C V815E HCT116 N.D. *1/*1 *1/*10B *1/*1 677C/T *1/*1 H1975 N.D. *1/*1 *1/*10B *1/*1 N.D. *1/1 HT29 R273H *1/*1 *1/*1 *1/*1 677C/T
1298A/C *1/*9 A549 N.D. *1/*1 *10B/*10B *1/*1 1298C/C *1/*1 SW480 R273H
P309S *1/*1 *1/*1 *1/*1 N.D. *1/1

As a result, it can be seen that they match with 100% accuracy.

So far, the present invention has been examined focusing on its preferred embodiments. A person skilled in the art to which the present invention pertains will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered from an illustrative rather than a restrictive perspective. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the equivalent scope should be construed as being included in the present invention.

<110> SPMED Co.,Ltd. <120> NEXT GENERATION SEQUENCING (NGS)-BASED HYBRID DIAGNOSTIC PANEL FOR ANALYZING VARIATION OF CANCER GENE AND ANTICANCER DRUG-RELATED GENE <130> DPP170184KR <160> 128 <170> KoPatentIn 3.0 <210> 1 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_01_FOR <400> 1 gggcacagga tggggaagtc acagc 25 <210> 2 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_01 _REV <400> 2 cgggagaacc aaaccggaat ggtcac 26 <210> 3 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_02_FOR <400> 3 gaaccagggt ccccactcca gcatc 25 <210> 4 <211> 28 < 212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_02_REV <400> 4 tggggagctg aaggactact acctcttc 28 <210> 5 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_03_ FOR <400> 5 acatcttcag cagctcctcc ttggg 25 <210> 6 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_03_REV <400> 6 tacaggaatg gcctcctggg catgtg 26 <210> 7 <211> 27 <2 12> DNA < 213> Artificial Sequence <220> <223> >520999_MTHFR_04_FOR <400> 7 tcagcgaact cagcactcca cccagag 27 <210> 8 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_04_RE V <400> 8 cttccgcttt gtgaaggcat GCACCGA 27 <210> 9 <211> 24 <212> DNA <213> Artificial sequence <220> <223> 520999_MTHFR_05_FOR <400> 9 gagggagct ATGGCTC CTGG 24 <210> 10 <211> 29 <212> DNA <213 > Artificial Sequence <220> <223> >520999_MTHFR_05_REV <400> 10 ctgaagcact tgaaggagaa ggtgtctgc 29 <210> 11 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_06 _FOR <400> 11 atgtgtcagc ctcaaagaaa agctgc 26 <210> 12 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_06_REV <400> 12 ctctcctgac tgtcatccct attggcag 28 <210> 13 <211> 27 <212> DNA <21 3> Artificial Sequence <220> <223> >520999_MTHFR_07_FOR <400> 13 ttcaagtgct tcaggtcagc ctcaaag 27 <210> 14 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_MTHFR_07_RE V <400> 14 tggtctcttc atccctcgcc ttgaaca 27 <210> 15 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_01_FOR <400> 15 gggcaattcc tcaaaaacat gtcagtgtg 29 <210> 16 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_01_REV <400> 16 gcaatatacg ttgtcttgag aaggttgatg c 31 <210> 17 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_02_FOR <400> 17 gcttttcaaa aagacagtca attccccaac 30 <210> 18 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_02_REV <400> 18 gggagaatcc ctgatgtcat tcttcatag 29 <210> 19 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_03_FOR <400> 19 gggatcaaga aactaggcaa ctggtaaaag 30 <210> 20 <211> 32 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_03_REV <400> 20 ccttcttgtg ttctttgtag ctatgcagat ac 32 <210> 21 <211> 33 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_04_FOR <400> 21 gttggatcat aagaaagaac acacaggaga tac 33 <210> 22 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_04_REV <400> 22 cagcgaaagt aacttctggc ttccttcc 28 <210> 23 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_05_FOR < 400> 23 gggaagtcta agctgatttt ctagaaccca g 31 <210> 24 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_05_REV <400> 24 gggcaaattt gacatgattt gggatagagg 30 <210> 25 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_06_FOR <400> 25 gggttactta ccattgcga tcacctgg 28 <210> 26 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_06_REV <40 0> 26 gattgttgaa gtaccagcat gcaccatg 28 <210> 27 <211> 33 <212> DNA <213> Artificial sequence <220> <223> 520999_tpmt_07_for <400> 27 GGCTGAGAAA AactTTGTGTGAC 33 <210> 28 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_07_REV <400> 28 gtgtagttgg tgtggaaatc agtgaacttg g 31 <210> 29 <211> 32 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_08_ FOR <400> 29 gggttcttct gagtaagaaa gattctgctc tg 32 <210> 30 <211> 36 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_08_REV <400> 30 gagggtgctt actctaatat aaccctctat ttagtc 36 <210> 31 <211> 34 <212 > DNA < 213> Artificial Sequence <220> <223> >520999_KRAS_01_FOR <400> 31 ggggacataa cagttatgat tttgcagaaa acag 34 <210> 32 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS _01_REV <400> 32 gccttctaga acagtagaca caaaacaggc 30 <210> 33 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_02_FOR <400> 33 ggcttacctg tcttgtcttt gctgatgttt c 31 <210> 3 4 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_02_REV <400> 34 gttaaggact ctgaagatgt acctatggtc c 31 <210> 35 <211> 33 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_03_FOR <400> 35 gttttgtgtc tactgttcta gaaggcaaat cac 33 <21 0> 36 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_03_REV <400> 36 gggacaaaag ttgtggacag gttttgaaag 30 <210> 37 <211> 32 <212> DNA <213> Artificial Sequence <220> <223> >520999_K RAS_04_FOR <400> 37 ccagaggact ataattactc cttaatgtca gc 32 <210> 38 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_04_REV <400> 38 gagtacagtg caatgaggga ccagtac 27 <210> 39 <211 > 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_05_FOR <400> 39 ggcaaataca caaagaaagc cctccc 26 <210> 40 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_05_ REV <400> 40 gggtgcactg taataatcca gactgtg 27 <210> 41 <211> 31 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_06_FOR <400> 41 cctttatctg tatcaaagaa tggtcctgca c 31 <210> 42 < 211> 33 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_06_REV <400> 42 gactgaatat aaacttgtgg tagttggagc tgg 33 <210> 43 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS _07_FOR <400 > 43 ctgaattagc tgtatcgtca aggcactc 28 <210> 44 <211> 30 <212> DNA <213> Artificial Sequence <220> <223> >520999_KRAS_07_REV <400> 44 gggaaggtac tggtggagta tttgatagtg 30 <210> 45 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_01_FOR <400> 45 gtacattaga gcctctggct agggagcag 29 <210> 46 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP 2D6_01_REV <400> 46 acttcagctt ctcggtgccc actgg 25 <210> 47 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_02_FOR <400> 47 gctcaccagg aaagcaaaga caccatgg 28 <210> 48 <211 > 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_02_REV <400> 48 gtatcaccca ggagccaggc tcactgac 28 <210> 49 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP 2D6_03_FOR <400> 49 gcaagactcc acggaagggg acagg 25 <210> 50 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_03_REV <400> 50 gctgaaggat gaggccgtct gggag 25 <210> 51 <211> 26 < 212> DNA < 213> Artificial Sequence <220> <223> >520999_CYP2D6_04_FOR <400> 51 catccaggaa gtgttcgggg tggaag 26 <210> 52 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2 D6_04_REV <400> 52 ccagcatcct agagtccagt ccccac 26 <210> 53 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_05_FOR <400> 53 ctatcaccag gtgctggtgc tgagctg 27 <210> 54 <211> 28 <212> DNA <213 > Artificial Sequence <220> <223> >520999_CYP2D6_05_REV <400> 54 atgccctaca ccactgccgt gattcatg 28 <210> 55 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_0 6_FOR <400> 55 tcatatgggt cacacccagg gggacg 26 <210> 56 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_06_REV <400> 56 gtgaggacgc atgtctgtcc aggcc 25 <210> 57 <211> 28 <212> DNA <21 3> Artificial Sequence <220> <223> >520999_CYP2D6_07_FOR <400> 57 acctcatgaa tcacggcagt ggtgtagg 28 <210> 58 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_ 07_REV <400> 58 gcaagaagga gtgtcagggc cggac 25 <210> 59 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_08_FOR <400> 59 cacgggtgtc ccagcaaagt tcatgg 26 <210> 60 <211> 26 <212> DNA <213> Art ificial Sequence <220> <223> >520999_CYP2D6_08_REV <400> 60 ctgacaggat ggtgaccacc tcgacc 26 <210> 61 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_09_FOR < 400> 61 gatgagctca cgctgcacat ccggatg 27 <210> 62 <211> 27 <212> DNA <213> Artificial sequence <220> <223>> 520999_cyp2d6_09_REV <400> 62 CTCAGACATG CTCAGGCAA GGGAAC 27 <210> 63 <211> 25 <212> DNA <213> Artificial sequence <220> <223> >520999_CYP2D6_10_FOR <400> 63 ccatcccggc agagaacagg tcagc 25 <210> 64 <211> 27 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_10_REV <400 > 64 ctaccccgtt ctgtcccgag tatgctc 27 < 210> 65 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_11_FOR <400> 65 gactaccctc attcctcctg ggacgctc 28 <210> 66 <211> 30 <212> DNA <213> Artificial Sequence < 220> <223> >520999_CYP2D6_11_REV <400> 66 gatgagctgc taactgagca caggatgacc 30 <210> 67 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_12_FOR <40 0> 67 cagccactct caccttctcc atctctgc 28 <210 > 68 <211> 28 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_12_REV <400> 68 gaatgctgtc cccgtcctcc tgcatatc 28 <210> 69 <211> 29 <212> DNA <213> Artificial Sequence <220 > <223> >520999_CYP2D6_13_FOR <400> 69 gaaagccttt tggaagcgta ggaccttgc 29 <210> 70 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_13_REV <4 00> 70 gagatggctg gggcctgaga cttgtc 26 <210> 71 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_14_FOR <400> 71 ctgcagagac tcctcggtct ctcgc 25 <210> 72 <211> 26 <212> DNA <213> Artificial Sequence <2 20> <223> >520999_CYP2D6_14_REV <400> 72 gaagaccctt tcgccccaac ggtctc 26 <210> 73 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_15_FOR <400> 7 3 gaagcgaggg tcgtcgtact cgaagc 26 <210> 74 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_15_REV <400> 74 ggaagacaga ggacggggaa ggcgac 26 <210> 75 <211> 29 <212> DNA <213> Artificial Sequence <220> < 223> >520999_CYP2D6_16_FOR <400> 75 gagagatgag agtaaggggt cgccttccc 29 <210> 76 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_16_REV <400> 76 gactgggcaa gaagtcgctg gagcag 26 <210> 77 < 211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_17_FOR <400> 77 ctgaccatca cccaccggag tggttg 26 <210> 78 <211> 25 <212> DNA <213> Artificial Sequence <220> <2 23 > >520999_CYP2D6_17_REV <400> 78 cacacacaca ggggtgttcc tggcg 25 <210> 79 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_18_FOR <400> 79 cacagacc ca agttgcgcaa ggtgg 25 <210> 80 <211 > 26 <212> DNA <213> Artificial sequence <220> <223>> 520999_Cyp2d6_18_REV <400> 80 GTGGTGGTGGTGGGGGGG 26 <210> 81 <211> 26 <212> DNA <213> FICIAL SEQUENCE <220> <223> >520999_CYP2D6_19_FOR <400> 81 ccgggtccca cggaaatctg tctctg 26 <210> 82 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_19_REV <400> 82 gacagtgg tc gtgctcaatg ggctg 25 <210> 83 <211> 25 <212> DNA <213> Artificial sequence <220> <223>> 520999_Cyp2d6_20_for <400> 83 CAACAGCTGCTGGGG AACGC 25 <210> 84 <211> 25 <212> DNA <213> FICIAL SEQUENCE <220> <223>> 520999_CYP2D6_20_REV <400> 84 cttcggggac gtgttcagcc tgcag 25 <210> 85 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_21_FOR <400> 85 cacatt gagc acgaccaccg gcgtc 25 <210> 86 <211> 33 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_21_REV <400> 86 ggttcaaata ggactaggac ctgtagtctg ggg 33 <210> 87 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> > 520999_CYP2D6_22_FOR <400> 87 gcttctggtc cagcctgtgg tttcac 26 <210> 88 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_22_REV <400> 88 gcaac ctgct gcatgtggac ttccag 26 <210> 89 <211> 26 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_23_FOR <400> 89 gacctcctcc ctcacctggt cgaagc 26 <210> 90 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >5209 99_CYP2D6_23_REV <400> 90 gccatcttcc tgctcctggt ggacc 25 <210> 91 <211> 25 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_24_FOR <400> 91 gatagagtgc agcccagcgt tggcg 25 <21 0> 92 <211> 27 < 212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_24_REV <400> 92 ccaggtgtgt ccagaggagc ccatttg 27 <210> 93 <211> 29 <212> DNA <213> Artificial Sequence <220> <223> >52 0999_BRAF_01_FOR < 400> 93 ctttctagta actcagcagc atctcaggg 29 <210> 94 <211> 32 <212> DNA <213> Artificial Sequence <220> <223> >520999_BRAF_01_REV <400> 94 ggtgattttg gtctagctac agtgaaatct cg 32 <210> 95 <211> 28 < 212> DNA <213> Artificial Sequence <220> <223> >520999_BRAF_02_FOR <400> 95 ggatccagac aactgttcaa actgatgg 28 <210> 96 <211> 33 <212> DNA <213> Artificial Sequence <220> <223> >520999_ BRAF_02_REV < 400> 96 gcctaaactc ttcataatgc ttgctctgat agg 33 <210> 97 <211> 104 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_01 <400> 97 gctggggact aggtacccca ttctagcggg gcacag caca aagctcatag ggggatgggg 60 tcaccaggaa agcaaagaca ccatggtggc tgggccgggg ctgt 104 <210> 98 <211> 134 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_02 <400> 98 tggctgggcc ggggctgtcc agtgggcacc gagaagctga agtgctgcag cagggaggtg 60 aagaagagga agagctccat g cgggccagg ggctccccga ggcatgcacg gcggcctgtg 120 gggaggggag gggc 134 <210> 99 <211> 107 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_03 <400> 99 gagccgggct ccccacaggc acctgctgag aaaggcagga aggcctccgg cttcacaaag 60 tggccctggg catccaggaa gtgttcgggg tgga agcgga agggctt 107 <210> 100 <211> 92 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_04 <400> 100 cggaagggct tctcccagac ggcctcatcc ttcagcaccg atgacaggtt ggtgatgagt 60 gtcgttccct gggcagaaga tgcagggtga ga 92 <210> 101 <211> 113 <212> DNA <213> Artificial Sequence <220> < 223> >520999_CYP2D6_05 <400> 101 gggtgaggag ggcgccaggc ctaccttagg gatgcggaag ccctgtactt cgatgtcacg 60 ggatgtcata tgggtcacac ccagggggac gatgtcccca aagcgctgca cct 113 <210> 102 <211> 118 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_06 <400> 102 atgtccccaa agcgctgcac ctcatgaatc acggcagtgg tgtagggcat gtgagcctgg 60 tcacccatct ctggtcgccg cacctgccct atcacgtcgt cgatctcctg ttggacac 118 <210> 103 <211> 117 <212> DNA <213> Artificial S equence <220> <223> >520999_CYP2D6_07 <400> 103 gcatgtgagc ctggtcaccc atctctggtc gccgcacctg ccctatcacg tcgtcgatct 60 cctgttggac acggcctgga cagacatgcg tccccacaat gggtcagcac ccagggg 117 <210> 104 <211> 106 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_08 <400> 104 gcccccgcct gtacccttcc tccctcggcc cctgcactgt ttcccagatg ggctcacgct 60 gcacatccgg atgtaggatc atgagcagga ggccccaggc cagcgt 106 <210> 105 <211> 114 <212> DNA <213> Artificial Sequence <220> <223> > 520999_CYP2D6_09 <400> 105 taggatcatg agcaggaggc cccaggccag cgtggtcgag gtggtcacca tcccggcaga 60 gaacaggtca gccaccacta tgcacaggtt ctcatcattg aagctgctct cagg 114 <210> 106 <211> 68 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_10 <400> 106 caccactatg cacaggttct catcattgaa gctgctctca g ggttcccct tggcctgagc 60 agggccga 68 <210> 107 <211 > 101 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_11 <400> 107 aacccaccac ccttgccccc caccgtggca gccactctca ccttctccat ctctgccagg 60 aaggcctcag tcaggtctcg ggggggctgg gctgggtcc c a 101 <210> 108 <211> 129 <212> DNA <213 > Artificial Sequence <220> <223> >520999_CYP2D6_12 <400> 108 caggaaggcc tcagtcaggt ctcggggggg ctgggctggg tcccaggtca tcctgtgctc 60 agttagcagc tcatccagct gggtcaggaa agccttttgg aagcgtagga ccttgcc agc 120 cagcgctgg 129 <210> 109 <211> 98 <212> DNA <213> Artificial Sequence <220 > <223> >520999_CYP2D6_13 <400> 109 cagccagcgc tgggatatgc aggaggacgg ggacagcatt cagcacctac accagacaga 60 acggggtctc aatccctcct gtgctctgcg ttcacctg 98 <210> 110 <211> 142 <21 2> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_14 <400> 110 tccgcacctc gcgcagaaag cccgactcct ccttcagtcc ctcctgagct aggtccagca 60 gcctgaggaa gcgagggtcg tcgtactcga agcggcgccc gcaggtgagg gaggcgatca 120 cgttgctcac ggctttgtcc aa 142 <210> 11 1 <211> 101 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_15 <400> 111 ggcgcccgca ggtgagggag gcgatcacgt tgctcacggc tttgtccaag agaccgttgg 60 ggcgaaaggg gcgtcctggg ggtgggagat gcgggtaagg g 101 <210> 112 <211> 103 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP 2D6_16 <400> 112 cgtcccccgc cttcccagtt cccgctttgt gcccttctgc ccatcaccca ccggagtggt 60 tggcgaaggc ggcacaaagg caggcggcct cctcggtcac cca 103 <210> 113 <211> 128 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_17 <400> 113 gcgaaggcgg cacaaaggca ggcggcctcc tcggtcaccc actgctccag cgacttcttg 60 cccaggccca agttg cgcaa ggtggagacg gagaagcgcc tctgctcgcg ccacgcgggc 120 ccatagcg 128 <210> 114 < 211> 95 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_18 <400> 114 agacggagaa gcgcctctgc tcgcgccacg cgggcccata gcgcgccagg aacacccctg 60 ggggtgggac gggcacgtgc gcg tggccat gaagg 95 <210> 115 <211> 117 <212> DNA <213 > Artificial Sequence <220> <223> >520999_CYP2D6_19 <400> 115 tccccaccgc tgcttgcctt gggaacgcgg cccgaaaccc aggatctggg tgatgggcac 60 aggcgggcgg tcggcggtgt cctcgccgtg ggtcaccagc gcctcgc gca cggccgc 117 <210> 116 <211> 125 <212> DNA <213> Artificial Sequence <220> < 223> >520999_CYP2D6_20 <400> 116 ggcccgaaac ccaggatctg ggtgatgggc acaggcgggc ggtcggcggt gtcctcgccg 60 tgggtcacca gcgcctcgcg cacggccgcc agcccattga gcacgaccac cggcgtccag 120 g ccag 125 <210> 117 <211> 85 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_21 < 400> 117 caggccagct gcaggctgaa cacgtccccg aagcggcgcc gcaactgcag agggagggtc 60 agggcctctt gtcaagccag gatcc 85 <210> 118 <211> 95 <212> DNA <213> Artificial Sequence <220> <223> >520999_CY P2D6_22 <400> 118 ccaccaccca tgtttgctgg tggtggggca tcctcaggac ctctgccgcc ctccaggacc 60 tcctccctca cctggtcgaa gcagtatggt gtgtt 95 <210> 119 <211> 105 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_23 <400> 119 agtatggtgt gttctggaag tccacatgca gcagg ttgcc cagcccgggc agtggcaggg 60 ggcctggtgg gtagcgtgca gcccagcgtt ggcgccggtg catca 105 <210> 120 <211> 89 <212> DNA <213> Artificial Sequence <220> <223> >520999_CYP2D6_24 <400> 120 ccggtgcatc aggtccacca ggagcaggaa gatggccact atcacggcca ggggcaccag 60 tgcttctagc cccatacctg cctcactac 8 9 <210> 121 <211> 96 <212> DNA < 213> Artificial Sequence <220> <223> >520999_TPMT_01 <400> 121 attttatttt atctatgtct catttacttt tctgtaagta gatataactt ttcaaaaaga 60 cagtcaattc cccaactttt atgtcgttct tcaaaa 96 <210> 122 <211 > 91 <212> DNA <213> Artificial Sequence <220> <223 > >520999_TPMT_02 <400> 122 ttttatgtcg ttcttcaaaa gcatcaacct tctcaagaca acgtatattg catattttac 60 ctgaaacaag aaagagtaac atgttaaaat a 91 <210> 123 <211> 100 <212> DNA <213> Artificial Sequence <220 > <223> >520999_TPMT_03 <400> 123 aaaaaaaaaaa aacccaaacaa ctttacctgg atgtttagtt ggatcataag aaagaacaca 60 caggagatac tgaaacttct ttcccaggag ggaaaacatt 100 <210> 124 <211> 112 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_04 <400> 124 tga aacttct ttcccaggag ggaaaacatt gtatctgcat agctacaaag aacacaagaa 60 ggtatttgtt acatttctct acacaggcaa aggctggagg gacaaaaggc ag 112 <210> 125 <211> 95 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_05 <400> 125 aaaaagtata gtatactaaa aaattaagac agctaaacaa aaaaagaaaa attacttacc 60 atttgcga tc acctggattg atggcaacta atgct 95 <210> 126 <211 > 126 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_06 <400> 126 attgatggca actaatgctc ctctatccca aatcatgtca aatttgccaa tatttgtcct 60 accagaaaga gaaaaaaacat tttatgggag aaaaatcaaa tctttaagaa gatgagcagc 120 gtcccc 126 <210> 127 <211> 108 <212> DNA <213> Artificial Sequence <220> <223> >520999_TPMT_07 <400> 127 aattatttac ccaaatcaaa acaaacctta aatactttgg ttccaggaat ttcggtgatt 60 ggttcttctg agtaagaaag attctgctct gtaaaaaatt cttgtatc 108 <210 > 128 <211> 111 <212> DNA <213> Artificial Sequence <220 > <223> >520999_TPMT_08 <400> 128 taaaaaattc ttgtatccca agttcactga tttccacacc aactacactg tgtccccggt 60ctgcaaacct gcataaaatc atacatttac acttaaatta tgttttcaaa t 111

Claims (8)

Amplifying a target site from the DNA of a sample using primers capable of amplifying the target site of a gene selected from the group consisting of ERBB2, FOXL2, UGT1A1, CYP2D6, and DPYD;
Attaching an adapter to the amplified product;
Preparing a final product by amplifying the product to which the adapter is attached; and
Analyzing the sequence of the final product and detecting genetic mutations by comparing it with the sequence of the amplicon for the target site
A next-generation sequencing (NGS) method for analyzing genetic mutations related to cancer genes and anticancer drug metabolism, comprising: According to paragraph 1,
The method, wherein the target site comprises A775_G776YVMA (ERBB2) or C123W (FOXL2). According to paragraph 1,
The method is characterized in that the primer is selected from the primers of SEQ ID NOs: 1 to 96. According to paragraph 1,
The method, characterized in that the amplicon is selected from the sequences of SEQ ID NOs: 97 to 128. According to paragraph 1,
Characterized in that it further comprises the step of purifying the amplified product. A composition for amplifying a target site from DNA of a sample, comprising primers capable of amplifying a target site of a gene selected from the group consisting of ERBB2, FOXL2, UGT1A1, CYP2D6, and DPYD. In clause 7,
A composition characterized in that the target site includes A775_G776YVMA (ERBB2) or C123W (FOXL2). In clause 7,
A composition, characterized in that the primer is selected from the primers of SEQ ID NOs: 1 to 96.