Detection of somatic mutations and HPV in the saliva and plasma of patients with head and neck squamous cell carcinomas

Wang, Yuxuan; Springer, Simeon; Mulvey, Carolyn L.; Silliman, Natalie; Schaefer, Joy; Sausen, Mark; James, Nathan T.; Rettig, Eleni M.; Guo, Theresa; Pickering, Curtis R.; Bishop, Justin A.; Chung, Christine H.; Califano, Joseph A.; Eisele, David W.; Fakhry, Carole; Gourin, Christine G.; Ha, Patrick K.; Kang, Hyunseok; Kiess, Ana P.; Koch, Wayne M.; Myers, Jeffrey N.; Quon, Harry; Richmon, Jeremy D.; Sidransky, David; Tufano, Ralph P.; Westra, William H.; Bettegowda, Chetan; Díaz, Luis A.; Papadopoulos, Nickolas; Kinzler, Kenneth W.; Vogelstein, Bert; Agrawal, Nishant

doi:10.1126/scitranslmed.aaa8507

Cited by 383 publications

(385 citation statements)

References 51 publications

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“…The somewhat unexpected source of leukocyte DNA indicates that we have to develop more sensitive assays, especially for transplanted patients. New genetic assays, using next generation sequencing approaches, might improve the applicability of this noninvasive screening tool and might have a higher sensitivity (47). However, it is important to realize that these approaches are still expensive, usually require larger amounts of input DNA and will also be influenced by the presence of leukocyte DNA.…”

Section: Discussionmentioning

confidence: 99%

Noninvasive Molecular Screening for Oral Precancer in Fanconi Anemia Patients

Smetsers

Velleuer

Dietrich³

et al. 2015

Cancer Prevention Research

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LOH at chromosome arms 3p, 9p, 11q, and 17p are wellestablished oncogenetic aberrations in oral precancerous lesions and promising biomarkers to monitor the development of oral cancer. Noninvasive LOH screening of brushed oral cells is a preferable method for precancer detection in patients at increased risk for head and neck squamous cell carcinoma (HNSCC), such as patients with Fanconi anemia. We determined the prevalence of LOH in brushed samples of the oral epithelium of 141 patients with Fanconi anemia and 144 aged subjects, and studied the association between LOH and HNSCC. LOH was present in 14 (9.9%) nontransplanted patients with Fanconi anemia, whereas LOH was not detected in a low-risk group (n ¼ 50, >58 years, nonsmoking/nonalcohol history) and a group with somewhat increased HNSCC risk (n ¼ 94, >58 years, heavy smoking/excessive alcohol use); Fisher exact test, P ¼ 0.023 and P ¼ 0.001, respectively. Most frequent genetic alteration was LOH at 9p. Age was a signif-

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Section: Discussionmentioning

confidence: 99%

Noninvasive Molecular Screening for Oral Precancer in Fanconi Anemia Patients

Smetsers

Velleuer

Dietrich³

et al. 2015

Cancer Prevention Research

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“…Similarly, cfDNA collected from thoracic effusions and malignant ascites might be highly informative: Krimmel and colleagues successfully identified TP53 mutations in cfDNA from peritoneal fluid from patients with high-grade serous ovarian tumors (31), and bronchoalveolar lavage and pleural fluids were successfully used to detect EGFR mutations in advanced NSCLC (32). ctDNA has also been isolated from saliva and urine (33,34). Therefore, analysis from multiple sources could be useful in dissecting interlesion heterogeneity.…”

Section: Reviewmentioning

confidence: 99%

Tumor Evolution as a Therapeutic Target

Amirouchene-Angelozzi

2017

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Recent technological advances in the fi eld of molecular diagnostics (including blood-based tumor genotyping) allow the measurement of clonal evolution in patients with cancer, thus adding a new dimension to precision medicine: time. The translation of this new knowledge into clinical benefi t implies rethinking therapeutic strategies. In essence, it means considering as a target not only individual oncogenes but also the evolving nature of human tumors. Here, we analyze the limitations of targeted therapies and propose approaches for treatment within an evolutionary framework.Signifi cance: Precision cancer medicine relies on the possibility to match, in daily medical practice, detailed genomic profi les of a patient's disease with a portfolio of drugs targeted against tumor-specifi c alterations. Clinical blockade of oncogenes is effective but only transiently; an approach to monitor clonal evolution in patients and develop therapies that also evolve over time may result in improved therapeutic control and survival outcomes. Cancer Discov; 7(8);

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“…Conventional nextgeneration sequencing (NGS) technologies have a high false positive error rate, which precludes reliable detection of mutations at frequencies <1/100 (1). "Molecular tagging" of single-stranded DNA decreases the rate of false mutations to less than 1 per 10,000 sequenced nucleotides and has been successfully applied to the detection of mutant cancer DNA in a variety of clinical samples (2)(3)(4)(5)(6). However, this false positive error rate limits the specificity of this method in challenging situations in which ultra-deep sequencing is needed to detect extremely low frequency mutant molecules (e.g., <1/10,000), as is the case of ovarian cancer DNA in Pap smears (5).…”

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confidence: 99%

Ultra-deep sequencing detects ovarian cancer cells in peritoneal fluid and reveals somatic TP53 mutations in noncancerous tissues

Krimmel

Schmitt

Harrell

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

139

108

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Current sequencing methods are error-prone, which precludes the identification of low frequency mutations for early cancer detection. Duplex sequencing is a sequencing technology that decreases errors by scoring mutations present only in both strands of DNA. Our aim was to determine whether duplex sequencing could detect extremely rare cancer cells present in peritoneal fluid from women with highgrade serous ovarian carcinomas (HGSOCs). These aggressive cancers are typically diagnosed at a late stage and are characterized by TP53 mutations and peritoneal dissemination. We used duplex sequencing to analyze TP53 mutations in 17 peritoneal fluid samples from women with HGSOC and 20 from women without cancer. The tumor TP53 mutation was detected in 94% (16/17) of peritoneal fluid samples from women with HGSOC (frequency as low as 1 mutant per 24,736 normal genomes). Additionally, we detected extremely low frequency TP53 mutations (median mutant fraction 1/13,139) in peritoneal fluid from nearly all patients with and without cancer (35/37). These mutations were mostly deleterious, clustered in hotspots, increased with age, and were more abundant in women with cancer than in controls. The total burden of TP53 mutations in peritoneal fluid distinguished cancers from controls with 82% sensitivity (14/17) and 90% specificity (18/20). Age-associated, low frequency TP53 mutations were also found in 100% of peripheral blood samples from 15 women with and without ovarian cancer (none with hematologic disorder). Our results demonstrate the ability of duplex sequencing to detect rare cancer cells and provide evidence of widespread, low frequency, age-associated somatic TP53 mutation in noncancerous tissue.TP53 mutations | ultra-deep sequencing | ovarian cancer | clonal hematopoiesis | premalignant mutations T he detection of tumor-specific mutations in clinically accessible samples has enormous potential to transform cancer diagnostics, monitoring, and screening. However, a major limitation is insufficiently accurate sequencing methods. Conventional nextgeneration sequencing (NGS) technologies have a high false positive error rate, which precludes reliable detection of mutations at frequencies <1/100 (1). "Molecular tagging" of single-stranded DNA decreases the rate of false mutations to less than 1 per 10,000 sequenced nucleotides and has been successfully applied to the detection of mutant cancer DNA in a variety of clinical samples (2-6). However, this false positive error rate limits the specificity of this method in challenging situations in which ultra-deep sequencing is needed to detect extremely low frequency mutant molecules (e.g., <1/10,000), as is the case of ovarian cancer DNA in Pap smears (5). Because true mutations are indistinguishable from artifacts, compromised specificity leads to lower sensitivity and overall low diagnostic accuracy. Duplex sequencing is an NGS technology that employs molecular tagging of both strands of DNA independently. True mutations are defined as mutations that are present at the same...

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Detection of somatic mutations and HPV in the saliva and plasma of patients with head and neck squamous cell carcinomas

Cited by 383 publications

References 51 publications

Noninvasive Molecular Screening for Oral Precancer in Fanconi Anemia Patients

Noninvasive Molecular Screening for Oral Precancer in Fanconi Anemia Patients

Tumor Evolution as a Therapeutic Target

Ultra-deep sequencing detects ovarian cancer cells in peritoneal fluid and reveals somatic TP53 mutations in noncancerous tissues

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