Multiplex PCR-based Next-generation Sequencing Research Articles

Prospective assessment of circulating tumor DNA in patients with metastatic uveal melanoma treated with tebentafusp

Tebentafusp, a bispecific immune therapy, is the only drug that demonstrated an overall survival benefit in patients with metastatic uveal melanoma (MUM). Circulating tumor DNA (ctDNA) has emerged as a potential prognostic and predictive marker in the phase 3 IMCgp100-202 trial using multiplex PCR-based next-generation sequencing (NGS). In this study (NCT02866149), ctDNA dynamics were assessed using droplet digital PCR (ddPCR) in 69 MUM patients undergoing tebentafusp treatment. Notably, 61% of patients exhibited detectable ctDNA before treatment initiation, which was associated with shorter overall survival (median 12.9 months versus 40.5 months for patients with undetectable ctDNA; p < 0.001). Patients manifesting a 90% or greater reduction in ctDNA levels at 12 weeks demonstrated markedly prolonged overall survival (median 21.2 months versus 12.9 months; p = 0.02). Our findings highlight the potential of ddPCR-based ctDNA monitoring as an economical, pragmatic and informative approach in MUM management, offering valuable insights into treatment response and prognosis.

Tumor-informed deep sequencing of ctDNA detects minimal residual disease and predicts relapse in osteosarcoma

Current surveillance modalities of osteosarcoma relapse exhibit limited sensitivity and specificity. Although circulating tumor DNA (ctDNA) has been established as a biomarker of minimal residual disease (MRD) in many solid tumors, a sensitive ctDNA detection technique has not been thoroughly explored for longitudinal MRD detection in osteosarcoma. From August 2019 to June 2023, 59 patients diagnosed with osteosarcoma at the First Affiliated Hospital of Sun Yat-sen University were evaluated in this study. Tumor-informed MRD panels were developed through whole exome sequencing (WES) of tumor tissues. Longitudinal blood samples were collected during treatment and subjected to multiplex PCR-based next-generation sequencing (NGS). Kaplan-Meier curves and Log-rank tests were used to compare outcomes, and Cox regression analysis was performed to identify prognostic factors. WES analysis of 83 patients revealed substantial mutational heterogeneity, with non-recurrent mutated genes accounting for 58.1%. Tumor-informed MRD panels were successfully obtained for 85.5% of patients (71/83). Among 59 patients with successful MRD panel customization and available blood samples, 13 patients exhibited positive ctDNA detection after surgery. Patients with negative post-operative ctDNA had better event-free survival (EFS) compared to those with positive ctDNA, at 1-6 months after surgery, after adjuvant chemotherapy, and more than 6 months after surgery (p<0.05). In both univariate and multivariate Cox regression analysis, ctDNA results emerged as a significant predictor of EFS (p<0.05). ctDNA detection preceded positive imaging in 5 patients, with an average lead time of 92.6 days. Thirty-nine patients remained disease-free, with ctDNA results consistently negative or turning negative during follow-up. Our study underscores the applicability of tumor-informed deep sequencing of ctDNA in osteosarcoma MRD surveillance and, to our knowledge, represents the largest cohort to date. ctDNA detection is a significant prognostic factor, enabling the early identification of tumor relapse and progression compared to standard imaging, thus offering valuable insights in guiding osteosarcoma patient management. The Grants of National Natural Science Foundation of China (No. 82072964, 82072965, 82203798, 82203026), the Natural Science Foundation of Guangdong (No. 2023A1515012659, 2023A1515010302), and the Regional Combination Project of Basic and Applied Basic Research Foundation of Guangdong (No. 2020A1515110010).

Kinetics of postoperative circulating cell-free DNA and impact on minimal residual disease detection rates in patients with resected stage I-III colorectal cancer.

5 Background: A growing body of evidence supports the utility of circulating tumor DNA (ctDNA) as a useful biomarker for detecting molecular residual disease (MRD) in colorectal cancer (CRC). Immediately after surgery or during adjuvant therapy, high levels of cell-free DNA (cfDNA) from normal tissue may limit the detection of tumor-derived ctDNA. The optimal timing of blood collection for reliable MRD detection after surgery or adjuvant therapy remains unclear. Methods: In this retrospective, U.S.-based, multi-institutional study, data from commercial ctDNA testing in 16,347 patients with stage I-III CRC were analyzed. Complete clinical data were available for 417 patients with 2,538 plasma samples collected between 6/2019 and 4/2022. The median follow-up for relapsed and non-relapsed patients was 730 and 615 days, respectively. A personalized, tumor-informed multiplex PCR-based next-generation sequencing assay (Signatera) was used to quantify ctDNA prior to surgery and postoperatively in a longitudinal manner. We analyzed the kinetics of total cfDNA and compared it with the ctDNA MRD positivity rates at various time points after surgery. Results: Among all patients, cfDNA levels were higher immediately after surgery (0-2 weeks) and gradually declined during the subsequent 2-8 weeks (p&lt;0.0001). Despite the higher cfDNA levels, among patients with immediate post-operative draws (0-2 weeks) 30.6% (113/369) of patients were ctDNA positive. Similar ctDNA detection rates were observed with conventional MRD windows after resection, whether the window was defined as 2-6 weeks (20.8%; 957/4605) or 2-8 weeks (20.9%; 1155/5534). In the clinically annotated cohort, ctDNA-positivity during the MRD time window of 2-8 weeks and during surveillance (&gt;6 months post-operatively and subsequent to any adjuvant therapy) was significantly associated with worse recurrence-free survival as compared to ctDNA negative patients (MRD: HR 14.1, 95% CI: 5.8-34; p&lt;0.0001; and surveillance HR 20.6, 95% CI: 10.6-37.6; p&lt;0.0001), respectively. On analyzing cfDNA dynamics during adjuvant therapy, cfDNA levels gradually increased between 8 weeks and 8 months after surgery (p=0.0001), suggesting a potential impact of treatment on cell death and cfDNA shed. Conclusions: This is one of the first, large-scale in-depth studies evaluating treatment-based fluctuations in post-operative cfDNA and its correlation with ctDNA-positivity. Our analyses demonstrated no significant impact of plasma cfDNA levels on ctDNA detection rates across different MRD windows using a tumor-informed approach. This may affect real-world application of personalized ctDNA testing by allowing earlier testing windows, as well as guide clinical trial designs using ctDNA as an integral biomarker.

Circulating tumor DNA (ctDNA) informs clinical practice in patients with recurrent/metastatic gastroesophageal cancers.

427 Background: Gastric and esophageal cancers (GECs) together account for a significant global burden in terms of new diagnoses and deaths. Over the last several years, the utility of ctDNA has ranged from estimating tumor burden and characterizing the genomic landscape of tumor biology and response to therapy in the metastatic setting to detection of minimal residual disease (MRD) and cancer surveillance in the locally advanced setting. We have previously studied the role of a commercial ctDNA assay for MRD detection and surveillance in locally advanced GECs. Herein, we present our experience with the same ctDNA assay in advanced stage settings for GECs. Methods: In this retrospective analysis of real-world data obtained from commercial circulating tumor DNA (ctDNA) testing, 53 patients with recurrent/ metastatic esophageal cancer were analyzed. A total of 216 plasma samples were collected between 10/29/2008 and 08/23/2022. The patients were divided into 3 cohorts: Cohort A (N=30) included patients with stage II/III disease who had confirmed clinical recurrence (R). Cohort B (N=25) included recurrent and Stage IV patients who achieved a state of no evidence of disease (NED) on imaging. Cohort C (N=5) included recurrent and Stage IV patients who transiently achieved NED on imaging. A personalized, tumor-informed multiplex PCR-based next-generation sequencing assay (Signatera) was used to quantify ctDNA either postoperatively, on adjuvant or palliative therapy, or during active surveillance. Results: Of 53 patients, 30 patients with recurrent stage II/III esophageal cancer had ctDNA status available postoperatively within 150 days of confirmed clinical recurrence. Cohort A: Among these cases, 25 patients were ctDNA-positive ahead of clinical recurrence (sensitivity 83.3%) with a median of 31 days (range: 1-147 days). Cohort B: Next, we explored the correlation between ctDNA status and imaging, wherein, 96% (24/25) of patients showed a significant correlation between ctDNA status (positive or negative) and disease status by imaging (Fisher exact test p=0.0001). Of the 23 patients, 17 patients were ctDNA-negative and showed NED on imaging (negative predictive value of 100%; 17/17). Cohort C: 100% of patients (N=6) who demonstrated recurrent disease on imaging after NED were ctDNA-positive prior to imaging (positive predictive value of 100%). Conclusions: Our data demonstrate the utility of ctDNA in accurately predicting disease progression and support the potential use of ctDNA to inform treatment decisions or prompt early radiographic imaging. ctDNA may ultimately supersede traditional radiographic surveillance with the advantage of being minimally invasive and cost-effective in monitoring patients during/post-treatment.

Genotyping and Molecular Diagnosis of Hepatitis A Virus in Human Clinical Samples Using Multiplex PCR-Based Next-Generation Sequencing.

Hepatitis A virus (HAV) is a serious threat to public health worldwide. We used multiplex polymerase chain reaction (PCR)-based next-generation sequencing (NGS) to derive information on viral genetic diversity and conduct precise phylogenetic analysis. Four HAV genome sequences were obtained using multiplex PCR-based NGS. HAV whole-genome sequence of one sample was obtained by conventional Sanger sequencing. The HAV strains demonstrated a geographic cluster with sub-genotype IA strains in the Republic of Korea. The phylogenetic pattern of HAV viral protein (VP) 3 region showed no phylogenetic conflict between the whole-genome and partial-genome sequences. The VP3 region in serum and stool samples showed sensitive detection of HAV with differences of quantification that did not exceed <10 copies/μL than the consensus VP4 region using quantitative PCR (qPCR). In conclusion, multiplex PCR-based NGS was implemented to define HAV genotypes using nearly whole-genome sequences obtained directly from hepatitis A patients. The VP3 region might be a potential candidate for tracking the genotypic origin of emerging HAV outbreaks. VP3-specific qPCR was developed for the molecular diagnosis of HAV infection. This study may be useful to predict for the disease management and subsequent development of hepatitis A infection at high risk of severe illness.

Urinary genome detection and tracking of Hantaan virus from hemorrhagic fever with renal syndrome patients using multiplex PCR-based next-generation sequencing.

BackgroundHantavirus infection occurs through the inhalation of aerosolized excreta, including urine, feces, and saliva of infected rodents. The presence of Hantaan virus (HTNV) RNA or infectious particles in urine specimens of patient with hemorrhagic fever with renal syndrome (HFRS) remains to be investigated.Methodology/Principal findingsWe collected four urine and serum specimens of Republic of Korea Army (ROKA) patients with HFRS. We performed multiplex PCR-based next-generation sequencing (NGS) to obtain the genome sequences of clinical HTNV in urine specimens containing ultra-low amounts of viral genomes. The epidemiological and phylogenetic analyses of HTNV demonstrated geographically homogenous clustering with those in Apodemus agrarius captured in highly endemic areas, indicating that phylogeographic tracing of HTNV genomes reveals the potential infection sites of patients with HFRS. Genetic exchange analyses showed a genetic configuration compatible with HTNV L segment exchange in nature.Conclusion/SignificanceOur results suggest that whole or partial genome sequences of HTNV from the urine enabled to track the putative infection sites of patients with HFRS by phylogeographically linking to the zoonotic HTNV from the reservoir host captured at endemic regions. This report raises awareness among physicians for the presence of HTNV in the urine of patients with HFRS.

A Clinical Case of Scrub Typhus in the United States Forces Korea Patient with Eschar and Genetic Identification of Orientia tsutsugamushi Using Multiplex PCR-Based Next-Generation Sequencing.

An epidemiological investigation was conducted for a scrub typhus case reported in a U.S. Forces Korea military patient in the Republic of Korea in November 2018. The patient had a fever, maculopapular rash, and an eschar. The full-length sequence of Orientia tsutsugamushi 56-kDa type-specific antigen (TSA) gene was obtained from eschar tissue by multiplex PCR-based Next Generation Sequencing for genetic identification. Based on the 56-kDa TSA gene, the O. tsutsugamushi aligned most closely with the Boryong strain.

Diagnostic Utility of a Custom 34-Gene Anchored Multiplex PCR-Based Next-Generation Sequencing Fusion Panel for the Diagnosis of Bone and Soft Tissue Neoplasms With Identification of Novel USP6 Fusion Partners in Aneurysmal Bone Cysts.

Bone and soft tissue tumors are heterogeneous, diagnostically challenging, and often defined by gene fusions. To present our experience using a custom 34-gene targeted sequencing fusion panel. Total nucleic acid extracted from formalin-fixed, paraffin-embedded (FFPE) tumor specimens was subjected to open-ended, nested anchored multiplex polymerase chain reaction and enrichment of 34 gene targets, thus enabling detection of known and novel fusion partners. During a 12-month period, 147 patients were tested as part of routine clinical care. Tumor percentage ranged from 10% to 100% and turnaround time ranged from 3 to 15 (median, 7.9) days. The most common diagnostic groups were small round blue cell tumors, tumors of uncertain differentiation, fibroblastic/myofibroblastic tumors, and adipocytic tumors. In-frame fusion transcripts were identified in 64 of 142 cases sequenced (45%): in 62 cases, the detection of a disease-defining fusion confirmed the morphologic impression; in 2 cases, a germline TFG-GPR128 polymorphic fusion variant was detected. Several genes in the panel partnered with multiple fusion partners specific for different diagnoses, for example, EWSR1, NR4A3, FUS, NCOA2, and TFE3. Interesting examples are presented to highlight how fusion detection or lack thereof was instrumental in establishing accurate diagnoses. Novel fusion partners were detected for 2 cases of solid aneurysmal bone cysts (PTBP1-USP6, SLC38A2-USP6). Multiplex detection of fusions in total nucleic acid purified from FFPE specimens facilitates diagnosis of bone and soft tissue tumors. This technology is particularly useful for morphologically challenging entities and in the absence of prior knowledge of fusion partners, and has the potential to discover novel fusion partners.

Phylogeographic diversity and hybrid zone of Hantaan orthohantavirus collected in Gangwon Province, Republic of Korea

BackgroundHantaan orthohantavirus (Hantaan virus, HTNV), harbored by Apodemus agrarius (the striped field mouse), causes hemorrhagic fever with renal syndrome (HFRS) in humans. Viral genome-based surveillance at new expansion sites to identify HFRS risks plays a critical role in tracking the infection source of orthohantavirus outbreak. In the Republic of Korea (ROK), most studies demonstrated the serological prevalence and genetic diversity of orthohantaviruses collected from HFRS patients or rodents in Gyeonggi Province. Gangwon Province is a HFRS-endemic area with a high incidence of patients and prevalence of infected rodents, ROK. However, the continued epidemiology and surveillance of orthohantavirus remain to be investigated.Methodology/Principal findingsWhole-genome sequencing of HTNV was accomplished in small mammals collected in Gangwon Province during 2015–2018 by multiplex PCR-based next-generation sequencing. To elucidate the geographic distribution and molecular diversity of viruses, we conducted phylogenetic analyses of HTNV tripartite genomes. We inferred the hybrid zone using cline analysis to estimate the geographic contact between two different HTNV lineages in the ROK. The graph incompatibility based reassortment finder performed reassortment analysis. A total of 12 HTNV genome sequences were completely obtained from A. agrarius newly collected in Gangwon Province. The phylogenetic and cline analyses demonstrated the genetic diversity and hybrid zone of HTNV in the ROK. Genetic exchange analysis suggested the possibility of reassortments in Cheorwon-gun, a highly HFRS-endemic area.Conclusions/SignificanceThe prevalence and distribution of HTNV in HFRS-endemic areas of Gangwon Province enhanced the phylogeographic map for orthohantavirus outbreak monitoring in ROK. This study revealed the hybrid zone reflecting the genetic diversity and evolutionary dynamics of HTNV circulating in Gangwon Province. The results arise awareness of rodent-borne orthohantavirus diseases for physicians in the endemic area of ROK.

SMAD4 Somatic Mutations in Head and Neck Carcinoma Are Associated With Tumor Progression.

As the incidence and the mortality rate of head and neck squamous cell carcinoma (HNSCC) is increasing worldwide, gaining knowledge about the genomic changes which happen in the carcinogenesis of HNSCC is essential for the diagnosis and therapy of the disease. SMAD4 (DPC4) is a tumor suppressor gene. It is located at chromosome 18q21.1 and a member of the SMAD family. Which mediates the TGF-β signaling pathway, thereby controlling the growth of epithelial cells. In the study presented here, we analyzed tumor samples by multiplex PCR-based next-generation sequencing (NGS) and found deleterious mutations of SMAD4 in 4.1% of the tumors. Knock-down experiments of endogenous and exogenous SMAD4 expression demonstrated that SMAD4 is involved in the migration and invasion of HNSCC cells. Functional analysis of a missense mutation in the MH1 domain of SMAD4 may be responsible for the loss of function in suppressing tumor progression. Missense SMAD4 mutations, therefore, could be useful prognostic determinants for patients affected by HNSCCs. This report is the first study where NGS analysis based on multiplex-PCR is used to demonstrate the imminent occurrence of missense SMAD4 mutations in HNSCC cells. The gene analysis that we performed may support the identification of SMAD4 mutations as a diagnostic marker or even as a potential therapeutic target in head and neck cancer. Moreover, the analytic strategy proposed for the detection of mutations in the SMAD4 gene may be validated as a platform to assist mutation screening.

ANKRD26-RET - A novel gene fusion involving RET in papillary thyroid carcinoma

BackgroundRearrangements of RET are drivers of oncogenesis, traceable in different cancer types as papillary thyroid carcinoma (PTC), non-small cell lung cancer, colorectal or breast cancer. Anchored multiplex PCR based next-generation sequencing (NGS) can detect RET rearrangements involving previously unknown partner genes. MethodsA sample of PTC underwent NGS, following detection of RET rearrangement by fluorescence in situ hybridization. Expression analysis of ANKRD26 and RET was performed for the tumor harboring ANKRD26-RET, for corresponding normal thyroid tissue and PTC tumors with representative genetic alterations (BRAFV600E, CCDC6-RET), complemented by a comparative search in the “UniProt” database. ResultsNGS analysis resulted in the discovery of the fusion ANKRD26-RET. ANKRD26 mRNA was expressed in all PTC tumors (ANKRD26-RET, BRAFV600E, CCDC6-RET) and in normal thyroid tissue, whereas RET mRNA was detected only in the tumors with RET rearrangement. On protein level, ANKRD26-RET combines the RET tyrosine kinase to ankyrin repeat and coiled-coil domains. ConclusionsANKRD26-RET is a novel rearrangement of the RET gene, associated with RET expression in thyroid tissue. The result is a fusion of the RET tyrosine kinase to prominent protein-protein interaction motifs. Further studies are required to investigate the influence of different RET rearrangements on metastasis and disease-free survival in PTC.

FAT1 somatic mutations in head and neck carcinoma are associated with tumor progression and survival.

In recent years, the incidence and mortality rates of head and neck squamous cell carcinoma (HNSCC) have increased worldwide. Therefore, understanding genomic alterations in HNSCC carcinogenesis is crucial for appropriate diagnosis and therapy. Protocadherin FAT1, which encodes 4588 amino acid residues, regulates complex mechanisms to promote oncogenesis or suppression of malignancies. Multiplex PCR-based next-generation sequencing (NGS) revealed FAT1 somatic mutations. The clinicopathologic implications of FAT1 in HNSCC were investigated using expression assays, and the functional role of FAT1 in HNSCC pathogenesis was determined using ectopic expression and knockdown experiments. Approximately 29% patients with HNSCC harbored damaging FAT1 mutations. InVEx algorithm identified FAT1 as a significant functional mutation burden. Each type of mutation (missense, nonsense and frameshift) accounted for nearly one-third of deleterious mutations. FAT1 mutations correlated with lower FAT1 expression in tumors. The knockdown of the endogenous expression of FAT1 and exogenous expression of crucial FAT1 domains unequivocally indicated that FAT1 suppressed the migration and invasion capability of HNSCC cells. Functional analysis suggested that nonsense mutations in FAT1 result in the loss of the suppression of tumor progression. FAT1 mutations and downregulation defined nodal involvement, lymphovascular permeation and tumor recurrence. In addition, FAT1 mutations and downregulation are independent predictors of poor disease-free survival in patients with HNSCC. This study is the first to perform multiplex PCR-based NGS to indicate marked non-synonymous FAT1 mutations in HNSCC, which are prognostic indicators. The gene analysis strategy proposed for detecting FAT1 mutations may be a valid method for mutation screening.

Abstract 1234: Somatic mutations of FAT1 in oral cancer are associated with tumor progression and survival

Abstract In recent years, the incidence and mortality rates of oral squamous cell carcinoma (OSCC) have increased worldwide. Therefore, understanding genomic alterations in OSCC carcinogenesis is crucial for appropriate diagnosis and therapy. Procadherin FAT1, which encodes 4588 amino acid residues, regulates complex mechanisms to promote oncogenesis or suppression of malignancies. Multiplex polymerase chain reaction (PCR)-based next-generation sequencing (NGS) revealed FAT1 somatic mutations. The clinicopathologic implications of FAT1 in OSCC were investigated using expression assays, and the functional role of FAT1 in HNSCC pathogenesis was determined using ectopic expression and knockdown experiments. Approximately 29% of patients with OSCC harbored damaging FAT1 mutations. Each type of mutation (missense, nonsense, and frameshift mutations) accounted for nearly one-third of deleterious mutations. FAT1 mutations correlated with lower FAT1 expression in tumors. The knockdown of the endogenous expression of FAT1 and exogenous expression of crucial FAT1 domains unequivocally indicated that FAT1 suppressed the migration and invasion capability of OSCC cells. Functional analysis suggested that nonsense mutations in FAT1 result in the loss of the suppression of tumor progression. FAT1 mutations and downregulation defined nodal involvement, lymphovascular permeation, and tumor recurrence. In addition, FAT1 mutations and downregulation are independent predictors of poor disease-free survival in patients with HNSCC. This study is the first to perform multiplex PCR-based NGS to indicate marked nonsynonymous FAT1 mutations in OSCC, which are prognostic indicators. The gene analysis strategy proposed for detecting FAT1 mutations may be a valid method for mutation screening. Citation Format: Chung Ji Liu, Shu-Chun Lin, Li-Han Lin. Somatic mutations of FAT1 in oral cancer are associated with tumor progression and survival [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1234.

Multiplex PCR-Based Next-Generation Sequencing and Global Diversity of Seoul Virus in Humans and Rats.

Seoul virus (SEOV) poses a worldwide public health threat. This virus, which is harbored by Rattus norvegicus and R. rattus rats, is the causative agent of hemorrhagic fever with renal syndrome (HFRS) in humans, which has been reported in Asia, Europe, the Americas, and Africa. Defining SEOV genome sequences plays a critical role in development of preventive and therapeutic strategies against the unique worldwide hantavirus. We applied multiplex PCR–based next-generation sequencing to obtain SEOV genome sequences from clinical and reservoir host specimens. Epidemiologic surveillance of R. norvegicus rats in South Korea during 2000–2016 demonstrated that the serologic prevalence of enzootic SEOV infections was not significant on the basis of sex, weight (age), and season. Viral loads of SEOV in rats showed wide dissemination in tissues and dynamic circulation among populations. Phylogenetic analyses showed the global diversity of SEOV and possible genomic configuration of genetic exchanges.

Leukemia Fusion Gene Detection in the Clinical Molecular Laboratory Using RNA-Based Targeted Next-Generation Sequencing

Introduction: The diagnosis and risk stratification for patients with B-lymphoblastic leukemia (B-ALL) requires the accurate detection of fusion genes such as BCR-ABL1, ETV6-RUNX1,or Philadelphia-like (Ph-like) B-ALL kinase fusions, or gene rearrangements (e.g. KMT2A). No single assay can detect all relevant alterations, so costly and inefficient testing algorithms that combine karyotyping, fluorescent in situ hybridization (FISH), and reverse transcriptase PCR (RT-PCR) are often required. A comprehensive and sensitive RNA-based next-generation sequencing (NGS) assay that could consolidate diagnostic and prognostic B-ALL gene fusion and rearrangement testing into a single clinical test is an attractive alternative.Methods: We obtained RNA from 15 clinical specimens collected from 14 patients [11 bloods (2 from the same patient) and 4 bone marrows] with hematologic malignancies and known genomic alterations by RT-PCR, FISH, or cytogenetics, and 1 Ph-positive B-ALL cell line (SUP-B15). Samples harbored either B-ALL-associated alterations [BCR-ABL1 (3), ETV6-RUNX1 (2), intrachromosomal amplification 21 (iAMP21) (2), and KMT2A (2) or PDGFRB (1) rearrangements], or alterations detected in other hematologic malignancies [PML-RARA (2, same patient), RUNX1-RUNX1T1, t(5;9)(q33;q22), t(1;4)(p13;q12), and monosomy 7]. We prepared NGS libraries from extracted total RNA (100 ng) using the Archer® FusionPlex® Heme v2 anchored multiplex PCR-based NGS library with molecular barcoding protocol that targets 553 exons in 87 genes associated with B-ALL and other hematologic malignancies for detection of expressed fusions regardless of gene partner. Illumina paired-end indexed libraries were multiplexed (8 per run) and sequenced on a MiSeq (2x150 bp, v2) in two separate runs. Data were analyzed using vendor-provided virtual-machine based analysis pipelines and custom-developed scripts. ANNOVAR was used for breakpoint annotation, and fusion calls were compared to previous molecular results.Results: A mean total of 5.1x105 unique and 6.26x104 unique RNA paired-end reads were generated. One sample [t(1;4)(p13;q12)] failed QC due to inadequate RNA reads and was excluded from analysis. NGS detected the fusion or gene rearrangement in 10/11 samples (91%) with mean supporting split read counts of 175 reads (range: 6-1209). NGS detected both ETV6-RUNX1 fusions in samples with 4% and 5% blasts, respectively, defined binding partners for the KMT2A and PDGFRB gene rearrangements (KMT2A-MLLT10, KMT2A-MLLT3, and CCDC88C-PDGFRB), and detected novel P2RY8-CRLF2 fusions in both iAMP21 samples. NGS failed to detect a PML-RARA fusion in a post-treatment low-level RT-PCR-positive, FISH-, flow-, and morphology-negative blood sample, and no fusion was detected in the t(5;9)(q33;q22) sample. A low-level KMT2A-MLLT10 fusion was detected in an ETV6-RUNX1 sample suggesting a minor subclone or false-positive result.Conlcusions: In summary, RNA-based targeted NGS detects gene fusions and rearrangements comparable to conventional methods, accurately detects fusions in samples with ~5% blasts, and highlights previously unknown fusions and fusion partners. Additional studies are required to establish clinical specimen requirements, limit of detection, sensitivity, and specificity. Experiments are underway to confirm novel fusions, sequence additional recurrent B-ALL alterations (e.g. JAK2, TCF3, and PDGFRA fusions), and assess assay performance in formalin-fixed, paraffin-embedded tissue samples. RNA-based targeted NGS may be a clinically useful method to detect gene fusions and rearrangements in B-ALL and other hematologic malignancies. DisclosuresNo relevant conflicts of interest to declare.

Abstract 3984: Novel t(X;21)(q26;q22) detected in a case of acute unclassifiable leukemia by application of anchored multiplex PCR-based next-generation sequencing

Abstract In this study, we demonstrate real-time clinical application of novel anchored multiplex PCR (AMP) technology in hematologic disease. A 78-year-old man with a history of hairy cell leukemia treated with Cladribine (2013) and bladder cancer (2014) developed dyspnea in August 2015. Work up revealed bicytopenia and leukocytosis. Outside bone marrow biopsy was read as B lymphoblastic leukemia/lymphoma. Rebiopsy was performed at our NCI-designated cancer center with extensive work up resulted in reclassification as acute unclassifiable leukemia (rare) with deferral to molecular diagnostics for guidance regarding classification. MLL, BCR-ABL, and MDS FISH panel were negative. Next generation sequencing (NGS) interrogating more than 400 genes showed FLT3-ITD, truncation of RUNX1 exon 6, ASXL1 p.G646Wfs*12, MLL p.V297L, and EZH2 p.V674M and p.C443Y mutations. The molecular profile favored therapy-related AML. Interestingly, cytogenetics revealed 46,Y,t(X;21)(q26;q22)[20]. FISH confirmed RUNX1 rearrangement but the partner was unknown. The t(X;21)(q26;q22) appears to be novel. However, the rare t(3;21)(q26.2;q22) has been cited to segregate with therapy-related MDS/AML. Subsequent aberrant activation of RUNX1 and MECOM is postulated to be pivotal in pathogenesis. Therefore, it is of great interest to determine the translocation partner associated with RUNX1 in our case. This type of analysis is not easily amenable to either Sanger or conventional NGS approaches. Fortuitously, with the recent advent of AMP technology (Archer FusionPlex) novel fusion detection has become possible. AMP was key in the characterization of this sample and promotes discovery of novel fusions by targeting one (known) of the two genes involved in a translocation event. Application of this cutting edge technology lead to the discovery of the novel fusion RUNX1-G6PD in this case. The identity of the novel fusion partners was supported by the breakpoints originally observed by the karyotype analysis. G6PD has been previously reported to be upregulated in acute leukemia. This discovery raises the possibility convergent pathogenic pathways and carries potential biological, diagnostic, and therapeutic implications. Citation Format: Laura Johnson, Helen Wang, Katelyn Trifilo, Brian Kudlow, Peter R. Pappenhausen, Mohammad Hussaini. Novel t(X;21)(q26;q22) detected in a case of acute unclassifiable leukemia by application of anchored multiplex PCR-based next-generation sequencing. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3984.

Phylogeographic analysis of hemorrhagic fever with renal syndrome patients using multiplex PCR-based next generation sequencing.

Emerging and re-emerging infectious diseases caused by RNA viruses pose a critical public health threat. Next generation sequencing (NGS) is a powerful technology to define genomic sequences of the viruses. Of particular interest is the use of whole genome sequencing (WGS) to perform phylogeographic analysis, that allows the detection and tracking of the emergence of viral infections. Hantaviruses, Bunyaviridae, cause hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS) in humans. We propose to use WGS for the phylogeographic analysis of human hantavirus infections. A novel multiplex PCR-based NGS was developed to gather whole genome sequences of Hantaan virus (HTNV) from HFRS patients and rodent hosts in endemic areas. The obtained genomes were described for the spatial and temporal links between cases and their sources. Phylogenetic analyses demonstrated geographic clustering of HTNV strains from clinical specimens with the HTNV strains circulating in rodents, suggesting the most likely site and time of infection. Recombination analysis demonstrated a genome organization compatible with recombination of the HTNV S segment. The multiplex PCR-based NGS is useful and robust to acquire viral genomic sequences and may provide important ways to define the phylogeographical association and molecular evolution of hantaviruses.

A Multiplex PCR-Based Next-Generation Sequencing Approach Has Detected a Common Large Deletion in STS Gene in a Patient with X-Linked Ichthyosis

Several nuclear genes have been found to be linked to ichthyosis, and Next Generation Sequencing approach on panels of targeted genes has turned out to be particularly useful in analyzing diseases characterized by significant genetic and phenotypic heterogeneity. We developed a panel of 26 genes to be screened with the Ion Personal Genome Machine (PGM) for causative mutations relating to ichthyosis. Sequencing runs were obtained from a patient with ichthyosis using the Ion Torrent PGM and then processed with Ion Torrent Suite, Variant Caller, Coverage Analysis and wANNOVER tools. No causative mutations were found using Variant Caller and wANNOVER softwares, whereas the “Coverage Analysis” tool revealed a common large deletion in STS gene in a patient with X-linked ichthyosis. Identification of indels in Next Generation Sequencing (NGS) data is a veritable challenge. This study demonstrates the efficacy and effectiveness of using NGS approach to detect large deletions without resorting to specific algorithms for “indel” detection. Our results indicate that the NGS panel is a useful, rapid and cost-effective screening test for patients whose features are suggestive of a genetic etiology involving one of the genes embedded in the panel. It is an excellent alternative to Sanger sequencing as for costs, ease of analysis, and turnaround time.

Targeted next-generation sequencing of the ATP7B gene for molecular diagnosis of Wilson disease

ObjectivesIn recent years, next-generation sequencing (NGS) technologies, which enable high throughput sample processing at relatively lower costs, are adopted in both research and clinical settings. A multiplex PCR-based NGS assay to identify mutations in the ATP7B gene for routine molecular diagnosis of Wilson disease was evaluated in comparison with the gold standard direct Sanger sequencing. Design and methodsFive multiplex PCRs to amplify the partial promoter, 5′ untranslated and the entire coding regions of the ATP7B gene were designed. Indexed paired-end libraries were generated from the pooled amplicons using Nextera XT DNA Sample Preparation Kit and subjected to NGS on the MiSeq platform. DNA from the peripheral blood of 12 patients with Wilson disease, 2 B-lymphocyte cell lines and 3 external quality assurance samples were sequenced by the MiSeq and Sanger sequencing. ResultsComplete coverage was achieved across the targeted bases without any drop-out sequences. The observed read depth in a single run with 20 samples was >100X. Comparison of the NGS results against Sanger sequencing data on a panel of clinical specimens, cell lines and European Molecular Genetics Quality Networks (EMQN) quality assurance samples showed 100% concordance in identifying pathogenic mutations. ConclusionWith the capability of generating relatively higher throughput in a short time period, the NGS assay is a viable alternative to Sanger sequencing for detecting ATP7B mutations causally linked to Wilson disease in the clinical diagnostic laboratory.

False Positives in Multiplex PCR-Based Next-Generation Sequencing Have Unique Signatures

Next-generation sequencing shows great promise by allowing rapid mutational analysis of multiple genes in human cancers. Recently, we implemented the multiplex PCR-based Ion AmpliSeq Cancer Hotspot Panel (>200 amplicons in 50 genes) to evaluate EGFR, KRAS, and BRAF in lung and colorectal adenocarcinomas. In 10% of samples, automated analysis identified a novel G873R substitution mutation in EGFR. By examining reads individually, we found this mutation in >5% of reads in 50 of 291 samples and also found similar events in 18 additional amplicons. These apparent mutations are present only in short reads and within 10 bases of either end of the read. We therefore hypothesized that these were from panel primers promiscuously binding to nearly complementary sequences of nontargeted amplicons. Sequences around the mutations matched primer binding sites in the panel in 18 of 19 cases, thus likely corresponding to panel primers. Furthermore, because most primers did not show this effect, we demonstrated that next-generation sequencing may be used to better design multiplex PCR primers through iterative elimination of offending primers to minimize mispriming. Our results indicate the need for careful sequence analysis to avoid false-positive mutations that can arise in multiplex PCR panels. The AmpliSeq Cancer panel is a valuable tool for clinical diagnostics, provided awareness of potential artifacts.