PURPOSE Patients with neuroblastoma in molecular remission remain at considerable risk for disease recurrence. Studies have found that neuroblastoma tissue contains adrenergic (ADRN) and mesenchymal (MES) cells; the latter express low levels of commonly used markers for minimal residual disease (MRD). We identified MES-specific MRD markers and studied the dynamics of these markers during treatment. PATIENTS AND METHODS Microarray data were used to identify genes differentially expressed between ADRN and MES cell lines. Candidate genes were then studied using real-time quantitative polymerase chain reaction in cell lines and control bone marrow and peripheral blood samples. After selecting a panel of markers, serial bone marrow, peripheral blood, and peripheral blood stem cell samples were obtained from patients with high-risk neuroblastoma and tested for marker expression; survival analyses were also performed. RESULTS PRRX1, POSTN, and FMO3 mRNAs were used as a panel for specifically detecting MES mRNA in patient samples. MES mRNA was detected only rarely in peripheral blood; moreover, the presence of MES mRNA in peripheral blood stem cell samples was associated with low event-free survival and overall survival. Of note, during treatment, serial bone marrow samples obtained from 29 patients revealed a difference in dynamics between MES mRNA markers and ADRN mRNA markers. Furthermore, MES mRNA was detected in a higher percentage of patients with recurrent disease than in those who remained disease free (53% v 32%, respectively; P = .03). CONCLUSION We propose that the markers POSTN and PRRX1, in combination with FMO3, be used for real-time quantitative polymerase chain reaction–based detection of MES neuroblastoma mRNA in patient samples because these markers have a unique pattern during treatment and are more prevalent in patients with poor outcome. Together with existing markers of MRD, these new markers should be investigated further in large prospective studies.
PURPOSE Circulating tumor DNA (ctDNA) has been used for disease monitoring in several types of cancer. The aim of our study was to investigate whether ctDNA can be used for response monitoring in neuroblastoma. METHODS One hundred forty-nine plasma samples from 56 patients were analyzed by quantitative polymerase chain reaction (qPCR) for total cell free DNA (cfDNA; albumin and β-actin) and ctDNA (hypermethylated RASSF1A). ctDNA results were compared with mRNA-based minimal residual disease (qPCR) in bone marrow (BM) and blood and clinical patient characteristics. RESULTS ctDNA was detected at diagnosis in all patients with high-risk and stage M neuroblastoma and in 3 of 7 patients with localized disease. The levels of ctDNA were highest at diagnosis, decreased during induction therapy, and not detected before or after autologous stem-cell transplantation. At relapse, the amount of ctDNA was comparable to levels at diagnosis. There was an association between ctDNA and blood or BM mRNA, with concordant results when tumor burden was high or no tumor was detected. The discrepancies indicated either low-level BM infiltration (ctDNA negative/mRNA positive) or primary tumor/soft tissue lesions with no BM involvement (ctDNA positive/mRNA negative). CONCLUSION ctDNA can be used for monitoring disease in patients with neuroblastoma. In high-risk patients and all patients with stage M at diagnosis, ctDNA is present. Our data indicate that at low tumor load, testing of both ctDNA and mRNA increases the sensitivity of molecular disease monitoring. It is likely that ctDNA can originate from both primary tumor and metastases and may be of special interest for disease monitoring in patients who experience relapse in other organs than BM.
Background: The tumor suppressor gene RASSF1A is hypermethylated in many adult and pediatric cancers. With the absence of recurrent mutations or translocations in various pediatric and young adult (malignant) tumors, detection of hypermethylated RASSF1A (RASSF1A-M) is an attractive biomarker for diagnosis as well as follow-up. Previously, we showed that RASSF1A-M can be used to detect neuroblastoma cells in bone marrow. Here we provide proof of concept of the detection of RASSF1A-M in plasma and serum of patients with neuroblastoma, renal tumors, rhabdomyosarcoma and germ cell tumors. Method: Plasma was collected at diagnosis from patients with neuroblastoma (n=47), renal tumors (n=13), and rhabdomyosarcoma (n=19) and during treatment and follow-up for neuroblastoma (n=121). Serum was collected from patients with germ cell tumors at diagnosis (n=94). Initially, cell-free DNA (cfDNA) was isolated, bisulfite treated, and tested by qPCR for actin beta (ACTB), unmethylated and hypermethylated RASSF1A (35 diagnostic and 121 follow-up neuroblastoma samples, 19 rhabdomyosarcoma samples). Subsequently, a droplet digital PCR (ddPCR) method for RASSF1A-M and ACTB, including a methylation-specific restriction enzymatic digestion, was applied on the remaining samples to ensure accurate quantification and reducing bisulfite induced cfDNA loss. A threshold for detection of RASSF1A-M was established by testing plasma (73 by qPCR, 25 by ddPCR) and serum samples (21 by ddPCR) from healthy donors. Results: In plasma samples, the total cfDNA level (ng/mL; median) was significantly higher in patients with renal tumors and neuroblastoma (localized and metastatic disease), but not in rhabdomyosarcoma patients, when compared to healthy donors (66.4; 34.4; 80.9; 3.0 and 2.4, respectively). For diagnostic neuroblastoma samples, RASSF1A-M was detected in all 26 patients with metastatic disease and in 10/21 patients with localized disease (mean 71.4% and 8.4% RASSF1A-M, respectively). RASSF1A-M levels decreased during therapy and re-elevated at relapse. RASSF1A-M was detected in 10/13 renal tumor and 8/21 rhabdomyosarcoma diagnostic samples (18.6% and 19.7% RASSF1A-M, respectively). Total cfDNA levels in healthy donor samples were higher in serum when compared to plasma (39.9 versus 2.4 ng/mL). cfDNA levels were significantly higher in patients with germ cell tumors (230.20 ng/mL) compared to healthy donor serum. RASSF1A-M was detected across all subtypes, including 15/16 embryonal carcinomas, 16/18 seminomas, 2/2 yolk sac tumors, 10/11 teratomas, 1/1 choriocarcinoma, and 42/46 mixed tumors. Conclusion: Our findings demonstrate the value of RASSF1A-M as a molecular circulating tumor marker in various solid tumors. We developed a ddPCR-based sensitive and quantitative assay for RASSF1A-M detection. Based on the data presented, RASSF1A hypermethylation is an interesting biomarker for detection of minimal residual disease across various solid tumor types, including those lacking recurrent mutations/translocations. Citation Format: Lieke M. J. van Zogchel, João Lobo, Nathalie Lak, Esther M. van Wezel, Jalenka van Wijk, Janine Stutterheim, Lily Zappeij-Kannegieter, Leendert H.J. Looijenga, Ellen van der Schoot, Godelieve A. M. Tytgat. Hypermethylated RASSF1A as circulating tumor marker in pediatric and adolescent solid tumors [abstract]. In: Proceedings of the AACR Special Conference on Advances in Liquid Biopsies; Jan 13-16, 2020; Miami, FL. Philadelphia (PA): AACR; Clin Cancer Res 2020;26(11_Suppl):Abstract nr A53.
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