The C-Circle Biomarker Is Secreted by Alternative-Lengthening-of-Telomeres Positive Cancer Cells inside Exosomes and Provides a Blood-Based Diagnostic for ALT Activity.

Yuan-Yin Chen,Yuchen Zhang,Roger R Reddel,Robert Lu,Jeremy D Henson,Klaus Holzmann,Sandra Sampl,Loretta M S Lau,Joyce H Y Lee,Rebecca Dagg,Medina Korkut-Demirbaş,Nancy Martin La Rotta

doi:10.3390/cancers13215369

Abstract

Simple SummaryA clinical test for alternative-lengthening-of-telomeres (ALT) could assist with cancer diagnosis and monitoring of disease progression. ALT-targeted anticancer treatments are being developed; however, there is no appropriate companion ALT diagnostic. The C-Circle biomarker is the only known ALT specific molecule and the C-Circle Assay the only quantitative ALT assay that is amenable to clinical use. We show here that C-Circles are secreted by ALT+ cancer cell lines inside the exosomes and are protected from nucleases. We also show that secreted C-Circles, like intracellular C-Circles, are an ALT-specific biomarker, and in high-risk neuroblastoma, the blood-based C-Circle Assay has the potential to be an accurate diagnostic for ALT cancer activity. Therefore, the secretion of C-Circles by ALT+ cancer cells in the exosomes provides a stable blood-based biomarker and, potentially, a clinical diagnostic for ALT activity, which is required for the development of ALT-targeted therapies as well as for the diagnosis and monitoring of ALT+ cancer.C-Circles, self-primed telomeric C-strand templates for rolling circle amplification, are the only known alternative-lengthening-of-telomeres (ALT)-specific molecule. However, little is known about the biology of C-Circles and if they may be clinically useful. Here we show that C-Circles are secreted by ALT+ cancer cells inside exosomes, and that a blood-based C-Circle Assay (CCA) can provide an accurate diagnostic for ALT activity. Extracellular vesicles were isolated by differential centrifugation from the growth media of lung adenocarcinoma, glioblastoma, neuroblastoma, osteosarcoma, and soft tissue sarcoma cell lines, and C-Circles were detected in the exosome fraction from all eleven ALT+ cancer cell lines and not in any extracellular fraction from the eight matching telomerase positive cancer cell lines or the normal fibroblast strain. The existence of C-Circles in ALT+ exosomes was confirmed with exosomes isolated by iodixanol gradient separation and CD81-immunoprecipitation, and C-Circles in the exosomes were protected from nucleases. On average, 0.4% of the total ALT+ intracellular C-Circles were secreted in the exosomes every 24 h. Comparing the serum-based and tumor-based CCAs in 35 high risk neuroblastoma patients divided randomly into ALT+ threshold derivation and validation groups, we found the serum-based CCA to have 100% sensitivity (6/6), 70% specificity (7/10), and 81% concordance (13/16). We conclude that the secretion of C-Circles by ALT+ cancer cells in the exosomes provides a stable blood-based biomarker and a potential clinical diagnostic for ALT activity.

Highlights

Telomere maintenance mechanisms (TMMs), telomerase, and alternative-lengtheningof-telomeres (ALT), are hallmarks of cancer that are required by cancer cells for continued growth and survival [1], and provide diagnostic and therapeutic opportunities
To determine how C-Circles are secreted by cancer cells, we collected 24 h-old cell culture medium and used differential centrifugation to isolate the secreted extracellular vesicles (ECV), which include apoptotic bodies (AB), microvesicles (MV), and exosomes (EXO) [24,36]
CD9, CD63, and CD81 are standardly used as exosome markers, a substantial proportion are usually found in the 18K (MV-enriched) pellet and the average proportion, 35%, found in the 18K pellet is consistent with the results reported by other research groups [36]

Summary

Introduction

Telomere maintenance mechanisms (TMMs), telomerase, and alternative-lengtheningof-telomeres (ALT), are hallmarks of cancer that are required by cancer cells for continued growth and survival [1], and provide diagnostic and therapeutic opportunities. ALT appears to be a homologous-recombination-directed DNA replication process [2] that requires PML-dependent localisation of the BLM-TOP3A-RMI (BTR) complex to telomeres [3] This co-localisation usually occurs in PML nuclear bodies, which, with the presence of telomeric DNA, are called ALT-associated PML bodies (APBs), a useful single cell ALT marker [4,5,6]. Another characteristic of ALT is heterogeneous telomere lengths ranging from (telomere) signal-free chromosome ends to abnormally long telomeres [2,4,7,8]. One type of ECTR associated with ALT activity is the C-Circle, a partially single stranded and circular molecule of C-rich telomeric DNA that is preferentially derived from lagging strand replicated telomeres [14,15]

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