Replication and transcription of eccDNAfib-L, an extrachromosomal circular DNA in the silk gland of silkworm, Bombyx mori.

Extrachromosomal DNA circularization is a common event in cancer cells and frequently serves as a vehicle for cancer oncogene amplification. Random segregation of oncogene-containing extrachromosomal circular DNA promotes rapid intercellular heterogeneity, conferring tumors the ability to rapidly evolve and escape therapy. Smaller, copy-number neutral extrachromosomal circular DNAs are also abundantly identified in both healthy and malignant tissues, but their function in cancer is still unknown. Understanding how extrachromosomal circular DNAs contribute to intercellular heterogeneity in cancer cells remains crucial, however methods for an unbiased characterization of extrachromosomal circular DNAs in single cells are lacking. We introduce scEC&T-seq (single cell extrachromosomal circular DNA and transcriptomic sequencing), a method for parallel detection of extrachromosomal circular DNAs and full-length mRNA in single cells. We demonstrate the ability of our method to isolate and detect extrachromosomal circular DNAs genome-wide from all range of sizes in single cells. We observed that whereas large oncogene-containing circular DNAs are clonally present in most cancer cells, only a very small fraction of small circular DNAs are recurrently identified in single cells, indicating yet unknown prerequisites for maintenance and propagation. Our method was able to capture and recapitulate the structural complexity of oncogene-containing extrachromosomal circular DNAs in single cells, and the matching transcriptomic data allowed us to identify fusion transcripts resulting from the rearranged extrachromosomal structures. In addition, we observed that whereas the main structure of extrachromosomal circular DNAs is mostly stable in single cells, intercellular differences in extrachromosomal circular DNAs’ content can drive differences in oncogene transcription levels in single cells. We envision that by integrating extrachromosomal circular DNA and mRNA sequencing, our method will not only be useful to investigate the impact of intercellular heterogeneity in extrachromosomal circular DNA in tumor evolution, but also to interrogate its function in other biological and pathological processes. Citation Format: Rocio Chamorro Gonzalez, Thomas Conrad, Robin Xu, Madalina Giurgiu, Maja Cwikla, Katharina Kasack, Lotte Brückner, Eric van Leen, Elias Rodriguez-Fos, Konstantin Helmsauer, Heathcliff Dorado Garcia, Yi Bei, Karin Schmelz, Sascha Sauer, Angelika Eggert, Johannes H. Schulte, Roland F. Schwarz, Kerstin Haase, Richard P. Koche, Anton G. Henssen. Dissecting intercellular extrachromosomal circular DNA heterogeneity in single cancer cells with scEC&T-seq [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 1693.

The silk gland of the silkworm Bombyx mori is a long tubular organ that is divided into several subparts along its anteroposterior (AP) axis. As a trait of terminal differentiation of the silk gland, several silk protein genes are expressed with unique regional specificities. Most of the Hox and some of the homeobox genes are also expressed in the differentiated silk gland with regional specificities. The expression patterns of Hox genes in the silk gland roughly correspond to those in embryogenesis showing “colinearity”. The central Hox class protein Antennapedia (Antp) directly regulates the expression of several middle silk gland–specific silk genes, whereas the Lin-1/Isl-1/Mec3 (LIM)-homeodomain transcriptional factor Arrowhead (Awh) regulates the expression of posterior silk gland–specific genes for silk fiber proteins. We summarize our results and discuss the usefulness of the silk gland of Bombyx mori for analyzing the function of Hox genes. Further analyses of the regulatory mechanisms underlying the region-specific expression of silk genes will provide novel insights into the molecular bases for target-gene selection and regulation by Hox and homeodomain proteins.

Rationale: Extrachromosomal circular DNA is a hallmark of cancer, but its role in shaping the genome heterogeneity of urothelial bladder carcinoma (UBC) remains poorly understood. Here, we comprehensively analyzed the features of extrachromosomal circular DNA in 80 UBC patients.Methods: We performed whole-genome/exome sequencing (WGS/WES), Circle-Seq, single-molecule real-time (SMRT) long-read sequencing of circular DNA, and RNA sequencing (RNA-Seq) on 80 pairs of tumor and AT samples. We used our newly developed circular DNA analysis software, Circle-Map++ to detect small extrachromosomal circular DNA from Circle-Seq data.Results: We observed a high load and significant heterogeneity of extrachromosomal circular DNAs in UBC, including numerous single-locus and complex chimeric circular DNAs originating from different chromosomes. This includes highly chimeric circular DNAs carrying seven oncogenes and circles from nine chromosomes. We also found that large tumor-specific extrachromosomal circular DNAs could influence genome-wide gene expression, and are detectable in time-matched urinary sediments. Additionally, we found that the extrachromosomal circular DNA correlates with hypermutation, copy number variation, oncogene amplification, and clinical outcome.Conclusions: Overall, our study provides a comprehensive extrachromosomal circular DNA map of UBC, along with valuable data resources and bioinformatics tools for future cancer and extrachromosomal circular DNA research.

Extrachromosomal circular DNA was recently found to be particularly abundant in multiple human cancer cells, although its frequency varies among different tumor types. Elevated levels of extrachromosomal circular DNA have been considered an effective biomarker of cancer pathogenesis. Multiple reports have demonstrated that the amplification of oncogenes and therapeutic resistance genes located on extrachromosomal DNA is a frequent event that drives intratumoral genetic heterogeneity and provides a potential evolutionary advantage. This review highlights the current understanding of the extrachromosomal circular DNA present in the tissues and circulation of patients with advanced cancers and provides a detailed discussion of their substantial roles in tumor regulation. Confirming the presence of cancer-related extrachromosomal circular DNA would provide a putative testing strategy for the precision diagnosis and treatment of human malignancies in clinical practice.

Extrachromosomal circular DNAs (eccDNAs) can be originated from the sequences of chromosomes, and have high heterogeneity in origin. In different surroundings, the production of eccDNAs involves various generation model and repair mechanisms. Technologies as high throughput sequencing (HTS) greatly help to identify more eccDNAs. Recently, eccDNAs were found in human circulating system. EccDNAs can affect cell life activities, promote tumor cell adaptive evolution and increase the genome plasticity and instability. EccDNAs show great potential in diagnosis, prognosis prediction and treatment of tumors and in liquid biopsy as well. The purpose of this review is to elucidate the research progress on the origin, function, study strategy and potential utility of human eccDNAs. Key words: Extrachromosomal circular DNA; Episome; Double minutes; Small polydispersed circular DNA; microDNA; Liquid biopsy

Extrachromosomal circular DNA (eccDNA) is a fascinating form of genetic material found outside the usual chromosomal DNA in eukaryotic cells, including humans. Since its discovery in the 1960s, eccDNA has been linked to critical roles in cancer progression and age-related diseases. This review thoroughly explores eccDNA, covering its types, how it forms, and its significant impact on diseases, particularly cancer. EccDNA, especially in its extrachromosomal DNA (ecDNA) form, contributes to the genetic diversity of tumour cells, helping them evolve quickly and resist treatments. Beyond cancer, eccDNA is also connected to age-related conditions like Werner syndrome, amyotrophic lateral sclerosis (ALS), and type 2 diabetes mellitus (T2DM), where it may affect genomic stability and disease development. The potential of eccDNA as a biomarker for predicting disease outcomes and as a target for new treatments is also highlighted. This review aims to deepen our understanding of eccDNA and inspire further research into its roles in human health and disease, paving the way for innovative diagnostic and therapeutic approaches.

Still unresolved is the question of how a lifetime accumulation of somatic gene copy number alterations impact organ functionality and aging and age-related pathologies. Such an issue appears particularly relevant in the broadly post-mitotic central nervous system (CNS), where non-replicative neurons are restricted in DNA-repair choices and are prone to accumulate DNA damage, as they remain unreplaced over a lifetime. Both DNA injuries and consecutive DNA-repair strategies are processes that can evoke extrachromosomal circular DNA species, apparently from either part of the genome. Due to their capacity to amplify gene copies and related transcripts, the individual cellular load of extrachromosomal circular DNAs will contribute to a dynamic pool of additional coding and regulatory chromatin elements. Analogous to tumor tissues, where the mosaicism of circular DNAs plays a well-characterized role in oncogene plasticity and drug resistance, we suggest involvement of the “circulome” also in the CNS. Accordingly, we summarize current knowledge on the molecular biogenesis, homeostasis and gene regulatory impacts of circular extrachromosomal DNA and propose, in light of recent discoveries, a critical role in CNS aging and neurodegeneration. Future studies will elucidate the influence of individual extrachromosomal DNA species according to their sequence complexity and regional distribution or cell-type-specific abundance.

Penetrance and low concordance in monozygotic twins in disease: are they the results of alterations in somatic genomes?

Tissue-specific and age-related variations in repetitive sequences of mouse extrachromosomal circular DNAs

Chinese hamster ovary (CHO) cell lines are widely used to manufacture biopharmaceuticals. However, CHO cells are not an optimal expression host due to the intrinsic plasticity of the CHO genome. Genome plasticity can lead to chromosomal rearrangements, transgene exclusion, and phenotypic drift. A poorly understood genomic element of CHO cell line instability is extrachromosomal circular DNA (eccDNA) in gene expression and regulation. EccDNA can facilitate ultra-high gene expression and are found within many eukaryotes including humans, yeast, and plants. EccDNA confers genetic heterogeneity, providing selective advantages to individual cells in response to dynamic environments. In CHO cell cultures, maintaining genetic homogeneity is critical to ensuring consistent productivity and product quality. Understanding eccDNA structure, function, and microevolutionary dynamics under various culture conditions could reveal potential engineering targets for cell line optimization. In this study, eccDNA sequences were investigated at the beginning and end of two-week fed-batch cultures in an ambr®250 bioreactor under control and lactate-stressed conditions. This work characterized structure and function of eccDNA in a CHO-K1 clone. Gene annotation identified 1551 unique eccDNA genes including cancer driver genes and genes involved in protein production. Furthermore, RNA-seq data is integrated to identify transcriptionally active eccDNA genes.

Duplication plays an important role in creating drastic changes in genome evolution. In addition to well-known tandem duplication, duplication can occur such that a duplicated DNA fragment is inserted at another location in the genome. Here, we report several genomic regions in the human genome that could be best explained by two types of insertion-based duplication mechanisms, where a duplicated DNA fragment was modified structurally and then inserted into the genome. In one process, the DNA fragment is turned into an extrachromosomal circular DNA, cut somewhere in the circle, and reintegrated into another location in the genome. And in the other, the DNA fragment forms a “lariat structure” with a “knot”, the strand is swapped at the knot, and is then reintegrated into the genome. Our results suggest that insertion-based duplication may not be a simple process; it may involve a complicated procedures such as structural modification before reintegration. However, the molecular mechanism has yet to be fully understood.

Extrachromosomal circular DNA (eccDNA), an extrachromosomal circular structured DNA, is extensively found in eukaryotes. Investigating eccDNA at the single-cell level is crucial for understanding cellular heterogeneity, evolution, development, and specific cellular functions. However, high-throughput identification methods for single-cell eccDNA are complex, and the lack of mature, widely applicable technologies has resulted in limited resources. To address this gap, we built scEccDNAdb, a database based on single-cell whole-genome sequencing data. It contains 3 195 464 single-cell eccDNA entries from human and mouse samples, with annotations including oncogenes, typical enhancers, super-enhancers, CCCTC-binding factor-binding sites, single nucleotide polymorphisms, chromatin accessibility, expression quantitative trait loci, transcription factor binding sites, motifs, and structural variants. Additionally, it provides nine online analysis and visualization tools, which enable the creation of publication-quality figures through user-uploaded files. Overall, scEccDNAdb is a comprehensive database for analyzing single-cell eccDNA data across diverse cell types, tissues, and species. Database URL: https://lcbb.swjtu.edu.cn/scEccDNAdb/.

Breaking the vicious circle: Extrachromosomal circular DNA as an emerging player in tumour evolution

Extrachromosomal circular DNA (ecDNA) has gained renewed interest since its discovery more than half a century ago, emerging as critical driver of tumor evolution. ecDNA is highly prevalent in many types of cancers, including colorectal cancer (CRC), which is one of the most deadly cancers worldwide. ecDNAs play an essential role in regulating oncogene expression, intratumor heterogeneity, and resistance to therapy independently of canonical chromosomal alterations in CRC. Furthermore, the existence of ecDNAs is attributed to the patient’s prognosis, since ecDNA-based oncogene amplification adversely affects clinical outcomes. Recent understanding of ecDNA put an extra layer of complexity in the pathogenesis of CRC. In this review, we will discuss the current understanding on mechanisms of biogenesis, and distinctive features of ecDNA in CRC. In addition, we will examine how ecDNAs mediate oncogene overexpression, gene regulation, and topological interactions with active chromatin, which facilitates genetic heterogeneity, accelerates CRC malignancy, and enhances rapid adaptation to therapy resistance. Finally, we will discuss the potential diagnostic and therapeutic implications of ecDNAs in CRC.

Extrachromosomal circular DNAs and genomic sequence plasticity in eukaryotic cells