key: cord-1051573-2b4g36bu
authors: Grabuschnig, Stefan; Bronkhorst, Abel Jacobus; Holdenrieder, Stefan; Rosales Rodriguez, Ingund; Schliep, Klaus Peter; Schwendenwein, Daniel; Ungerer, Vida; Sensen, Christoph Wilhelm
title: Putative Origins of Cell-Free DNA in Humans: A Review of Active and Passive Nucleic Acid Release Mechanisms
date: 2020-10-29
journal: Int J Mol Sci
DOI: 10.3390/ijms21218062
sha: 323a46fdc27000cda754501a1a76d06ce4926eeb
doc_id: 1051573
cord_uid: 2b4g36bu

Through various pathways of cell death, degradation, and regulated extrusion, partial or complete genomes of various origins (e.g., host cells, fetal cells, and infiltrating viruses and microbes) are continuously shed into human body fluids in the form of segmented cell-free DNA (cfDNA) molecules. While the genetic complexity of total cfDNA is vast, the development of progressively efficient extraction, high-throughput sequencing, characterization via bioinformatics procedures, and detection have resulted in increasingly accurate partitioning and profiling of cfDNA subtypes. Not surprisingly, cfDNA analysis is emerging as a powerful clinical tool in many branches of medicine. In addition, the low invasiveness of longitudinal cfDNA sampling provides unprecedented access to study temporal genomic changes in a variety of contexts. However, the genetic diversity of cfDNA is also a great source of ambiguity and poses significant experimental and analytical challenges. For example, the cfDNA population in the bloodstream is heterogeneous and also fluctuates dynamically, differs between individuals, and exhibits numerous overlapping features despite often originating from different sources and processes. Therefore, a deeper understanding of the determining variables that impact the properties of cfDNA is crucial, however, thus far, is largely lacking. In this work we review recent and historical research on active vs. passive release mechanisms and estimate the significance and extent of their contribution to the composition of cfDNA.

Cell-free DNA (cfDNA) is a fraction of circulating nucleic acids (CNAs), which was discovered and first described by Mandel and Metais, in 1948 [1] . The term encompasses all kinds of extracellular DNA molecules found in serum or plasma and other body fluids [2] of vertebrates and includes genomic and mitochondrial host DNA [3, 4] , as well as foreign DNA [5, 6] , for example, of bacterial or viral origin. The cfDNA molecules occur predominantly in the form of double-stranded DNA genomic and mitochondrial host DNA [3, 4] , as well as foreign DNA [5, 6] , for example, of bacterial or viral origin. The cfDNA molecules occur predominantly in the form of double-stranded DNA (dsDNA) [7] and are mostly of small size, ranging between 100 and 200 base pairs (bp) [8] . Larger fragments, even in the range of several kilobase pairs (Kbp) have also been reported [9] [10] [11] .

In 1973, Leon et al. showed that cancer patients exhibited elevated levels of cfDNA in serum [12] . For this purpose, the group developed and performed a radioimmunoassay, where 125 I-Iododeoxyuridine labelled DNA was detected via antibodies from a lupus erythematosus patient. Similar results had already been described by Tan et al., in 1966 , [13] for systemic lupus erythematosus, and even as early as 1948, Mandel and Metais [1] showed that cfDNA levels were elevated in several disease conditions. Although the cfDNA concentrations in the serum declined in correlation with improved clinical conditions after treatment, Leon et al. were initially skeptical about the potential diagnostic value of cfDNA, because approximately half of the cancer patients had serum cfDNA concentrations that were within the same low range as found in healthy subjects. However, the group kept pursuing the idea of a cfDNA-based assay for benign and malignant gastrointestinal diseases [14] due to their discovery that high serum cfDNA levels were associated with other pathological conditions, such as rheumatoid arthritis [15] and pulmonary embolism [16] .

Since then, a wide range of diagnostic approaches, collectively referred to as "liquid biopsies", has been developed [17, 18] . While cancer-related approaches have often targeted circulating tumor DNA (ctDNA), carrying cancer-specific genetic alterations [19, 20] , other strategies have involved length profiling of cfDNA molecules [10] or screening for epigenetic modifications [21] , which were specific for various malignancies [22] . Another well-established application for cfDNA-based liquid biopsies is the cell-free foetal DNA (cffDNA)-based prenatal test for the detection of Down syndrome and other trisomies in maternal blood [23] [24] [25] [26] .

Altogether, a large number of studies are currently focused on the diagnostic capabilities of cfDNA [17, 18, 22] , while the characterization of the molecular mechanisms [27] underlying their release and biology remains largely neglected. Therefore, the purpose of this review is to outline the mechanisms of cfDNA release into the bloodstream and the biological properties of cfDNA molecules, as known thus far ( Figure 1 ). hematopoietic stem cells [71, 72] , involves several intermediate stages and occurs mostly in bone marrow, but also in the spleen and liver [71, 73] . While nuclei of vertebrate RBCs become highly condensed, pyknotic, and transcriptionally inactive during maturation in general [69] , mature mammalian erythrocytes even lack a nucleus [70] [71] [72] . This was discovered in 1875 by Gulliver [74] and was thought to enable higher hemoglobin levels in the blood [69, 72] . The process of enucleation (formerly also called denucleation), which was visualized via electron microscopy by Simpson in 1967 [75] , occurred at the stage of orthochromatic erythroblasts at the erythroblastic islands [70, 71, 73] , which were discovered by Bessis, in 1958 [76] . Erythroblastic islands consist of a central macrophage, surrounded by physically attached erythroblasts, which mature from proerythroblasts via basophilic and polychromatophilic forms to orthochromatic erythroblasts, losing all organelles in the process [70, 71, 73] . Orthochromatic erythroblasts finally exit their cell cycle and enucleate, separating into a reticulocyte and into a pyrenocyte [70] [71] [72] . Reticulocytes contain most of the cytoplasm [77] and enter into the bloodstream, where they mature within a time frame of approximately two days [71] . Pyrenocytes consist of the nucleus which is surrounded by a thin rim of cytoplasm and the plasma membrane [78] . They are readily phagocytized by the central macrophage [70, 71, 73] , which is promoted by phosphatidylserine residues on their surface, acting as "eat-me" signals [71, 72, 79] . Engulfed nuclei are subsequently digested by DNaseII in lysosomes [72, 80] .

Although, in the literature, erythroblast enucleation has been repeatedly suggested to be a potential source of cfDNA [27, [81] [82] [83] , experimental evidence for this hypothesis is relatively sparse. When analyzing blood plasma of sex-mismatched bone marrow transplantation patients via quantitative real-time PCR (qPCR), Lui et al. (2002) [84] found that plasma cfDNA was predominantly of donor origin, and they concluded that cfDNA stemmed largely from cells of the hematopoietic lineage. This conclusion was confirmed by methylation-based tissue-mapping approaches [85, 86] and by nucleosome footprint analyses [43] , where it was stated that approximately 55% of cfDNA originated from white blood cells and 30% from erythrocyte progenitors [86, 87] . Exercise-induced elevation of cfDNA levels in the blood was also attributed to cells of the hematopoietic linage by Tug et al. (2015) [83] in an analysis of cfDNA from sex-mismatched hematopoietic stem cell recipients via qPCR. Using high-resolution methylation profiles, Lam et al. (2017) [88] identified three genomic loci featuring erythroblast-specific low methylation density. They determined that erythroid DNA represented about 30% of the plasma cfDNA via qPCR and postulated that degraded erythroblast DNA from bone marrow could somehow escape into circulation. The question of how exactly DNA from pyrenocytes relates to cfDNA fragments, which can be found in the blood plasma or serum, remains largely unanswered thus far.

Another mechanism, the release of neutrophil extracellular traps (NETs), which can lead to the creation of cfDNA, was discovered more recently [89] . NETs have been characterized as an innate response of neutrophils, with the function to trap and kill microorganisms. According to Yipp et al. [90] , the indications for this process, which have been termed NETosis [91, 92] , were observed earlier, but not named or recognized as an independent event. The NETosis process is now accepted as an independent reaction to a threat and is considered to be different from apoptosis and necrosis.

NETs consist of disintegrated chromatin, which "trap" the microorganisms, and also serves as an anionic binding matrix for different antimicrobial proteins in order to kill the entrapped bacteria [90, 93, 94] . The proteins are usually found in granules inside of the cell and are released during NETosis. This release can occur either slowly, via a lytic cell death, or rapidly, via an explosive discharge of disintegrated chromatin and peptides, while the cell remains functional and can still respond to the surroundings [93, 94] . These two different forms of NETosis are termed suicidal and vital [90] , respectively. The mechanism of the NET formation was initially considered to be solely the result of NADPH oxidase-dependent production of reactive oxygen species (ROS) [91] , but evidence for NADPH independent pathways was discovered subsequently [95, 96] . There was also evidence that cell cycle proteins could be regulating NET formation [97] .

Persistent NET structures in the bloodstream can lead to vascular occlusion [40] , therefore, an effective removal system is required. It has been shown that the degradation of the released chromatin starts by host DNases circulating in the body fluid. The degradation is performed by two independent DNases, namely, DNaseI and DNaseI L-3 [40] . This breakdown of the chromatin is not the only process of NET removal, as the full clearing is performed with the support of macrophages [98] . It seems that DNases are involved with preprocessing the NET structure, while the total NET removal is performed by macrophages and other cell types incorporating and digesting the remainders of the NETs.

There is an indication that NETs may have an influence on cfDNA levels, since large amounts of DNA are released into the bloodstream, or into tissues, in a relatively short time. This influence has been studied for different health conditions and can correspond to increased cfDNA levels in diseased patients [99] . The cfDNA levels are also influenced by stalling the degradation process. Several diseases have been shown to lead to problems with a regulated full degradation of NETs, thus leading to higher cfDNA levels [100] [101] [102] [103] .

In addition to the degradation by endogenous DNases, it has also been shown that different species of bacteria could escape NETs by degrading the chromatin matrix via the release of DNases [104] [105] [106] [107] . It may be possible that bacterial DNases produce different fragments of NETs as compared with the endogenous DNase degradation system, which could lead to an altered degradation pattern. To date, there is a lack of evidence for all of these possibilities. To protect the NET structures and preserve their antimicrobial character, the immune system coats the chromatin fraction with peptides, such as LL-37 and defensin-3 against degradation, which then hinders the activity of these DNases [108] .

NETs do not always have beneficial effects during an immune response and the response to a threat by NETosis can even have detrimental effects for the organism. It has been shown, for example, that dormant cancer cells can be reactivated during inflammation reactions involving NETs in mice [109] . In chronic inflammation reactions, the lytic cell death mechanism has been shown to be proinflammatory, and therefore could counteract medical treatments [110] . It was also shown by Katkar et al. [111] that an exaggerated immune response, containing NETs together with the lack of DNase activity, was the main cause of tissue destruction by snake venom in mice. Tissue destruction due to NETosis and the following immune response were shown in this particular response, and also in other instances [99] . The same response pattern, together with increased cfDNA levels, has also been shown in patients with active COVID-19 infection, as recently reported by Zuo et al. [112] .

Gahan and Stroun [113] coined the term virtosome, in 2010, to describe a circulating DNA-RNA-lipoprotein complex, which was actively released from living cells. Active release of DNA was first observed for stimulated lymphocyte cells [114] . Subsequently, DNA release was also shown for non-stimulated rat and human lymphocytes [115, 116] . Furthermore, DNA release was observed for different eukaryotic cell types, for example, frog heart auricles [117] or rat spleen [118] mostly using in vitro studies, but it was also observed in vivo, for example using chick embryo fibroblasts [119] . The release was dependent on the concentration of the complex in the medium, with high concentrations in the environment suppressing further release [115, 120] . The release mechanism itself was mostly unknown, however it was suggested that it may appear in phase G0 or G1 of the cell cycle [113] .

It has been confirmed previously, by means of a 3 H-thymidine labeling study, that DNA was newly synthesized within the cell [115] . The presence of proteins and lipids after treatment of the complex with proteinase K or lipase was observed and showed RNase activity [118] . A recent study by Cataldi and Viola-Magni [120] quantified the composition of virtosomes released from human lymphocytes into both the cytoplasm and the cell culture supernatant. This study found that the complexes in the cytoplasm contained approximately 3.45% DNA, 35.09% RNA, 19.90% phospholipids, and 41.01% proteins. Correspondingly, the cell culture supernatants contained 3.92% DNA, 36.41% RNA, 32.21% phospholipids, and 27.44% proteins. It was also suggested that there was no membrane around the virtosome [121] , which was further supported by the low proportion of cholesterol and phosphatidylcholine in the complex [120] . These DNA molecules were believed to be around 450-700 bp long [113] . To our knowledge, there have not yet been any reports describing sequencing results (DNA and RNA) of virtosome complexes, which could be used to shed light onto the composition and specific origin of this fraction of cfDNA. Cells can uptake the virtosome complex [113] that has been released from cells of different cell types and the virtosomes can modify the biology of the receiving dividing cells [122, 123] . This indicates that the virtosome complexes may be involved in signaling pathways between different cell types or horizontal gene transfer.

It is worth noting that Gahan and Stroun [113] pointed out several similarities between virtosomal DNA and metabolic DNA. It has been suggested that this unique population of DNA results from unscheduled DNA synthesis and occurs independently from the high molecular weight chromatin mass in cell nuclei [27, 124] . In an early study of adult mouse heart, intestine, and skeletal muscle, it was found that metabolic DNA ranged between 500,000 and 4,000,000 Daltons [125] which equated to approximately 769 bp-6 Kbp in size. Interestingly, cfDNA fragments which exhibited this size profile have been observed in the supernatant of various cultured cell lines [126] [127] [128] and have been shown to be part of the cargo of some EVs [62, 129, 130] . They are often encountered in human biospecimens [131] [132] [133] . While it is an interesting possibility that metabolic DNA could serve as the precursor to larger~1-6 Kbp cfDNA fragments, more research is needed to determine whether they truly represent a population of cfDNA originating from a regulated extrusion pathway, or whether they are simply the product of passive release mechanisms, such as apoptosis or necrosis.

The release of EVs by cells was first described in 1967 for chondrocytes [134] and blood platelets [135] . These vesicles are characterized as single-lipid bilayer membrane extracellular organelles of simple spheroid morphology, which are present in all biological fluids tested thus far [136] [137] [138] . Constitutive release of EVs was reported for prokaryote [139] and eukaryote [134] [135] [136] [137] [138] cells and was considered to be a part of the normal physiology of all cells [138, 140] . Currently, three main types can be distinguished, based on their size and their mechanisms of biogenesis [136, 137, 141] (Figure 2 ). Apoptotic bodies with diameters of 500-5000 nm are formed in the course of cell disintegration during programmed cell death [53, 142] . Ectosomes, which encompass microparticles, microvesicles, and large vesicles with diameters from 50 to 1000 nm, are released directly from the plasma membrane via outward budding and fission [142, 143] . Exosomes, with diameters of 30-200 nm, have been released via fusion of multivesicular bodies (MVBs) with the plasma membrane [136, 137, 141, 143] , which was first shown for rat reticulocytes, in 1983 [144] . The association of EVs with dsDNA was initially reported for human prostasomes, which were EVs secreted by the tissue of the prostatic gland, in a preliminary lab report from Olsson and Ronquist, in 1990 [145] . This result was finally confirmed almost twenty years later by Ronquist et al. (2009) [146] . In the following year, Guescini et al. (2010) [147] , reported the presence of mitochondrial DNA (mtDNA) in EVs, which were characterized as exosomes released from astrocytes and glioblastoma cells. In prokaryotes, the release of DNA-containing outer membrane vesicles (OMVs) was first described, in 1989, by Dorward et al. [148] for Neisseria gonorrhoeae and by Garon et al. [149] for Borrelia burgdorferi. The studies also both showed that the encapsulated DNA was protected from digestion by DNaseI. When screening for viruses in hyperthermophilic archaea of the order Thermococcales, Soler et al. (2008) [150] observed the release of spherical membrane vesicles containing cellular DNA, which were not related to any viral activity and also exhibited resistance to DNase digestion. satellite repeat DNA [154, 168] , suggests that other mechanisms could contribute to the abundance of cytosolic DNA fragments in a significant way. This overrepresentation of DNA from RTEs and satellite repeats has been found for cancer-cell culture supernatants [168, 169] , as well as the serum of healthy human subjects [169] . The respective fractions of these elements were significantly increased in human sepsis patients (bacterial and fungal sepsis), indicating an increased release in response to their medical condition [169] . 

Recent reports have indicated the possibility that a portion of the total cfDNA population in vitro, as well as in vivo, could be a product of the effects of chromosome instability (CIN). CIN is one form of genetic instability that is characterized by sustained and often accelerated changes in the chromosome structure or number [170] . There are different pathways through which CIN results in the release of genomic DNA into the extracellular space, each of which can be modulated by a wide range of biological factors, thus, representing multiple layers of regulation [168] . Here, we limit the focus to specific chromosome mis-segregation events that can occur during mitosis.

After DNA replication, chromosomes possess two kinetochores, which are complex protein structures that serve as attachment points for the mitotic spindle. In the prometaphase, these kinetochores interact with spindle microtubules in both a lateral and end-on fashion. During the metaphase, each kinetochore binds to microtubules oriented towards opposite spindle poles. These bi-oriented kinetochore-microtubule (k-MT) attachments are crucial for the proper alignment and segregation of the chromosomes that are attached to the spindle [171] . However, due to the asynchronous and stochastic nature of the initial capture of microtubules by kinetochores, some k-MT attachments are not bi-oriented, resulting in either delayed or inappropriate attachment of chromosomes to the spindle during the prometaphase-to-metaphase transition [172] . Among the A number of studies have demonstrated that DNA was affiliated with exosomes [129, [151] [152] [153] and microvesicles [154, 155] , which were, for example, derived from diverse tumor types [129, 151, 152, 154, 156] or normal cells [155] [156] [157] [158] . Furthermore, it has been shown that DNA molecules originating from both healthy [155, 157, 158] and tumor [153, 154, 159] cells could be transferred to other cells via EVs and may affect gene expression [155, [157] [158] [159] . Similar observations have been made for bacterial DNA shuttled by OMVs [148, 160] . Apart from affecting the gene expression of recipient cells, stable genomic integration of DNA transferred by vesicles was also shown in a proof-of-principle experiment by Fischer et al. (2016) [161] . Therefore, it is clear that EVs constitute a distinct, and perhaps biologically active, subpopulation of cfDNA molecules. However, several aspects concerning EV-associated cfDNA remain poorly understood, mainly because the phenomenon has, thus far, been underinvestigated and conflicting results have been reported in the literature.

One reason is that a fraction of the total cfDNA population in the blood plasma or serum, which is associated with EVs has not yet been clearly defined. An early study suggested that, rather than floating freely, the majority of cfDNA in the blood of cancer patients was contained within exosomes [152] . In support of this, Fernando et al. (2017) observed that up to 90% of the cfDNA in human blood was exosome-associated [62] . In contrast, Helmig et al. (2015) found that only about 5% of the total cfDNA population in blood collected from healthy individuals before and after physical exercise was associated with EVs [82] . Taking into consideration the relatively short half-life of free-floating cfDNA [87, 162] , the discrepancy between the reported proportions of vesicle-associated cfDNA in the above studies may be explained by different sample handling procedures. For example, in the study by Helmig et al., 2015, [82] , the blood was analyzed directly after the blood draw, while the blood samples used in both the Kahlert et al. (2014) [152] and Fernando et al. (2017) [62] studies were taken at an external facility with a larger temporal delay before the analysis.

A second aspect is the question that, prior to its release from cells, it is not clear what fraction of the genomic DNA is packaged within the interior of the EVs vs. molecules that are attached to their exterior surface. In line with this, it is not known how much cfDNA can and does attach to different EVs after entering the extracellular space. [163] who reported that cfDNA was mainly associated with the outer membrane surface of EVs, with a smaller amount being contained within the vesicles. However, additional research is needed to determine the exact proportions in baseline conditions, as well as changes upon various stimuli.

Third, relatively little is known about the biological and physiological characteristics of EV-associated DNA, including, but not limited to the following: (i) the mechanisms that underlie the vesicle-mediated release of DNA molecules, (ii) the relative proportion of the total EV-associated cfDNA population that is complexed with each of the different EV types (i.e., apoptotic bodies, microvesicles, and exosomes), (iii) the physiological factors that modulate these mechanisms, and ultimately (iv) the relative contribution of different cell types toward the total EV-associated cfDNA population. Despite the lack of research on these topics, some recent studies provide at least some insights. Takahashi et al. (2017) [164] , described the sustained exocytosis of DNA fragments via exosomes as an important physiological process for the preservation of cellular homeostasis, where the inhibition of exosome secretion led to intracellular accumulation of cytosolic DNA. This resulted in the activation of the ROS-dependent DNA damage response, followed by senescence and ultimately cell death. They also observed an increased release of DNA via exosomes in senescent cells. This suggests that cytosolic DNA fragments can be a significant source of intracellular stress, which is connected to increased exosome secretion, as described by Hessvik and Llorente (2017) [136] . MVBs can either be directed to lysosomes, where their content is degraded, or to the cell membrane, where they fuse with the membrane and release their vesicular content into the extracellular space as exosomes [136, 142] . The destination of MVBs is considered to be dependent on cellular homeostasis [136, 165, 166] . Such an increase in exosome secretion in connection to a stress response has also been described for bacteria [160] . It is also noteworthy that Brahmer et al. (2019) [167] reported an increased release of EVs triggered by exercise. They identified endothelial cells, platelets, as well as different types of leukocytes, to be the main sources of these vesicles. Since the DNA cargo of the vesicles was not addressed in the study, the question of whether the increase in vesicles could lead to an increased amount of vesicle-associated DNA in the bloodstream remains currently unanswered.

Fourth, and in line with the previous point, the composition and size of the cfDNA molecules that are associated with EVs is unclear. Studies have shown that EVs contain fragments of single-stranded DNA [154] , double-stranded DNA [129, 151, 152] , as well as mtDNA [147, 153] . These fragments have been found to range from as small as~100 bp up to sizes exceeding 10 Kbp [129, 152, 154] . While the excreted cytosolic DNA fragments have long been thought to be a product of DNA damage [159, 164] , the heterogeneous composition of the exosomal DNA content, which features disproportionally large amounts of DNA from retro-transposable elements (RTEs) and satellite repeat DNA [154, 168] , suggests that other mechanisms could contribute to the abundance of cytosolic DNA fragments in a significant way. This overrepresentation of DNA from RTEs and satellite repeats has been found for cancer-cell culture supernatants [168, 169] , as well as the serum of healthy human subjects [169] . The respective fractions of these elements were significantly increased in human sepsis patients (bacterial and fungal sepsis), indicating an increased release in response to their medical condition [169] .

Recent reports have indicated the possibility that a portion of the total cfDNA population in vitro, as well as in vivo, could be a product of the effects of chromosome instability (CIN). CIN is one form of genetic instability that is characterized by sustained and often accelerated changes in the chromosome structure or number [170] . There are different pathways through which CIN results in the release of genomic DNA into the extracellular space, each of which can be modulated by a wide range of biological factors, thus, representing multiple layers of regulation [168] . Here, we limit the focus to specific chromosome mis-segregation events that can occur during mitosis.

After DNA replication, chromosomes possess two kinetochores, which are complex protein structures that serve as attachment points for the mitotic spindle.

In the prometaphase, these kinetochores interact with spindle microtubules in both a lateral and end-on fashion. During the metaphase, each kinetochore binds to microtubules oriented towards opposite spindle poles. These bi-oriented kinetochore-microtubule (k-MT) attachments are crucial for the proper alignment and segregation of the chromosomes that are attached to the spindle [171] . However, due to the asynchronous and stochastic nature of the initial capture of microtubules by kinetochores, some k-MT attachments are not bi-oriented, resulting in either delayed or inappropriate attachment of chromosomes to the spindle during the prometaphase-to-metaphase transition [172] . Among the various k-MT attachment errors that can occur, merotelic attachments constitute a pathway for the generation of cfDNA. In merotelic attachments, one kinetochore binds to microtubules growing from opposite spindle poles [173, 174] . Since merotelic attachments are not detected by the mitotic spindle checkpoint, cells can proceed to anaphase without completing error correction [175] . Although most merotelic chromosomes segregate correctly during anaphase, a small fraction remain at the spindle equator, resulting in lagging chromosomes [173] . Interestingly, if there is sufficient distance between a lagging chromosome and the main chromatin mass at the end of cell division, the lagging chromosome can recruit its own nuclear envelope and form a so-called micronucleus (MN), which is also known as a Howell-Jolly body [176] . In such cases, an interphase daughter cell contains the following two types of nuclei: (a) the primary large nucleus and (b) up to several smaller micronuclei (MNi) that house the mis-segregated chromosomes. While chromosome lagging and micronucleation can occur at low levels in normal cells [175, 177] , increased levels of MNi have been shown for various pathologies, especially in cancer cells with CIN [178] [179] [180] [181] [182] . In keeping with this, we hypothesize that MNi, with their DNA cargo, may translocate to the extracellular space and serve as one of the sources of cfDNA.

Apart from fundamental chromosome segregation errors, such as merotely, MNi can also arise during mitosis as a result of telomere loss. Telomeres preserve genomic stability by protecting natural chromosome ends from degradation, illegitimate self-recombination, and end joining with nearby chromosomes [183] . However, in certain cases (e.g., cancer), accelerated shortening of telomeres (loss of the terminal sequence), or complete loss of the end-capping structure is a prevalent feature [168, [184] [185] [186] [187] . Loss of telomeres is mainly the consequence of the following: (i) attrition of telomere repeats, which is typically associated with repression or reduced activity of telomerase [188] ; (ii) loss of specific telomeric proteins, which may prompt the cell to identify chromosome ends as DNA breaks [189] ; or (iii) double-stranded DNA breaks (DSBs), which may form as a result of hypomethylation followed by transposon-induced breaks [190] [191] [192] , mis-repaired breaks caused by radiation [193] [194] [195] [196] , and deprivation of important metabolites, for example, folate [197, 198] . When a telomere-deficient chromosome is replicated, the two ends of the sister chromatids fuse and form a chromosome with two centromeres, i.e., a dicentric chromosome [199, 200] . Since a dicentric chromosome is able to attach to both spindle poles, the two centromeres are pulled to opposite poles during the anaphase, forming a continuous string of chromatin, stretching from one pole to the other, normally referred to as an anaphase bridge [201] . Anaphase bridges often break, resulting in various chromosomal abnormalities, often followed by the formation of MNi. The characteristics of the MNi and its DNA content depend on the location of the breaking point in the anaphase bridge [202] [203] [204] [205] .

Repeated pulling apart of dicentric chromosomes, anaphase bridge formation, and subsequent breakage in gene regions over multiple cell divisions, also known as breakage-fusion-bridge (BFB) cycles, results in the amplification of DNA sequences that are adjacent to the break or fusion point [201, 206] . The BFB cycles are typically sustained until the chromosome acquires a new telomere. However, during the process, recombination of homotypic sequences within the amplified DNA often results in the formation of mini circles of acentric and atelomeric DNA, which are eliminated from the aberrant chromosome. These structures, which are known as double minutes (DMs) [201, 206] , are capable of replication and can also localize to the nuclear periphery, exit the nucleus through budding, and eventually become extruded from cells in the form of microcells [203, 207] . When they are in the form of nuclear buds (NBUDs) after exiting the nucleus, they have a similar morphology as the typical MN [202] . Interestingly, this extra-chromosomally amplified DNA frequently consists of oncogenes [208] [209] [210] . This process, which is summarized in Figure 3 , may explain the recently reported presence of extrachromosomal circular DNA in the circulatory system of both mice and humans [211] [212] [213] . It may also explain the significant overrepresentation of specific retrotransposons in the cfDNA isolated from the cell culture supernatant of human bone osteosarcoma (143B) cells [168] . A chromosome that has lost its telomere (1) is replicated (2) and the sister chromatids fuse at the broken ends, forming a dicentric chromosome (3). The two centromeres are, then, pulled to opposite spindle poles during the anaphase, stretching out the chromatin to form an anaphase bridge (4). In many cases an anaphase bridge breaks (5) and the broken telomere-deficient chromosomes are again replicated (6) and once again fuse with their sister chromatids (7) . Several repetitions of this process result in the amplification of DNA sequences that are adjacent to the break or fusion point. An anaphase bridge may break in various regions, resulting in the amplification of different genomic regions (e.g., genes, oncogenes, and repetitive DNA). Recombination between homotypic sequences within the amplified DNA generates extrachromosomal circular DNA (8) , which can eventually become looped out of the chromosome (9). These mini circles of DNA can subsequently be extruded from the nucleus through budding (10) and eventually become extruded from cells into the extracellular space (11).

Cell death, primarily via apoptosis or, under certain circumstances, necrosis, has often been considered to be the only relevant mechanism of DNA release into the bloodstream. This assumption has been justified by the non-random fragmentation pattern of circulating cfDNA [44, 66, 67] . In contrast, several active mechanisms for the release of cfDNA from cells have now also been described, where, for instance, a considerable fraction of the total cfDNA, which is attributed to the erythroid cell lineage [85] [86] [87] 228] , cannot sufficiently be explained by cell death, since mature erythrocytes do not possess a nucleus when undergoing eryptosis (erythrocyte apoptosis) [229] . Additionally, the mechanism of NETosis, which contributes substantially to the cfDNA fraction is not considered to be a passive mechanism [92, 230] . Active release of DNA has been observed in many parts of the eukaryotic kingdom, i.e., it has been observed, for example, in humans, rats [231] , chickens [232] and allomyces arbusculus (fungi) [233] . However, in these papers, there were no detailed characterizations described which dealt with the mechanism of cfDNA or the associated functions. This led Elzanowska et al. (in 2020) [234] to conclude that "DNA can also be released from living cells by active cellular secretion, although at present little is known about why functional cells secrete DNA Figure 3 . Breakage-fusion-bridge cycles as a potential source of cell-free DNA (cfDNA). A chromosome that has lost its telomere (1) is replicated (2) and the sister chromatids fuse at the broken ends, forming a dicentric chromosome (3) . The two centromeres are, then, pulled to opposite spindle poles during the anaphase, stretching out the chromatin to form an anaphase bridge (4). In many cases an anaphase bridge breaks (5) and the broken telomere-deficient chromosomes are again replicated (6) and once again fuse with their sister chromatids (7) . Several repetitions of this process result in the amplification of DNA sequences that are adjacent to the break or fusion point. An anaphase bridge may break in various regions, resulting in the amplification of different genomic regions (e.g., genes, oncogenes, and repetitive DNA). Recombination between homotypic sequences within the amplified DNA generates extrachromosomal circular DNA (8) , which can eventually become looped out of the chromosome (9). These mini circles of DNA can subsequently be extruded from the nucleus through budding (10) and eventually become extruded from cells into the extracellular space (11) .

Anaphase bridges can also break in non-gene regions. Differentiation between chromosomes with varying telomere erosion profiles showed that the long and short arms of chromosomes 1 and 22, respectively, had critically short telomeres as compared with other chromosomes. Consistent with this observation, telomeric fusion of these chromosomes was the most striking cytogenetic abnormality observed at anaphase after the first population doubling of human mammary epithelial cells. However, since chromosome 1 contributed more to the formation of anaphase bridges, it was suggested that the loss of telomere function did not modulate the formation of nuclear anomalies through a single mechanism [214] . This concurred with a previous study showing that telomere dysfunction caused a spectrum of mitotic defects [194] . In this study, two different types of anaphase bridges were observed, i.e., one type consisting of one or two strings of decondensed chromatin connected to both spindle poles, whereas the other bridge had detached from either one or both spindle poles (resulting in lagging of entire chromosomes). Fragmented DNA was localized either in NBUDs, which contained completely fragmented and broken anaphase bridges, or in internuclear strings, which originated from anaphase bridges that were fragmented, but not fully broken. Interestingly, in more than 90% of strings and protrusions, DNA fragmentation began adjacent to the centromere and continued distally. Karyotype analysis of 338 cases of colorectal adenocarcinomas confirmed that this pericentromeric breakpoint pattern also occurred in vivo [194] .

In addition to the above observations, molecular studies of immunodeficiency, centromeric region instability, and facial anomalies (ICF syndrome) have shown that chromosomes 1 and 16 and, in some cases, chromosomes 2 and 9 were predisposed to hypomethylation at their centromeric and pericentromeric regions [215] , resulting in a variety of cytogenetic abnormalities, which included the extrusion of self-associated satellite DNA into MNi or NBUDs [216] . In line with this, several cancer types have shown preferential hypomethylation of the satellite repeat arrays on the basis of the q-arms of chromosomes 1, 9, and 16 [217-219] . This hypomethylation was causally linked to a high frequency of non-random rearrangements in the centromeric and pericentromeric heterochromatin of these chromosomes, which were nearly identical to those observed in ICF syndrome. In support of this, similar genomic aberrations and MNi-containing DNA derived from the centromeric and pericentromeric regions of chromosomes 1, 9, and 16 were induced in cultured cells through exposure to various clastogenic compounds that prevent normal methylation [220] [221] [222] [223] [224] . Taken together, these studies may explain why a growing number of studies have reported an overrepresentation of repetitive DNA in cfDNA [168, 169, [225] [226] [227] . More specifically, these studies may provide an explanation for the question why cfDNA derived from cultured cancer cells has been found to be enriched in repetitive DNA, which originated from the centromeric and pericentromeric regions of chromosomes 1, 9, and 22 [168] .

While these studies provided indirect evidence that a portion of the cfDNA originate from CIN-induced MNi, there is currently no direct experimental evidence that shows this. Indeed, as far as we know, there have been, thus far, no attempts to isolate "free-floating" MNi directly from human body fluids. Therefore, further studies on the nature of MNi would likely provide deeper insight into the biology and physicochemical properties of cfDNA.

Cell death, primarily via apoptosis or, under certain circumstances, necrosis, has often been considered to be the only relevant mechanism of DNA release into the bloodstream. This assumption has been justified by the non-random fragmentation pattern of circulating cfDNA [44, 66, 67] . In contrast, several active mechanisms for the release of cfDNA from cells have now also been described, where, for instance, a considerable fraction of the total cfDNA, which is attributed to the erythroid cell lineage [85] [86] [87] 228] , cannot sufficiently be explained by cell death, since mature erythrocytes do not possess a nucleus when undergoing eryptosis (erythrocyte apoptosis) [229] . Additionally, the mechanism of NETosis, which contributes substantially to the cfDNA fraction is not considered to be a passive mechanism [92, 230] . Active release of DNA has been observed in many parts of the eukaryotic kingdom, i.e., it has been observed, for example, in humans, rats [231] , chickens [232] and allomyces arbusculus (fungi) [233] . However, in these papers, there were no detailed characterizations described which dealt with the mechanism of cfDNA or the associated functions. This led Elzanowska et al. (in 2020) [234] to conclude that "DNA can also be released from living cells by active cellular secretion, although at present little is known about why functional cells secrete DNA and what is the biological significance of this process.

An entirely random release of DNA into the bloodstream as the predominant mechanism of cfDNA generation (i.e., essentially resulting fragmented entire chromosomes entering the bloodstream) contradicts, in our opinion, the fact that exosomal cfDNA clearly has an effect on cultured cells. For example, when exosomes hailing from radiated cell cultures were inoculated into cell cultures, which were not radiated, this led to a similar phenotype in the non-radiated cells as in the radiated cells [235] [236] [237] [238] . In addition, the fact that exosomal cfDNA can be incorporated into the nuclei of inoculated cells [161] within a short time frame allows us to speculate that the cfDNA molecules contained in these exosomes may contain messages, which can be utilized in the uptaking cell.

Passively released cfDNA is still a useful tool, which can be used in a biomedical context for certain diseases, although, in our opinion, this is limited to diseases which are connected to dramatic changes to the genome of the patient (e.g., chromosomal rearrangements in tumors). Currently, only a small number of diagnostic tests using cfDNA are approved by the U.S. Food and Drug Administration, for example, the cobas ® EGFR Mutation PCR Test v2 for non-small cell lung cancer [239] , a test for ctDNA for PIK3CA mutated hormone receptor positive breast cancer [240] , and the SEPT9 methylated DNA test for colorectal cancer [241] . The most prominent example is certainly the prenatal diagnostic test for Down syndrome and other chromosomal abnormalities [23] [24] [25] [26] , which is, to our knowledge, currently the only widely used cfDNA based diagnostic procedure available in public health institutions around the globe. Several groups are also developing screening tools for resistance in cancers, using cfDNA fragments originating from tumor tissue and constructing maps of tumor chromosomes after high-throughput DNA sequencing to determine mutations (insertions/deletions) on the cancer chromosomes [242] [243] [244] . As the detection limits for this cfDNA fraction are lowered (currently they lie around 2-5% of the total cfDNA), this is becoming a very valuable tool for non-invasive diagnosis of cancers [66, 245] .

Elevated levels of circulating cfDNA have been reported for several forms of physiological stress such as different disease conditions [12, 13, 15, 99, 246] or even simply exhaustion from physical exercise [82, 83, 247] . Correspondingly, increased active release of DNA fragments from cells via exosomes was found in connection with intracellular stress and senescence [164] . It is, in our opinion, unlikely that these cfDNA fractions are solely the product of apoptosis and necrosis, as very often the increase in cfDNA levels in the bloodstream occurs shortly after the stress exposure and is quite substantial [162] . The interplay of multiple cfDNA release mechanisms makes it difficult to relate the profile of cfDNA in blood to distinct diseases. We have experienced this ourselves when we investigated the occurrence of certain cfDNA sequence motifs (biomarkers) in relation to postsurgical bacteremia and sepsis [248] . Evaluating the frequencies of the motifs relative to the total cfDNA concentration of the samples did not yield any reliable correlation to the disease state. Therefore, we had to assume that several mechanisms contributed to the total cfDNA population being also overlaid (and thus partially masked) by the response to non-disease-related physiological causes, thus, interfering with our attempts to normalize the disease signals.

Evaluating the motif frequencies relative to each other in the form of motif pairs provided an intrinsic reference system, which ultimately enabled a motif-based distinction between samples from sepsis patients and samples from healthy probands [248] . These results provided evidence that information may be contained in cfDNA fragment frequency, methylation patterns, or the occurrence of mutations in some genomic regions, and also in the relative abundance of particular cfDNA motifs. The cfDNA fraction comprised by certain sequence elements, especially RTE and satellite repeats, seemed to change in response to physiological conditions [169, 248] , which could provide novel perspectives for future diagnostic approaches. Similar overrepresentation of these repeat elements has also been found in human bone osteosarcoma cancer cell culture supernatants [168] . Since different methods for DNA purification, amplification, and sequencing were used in these studies, it is very unlikely that these results were obtained due to artifacts caused by the applied methodology. Assessing the contribution of different cfDNA release mechanisms under varying physiological conditions may be crucial for the identification of additional reliable and robust signals within the information continuum provided by the cfDNA composition in body fluids. We expect that this should lead to the development of further diagnostic assays in the future. This research and development field is only emerging now, with very detailed studies possible due to third-generation high-throughput DNA sequencing methods being applied to the characterization of the entire DNA content of serum or plasma samples from patients and controls. Unlike the diagnostic assays, which solely consider passively released DNA as the target, the efforts focusing on including actively released cfDNA molecules have the advantage that they deal with the full spectrum of DNA circulating in the bloodstream, thus, increasing the signal-to-noise ratio considerably. 

Les acides nucléiques du plasma sanguin chez l'homme

Other body fluids as non-invasive sources of cell-free DNA/RNA

Levels of circulating cell-free nuclear and mitochondrial dna in benign and malignant ovarian tumors

Levels of plasma circulating cell free nuclear and mitochondrial DNA as potential biomarkers for breast tumors

Diagnosis of Sepsis with Cell-free DNA by Next-Generation Sequencing Technology in ICU Patients

Numerous uncharacterized and highly divergent microbes which colonize humans are revealed by circulating cell-free DNA

Isolation and characterization of DNA from the plasma of cancer patients

Partial purification and characterization of plasma DNA and its relation to disease activity in systemic lupus erythematosus

Endogenous circulating DNA in systemic lupus erythematosus. Occurrence as multimeric complexes bound to histone

Cell-free DNA in human blood plasma: Length measurements in patients with pancreatic cancer and healthy controls

Origins, structures, and functions of circulating DNA in oncology

Free DNA in the Serum of Cancer Patients and the Effect of Therapy

Deoxybonucleic acid (DNA) and antibodies to DNA in the serum of patients with systemic lupus erythematosus

Determination of circulating DNA levels in patients with benign or malignant gastrointestinal disease

Free DNA in the serum of rheumatoid arthritis patients

Detection of circulating dna by counterimmunoelectrophoresis (cie)

The Long and Short of Circulating Cell-Free DNA and the Ins and Outs of Molecular Diagnostics

Liquid biopsies come of age: Towards implementation of circulating tumour DNA

Cancer genome scanning in plasma: Detection of tumor-associated copy number aberrations, single-nucleotide variants, and tumoral heterogeneity by massively parallel sequencing

Liquid biopsy: Unlocking the potentials of cell-free DNA

Noninvasive detection of cancer-associated genome-wide hypomethylation and copy number aberrations by plasma DNA bisulfite sequencing

Circulating nucleic acids: An analysis of their occurrence in malignancies

Presence of fetal DNA in maternal plasma and serum

DNA sequencing of maternal plasma to detect Down syndrome: An international clinical validation study

DNA sequencing of maternal plasma reliably identifies trisomy 18 and trisomy 13 as well as Down syndrome: An international collaborative study

Circulating cell-free nucleic acids: Characteristics and applications

The diverse origins of circulating cell-free DNA in the human body: A critical re-evaluation of the literature

DNA fragments in the blood plasma of cancer patients: Quantitations and evidence for their origin from apoptotic and necrotic cells

Quantification of plasma cell-free DNA in patients with gastric cancer

Characterization of cell-free circulating DNA in plasma in patients with prostate cancer

Dysregulation of apoptosis in cancer

Molecular mechanisms of cell death: Recommendations of the Nomenclature Committee on Cell Death

Regulation of apoptosis in health and disease: The balancing act of BCL-2 family proteins

Apoptotic caspases suppress mtDNA-induced STING-mediated type I IFN production

A perspective on mammalian caspases as positive and negative regulators of inflammation

Apoptotic cell-derived extracellular vesicles: More than just debris

Apoptotic DNA fragmentation may be a cooperative activity between caspase-activated deoxyribonuclease and the poly(ADP-ribose) polymerase-regulated DNAS1L3, an endoplasmic reticulum-localized endonuclease that translocates to the nucleus during apoptosis

DNase γ, DNase I and caspase-activated DNase cooperate to degrade dead cells

Host DNases prevent vascular occlusion by neutrophil extracellular traps

Regulation of DNA fragmentation: The role of caspases and phosphorylation

A caspase-activated DNase that degrades DNA during apoptosis, and its inhibitor ICAD

Cell-free DNA Comprises an in Vivo Nucleosome Footprint that Informs Its Tissues-Of-Origin

The Biology of Cell-free DNA Fragmentation and the Roles of DNASE1, DNASE1L3, and DFFB

Impaired DNase1-mediated degradation of neutrophil extracellular traps is associated with acute thrombotic microangiopathies

Cell-free DNA in blood circulation is generated by DNase1L3 and caspase-activated DNase

Cooperation of factor VII-activating protease and serum DNase I in the release of nucleosomes from necrotic cells

Factor H uptake regulates intracellular C3 activation during apoptosis and decreases the inflammatory potential of nucleosomes

Circulating-tumor DNA as an early detection and diagnostic tool

High-resolution profiling of fetal DNA clearance from maternal plasma by massively parallel sequencing

Cell-free DNA: The role in pathophysiology and as a biomarker in kidney diseases

The emerging role of cell-free DNA as a molecular marker for cancer management

Apoptosis: A basic biological phenomenon with wide-ranging implications in tissue kinetics

Phospholipid rearrangement of apoptotic membrane does not depend on nuclear activity

Molecular mechanisms of biogenesis of apoptotic exosome-like vesicles and their roles as damage-associated molecular patterns

Cell-to-cell communication: microRNAs as hormones

The many ways tissue phagocytes respond to dying cells

Distinct RNA profiles in subpopulations of extracellular vesicles: Apoptotic bodies, microvesicles and exosomes

Corpse clearance defines the meaning of cell death

A novel mechanism of generating extracellular vesicles during apoptosis via a beads-on-a-string membrane structure

Disassembly of the Dying: Mechanisms and Functions

New evidence that a large proportion of human blood plasma cell-free DNA is localized in exosomes

Priming of dendritic cells by DNA-containing extracellular vesicles from activated T cells through antigen-driven contacts

Characterization of the release and biological significance of cell-free DNA from breast cancer cell lines

Dnase1l3 deletion causes aberrations in length and end-motif frequencies in plasma DNA

Cell-Free DNA and Apoptosis: How Dead Cells Inform About the Living

Necrosis, and Apoptosis Govern Circulating Cell-free DNA Release Kinetics

Measurement of Red Cell Lifespan and Aging

Formation of mammalian erythrocytes: Chromatin condensation and enucleation

Primitive and definitive erythropoiesis in mammals

From Erythroblasts to Mature Red Blood Cells: Organelle Clearance in Mammals

Erythroblastic islands: Niches for erythropoiesis

Observations on the size and shapes of the red corpuscles of the blood of vertebrates with drawings of them to a uniform scale and extended and revised tables of measurements

The mechanism of denucleation in circulating erythroblasts

L'ílot érythroblastique, unité fonctionnelle de la moelle osseuse

Molecular changes in the membranes of mouse erythroid cells accompanying differentiation

Enucleation of primitive erythroid cells generates a transient population of "pyrenocytes" in the mammalian fetus

Phosphatidylserine-dependent engulfment by macrophages of nuclei from erythroid precursor cells

Requirement of DNase II for Definitive Erythropoiesis in the Mouse Fetal Liver

Decreased serum cell-free DNA levels in rheumatoid arthritis

Release of bulk cell free DNA during physical exercise occurs independent of extracellular vesicles

Exercise-induced increases in cell free DNA in human plasma originate predominantly from cells of the haematopoietic lineage

Predominant hematopoietic origin of cell-free DNA in plasma and serum after sex-mismatched bone marrow transplantation

Cell-free DNA in maternal plasma and serum: A comparison of quantity, quality and tissue origin using genomic and epigenomic approaches

Comprehensive human cell-type methylation atlas reveals origins of circulating cell-free DNA in health and disease

Life and death of circulating cell-free DNA

DNA of Erythroid Origin Is Present in Human Plasma and Informs the Types of Anemia

NETosis: How vital is it? Blood

Novel cell death program leads to neutrophil extracellular traps

Neutrophil Extracellular Traps: Current Perspectives in the Eye

Molecular mechanisms regulating NETosis in infection and disease

A Novel Mechanism of Rapid Nuclear Neutrophil Extracellular Trap Formation in Response to Staphylococcus aureus

Translational Modifications in NETosis and NETs-Mediated Diseases. Biomolecules

Diverse stimuli engage different neutrophil extracellular trap pathways

Cell-Cycle Proteins Control Production of Neutrophil Extracellular Traps

Macrophage Clearance of Neutrophil Extracellular Traps Is a Silent Process

The origin and properties of extracellular DNA: From PAMP to DAMP

Neutrophil Extracellular Traps and Systemic Lupus Erythematosus

Neutrophil Extracellular Traps That Are Not Degraded in Systemic Lupus Erythematosus Activate Complement Exacerbating the Disease

Degradation of neutrophil extracellular traps is decreased in patients with antiphospholipid syndrome

Impairment of neutrophil extracellular trap degradation is associated with lupus nephritis

Nucleases from Prevotella intermedia can degrade neutrophil extracellular traps

Nuclease expression by Staphylococcus aureus facilitates escape from neutrophil extracellular traps

Streptococcus suis DNase SsnA contributes to degradation of neutrophil extracellular traps (NETs) and evasion of NET-mediated antimicrobial activity

Evasion of neutrophil extracellular traps by respiratory pathogens

Novel role of the antimicrobial peptide LL-37 in the protection of neutrophil extracellular Traps against degradation by bacterial nucleases

Neutrophil extracellular traps produced during inflammation awaken dormant cancer cells in mice

Cell death in chronic inflammation: Breaking the cycle to treat rheumatic disease

NETosis and lack of DNase activity are key factors in Echis carinatus venom-induced tissue destruction

Neutrophil extracellular traps in COVID-19

The virtosome-a novel cytosolic informative entity and intercellular messenger

Excretion of Deoxyribonucleic Acid by Lymphocytes Stimulated with Phytohemagglutinin or Antigen

Spontaneous release of DNA by human blood lymphocytes as shown in an in vitro system

Spontaneous extracellular synthesis of DNA released by human blood lymphocytes

Nucleic acids spontaneously released by living frog auricles

The DNA extruded by rat spleen cells in culture

Further studies on the size and composition of the chick embryo fibroblast cytosolic DNA complex

Components of the cytosolic and released virtosomes from stimulated and non-stimulated human lymphocytes

In vitro stimulation by tumour cell media of [3H]-thymidine incorporation by mouse spleen lymphocytes

Cell-free nucleic acids circulating in the plasma of colorectal cancer patients induce the oncogenic transformation of susceptible cultured cells

Non-dividing Cell Virtosomes Affect In Vitro and In Vivo Tumour Cell Replication

Turnover of DNA and function

Metabolic DNA in heart and skeletal muscle and in the intestine of mice

Characterization of the cell-free DNA released by cultured cancer cells

Kinetic analysis, size profiling, and bioenergetic association of DNA released by selected cell lines in vitro

Circulating cell-free DNA release in vitro: Kinetics, size profiling, and cancer-related gene methylation

Double-stranded DNA in exosomes: A novel biomarker in cancer detection

Prostasomes are mediators of intercellular communication: From basic research to clinical implications

Evaluating the quantity, quality and size distribution of cell-free DNA by multiplex droplet digital PCR

Detection of ctDNA from Dried Blood Spots after DNA Size Selection

Assessing HER2 amplification in plasma cfDNA

Fine structure of early cartilage calcification

The Nature and Significance of Platelet Products in Human Plasma

Current knowledge on exosome biogenesis and release

The biology, function, and biomedical applications of exosomes

Gram-negative and Gram-positive bacterial extracellular vesicles

The biology of extracellular vesicles: The known unknowns

Extracellular vesicles: Exosomes, microvesicles, and friends

Biogenesis of extracellular vesicles (EV): Exosomes, microvesicles, retrovirus-like vesicles, and apoptotic bodies

Overview of Extracellular Vesicles, Their Origin, Composition, Purpose, and Methods for Exosome Isolation and Analysis

Receptor-mediated endocytosis of transferrin and recycling of the transferrin receptor in rat reticulocytes

Nucleic Acid Association to Human Prostasomes

Human prostasomes contain chromosomal DNA

Astrocytes and Glioblastoma cells release exosomes carrying mtDNA

Export and intercellular transfer of DNA via membrane blebs of Neisseria gonorrhoeae

Structural features of Borrelia burgdorferi-the Lyme disease spirochete: Silver staining for nucleic acids

Virus-like vesicles and extracellular DNA produced by hyperthermophilic archaea of the order Thermococcales

Discovery of double-stranded genomic DNA in circulating exosomes

Identification of Double-stranded Genomic DNA Spanning All Chromosomes with Mutated KRAS and p53 DNA in the Serum Exosomes of Patients with Pancreatic Cancer

Packaging and transfer of mitochondrial DNA via exosomes regulate escape from dormancy in hormonal therapy-resistant breast cancer

Tumour microvesicles contain retrotransposon elements and amplified oncogene sequences

Cardiomyocyte Microvesicles Contain DNA/RNA and Convey Biological Messages to Target Cells

Detection of mutant KRAS and TP53 DNA in circulating exosomes from healthy individuals and patients with pancreatic cancer

Extracellular vesicle-mediated transfer of donor genomic DNA to recipient cells is a novel mechanism for genetic influence between cells

Functional transferred DNA within extracellular vesicles

Exosome DNA: Critical regulator of tumor immunity and a diagnostic biomarker

Bacterial membrane vesicles transport their DNA cargo into host cells

Indication of Horizontal DNA Gene Transfer by Extracellular Vesicles

Kinetics of circulating cell-free DNA for biomedical applications: Critical appraisal of the literature

DNA analysis of low-and high-density fractions defines heterogeneous subpopulations of small extracellular vesicles based on their DNA cargo and topology

Exosomes maintain cellular homeostasis by excreting harmful DNA from cells

Exosomes and autophagy: Coordinated mechanisms for the maintenance of cellular fitness

Role of exosomes in the protection of cellular homeostasis

Platelets, endothelial cells and leukocytes contribute to the exercise-triggered release of extracellular vesicles into the circulation

Sequence analysis of cell-free DNA derived from cultured human bone osteosarcoma (143B) cells

Circulating cell-free DNA is predominantly composed of retrotransposable elements and non-telomeric satellite DNA

Irminger-Finger, I. Mechanisms of chromosome instability in cancers

Functions of the centromere and kinetochore in chromosome segregation

Aneuploidy: A matter of bad connections

Merotelic kinetochore orientation occurs frequently during early mitosis in mammalian tissue cells and error correction is achieved by two different mechanisms

Correcting improper chromosome-spindle attachments during cell division

Merotelic kinetochore orientation is a major mechanism of aneuploidy in mitotic mammalian tissue cells

Jolly bodies: A brief historical review

The micronucleus assay in human buccal cells as a tool for biomonitoring DNA damage: The HUMN project perspective on current status and knowledge gaps

Chromosome elimination in micronuclei: A common cause of hypoploidy

Induction of micronuclei and anaphase aberrations by cytochalasin B in human lymphocyte cultures

Chromosome errors at mitotic anaphase

The X chromosome frequently lags behind in female lymphocyte anaphase

What do human micronuclei contain? Mutagenesis

Telomeres, chromosome instability and cancer

Abnormal nuclear shape in solid tumors reflects mitotic instability

Telomere dysfunction triggers extensive DNA fragmentation and evolution of complex chromosome abnormalities in human malignant tumors

Telomere length abnormalities occur early in the initiation of epithelial carcinogenesis

Telomere length dynamics in telomerase-positive immortal human cell populations

Telomeres in cancer: Tumour suppression and genome instability

The shortest telomere, not average telomere length, is critical for cell viability and chromosome stability

Inviting instability: Transposable elements, double-strand breaks, and the maintenance of genome integrity

The human LINE-1 retrotransposon creates DNA double-strand breaks

DNA demethylation and pericentromeric rearrangements of chromosome 1

Phosphorylation of histone H2AX in radiation-induced micronuclei

Structural and numerical chromosome changes in colon cancer develop through telomere-mediated anaphase bridges, not through mitotic multipolarity

Transmission of radiation-induced acentric chromosomal fragments to micronuclei in normal human fibroblasts

PCR amplification of chromosome-specific alpha satellite DNA: Definition of centromeric STS markers and polymorphic analysis

DNA damage and the aging brain

Origin of nuclear buds and micronuclei in normal and folate-deprived human lymphocytes

Dicentric chromosomes: Unique models to study centromere function and inactivation

The role of dicentric chromosome formation and secondary centromere deletion in the evolution of myeloid malignancy

The Fusion of Broken Ends of Chromosomes Following Nuclear Fusion

Molecular mechanisms of micronucleus, nucleoplasmic bridge and nuclear bud formation in mammalian and human cells

Selective elimination of acentric double minutes from cancer cells through the extrusion of micronuclei

When, where and how the bridge breaks: Anaphase bridge breakage plays a crucial role in gene amplification and HSR generation

Molecular mechanisms of the origin of micronuclei from extrachromosomal elements

Cytokinesis-block micronucleus assay evolves into a "cytome" assay of chromosomal instability, mitotic dysfunction and cell death

Selective entrapment of extrachromosomally amplified DNA by nuclear budding and micronucleation during S phase

Emergence of micronuclei and their effects on the fate of cells under replication stress

Generation of micronuclei during interphase by coupling between cytoplasmic membrane blebbing and nuclear budding

Identification and characterization of extrachromosomal circular DNA in maternal plasma

Normal and Cancerous Tissues Release Extrachromosomal Circular DNA (eccDNA) into the Circulation

Molecular characterization of cell-free eccDNAs in human plasma

Telomere dysfunction and chromosome structure modulate the contribution of individual chromosomes in abnormal nuclear morphologies

Immunodeficiency, centromeric region instability, facial anomalies syndrome (ICF)

Viegas-Péquignot, E. Chromosome instability and immunodeficiency syndrome caused by mutations in a DNA methyltransferase gene

Frequent hypomethylation in Wilms tumors of pericentromeric DNA in chromosomes 1 and 16

Satellite DNA hypomethylation vs. overall genomic hypomethylation in ovarian epithelial tumors of different malignant potential

Hypomethylation of pericentromeric DNA in breast adenocarcinomas

Chromosome painting reveals specific patterns of chromosome occurrence in mitomycin C-and diethylstilboestrol-induced micronuclei

Frequencies of occurrence of all human chromosomes in micronuclei from normal and 5-azacytidine-treated lymphocytes as revealed by chromosome painting

Comparison of spontaneous and idoxuridine-induced micronuclei by chromosome painting

Effects of 5-azacytidine on the centromeric region of human fibroblasts studied by CREST staining and in situ hybridization on cytokinesis-blocked cells

Exclusion of specific human chromosomes into micronuclei by 5-azacytidine treatment of lymphocyte cultures

Profile of the Circulating DNA in apparently healthy individuals

Circulating nucleic acids damage DNA of healthy cells by integrating into their genomes

Heterochromatic Tandem Repeats in the Extracellular DNA

Red Blood Cells: Centerpiece in the Evolution of the Vertebrate Circulatory System

Erythrocyte programmed cell death

Cellular Mechanisms of NETosis

Stimulated and Non-stimulated Rat Spleen Cells Release Different DNA-Complexes. Differentiation

Further studies on the extrusion of cytosol macromolecules by cultured chick embryo fibroblast cells

Release of RNA-DNA-protein complex during differentiation of the water mould Allomyces arbuscula

DNA in extracellular vesicles: Biological and clinical aspects

Oxidative stress as a significant factor for development of an adaptive response in irradiated and nonirradiated human lymphocytes after inducing the bystander effect by low-dose X-radiation

An extracellular DNA mediated bystander effect produced from low dose irradiated endothelial cells

Oxidized Cell-Free DNA Is a Factor of Stress Signaling in Radiation-Induced Bystander Effects in Different Types of Human Cells

Radiation-Induced Bystander Effect is Mediated by Mitochondrial DNA in Exosome-Like Vesicles

The Cobas®EGFR Mutation Test v2 assay

Alpelisib for PIK3CA-mutated, hormone receptor-positive advanced breast cancer

Septin 9 methylated DNA is a sensitive and specific blood test for colorectal cancer

Clinical relevance of blood-based ctDNA analysis: Mutation detection and beyond

Next-generation sequencing in liquid biopsy: Cancer screening and early detection

High-intensity sequencing reveals the sources of plasma circulating cell-free DNA variants

Current and future perspectives of liquid biopsies in genomics-driven oncology

The occurrence of single-stranded DNA in the serum of patients with systemic lupus erythematosus and other diseases

Short-Term Treadmill Running as a Model for Studying Cell-Free DNA Kinetics In Vivo

Evaluation of host-based molecular markers for the early detection of human sepsis

A.J.B. is supported by the Georg Forster Research Fellowship Program of the Alexander von Humboldt Foundation. The financial assistance of the Alexander von Humboldt Foundation is hereby acknowledged.

The authors declare no conflict of interest.