CircTLK1 modulates sepsis-induced cardiomyocyte apoptosis via enhancing PARP1/HMGB1 axis-mediated mitochondrial DNA damage by sponging miR-17-5p.

INTRODUCTION: Septic cardiomyopathy is a common complication of sepsis with high morbidity and mortality, but lacks specific therapy. This study aimed to reveal the role of circTLK1 and its potential mechanisms in septic cardiomyopathy. MATERIALS AND METHODS: The in vitro and in vivo models of septic cardiomyopathy were established. Cell viability and apoptosis were detected by CCK8, TUNEL and flow cytometry, respectively. LDH, CK, SOD, MDA, ATP, 8-OHdG, NAD+/NADH ratio, ROS level, mitochondrial membrane potential and cytochrome C distribution were evaluated using commercial kits. qRT-PCR and western blotting were performed to detect RNA and protein levels. Mitochondrial DNA (mtDNA) copy number and transcription were assessed by quantitative PCR. Dual-luciferase assay, RNA immunoprecipitation and co-immunoprecipitation were performed to verify the interaction between circTLK1/PARP1 and miR-17-5p. RESULTS: CircTLK1, PARP1 and HMGB1 were up-regulated in the in vitro and in vivo models of septic cardiomyopathy. CircTLK1 inhibition restrained LPS-induced up-regulation of PARP1 and HMGB1. Moreover, circTLK1 knockdown repressed sepsis-induced mtDNA oxidative damage, mitochondrial dysfunction and consequent cardiomyocyte apoptosis by inhibiting PARP1/HMGB1 axis in vitro and in vivo. In addition, circTLK1 enhanced PARP1 expression via sponging miR-17-5p. Inhibition of miR-17-5p abolished the protective effects of circTLK1 silencing on oxidative mtDNA damage and cardiomyocyte apoptosis. CONCLUSION: CircTLK1 sponged miR-17-5p to aggravate mtDNA oxidative damage, mitochondrial dysfunction and cardiomyocyte apoptosis via activating PARP1/HMGB1 axis during sepsis, indicating that circTLK1 may be a putative therapeutic target for septic cardiomyopathy.

Episomal minicircles persist in periods of transcriptional inactivity and can be transmitted through somatic cell nuclear transfer into bovine embryos.

Episomal plasmids based on a scaffold/matrix attachment region (S/MAR) are extrachromosomal DNA entities that replicate once per cell cycle and are stably maintained in cells or tissue. We generated minicircles, episomal plasmids devoid of bacterial sequences, and show that they are stably transmitted in clonal primary bovine fibroblasts without selection pressure over more than two months. Total DNA, plasmid extraction and fluorescence in situ hybridization (FISH) analyses suggest that the minicircles remained episomal and were not integrated into the genome. Minicircles survived extended periods in serum-starved cells, which indicates that ongoing transcription in non-proliferating cells is not necessary for the maintenance of S/MAR-episomes. To test whether minicircles endure the process of somatic cell nuclear transfer (SCNT), we used cell-cycle synchronized, serum-starved, minicircle-containing cells. Analysis of cells outgrown from SCNT-derived blastocysts shows that the minicircles are maintained through SCNT and early embryonic development, which raises the prospect of using cell lines with episomal minicircles for the generation of transgenic animals.

Genomic Copy-Number Loss Is Rescued by Self-Limiting Production of DNA Circles.

Copy-number changes generate phenotypic variability in health and disease. Whether organisms protect against copy-number changes is largely unknown. Here, we show that Saccharomyces cerevisiae monitors the copy number of its ribosomal DNA (rDNA) and rapidly responds to copy-number loss with the clonal amplification of extrachromosomal rDNA circles (ERCs) from chromosomal repeats. ERC formation is replicative, separable from repeat loss, and reaches a dynamic steady state that responds to the addition of exogenous rDNA copies. ERC levels are also modulated by RNAPI activity and diet, suggesting that rDNA copy number is calibrated against the cellular demand for rRNA. Last, we show that ERCs reinsert into the genome in a dosage-dependent manner, indicating that they provide a reservoir for ultimately increasing rDNA array length. Our results reveal a DNA-based mechanism for rapidly restoring copy number in response to catastrophic gene loss that shares fundamental features with unscheduled copy-number amplifications in cancer cells.

A Role for the Host DNA Damage Response in Hepatitis B Virus cccDNA Formation-and Beyond?

Chronic hepatitis B virus (HBV) infection puts more than 250 million people at a greatly increased risk to develop end-stage liver disease. Like all hepadnaviruses, HBV replicates via protein-primed reverse transcription of a pregenomic (pg) RNA, yielding an unusually structured, viral polymerase-linked relaxed-circular (RC) DNA as genome in infectious particles. Upon infection, RC-DNA is converted into nuclear covalently closed circular (ccc) DNA. Associating with cellular proteins into an episomal minichromosome, cccDNA acts as template for new viral RNAs, ensuring formation of progeny virions. Hence, cccDNA represents the viral persistence reservoir that is not directly targeted by current anti-HBV therapeutics. Eliminating cccDNA will thus be at the heart of a cure for chronic hepatitis B. The low production of HBV cccDNA in most experimental models and the associated problems in reliable cccDNA quantitation have long hampered a deeper understanding of cccDNA molecular biology. Recent advancements including cccDNA-dependent cell culture systems have begun to identify select host DNA repair enzymes that HBV usurps for RC-DNA to cccDNA conversion. While this list is bound to grow, it may represent just one facet of a broader interaction with the cellular DNA damage response (DDR), a network of pathways that sense and repair aberrant DNA structures and in the process profoundly affect the cell cycle, up to inducing cell death if repair fails. Given the divergent interactions between other viruses and the DDR it will be intriguing to see how HBV copes with this multipronged host system.

Roles of hepatocyte nuclear factors in hepatitis B virus infection.

Approximately 350 million people are estimated to be persistently infected with hepatitis B virus (HBV) worldwide. HBV maintains persistent infection by employing covalently closed circular DNA (cccDNA), a template for all HBV RNAs. Chronic hepatitis B (CHB) patients are currently treated with nucleos(t)ide analogs such as lamivudine, adefovir, entecavir, and tenofovir. However, these treatments rarely cure CHB because they are unable to inhibit cccDNA transcription and inhibit only a late stage in the HBV life cycle (the reverse transcription step in the nucleocapsid). Therefore, an understanding of the factors regulating cccDNA transcription is required to stop this process. Among numerous factors, hepatocyte nuclear factors (HNFs) play the most important roles in cccDNA transcription, especially in the generation of viral genomic RNA, a template for HBV replication. Therefore, proper control of HNF function could lead to the inhibition of HBV replication. In this review, we summarize and discuss the current understanding of the roles of HNFs in the HBV life cycle and the upstream factors that regulate HNFs. This knowledge will enable the identification of new therapeutic targets to cure CHB.

A balance between circular and linear forms of the dengue virus genome is crucial for viral replication.

The plasticity of viral plus strand RNA genomes is fundamental for the multiple functions of these molecules. Local and long-range RNA-RNA interactions provide the scaffold for interacting proteins of the translation, replication, and encapsidation machinery. Using dengue virus as a model, we investigated the relevance of the interplay between two alternative conformations of the viral genome during replication. Flaviviruses require long-range RNA-RNA interactions and genome cyclization for RNA synthesis. Here, we define a sequence present in the viral 3'UTR that overlaps two mutually exclusive structures. This sequence can form an extended duplex by long-range 5'-3' interactions in the circular conformation of the RNA or fold locally into a small hairpin (sHP) in the linear form of the genome. A mutational analysis of the sHP structure revealed an absolute requirement of this element for viral viability, suggesting the need of a linear conformation of the genome. Viral RNA replication showed high vulnerability to changes that alter the balance between circular and linear forms of the RNA. Mutations that shift the equilibrium toward the circular or the linear conformation of the genome spontaneously revert to sequences with different mutations that tend to restore the relative stability of the two competing structures. We propose a model in which the viral genome exists in at least two alternative conformations and the balance between these two states is critical for infectivity.

Control of cccDNA function in hepatitis B virus infection.

The template of hepatitis B virus (HBV) transcription, the covalently closed circular DNA (cccDNA), plays a key role in the life cycle of the virus and permits the persistence of infection. Novel molecular techniques have opened new possibilities to investigate the organization and the activity of the cccDNA minichromosome in vivo, and recent advances have started to shed light on the complexity of the mechanisms controlling cccDNA function. Nuclear cccDNA accumulates in hepatocyte nuclei as a stable minichromosome organized by histone and non-histone viral and cellular proteins. Identification of the molecular mechanisms regulating cccDNA stability and its transcriptional activity at the RNA, DNA and epigenetic levels in the course of chronic hepatitis B (CH-B) infection may reveal new potential therapeutic targets for anti-HBV drugs and hence assist in the design of strategies aimed at silencing and eventually depleting the cccDNA reservoir.

Extrachromosomal circular DNA in eukaryotes: possible involvement in the plasticity of tandem repeats.

Extrachromosomal circular DNA (eccDNA) is ubiquitous in eukaryotic organisms, and has been noted for more than 3 decades. eccDNA occurs in normal tissues and in cultured cells, is heterogeneous in size, consists of chromosomal sequences and reflects plasticity of the genome. Two-dimensional (2D) gel electrophoresis has been adapted for the detection and characterization of eccDNA. It shows that most eccDNA consists of chromosomal tandem repeats, both coding genes and satellite DNA and is organized as circular multimers of the repeating sequence. 2D gels were unable to detect dispersed repeats within the population of eccDNA. eccDNA, organized as circular multimers, can be formed de novo in Xenopus egg extracts, in the absence of DNA replication. These findings support a mechanism for the formation of eccDNA that involves intra-chromosomal homologous recombination between tandem repeats and looping-out. Furthermore, eccDNA appears to undergo extrachromosomal replication via a rolling circle mechanism. Hence, the formation of eccDNA from arrays of tandem repeats may cause deletions, and the possible re-integration of rolling-circle replication products could expand these arrays. This review summarizes recent experimental data which characterizes eccDNA in several organisms using 2D gel electrophoresis, and discusses its possible implications on the dynamics of chromosomal tandem repeats.

Chromosomal instability mediated by non-B DNA: cruciform conformation and not DNA sequence is responsible for recurrent translocation in humans.

Chromosomal aberrations have been thought to be random events. However, recent findings introduce a new paradigm in which certain DNA segments have the potential to adopt unusual conformations that lead to genomic instability and nonrandom chromosomal rearrangement. One of the best-studied examples is the palindromic AT-rich repeat (PATRR), which induces recurrent constitutional translocations in humans. Here, we established a plasmid-based model that promotes frequent intermolecular rearrangements between two PATRRs in HEK293 cells. In this model system, the proportion of PATRR plasmid that extrudes a cruciform structure correlates to the levels of rearrangement. Our data suggest that PATRR-mediated translocations are attributable to unusual DNA conformations that confer a common pathway for chromosomal rearrangements in humans.

Hepatitis B virus replication.

Hepadnaviruses, including human hepatitis B virus (HBV), replicate through reverse transcription of an RNA intermediate, the pregenomic RNA (pgRNA). Despite this kinship to retroviruses, there are fundamental differences beyond the fact that hepadnavirions contain DNA instead of RNA. Most peculiar is the initiation of reverse transcription: it occurs by protein-priming, is strictly committed to using an RNA hairpin on the pgRNA, epsilon, as template, and depends on cellular chaperones; moreover, proper replication can apparently occur only in the specialized environment of intact nucleocapsids. This complexity has hampered an in-depth mechanistic understanding. The recent successful reconstitution in the test tube of active replication initiation complexes from purified components, for duck HBV (DHBV), now allows for the analysis of the biochemistry of hepadnaviral replication at the molecular level. Here we review the current state of knowledge at all steps of the hepadnaviral genome replication cycle, with emphasis on new insights that turned up by the use of such cell-free systems. At this time, they can, unfortunately, not be complemented by three-dimensional structural information on the involved components. However, at least for the epsilon RNA element such information is emerging, raising expectations that combining biophysics with biochemistry and genetics will soon provide a powerful integrated approach for solving the many outstanding questions. The ultimate, though most challenging goal, will be to visualize the hepadnaviral reverse transcriptase in the act of synthesizing DNA, which will also have strong implications for drug development.

DNA diffusion in mucus: effect of size, topology of DNAs, and transfection reagents.

DNA represents a promising therapeutic and prophylactic macromolecule in treating genetic diseases, infectious diseases and cancers. The therapeutic potential of DNA is directly related to how DNA transports within the targeted tissue. In this study, fluorescence photobleaching recovery was used to examine the diffusion of plasmid DNAs with various size (2.7-8.3 kb), topology, and in the presence of transfection reagents in mucus. We observed that DNAs diffused slower when size of DNAs increased; supercoiled DNAs diffused faster than linear ones; mucus did not reduce the diffusion of linear DNAs but retarded the diffusion of supercoiled DNAs. Diffusion data were fitted to models of a polymer chain diffusing in gel systems. Diffusion of linear DNAs in mucus were better described by the Zimm model with a scaling factor of -0.8, and supercoiled DNAs showed a reptational behavior with a scaling factor of -1.3. Based on the Zimm model, the pore size of bovine mucus was estimated and agreed well with previous experimental data. In the presence of transfection reagents, e.g., liposomes, the diffusion of DNAs increased by a factor of 2 in mucus. By using bovine mucus as a model system, this work suggests that DNA size, topology, and the presence of transfection reagents may affect the diffusion of DNA in tissues, and thus the therapeutic effects of DNA.

Fluorescent tagged analysis of neural gene function using mosaics in zebrafish and Xenopus laevis.

An important question in the neurosciences is the role of specific gene expression in the control of neural morphology and connectivity. To address this question, methods are needed for expression of exogenous genes in a subset of neurons. This limited and mosaic expression allows the assessment of gene expression in a cell autonomous fashion without environmental contributions from neighboring expressing cells. These methods must also label neurons so that detailed morphology and neural connections can be evaluated. The labeling method should label only a subset of neurons so that neuronal morphology can be viewed upon a non-stained background, in a Golgi staining fashion. Here, we report methods using plasmids called pTAGUM (tagged analysis of genes using mosaics) that accomplish these goals. These methods should prove useful for the analysis of neural gene function in two important model organisms, the zebrafish and Xenopus laevis.

Characterization of a complex 125I-induced DNA double-strand break: implications for repair.

PURPOSE: To examine the role of radiation-induced DNA double-strand break (DSB) structural organization in DSB repair, and characterize the structural features of 125I-induced DSBs that may impact the repair process. METHODS: Plasmid DNA was linearized by sequence-specific targeting using an 125I-labeled triplex-forming oligonucleotide (TFO). Following isolation from agarose gels, base damage structures associated with the DSB ends in plasmids linearized by the 125I-TFO were characterized by probing with the E. coli DNA damage-specific endonuclease and DNA-glycosylases, endonuclease IV (endo IV), endonuclease III (endo III), and formamidopyrimidine-glycosylase (Fpg). RESULTS: Plasmid DNA containing DSBs produced by the high-LET-like effects of 125I-TFO has been shown to support at least 2-fold lower end joining than gamma-ray linearized plasmid, and this may be a consequence of the highly complex structure expected near an 125I-induced DSB end. Therefore, to determine if a high density of base damage exists proximal to the DSBs produced by 125I-TFOs, short fragments of DNA recovered from the DSB end of 125I-TFO-linearized plasmid were enzymatically probed. Base damage and AP site clustering was demonstrated within 3 bases downstream and 7 bases upstream of the targeted base. Furthermore, the pattern and extent of base damage varied depending upon the presence or absence of 2 M DMSO during irradiation. CONCLUSIONS: 125I-TFO-induced DSBs exhibit a high degree of base damage clustering proximal to the DSB end. At least 60% of the nucleotides within 10 bp of the 125I decay site are sensitive to cleavage by endo IV, endo III, or Fpg following damage accumulation in the presence of DMSO, whereas > or = 80% are sensitive in the absence of DMSO. The high degree of base damage clustering associated with the 125I-TFO-induced DSB end may be a major factor leading to its negligible in vitro repair by the non-homologous end-joining pathway (NHEJ).

HIV-1 extrachromosomal 2-LTR circular DNA is long-lived in human macrophages.

HIV-1 extrachromosomal 2-LTR circles (cc2LTR) are rapidly lost in dividing cell populations and, therefore, might be interpreted as representing new infection and ongoing viral replication. However, recent work demonstrated that cc2LTR persist in infected, growth-arrested T cell lines beyond their predicted half-life as previously determined in dividing cell populations. In this study, the evaluation of the stability of cc2LTR was extended to include primary human macrophages, a natural, non-dividing target of HIV-1. By quantitative real-time PCR, cc2LTR were found to persist out to 21 days post-infection in macrophages infected with both integrase competent and integrase- defective, recombinant HIV-1, whereas in activated CD4(+) T lymphocytes, they rapidly decreased over time. This persistence was associated with persistent, low level expression of the indicator gene, luciferase. These data suggest that the presence of HIV-1 cc2LTR in the PBMC of HIV-1-infected patients on suppressive HAART could be due either to ongoing generation of newly infected dividing cells, or persistence of circles in non-dividing cell populations where they appear to be stable. Furthermore, exrachromosomal circular DNA in this cell population could be a source of persisent viral protein expression.

Lagging strand replication of rolling-circle plasmids in Streptomyces lividans: an RNA polymerase-independent primer synthesis.

The rolling circle (RC) mechanism of DNA replication generating single-stranded DNA (ssDNA) intermediates is common in various high-copy circular plasmids in Streptomyces, and the ssDNA released after leading strand synthesis is converted to its double-stranded form (dsDNA) by the host proteins. The in vivo and in vitro lagging strand syntheses from ssDNA replicative intermediates of RC plasmid pSN22 in Streptomyces lividans was characterized. The presence or absence of the single-strand origin (sso), the replication initiation site of lagging strand synthesis, did not significantly affect the copy numbers of pSN22 derivatives. In vivo lagging strand synthesis was not affected by the rifampicin inhibition of S. lividans RNA polymerase. Likewise, in vitro lagging strand synthesis using cell-free extracts revealed sso-independent, rifampicin-resistant lagging strand synthesis in S. lividans. Although all four dNTPs are usually required for the initiation of such synthesis, the presence of only one NTP was sufficient to carry outlagging strand synthesis in vitro. Interestingly, the cell-free extract of exponential-phase cells required less ATP than that of stationary-phase cells. These results reveal a predominant RNA polymerase-independent priming system in S. lividans that may be a result of the stabilization of RC plasmids lacking sso in S. lividans.

Decline in excision circles requires homeostatic renewal or homeostatic death of naive T cells.

When the TCR is formed in the thymus, fragments of DNA are excised from the T cell progenitor chromosome. These TCR rearrangement excision circles (TRECs) are stable, are not replicated in cell division and are therefore most frequent in naive T cells that have recently left the thymus. During life, the average TREC content of peripheral naive T cells decreases between one and two orders of magnitude in humans. It is generally believed that the age-dependent decrease in the production of naive T cells by the thymus is sufficient to explain the decrease in the TREC content. Here, we demonstrate that this decrease in thymic production is required, but it is not sufficient to explain the TREC data. Only if the decrease in thymic output is compensated by homeostasis can one explain the decrease in the TREC content. The homeostatic response can take two forms: when the total number of naive T cells declines, there could be an increase in the renewal rate or an increase of the average cellular lifespan.