Tinzaparin inhibits VL30 retrotransposition induced by oxidative stress and/or VEGF in HC11 mouse progenitor mammary cells: Association between inhibition of cancer stem cell proliferation and mammosphere disaggregation.

Tinzaparin is an anticoagulant and antiangiogenic drug with inhibitory properties against tumor growth. VEGF stimulates angiogenesis, while an association between reactive oxygen species (ROS) and angiogenesis is involved in tumor progression. The present study aimed to investigate the effect of tinzaparin on VL30 retrotransposition­positive mouse HC11 mammary stem­like epithelial cells, previously reported to be associated with induced mammosphere/cancer stem cell (CSC) generation and tumorigenesis. Under 24 h serum starvation, 15.2% nominal retrotransposition frequency was increased to 29%. Additionally, while treatment with 3­12 ng/ml VEGF further induced retrotransposition frequency in a dose­dependent manner (up to 40.3%), pre­incubation with tinzaparin (2 IU/ml) for 0.5­4 h reduced this frequency to 18.3% in a time­dependent manner, confirmed by analogous results in NIH3T3 fibroblasts. Treatment with 10­40 pg/ml glucose oxidase (GO) for 24 h induced HC11 cell retrotransposition in a dose­dependent manner (up to 82.5%), while a 3 h pre­incubation with tinzaparin (1 or 2 IU/ml) elicited a 13.5 or 25.5% reduction in retrotransposition, respectively. Regarding tumorigenic VL30 retrotransposition­positive HC11 cells, treatment with 2 IU/ml tinzaparin for 5 days reduced proliferation rate in a time­dependent manner (up to ~55%), and after 3 weeks, disaggregated soft agar­formed foci, as well as low­adherent mammospheres, producing single mesenchymal­like cells with a ~50% reduced retrotransposition. With respect to the VL30 retrotransposition mechanism: While 12 ng/ml VEGF increased the level of VL30 and endogenous reverse transcriptase (enRT) transcripts ~1.41­ and ~1.16­fold, respectively, subsequent tinzaparin treatment reduced both endogenous/ROS­ and VEGF­induced levels 1.15­ and 0.40­fold (VL30) and 0.60­ and 0.52­fold (enRT), respectively. To the best of our knowledge, these data demonstrate for the first time, the novel inhibition activity of tinzaparin against ROS­ and VEGF­induced VL30 retrotransposition, and the proliferation and/or aggregation of mouse HC11 mammosphere/tumor­initiating CSCs, thus contributing to the inhibition of VL30 retrotransposition­induced primary tumor growth.

VL30 retrotransposition is associated with induced EMT, CSC generation and tumorigenesis in HC11 mouse mammary stem­like epithelial cells.

Retrotransposons copy their sequences via an RNA intermediate, followed by reverse transcription into cDNA and random insertion, into a new genomic locus. New retrotransposon copies may lead to cell transformation and/or tumorigenesis through insertional mutagenesis. Methylation is a major defense mechanism against retrotransposon RNA expression and retrotransposition in differentiated cells, whereas stem cells are relatively hypo­methylated. Epithelial­to­mesenchymal transition (EMT), which transforms normal epithelial cells into mesenchymal­like cells, also contributes to tumor progression and tumor metastasis. Cancer stem cells (CSCs), a fraction of undifferentiated tumor­initiating cancer cells, are reciprocally related to EMT. In the present study, the outcome of long terminal repeat (LTR)­Viral­Like 30 (VL30) retrotransposition was examined in mouse mammary stem­like/progenitor HC11 epithelial cells. The transfection of HC11 cells with a VL30 retrotransposon, engineered with an EGFP­based retrotransposition cassette, elicited a higher retrotransposition frequency in comparison to differentiated J3B1A and C127 mouse mammary cells. Fluorescence microscopy and PCR analysis confirmed the specificity of retrotransposition events. The differentiated retrotransposition­positive cells retained their epithelial morphology, while the respective HC11 cells acquired mesenchymal features associated with the loss of E­cadherin, the induction of N­cadherin, and fibronectin and vimentin protein expression, as well as an increased transforming growth factor (TGF)­ß1, Slug, Snail­1 and Twist mRNA expression. In addition, they were characterized by cell proliferation in low serum, and the acquisition of CSC­like properties indicated by mammosphere formation under anchorage­independent conditions. Mammospheres exhibited an increased Nanog and Oct4 mRNA expression and a CD44+/CD24­/low antigenic phenotype, as well as self­renewal and differentiation capacity, forming mammary acini­like structures. DNA sequencing analysis of retrotransposition­positive HC11 cells revealed retrotransposed VL30 copies integrated at the vicinity of EMT­, cancer type­ and breast cancer­related genes. The inoculation of these cells into Balb/c mice produced cytokeratin­positive tumors containing pancytokeratin­positive cells, indicative of cell invasion features. On the whole, the findings of the present study demonstrate, for the first time, to the best of our knowledge, that stem­like epithelial HC11 cells are amenable to VL30 retrotransposition associated with the induction of EMT and CSC generation, leading to tumorigenesis.

Genomic analysis of mouse VL30 retrotransposons.

BACKGROUND: Retrotransposons are mobile elements that have a high impact on shaping the mammalian genomes. Since the availability of whole genomes, genomic analyses have provided novel insights into retrotransposon biology. However, many retrotransposon families and their possible genomic impact have not yet been analysed. RESULTS: Here, we analysed the structural features, the genomic distribution and the evolutionary history of mouse VL30 LTR-retrotransposons. In total, we identified 372 VL30 sequences categorized as 86 full-length and 49 truncated copies as well as 237 solo LTRs, with non-random chromosomal distribution. Full-length VL30s were highly conserved elements with intact retroviral replication signals, but with no protein-coding capacity. Analysis of LTRs revealed a high number of common transcription factor binding sites, possibly explaining the known inducible and tissue-specific expression of individual elements. The overwhelming majority of full-length and truncated elements (82/86 and 40/49, respectively) contained one or two specific motifs required for binding of the VL30 RNA to the poly-pyrimidine tract-binding protein-associated splicing factor (PSF). Phylogenetic analysis revealed three VL30 groups with the oldest emerging ~17.5 Myrs ago, while the other two were characterized mostly by new genomic integrations. Most VL30 sequences were found integrated either near, adjacent or inside transcription start sites, or into introns or at the 3' end of genes. In addition, a significant number of VL30s were found near Krueppel-associated box (KRAB) genes functioning as potent transcriptional repressors. CONCLUSION: Collectively, our study provides data on VL30s related to their: (a) number and structural features involved in their transcription that play a role in steroidogenesis and oncogenesis; (b) evolutionary history and potential for retrotransposition; and (c) unique genomic distribution and impact on gene expression.

Arsenic induces VL30 retrotransposition: the involvement of oxidative stress and heat-shock protein 70.

Arsenic is an environmental contaminant with known cytotoxic and carcinogenic properties, but the cellular mechanisms of its action are not fully known. As retrotransposition consists a potent mutagenic factor affecting genome stability, we investigated the effect of arsenic on retrotransposition of an enhanced green fluorescent protein (EGFP)-tagged nonautonomous long terminal repeat (LTR)-retrotransposon viral-like 30 (VL30) in a mouse NIH3T3 cell culture-retrotransposition assay. Flow cytometry analysis of assay cells treated with 2.5-20µM sodium arsenite revealed induction of retrotransposition events in a dose- and time-dependent manner, which was further confirmed as genomic integrations by PCR analysis and appearance of EGFP-positive cells by UV microscopy. Specifically, 20µM sodium arsenite strongly induced the VL30 retrotransposition frequency, which was ~90,000-fold higher than the natural one and also VL30 RNA expression was ~6.6-fold. Inhibition of the activity of endogenous reverse transcriptases by efavirenz at 15µM or nevirapine at 375µM suppressed the arsenite-induced VL30 retrotransposition by 71.16 or 79.88%, respectively. In addition, the antioxidant N-acetyl-cysteine reduced the level of arsenite-induced retrotransposition, which correlated with the rescue of arsenite-induced G2/M cell cycle arrest and cell toxicity. Treatment of assay cells ectopically overexpressing the human heat-shock protein 70 (Hsp70) with 15µM sodium arsenite resulted in an additional ~4.5-fold induction of retrotransposition compared with normal assay cells, whereas treatment with 20µM produced a massive cell death. Our results show for the first time that arsenic both as an oxidative and heat-shock mimicking agent is a potent inducer of VL30 retrotransposition in mouse cells. The impact of arsenic-induced retrotransposition, as a cellular response, on contribution to or explanation of the arsenic-associated toxicity and carcinogenicity is discussed.

H2O2 signals via iron induction of VL30 retrotransposition correlated with cytotoxicity.

The impact of oxidative stress on mobilization of endogenous retroviruses and their effects on cell fate is unknown. We investigated the action of H2O2 on retrotransposition of an EGFP-tagged mouse LTR-retrotransposon, VL30, in an NIH3T3 cell-retrotransposition assay. H2O2 treatment of assay cells caused specific retrotranspositions documented by UV microscopy and PCR analysis. Flow cytometric analysis revealed an unusually high dose- and time-dependent retrotransposition frequency induced, ∼420,000-fold at 40 µM H2O2 compared to the natural frequency, which was reduced by ectopic expression of catalase. Remarkably, H2O2 moderately induced the RNA expression of retrotransposon B2 without affecting the basal expression of VL30s and L1 and significantly induced the expression of various endogenous reverse transcriptase genes. Further, whereas treatment with 50 µM FeCl2 alone was ineffective, cotreatment with 10 µM H2O2 and 50 µM FeCl2 caused a 6-fold higher retrotransposition induction than H2O2 alone, which was associated with cytotoxicity. H2O2- or H2O2/FeCl2-induced retrotransposition was significantly reduced by the iron chelator DFO or the antioxidant NAC, respectively. Furthermore, both H2O2-induced retrotransposition and associated cytotoxicity were inhibited after pretreatment of cells with DFO or the reverse transcriptase inhibitors efavirenz and etravirine. Our data show for the first time that H2O2, acting via iron, is a potent stimulus of retrotransposition contributing to oxidative stress-induced cell damage.

VL30 retrotransposition signals activation of a caspase-independent and p53-dependent death pathway associated with mitochondrial and lysosomal damage.

The impact of long terminal repeat (LTR) retrotransposition on cell fate is unknown. Here, we investigated the effect of VL30 retrotransposition on cell death in SV40-transformed mouse SVTT1 cells. Transfection of a VL30 retrotransposon decreased the clonogenicity of SVTT1 by 17-fold, as compared to parental NIH3T3 cells. Correlated levels of retrotransposition frequency and cell death rates were found in retrotransposition-positive SVTT1 cloned cells, exhibiting DNA fragmentation, nuclear condensation, multinucleation and cytoplasmic vacuolization. Analysis of activation of effector caspases revealed a caspase-independent cell death mechanism. However, cell death was associated with p53 induction and concomitant upregulation of PUMAalpha and Bax and downregulation of Bcl-2 and Hsp70 protein expression. Moreover, we found partial loss of colocalization of large T-antigen (LT)/p53 and p53 translocation to mitochondria, leading to mitochondrial outer membrane permeabilization (MOMP) accompanied by lysosomal membrane permeabilization (LMP). Interestingly, treatment with the antioxidant N-acetylcysteine abolished cell death, suggesting the involvement of mitochondrial-derived reactive oxygen species, and resulted in an increase of retrotransposition frequency. Importantly, the induction of cell death was VL30 retrotransposon-specific as VL30 mobilization was induced; in contrast, mobilization of the non-LTR L1 (LINE-1, long interspersed nuclear element-1), B2 and LTR MusD retrotransposons decreased. Our results provide, for the first time, strong evidence that VL30 retrotransposition mediates cell death via mitochondrial and lysosomal damage, uncovering the role of retrotransposition as a nuclear signal activating a mitochondrial-lysosomal crosstalk in triggering cell death.

Vanadium induces VL30 retrotransposition at an unusually high level: a possible carcinogenesis mechanism.

Carcinogenesis by vanadium is thought to occur through induction of DNA-double-strand breaks (DSBs) but its mechanism is not fully understood. We investigated the effect of vanadium on induction of viral-like 30 element (VL30) retrotransposition using a NIH3T3 cell-retrotransposition assay based on a recombinant VL30/EGFP element. Incubation of assay cells with vanadyl sulphate (VOSO(4)) induced retrotransposition frequency in a dose and time-dependent manner, measured by fluorescence-activated cell scanning (FACS) and retrotransposition events were confirmed by UV microscopy and PCR analysis. Among vanadium salts with different valence tested, vanadyl (4+) ions were the most potent retrotransposition inducers. VOSO(4), at 50 muM induced retrotranspositions at an unusually high frequency of up to 0.185 events per cell per generation. VOSO(4), acting at the transcription level, strongly induced VL30 and endogenous reverse transcriptase (enRT) transcripts with maxima at 50 muM and 100 muM of 22 and 18-fold, respectively. VOSO(4)-induced retrotransposition frequency was inhibited by 42% with efavirenz, an inhibitor of enRTs, while paraquat, a DNA-DSBs inducer, had no effect. Furthermore, it was completely abolished with deferoxamine, a metal chelator, while reduced by 75% with N-acetyl-cysteine, a general antioxidant. Remarkably, H(2)O(2) reproduced inducible retrotransposition linking for the first time oxidative stress to induction of retrotransposition. We propose that VOSO(4)-induced VL30 retrotransposition through H(2)O(2) generation may be an alternative mutagenic, DNA-DSBs independent, mechanism leading to carcinogenesis.

SV40 large T antigen up-regulates the retrotransposition frequency of viral-like 30 elements.

The regulation of non-autonomous retrotransposition is not known. A recombinant bearing a hygromycin gene and a viral-like 30 (VL30) retrotransposon tagged with an enhanced green fluorescent protein (EGFP) gene-based retrotransposition cassette was constructed and used for detection of retrotransposition events. Transfection of this recombinant produced retrotransposition events, detected both by EGFP fluorescence and PCR analysis, in hygromycin-selected clones of two established simian virus 40 (SV40)-transformed mouse NIH3T3 cell lines but not in normal NIH3T3 cells. The retrotransposition potential of this recombinant, as a provirus, was studied in stably transfected NIH3T3 clones. Transfection of these clones with either a wild-type or a mutant LE1135T SV40 large T antigen gene, not expressing small t protein, induced retrotransposition events at high frequencies as measured by fluorescence-activated cell scanning (FACS). In addition, measuring retrotransposition frequencies over a period of nine days following infection with isolated SV40 particles, revealed that the frequency of retrotransposition was time-dependent and induced as early as 24 h, increasing exponentially to high levels (>10(-2) events per cell per generation) up to nine days post-infection. Furthermore, ectopic expression of a cloned MoMLV-reverse transcriptase gene also produced retrotransposition events and suggested that the large T antigen most likely acted through induction of expression of endogenous reverse transcriptase genes. Our results show a direct correlation between SV40-cell transformation and VL30 retrotransposition and provide for the first time strong evidence that SV40 large T antigen up-regulates the retrotransposition of VL30 elements.