Selective inhibition of the human tie-1 promoter with triplex-forming oligonucleotides targeted to Ets binding sites

Development and functional evaluation of a psoralen-conjugated nucleoside mimic for triplex-forming oligonucleotides

Psoralen-conjugated triplex-forming oligonucleotides (Ps-TFOs) have been employed for the photodynamic regulation of gene expression by the photo-cross-linking of psoralen with the target DNA. However, stable triplex formation requires a consecutive purine base sequence in one strand of the target DNA duplexes. The pyrimidine-base interruption in the consecutive purine base sequence drastically decreases the thermodynamic stability of the corresponding triplex, which hampers the TFO application. Here, we propose a design of the Ps-TFO for stable triplex formation with target DNA sequences containing pyrimidine-base interruptions under physiological conditions. This Ps-TFO, named 1'(one)-psoralen-conjugated triplex-forming oligonucleotide (OPTO), incorporates a synthesized nucleoside mimic 1'-psoralen-conjugated deoxyribose to increase the thermodynamic stability of the corresponding triplex by the intercalation of psoralen. The triplex-forming abilities of the OPTO were successfully demonstrated in combination with LNA and 5-methylcytosine, indicating that the use of OPTO will expand the range of the target sequences of TFO for photodynamic gene regulation.

Tailed-Hoogsteen Triplex DNA Silver Nanoclusters Emit Red Fluorescence upon Target miRNA Sensing

MicroRNAs (miRNAs) are small RNA molecules, typically 21‒22 nucleotides in size, which play a crucial role in regulating gene expression in most eukaryotes. Their significance in various biological processes and disease pathogenesis has led to considerable interest in their potential as biomarkers for diagnosis and therapeutic applications. In this study, a novel method for sensing target miRNAs using Tailed-Hoogsteen triplex DNA-encapsulated Silver Nanoclusters (DNA/AgNCs) is introduced. Upon hybridization of a miRNA with the tail, the Tailed-Hoogsteen triplex DNA/AgNCs exhibit a pronounced red fluorescence, effectively turning on the signal. It is successfully demonstrated that this miRNA sensor not only recognized target miRNAs in total RNA extracted from cells but also visualized target miRNAs when introduced into live cells, highlighting the advantages of the turn-on mechanism. Furthermore, through gel-fluorescence assays and small-angle X-ray scattering (SAXS) analysis, the turn-on mechanism is elucidated, revealing that the Tailed-Hoogsteen triplex DNA/AgNCs undergo a structural transition from a monomer to a dimer upon sensing the target miRNA. Overall, the findings suggest that Tailed-Hoogsteen triplex DNA/AgNCs hold great promise as practical sensors for small RNAs in both in vitro and cell imaging applications.

Recent Advancements in Development and Therapeutic Applications of Genome-Targeting Triplex-Forming Oligonucleotides and Peptide Nucleic Acids

Recent developments in artificial nucleic acid and drug delivery systems present possibilities for the symbiotic engineering of therapeutic oligonucleotides, such as antisense oligonucleotides (ASOs) and small interfering ribonucleic acids (siRNAs). Employing these technologies, triplex-forming oligonucleotides (TFOs) or peptide nucleic acids (PNAs) can be applied to the development of symbiotic genome-targeting tools as well as a new class of oligonucleotide drugs, which offer conceptual advantages over antisense as the antigene target generally comprises two gene copies per cell rather than multiple copies of mRNA that are being continually transcribed. Further, genome editing by TFOs or PNAs induces permanent changes in the pathological genes, thus facilitating the complete cure of diseases. Nuclease-based gene-editing tools, such as zinc fingers, CRISPR-Cas9, and TALENs, are being explored for therapeutic applications, although their potential off-target, cytotoxic, and/or immunogenic effects may hinder their in vivo applications. Therefore, this review is aimed at describing the ongoing progress in TFO and PNA technologies, which can be symbiotic genome-targeting tools that will cause a near-future paradigm shift in drug development.

Silver Nanoclusters Serve as Fluorescent Rivets Linking Hoogsteen Triplex DNA and Hairpin-Loop DNA Structures

Greater understanding of the mutual influence between DNA and the associated nanomaterial on the properties of each other can provide alternative strategies for designing and developing DNA nanomachines. DNA secondary structures are essential for encapsulating highly emissive silver nanoclusters (DNA/AgNCs). Likewise, AgNCs stabilize secondary DNA structures, such as hairpin DNA, duplex DNA, and parallel-motif DNA triplex. In this study, we found that the fluorescence of AgNCs encapsulated within a Hoogsteen triplex DNA structure can be turned on and off in response to pH changes. We also show that AgNCs can act as nanoscale rivets, linking two functionally distinctive DNA nanostructures. For instance, we found that a Hoogsteen triplex DNA structure with a seven-cytosine loop encapsulates red fluorescent AgNCs. The red fluorescence faded under alkaline conditions, whereas the fluorescence was restored in a near-neutral environment. Hairpin DNA and random DNA structures did not exhibit this pH-dependent AgNCs fluorescence. A fluorescence lifetime measurement and a small-angle X-ray scattering analysis showed that the triplex DNA-encapsulated AgNCs were photophysically convertible between bright and dark states. An in-gel electrophoresis analysis indicated that bright and dark convertibility depended on the AgNCs-riveted dimerization of the triplex DNAs. Moreover, we found that AgNCs rivet the triplex DNA and hairpin DNA to form a heterodimer, emitting orange fluorescence. Our findings suggest that AgNCs between two cytosine-rich loops can be used as nanorivets in designing noncanonical DNA origami beyond Watson-Crick base pairing.

Antigene and Antiproliferative Effects of Triplex-Forming Oligonucleotide (TFO) Targeted on hmgb1 Gene in Human Hepatoma Cells

BACKGROUND

The high mobility group box 1 (hmgb1) is one of the frequently over-expressed genes whose aberrant expression is reported in a number of human cancers. Various strategies are underway to inhibit hmgb1 expression in cancer cells having considerable therapeutic value.

OBJECTIVE

The present work involves selective transcriptional inhibition of the hmgb1 gene using selective DNA triplex structure-based gene technology. Here, the promoter region of the hmgb1 gene at position (-183 to -165) from the transcription start site as a target was selected using bioinformatic tools.

METHODS

The DNA triplex formation by the DNA of the target gene and TFO was confirmed using UV absorption spectroscopy, Circular Dichroism, and Isothermal Calorimetry.

RESULTS

Treatment of HepG2 cell with specific Triplex-forming Oligonucleotide significantly downregulated HMGB1 expression level at mRNA and protein levels by 50%, while the classical anticancer drugs, actinomycin/ adriamycin as positive controls showed 65% and the combination of TFO and drug decreased by 70%. The anti-proliferative effects of TFO correlated well with the fact of accumulation of cells in the Go phase and apoptotic cell death. Further, the binding of anti-cancer drugs to hmgb1 is stronger in DNA triplex state as compared to hmgb1 alone, suggesting the combination therapy as a better option.

CONCLUSION

Therefore, the ability of hmgb1 targeted triplex-forming oligonucleotide in combination with triplex selective anticancer drug holds promise in the treatment of malignancies associated with hmgb1 overexpression. The result obtained may open up new vistas to provide a basis for the rational drug design and searching for high-affinity ligands with a high triplex selectivity.

Triplex DNA Nanostructures: From Basic Properties to Applications

Triplex nucleic acids have recently attracted interest as part of the rich "toolbox" of structures used to develop DNA-based nanostructures and materials. This Review addresses the use of DNA triplexes to assemble sensing platforms and molecular switches. Furthermore, the pH-induced, switchable assembly and dissociation of triplex-DNA-bridged nanostructures are presented. Specifically, the aggregation/deaggregation of nanoparticles, the reversible oligomerization of origami tiles and DNA circles, and the use of triplex DNA structures as functional units for the assembly of pH-responsive systems and materials are described. Examples include semiconductor-loaded DNA-stabilized microcapsules, DNA-functionalized dye-loaded metal-organic frameworks (MOFs), and the pH-induced release of the loads. Furthermore, the design of stimuli-responsive DNA-based hydrogels undergoing reversible pH-induced hydrogel-to-solution transitions using triplex nucleic acids is introduced, and the use of triplex DNA to assemble shape-memory hydrogels is discussed. An outlook for possible future applications of triplex nucleic acids is also provided.

Triplex forming oligonucleotides targeted to hmga1 selectively inhibit its expression and induce apoptosis in human cervical cancer

High-mobility group A1 (HMGA1) is a non-histone chromosomal protein, which is known as 'architectural' transcription factor that facilitates the assembly of 'enhanceosome.' Because of its elevated expression in a number of human malignancies, with barely minimal levels in healthy adults, HMGA1 is considered as potential 'tumor marker.' Therefore, we looked at the inhibition of hmga1 using anti-gene strategy, as an attractive therapeutic approach. This was achieved by two triplex forming oligonucleotides (TFOs), TFO1 and TFO2 targeted to the promoter of hmga1 at positions, -284--304 and -2800--2826, respectively. The stability of two DNA triplexes was characterized using a variety of biophysical and thermodynamics techniques and was confirmed by gel retardation assay using γ-³²P [ATP]. The efficacy of TFOs on HMGA1 expression was evaluated in HeLa cells using MTT assay, Flow cytometry, Western blot, and RT-PCR. Results revealed that DNA Triplex1 formed by TFO1 is more stable and stronger than the corresponding Triplex2. Although both TFOs downregulated hmga1 expression at mRNA and protein levels and caused apoptotic cell death in HeLa cell line, TFO1 demonstrated a greater effect at low concentration which corroborates well with the stability data. Thus, TFO-mediated inhibition of hmga1 expression can be a promising strategy for the development of novel anti-cancer therapeutics.

Preferential binding of anticancer drugs to triplex DNA compared to duplex DNA: a spectroscopic and calorimetric study

Binding study of adriamycin and actinomycin to triplex DNA formed on the promoter region of hmgb1 gene using spectroscopic and calorimetric technique.

Improved design of PPRHs for gene silencing

Nowadays, the modulation of gene expression by nucleic acids has become a routine tool in biomedical research for target validation and it is also used to develop new therapeutic approaches. Recently, we developed the so-called polypurine reverse Hoogsteen hairpins (PPRHs) that show high stability and a low immunogenic profile and we demonstrated their efficacy both in vitro and in vivo. In this work, we explored different characteristics of PPRHs to improve their usage as a tool for gene silencing. We studied the role of PPRH length in the range from 20 to 30 nucleotides. We also proved their higher affinity of binding and efficacy on cell viability compared to nonmodified TFOs. To overcome possible off-target effects, we tested wild-type PPRHs, which proved to be capable of binding to their target sequence with more affinity, displaying a higher stability of binding and a higher effect in terms of cell viability. Moreover, we developed a brand new molecule called Wedge-PPRH with the ability to lock the ds-DNA into the displaced structure and proved its efficacy in prostate and breast cancer cell lines.

Understanding the role of ETS-mediated gene regulation in complex biological processes

Ets factors are members of one of the largest families of evolutionarily conserved transcription factors, regulating critical functions in normal cell homeostasis, which when perturbed contribute to tumor progression. The well-documented alterations in ETS factor expression and function during cancer progression result in pleiotropic effects manifested by the downstream effect on their target genes. Multiple ETS factors bind to the same regulatory sites present on target genes, suggesting redundant or competitive functions. The anti- and prometastatic signatures obtained by examining specific ETS regulatory networks will significantly improve our ability to accurately predict tumor progression and advance our understanding of gene regulation in cancer. Coordination of multiple ETS gene functions also mediates interactions between tumor and stromal cells and thus contributes to the cancer phenotype. As such, these new insights may provide a novel view of the ETS gene family as well as a focal point for studying the complex biological control involved in tumor progression. One of the goals of molecular biology is to elucidate the mechanisms that contribute to the development and progression of cancer. Such an understanding of the molecular basis of cancer will provide new possibilities for: (1) earlier detection, as well as better diagnosis and staging of disease; (2) detection of minimal residual disease recurrences and evaluation of response to therapy; (3) prevention; and (4) novel treatment strategies. Increased understanding of ETS-regulated biological pathways will directly impact these areas.

Properties of oligonucleotide with phenyl-substituted carbocyclic nucleoside analogs for the formation of duplex and triplex DNA

(1S,3S,4R)-1-Phenyl-1-thymidyl-3-hydroxy-4-hydroxymethylcyclopentane (10) and their analogs were synthesized, incorporated into the oligodeoxynucleotides, and their properties were evaluated for the formation of duplex and triplex DNA. The known chiral cyclopentanone derivative was converted into the corresponding ketimine sulfonamide derivative, which was subjected to a stereoselective PhLi addition. The formed sulfonamide was hydrolyzed to afford the primary amino group, on which the thymine moiety was built. The benzyl protecting groups were removed to form the nucleoside analog having a phenyl group and the thymine unit at the 1' position of a carbocyclic skeleton (10). In the estimation of the oligodeoxynucleotides incorporating 10 for duplex and triplex formation, the carbocyclic nucleoside analog 10 did not show the stabilizing effect for duplex formation; on the other hand, it stabilized the triplex. Therefore, the skeleton of the phenyl-substituted carbocyclic nucleoside analog 10 may be a platform for the formation of stable triplex DNA.

Identification and characterization of a novel porcine endothelial cell-specific Tie1 promoter

BACKGROUND

The use of a transgenic pig for xenotransplantation and as a cardiovascular disease model has caught much attention in the past decades. The vascular endothelial cell is the primary modification target for the application of genetically modified pigs in this field. However, the powerful porcine endothelial cell-specific promoter is still so rare that the mouse and human promoters are commonly used. In the study, the porcine Tie1 (sTie1) promoter was identified and characterized as a potential endothelial cell-specific promoter to generate a cardiovascular disease model.

METHODS

Tie1 promoters with different lengths of 5'-regulatory regions were cloned, and major putative DNA-binding motifs were mutated by site-directed mutagenesis. All fragments were ligated into the luciferase reporter system and were transiently transfected into endothelial cells to identify luciferase activity using a dual luciferase reporter assay.

RESULTS

The luciferase activities of sTie1 promoters with different lengths of the 5'-regulatory region were tested. Results showed that the luciferase activity of the 1234-bp sTie1 fragment was the strongest compared with that of others (P < 0.001). Site-directed mutagenesis in transcription-factor-binding sites, including Ets, GATA, and AP2, verified their key roles in regulating transcription, especially sites Ets (-103), GATA (-211), and AP2 (-3). The activities of Tie1 promoters from pig, human, and mouse were significantly different in pig iliac endothelial cells (PIECs) (P < 0.001), and the sTie1 promoter showed the highest activity. Moreover, sTie1 promoter activity could be detected in porcine embryo fibroblasts and skeletal muscle cells.

CONCLUSIONS

The sTie1 promoter shows a highly conserved sequence compared with the Tie1 promoters in human and mouse, but it has a greater activity in the porcine endothelial cell line than that of human and mouse promoters. Thus, sTie1 will be a valuable tool for generating a pig cardiovascular disease model.

Potential in vivo roles of nucleic acid triple-helices

The ability of double-stranded DNA to form a triple-helical structure by hydrogen bonding with a third strand is well established, but the biological functions of these structures remain largely unknown. There is considerable albeit circumstantial evidence for the existence of nucleic triplexes in vivo and their potential participation in a variety of biological processes including chromatin organization, DNA repair, transcriptional regulation, and RNA processing has been investigated in a number of studies to date. There is also a range of possible mechanisms to regulate triplex formation through differential expression of triplex-forming RNAs, alteration of chromatin accessibility, sequence unwinding and nucleotide modifications. With the advent of next generation sequencing technology combined with targeted approaches to isolate triplexes, it is now possible to survey triplex formation with respect to their genomic context, abundance and dynamical changes during differentiation and development, which may open up new vistas in understanding genome biology and gene regulation.

Polypurine hairpins directed against the template strand of DNA knock down the expression of mammalian genes

We analyzed whether polypurine hairpins (PPRHs) had the ability to knock down gene expression. These hairpins are formed by two antiparallel purine domains linked by a loop that allows the formation of Hoogsteen bonds between both domains and Watson-Crick bonds with the target polypyrimidine sequence, forming triplex structures. To set up the experimental conditions, the human dhfr gene was used as a model. The PPRHs were designed toward the template strand of DNA. The transfection of the human breast cancer cell line SKBR3 with these template hairpins against the dhfr gene produced higher than 90% of cell mortality. Template PPRHs produced a decrease in DHFR mRNA, protein, and its corresponding enzymatic activity. In addition, the activity of DHFR PPRHs was tested against breast cancer cells resistant to methotrexate, observing high cell mortality. Given the difficulty in finding long polypyrimidine stretches, we studied how to compensate for the presence of purine interruptions in the polypyrimidine target sequence. The stability of PPRH was measured, resulting in a surprisingly long half-life of about 5 days. Finally, to test the generality of usage, template PPRHs were employed against two important genes involved in cell proliferation, telomerase and survivin, producing 80 and 95% of cell death, respectively. Taken together our results show the ability of antiparallel purine hairpins to bind the template strand of double strand DNA and to decrease gene transcription. Thus, PPRHs can be considered as a new type of molecules to modulate gene expression.

The triple helix: 50 years later, the outcome

Triplex-forming oligonucleotides constitute an interesting DNA sequence-specific tool that can be used to target cleaving or cross-linking agents, transcription factors or nucleases to a chosen site on the DNA. They are not only used as biotechnological tools but also to induce modifications on DNA with the aim to control gene expression, such as by site-directed mutagenesis or DNA recombination. Here, we report the state of art of the triplex-based anti-gene strategy 50 years after the discovery of such a structure, and we show the importance of the actual applications and the main challenges that we still have ahead of us.

Targeting transcription factors for therapeutic benefit

Transcription factors are a large class of biological molecules that are important for health and disease. Despite that there are challenges to targeting them therapeutically and most approaches alter their activity indirectly. Research at the chemical biology interface has led to the development of new ways of targeting transcription factors including blocking transcription factor dimerisation, targeting specific DNA sequences and DNA decoys. This review discusses these issues with a view to inspiring the development of new agents that could be useful for the treatment of cancer.

Purine twisted-intercalating nucleic acids: a new class of anti-gene molecules resistant to potassium-induced aggregation

Sequence-specific targeting of genomic DNA by triplex-forming oligonucleotides (TFOs) is a promising strategy to modulate in vivo gene expression. Triplex formation involving G-rich oligonucleotides as third strand is, however, strongly inhibited by potassium-induced TFO self-association into G-quartet structures. We report here that G-rich TFOs with bulge insertions of (R)-1-O-[4-(1-pyrenylethynyl)-phenylmethyl] glycerol (called twisted intercalating nucleic acids, TINA) show a much lower tendency to aggregate in potassium than wild-type analogues do. We designed purine-motif TINA–TFOs for binding to a regulatory polypurine-polypyrimidine (pur/pyr) motif present in the promoter of the KRAS proto-oncogene. The binding of TINA–TFOs to the KRAS target has been analysed by electrophoresis mobility shift assays and DNase I footprinting experiments. We discovered that in the presence of potassium the wild-type TFOs did not bind to the KRAS target, differently from the TINA analogues, whose binding was observed up to 140 mM KCl. The designed TINA–TFOs were found to abrogate the formation of a DNA–protein complex at the pur/pyr site and to down-regulate the transcription of CAT driven by the murine KRAS promoter. Molecular modelling of the DNA/TINA–TFO triplexes are also reported. This study provides a new and promising approach to create TFOs to target in vivo the genome.

ETS transcription factors: oncogenes and tumor suppressor genes as therapeutic targets for prostate cancer

ETS factors represent one of the largest families of transcriptional regulators and have known functional roles in many biological processes. Significantly, ETS factors have oncogenic and suppressive activity and their aberrant expression is associated with many of the processes that lead to prostate cancer progression. The targeting of transcription for therapeutic gain has met with some success. Therefore, better understanding the mechanisms that regulate ETS factor activity during both normal and aberrant transcription provides a novel means to identify processes that may be targeted in order to re-establish the normal ETS regulatory networks that are perturbed in cancer. Specific examples of altered ETS factor expression are highlighted, and therapeutic technologies that may be used to target ETS factors and their cofactors and downstream target genes in prostate cancer are discussed.