Protamine-fragment peptides fused to an SV40 nuclear localization signal deliver oligonucleotides that produce antisense effects in prostate and bladder carcinoma cells

The development of antisense technology has focused on improving methods for oligonucleotide delivery into cells. In the present work, we describe a novel strategy for oligonucleotide delivery based on a bifunctional peptide composed of a C-terminal protamine-fragment that contains a DNA-binding domain and an N-terminal nuclear localization signal sequence derived from the SV40 large-T antigen (The sequences of two of the peptides are R6WGR6-PKKKRKV [s-protamine-NLS] and R4SR6FGR6VWR4-PKKKRKV [l-protamine-NLS]). We demonstrated, by intrinsic fluorescence quenching, that peptides of this class form complexes with oligodeoxynucleotides. To evaluate delivery, we used a 20-mer phosphorothioate oligomer (Isis 3521) targeted to the 3'-untranslated region of the PKC-alpha mRNA and G3139, an 18-mer phosphorothioate targeted to the first six codons of the human bcl-2 open reading frame, and complexed them with either of two peptides (s- or l-protamine-NLS). These peptides bind to and deliver antisense oligonucleotides to the nucleus of T24 bladder and PC3 prostate cancer cells, as demonstrated by confocal microscopy. Furthermore, as shown by Western and Northern blotting, the peptide-oligonucleotide complexes produced excellent downregulation of the expression of the complementary mRNAs, which in turn resulted in downregulation of protein expression. However, under certain circumstances (predominantly in PC3 cells), incubation of the cells with chloroquine was required to produce antisense activity. Using this strategy, PKC-alpha protein and mRNA expression in T24 and PC3 cells and bcl-2 expression in PC3 cells was reduced by approximately 75 +/- 10% at a minimum concentration of oligomer of 0.25 microM, in combination with 12-15 microM peptide. On the basis of our results, we conclude that arginine-rich peptides of this class may be potentially useful delivery vehicles for the cellular delivery of antisense oligonucleotides. This new strategy may have several advantages over other methods of oligonucleotide delivery and may complement already existing lipid-based technologies.     

Optical antisense imaging of tumor with fluorescent DNA duplexes

Antisense targeting of tumor with fluorescent conjugated DNA oligomers has the potential of improving tumor/normal tissue ratios over that achievable by nuclear antisense imaging. When administered as a linear duplex of two fluorophore-conjugated oligomers arranged in a manner that inhibits fluorescence as the duplex and designed to dissociate only in the presence of the target mRNA, the fluorescence signal should in principle be inhibited everywhere except in the target cell. Optical imaging by fluorescence quenching using linear fluorophore-conjugated oligomers has not been extensively investigated and may not have been previously considered for antisense targeting. We evaluated in cell culture and in KB-G2 tumor bearing nude mice a 25-mer phosphorothioate (PS) anti- mdr1 antisense DNA conjugated with the Cy5.5 emitter on its 3' equivalent end and hybridized as a linear duplex with a shorter 18-mer phosphodiester (PO) complementary DNA (cDNA) with the Black Hole inhibitor BHQ3 on its 5' end. In serum environments, 90% of the DNA25-Cy5.5 fluorescence was inhibited immediately following addition of the cDNA18-BHQ3 and showed only slight loss of inhibition over 24 h at 37 degrees C. As evidence of antisense specific binding, when incubated with the DNA25-Cy5.5/cDNA18-BHQ3 duplex, the fluorescence was lower in KB-31 (Pgp +/-) cells compared to KB-G2 (Pgp++) cells, but when incubated with the control cDNA18-Cy5.5/DNA25-BHQ3 duplex in which the fluorophores were reversed, the fluorescence of both cell types was low. As further evidence of specific binding, the fluorescent intensity of total RNA from KB-G2 cells incubated with the study duplex showed evidence of dissociation and hybridization with the target mRNA. Furthermore, the fluorescence microscopy images of KB-G2 cells incubated with DNA25-Cy5.5 as the singlet or study duplex show that migration in both cases is to the nucleus. The animal studies were performed in mice bearing KB-G2 tumor in one thigh and receiving iv the study or control duplexes. The tumor/normal thigh fluorescence ratio was clearly positive as early as 30 min postinjection in the study mice and reached a maximum at 5 h. By contrast, much lower fluorescence was observed in mice receiving the control duplex at the same dosage. Fluorescence microscope imaging showed that the Cy5.5 fluorescence was much higher in tumor sections from the animal that had received the study rather than control duplex. Thus combining a fluorophore-conjugated antisense DNA with an inhibitor-conjugated shorter complementary cDNA inhibited fluorescence both in cell culture and in tumored animals except in the presence of the target mRNA. This proof of concept investigation of optical antisense targeting therefore suggests that further studies including optimization of this approach are appropriate.     

A DNA uptake-stimulating protein increases the antiproliferative effect of c-myb antisense oligonucleotide on leukemic cells

Proliferation of HL-60 and MOLT4 leukemia cells was inhibited by a c-myb antisense oligonucleotide (ASO) in the presence of a DNA uptake-stimulating protein (DNA uptake-stimulating factor, DUSF). The inhibitory effect was very mild in the absence of DUSF. Sense oligonucleotides or DUSF, alone or in combination, were found to be ineffective. Cellular expression of the c-myb protein was significantly more inhibited by the c-myb ASO in the presence than in the absence of DUSF. In the presence of DUSF, c-myb protein practically disappeared from the nuclei of HL-60 and MOLT4 cells treated with the ASO. Thus, DUSF appears to effectively stimulate the uptake of c-myb ASO into tumor cells in vitro, augmenting its antiproliferative effect by decreasing c-myb expression.     

Characterization of the sequence-specific interaction of mouse c-myb protein with DNA.

We have examined parameters that affect sequence-specific interactions of the mouse c-myb protein with DNA oligomers containing the Myb-binding motif (CA/CGTTPu). Complexes formed between these oligomers and in vitro translated c-myb proteins were analysed by electrophoresis on non-denaturing polyacrylamide gels using the mobility-shift assay. By progressive truncation of c-myb coding sequences it was demonstrated that amino acids downstream of a region of three imperfect 51-52 residue repeats (designated R1, R2 and R3), which are located close to the amino terminus of the protein, had no qualitative or quantitative effect on the ability to interact specifically with this DNA motif. However, removal of only five amino acids of the R3 repeat completely abolished this activity. The contribution of individual DNA-binding domain repeats to this interaction was investigated by precisely deleting each individually: it was demonstrated that a combination of R2 and R3 was absolutely required for complex formation while the R1 repeat was completely dispensible. c-myb proteins showed quantitatively greater interaction with oligomers containing duplicated rather than single Myb-binding motif, in particular where these were arranged in tandem. Moreover, it was observed that c-myb protein interacted with these tandem motifs as a monomer. These findings imply that a single protein subunit straddles adjacent binding sites and the implications for c-myb activity are discussed.     

Formation of a G-tetrad and higher order structures correlates with biological activity of the RelA (NF-kappaB p65) 'antisense' oligodeoxynucleotide.

We have examined the behavior of the phosphorothioate antisense Rel A (NF-kappaB p65) oligodeoxynucleotide (oligo) and related molecules. Because of the presence of a G-tetrad near its 5'terminus, this molecule is capable of forming tetraplexes and other higher order structures in a temperature and time dependent manner. The G-tetrad in the phosphodiester congener is protected from methylation by dimethylsulfate when the oligomer is 3'-phosphorylated. However, this protection is completely lost when it is 5'phosphorylated, indicating that the formation of at least some higher order structures has been blocked. In addition, we also prevented tetraplex formation by substitution of 7-deazaguanosine (7-DG) for guanosine at several positions within and outside of the tetrad. This substitution retains Watson-Crick base pair hybridization but prevents Hoogsteen base-pair interactions. When murine K-Balb cells were treated with 20microM antisense RelA oligo, complete blockade of nuclear translocation of RelA was observed. However, this effect was virtually entirely abrogated in most cases by 7-DG substitution within the tetrad, but retained when the substitution was made 3' to the tetrad. The AS RelA-induced downregulation of Sp-1 activity behaved similarly after 7-DG substitution. Thus, the parent phosphorothioate AS RelA molecule cannot be a Watson-Crick antisense agent. However, these conclusions cannot be extrapolated to other G-tetrad containing oligomers and each must be evaluated individually.     

Inhibition of MDR1 gene expression by chimeric HNA antisense oligonucleotides

Hexitol nucleic acids (HNAs) are nuclease resistant and provide strong hybridization to RNA. However, there is relatively little information on the biological properties of HNA antisense oligonucleotides. In this study, we compared the antisense effects of a chimeric HNA ‘gapmer’ oligonucleotide comprising a phosphorothioate central sequence flanked by 5′ and 3′ HNA sequences to conventional phosphorothioate oligonucleotides and to a 2′-O-methoxyethyl (2′-O-ME) phosphorothioate ‘gapmer’. The antisense oligomers each targeted a sequence bracketing the start codon of the message of MDR1, a gene involved in multi-drug resistance in cancer cells. Antisense and control oligonucleotides were delivered to MDR1-expressing cells using transfection with the cationic lipid Lipofectamine 2000. The anti-MDR1 HNA gapmer was substantially more potent than a phosphorothioate oligonucleotide of the same sequence in reducing expression of P-glycoprotein, the MDR1 gene product. HNA and 2′-O-ME gapmers displayed similar potency, but a pure HNA antisense oligonucleotide (lacking the phosphorothioate ‘gap’) was ineffective, indicating that RNase H activity was likely required. Treatment with anti-MDR1 HNA gapmer resulted in increased cellular accumulation of the drug surrogate Rhodamine 123 that correlated well with the reduced cell surface expression of P-glycoprotein. Thus, HNA gapmers may provide a valuable additional tool for antisense-based investigations and therapeutic approaches.     

Polyethylenimine but not cationic lipid improves antisense activity of 3'-capped phosphodiester oligonucleotides

Lipofectin, which is a mixture of neutral lipid with a cationic lipid, has been widely used to enhance cellular delivery of phosphorothioate, 2'-sugar-modified, and chimeric antisense oligonucleotides. Phosphodiester oligonucleotides delivered with Lipofectin usually do not elicit antisense activity probably because cationic lipid formulations do not sufficiently protect unmodified oligonucleotides from nuclease degradation. We show that a cationic polymer, polyethylenimine (PEI), improves the uptake and antisense activity of 3'-capped 20-mer and 12-mer antisense phosphodiester oligonucleotides (PO-ODN) targeted to different regions of Ha-ras mRNA and to the 3'-untranslated region (3'-UTR) of C-raf kinase. In contrast, PEI, which forms a very stable complex with the 20-mer phosphorothioate oligonucleotide (PS-ODN), does not enhance its antisense activity. Using fluorescently labeled carriers and ODN, we show that PEI-PS-ODN particles are very efficiently taken up by cells but PS-ODN is not dissociated from the carrier. Our results indicate that carrier-ODN particle size and stability and ODN release kinetics vary with the chemical nature of the ODN and the carrier being transfected into the cells. The very low cost of PEI compared with cytofectins and the increased affinity for target mRNA and decreased affinity for proteins of PO-ODN compared with PS-ODN make the use of PEI-PO-ODN very attractive.     

Potent growth inhibition of leukemic cells by novel ribbon-type antisense oligonucleotides to c-myb1

We studied the effects of antisense oligonucleotides (AS oligos) with a novel structure. The AS oligos were covalently closed to avoid exonuclease activities by enzymatic ligation of two identical molecules. The AS oligos of a ribbon type (RiAS oligos) consist of two loops containing multiple antisense sequences and a stem connecting the two loops. Three antisense sequences targeting different binding sites were placed in a loop that was designed to form a minimal secondary structure by itself. RiAS oligos were found to be stable because they largely preserved their structural integrity after 24 h incubation in the presence of either exonuclease III or serums. When a human promyelocytic cell line, HL-60, was treated with RiAS oligos to c-myb, c-myb expression was effectively ablated. Cell growth was inhibited by >90% determined by both the 3-[4,5-dimethythiazol-2-yl]-2,5-diphenyltetrazolium bromide assay and [(3)H]thymidine incorporation. Further, when the leukemic cell line K562 was treated with c-myb RiAS oligos, colony formation on soft agarose was reduced by 92 +/- 2%. These results suggest that RiAS oligos may be employed for developing molecular antisense drugs as well as for the functional study of a gene.     

Natural and Phosphorothioate-Modified Oligodeoxyribonucleotides Exhibit a Non-Random Cellular Distribution

Abstract

Addition of specific antisense oligomers to LTK- cells infected with HSV-1 has been shown to decrease viral production (1,8). We have investigated the cellular components that contain these oligomers and a phosphorothioate derivative by Normarski light microscopy and gel analysis of sucrose gradient cell fractions. Fractionation analysis suggests that these oligomers are distributed throughout the cell in a non-random manner and gel analysis suggest that intact oligomers are not equally distributed in the cytosol, nuclear or membrane component. Information about the cellular location of antisense oligomers should aid in the understanding of their antiviral effect and in the design of more effective oligonucleotide derivatives as potential antiviral agents.     

A cationic derivative of amphotericin B as a novel delivery system for antisense oligonucleotides

A novel approach based on a plasma membrane permeability-disturbing agent was proposed as an antisense oligonucleotide delivery system. AMA, a derivative of the polyene antibiotic amphotericin B, formed a stable complex when mixed with phosphodiester oligodeoxynucleotides and enhanced the intracellular uptake of a 5' fluoresceinated anti-mdr1 20-mer into NIH-MDR-G185 cells. The nonlabeled phosphorothioate form of the oligodeoxynucleotide, complexed to AMA, inhibited P-glycoprotein expression with better efficiency and less nonspecific effects than when vectorized by Lipofectin. AMA may thus be a good agent for antisense strategy.     

The binding of an antisense oligonucleotide to a hairpin structure via triplex formation inhibits chemical and biological reactions.

We have investigated the binding of a 26-mer antisense oligodeoxynucleotide to a 69-mer DNA hairpin with a 13 base pair stem, bearing an Rsa1 restriction site. The 5' part of the 26-mer annealed to a stretch of six purines at the bottom of the hairpin. The 3' part was designed to fold back to form a triplex with both the stem of the hairpin and with the sequence paired to its own 5' region. Using non-denaturing polyacrylamide gel electrophoresis, melting curves (Tm) and chemical footprinting, we were able to show the formation of a 'double-hairpin' complex between the 69-mer and the 26-mer antisense oligopyrimidines. The association was both sequence and pH-dependent. The formation of a double hairpin complex was shown to prevent the alkylation of the 69-mer DNA target by an oligonucleotide-nitrogen mustard conjugate and to selectively inhibit the action of Rsa1.     

Synthesis of an antisense oligonucleotide targeted against C-raf kinase: efficient oligonucleotide synthesis without chlorinated solvents

It is demonstrated that a solution of dichloroacetic acid in toluene removes dimethoxytrityl groups from the 5'-terminus of an antisense phosphorothioate oligodeoxyribonucleotide (ISIS 5132/CGP69846A) during synthesis on solid support cleanly and efficiently. It is therefore suggested to replace health hazardous dichloromethane which is typically used in oligonucleotide synthesis as solvent for DMTr-removal by toluene.     

Interaction of antisense DNA with nucleic acids/proteins.

In order to study interaction of various types of labeled antisense DNAs were prepared. Fluorescein and 2,2,6,6-tetramethypiperidine-N-oxyl were the label molecules, which were introduced to 5'-end of oligonucleotides and their analogs. Interactions of labeled antisense DNAs with nucleic acids or proteins such as HSA, HIG and TF, were studied by UV, fluorescence depolarization spectroscopy, and ESR spectroscopy. Hybrid formation of antisense DNAs with oligonucleotides in solution could be monitored by the increase in fluorescence anisotropy (r) and by intensity change in ESR spectra. When phosphorothioate type antisense molecules anchoring fluorescein (F-OPT) were mixed with proteins, r drastically increased, whereas ODN slightly increased. These results suggest that OPTs have much more affinity for proteins than ODNs.     

Enhanced activity of an antisense oligonucleotide targeting murine protein kinase C-alpha by the incorporation of 2'-O-propyl modifications.

We have previously described the characterization of a 20mer phosphorothioate oligodeoxynucleotide (ISIS 4189) which inhibits murine protein kinase C-alpha (PKC-alpha) gene expression, both in vitro and in vivo. In an effort to increase the antisense activity of this oligonucleotide, 2'-O-propyl modifications have been incorporated into the 5'- and 3'-ends of the oligonucleotide, with the eight central bases left as phosphorothioate oligodeoxynucleotides. Hybridization analysis demonstrated that these modifications increased affinity by approximately 8 and 6 degrees C per oligonucleotide for the phosphodiester (ISIS 7815) and phosphorothioate (ISIS 7817) respectively when hybridized to an RNA complement. In addition, 2'-O-propyl incorporation greatly enhanced the nuclease resistance of the oligonucleotides to snake venom phosphodiesterase or intracellular nucleases in vivo. The increase in affinity and nuclease stability of ISIS 7817 resulted in a 5-fold increase in the ability of the oligonucleotide to inhibit PKC-alpha gene expression in murine C127 cells, as compared with the parent phosphorothioate oligodeoxynucleotide. Thus an RNase H-dependent phosphorothioate oligodeoxynucleotide can be modified as a 2'-O-propyl 'chimeric' oligonucleotide to provide a significant increase in antisense activity in cell culture.     

Evaluation of some properties of a phosphorodithioate oligodeoxyribonucleotide for antisense application.

An all phosphorodithioate oligodeoxyribonucleotide (PS2; 17-mer) complementary to the coding region of the rabbit beta-globin mRNA was compared with the normal (PO2) and phosphorothioate (POS) oligonucleotide of the same size and sequence with respect to physicochemical properties and antisense activity in cell-free systems. The melting temperature (Tm) of the PS2-cDNA duplex was reduced by 17 degrees C relative to the PO2-cDNA duplex, compared to 11 degrees C for the POS-cDNA duplex, suggesting a decreased stability of the duplex with an increasing sulfur substitution. Like the POS-derivative, the PS2 oligonucleotide is quite stable against exonucleases, but these modified oligonucleotides showed different stability towards endonucleases and also towards different sub-cellular fractions of MCF-7 cells. During in vitro protein binding studies, the PS2 oligonucleotide showed similar binding (10-20%) to that of the PO2 oligonucleotide, while the POS oligonucleotide bound 60%. In cell-free translation, the PS2 oligonucleotide produced slightly higher specific translation inhibition of rabbit beta-globin mRNA compared to that of the PO2 oligonucleotide, and this was true only at concentration below 2 mM. The POS-derivative, except at 10 mM concentration, always showed higher translation arrest of the rabbit beta-globin mRNA compared to that of the other two oligonucleotides. The present study suggests that the PS2 oligonucleotide offers very little advantage over the POS oligonucleotide for use as an antisense analog.     

Inhibition of vascular smooth muscle cell proliferation by ribozymes that cleave c-myb mRNA.

Proliferation of injured smooth muscle cells contributes to the reocclusion or restenosis of coronary arteries that often occurs following angioplasty procedures. We have identified and optimized nuclease-resistant ribozymes that efficiently cleave c-myb RNA. Three ribozymes targeting different sites in the c-myb mRNA were synthesized chemically and delivered to rat aortic smooth muscle cells with cationic lipids; all three inhibited serum-stimulated cell proliferation significantly. RNA molecules with two base substitutions in the catalytic core that render the ribozyme catalytically inactive had little effect on smooth muscle cell proliferation. Ribozymes with scrambled binding arm sequences also failed to affect cell cycle progression of vascular smooth muscle cells. Furthermore, inhibition of rat smooth muscle cell proliferation correlated with a reduction in intact c-myb mRNA. Efficacy of the chemically-modified ribozyme was compared directly to phosphorothioate antisense oligodeoxynucleotides targeting the same site in the c-myb RNA; the ribozyme had superior efficacy and showed greater specificity than the antisense molecules. Exogenously delivered ribozymes also inhibited porcine and human smooth muscle cell proliferation effectively. Ribozymes targeting c-myb or other regulators of smooth muscle cell proliferation may represent novel therapeutics for the treatment of restenosis after coronary angioplasty.     

Selective inhibition of mutant Ha-ras mRNA expression by antisense oligonucleotides.

A biological reporter gene assay was employed to determine the crucial parameters for maximizing selective targeting of a Ha-ras codon 12 point mutation (G----T) using phosphorothioate antisense oligonucleotides. We have tested a series of oligonucleotides ranging in length between 5 and 25 bases, each centered around the codon 12 point mutation. Our results indicate that selective targeting of this point mutation can be achieved with phosphorothioate antisense oligonucleotides, but this selectivity is critically dependent upon oligonucleotide length and concentration. The maximum selectivity observed in antisense experiments, 5-fold for a 17-base oligonucleotide, was closely predicted by a simple thermodynamic model that relates the fraction of mutant to wild type target bound as a function of oligonucleotide concentration and affinity. These results suggest thermodynamic analysis of oligonucleotide/target interactions is useful in predicting the specificity that can be achieved by an antisense oligonucleotide targeted to a single base point mutation.     

Differential effects of c-myb and c-fes antisense oligodeoxynucleotides on granulocytic differentiation of human myeloid leukemia HL60 cells

To gain some insight into the role of c-myb and c-fes in myeloid differentiation, the authors have analyzed the ability of HL60 cells to differentiate in response to several different inducers after inhibition of c-myb and c-fes function. This function has been inhibited almost completely by using deoxynucleotides complementary to two 18-nucleotide sequences of c-myb and c-fes encoding mRNA. After 5 days in culture, in several separate experiments with different oligomer preparations, more than 90% growth inhibition was observed in c-myb antisense-treated HL60 cells. At this time, independent of the differentiation inducer used, c-myb antisense-treated HL60 cells differentiate only along the monocytic pathway, whereas in sense oligomer-treated cultures, retinoic acid and dimethyl sulfoxide induced granulocytic differentiation. No perturbation of the HL60 cell growth was observed after 5 days of treatment with antisense c-fes oligomer. However, induction to granulocytic differentiation by retinoic acid and dimethyl sulfoxide resulted in progressive cell death, whereas monocytic differentiation by other differentiation inducers was only marginally affected. These results suggest that granulocytic, unlike monocytic, differentiation requires c-myb-conditioned proliferation and the activity of the protein encoded by c-fes.     

Evaluating the specificity of antisense oligonucleotide conjugates. A DNA array analysis

Antisense oligonucleotides are potentially powerful tools for selective control of cellular and viral gene expression. Crucial to successful application of this approach is the specificity of the oligonucleotide for the chosen RNA target. Here we apply DNA array technology to examine the specificity of antisense oligonucleotide treatments. The molecules used in these studies consisted of phosphorothioate oligomers linked to the Antennapedia (Ant) delivery peptide. The antisense oligonucleotide component was complementary to a site flanking the AUG of the MDR1 message, which codes for P-glycoprotein, a membrane ATPase associated with multidrug resistance in tumor cells. Using a DNA array of 2059 genes, we analyzed cellular responses to molecules comprised of Ant peptide-oligonucleotide conjugates, as well as to the Ant peptide alone. Besides the expected reduction in MDR1 message level, 37 other genes (approximately 2% of those tested) showed changes of comparable magnitude. The validity of the array results was confirmed for selected genes using Northern blots to assess messenger RNA levels. These results suggest that studies using antisense oligonucleotide technology to modulate gene expression need to be interpreted with caution.