Introduction

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A modern strategy in pharmacology for interfering with receptor or channel proteins is to manipulate lifetime and translation efficacy of their coding mRNAs using antisense oligodeoxynucleotides (aODNs) (Wagner, 1995; Li et al., 1997; Branch, 1998). Such aODNs can be very specific because they exert their action by binding to a unique part (with a length of 12-20 bases) of their target mRNA. Their specificity lets them distinguish between closely related isoforms of RNAs (Hescheler, 1994; Brinkmeier et al., 1997) and even between wild-type and point-mutant RNAs (Duroux et al., 1995).

For an effective inhibition of protein translation in vivo or in cultured cells, the aODNs have to be protected against extracellular degradation, they must also be able to pass through the lipophilic plasma membrane, and finally they must be made to escape intracellular degradation and sequestration into organelles (Nakai et al., 1996; Crooke, 1998). Most importantly, when aODNs have reached their RNA, they must find access to their specific target site within the three-dimensional folding of this molecule (Branch, 1998).

Some of these tasks can now easily be solved, e.g., degradation is substantially slowed when phosphorothioate-protected ODNs are used instead of phosphodiester ODNs (Crooke, 1998). The accessibility of a specific target site in a given RNA can be tested in advance in vitro by means of binding assays or translation arrest assays (Schu and Brinkmeier, 1999). As for the specificity for closely related isoforms of voltage-gated Na⁺ channels, we have earlier developed highly specific 15-mer aODNs against the RNAs of the Na⁺ channels in human heart (hH1, Gellens et al., 1992) and skeletal muscle (hSkM1, Chahine et al., 1994). Using an in vitro assay and Xenopus oocytes as a cellular model, we showed that these aODNs are clearly able to discriminate between the two isoforms (Brinkmeier et al., 1997). The aim of the present study was to achieve uptake of these aODNs into intact cultured cells and to test whether they are able to selectively prevent translation of the respective RNAs.

	Materials and Methods

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Cells and Application of Oligonucleotides. Human myotubes expressing both the tetrodotoxin (TTX)-sensitive skeletal muscle-specific hSkM1 and the TTX-insensitive heart-specific hH1 Na⁺ channel (Ruppersberg and Rüdel, 1988; Yang et al., 1993; Kaspar et al., 1994) were cultivated from satellite cells isolated from muscle biopsies (Brinkmeier et al., 1993). Proliferation of myogenic stem cells was supported in a medium composed of a 1:1 (v/v) mixture of Ham's F-12 medium (Biochrom, Berlin, Germany) and Dulbecco's modified Eagle's medium (PAA Laboratories, Linz, Austria) with 5% fetal calf serum (FCS), 5% horse serum (both Life Technologies, Inc., Karlsruhe, Germany), and 2.5 mg/ml glucose, 0.3 mg/ml glutamine, and 1.2 g/l NaHCO₃. Two days after seeding, the serum content of the medium was reduced to 2% FCS and 2% horse serum, allowing the cells to differentiate into multinucleated myotubes within 2 weeks (Brinkmeier et al., 1993). HEK-293 cells stably expressing the -subunit of hSkM1 (Mitrovic et al., 1994) were used in ancillary experiments. The cells were grown in a medium composed of 90% minimum essential medium (MEM) and 10% FCS. To select for high expression of hSkM1 the medium contained in addition 800 µg/ml of the antibiotic geneticin (G418; Boehringer Mannheim, Mannheim, Germany).

Electrophysiology. Whole-cell Na⁺ currents were recorded at room temperature using an EPC-7 patch-clamp amplifier (List, Darmstadt, Germany). The standard external solution contained 140 mM NaCl, 3.5 mM KCl, 1.0 mM CaCl₂, 1.0 mM MgCl₂, and 2 mM HEPES, pH 7.4 (all ingredients from Merck, Darmstadt, Germany). The pipettes were filled with standard internal solution containing 140 mM CsCl, 1.4 mM MgCl₂, 10 mM EGTA, and 10 mM HEPES. Pipette resistances were 0.5 M for myotubes and 1 to 1.5 M for HEK-293 cells. Seal resistance, cell capacity, and access resistance were determined as described (Pröbstle et al., 1988; Hamm et al., 1996). The voltage error due to series resistance was estimated to be lower than 4 mV for all experiments.

Quantification of RNA Concentration. Myotube cultures were harvested by trypsin treatment, once washed with serum-free medium, centrifuged and the pellets stored at 70°C. RNAs were isolated with the RNeasy kit (Qiagen, Hilden, Germany), the integrity of the preparations checked by agarose gel electrophoresis, and the RNA concentration adjusted to 100 ng/ml for all samples. To quantify the concentrations of hH1 and hSkM1 mRNAs, 1 µl of each RNA solution was added to 19 µl of a one-tube RT-PCR master mix (Roche Molecular Biochemicals, Mannheim, Germany) containing 20 picomoles of upstream and downstream primers. The reverse transcription-polymerase chain reaction (RT-PCR) was then carried out in a real time PCR analysis system (Lightcycler; Roche Molecular Biochemicals) in the presence of the fluorescent indicator SYBER green (contained in the master mix). Two primers were used each for hH1 and hSkM1 RNA. For hH1 the oligonucleotide (from 5' to 3') GAG CAG CCT CAG TGG GAA TA served as upstream primer and GCC TGC TTG GTC ACA ATG T as downstream primer. The hSkM1 RNA primers were CGC TGG CTC AAT GTC A (upstream) and AGC CAA AGA TGA TGA AGA TG (downstream). As standards to quantify the mRNA levels, different dilutions of plasmid hSkM1 or hH1 cDNA were added to the master mix instead of RNA samples and amplified parallely. The Lightcycler system is a device to measure the raising concentration of double-stranded PCR products with a fluorimetric technique during a PCR. We used SYBER green as a fluorophore. To increase the specificity of the SYBER green-based detection we performed the measurements in an additional 81°C step (hH1) or at 84°C (hSkM1) during each amplification cycle.

	Results

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Uptake of the ODNs into Myotubes. In preliminary experiments we exposed myotubes to standard, phosphorothioate-capped, and completely phosphorothioate-modified aODNs (1 to 10 µM) or aODNs (1 µM) coupled to the carrier peptide penetratin (Brugidou et al., 1995) and investigated the amplitudes of the Na⁺ currents conducted by these cells. The results did not suggest that the aODNs inhibited RNA translation. Labeling of phosphorothioate-capped or completely phosphorothioate-modified aODNs with FITC showed that these aODNs were not incorporated into cells.

Effects of aODNs on Sodium Currents Conducted by Myotubes. Because myotubes regularly express both hH1 and hSkM1, we applied aODNs against either RNA to test for selective suppression of the translation of the RNA for either channel. Because hSkM1 is more sensitive to TTX than hH1, the simplest test was to compare the TTX sensitivities of the channels in treated and untreated cells.

View larger version (22K): [in this window] [in a new window]   Fig. 1.   A, suppression of hH1-conducted Na+ currents in myoballs treated with anti-hh1 ODN 4444asen (top) and absence of suppression of hSkM1-conducted Na+ currents in myoballs treated with anti-hSkM1 ODN 3866asen (bottom). Three days before current recordings, test cells had been incubated with phosphorothioate ODNs (5 µM) and cationic lipids (5 µl/ml), whereas control cells, tested in parallel, were incubated with cationic lipids only. The illustrated transient Na+ currents were all elicited by 8-ms square voltage pulses going from 85 mV for 100 ms to 135 mV and then to 21 mV, first with the cells in standard extracellular fluid, and then in extracellular fluid with 100 nM TTX added. For each of the four cells, the amplitudes of the currents in standard solution (ranging between 7 and 10 nA) were normalized to unity. Addition of the TTX-containing solution inhibits the current more than control in the case of blockade of hH1 RNA, indicating high efficacy of aODN 4444asen. Addition of TTX-containing solution inhibits the current less than control in the case of blockade of hSkM1 RNA, indicating low efficacy of aODN 3866asen. B, summary of results from similar experiments with a number of cells ascribed to each column in parentheses. Fraction of hH1-conducted current (±S.E.M.) of total Na+ current recorded from myoballs treated with anti-hH1 aODN 4444asen (left) and anti-hSkM1 aODN 3866asen (right). Plotted are the quotients of the maximum values of current-voltage relationships recorded in presence/absence of 100 nM TTX. ***, significantly different from control 2, P < .001, Mann-Whitney U test.

View larger version (26K): [in this window] [in a new window]   Fig. 2.   Suppression of hH1 currents (top) and absence of suppression of hSkM1 currents (bottom) demonstrated by the size of the shift of the h curve (voltage dependence of steady-state inactivation) of Na+ channels on addition of 100 nM TTX (see text). Myoballs treated with aODNs 4444asen (top left) or 3866asen (bottom left) in absence (filled symbols) or presence (open symbols) of TTX. Control cells incubated with liposomes only. The big left-shift seen in the presence of TTX with cells treated with aODN 4444asen indicates an effective suppression of the current conducted by hH1 channels. Same concentrations and incubation conditions as in Fig. 1.

Effects of aODNs on mRNA Levels of hH1 and hSkM1. To test whether the low efficacy of the anti-hSkM1 aODN 3866asen is also seen on the mRNA level, we determined mRNA concentrations of both hSkM1 and hH1 mRNAs in myotubes with a quantitative PCR technique. Myotube cultures having been treated with 4444asen for 3 days showed about a 60% decrease of hH1 RNA compared with control. A scrambled ODN and the 3866asen against hSkM1 showed, as expected, nearly no effects (Fig. 3A). In contrast, hSkM1 RNA was resistant against the application of its specific 3866asen oligonucleotide. Concentrations of messenger RNA coding for hSkM1 were all in the same range regardless of the applied ODN (Fig. 3B). To discriminate between two possible mechanisms, that of an early suppression followed by an up-regulation of hSkM1 during days 2 and 3 and that of a compete lack of inhibition we quantified the hSkM1 mRNA after 24 h (instead of 3 days) after treatment with 3866asen. Also at that time the aODN had no influence on the hSkM1 mRNA level (data not shown).

View larger version (33K): [in this window] [in a new window]   Fig. 3.   Messenger RNA levels of hH1 (A) and hSkM1 (B) isolated from myotubes after a 3 days treatment with the hH1 antisense oligonucleotide 4444asen, hSkM1 antisense oligonucleotide 3866asen, or scrambled oligonucleotide. RNA concentrations were determined using a series of dilutions of plasmid DNA and normalized to control (cells without treatment). Mean values ± S.D. given from three independent experiments (A) and two experiments (B), respectively.

Effects of aODN 3866asen on Sodium Currents in HEK-293 Cells. Because aODN 3866asen had been very effective in vitro, we decided to test its efficacy in another cell system, i.e., HEK-293 cells stably expressing the -subunit of hSkM1. As with myotubes, also with HEK cells we found substantial uptake of FITC-labeled aODNs when the latter had been mixed with liposomes. In contrast to the results with myotubes, we found in all tested cell cultures only 30 to 40% of the cells fluorescent. As with myotubes, the fluorescence remained stable for at least 3 days in the cells that had taken up the aODNs. As another difference to the observations with the myotubes where the fluorescence was mainly contained in the nuclei, in the HEK cells it was more or less homogeneously distributed in nuclei and cytoplasm.

View larger version (35K): [in this window] [in a new window]   Fig. 4.   Na+ currents recorded from HEK-293 cells expressing hSkM1 that had been incubated with 5 µM aODN 3866asen. Controls from cells treated with liposomes only. A and B, original recordings of families of Na+ currents elicited by square voltage pulses from 85 to 135 mV and then to various test potentials between 73 and +31 mV. Smaller amplitudes of currents conducted by cells treated with the 3866asen aODN indicate efficacy of this oligo in HEK cells. C, summarized results of experiments as shown in A and B. The maximum values attained in current-voltage curves for cells treated with antisense (asen) or sense (sen) aODNs are compared with maximum values seen in controls treated with liposomes only. Cells showing bright fluorescence during microscopic inspection (columns 2 and 3) were selected for recordings: asen: aODN 3866asen (5 µM); sen: corresponding 3866sen ODN (5 µM). Another group of cells from the same culture showing no or little fluorescence was studied accordingly (columns 4 and 5). Means ± S.E.M. Number of tested cells given in parentheses. *, difference significant compared with groups (from left to right) 1, 3, and 4; P < .05, Kruskall-Wallis nonparametric ANOVA test.

View larger version (13K): [in this window] [in a new window]   Fig. 5.   Absence of influence of incorporation of aODN 3866asen on the gating characteristics of HEK-293 cells. Voltage dependence of inactivation (A) and activation (B) of Na+ channels in cells that were incubated with the oligo () or with solution containing liposomes only (). The same concentrations and incubation conditions were used as described in Fig. 1. Boltzmann curves (continuous lines) were fitted to each set of data points.

	Discussion

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The positive result of this study is that specific aODNs can be incorporated into human muscle cells. The negative result is that one of our aONDs tested was not effective even when clearly taken up by the cells. For unknown reasons, the anti-hSkM1 aODN that can effectively prevent RNA translation, as shown previously in vitro (Brinkmeier et al., 1997) and now also in cultured HEK-293 cells, did not seem to be effective in myotubes. We conclude from this latter finding that cellular uptake of aODNs and intracellular access to the RNA target are necessary, but not always sufficient conditions for an effective block of RNA translation in intact cells.

The question of cellular uptake is still of particular concern in the use of antisense oligonucleotides. Only in a few experimental settings without special delivery system did aODNs reach intracellular concentrations that were sufficient for a specific block of translation (Melone et al., 1998). With our two human cell systems, i.e., primary muscle cells and HEK cells, the difficult barrier of the plasma membrane was only overcome when the aODNs were coincubated with cationic lipids (Bennett et al., 1992). Visible fluorescence then indicated that the intracellular aODN concentration was sufficient. Nonfluorescent cells, when tested with simple current measurements did not show an antisense effect. For our cell and delivery systems, fluorescence-labeled aODNs resulted in homogeneous nuclear and cytoplasmic staining. This is in agreement with recent observations made with monocytes and lymphocytes using the cationic lipid-mediated uptake technique (Hartmann et al., 1998). Fortunately, we did not observe signs of cytotoxicity, such as formation of intracellular granules, surface blebs, or detachment of cells as a consequence of the use of our phosphorothioate-protected aODNs.

Studies on the kinetics of aODN uptake and efflux have given evidence for a high initial uptake during the first hours followed by a slower uptake process (24 h and after), the latter giving way to a dynamic balance of efflux and influx (Li et al., 1997). A high initial uptake rate might explain why we found 5 h of exposure time enough for sufficient uptake yield with both cell systems. Our observation of a fluorescence remaining fairly constant for 3 to 4 days can be explained by a long half-time for the aODN efflux (4-5 days according to Li et al., 1997).

The anti-hSkM1 aODN 3688asen was shown to have good access to its RNA target sequence because it was very effective in translation arrest assays and after coinjection with RNAs into X. laevis oocytes (Brinkmeier et al., 1997). The expectation that an aODN, once it was taken up by a myotube as demonstrated by fluorescence, would block RNA translation was not fulfilled. Several mechanisms may be involved. In myotubes, hSkM1 could be more stable than hH1 and it could be more stable in myotubes than in HEK-293 cells (Spiller et al., 1998). For the TTX-sensitive Na⁺ channel in rat myotubes, however, a half-life of 18 h was determined (Sherman et al., 1985). A similar half-life for hSkM1 in human myotubes would be short enough for a marked antisense effect under our experimental conditions. A second possible mechanism, the compensatory up-regulation due to post-transcriptional feedback mechanisms (Rothenberger et al., 1990; Mosner et al., 1995), which has been shown to exist for the skeletal muscle chloride channel (Chen et al., 1997), is also unlikely because we have shown a normal hSkM1 RNA concentration at days 1 and 3 in the presence of the oligonucleotide. A third possibility seems to be the most likely, a structural difference between the natural mRNA and the coinjected and transfected cRNA. The structures of such huge RNAs (6.5 to 7.5 kb) are difficult to predict or determine (for a review of RNA structure and structural transitions, see Klaff et al., 1996). Considering the current knowledge of aODN action, our finding that hSkM1 mRNA is stable in myotubes is best explained by a poor access of 3866asen ODN to its mRNA target sequence. Thus, in spite of its good access to the hSkM1 cRNA in vitro, in X. laevis oocytes (Brinkmeier et al., 1997), and HEK-293 cells the OND 3866asen is probably prevented by an unknown mechanism from reaching its mRNA target sequence in myotubes, or else it cannot fulfill its degradative antisense action.