Nuclear antisense effects in cyclophilin A pre‐mRNA splicing by oligonucleotides: a comparison of tricyclo‐DNA with LNA
Identifieur interne : 001553 ( Istex/Corpus ); précédent : 001552; suivant : 001554Nuclear antisense effects in cyclophilin A pre‐mRNA splicing by oligonucleotides: a comparison of tricyclo‐DNA with LNA
Auteurs : Damian Ittig ; Songkai Liu ; Dorte Renneberg ; Daniel Schu Mperli ; Christian J. LeumannSource :
- Nucleic Acids Research [ 0305-1048 ] ; 2004.
English descriptors
- Teeft :
- Analogue, Antisense, Antisense activity, Antisense effect, Antisense effects, Antisense oligonucleotides, Antisense response, Assay, Backbone systems, Cellular, Cellular distribution, Cellular uptake, Chem, Cyclophilin, Cypa, Cypa mrna, Cypa protein, Dystrophin, Exon, Full length, Hela, Hela cells, Human virus type, Lipofectamine, Lna6, Mmol scale, Mrna, Natl acad, Nuclear antisense effects, Nucleic, Nucleic acids, Nucleic acids research, Oligonucleotide, Oligonucleotide analogues, Oligonucleotides, Splice, Splice sites, Thermal stability, Transfection, Untreated cells, Uorescence, Uorescence microscopy, Western blot.
Abstract
The nuclear antisense properties of a series of tricyclo (tc)‐DNA oligonucleotide 9–15mers, targeted against the 3′ and 5′ splice sites of exon 4 of cyclophilin A (CyPA) pre‐mRNA, were evaluated in HeLa cells and compared with those of corresponding LNA‐oligonucleotides. While the 9mers showed no significant antisense effect, the 11–15mers induced exon 4 skipping and exon 3+4 double skipping to about an equal extent upon lipofectamine mediated transfection in a sequence‐ and dose‐dependent manner, as revealed by a RT–PCR assay. The antisense efficacy of the tc‐oligonucleotides was found to be superior to that of the LNA‐oligonucleotides in all cases by a factor of at least 4–5. A tc‐oligonucleotide 15mer completely abolished CyPA mRNA production at 0.2 µM concentration. The antisense effect was confirmed by western blot analysis which revealed a reduction in CyPA protein to 13% of its normal level. Fluorescence microscopic investigations with a fluorescein labeled tc‐15mer revealed a strong propensity for homogeneous nuclear localization of this backbone type after lipofectamine mediated transfection, while the corresponding lna 15mer showed a less clear cellular distribution pattern. Transfection without lipid carrier showed no significant internalization of both tc‐ and LNA‐ oligonucleotides. The obtained results confirm the power of tc‐DNA for nuclear antisense applications. Moreover, CyPA may become an interesting therapeutic target due to its important role in the early steps of the viral replication of HIV‐1.
Url:
DOI: 10.1093/nar/gkh187
Links to Exploration step
ISTEX:E5ADDCE4666F92C864509019B007891E86B667FCLe document en format XML
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Leumann</name><affiliation><mods:affiliation>*To whom correspondence should be addressed. Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: leumann@ioc.unibe.ch The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors</mods:affiliation></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Nucleic Acids Research</title><title level="j" type="abbrev">Nucl. 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While the 9mers showed no significant antisense effect, the 11–15mers induced exon 4 skipping and exon 3+4 double skipping to about an equal extent upon lipofectamine mediated transfection in a sequence‐ and dose‐dependent manner, as revealed by a RT–PCR assay. The antisense efficacy of the tc‐oligonucleotides was found to be superior to that of the LNA‐oligonucleotides in all cases by a factor of at least 4–5. A tc‐oligonucleotide 15mer completely abolished CyPA mRNA production at 0.2 µM concentration. The antisense effect was confirmed by western blot analysis which revealed a reduction in CyPA protein to 13% of its normal level. Fluorescence microscopic investigations with a fluorescein labeled tc‐15mer revealed a strong propensity for homogeneous nuclear localization of this backbone type after lipofectamine mediated transfection, while the corresponding lna 15mer showed a less clear cellular distribution pattern. Transfection without lipid carrier showed no significant internalization of both tc‐ and LNA‐ oligonucleotides. The obtained results confirm the power of tc‐DNA for nuclear antisense applications. 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Leumann</name><affiliations><json:string>*To whom correspondence should be addressed. Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: leumann@ioc.unibe.ch The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors</json:string></affiliations></json:item></author><arkIstex>ark:/67375/HXZ-JMM7R2KH-9</arkIstex><language><json:string>eng</json:string></language><originalGenre><json:string>research-article</json:string></originalGenre><abstract>The nuclear antisense properties of a series of tricyclo (tc)‐DNA oligonucleotide 9–15mers, targeted against the 3′ and 5′ splice sites of exon 4 of cyclophilin A (CyPA) pre‐mRNA, were evaluated in HeLa cells and compared with those of corresponding LNA‐oligonucleotides. While the 9mers showed no significant antisense effect, the 11–15mers induced exon 4 skipping and exon 3+4 double skipping to about an equal extent upon lipofectamine mediated transfection in a sequence‐ and dose‐dependent manner, as revealed by a RT–PCR assay. The antisense efficacy of the tc‐oligonucleotides was found to be superior to that of the LNA‐oligonucleotides in all cases by a factor of at least 4–5. A tc‐oligonucleotide 15mer completely abolished CyPA mRNA production at 0.2 µM concentration. The antisense effect was confirmed by western blot analysis which revealed a reduction in CyPA protein to 13% of its normal level. Fluorescence microscopic investigations with a fluorescein labeled tc‐15mer revealed a strong propensity for homogeneous nuclear localization of this backbone type after lipofectamine mediated transfection, while the corresponding lna 15mer showed a less clear cellular distribution pattern. Transfection without lipid carrier showed no significant internalization of both tc‐ and LNA‐ oligonucleotides. The obtained results confirm the power of tc‐DNA for nuclear antisense applications. 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Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: leumann@ioc.unibe.ch
The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors</affiliation></author><idno type="istex">E5ADDCE4666F92C864509019B007891E86B667FC</idno><idno type="ark">ark:/67375/HXZ-JMM7R2KH-9</idno><idno type="other">gkh187</idno><idno type="DOI">10.1093/nar/gkh187</idno></analytic><monogr><title level="j" type="main">Nucleic Acids Research</title><title level="j" type="abbrev">Nucl. Acids Res.</title><idno type="hwp">nar</idno><idno type="nlm-ta">Nucleic Acids Res</idno><idno type="publisher-id">nar</idno><idno type="pISSN">0305-1048</idno><idno type="eISSN">1362-4962</idno><imprint><publisher>Oxford University Press</publisher><date type="published">2004</date><biblScope unit="vol">32</biblScope><biblScope unit="issue">1</biblScope><biblScope unit="page" from="346">346</biblScope><biblScope unit="page" to="353">353</biblScope></imprint></monogr></biblStruct></sourceDesc></fileDesc><encodingDesc><schemaRef type="ODD" url="https://xml-schema.delivery.istex.fr/tei-istex.odd"></schemaRef><appInfo><application ident="pub2tei" version="1.0.41" when="2020-04-06"><label>pub2TEI-ISTEX</label><desc>A set of style sheets for converting XML documents encoded in various scientific publisher formats into a common TEI format.
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<article-title>Nuclear antisense effects in cyclophilin A pre‐mRNA splicing by oligonucleotides: a comparison of tricyclo‐DNA with LNA</article-title>
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<contrib-group>
<contrib contrib-type="author">
<name>
<surname>Ittig</surname>
<given-names>Damian</given-names>
</name>
</contrib>
<contrib contrib-type="author">
<name>
<surname>Liu</surname>
<given-names>Songkai</given-names>
</name>
<xref rid="GKH187A1">1</xref>
</contrib>
<contrib contrib-type="author">
<name>
<surname>Renneberg</surname>
<given-names>Dorte</given-names>
</name>
</contrib>
<contrib contrib-type="author">
<name>
<surname>Schümperli</surname>
<given-names>Daniel</given-names>
</name>
<xref rid="GKH187A1">1</xref>
</contrib>
<contrib contrib-type="author">
<name>
<surname>Leumann</surname>
<given-names>Christian J.</given-names>
</name>
<xref rid="COR1">*</xref>
</contrib>
<aff>Department of Chemistry and Biochemistry, University of Berne, Freiestrasse 3, CH‐3012 Berne and</aff>
<aff id="GKH187A1"><label>1</label>Institute of Cell Biology, University of Berne, Baltzerstrasse 4, CH‐3012 Berne, Switzerland</aff>
</contrib-group>
<author-notes>
<corresp id="COR1">*To whom correspondence should be addressed. Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: <ext-link xlink:href="leumann@ioc.unibe.ch" ext-link-type="email">leumann@ioc.unibe.ch</ext-link>
The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors</corresp>
</author-notes>
<pub-date pub-type="ppub">
<day>16</day>
<month>01</month>
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<issue>1</issue>
<fpage>346</fpage>
<lpage>353</lpage>
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<copyright-year>2004</copyright-year>
</permissions>
<abstract xml:lang="en">
<p>The nuclear antisense properties of a series of tricyclo (tc)‐DNA oligonucleotide 9–15mers, targeted against the 3′ and 5′ splice sites of exon 4 of cyclophilin A (CyPA) pre‐mRNA, were evaluated in HeLa cells and compared with those of corresponding LNA‐oligonucleotides. While the 9mers showed no significant antisense effect, the 11–15mers induced exon 4 skipping and exon 3+4 double skipping to about an equal extent upon lipofectamine mediated transfection in a sequence‐ and dose‐dependent manner, as revealed by a RT–PCR assay. The antisense efficacy of the tc‐oligonucleotides was found to be superior to that of the LNA‐oligonucleotides in all cases by a factor of at least 4–5. A tc‐oligonucleotide 15mer completely abolished CyPA mRNA production at 0.2 µM concentration. The antisense effect was confirmed by western blot analysis which revealed a reduction in CyPA protein to 13% of its normal level. Fluorescence microscopic investigations with a fluorescein labeled tc‐15mer revealed a strong propensity for homogeneous nuclear localization of this backbone type after lipofectamine mediated transfection, while the corresponding lna 15mer showed a less clear cellular distribution pattern. Transfection without lipid carrier showed no significant internalization of both tc‐ and LNA‐ oligonucleotides. The obtained results confirm the power of tc‐DNA for nuclear antisense applications. Moreover, CyPA may become an interesting therapeutic target due to its important role in the early steps of the viral replication of HIV‐1.</p>
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<p content-type="arthw-misc">Received October 9, 2003; Revised and Accepted December 3, 2003</p>
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</front>
<body>
<sec>
<title>INTRODUCTION</title>
<p>Antisense oligonucleotides that are stable against nucleolytic degradation and that do not induce RNase H catalyzed hydrolysis of complementary mRNA were shown to be powerful modulators of pre‐mRNA splicing <italic>in vitro</italic> and <italic>in vivo</italic> (<xref rid="GKH187C1">1</xref>,<xref rid="GKH187C2">2</xref>). Such oligonucleotides have successfully been used in the past to shift pre‐mRNA splicing of CFTR (<xref rid="GKH187C3">3</xref>), IL‐5R (<xref rid="GKH187C4">4</xref>), c‐myc (<xref rid="GKH187C5">5</xref>), tau (<xref rid="GKH187C6">6</xref>), SMN‐2 (<xref rid="GKH187C7">7</xref>), bcl‐x (<xref rid="GKH187C8">8</xref>–<xref rid="GKH187C10">10</xref>), β‐globin (<xref rid="GKH187C11">11</xref>,<xref rid="GKH187C12">12</xref>) and dystrophin (<xref rid="GKH187C13">13</xref>–<xref rid="GKH187C15">15</xref>). Amongst the oligonucleotide analogues most intensively investigated for splice shifting are the anionic analogues 2′‐OMe‐RNA and 2′‐methoxyethyl (MOE)‐RNA, as well as the charge neutral analogues morpholino‐DNA and PNA. A direct comparison of the four different backbone types has recently been performed in a <italic>in vitro</italic> assay in which the modified oligonucleotides blocked aberrant and restored correct splicing of modified enhanced green fluorescent protein (EGFP) pre‐mRNA (<xref rid="GKH187C16">16</xref>). It was found that free uptake and the antisense efficacy of neutral morpholino derivatives and of PNA carrying 4 C‐terminal lysine residues were significantly higher than that of the negatively charged 2′‐O‐alkyl RNAs. Interestingly, the same assay in a transgenic mouse model showed inverted results with the 2′‐O‐MOE oligonucleotides showing much higher activity than the lysine modified PNA or morpholino‐oligonucleotides.</p>
<p>High potential in terms of antisense properties is given to the class of conformationally constrained oligonucleotide analogues such as for example LNA (<xref rid="GKH187C17">17</xref>,<xref rid="GKH187C18">18</xref>) or tricyclo (tc)‐DNA (<xref rid="GKH187C19">19</xref>) (Fig. <xref rid="GKH187F1">1</xref>), which show significantly enhanced target binding properties and enhanced biological stability. In the case of LNA, efficient antisense activity was reported for a G‐protein coupled receptor in rat brain (<xref rid="GKH187C20">20</xref>), HIV‐1 TAR (<xref rid="GKH187C21">21</xref>), VR1 (<xref rid="GKH187C22">22</xref>,<xref rid="GKH187C23">23</xref>) and human telomerase (<xref rid="GKH187C24">24</xref>). Given the fact that both backbone systems do not mediate RNaseH activity, they seem particularly well suited for nuclear antisense applications. We recently investigated tc‐DNA for correction of aberrant β‐globin splicing in a cellular assay and found a 100‐fold increased antisense activity relative to 2′OMe‐PS‐RNA (<xref rid="GKH187C25">25</xref>). In order to compare the nuclear antisense properties of the two backbone systems we set out to study their performance side by side in a cyclophilin A (CyPA) splice assay.</p>
<p>We chose CyPA because of recent data, suggesting it to be a target for the inhibition of HIV‐1 replication. CyPA is a proline <italic>cis</italic>–<italic>trans</italic> isomerase that was initially discovered as the cellular ligand of the immunosuppressive drug cyclosporin A (CsA) (<xref rid="GKH187C26">26</xref>). Although CyPA has been implicated in diverse functions such as for example in the heat‐shock response (<xref rid="GKH187C27">27</xref>), in the nuclear import of some proteins (<xref rid="GKH187C28">28</xref>), and in various signal transduction pathways (<xref rid="GKH187C29">29</xref>,<xref rid="GKH187C30">30</xref>), its exact function is still not yet fully understood. Surprisingly, it was shown that CyPA was specifically incorporated into HIV‐1 virions and was required to maintain efficient viral replication (<xref rid="GKH187C31">31</xref>–<xref rid="GKH187C34">34</xref>). Virions lacking CyPA show normal morphologies, package normal levels of viral proteins and RNAs, and exhibit normal reverse transcriptase activity (<xref rid="GKH187C31">31</xref>,<xref rid="GKH187C35">35</xref>). However, the viral replication is blocked at some step after viral entry but before the reverse transcription starts (<xref rid="GKH187C31">31</xref>). More recently, it was shown that CyPA might also function at the viral entry step of HIV‐1 infection (<xref rid="GKH187C36">36</xref>,<xref rid="GKH187C37">37</xref>). Taken together, these observations imply that CyPA not only participates in post‐entry events, but also contributes to the early events of HIV‐1 replication (<xref rid="GKH187C36">36</xref>–<xref rid="GKH187C38">38</xref>).</p>
<p>We found that tc‐oligonucleotides, 11–15 nt in length, targeted to the 3′‐splice site of exon 4 of the CyPA pre‐mRNA efficiently redirect splicing by skipping exon 3 and 4 simultaneously in a dose‐dependent manner. Down‐regulation of CyPA was confirmed by western blot analysis. In the given assay, tc‐DNA outperformed LNA in antisense efficacy. Intracellular distribution of a 3′‐fluorescein labeled tc‐oligonucleotide 15mer in HeLa cells after lipofection revealed selective accumulation of the oligonucleotide in the nucleus which might be a reason for the observed strong nuclear antisense effect.</p>
</sec>
<sec>
<title>MATERIALS AND METHODS</title>
<sec>
<title>Synthesis and purification of oligonucleotides</title>
<p>Tc‐oligonucleotides (Table <xref rid="GKH187TB1">1</xref>) were prepared on the 0.2 and 1.3 µmol scale on a PerSeptive Biosystems Expedite or on a Pharmacia Gene Assembler Special™ DNA‐synthesizer using the modified phosphoramidite chemistry procedure as reported previously (<xref rid="GKH187C19">19</xref>). The oligomers tc1 and tc2 were synthesized on universal solid support (GlenResearch). The oligomers tc3–tc5 were assembled on a universal solid support (CT‐Gen, San Jose, CA). The 3′‐fluorescein‐labeled oligomer tc6 was synthesized on the 1.3 µmol scale using LC fluorescein CPG (Roche Diagnostics). All tc‐oligomers were synthesized with an additional nucleotide unit at its 5′ end which is cleaved during deprotection, resulting in a 5′‐terminal phosphate group (<xref rid="GKH187C39">39</xref>). The coupling time was set to 10 min, and 5‐(ethylthio)‐1<italic>H</italic>‐tetrazole (0.25 M in CH<sub>3</sub>CN) was used as activator. Coupling yields were >95% per step. Deprotection and cleavage from the solid support were performed under standard conditions (conc. NH<sub>3</sub>, 16–60 h, 55–65°C). The molecular compositions of all oligonucleotides were determined by ESI<sup>–</sup> mass spectrometry (Table <xref rid="GKH187TB1">1</xref>). The experimental masses of tc1 and tc2 showed the presence of a 3′‐terminal 2,5‐dimethoxytetrahydrofuran‐3,4‐diol unit arising from the universal solid support. Oligonucleotide tc‐NS had already been synthesized before and was used in the present study as a nonsense‐sequence (<xref rid="GKH187C25">25</xref>). LNA phosphoramidites with the bases adenine, thymine, guanine and 5‐methylcytosine were purchased from Exiqon. The LNA oligonucleotides were prepared on the 1.3 µmol scale on a Pharmacia Gene Assembler Special™ DNA‐synthesizer according to the manufacturer’s protocol on either universal solid support from CT‐Gen (lna1–lna5) or on LC fluorescein CPG (lna6). Crude oligonucleotides were purified by DEAE ion exchange HPLC and/or reversed phase HPLC. Oligonucleotide tc6 was prepurified by gel filtration over Sephadex G‐25 and then purified by reversed phase HPLC. Also in these cases the compositions of the oligonucleotides were confirmed by ESI‐MS (Table <xref rid="GKH187TB1">1</xref>).</p>
</sec>
<sec>
<title>Cell culture, transfection and analysis</title>
<p>HeLa cells were grown in Dulbecco’s modified Eagle’s medium supplemented with 10% fetal calf serum, 100 U/ml penicillin and 100 µg/ml streptomycin at 37°C in an incubator containing 5% CO<sub>2</sub>. For transfection, 2.5 × 10<sup>5</sup> HeLa cells were seeded in a six‐well plate. After 12 h, 0.05, 0.1 or 0.2 µM of oligonucleotides (final concentration in 1 ml of transfection solution) were complexed with 1.5, 3 or 6 µl LipofectAMINE (Invitrogen/Life Technologies), respectively in 0.2 ml of OptiMEM (Invitrogen/Life Technologies) at room temperature for 30 min. Then the complex was diluted with OptiMEM to a final volume of 1 ml and added to the cells for further incubation. The medium was replaced by normal growth medium after 5 h.</p>
<p>TRI‐Reagent Kit (MRC, Cincinnati, OH) was used for total RNA isolation, and the RNA was usually isolated 48 h after transfection. To detect CyPA mRNA, 250 ng of total RNA was analyzed by RT–PCR using rTth DNA polymerase (Applied Biosystems) in a final volume of 50 µl with forward and reverse primers corresponding to the sequences of exon 1 and exon 5, respectively. CyPA 5′‐primer: (1671–1690, CyPA exon 1): 5′‐CACCGTGTTCTTCGACATTG; 3′‐primer: (6260–6279, CyPA exon 5), 5′‐CCATGGCCTCCACAA TATTC. The reverse transcribed CyPA mRNA was amplified with <sup>32</sup>P‐labeled dCTP for 31 cycles (94°C for 1 min, 60°C for 1 min, 72°C for 10 min). The RT–PCR products were separated on 6% non‐denaturing polyacrylamide gels. Dried gels were exposed to storage phosphor screens (Molecular Dynamics) and visualized with the AIDA program (version 2.31, Raytest Isotopenmessgeräte GmbH, Straubenhardt, Germany). Data were analyzed using ImageQuant software (version 3.3).</p>
</sec>
<sec>
<title>Western blot</title>
<p>HeLa cells were transfected with oligonucleotide tc4. After 72 h, the cells were lysed in SDS sample buffer and separated by 12% SDS–PAGE. The gel was transferred to a nitrocellulose membrane overnight. Polyclonal rabbit anti‐human CyPA‐ (1:1000, gift from Dr Uta Vonschwedler, University of Utah) or anti‐actin‐ (Sigma, 1:500) antibodies were used as the first antibodies, and anti‐rabbit horseradish peroxidase‐linked antibody (Promega, 1:2500) as the secondary antibody. Detection was carried out using the ECL chemiluminescence technique (Amersham Pharmacia) and the blot was exposed to an AGFA X‐ray film. The protein level was quantified with ImageQuant software (version 3.3). The signals were corrected to the actin loading level.</p>
</sec>
<sec>
<title>Cellular uptake and microscopy</title>
<p>HeLa cells were cultured and transfected with 0.2 µM (final concentration) of fluorescein labeled oligonucleotide tc6 or lna6, complexed with 6 µl lipofectAMINE as described before, and analyzed after 24 h by fluorescence microscopy (Leica Microsystems, Leica TCS SP2; microscope: Leica DM IRE2). For transfection without lipofectamine, HeLa cells were cultured and treated with a 20 µM solution of tc6 or lna6 in DMEM+/+ medium at 37°C for 24 h. The cells were then washed twice with PBS solution, and fresh DMEM+/+ was added. The living cells were first analyzed by fluorescence microscopy and then counted with a fluorescence activated cell sorter (FACS).</p>
</sec>
</sec>
<sec>
<title>Results</title>
<sec>
<title>Design of oligonucleotides and general splicing pattern</title>
<p>We decided to investigate the modification of CyPA pre‐mRNA splicing patterns in HeLa cell cultures using oligonucleotides that were targeted to the 3′‐ or 5′‐splice sites of exon 4 (Table <xref rid="GKH187TB1">1</xref>).</p>
<p>More precisely, sequences complementary to the 5′‐splice site between exon 4 and intron 4 were used to compare the efficacy, minimal length requirements and mismatch sensitivity of tc‐ and LNA‐oligonucleotides (tc1–5 and lna1–5). The 3′‐splice site between intron 3 and exon 4 was the target of tc6 and lna6 which were 3′‐fluorescein (FAM) labeled. This sequence was primarily used to follow cellular uptake and distribution. In all cases, we observed a general splicing pattern in which skipping of exon 4 and double skipping of exons 3+4 occurred on the mRNA level. A schematic representation of the redirection of CyPA pre‐mRNA splicing in the presence of antisense oligonucleotides is given in Figure <xref rid="GKH187F2">2</xref>.</p>
</sec>
<sec>
<title>Thermal stability of tc‐ and LNA oligonucleotides with complementary RNA</title>
<p>Thermal stabilities of duplexes with the RNA 17mer representing the 5′‐splice site of CyPA pre‐mRNA were assessed by UV‐melting curve analysis, and the corresponding <italic>T</italic><sub>m</sub>s are listed in Table <xref rid="GKH187TB1">1</xref>. The <italic>T</italic><sub>m</sub>s of tc1–4 range from 56 to 83°C. The mismatched 15mer tc5 shows a decrease in thermal stability relative to the matched 15mer tc4 by 23°C. Its thermal stability is thus between that of the matched 9‐ and 11mer (tc1 and tc2). The corresponding oligonucleotides with the LNA backbone bind significantly more efficiently to the corresponding RNA target. While lna1 shows a <italic>T</italic><sub>m</sub> of 82.6°C, that of lna2 was already at 95°C. For lna3 and lna4, no sigmoidal melting curves could be observed indicating even higher <italic>T</italic><sub>m</sub>s. The mismatched 15mer lna5 showed a <italic>T</italic><sub>m</sub> of 92°C which lies in between that of the 9mer lna1 and 11mer lna2, as in the case of tc‐DNA. Thus LNA binds RNA with comparable selectivity but overall higher affinity by ca. 2.5–3.0°C/per mod. relative to tc‐DNA. Whether the increase in affinity of LNA is entirely due to the backbone or arises in part by the base 5‐methylcytosine used instead of cytosine remains open.</p>
</sec>
<sec>
<title>Antisense activity of tc‐oligonucleotides</title>
<p>HeLa cells were transfected with three different concentrations (0.05, 0.1 and 0.2 µM) of oligonucleotides tc1–5. After 48 h total RNA was isolated, amplified by RT–PCR, and the products separated by PAGE (Fig. <xref rid="GKH187F3">3</xref>). To obtain quantitative data, we determined the residual full‐length CyPA mRNA as a fraction of total RNA (full length + exon skipped RNA) by phosphor imaging (Fig. <xref rid="GKH187F4">4</xref>).</p>
<p>With the exception of tc1 (9mer), all oligonucleotides led to a significant amount of exon 4 skipping and exon 3+4 double skipping. The degree of splice shifting increased with increasing length and increasing dose of the antisense oligonucleotides. At the lowest (50 nM) concentration investigated, essentially no antisense effect was observed for tc2 (11mer) while a reduction in full length RNA by ca. 10% occurs for tc3 (13mer) and tc4 (15mer). At 0.1 µM concentration of tc2, tc3 and tc4, full length RNA is reduced to 70%, 43% and 25%, respectively, relative to the control without oligonucleotide. At 0.2 µM concentration, the level of full length RNA was below 20% for tc2 and 3, and was essentially undetectable in the case of tc4, indicating quantitative splice shifting in the corresponding pre‐mRNA. In all cases, the bands corresponding to mRNA in which only exon 4 was skipped were slightly more intense than that of exon 3+4 double skipping.</p>
<p>Sequence specificity in the antisense response was investigated with oligonucleotide tc5, showing the same length as tc4 but two mismatches in the center of the sequence. In this case, we observed a reduction in full length RNA (Fig. <xref rid="GKH187F4">4</xref>) by 28% only at high (0.2 µM) concentration. Thus its antisense activity lies between those of the matched 9‐ and 11mers and is far inferior to that of the fully matched 15mer tc4. An additional control with the non‐sequence related oligonucleotide tcNS showed no exon skipping at all by RT–PCR over the same concentration range (data not shown).</p>
<p>From these results, we conclude that the observed change in the splice pattern of CyPA pre‐mRNA is due to a true antisense effect of the oligonucleotide analogues. Furthermore, a sequence length of 9 is insufficient for eliciting significant antisense effects in the submicromolar range while with 15, complete reorientation of splicing is achieved at 0.2 µM concentration.</p>
<p>The fluorescein labeled oligonucleotide tc5 targeted to the 3′ splice site displayed an antisense activity comparable to the oligonucleotides directed to the 5′‐splice site, displaying the same single and double skipping pattern of exons 3 and 4. We found that tc6 reduced the full‐length CyPA mRNA by 98% at 0.2 µM concentration (Fig. <xref rid="GKH187F4">4</xref>).</p>
</sec>
<sec>
<title>Antisense activity of LNA‐oligonucleotides</title>
<p>In order to compare the antisense efficacy of tc‐DNA with that of LNA, the same experiments were repeated with the LNA‐oligonucleotides lna1–4. A representative gel of the RT–PCR products is given in Figure <xref rid="GKH187F5">5</xref>, and the corresponding data for residual full‐length CyPA mRNA were determined as before (Fig. <xref rid="GKH187F6">6</xref>).</p>
<p>As in the case of tc‐DNA, exon 3 skipping and exon 3+4 double skipping to about equal ratios was observed with lna3 and lna4 while no effect occurred with lna1 (9mer). Also here nuclear antisense effects increased with increasing dose and length of the oligonucleotides. However, full‐length RNA was only reduced to 69% with lna2 (11mer) at 0.2 µM concentration. This indicates roughly a 5‐fold less efficient splice shifting compared to tc2. Interestingly, even with lna3 and lna4 at 0.2 µM, 44 and 43%, respectively, of full length RNA was still observed. This contrasts with the efficacy of the tricyclo‐backbone which reduced the amount of full‐length RNA to 11 and 0%, respectively. Furthermore, no increase in nuclear antisense activity was observed between the 13mer and 15mer LNA at 0.2 µM which indicated that the optimum length/activity relation is already met at the level of a 13mer.</p>
<p>As in the case of tc‐DNA, the selectivity of the antisense response was investigated with the double mismatch sequence lna5. With this oligonucleotide a full‐length RNA production of 88% relative to untreated controls was observed. Also here, the antisense activity is not only dose‐ but also sequence‐dependent and reminiscent of a true antisense effect.</p>
<p>We also tested the fluorescently labeled oligonucleotide lna6 for antisense activity. As with tc6, lna6 also showed antisense activity with single and double exon skipping, but again with less efficiency (64% remaining full‐length RNA) as compared to tc6. Thus in the cases investigated here, tricyclo‐oligonucleotides show stronger nuclear antisense effects than corresponding lna‐oligonucleotides by at least a factor of 4–5 although the overall affinity of tc‐DNA to an RNA target is inferior to that of LNA.</p>
</sec>
<sec>
<title>Western blot</title>
<p>To ensure that exon skipping induced by tc‐oligonucleotides also led to a reduced CyPA protein level, a western blot was performed. To this end, HeLa cells were transfected with tc4 (15mer) and left for 72 h before blotting. As can be seen from Figure <xref rid="GKH187F7">7</xref>, CyPA protein is down‐regulated in a concentration‐dependent manner. β‐Actin was analyzed as a loading control. At 0.1 µM concentration of tc4, only 45% of the normal CyPA level was produced while at 0.2 µM, expression was reduced to 13%. This experiment lends further evidence for tc‐DNA acting as specific and potent nuclear antisense oligonucleotides.</p>
</sec>
<sec>
<title>Cellular uptake and distribution</title>
<p>Given the surprisingly strong nuclear antisense effects, it was of interest to follow the cellular uptake and distribution of the tc‐ and lna‐oligonucleotides. For this purpose we produced the fluorescently labeled oligonucleotide tc6 and lna6 (13mers) targeting the 3′‐splice site upstream of exon 4. Free cellular uptake by HeLa cells was investigated by fluorescence microscopy via direct addition of a high concentration (20 µM) of tc6 or lna6 to the cell culture. For both backbone systems, we found no significant fluorescence accumulation in the cytosol or in the nucleus after 24 h of incubation. Only a high background fluorescence associated with the cell membrane was observed, indicating that no significant internalization occurred. A FACS analysis revealed a final free oligonucleotide uptake of only 3% in the case of tc6 and 0% for lna6.</p>
<p>In a second experiment, we investigated the cellular distribution of tc6 and lna6 24 h after lipofection at a concentration of 0.2 µM (Fig. <xref rid="GKH187F8">8</xref>). We found some differences in the cellular distribution of the two oligonucleotide analogues. Tc‐DNA (Fig. <xref rid="GKH187F8">8</xref>, left) is almost exclusively accumulated in the nucleus and virtually absent in the cytosol. Within the nucleus, tc‐DNA seems to be homogeneously distributed with no obvious compartmentalization. The situation is somewhat different in the case of LNA (Fig. <xref rid="GKH187F8">8</xref>, right). Also here, most of the oligonucleotide is localized in the nucleus, although some fluorescence still remains in the cytosol. Within the nucleus, LNA is unevenly distributed and preferentially enriched in small bodies, most likely the nucleoli.</p>
</sec>
</sec>
<sec>
<title>DISCUSSION</title>
<p>Tc‐DNA and LNA both belong to the class of conformationally constrained DNA analogues. They share many common features, such as the anionic nature of the backbone, increased affinity for RNA targets, overall A‐like conformation in duplexes with RNA, inability to activate RNaseH and increased biostability (<xref rid="GKH187C18">18</xref>,<xref rid="GKH187C19">19</xref>,<xref rid="GKH187C25">25</xref>). There are, however, differences in the relative dimensions of some of these features that translate into different biological properties. For example, the average increase in <italic>T</italic><sub>m</sub> of a modified unit in RNA target recognition relative to a DNA unit is between 4 and 7°C in the case of LNA (<xref rid="GKH187C17">17</xref>) and between 2 and 3°C in the case of tc‐DNA (<xref rid="GKH187C19">19</xref>). The higher RNA affinity of LNA relative to tc‐DNA is corroborated by the observed differences in the thermal stabilities of LNA/RNA and tc‐DNA/RNA duplexes, where <italic>T</italic><sub>m</sub> differences of ca. 2.5–3.0°C per nucleotide unit were found. Furthermore, tc‐DNA possesses a sugar–phosphate backbone which is more hydrophobic due to the extended carbon framework of the sugar unit. This might affect cellular uptake and distribution. Moreover, there may also be differences as to the extent of biostability against nucleolytic activity of both backbone systems. In previous experiments with tc‐DNA we found a remarkable stability of tc‐DNA against snake venom phosphodiesterase (<xref rid="GKH187C39">39</xref>) as well as in heat deactivated fetal calf serum (<xref rid="GKH187C25">25</xref>).</p>
<p>Tc‐ and lna‐oligonucleotides with a length of 15 nt, used in the submicromolar concentration range, can efficiently change RNA maturation and largely abolish the production of the associated protein in the cell. This goes along with no significant level of toxicity (measured in terms of cell number) or alteration of cell morphology upon transfection. Furthermore, we found that all antisense effects observed were sequence‐dependent, and thus true antisense effects. This was demonstrated with the double mismatch oligonucleotides which showed largely reduced antisense efficacy, and with a nonsense 18mer tc‐DNA which showed no antisense effect at all. Remarkably, the differential increase in full‐length RNA production between tc4 and tc5 is higher (Δ = 70%) than in the pair lna4 and lna5 (Δ = 45%). This indicates a slightly higher selectivity of the tc‐system in the antisense effect, compared to LNA. With a sequence length of 15, genome‐wide statistical selectivity on the level of RNA is unlikely to be compromised. Thus, strong binding oligonucleotide analogues such as tc‐DNA or LNA enable a reduction in the size of antisense oligonucleotides, which for typical applications are 20–25 nt in length. This could potentially reduce costs and material load and increase selectivity.</p>
<p>According to the RT–PCR assays, tc‐DNA shows increased nuclear antisense effects by a factor of 4–5 or more, compared to LNA. This contrasts with RNA target affinity where LNA is superior to tc‐DNA. Thus there is an inverse affinity/antisense activity relation between the two systems. Differences in the antisense response could in principle arise from different cellular distribution patterns of the oligonucleotide systems. LNA was previously found to occur in all compartments of HeLa and other cells (<xref rid="GKH187C20">20</xref>,<xref rid="GKH187C24">24</xref>). In our experiments, we observed some differences in the cellular distribution pattern of tc‐DNA and LNA. tc‐DNA showed a higher propensity for nuclear localization and a more homogeneous distribution within the nucleus as compared to LNA (Fig. <xref rid="GKH187F8">8</xref>). This could be one reason for the higher antisense efficacy of the former system. Along the same lines, the observed accumulation of LNA presumably in the nucleoli, the site of assembly of the ribosomes, may competitively reduce its binding to the spliceosome.</p>
<p>As a note of care, we add that the observed cellular distribution could also be a property of the lipofectamine/oligonucleotide complex and not a property of the oligonucleotidic system alone. Thus we cannot exclude that the distribution pattern changes when the nature of the cationic lipid is varied. It was shown before in HeLa cells that 2′‐OMe and 2′‐MOE‐oligonucleotides have higher nuclear accumulation when transfected with lipofectAMINE compared to when scrape loaded (<xref rid="GKH187C16">16</xref>). Also, we cannot exclude the possibility that other effects, such as higher nuclease stability of tc‐DNA, also contribute to the observed higher efficacy of tc‐DNA.</p>
<p>The fact that no significant uptake was found for tc‐oligonucleotides applied at high doses but in the absence of transfecting agents is in line with observations on 2′‐O‐alkyl RNAs and also for LNA (<xref rid="GKH187C24">24</xref>). However, we showed previously that small amounts of tc‐DNA, sufficient to give weak antisense effects, may still enter the cell under these conditions (<xref rid="GKH187C25">25</xref>). Nevertheless the increased hydrophobicity of the tc‐DNA backbone does not significantly increase passive penetration into cells. Efficient membrane passage is therefore still a privilege of charge neutral DNA analogues such as morpholino‐DNA or cationic PNAs (<xref rid="GKH187C16">16</xref>).</p>
<p>Interestingly, not only exon 4 is skipped, but also exon 3+4 double skipping occurs in spite of the fact that the oligonucleotides were designed to bind exclusively to the splice sites flanking exon 4. This fact seems to be neither dependent on the oligonucleotide type used, as it occurs with both LNA‐ and tc‐oligonucleotides, nor is it dependent on the length of the oligonucleotides. A sequence alignment revealed no further binding site with nine or more matched base pairs in the CyPA pre‐mRNA (we note explicitly that neither of the matched 9mers lna1 or tc1 showed a significant antisense effect). Furthermore, there is no difference in the splicing pattern whether the 5′‐ or the 3′‐splice site is targeted. Using antisense U7 snRNAs targeting either exon 4 or exon 3 of CyPA, the same phenomenon also occurs (D.Schümperli and co‐workers, manuscript in preparation). Multiple exon skipping was already observed before with antisense oligonucleotides or U7 snRNAs targeting exon 23 splice sites of the mouse dystrophin gene (<xref rid="GKH187C40">40</xref>,<xref rid="GKH187C41">41</xref>). This implies that certain groups of exons may be recognized by the splicing machinery in a concerted fashion so that they tend to be coordinately included in or excluded from the mRNA. However, the mechanism for this is still unknown.</p>
<p>In summary, we have shown that tc‐oligonucleotide 11– 15 mers, targeted to the 5′‐splice site of exon 4 efficiently change the splice pattern of CyPA pre‐mRNA. A direct comparison with the analogous LNA‐oligonucleotides revealed a higher antisense efficacy of tc‐DNA by at least a factor of 4–5. Thus, tc‐DNA emerges as a very powerful nuclear antisense system. Whether tc‐DNA is also useful for cytosolic antisense applications has still to be shown. Investigations in this direction with tc‐DNA and tc‐DNA–DNA/tcDNA gapmers are currently under way in our laboratories.</p>
</sec>
<sec>
<title>ACKNOWLEDGEMENTS</title>
<p>D.R. and C.J.L. gratefully acknowledge financial support from the Swiss National Science Foundation (grant No. 200020–100178). Work in the laboratory of D.S. was supported by the Swiss AIDS Research Program (grant no. 3339‐63429).</p>
</sec>
<sec>
<title></title>
<p>
<fig id="GKH187F1" position="float">
<caption>
<p><bold>Figure 1.</bold> Molecular structures of tc‐DNA and LNA in comparison to DNA.</p>
</caption>
<graphic xlink:href="gkh187f1"></graphic>
</fig>
<fig id="GKH187F2" position="float">
<caption>
<p><bold>Figure 2.</bold> Schematic representation of the splicing pattern of CyPA pre‐mRNA. The ball at tc6 or lna6 represents the fluorescein label.</p>
</caption>
<graphic xlink:href="gkh187f2"></graphic>
</fig>
<fig id="GKH187F3" position="float">
<caption>
<p><bold>Figure 3.</bold> RT–PCR analysis of CyPA pre‐mRNA splicing in HeLa cells in the presence of varying concentrations (0.05, 0.1 and 0.2 µM) of antisense tc‐oligonucleotides (lanes 1–12). Lane 13 (control): RNA from untreated cells.</p>
</caption>
<graphic xlink:href="gkh187f3"></graphic>
</fig>
<fig id="GKH187F4" position="float">
<caption>
<p><bold>Figure 4.</bold> Quantitative evaluation of full‐length CyPA mRNA after treatment with tc‐oligonucleotides. Values are normalized averages of two independent experiments. Control: RNA from untreated cells.</p>
</caption>
<graphic xlink:href="gkh187f4"></graphic>
</fig>
<fig id="GKH187F5" position="float">
<caption>
<p><bold>Figure 5.</bold> RT–PCR analysis of CyPA pre‐mRNA splicing in HeLa cells in the presence of varying concentrations (0.05, 0.1 and 0.2 µM) of antisense lna‐oligonucleotides (lanes 1–12). Lane 13 (control): RNA from untreated cells.</p>
</caption>
<graphic xlink:href="gkh187f5"></graphic>
</fig>
<fig id="GKH187F6" position="float">
<caption>
<p><bold>Figure 6.</bold> Quantitative evaluation of full‐length CyPA mRNA after treatment with lna‐oligonucleotides. All values are normalized averages with standard deviations from three independent experiments. Control: RNA from untreated cells.</p>
</caption>
<graphic xlink:href="gkh187f6"></graphic>
</fig>
<fig id="GKH187F7" position="float">
<caption>
<p><bold>Figure 7.</bold> Western blot, demonstrating the down‐regulation of CyPA protein by tc4. CyPA protein was probed with polyclonal anti‐CyPA antibodies. A polyclonal anti‐actin antibody was used for loading control.</p>
</caption>
<graphic xlink:href="gkh187f7"></graphic>
</fig>
<fig id="GKH187F8" position="float">
<caption>
<p><bold>Figure 8.</bold> Fluorescence microscopic images of the cellular distribution of tc6 (left) and lna6 (right) in HeLa cells (top: phase contrast image; center: UV image; and bottom: overlay of both images).</p>
</caption>
<graphic xlink:href="gkh187f8"></graphic>
</fig>
<table-wrap id="GKH187TB1">
<label>
<bold>Table 1.</bold>
</label>
<caption>
<p>Oligonucleotides prepared and used in this study</p>
</caption>
<table>
<tbody align="left" valign="bottom">
<tr content-type="rowsep">
<td valign="bottom" rowspan="1">Oligomer</td>
<td valign="bottom" rowspan="1">Sequence 5′ → 3′<sup>a</sup></td>
<td valign="bottom" rowspan="1">Target site (exon 4)</td>
<td valign="bottom" rowspan="1"><italic>T</italic><sub>m</sub> (°C)<sup>b</sup></td>
<td valign="bottom" rowspan="1">ESI‐MS<sup>c</sup>, calc.</td>
<td valign="bottom" rowspan="1">ESI‐MS<sup>c</sup>, found</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc1</td>
<td valign="bottom" rowspan="1">pCTTAC′CACT*</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">56.4</td>
<td valign="bottom" rowspan="1">3281.4</td>
<td valign="bottom" rowspan="1">3282.9</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc2</td>
<td valign="bottom" rowspan="1">pCCTTAC′CACTC*</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">69.3</td>
<td valign="bottom" rowspan="1">3935.8</td>
<td valign="bottom" rowspan="1">3937.0</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc3</td>
<td valign="bottom" rowspan="1">pCCCTTAC′CACTCA</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">77.4</td>
<td valign="bottom" rowspan="1">4388.2</td>
<td valign="bottom" rowspan="1">4389.0</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc4</td>
<td valign="bottom" rowspan="1">pACCCTTAC′CACTCAG</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">83.2</td>
<td valign="bottom" rowspan="1">5106.7</td>
<td valign="bottom" rowspan="1">5107.6</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc5</td>
<td valign="bottom" rowspan="1">pACCCTTA<bold><italic>A</italic></bold>′C<bold><italic>T</italic></bold>CTCAG</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">60.2</td>
<td valign="bottom" rowspan="1">5121.7</td>
<td valign="bottom" rowspan="1">5121.5</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tc6</td>
<td valign="bottom" rowspan="1">pACCACC′CTGTCAA‐FAM</td>
<td valign="bottom" rowspan="1">3′ss</td>
<td valign="bottom" rowspan="1">–</td>
<td valign="bottom" rowspan="1">5035.0</td>
<td valign="bottom" rowspan="1">5034.8</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">tcNS</td>
<td valign="bottom" rowspan="1">pCATTATTGCCCTGAAAGa</td>
<td valign="bottom" rowspan="1">–</td>
<td valign="bottom" rowspan="1">–</td>
<td valign="bottom" rowspan="1">6210.2</td>
<td valign="bottom" rowspan="1">6209.3</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">lna1</td>
<td valign="bottom" rowspan="1"><underline>C</underline>TTA<underline>C</underline>′<underline>C</underline>A<underline>C</underline>T</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">82.6</td>
<td valign="bottom" rowspan="1">2942.5</td>
<td valign="bottom" rowspan="1">2941.0</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">lna2</td>
<td valign="bottom" rowspan="1"><underline>CC</underline>TTA<underline>C</underline>′<underline>C</underline>A<underline>C</underline>T<underline>C</underline></td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">≈95</td>
<td valign="bottom" rowspan="1">3605.3</td>
<td valign="bottom" rowspan="1">3604.0</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">lna3</td>
<td valign="bottom" rowspan="1"><underline>CCC</underline>TTA<underline>C</underline>′<underline>C</underline>A<underline>C</underline>T<underline>C</underline>A</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">>95</td>
<td valign="bottom" rowspan="1">4277.9</td>
<td valign="bottom" rowspan="1">4276.2</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">lna4</td>
<td valign="bottom" rowspan="1">A<underline>CCC</underline>TTA<underline>C</underline>′<underline>C</underline>A<underline>C</underline>T<underline>C</underline>AG</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">>95</td>
<td valign="bottom" rowspan="1">4976.3</td>
<td valign="bottom" rowspan="1">4976.1</td>
</tr>
<tr>
<td valign="bottom" rowspan="1">lna5</td>
<td valign="bottom" rowspan="1">A<underline>CCC</underline>TTA<bold><italic>A</italic></bold>′<underline>C</underline><bold><italic>T</italic></bold><underline>C</underline>T<underline>C</underline>AG</td>
<td valign="bottom" rowspan="1">5′ss</td>
<td valign="bottom" rowspan="1">92.3</td>
<td valign="bottom" rowspan="1">4977.3</td>
<td valign="bottom" rowspan="1">4975.0</td>
</tr>
<tr content-type="rowsep">
<td valign="bottom" rowspan="1">lna6</td>
<td valign="bottom" rowspan="1">A<underline>CC</underline>A<underline>CC</underline>′<underline>C</underline>TGT<underline>C</underline>AA‐FAM</td>
<td valign="bottom" rowspan="1">3′ss</td>
<td valign="bottom" rowspan="1">–</td>
<td valign="bottom" rowspan="1">4908.3</td>
<td valign="bottom" rowspan="1">4907.0</td>
</tr>
</tbody>
</table>
<table-wrap-foot>
<p><sup>a</sup>Bold italic: mismatch position; <underline>C</underline>: 5‐methylcytosine; a: 2′‐deoxyadenosine; (′) denotes the splice position on the pre‐mRNA; (*) denotes a 3′‐terminal modification by a 2,5‐dimethoxytetrahydrofuran‐3,4‐diol unit (see Materials and Methods).</p>
<p><sup>b</sup><italic>T</italic><sub>m</sub> values (2 µM duplex in 10 mM NaH<sub>2</sub>PO<sub>4</sub>, 150 mM NaCl, pH 7.0) were measured with the RNA complement r(ACUGAGUGGUAAGGGUA).</p>
<p><sup>c</sup>Molecular masses were recorded in the negative ion mode and are indicated as [M‐H]<sup>–</sup>.</p>
</table-wrap-foot>
</table-wrap>
</p>
</sec>
</body>
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</istex:document></istex:metadataXml><mods version="3.6"><titleInfo lang="en"><title>Nuclear antisense effects in cyclophilin A pre‐mRNA splicing by oligonucleotides: a comparison of tricyclo‐DNA with LNA</title></titleInfo><titleInfo type="alternative" lang="en" contentType="CDATA"><title>Nuclear antisense effects in cyclophilin A pre‐mRNA splicing by oligonucleotides: a comparison of tricyclo‐DNA with LNA</title></titleInfo><name type="personal"><namePart type="given">Damian</namePart><namePart type="family">Ittig</namePart><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Songkai</namePart><namePart type="family">Liu</namePart><affiliation>Institute of Cell Biology, University of Berne, Baltzerstrasse 4, CH‐3012 Berne, Switzerland</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Dorte</namePart><namePart type="family">Renneberg</namePart><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Daniel</namePart><namePart type="family">Schümperli</namePart><affiliation>Institute of Cell Biology, University of Berne, Baltzerstrasse 4, CH‐3012 Berne, Switzerland</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Christian J.</namePart><namePart type="family">Leumann</namePart><affiliation>*To whom correspondence should be addressed. Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: leumann@ioc.unibe.ch The authors wish it to be known that, in their opinion, the first two authors should be regarded as joint First Authors</affiliation><role><roleTerm type="text">author</roleTerm></role></name><typeOfResource>text</typeOfResource><genre type="research-article" displayLabel="research-article" authority="ISTEX" authorityURI="https://content-type.data.istex.fr" valueURI="https://content-type.data.istex.fr/ark:/67375/XTP-1JC4F85T-7">research-article</genre><originInfo><publisher>Oxford University Press</publisher><dateIssued encoding="w3cdtf">2004-01-16</dateIssued><copyrightDate encoding="w3cdtf">2004</copyrightDate></originInfo><language><languageTerm type="code" authority="iso639-2b">eng</languageTerm><languageTerm type="code" authority="rfc3066">en</languageTerm></language><abstract lang="en">The nuclear antisense properties of a series of tricyclo (tc)‐DNA oligonucleotide 9–15mers, targeted against the 3′ and 5′ splice sites of exon 4 of cyclophilin A (CyPA) pre‐mRNA, were evaluated in HeLa cells and compared with those of corresponding LNA‐oligonucleotides. While the 9mers showed no significant antisense effect, the 11–15mers induced exon 4 skipping and exon 3+4 double skipping to about an equal extent upon lipofectamine mediated transfection in a sequence‐ and dose‐dependent manner, as revealed by a RT–PCR assay. The antisense efficacy of the tc‐oligonucleotides was found to be superior to that of the LNA‐oligonucleotides in all cases by a factor of at least 4–5. A tc‐oligonucleotide 15mer completely abolished CyPA mRNA production at 0.2 µM concentration. The antisense effect was confirmed by western blot analysis which revealed a reduction in CyPA protein to 13% of its normal level. Fluorescence microscopic investigations with a fluorescein labeled tc‐15mer revealed a strong propensity for homogeneous nuclear localization of this backbone type after lipofectamine mediated transfection, while the corresponding lna 15mer showed a less clear cellular distribution pattern. Transfection without lipid carrier showed no significant internalization of both tc‐ and LNA‐ oligonucleotides. The obtained results confirm the power of tc‐DNA for nuclear antisense applications. Moreover, CyPA may become an interesting therapeutic target due to its important role in the early steps of the viral replication of HIV‐1.</abstract><note>Received October 9, 2003; Revised and Accepted December 3, 2003</note><note type="author-notes">*To whom correspondence should be addressed. Tel: +41 31 631 4355; Fax: +41 31 631 3422; Email: leumann@ioc.unibe.ch
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