Surface modification of tri-calcium phosphate nanoparticles by DOPE and/or anti-E6 antibody to enhance uptake of antisense of E6 mRNA.

The main aim of this study was to evaluate the uptake of E6 mRNA antisense into cervical cancer cells, induced by human papilloma virus (HPV). In this study, the carrier of the antisense was tri-calcium phosphate nanoparticles (TCP NPs) conjugated with dioleoyl phosphatidyl ethanolamine (DOPE) and/or anti-E6 antibody. At first, TCP NPs were synthesized, coated with carboxy-polyethylene glycol, and then conjugated with anti-E6 antibody and/or DOPE by carbodiimide cross-linker. Then, a single stranded DNA, which was complementary (antisense) of E6 mRNA, was attached to each one. Finally, the uptake of conjugated and unconjugated TCP NPs into HelaS3 cells was separately evaluated by Fourier transform infrared spectroscopy, optical microscopy, and fluorescent microscopy. Also, the cytotoxicity of these carriers was measured by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazolium bromide (MTT) assay. Overall, 4 types of TCP NPs were used in this study, including 1) TCP NPs conjugated with DOPE (TCP NPs/DOPE), 2) TCP NPs conjugated with DOPE and antibody (TCP NPs/DOPE/Anti-E6 Ab), 3) TCP NPs conjugated with antibody (TCP NPs/Anti-E6 Ab), and 4) TCP NPs which not conjugated with DOPE and antibody (unconjugated TCP NPs). Uptake tests showed that although all types of TCP NPs could transfer antisense of E6 mRNA into HelaS3 cells, TCP NPs/DOPE and TCP NPs/DOPE/Anti-E6 Ab had more uptake than TCP NPs/Anti-E6 Ab and unconjugated TCP NPs. Moreover, MTT assay showed that TCP NPs/DOPE was more toxic than TCP NPs/DOPE/Anti-E6 Ab, TCP NPs/Anti-E6 Ab, and unconjugated TCP NPs. It can be concluded that TCP NPs/DOPE/Anti-E6 Ab is a good choice for oligonucleotide delivery, because of higher uptake and less toxicity, compared with other formulations.

Identification of a KIR antisense lncRNA expressed by progenitor cells.

Human NK cells express cell surface class I MHC receptors (killer cell immunoglobulin-like receptor, KIR) in a probabilistic manner. Previous studies have shown that a distal promoter acts in conjunction with a proximal bidirectional promoter to control the selective activation of KIR genes. We report here the presence of an intron 2 promoter in several KIR genes that produce a spliced antisense transcript. This long noncoding RNA (lncRNA) transcript contains antisense sequence complementary to KIR-coding exons 1 and 2 as well as the proximal promoter region of the KIR genes. The antisense promoter contains myeloid zinc finger 1 (MZF-1)-binding sites, a transcription factor found in hematopoietic progenitors and myeloid precursors. The KIR antisense lncRNA was detected only in progenitor cells or pluripotent cell lines, suggesting a function that is specific for stem cells. Overexpression of MZF-1 in developing NK cells led to decreased KIR expression, consistent with a role for the KIR antisense lncRNA in silencing KIR gene expression early in development.

Secondary structure of antisense RNAß, an internal transcriptional terminator of the plasmid-encoded iron transport-biosynthesis operon of Vibrio anguillarum.

RNAß affects the transcription process of the iron transport-biosynthesis operon encoded in the pJM1 plasmid of Vibrio anguillarum at a stem-loop structure located in the intergenic region between the fatA and angR genes. The net result is a higher level of the fatD, fatC, fatB, and fatA moiety as compared with the longer transcript encoding those genes as well as the angR and angT genes. In this work we report the secondary structure of RNAß determined by treatment with single and double strand specific ribonucleases as well as lead acetate followed by sequencing. The generated in vitro structural data indicated that three of the four previously described loops are in agreement with the original model, however, the alteration of loop IV as well as several other structural differences in the overall shape of the molecule led to the necessity of creating a new in silico model. Using the sites of mutations in the various loops we modeled the change in the RNAß secondary structure induced by those mutations. Mutations of loops III and IV to their complementary bases alter the overall structure of the RNAß significantly and increase its function while mutations in loops I and II have the opposite effect, the structure is unchanged but the activity of RNAß decreases. This indicates that loops I and II are necessary for interaction with the target mRNA. It is possible that the structural rearrangement introduced by mutations in loops III and IV promote activity and binding in loops I and II through reducing steric hindrance or increased binding to the target. This result also indicates that the exact relative positions of the critical loops are unimportant for activity.

Effect of salt and RNA structure on annealing and strand displacement by Hfq.

The Sm-like protein Hfq promotes the association of small antisense RNAs (sRNAs) with their mRNA targets, but the mechanism of Hfq's RNA chaperone activity is unknown. To investigate RNA annealing and strand displacement by Hfq, we used oligonucleotides that mimic functional sequences within DsrA sRNA and the complementary rpoS mRNA. Hfq accelerated at least 100-fold the annealing of a fluorescently labeled molecular beacon to a 16-nt RNA. The rate of strand exchange between the oligonucleotides increased 80-fold. Therefore, Hfq is very active in both helix formation and exchange. However, high concentrations of Hfq destabilize the duplex by preferentially binding the single-stranded RNA. RNA binding and annealing were completely inhibited by 0.5 M salt. The target site in DsrA sRNA was 1000-fold less accessible to the molecular beacon than an unstructured oligonucleotide, and Hfq accelerated annealing with DsrA only 2-fold. These and other results are consistent with recycling of Hfq during the annealing reaction, and suggest that the net reaction depends on the relative interaction of Hfq with the products and substrates.

Screening and identification of natural antisense transcripts in Helicobacter pylori by a novel approach based on RNase I protection assay.

Natural antisense transcripts (NATs) are endogenous RNA molecules that exhibit partial or complete complementarity to other RNAs. Studies have shown that NATs may participate in a broad range of gene regulatory events. The identification of NATs in human, mouse and Escherichia coli has revealed their widespread occurrence in both eukaryotic and prokaryotic life. However, little is known about NATs in Helicobacter pylori (H. pylori), a human pathogen which is associated with gastric diseases. Here we systematically screened NATs in H. pylori by a novel experimental strategy based on RNase I protection assay. We successfully constructed a cDNA library of NATs and developed a novel poly(A)-tailed RT-PCR method to monitor the expression of NATs. After sequencing, bioinformatic analysis and expression detection, two novel NATs (NAT-39 and NAT-67) were confirmed. They were, respectively, complementary to the following genes: iron-regulated outer membrane protein (frpB) and periplasmic iron-binding protein (ceuE). Taken together, the results suggest that NAT-39 and NAT-67 may participate in the regulation of iron homeostasis in H. Pylori in a sequence complementary manner with target mRNAs.

Antisense transcripts are targets for activating small RNAs.

Agents that activate expression of specific genes to probe cellular pathways or alleviate disease would go beyond existing approaches for controlling gene expression. Duplex RNAs complementary to promoter regions can repress or activate gene expression. The mechanism of these promoter-directed antigene RNAs (agRNAs) has been obscure. Other work has revealed noncoding transcripts that overlap mRNAs. The function of these noncoding transcripts is also not understood. Here we link these two sets of enigmatic results. We find that antisense transcripts are the target for agRNAs that activate or repress expression of progesterone receptor (PR). agRNAs recruit Argonaute proteins to PR antisense transcripts and shift localization of the heterogeneous nuclear ribonucleoprotein-k, RNA polymerase II and heterochromatin protein 1 gamma. Our data demonstrate that antisense transcripts have a central role in recognition of the PR promoter by both activating and inhibitory agRNAs.

RETRACTED: Secondary siRNAs result from unprimed RNA synthesis and form a distinct class.

In Caenorhabditis elegans, an effective RNA interference (RNAi) response requires the production of secondary short interfering RNAs (siRNAs) by RNA-directed RNA polymerases (RdRPs). We cloned secondary siRNAs from transgenic C. elegans lines expressing a single 22-nucleotide primary siRNA. Several secondary siRNAs start a few nucleotides downstream of the primary siRNA, indicating that non-RISC (RNA-induced silencing complex)-cleaved mRNAs are substrates for secondary siRNA production. In lines expressing primary siRNAs with single-nucleotide mismatches, secondary siRNAs do not carry the mismatch but contain the nucleotide complementary to the mRNA. We infer that RdRPs perform unprimed RNA synthesis. Secondary siRNAs are only of antisense polarity, carry 5' di- or triphosphates, and are only in the minority associated with RDE-1, the RNAi-specific Argonaute protein. Therefore, secondary siRNAs represent a distinct class of small RNAs. Their biogenesis depends on RdRPs, and we propose that each secondary siRNA is an individual RdRP product.

An internal antisense RNA regulates expression of the photosynthesis gene isiA.

Small regulatory noncoding RNAs exist in both eukaryotic and prokaryotic organisms. Most of these RNA transcripts are trans-encoded RNAs with short and only partial antisense complementarity to their target RNAs, which regulate gene expression by modifying mRNA stability and translation. In contrast, reports on the function of cis-encoded, perfectly complementary antisense RNAs in eubacteria are rare. Cyanobacteria respond to iron deficiency by expressing IsiA (iron stress-induced protein A), which forms a giant ring structure around photosystem I. Here, we show that this process is controlled by IsrR (iron stress-repressed RNA), a cis-encoded antisense RNA transcribed from the isiA noncoding strand. Artificial overexpression of IsrR under iron stress causes a strongly diminished number of IsiA-photosystem I supercomplexes, whereas IsrR depletion results in premature expression of IsiA. The coupled degradation of IsrR/isiA mRNA duplexes appears to be a reversible switch that can respond to environmental changes. IsrR is the only RNA known so far to regulate a photosynthesis component.

Antisense radiotherapy: targeting full-size mdrl mRNA with 125I-labelled oligonucleotides.

PURPOSE: Antisense radiotherapy is an approach based on the targeting of mRNA of specific genes by complementary oligonucleotide probes labelled with an Auger-electron-emitting radioisotope. Decay of the Auger emitter should specifically destroy the targeted mRNA while producing minimal damage to the rest of mRNA pool and the nuclear DNA. The feasibility of this approach was investigated by using full-length human multidrug-resistance gene (mdr1) mRNA as a target. MATERIALS AND METHODS: Antisense oligonucleotides were labelled with [125I] I-dCTP by primer extension and annealed to target mRNA. Breaks in the target mRNA were analysed by denaturing polyacrylamide gel electriphoresis. RESULTS: The efficiency of 125I-labelled antisense oligonucleotides in producing RNA strand breaks was tested on short synthetic RNA and DNA targets. The position and specificity of 125I-induced breaks in the full-length mRNA were then tested and compared with the cleavage of the target by RNase H. The distribution of the breaks in the longer mRNA is different from that in the short RNA targets, most likely due to a complex folding of RNA strands in the full-length mRNA. CONCLUSIONS: The authors posit that 125I-labelled antisense probes could be useful not only for targeting mRNA, but also as probes for mRNA folding in vivo.

Micro RNAs are complementary to 3' UTR sequence motifs that mediate negative post-transcriptional regulation.

Micro RNAs are a large family of noncoding RNAs of 21-22 nucleotides whose functions are generally unknown. Here a large subset of Drosophila micro RNAs is shown to be perfectly complementary to several classes of sequence motif previously demonstrated to mediate negative post-transcriptional regulation. These findings suggest a more general role for micro RNAs in gene regulation through the formation of RNA duplexes.

Antisense RNA-mediated deficiency of the calpain protease, nCL-4, in NIH3T3 cells is associated with neoplastic transformation and tumorigenesis.

We previously have described the use of an antisense RNA strategy termed random homozygous knock-out (RHKO) to identify negative regulators of cell proliferation. Here we report the discovery that RHKO-mediated deficiency of the nCL-4 calpain protease results in cellular transformation of and tumorigenesis by murine NIH3T3 fibroblasts. We isolated cell clones able to form colonies on 0.5% soft agar and found that these cells generated tumors when injected subcutaneously into nude mice. The gene inactivated by RHKO was identified as nCL-4 by genomic library screening, transcript analysis, and DNA sequencing. Anchorage-independent growth, as indicated by colony formation on soft agar, was reversed by reversal of antisense-mediated homozygous inactivation, but continued haplo-insufficiency of nCL-4 resulting from insertional mutagenesis of one nCL-4 allele was associated with persistent tumorigenesis. nCL-4 cDNA expressed in naive 3T3 cells in the antisense, but not sense, direction under control of the cytomegalovirus early promoter reproduced the anchorage-independent growth effects of RHKO. Our results implicate deficiency of the nCL-4 calpain protease in neoplastic transformation.

Intracellular mRNA cleavage induced through activation of RNase P by nuclease-resistant external guide sequences.

Most antisense oligonucleotide experiments are performed with molecules containing RNase H-competent backbones. However, RNase H may cleave nontargeted mRNAs bound to only partially complementary oligonucleotides. Decreasing such "irrelevant cleavage" would be of critical importance to the ability of the antisense biotechnology to provide accurate assessment of gene function. RNase P is a ubiquitous endogenous cellular ribozyme whose function is to cleave the 5' terminus of precursor tRNAs to generate the mature tRNA. To recruit RNase P, complementary oligonucleotides called external guide sequences (EGS), which mimic structural features of precursor tRNA, were incorporated into an antisense 2'-O-methyl oligoribonucleotide targeted to the 3' region of the PKC-alpha mRNA. In T24 human bladder carcinoma cells, these EGSs, but not control sequences, were highly effective in downregulating PKC-alpha protein and mRNA expression. Furthermore, the downregulation is dependent on the presence of, and base sequence in, the T-loop. Similar observations were made with an EGS targeted to the bcl-xL mRNA.

Antisense RNA control of gene expression in bacteriophage P22. II. Kinetic mechanism and cation specificity of the pairing reaction.

The bacteriophage P22 sar RNA-ant mRNA pairing reaction was characterized kinetically. The pairing reaction proceeds by a three-step pathway. First, reversible base pairs form between complementary hairpin loops in sar RNA and ant RNA (Kd = 270 nM). Next, stable duplex formation initiates between single-stranded nucleotides in sar RNA and ant RNA; the ant RNA nucleotides are at the bottom of a hairpin stem that is partially accessible. Concomitant unwinding of one sar RNA hairpin and the complementary ant RNA hairpin then occurs, to form a partially paired intermediate (k2 = 12 min(-1). Finally, a complete duplex forms after unwinding of the other sar RNA hairpin and the complementary ant RNA hairpin (k3 = 7 min(-1). Experiments with sar RNA sequence and length variants demonstrate that the precise structures of both sar RNA hairpins affect the kinetic parameters. The pairing reaction is Mg2+-dependent, and shows high specificity for the required cation. Maximal pairing rates are achieved when more than one Mg2+ ion is bound. The cation-dependence and specificity indicate a requirement for Mg2+-dependent tertiary structure.

Single strand targeted triplex-formation. Destabilization of guanine quadruplex structures by foldback triplex-forming oligonucleotides.

Oligonucleotides that can hybridize to single-stranded complementary polypurine nucleic acid targets by Watson-Crick base pairing as well as by Hoogsteen base pairing, referred to here as foldback triplex-forming oligonucleotides (FTFOs), have been designed. These oligonucleotides hybridize with target nucleic acid sequences with greater affinity than antisense oligonucleotides, which hybridize to the target sequence only by Watson-Crick hydrogen bonding [Kandimalla, E. R. and Agrawal, S. Gene(1994) 149, 115-121 and references cited therein]. FTFOs have been studied for their ability to destabilize quadruplexes formation by RNA or DNA target sequences. The influence of various DNA/RNA compositions of FTFOs on their ability to destabilize RNA and DNA quadruplexes has been examined. The ability of the FTFOs to destabilize quadruplex structures is related to the structurally and thermodynamically stable foldback triplex formed between the FTFO and its target sequence. Antisense oligonucleotides (DNA or RNA) that can form only a Watson-Crick double helix with the target sequence are unable to destabilize quadruplex structures of RNA and DNA target sequences and are therefore limited in their repertoire of target sequences. The quadruplex destabilization ability of FTFOs is dependent on the nature of the cation present in solution. The RNA quadruplex destabilization ability of FTFOs is -20% higher in the presence of sodium ion than potassium ion. The use of FTFOs, which can destabilize quadruplex structure, opens up new areas for development of oligonucleotide-based therapeutics, specifically, targeting guanine-rich sequences that exist at the ends of pro- and eukaryotic chromosomes and dimerization regions of retroviral RNA.