Characterization of RNA structure by bis-pyrene-labeled 2'-O-methyloligonucleotides.

Properties of 2'-O-methyloligoribonucleotides containing two consecutive 2'-O-(1-pyrenylmethyl)uridine were investigated as a fluorescent probe to search the single strand regions of RNA. The bis-pyrene-labeled 2'-O-methyloligoribonucleotide (OMUpy2) induced the formation of pyrene dimer upon hybridization with the complementary oligoribonucleotides and showed remarkable appearance of broad structureless fluorescence at 480 nm. Contrarily, when OMUpy2 was hybridized with the complementary oligodeoxyribonucleotides, such enhancement of fluorescence was scarcely observed. When various OMUpy2 were applied to E. coli 5S-rRNA, the fluorescence intensity at 480 nm was varied in a sequence specific manner.     

Detection of acceptor sites for antisense oligonucleotides on native folded RNA by fluorescence spectroscopy

Antisense strategy has high potential for curing diseases and studying gene functions by suppressing the translation step. For the strategy, it is essential to detect acceptor sites of antisense molecules on mRNA under physiological conditions. We propose a new analytical method for the detection of acceptor sites of antisense molecules with high sensitivity. 2'-O-Methyloligoribonucleotide containing 2'-O-(1-pyrenylmethyl)uridine (OMUpy) was chosen as the fluorescence probe. The fluorescence intensity due to the pyrene in single-stranded OMUpy was scarcely observed. When OMUpy was hybridized with the complementary oligoRNA, the fluorescence intensity at 375 nm was remarkably increased. It was found that the increase was derived from the localization of the pyrene by the measurements of time-resolved fluorescence spectroscopy, CD and UV absorption spectra. These results suggest that the change of the fluorescence intensity of OMUpy can be a useful index to monitor hybridization. In this study, we chose Escherichia coli. 16S-rRNA as the model RNA and chose seven regions for probing by OMUpy based on the reported secondary structure of 16S-rRNA. The fluorescence intensity of an equimolar mixture of OMUpy with 16S-rRNA varied depending on the sequence. In particular, the increment in the system of OMUpy-8, which can hybridize with region 887-896 nt of 16S-rRNA, was most significant among the systems. These results indicated that the site targeted by OMUpy-8 was exposed to regulatory molecules, and suggest that the method presented here is useful to design antisense molecules.     

Microarray-based label-free detection of RNA using bispyrene-modified 2'-O-methyl oligoribonucleotide as capture and detection probe

A novel oligonucleotide microarray that can detect RNAs without fluorescent labeling of sample RNAs was developed. As a capture and detection probe, bispyrene-modified 2'-O-methyl oligoribonucleotide (OMUpy2), whose fluorescence was dramatically increased when hybridized with its complementary RNA, was adopted. Fluorescence of the OMUpy2 tethered on the glass surface was enhanced as much as 22-fold by the addition of complementary oligoribonucleotide.     

Homogeneous fluorescence assays for RNA diagnosis by pyrene-conjugated 2'-O-methyloligoribonucleotides

We developed a bispyrene-conjugated 2'-O-methyloligoribonucleotide as an RNA-specific RNA-probe. The probe hybridized with the complementary RNA, greatly enhancing fluorescence and discriminating RNA from DNA. The assay was carried out in homogeneous aqueous media without removing the unbound probe from the detection solution. This homogeneous fluorescence assay also discriminated mismatch sequences in the target RNA. These pyrene probes could possess high potential to detect RNA in biological specimens simply.     

The nucleotide sequence at the 3'-end of Neurospora crassa 18S-rRNA and studies on the interaction with 5S-rRNA.

The sequence of more than 100 nucleotides at the 3'-end of Neurospora crassa 18S-rRNA was determined by chemical sequencing techniques. Extensive homologies with 18S-rRNA from other eukaryotes were found. Inspection of the nucleotide sequence at the 3'-end of N. crassa 5S-rRNA revealed the presence of sequences complementary to a region near the 3'-terminus of 18S-rRNA. Under the appropriate conditions a complex was formed between 18S-rRNA and 5S-rRNA (Tm 53 degrees C). Interaction was detected between 5S-rRNA and a specific 3'-terminal fragment from 18S-rRNA and between 18S-rRNA and a specific 3'-terminal fragment from 5S-rRNA. These findings are consistent with the idea that intermolecular base-pairing between nucleotides at the 3'-ends of 18S-rRNA and 5S-rRNA may be functionally important within the ribosome. Further investigation revealed that this intermolecular base-pairing is not essential for ribosome stability.     

Structural analysis of nucleic acids by labeled oligonucleotides

In this report, the characterization of labeled oligonucleotides was discussed from the view points of base sequence analysis and structural analysis of nucleic acids in solution. Oligonucleotides site specifically spin labeled with TEMPO and fluorescent labeled with fluorescein were prepared and used for those analyses. The changes of ESR lines and rotational correlation time (tau) of the spin labeled oligonucleotide (S-probe) were dependent on the base sequence of S-probe, diastereoisomers, and the manner of hybridization. These results suggest that the conformation of the hybrid largely affected the local mobility of TEMPO and that tau value of S-probe reflected the local structure of the hybrid. When S-probe which was complementary to a single strand region of 5S RNA, was mixed with 5S RNA, tau value largely changed, indicating that the S-probe could form hybrid with 5S RNA in solution. Similar results were also obtained in the fluorescence depolarization analysis using fluorescent labeled oligonucleotide (F-probe). These results suggest that S-probe and F-probe are capable for the recognition of the secondary structure of 5S RNA in solution and useful for the analysis of the secondary structure of other nucleic acids in solution.     

Syntheses and properties of fluorescent labeled oligonucleotides containing deoxyethenoadenosine at 5' end.

The fluorescent labeled oligodeoxyribonucleotides which contain deoxyethenoadenosione (d epsilon A) at their 5' end were prepared by treating CPG bound oligonucleotides with 5'-DMTr-deoxyethenoadenosine-3'-H-phosphonate. The hybrid formation of d epsilon A-oligonucleotide with its complementary DNA was studied by fluorescence spectroscopy. The fluorescence of d epsilon A in a single strand was largely quenched by stacking interaction with the base at 3' position. When d epsilon A-oligonucleotides hybridized with their complementary strands, relative fluorescence quantum yields (Qrel) against d epsilon A changed in specific manners. These results suggest that d epsilon A-oligonucleotides are applicable to study the local structure of DNA in solution.     

Structure and function of the non-coding regions of hepatitis C viral RNA

At the 5' and 3' end of genomic HCV RNA there are two highly conserved, untranslated regions, 5'UTR and 3'UTR. These regions are organized into spatially ordered structures and they play key functions in regulation of processes of the viral life cycle. Most nucleotides of the region located at the 5' side of the coding sequence serve as an internal ribosomal entry site, IRES, which directs cap-independent translation. The RNA fragment present at the 3' end of the genome is required for virus replication and probably contributes to translation of viral proteins. During virus replication its genomic strand is transcribed into a strand of minus polarity, the replicative strand. Its 3' terminus is responsible for initiation of synthesis of descendant genomic strands. This article summarizes our current knowledge on the structure and function of the non-coding regions of hepatitis C genomic RNA, 5'UTR and 3'UTR, and the complementary sequences of the replicative viral strand.     

Bulged adenosine influence on the RNA duplex conformation in solution

The RNA single bulge motif is an unpaired residue within a strand of several complementary base pairs. To gain insight into structural changes induced by the presence of the adenosine bulge on RNA duplex, the solution structures of RNA duplex containing a single adenine bulge (5'-GCAGAAGAGCG-3'/5'-CGCUCUCUGC-3') and a reference duplex with all Watson-Crick base pairs (5'-GCAGAGAGCG-3'/5'-CGCUCUCUGC-3') have been determined by NMR spectroscopy. The reference duplex structure is a regular right-handed helix with all of the attributes of an A-type helix. In the bulged duplex, single adenine bulge stacks into the helix, and the bulge region forms a well-defined structure. Both structures were analyzed by the use of calculated helical parameters. Distortions induced by the accommodation of unpaired residue into the helical structure propagate over the entire structure and are manifested as the reduced base pairs inclination and x-displacement. Intrahelical position of bulged adenine A5 is stabilized by efficient stacking with 5'-neighboring residues G4.     

A single-label phenylpyrrolocytidine provides a molecular beacon-like response reporting HIV-1 RT RNase H activity

6-Phenylpyrrolocytidine (PhpC), a structurally conservative and highly fluorescent cytidine analog, was incorporated into oligoribonucleotides. The PhpC-containing RNA formed native-like duplex structures with complementary DNA or RNA. The PhpC-modification was found to act as a sensitive reporter group being non-disruptive to structure and the enzymatic activity of RNase H. A RNA/DNA hybrid possessing a single PhpC insert was an excellent substrate for HIV-1 RT Ribonuclease H and rapidly reported cleavage of the RNA strand with a 14-fold increase in fluorescence intensity. The PhpC-based assay for RNase H was superior to the traditional molecular beacon approach in terms of responsiveness, rapidity and ease (single label versus dual). Furthermore, the PhpC-based assay is amenable to high-throughput microplate assay format and may form the basis for a new screen for inhibitors of HIV-RT RNase H.     

Bis-pyrene-labeled molecular beacon: a monomer-excimer switching probe for the detection of DNA base alteration

A new bis-pyrene-labeled oligonucleotide probe (BP-probe) has been designed for the detection of a single base mismatch in single strand (ss) DNA as a target. The sequence of BP-probe was chosen to form stem-loop structure similar to a molecular beacon (MB-probe), yielding bis-pyrene-labeled molecular beacon (BP-MB-probe). Partially double stranded (ds) BP-MB-probes were prepared by complexation with oligonucleotides whose sequences are complementary to the loop segment but not to the stem and exchangeable with the target DNA. The partially ds BP-MB-probes were shown to exhibit monomer fluorescence as major fluorescence, while the ss BP-MB-probe in the stem-loop form displays strong excimer fluorescence. The strand exchange reactions between partially ds BP-MB-probe and target ss DNA in the presence of cationic comb-type copolymer as a catalyst were monitored by the excimer fluorescence changes. The existence of a mismatched base can be determined by the slower PASE rates compared with fully matched DNA.     

Heterogeneity of the 3'' end of minus-strand RNA in the poliovirus replicative form.

The 3' terminus of the strand (minus strand) complementary to poliovirion RNA (plus strand) has been examined to see whether this sequence extends to the 5'-nucleotide terminus of the plus strand, or whether minus-strand synthesis terminates prematurely, perhaps due to the presence of a nonreplicated nucleotide primer for initiation of plus-strand synthesis. The 3' terminus was labeled with 32P using [5'-32P]pCp and RNA ligase, and complete RNase digests were performed with RNases A, T1, and U2. 32P-oligonucleotides were analyzed for size by polyacrylamide-urea gel electrophoresis. The major oligonucleotide products formed were consistent with the minus strand containing 3' ends complementary and flush with the 5' end of the plus strand. However, a variable proportion of the isolated minus strands from different preparations were heterogeneous in length and appeared to differ from each other by the presence of one, two, or three 3'-terminal A residues.     

Transcription map for adenovirus type 12 DNA.

The regions of the adenovirus type 12 genome which encode l- and r-strand-specific cytoplasmic RNA were mapped by the following procedure. Radioactive, intact, separated complementary strands of the viral genome were hybridized to saturating amounts of unlabeled late cytoplasmic RNA. The segments of each DNA strand complementary to the RNA were then purified by S1 nuclease digestion of the hybrids. The arrangement of the coding regions of each strand was deduced from the pattern of hybridization of these probes to unlabeled viral DNA fragments produced by digestion with EcoRI, BamHI, and HindIII.. The resulting map is similar, if not identical, to that of adenovirus type 2. The subset of the late cytoplasmic RNA sequences which are expressed at early times were located on the map by hybridizing labeled, early cytoplasmic RNA to both unlabeled DNA fragments and unlabeled complementary strands of specific fragments. Early cytoplasmic RNA hybridized to the r-strand to EcoRI-C and BamHI-B and to the l-strand of BamHI-E. Hybridization to BamHI-C was also observed. The relative rates of accumulation of cytoplasmic RNA complementary to individual restriction fragments was measured at both early and late times. Early during infection, most of the viral RNA appearing in the cytoplasm was derived from the molecular ends of the genome. Later (24 to 26 h postinfection) the majority of the newly labeled cytoplasmic RNA was transcribed from DNA sequences mapping between 25 and 60 map units on the genome.