Synthesis and characterization of 2′-modified-4′-thioRNA: a comprehensive comparison of nuclease stability

We report herein the synthesis and physical and physiological characterization of fully modified 2′-modified-4′-thioRNAs, i.e. 2′-fluoro-4′-thioRNA (F-SRNA) and 2′-O-Me-4′-thioRNA (Me-SRNA), which can be considered as a hybrid chemical modification based on 2′-modified oligonucleotides (ONs) and 4′-thioRNA (SRNA). In its hybridization with a complementary RNA, F-SRNA (15mer) showed the highest Tm value (+16°C relative to the natural RNA duplex). In addition, both F-SRNA and Me-SRNA preferred RNA as a complementary partner rather than DNA in duplex formation. The results of a comprehensive comparison of nuclease stability of single-stranded F-SRNA and Me-SRNA along with 2′-fluoroRNA (FRNA), 2′-O-MeRNA (MeRNA), SRNA, and natural RNA and DNA, revealed that Me-SRNA had the highest stability with t1/2 values of > 24 h against S1 nuclease (an endonuclease) and 79.2 min against SVPD (a 3′-exonuclease). Moreover, the stability of Me-SRNA was significantly improved in 50% human plasma (t1/2 = 1631 min) compared with FRNA (t1/2 = 53.2 min) and MeRNA (t1/2 = 187 min), whose modifications are currently used as components of therapeutic aptamers. The results presented in this article will, it is hoped, contribute to the development of 2′-modified-4′-thioRNAs, especially Me-SRNA, as a new RNA molecule for therapeutic applications

Nuclease-resistant chimeric ribozymes containing deoxyribonucleotides and phosphorothioate linkages.

Hammerhead ribozymes are considered to be potential therapeutic agents for HIV virus because of their site-specific RNA cleavage activities. In order to elucidate structure--function relationship and also to hopefully endow ribozymes with resistance to ribonucleases, we firstly synthesized chimeric DNA/RNA ribozymes in which deoxyribonucleotides were substituted for ribonucleotides at noncatalytic residues (stems I, II, and III). Kinetic analysis revealed that (i) DNA in the hybridizing arms (stems I and III) enhanced the chemical cleavage step. (ii) stem II and its loop do not affect its enzymatic activity. Secondly, we introduced deoxyribonucleotides with phosphorothioate linkages to the same regions (stems I, II, and III) in order to test whether such thio-linkages further improve their resistance to nucleases. Kinetic measurements revealed that this chimeric thio-DNA/RNA ribozyme had seven-fold higher cleavage activity (kcat = 27 min-1) than that of the all-RNA ribozyme. In terms of stability in serum, DNA-armed ribozymes gained about 10-fold higher stability in human serum but no increase in stability was recognized in bovine serum, probably because the latter serum mainly contained endoribonucleases that attacked unmodified catalytic-loop regions of these ribozymes. Thirdly, in order to protect them from endoribonucleases, three additional modifications were made at positions U7, U4 and C3 within the internal catalytic-loop region, that succeeded in gaining more than a hundred times greater resistance to nucleases in both serums. More importantly, these catalytic-loop modified ribozymes had the comparable cleavage activity (kcat) to the wild-type ribozyme. Since these chimeric thio-DNA/RNA ribozymes are more resistant to attack by both exonucleases and endoribonucleases than the wild-type all-RNA ribozymes in vivo and since their cleavage activities are not sacrificed, they appear to be better candidates than the wild type for antiviral therapeutic agents

Enhancement of the cleavage rates of DNA-armed hammerhead ribozymes by various divalent metal ions.

In order to characterize structure-function relationships, the kinetic behavior of chimeric RNA/DNA ribozyme was compared with that of all RNA ribozyme. Determined kcat values were proven to represent the chemical-cleavage step and not the product-dissociation step. In agreement with the finding by Dahm and Uhlenbeck [Biochemistry 30, 9464-9469 (1991)], various metal ions, including Co2+ and Ca2+ with the ionic radius of 0.65 and 1.0 A, respectively, could support hammerhead cleavage for both types of ribozyme. Measurements of kinetic parameters in the presence of various divalent metal ions revealed that DNA arms always enhanced kcat values. Chemical-probing data using dimethylsulfate indicated that the catalytic-loop structures of all-RNA and chimeric ribozymes were nearly identical with the exception of enhanced termination of primer extension reactions at C3 in the case of the chimeric ribozyme. These observations and others demonstrate that DNA substitution in non-catalytic-loop regions increases chemical-cleavage activity, possibly with an accompanying very subtle change in the structure

High-resolution NMR study of a synthetic oligoribonucleotide with a tetranucleotide GAGA loop that is a substrate for the cytotoxic protein, ricin.

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond at position A4324 in eukaryotic 28S rRNA. Its substrate domain forms a double helical stem and a 17-base loop that includes the sequence GAGA, the second adenosine of which corresponds to A4324. Recently, studies of mutant RNAs have shown that the four-nucleotide loop, GAGA, can function as a substrate for ricin. To investigate the structure that is recognized by ricin, we studied the properties of a short synthetic substrate, the dodecaribonucleotide r-CUCAGAGAUGAG, which forms a RNA hairpin structure with a GABA loop and a stem of four base pairs. The results of NMR spectroscopy allowed us to construct the solution structure of this oligonucleotide by restrained molecular-dynamic calculations. We found that the stem region exists as an A-form duplex. 5G and 8A in the loop region form an unusual G:A base pair, and the phosphodiester backbone has a turn between 5G and 6A. This turn seems to help ricin to gain access to 6A which is the only site of depurination in the entire structure. The overall structure of the GAGA loop is similar to those of the GAAA and GCAA loops that have been described but that are not recognized by ricin. Therefore, in addition to the adenosine at the depurination site, the neighboring guanosine on the 3' side (7G) may also play a role in the recognition mechanism together with 5G and 8A

Peat water treatment using oxidation and physical filtration system and its performance in reducing iron (Fe), turbidity, and color

This research was conducted to treat peat water using oxidation and physical filtration system. Initially, the characterization of peat water was determined by three parameters, including iron (Fe), turbidity, and color. These three parameters exhibited values that exceeded the water standard limit. This study used two samples consisting of high and low iron content. Both samples were treated using NaClO for the oxidation-catalytic process and Manganese sand for the filter. The trial time is 67 minutes by calculating the value of each parameter every 10 minutes. The result shows different performance in the sample with low iron and high iron. In the sample with low iron (0.32 mg/l), the efficiency of reducing iron is 65.62%, the efficiency of reducing turbidity is 78.95% and the efficiency of reducing color is 78.77%. The results obtained showed differences in samples with high iron (6.75 mg / l). Iron reduction efficiency is 29.17%, turbidity reduction efficiency is 69.05% and color reduction efficiency is 61.32%