Nucleic acids symposium series最新文献

Artificial peptides designed to form alpha-helical, beta-turn, antiparallel beta-sheet and beta-hairpin structures which are among the motifs most frequently found in natural DNA/RNA binding proteins were synthesized and their characteristic features were examined in the presence or absence of double or triple stranded DNA by means of UV melting experiments, CD spectra, SPR measurements. It was revealed that amphiphilic character arising from the specific secondary structures and positive charge in the hydrophobic face of peptides played an important role in the interaction with DNA, and that hybrid duplex and triplex were intensively stabilized by the cationic amphiphilic peptides. It was also found that these peptides could protect dsDNA against DNase 1 digestion. These results indicate that structurally designed amphiphilic peptides synthesized in the present study can be powerful tools for antisense and antigene strategies.

DAPI analogs containing an imidazoline ring or a tetrahydropyrimidine ring have been synthesized to study DNA binding properties. Spectroscopic (absorption, CD, flow dichroism and fluorescence) and viscosity measurements indicate that DAPI analogs interact with DNA both by intercalation and by groove binding. The solution structures of complexes between DAPI analog and DNA oligomers have been characterized by proton NMR spectroscopy.

Upon treatment with LTMP, 5'-O-protected D4T undergoes deprotonation of the vinylic proton (H-3' or H-2'): when 5'-O-silyl derivative was used, the 3'-C-silylated product was formed as a result of C3'-lithiation and subsequent O-->C silyl migration, while deprotonation at the 2'-position led to the formation of an allene derivative. A stannyl version of this reaction was also examined to develop a method for C3'-functionalization of D4T.

The cellular enzyme S-adenosyl-L-homocysteine (SAH) hydrolase has emerged as a target enzyme for the molecular design of anti-viral agents. Recently, SAH hydrolase has been considered as an attractive target in parasite chemotherapy for malaria. We report synthesis of several carbocyclic purine nucleosides and their inhibitory activities against human and malaria recombinant SAH hydrolases.

In this paper, we report the synthesis of hydroxymethylphosphonate alpha-DNAs and related compounds by use of the H-phosphonate method. These modified alpha-DNAs were designed to improve the inherent poor solubility of well-known methylphosphonate alpha-DNAs by introduction of a more hydrophilic hydroxymethylphosphonate function. The hybridization ability of hydroxymethylphosphonate alpha-DNAs was studied. We also report a novel strategy for the synthesis of alpha-thymidine by use of C1'-epimerization. The details of the neighboring effect of various 5'- and 3'-hydroxyl protective groups such as carbamoyl groups on the beta-->alpha conversion will be described.

The highly conserved P7 region is generally believed to act as a major portion of the catalytic site in the Group I intron ribozyme. However, its functions have not been elucidated except for the fact that it specifically binds a cofactor guanosine required for self-splicing reaction. We attempted an in vitro selection experiment to determine the sequence requirements of this region in the mechanism of catalysis by using the Tetrahymena ribozyme. We found that the selected active clones have the secondary structure similar to that of the wild type with few exceptions. However, their primary sequences were not conserved except G264 and C311 that are the major elements of the binding site for the guanosine. Our results suggest that the unique secondary structure of the P7 region is a primary requisite for the catalytic function of this class of ribozymes.

N-Phenylimidazolium triflate and N-methylbenzimidazolium triflate, new imidazole-related compound/triflic acid-complex type of promoters in the phosphoramidite method, has been developed. These reagents are, particularly, useful for internucleotide-bond formation with lowly reactive reactants and have allowed an efficient, high-yield synthesis of oligodeoxyribonucleotides both in a solution phase and on a solid supports.

5-Formyluracil, a major oxidized form of thymine, was incorporated into a predetermined site of one of the leading and lagging template strands of a double-stranded vector, and the DNA replication efficiency and the mutation frequency of 5-formyluracil in simian COS-7 cells were investigated. 5-Formyluracil did not block DNA replication and was weakly mutagenic in simian cells. 5-Formyluracil primarily elicited base substitutions at the modified positions.

We have been investigated the possibility of B-Z transition in ZnTMPyP-DNA interaction based on the observation of spectroscopic data. In this study, we found drastic change in the AFM image of supercoiled plasmid DNA when it was interacted with TMPyPs indicating that the considerable amount of unwinding of double helix or B-Z transition is induced by the drug-DNA interaction. Such phenomena were not observed for other cationic drugs examined.