Nucleic acids symposium series最新文献

Single long DNA molecule (T4 DNA) in agarose gel was visualized with a fluorescence microscope. We confirmed alternating current electric fields is effective for stretching of single DNA molecule in agarose gel. This stretching phenomenon was observed with wide range of agarose gel concentration from 0.5%(W/V) to 1.5%. From this observation, the presence of agarose gel fiber is essential for this stretching phenomenon. The stretching process of several DNA molecules in gel shows discontinuity, which is never observed in polymer systems. It would be based on topological restriction from gel fibers.

The solution structures of 1:1 complexes of a quinacrine-netropsin hybrid molecule with the self-complementary DNA duplexes, d(CGCGAATTCGCG)2 and d(CGAATTCG)2, have been studied by one- and two-dimensional 1H NMR spectroscopy. The NOE data indicate that the acridine ring of the hybrid intercalates into the 5'-GpA step and its netropsin moiety spans the minor groove of the central AATT region.

Drosophila melanogaster initiator methionine tRNA can adopt an alternative conformation in aqueous solution. In this alternative conformation, the aminoacyl- and the anticodon stems of tRNA are unfolded and then these unfolded regions are used to form extended D- and T-stems, resulting in the formation of two tandemly joined stems and loops. This conformational alternation was recognized then cleaved by the catalytic RNA of Escherichia coli ribonuclease P (M1 RNA). The cleavage occurs within the mature sequence of tRNA. This further processing within mature sequence is called hyperprocessing. During the screening experiments of other conformational changeable D. melanogaster tRNAs by M1 RNA, we incidentally found that M1 RNA also hyperprocessed D. melanogaster 2S rRNA. Kinetic analyses of the hyperprocessing reaction of 2S rRNA by M1 RNA revealed that 2S rRNA could form a homodimer.

A novel strategy for the incorporation of nonnatural amino acids into proteins was developed by using five-base codon-anticodon pairs. The streptavidin mRNA containing five-base codon CGGUA and the chemically aminoacylated tRNA with five-base anticodon UACCG were prepared, and added into E. coli in vitro translation system. As a result, the nonnatural amino acid was successfully incorporated into desired position of the protein. Other five-base codons CGGN1N2, where N1 and N2 indicate one of four nucleotides, were also available for the incorporation of the nonnatural amino acid.

We have modified a previously developed genetic assay system for RNA-polypeptide interactions in a attempt to more readily identify RNA-binding peptides. The first modification involved the design of a "complex" library that would contain a variety of RNA-binding polypeptides. The second modification involved the use of neomycin phosphotransferase (NPT II) as the reporter gene, therefore allowing "selection" of RNA-binding peptides by kanamycin resistance. The improved screening system should allow the identification of peptides that bind to a variety of RNA structures.

By Southern blot analysis of restriction fragments of a chlorovirus CVK2 genomic contig with probes of RNA expressed immediate early in infection, sixteen genes were specifically found to be expressed in the host cells. These genes include those for aminoacyl-tRNA synthetase, nucleolin, ribosomal protein S5, hyaluronan synthase, TFIID etc. All of these transcripts were polyadenylated and most likely expressed in the host nucleus. The structural characteristics of these genes are discussed in connection with their expression mechanism. The biological importance of the gene products in viral infection are also considered.

Non-structural protein 3 (NS3) derived from Hepatitis C virus (HCV) is essential for viral proliferation and has two functional domains; trypsin-like serine protease and helicase. Recently we obtained three types of RNA aptamers (G9-I, -II and -III) bound to NS3 protease domain (delta NS3) by in vitro selection and confirmed their strong inhibition for protease activity. These aptamers have a common sequence, 5'-GA(A/U)UGGGAC-3', forming a loop structure by Mulfold secondary structure modeling. G9-I shows a three-way junction and G9-II and -III have four-way junction structures. To characterize the active structure of these aptamers, we applied modification interference analysis using nucleotide analogs and identified common important nucleotides in these three aptamers.

Acyclic adenosine and thymidine analogs derived from L- and D-threonie were synthesised and incorporated into oligonucleotides by automated protocols using a standard phosphoramidite method. UV melting experiments with thus obtained oligonucleotides showed that incorporation of those acyclic nucleosides did not destabilize the hybrid duplexes and that the stabilities of them are influenced by the stereochemical structures of acyclic analogs. Modification of 3'-end of oligonucleotide with acyclic analogs protected the oligonucleotide against 3'-exonuclease.

The model structure of Escherichia coli AlkA (3-methyladenine-DNA glycosylase II) protein complexed with the double helical DNA is elucidated from X-ray structures of related DNA glycosylase enzymes and mutagenic studies. The free enzyme structure has no difficulty in building the platform to afford the bended and wedge DNA with the flipped out nucleotide. The helix-hairpin-helix motif and the insertion residue L125 in free structure can be located without severe contacts. The alkylated base is surrounded with a variety of aromatic rings, such as W218, W272, Y273 and F18. The aromatic indole ring of tryptophan is a good candidate for forming the stacking with the positively charged base moiety pi-cation interaction). Some hydrophobic residues, such as V128 and L240, also attend to substrate recognition.