Luboš Arnold

M13 and pUC vectors with new unique restriction sites for cloning

Several vectors based on the widely used phage M13 and plasmid pUC were constructed. The vectors contain polylinkers (MCS) for DNA insertions with several new restriction sites (e.g., ApaI, NotI, StuI, SacII). Moreover, the NarI site in the nonessential part of the vector molecule was changed into a BssHII site, so that the NarI site in the MCS became unique.

NMR evidence for helix geometry modifications by a G‐U wobble base pair in the acceptor arm of E. coli tRNAAla

A ribooligonucleotide duplex representing the acceptor stem of E. coli RNA Ala with a G3‐U70 wobble base pair, which is the main identity element for the recognition by the alanine‐tRNA synthetase, has been characterized by 2D‐NMR, as having two sequence variants with a regular Watson‐Crick G3‐C70 and an I3‐U70 wobble pair, respectively. As compared to a regular A‐RNA, the G‐U base pair gives rise to variations of the local helix geometry which are reflected in distinct local chemical shift changes. Structural differences between the duplex possessing an 13‐U70 base pair and the wild‐type G3‐U70 sequence have also been found. The nucleotides in the ubiquitous single‐stranded NCCA terminus display a surprisingly high degree of stacking order, especially between A73, C74, and C75.

The chemical synthesis of biochemically active oligoribonucleotides using dimethylaminomethylene protected purine H-phosphonates

Abstract Dimethylaminomethylene was applied as the protecting group for the exocyclic amino groups of adenosine and guanosine in the automated chemical synthesis of oligoribonucleotides on a polymer bound support. The dimethyl-aminomethylene protecting group can be removed at room temperature under conditions where the concomitant loss of the 2′-protection group can be excluded. The transformation of 2′-O-(t-butyldimethylsilyl)-5′-O-(4,4′-dimethoxytrityl) protected nucleosides to 3′-H-phosphonates yields synthons, well suited for the automated chemical synthesis of oligoribonucleotides. Using these H-phosphonate monomers, a coupling time of two minute: is sufficient to obtain average coupling yields of more than 98 %. Synthesized RNA is recognized as a substrate in an enzymatic reaction, forms the expected secondary structures and is suitable for NMR structural investigations.

The Unusual X-Form DNA in Oligodeoxynucleotides: Dependence of Stability on the Base Sequence and Length

X-form is an unusual double helix of DNA adopted by poly(dA-dT) or (dT-dA)4 at high concentrations of CsF. On the other hand, poly(dA), poly(dT), (dA-dT)4 and most other DNAs do not adopt this conformer. Here we demonstrate that the X-form is strongly destabilized by GC pairs or even minute perturbations of the alternating pyrimidinepurine sequence. For example, the 30-mer d(TATAAT)5, containing five tandem repeats of the Pribnow box, fails to isomerize into the X-form. After (dT-dA)4, the 16-mer (dT-dA)8 is shown to be the second most predisposed oligodeoxynucleotide in the (dT-dA)n series to isomerize into the X-form while the duplex lengths corresponding to n = 3,5,6,7,9,12 and 20 make the X-form unstable even in the strictly alternating (dT-dA)n sequence. Consequently, the (dT-dA)n duplex length is also a crucial factor of the X-form stability on the oligodeoxynucleotide level. We discuss a possibility that the X-form is a solution counterpart of the D-form adopted in dehydrated poly(dA-dT) fibers because properties of these two conformers are remarkably similar in many respects.

Caesium fluoride-induced changes in the c.d. spectra of synthetic DNA fragments

Ten DNA fragments containing self-complementary alternating sequences of adenine and thymine differing in length and the starting nucleotide were studied by c.d. spectroscopy. It was found that d(TATATATA) but not d(ATATATAT), d(TATATA), d(CTATATAG) or (dT-dA)20 isomerized into the unusual X-DNA double helix at molar concentrations of CsF in solution. But in contrast to poly(dA-dT), the octamer (dT-dA)4, isomerized very slowly, at relatively low CsF concentrations and the isomerization was strongly dependent on the octamer concentration. A model is proposed to account for the observed properties of the B-to-X isomerization on the oligomer level.

Interaction of a bZip Oligopeptide Model With Oligodeoxyribonucleotides Modelling DNA Binding Sites. The Effect of Flanking Sequences

A leucine zipper (bZip) binding peptide BP1 was constructed based on the DNA binding sequence of the GCN4 protein, slightly modified to make it more similar to the sequence of other bZip proteins (Jun) with related DNA binding specificity. Self-complementary DNA hexadecanucleotides containing ATF/CRE, AP-1 and C/EPB target sites were used to study peptide-DNA complex formation. Conformation changes in both components that occur on complex formation were studied by circular dichroism (CD) spectroscopy. The results show that the amount of alpha-helix formed in the peptide strongly depends not only on the target site present, but also on the type of the sequence flanking the ATF/CRE target site. Highest amount of the alpha-helix induced in the peptide was observed when homopurine homopyrimidine flanking sequences were present, whereas the presence of alternating sequences, especially of the CA/TG type, showed considerably lower effects. The change in DNA conformation on complex formation was generally small, but also depended on the type of the flanking sequence. It appears that the sequences flanking the target site can considerably modify the ability of the target sequence to bind specifically the bZip peptide, probably by slightly varying the overall DNA conformation.