Rapid and economical multiple base site-directed mutagenesis of double stranded plasmid DNA

This method for the mutagenesis of ds-DNA, utilizing the best features of previously published protocols, incorporates a fragmentation procedure on the plasmid, thermostable enzymes and two transformations in E. coli. Screening of positive clones can begin after about two days. Insertions, deletions and substitutions of up to 50 bp are routinely obtained with 90-95% of clones positive as proven by sequencing. The cost is about one half to one third of equiv-alent commercial procedures.     

Cleavage of nucleotides by Ce4+ and the lanthanide metal complexes

The cleavage of adenosine-5-monophosphate (5-AMP) and guanosine-5-monophosphate (5-GMP) by Ce⁴⁺ and lanthanide complex of 2-carboxyethylgermanium sesquioxide (Ge-132) in acidic and near neutral conditions was investigated by NMR , HPLC and measuring the liberated inorganic phosphate at 37°C and 50°C. The results showed that 5-GMP and 5-AMP was converted to guanine (G), 5-monophosphate (depurination of 5-GMP), ribose (depurination and dephosphorylation of 5-GMP), phosphate and adenine (A), 5-monophosphate (depurination of 5-AMP), ribose (depurination and dephosphorylation of 5-AMP), phosphate respectively by Ce⁴⁺. In presence of lanthanide complexes, 5-GMP and 5-AMP were converted to guanosine (Guo) and phosphate and adenosine (Ado) and phosphate respectively. The mechanism of cleaving 5-GMP and 5-AMP is hydrolytic scission     

Initiation signals for the conversion of single stranded to double stranded DNA forms in the streptococcal plasmid pLS1.

We have characterized a region in the streptococcal plasmid pLS1 located between nucleotides 4103 and 4218 which is a signal involved in the conversion of single stranded intermediates of replication to double stranded plasmid forms. This region has a large axis of dyad symmetry resulting in the formation of a secondary structure as revealed by the location of endonuclease S1-cleavage sites in supercoiled covalently closed circular pLS1 DNA. Deletions affecting this region caused a fivefold reduction in plasmid copy number, plasmid instability and the accumulation of single-stranded DNA intermediates. The conversion signal of pLS1 has homologues in other staphylococcal plasmids, sharing a consensus sequence located in the loop of the signal. Computer assisted analysis showed that the signal detected in pLS1 has a high degree of homology with the complementary strand origin of the Escherichia coli single stranded bacteriophages phi X174 and M13.     

Discrimination of phosphorylated double stranded DNA by naphthalene diimide having zinc(II) dipicolylamine complexes

Discrimination of phosphomonoesters and phosphodiesters of DNA was attempted with naphthalene diimide carrying two zinc-dipicolylamine (Dpa) units (1). The binding constant of 1 for a self-complementary octanucleotide was 1.3 × 10⁶ M⁻¹, while the value for the phosphorylated counterpart was 4.8 × 10⁶ M⁻¹. This fourfold increase in the binding constant seems to stem from higher affinity of the terminal monophosphate over the phosphodiesters of DNA as the fourth ligand for the metal in 1. Likewise, the binding constant of 1 for DNase I-treated calf thymus DNA (average size 200 bp) was twice as large as that for untreated DNA (1 kb), possibly because the terminal phosphate groups are five times abundant in the former. These findings provide a clue to developing a system where phosphomonoesters generated upon DNA nicking are discriminated specifically from intact phosphodiesters.     

Biotinylation of double stranded DNA after transamination

The bisulfite catalyzed transamination of cytidine and cytosine has been reported to be single strand specific, but local thermal instabilities of the DNA double helix, coupled with the extreme sensitivity of the Biotin-Avidin revelation methods, allows the random labelling of cytosines in d.s. DNA to detectable levels for those purposes where the overall label can be very low. We have evaluated the use of this reaction to prepare double stranded DNA molecules containing N4-aminoethyl-cytosine (4-aeC). After this step 4-aeC residues can be conjugated to biotinyl-n-hydroxysuccinimide ester yielding biotinylated DNA. This reaction allows the massive production of biotinylated probes. Labelled DNA can serve as molecular weight marker and positive control in Southern-blots. Moreover it can be useful in the study of DNA-protein interaction and in the isolation of d.s. DNA-binding proteins through chromatographic procedures.     

RecA-double stranded DNA complexes studied by atomic force microscopy.

RecA-double stranded (ds) DNA complexes have been studied by atomic force microscopy (AFM). When the complexes were prepared in the presence of ATP gamma S, fully covered RecA-dsDNA filaments were observed by AFM. When the concentration of RecA proteins was lower, various lengths of filaments were found. The variation of the observed structures may directly reflect the real distribution of the intermediate complexes in the reaction mixture, as the mixture was simply deposited on a mica surface for AFM observation without special fixation or staining. The use of a carbon nanotube (CNT) AFM tip enabled high resolution to reveal the periodicity of RecA-dsDNA filaments. Our observations demonstrated the potential of the AFM method for the structural studies of the RecA-dsDNA complexes, especially their intermediate states.     

Recognition of base pairs by polar peptides in double stranded DNA.

The resonance Raman spectrum of native DNA has been obtained using excitation at 257 nm. In a first part, the spectral lines are assigned to the different nucleotide bases which provide the resonance effect. In a second part, the interactions of DNA with basic peptides (Arginine Methylester, Lysine Methylester, Arginyl-Arginine) are investigated using excitation at 300 nm and 257 nm, which give complementary information about the DNA. Both Arginine Methylester and Arginyl-arginine recognize the A-T base pairs, the first one in the large groove, the second one in the narrow groove of DNA. The DNA-Lysine Methylester interaction is very likely not specific but can take place in the large groove of DNA.     

Cleavage of DNA by model complexes of cytochrome P-450

Thiolate-hemin complexes as chemical models for cytochrome P-450 have been shown to cause cleavage of DNA. The cleavage of DNA to open-circular and linear forms depended on the structure of thiol ligand and the thiol ligand:hemin ratio at pH 7.8. Complete cleavage of DNA was observed by complexes containing thioglycolate ethylester and mercaptoethanol at 400-600 moles excess of thiol ligand to hemin, those containing cysteine, cysteine methylester and cysteine ethylester at 50-200 moles excess, and those containing mercaptopropionylglycine, glutathione, glutathione dimethylester, penta- and nonapeptides at 5-100 moles excess. Inhibition experiments suggested the involvement of active oxygen species in the cleavage of DNA.     

Dynamics of double stranded DNA reptation from bacteriophage.

The dynamics of dsDNA release process from a phage head has been analyzed theoretically. The process was considered as dsDNA reptation through the phage tail. The driving force is assumed to be the decrease of the DNA globule free energy on its releasing from the head in the surrounding medium. The results of the equilibrium theory on an intraphage DNA globule were applied. Three possible sources of friction were examined. The first one is in the inner channel of the tail. The second is the friction of DNA segments in the whole globule volume, which is essential when the globule decondensation is a collective process, at simultaneous moving of all the turns (mechanism 1). The third is the globule friction with the capsid inner surface, that is most important when decondensation proceeds via the globule rotation as a whole spool (mechanism 2). Mechanism 1 would require a lot of time for ejection. Mechanism 2 would lead to different ejection dynamics of short- and long-tailed phages. Comparison of the theoretical results with the published experimental data argues in favor of mechanism 2.     

Cyanine dyes for the detection of double stranded DNA

Twenty three novel cyanine dyes have been applied as fluorescent stains for the detection of nucleic acids in agarose gel electrophoresis. Significant fluorescence enhancement of these dyes in the presence of double stranded DNA was observed. Five dyes offered superior sensitivity in the detection and quantification of DNA, over Ethidium Bromide, the most commonly used nucleic acid stain.     

Cleavage of parallel-stranded DNA duplex by peplomycin metal complexes.

Peplomycin-mediated degradation of parallel-stranded (ps) duplex was investigated. It was found that Co- and Fe-peplomycins degraded ps DNA duplex by 4'-hydrogen abstraction at 5'-GPy (pyrimidine) site in a similar manner to that of antiparallel B-DNA. While the orientation of two strands of ps and B-form DNA duplexes are reversed, peplomycin metal complex can bind to ps DNA duplex to cause oxidative DNA damage. These results indicate that peplomycin metal complex mainly interacts with one strand which is damaged.     

Cleavage of single-stranded DNA by plasmid pT181-encoded RepC protein.

RepC protein encoded by plasmid pT181 has single-stranded endonuclease and topoisomerase-like activities. These activities may be involved in the initiation (and termination) of pT181 replication by a rolling circle mechanism. RepC protein cleaves the bottom strand of DNA within the origin of replication at a single, specific site when the DNA is in the supercoiled or linear (double or single-stranded) form. We have found that RepC protein will also cleave single-stranded DNA at sites other than the origin of replication. We have mapped the secondary cleavage sites on pT181 DNA. When the DNA is in the supercoiled, or linear, double-stranded form, only the primary site within the origin is cleaved. However, when the DNA is present in the single-stranded form, several strong and weak cleavage sites are observed. The DNA sequence at these cleavage sites shows a strong similarity with the primary cleavage site. The presence of Escherichia coli SSB protein inhibited cleavage at all of the secondary nick sites while the primary nick site remained susceptible to cleavage.     

Cleavage of double-strand DNA by linear and triangular trinuclear copper complexes

Two trinuclear copper(II) complexes with linear or triangular metal-binding pendants, [Cu(3)(L(1))](6+) (1) and [Cu(3)(L(2))](6+) (2), have been synthesized and characterized, where L(1)=N,N,N',N'-tetra[(2-pyridyl)methyl]-5,5'-bis(aminomethyl)-2,2'-dipyridyl, L(2)=N,N,N',N',N',N'-hexa[(2-pyridyl)methyl]-1,3,5-tris(aminomethyl)-benzene. Interactions of them with calf thymus DNA have been investigated by measuring the changes in the melting temperature. The obtained DeltaT(m) values indicated that both 1 and 2 exhibited very high affinities towards DNA and strong destabilization of DNA, and were far better than their mononuclear analogues. In the absence of any reducing agent, 1 showed markedly higher nuclease activity than 2, and its hydrolytic process was further clarified in the presence of a few of radical scavengers. The pseudo Michaelis-Menten kinetic parameters (k(cat)) were determined through DNA cleavage versus the concentration of the complexes, to be 6.05 and 0.19 h(-1) for 1 and 2 respectively. Much higher nuclease activity of 1 is probably attributed to its linear multiple metal sites that fit well to the phosphodiester backbone of nucleic acid. DNA cleavage versus the concentration of DNA shows that rate constants rapidly increase at beginning and then markedly decrease with increasing DNA concentration. It is likely that excess substrates would promote intermolecular interaction between a complex and more plasmid DNA(s) and weaken its intramolecular cooperative effect that is propitious to DNA cleavage.