A model for DNA polymerase translocation: worm-like movement of DNA within the binding cleft

AbstractOn the basis of recent results, we propose a model for DNA polymerase translocation along DNA. Human immunodeficiency virus reverse transcriptase is taken as an example. According to the model, movement of the enzyme is the result of transition of the enzyme-bound DNA from the A- to B-form which is accompanied by lengthening of DNA within the binding channel. The driving force of this transition is the increase in water accessibility to the DNA-binding cleft after dNTP binding. dNTP hydrolysis proceeding during the following chemical step supplies the energy for the reverse B → A transition of DNA. Translocation is considered to be an integral part of the stage of conformational change preceding catalysis and can be described as a worm-like movement of DNA within the DNA-binding cleft

Proximity extension of circular DNA aptamers with real-time protein detection

Multivalent circular aptamers or ‘captamers’ have recently been introduced through the merger of aptameric recognition functions with the basic principles of DNA nanotechnology. Aptamers have strong utility as protein-binding motifs for diagnostic applications, where their ease of discovery, thermal stability and low cost make them ideal components for incorporation into targeted protein assays. Here we report upon a property specific to circular DNA aptamers: their intrinsic compatibility with a highly sensitive protein detection method termed the ‘proximity extension’ assay. The circular DNA architecture facilitates the integration of multiple functional elements into a single molecule: aptameric target recognition, nucleic acid hybridization specificity and rolling circle amplification. Successful exploitation of these properties is demonstrated for the molecular analysis of thrombin, with the assay delivering a detection limit nearly three orders of magnitude below the dissociation constants of the two contributing aptamer–thrombin interactions. Real-time signal amplification and detection under isothermal conditions points towards potential clinical applications, with both fluorescent and bioelectronic methods of detection achieved. This application elaborates the pleiotropic properties of circular DNA aptamers beyond the stability, potency and multitargeting characteristics described earlier

Ferrocene conjugates of dUTP for enzymatic redox labelling of DNA

Two ferrocene-labelled analogues of dTTP, 5-(3-ferrocenecarboxamidopropenyl-1) 2'-deoxyuridine 5'-triphosphate (Fc1-dUTP) and 5-(3-ferroceneacet-amidopropenyl-1) 2'-deoxyuridine 5'-triphosphate (Fc2-dUTP) have been produced to demonstrate the incorporation of redox labels into DNA by polymerases. Cyclic voltammetry indicates that the ferrocenyl moieties display reversible redox behaviour in aqueous buffer with E1/2 values of 398 (Fc1-dUTP) and 260 mV (Fc2-dUTP) versus Ag/AgCl. Primer extension by the proofreading enzymes Klenow fragment and T4 DNA polymerase shows that Fc1-dUTP is efficiently incorporated into DNA during synthesis, including incorporation of two successive modified nucleotides. Production of a 998 bp amplicon by Tth DNA polymerase demonstrates that Fc1-dUTP is also a satisfactory substrate for PCR. Despite its structural similarity, Fc2-dUTP acts predominantly as a terminator with the polymerases employed here. UV melting analysis of a 37mer duplex containing five Fc1-dU residues reveals that the labelled nucleotide introduces only a modest helix destabilisation, with Tm = 71 versus 75°C for the corresponding natural construct. Modified DNA is detected at femtomole levels using a HPLC system with a coulometric detector. The availability of simple and effective enzymatic labelling strategies should promote the further development of electrochemical detection in nucleic acid analysis.</p

Multipotential electrochemical detection of primer extension reactions on DNA self-assembled monolayers

Electroactive nucleoside triphosphates ("electrotides") have been incorporated into primers by DNA polymerase and detected on oligonucleotide surface-assembled monolayers. Four electrotides bearing three different electroactive moieties-ferrocene, vinylferrocene, and anthraquinone are detected in four alternative formats.</p