Incoming nucleotide binds to Klenow ternary complex leading to stable physical sequestration of preceding dNTP on DNA

Stable complexes formed by HIV-1 reverse transcriptase at distinct positions on the primer-template controlled by binding deoxynucleoside triphosphates or foscarnet

Binding of the next complementary dNTP by the binary complex containing HIV-1 reverse transcriptase (RT) and primer-template induces conformational changes that have been implicated in catalytic function of RT. We have used DNase I footprinting, gel electrophoretic mobility shift, and exonuclease protection assays to characterize the interactions between HIV-1 RT and chain-terminated primer-template in the absence and presence of various ligands. Distinguishable stable complexes were formed in the presence of foscarnet (an analog of pyrophosphate), the dNTP complementary to the first (+1) templating nucleotide or the dNTP complementary to the second (+2) templating nucleotide. The position of HIV-1 RT on the primer-template in each of these complexes is different. RT is located upstream in the foscarnet complex, relative to the +1 complex, and downstream in the +2 complex. These results suggest that HIV-1 RT can translocate along the primer-template in the absence of phosphodiester bond formation. The ability to form a specific foscarnet complex might explain the inhibitory properties of this compound. The ability to recognize the second templating nucleotide has implications for nucleotide misincorporation.

Direct electrical detection of DNA synthesis

Rapid, sequence-specific DNA detection is essential for applications in medical diagnostics and genetic screening. Electrical biosensors that use immobilized nucleic acids are especially promising in these applications because of their potential for miniaturization and automation. Current DNA detection methods based on sequencing by synthesis rely on optical readouts; however, a direct electrical detection method for this technique is not available. We report here an approach for direct electrical detection of enzymatically catalyzed DNA synthesis by induced surface charge perturbation. We discovered that incorporation of a complementary deoxynucleotide (dNTP) into a self-primed single-stranded DNA attached to the surface of a gold electrode evokes an electrode surface charge perturbation. This event can be detected as a transient current by a voltage-clamp amplifier. Based on current understanding of polarizable interfaces, we propose that the electrode detects proton removal from the 3'-hydroxyl group of the DNA molecule during phosphodiester bond formation.

Klenow exo-, as opposed to exo+, traverses through G-G:C triplex by melting G-G base pairs

G-G base-paired hairpin DNA structures on template strands offer potential "road-blocks" to a traversing polymerase. Klenow polymerase (exo+) pauses while replicating through G-G base-paired hairpin DNA due to the generation of G-G:C triplex. However, exonuclease-deficient Klenow traverses through de novo generated G-G:C triplexes leading to full-length C:G duplexes. Alleviation of such road-blocks by exo- Klenow ensues faster at lower Mg2+, a kinetic effect consistent with the role of Mg2+ in stabilizing G-G:C triplex fold. The ability of exonuclease-deficient polymerase to go past the de novo generated G-G:C triplexes suggests that the "idling" of exo+ polymerase at G-G road-block is due to the reiterative polymerase/exonuclease action. The full-length replication product carrying a C(n)-G(n) duplex at one end is further "expanded" by exo- Klenow through C-strand "slippage" leading to the generation of C+-G:C triplex, which is exemplified by the premature arrest of the same at low pH that further stabilizes the C+-G:C triplex.