Revealing an initiation inhibition of RCA and its application in nucleic acid detection.

Rolling circle amplification is a widely used biosensing technique. Although various secondary structures have been employed in RCA, their effects on RCA efficiency have seldom been reported. Here, we find that stems in circular templates can strongly inhibit RCA, and the primer-stem distance is responsible for the inhibition.

A Strategy Employing a TF-Splinting Duplex Nanoswitch to Achieve Single-Step, Enzyme-Free, Signal-On Detection of l-Tryptophan.

Transcription factor (TF)-based metabolite detection mainly depends on TF-regulated gene expression in cells. From TF activation to gene transcription and translation, the signal travels a relatively long way before it is received. Here, we propose a TF-splinting duplex DNA nanoswitch to detect metabolites.

Screening substrate-binding positions by rolling circle amplification suggesting a binding model of Nt.BstNBI.

Nicking endonucleases (NEs) become increasingly attractive for their promising applications in isothermal amplification. Unfortunately, in comparison with their applications, their catalytic mechanism studies have relatively lagged behind due to a paucity of crystal structure information. Nt.

Screening oligonucleotide sequences for silver staining and d-galactose visual detection using RCA silver staining in a tube.

Oligonucleotides were screened for strongly silver-stained repetitive sequences. An 'AG'-clustered purine sequence showed strong staining, and the staining density can be compromised by disrupting the continuity of the 'AG'-clustered sequence. The staining-favored sequence was then employed in rolling circle amplification (RCA) for its product detection.

Repressor logic modules assembled by rolling circle amplification platform to construct a set of logic gates.

Small molecule metabolites and their allosterically regulated repressors play an important role in many gene expression and metabolic disorder processes. These natural sensors, though valuable as good logic switches, have rarely been employed without transcription machinery in cells. Here, two pairs of repressors, which function in opposite ways, were cloned, purified and used to control DNA replication in rolling circle amplification (RCA) in vitro.

Mapping the nicking efficiencies of nickase R.BbvCI for side-specific LNA-substituted substrates using rolling circle amplification.

We used a novel asymmetric cleavage analysis method based on rolling circle amplification (RCA) to determine the effects of LNA modification of substrate on the two subunits of R.BbvCI cleavage. We designed two sets of cleavage circular substrates by using two different ligation strategies and analyzed the single strand cleavage efficiency affected by different modification positions both from the cleaved strands and the uncleaved strands.

Production of dumbbell probe through hairpin cleavage-ligation and increasing RCA sensitivity and specificity by circle to circle amplification.

Dumbbell probe (DP) attracts increasing interests in rolling circle amplification (RCA). A universal DP production method through cleavage-ligation of hairpin was proposed and optimized. The production is characterized by restriction endonuclease (RE)-induced cleavage ends ligation.

Suppression of rolling circle amplification by nucleotide analogs in circular template for three DNA polymerases.

Among wide applications of nucleotide analogs, their roles in enzyme catalytic reactions are significant in both fundamental and medical researches. By introducing analogs into circular templates, we succeeded in determining effects of four analogs on RCA efficiency for three different DNA polymerases. Results showed an obvious suppression effect for 2'-OMeRNA modification, which might be due to the size of the C2'-modified moieties.

Effects of cations on small fragment of DNA polymerase I using a novel FRET assay.

DNA polymerase I (PolI) digested by protease produces a small fragment (SF) containing 5'-3' exonuclease activity. The 5'-3' exonuclease activity of polI cleaves the downstream RNA primer strands during DNA replication in vivo. Previous in vitro studies suggested its capability of cleaving duplex from 5' terminal and a flap-structure-specific endonuclease activity.