The Chemistry of PCR Primers: Concept and Application

H-Bond Templated Oligomer Synthesis Using a Covalent Primer

Template-directed synthesis of nucleic acids in the polymerase chain reaction is based on the use of a primer, which is elongated in the replication process. The attachment of a high affinity primer to the end of a template chain has been implemented for templating the synthesis of triazole oligomers. A covalent ester base-pair was used to attach a primer to a mixed sequence template. The resulting primed template has phenol recognition units on the template, which can form noncovalent base-pairs with phosphine oxide monomers via H-bonding, and an alkyne group on the primer, which can react with the azide group on a phosphine oxide monomer. Competition reactions between azides bearing phosphine oxide and phenol recognition groups were used to demonstrate a substantial template effect, due to H-bonding interactions between the phenols on the template and phosphine oxides on the azide. The largest rate acceleration was observed when a phosphine oxide 2-mer was used, because this compound binds to the template with a higher affinity than compounds that can only make one H-bond. The 31P NMR spectrum of the product duplex shows that the H-bonds responsible for the template effect are present in the product, and this result indicates that the covalent ester base-pairs and noncovalent H-bonded base-pairs developed here are geometrically compatible. Following the templated reaction, it is possible to regenerate the template and liberate the copy strand by hydrolysis of the ester base-pair used to attach the primer, thus completing a formal replication cycle.

High allele discrimination in the typing of single nucleotide polymorphisms of miRNA

MicroRNAs (miRNAs) belonging to the same family have similar sequences and are difficult to identify. Herein, we report the reverse transcription-hairpin-probe-polymerase chain reaction (RT-Hpro-PCR) technique, which utilises a reverse transcription (RT) primer containing a 5'-end deoxyribonucleic acid (DNA) tag, to detect miRNAs with similar sequences. This strategy follows a two-step RT-PCR method using 6-7-mer RT-primers with a ~ 10-mer tag sequence at the 5'-end and a probe with a hairpin structure (Hpro), including two C-bulges, attached. The findings demonstrate that the specificity of RT could be increased by shortening the complementary part of the RT primer containing a different base, wherein the PCR could successfully progress with the use of 5'-end DNA tag because of an increase in the length of the hybridised tagged primer. This study shows the potential of RT-Hpro-PCR to precisely detect miRNAs with similar sequences, which could help explore the roles of miRNAs in several biological processes.

PCR-assisted impedimetric biosensor for colibactin-encoding pks genomic island detection in E. coli samples

A fast PCR-assisted impedimetric biosensor was developed for the selective detection of the clbN gene from the polyketide synthase (pks) genomic island in real Escherichia coli samples. This genomic island is responsible for the production of colibactin, a harmful genotoxin that has been associated with colorectal cancer. The experimental protocol consisted of immobilizing the designated forward primer onto an Au electrode surface to create the sensing probe, followed by PCR temperature cycling in blank, positive, and negative DNA controls. Target DNA identification was possible by monitoring changes in the system’s charge transfer resistance values (R_ct) before and after PCR treatment through electrochemical impedance spectroscopy (EIS) analysis. Custom-made, flexible gold electrodes were fabricated using chemical etching optical lithography. A PCR cycle study determined the optimum conditions to be at 6 cycles providing fast results while maintaining a good sensitivity. EIS data for the DNA recognition process demonstrated the successful distinction between target interaction resulting in an increase in resistance to charge transfer (R_ct) percentage change of 176% for the positive DNA control vs. 21% and 20% for the negative and non-DNA-containing controls, respectively. Results showed effective fabrication of a fast, PCR-based electrochemical biosensor for the detection of pks genomic island with a calculated limit of detection of 17 ng/μL.

RT-Hpro-PCR: A MicroRNA Detection System Using a Primer with a DNA Tag

MicroRNAs (miRNAs) are short RNAs that regulate the expression of complementary messenger RNAs and are involved in numerous human diseases. However, current detection techniques lack the sensitivity to detect miRNAs of low abundance. Moreover, at a length of 20-25 bases, miRNAs are too short for the reverse transcription (RT) polymerase chain reaction (PCR). Here we have developed a new, rapid, and simple miRNA detection system utilizing an RT primer containing a DNA tag at the 5'-end to increase the length of the cDNA. This strategy increases the length of the hybridized tagged primer and the complementary template DNA, as well as the melting temperature of the primer⋅template DNA duplex. PCR efficiency is thus increased, thereby enhancing miRNA detection sensitivity.

Fluorescence turn-on hairpin-probe PCR

A new fluorescence turn-on type of PCR monitoring system (Hpro-PCR) using a hairpin probe and a primer having a tag sequence at the 5′ end with the fluorescent molecule 2,7-diamino-1,8-naphthyridine derivative (DANP) has been developed.

Cytosine-bulge-dependent fluorescence quenching for the real-time hairpin primer PCR

The progress of a polymerase chain reaction (PCR) was sensitively monitored based on the increase in fluorescence of N,N'-bis(3-aminopropyl)-2,7-diamino-1,8-naphthyridine, which was covalently anchored on the cytosine bulge directly neighbouring the 5'-T_G-3'/5'-CCA-3' sequence in the hairpin tag at the 5' end of the PCR primer.