Optimization of Polymerase Chains Reaction Amplification for ssDeoxyribonucleic Acid Library using Capillary Electrophoresis with Laser-induced Fluorescence Detector

Comparing two conventional methods of emulsion PCR and optimizing of Tegosoft-based emulsion PCR

The selection of aptamers represents a promising route in the development of high affinity ligands. In these processes the formation of by-products is a common problem during the PCR-based amplification of complex oligonucleotide libraries. One approach to overcome this drawback is to separate each template oligonucleotide into an individual reaction compartment provided by a droplet. This method, termed emulsion PCR (ePCR), has already emerged to a standard method in sample preparation for 2nd generation sequencing. In this work, we compare different literature protocols that have been developed to generate stable emulsions for ePCR. We investigate different emulsification methods and evaluate the importance of the initial template concentration. We demonstrate that emulsion stability is of utmost importance for the successful inhibition of by-product formation and give an optimized protocol for generation of an emulsified PCR.

Construction and optimization of an efficient amplification method of a random ssDNA library by asymmetric emulsion PCR

Construction of a random ssDNA sublibrary is an important step of the aptamer screening process. The available construction methods include asymmetric PCR, biotin–streptavidin separation, and lambda exonuclease digestions, in which PCR amplification is a key step. The main drawback of PCR amplification is overamplification increasing nonspecific hybridization among different products and by‐products, which may cause the loss of potential high‐quality aptamers, inefficient screening, and even screening failure. Cycle number optimization in PCR amplification is the main way to avoid overamplification but does not fundamentally eliminate the nonspecific hybridization, and the decreased cycle number may lead to insufficient product amounts. Here, we developed a new method, “asymmetric emulsion PCR,” which could overcome the shortcomings of conventional PCR. In asymmetric emulsion PCR, different templates were separated by emulsion particles, allowing single‐molecule PCR, in which each template was separately amplified, and the nonspecific hybridization was avoided. Overamplification or formation of by‐products was not observed. The method is so simple that direct amplification of 40 or more cycles can provide a high‐quality ssDNA library. Therefore, the asymmetric emulsion PCR would improve the screening efficiency of systematic evolution of ligands by exponential enrichment.

Single-primer-limited amplification: a method to generate random single-stranded DNA sub-library for aptamer selection

The amplification of a random single-stranded DNA (ssDNA) library by polymerase chain reaction (PCR) is a key step in each round of aptamer selection by systematic evolution of ligands by exponential enrichment (SELEX), but it can be impeded by the amplification of by-products due to the severely nonspecific hybridizations among various sequences in the PCR system. To amplify a random ssDNA library free from by-products, we developed a novel method termed single-primer-limited amplification (SPLA), which was initiated from the amplification of minus-stranded DNA (msDNA) of an ssDNA library with reverse primer limited to 5-fold molar quantity of the template, followed by the amplification of plus-stranded DNA (psDNA) of the msDNA with forward primer limited to 10-fold molar quantity of the template and recovery of psDNA by gel excision. We found that the amount of by-products increased with the increase of template amount and thermal cycle number. With the optimized template amount and thermal cycle, SPLA could amplify target ssDNA without detectable by-products and nonspecific products and could produce psDNA 16.1 times as much as that by asymmetric PCR. In conclusion, SPLA is a simple and feasible method to efficiently generate a random ssDNA sub-library for aptamer selection.