Cloning of glyceraldehyde-3-phosphate dehydrogenase from an Antarctic psychrophilic bacterium by inverse and splinkerette PCR

A splinkerette PCR-based genome walking technique for the identification of transgene integration sites in CHO cells

Identification of recombinant gene integrations sites in the Chinese hamster ovary (CHO) cell genome is increasingly important to assure monoclonality. While next-generation sequencing (NGS) is commonly used for the gene integration site analysis, it is a time-consuming and costly technique as it analyzes the entire genome. Hence, simple, easy, and inexpensive methods to analyze transgene insertion sites are necessary. To selectively capture the integration site of transgene in the CHO genome, we applied splinkerette-PCR (spPCR). SpPCR is an adaptor ligation-based method using splinkerette adaptors that have a stable hairpin loop. Restriction enzymes with high frequencies in the CHO genome were chosen using a Python script and used for the in vitro spPCR assay development. After testing on two CHO housekeeping genes with known loci, the spPCR-based genome walking technique was successfully applied to recombinant CHO cells to identify the transgene integration site. Finally, the comparison with NGS methods exhibited that the time and cost required for the analysis can be substantially reduced. Taken together, the established technique would aid the stable cell line development process by providing a rapid and cost-effective method for transgene integration site analysis.

Retrieval of full-length functional genes using subtractive hybridization magnetic bead capture

Numerous gene-specific PCR methods have been developed for the cultivation-independent discovery of novel genes from complex environmental DNA samples. The recovery of full-length genes is, however, technically challenging. Here, we present an efficient and relatively simple approach that combines magnetic bead capture with subtractive hybridization for the rapid and direct recovery of full-length target ORFs. When compared with other PCR-based techniques, a higher degree of specificity is achieved through the use of larger gene fragments during hybridization followed by several high-stringency washes. Together with the recent advances in environmental nucleic acid extraction techniques, this approach should allow for the further exploration of the metagenomic sequence space.