Targeted gene integration using the combination of a sequence-specific DNA-binding protein and phiC31 integrase

Study on chromatin regulation patterns of expression vectors in the PhiC31 integration site

The PhiC31 integration system allows for targeted and efficient transgene integration and expression by recognizing pseudo attP sites in mammalian cells and integrating the exogenous genes into the open chromatin regions of active chromatin. In order to investigate the regulatory patterns of efficient gene expression in the open chromatin region of PhiC31 integration, this study utilized Ubiquitous Chromatin Opening Element (UCOE) and activating RNA (saRNA) to modulate the chromatin structure in the promoter region of the PhiC31 integration vector. The study analysed the effects of DNA methylation and nucleosome occupancy changes in the integrated promoter on gene expression levels. The results showed that for the OCT4 promoter with moderate CG density, DNA methylation had a smaller impact on expression compared to changes in nucleosome positioning near the transcription start site, which was crucial for enhancing downstream gene expression. On the other hand, for the SOX2 promoter with high CG density, increased methylation in the CpG island upstream of the transcription start site played a key role in affecting high expression, but the positioning and clustering of nucleosomes also had an important influence. In conclusion, analysing the DNA methylation patterns, nucleosome positioning, and quantity distribution of different promoters can determine whether the PhiC31 integration site possesses the potential to further enhance expression or overcome transgene silencing effects by utilizing chromatin regulatory elements.

Global mapping of binding sites for phic31 integrase in transgenic maden-darby bovine kidney cells using ChIP-seq

Background

ΦC31 integrase, a site-specific recombinase, can efficiently target attB-bearing transgenes to endogenous pseudo attP sites within mammalian genomes. The sequence features of endogenous binding sites will help us to fully understand the site-specific recognition function by ΦC31 integrase. The present study was aimed to uncover the global map of ΦC31 integrase binding sites in bovine cells and analysis the features of these binding sites by comprehensive bioinformatics methods.

Results

In this study, we constructed a ChIP-seq method that can be used to uncover the global binding sites by phiC31 integrase. 6740 potential ΦC31 integrase binding sites were identified. A sequence motif was found that contains inverted repeats and has similarities to wild-type attP site. Using REPEATMASKER, we identified a total of 20,183 repeat-regions distributed in 50 repeat types for the 6740 binding sites. These sites enriched in “regulation of GTPase activity” of in the GO category of biological process and KEGG pathway of signal transmembrane transporter activity.

Conclusion

This study is the first time to uncover the global map of binding sites for ΦC31 integrase using ChIP-sequencing method and analysis the features of these binding sites. This method will help us to fully understand the mechanism of the site-specific integration function by phiC31 integrase and will potentially boost its genetic manipulations in both gene therapy and generation of transgenic animals.

Electronic supplementary material

The online version of this article (10.1186/s41065-018-0079-z) contains supplementary material, which is available to authorized users.

Site-Specific Integration by Recruitment of a Complex of ΦC31 Integrase and Donor DNA to a Target Site by Using a Tandem, Artificial Zinc-Finger Protein

To solve the problem of uncontrolled therapeutic gene integration, which is a critical drawback of retroviral vectors for gene therapy, the integration sites of exogenous genes should be precisely controlled not to perturb endogenous gene expression. To accomplish this, we explored the possibility of site-specific integration using two six-finger artificial zinc-finger proteins (AZPs) tandemly conjugated via a flexible peptide linker (designated "Tandem AZP"). A Tandem AZP in which two AZPs recognize specific 19 bp targets in a donor and acceptor DNA was expected to site-specifically recruit the donor DNA to the acceptor DNA. Thereafter, an exogenously added integrase was expected to integrate the donor DNA into a specific site in the acceptor DNA (as it might be in the human genome). We demonstrated in vitro that in the presence of Tandem AZP, ΦC31 integrase selectively integrated a donor plasmid into a target acceptor plasmid not only at 30 °C (the optimum temperature of the integrase) but also at 37 °C (for future application in humans). We expect that with further improvement of our current system, a combination of Tandem AZP with integrase/recombinase will enable site-specific integration in mammalian cells and provide safer gene therapy technology.