Efficient site-specific integration in CHO-K1 cells using CRISPR/Cas9-modified donors

BACKGROUND

Conventional methods applied to develop recombinant CHO (rCHO) cell line as a predominant host for mammalian protein expression are limited to random integration approaches, which can prolong the process of getting the desired clones for months. CRISPR/Cas9 could be an alternative by mediating site-specific integration into transcriptionally active hot spots, promoting homogenous clones, and shortening the clonal selection process. However, applying this approach for the rCHO cell line development depends on an acceptable integration rate and robust sites for the sustained expression.

METHODS AND RESULTS

In this study, we aimed at improving the rate of GFP reporter integration to the Chromosome 3 (Chr3) pseudo-attP site of the CHO-K1 genome via two strategies; these include the PCR-based donor linearization and increasing local concentration of donor in the vicinity of DSB site by applying the monomeric streptavidin (mSA)-biotin tethering approach. According to the results, compared to the conventional CRISPR-mediated targeting, donor linearization and tethering methods exhibited 1.6- and 2.4-fold improvement in knock-in efficiency; among on-target clones, 84% and 73% were determined to be single copy by the quantitative PCR, respectively. Finally, to evaluate the expression level of the targeted integration, the expression cassette of hrsACE2 as a secretory protein was targeted to the Chr3 pseudo-attP site by applying the established tethering method. The generated cell pool reached 2-fold productivity, as compared to the random integration cell line.

CONCLUSION

Our study suggested reliable strategies for enhancing the CRISPR-mediated integration, introducing Chr3 pseudo-attP site as a potential candidate for the sustained transgene expression, which might be applied to promote the rCHO cell line development.

A comprehensive evaluation of stable expression "hot spot" in the ScltI gene of Chinese hamster ovary cells

The Chinese hamster ovary (CHO) cell is the most widely used biopharmaceutical expression system, but its long-term expression is unstable. This issue can be effectively addressed by site-specific integration of exogenous genes into the genome. Therefore, exogenous protein sites with stable expression in the CHO cell genome must be identified. CRISPR/Cas9 technology was used in this study to integrate various exogenous genes into the ScltI site as a "hot spot" at the CHO-K1 cell genome NW_003614095.1, and the stability and adaptability of exogenous genes expressed at the site were investigated. Flow cytometry sorting technology was used to obtain positive monoclonal cell lines that expressed either intracellular protein green fluorescent protein (EGFP) or secretory protein human serum albumin (HSA). For 60 passages, the positive monoclonal cell lines' cell growth cycles and exogenous protein expression were both observed. The results demonstrated that integrating the gene encoding exogenous proteins into the ScltI site had no effect on cell growth. The fluorescence intensity of EGFP was similar after 60 passages, and the expression of HSA increased slightly. Additionally, the super-monomeric protein VWF hydrolase (ADAMTS13) (190 kDa), human coagulation factor VII (FVII) (55 kDa), and interferon α2b (12 kDa) were integrated into the ScltI site for expression. In conclusion, the site located in the first exon of the ScltI gene within the CHO-K1 cell genome NW_003614095.1 is an ideal "hot spot" for the stable expression of various exogenous proteins. KEY POINTS: • The site-specific integration strategy of an exogenous gene in CHO cells was established for the ScltI site. • The genes for EGFP and HSA were site-directed integrated and stably expressed at the ScltI site. • The ScltI site fulfills the expression of exogenous proteins of different molecular weight sizes (15-190 kDa).

Cell Line Development Using Targeted Gene Integration into MAR-Rich Landing Pads for Stable Expression of Transgenes

Integration of a gene of interest (GOI) into the genome of mammalian cells is the first step of cell line development campaigns for the production of biotherapeutics. Besides random integration methods, targeted gene integration approaches have emerged as promising tools over the last few years. In addition to reducing heterogeneity within a pool of recombinant transfectants, this process can also facilitate shorter timelines of the current cell line development process. Herein, we describe protocols for generating host cell lines carrying matrix attachment region (MAR)-rich landing pads (LPs), including BxB1 recombination sites. These LP-containing cell lines allow for site-specific and simultaneous integration of multiple GOIs. The resulting transgene-expressing stable recombinant clones can be used for the production of mono- or multispecific antibodies.

Site-specific integration as an efficient method for production of recombinant human hyaluronidase PH20 in semi-adherent cells

PH20 is a hyaluronidase enzyme that can hydrolyze the glycosidic bond in hyaluronic acid as the major proteoglycan found in extracellular matrices. In the present study, we constructed and characterized two donor plasmids, one of them with one and the second with two PH20 expression cassettes. The expression vectors were site specifically integrated into the genome of HEK293T cells using PhiC31 integrase system to develop HEK293T stable cell lines secreting His-tagged recombinant human PH20 (rhPH20) in the culture supernatant. The produced rhPH20 was quantified using ELISA and turbidimetric assay tests, and its catalytic activity was also assessed by treating the mouse cumulus-oocyte complexes. Our results showed that the secreted rhPH20 in the culture supernatant had the specific activity of 16,660 IU/mg and the recombinant enzyme was able to remove the cumulus cells from oocytes. The results also indicated that phiC31 enzyme inserted the PH20-expressing donor vectors into the specific pseudo attP sites including 10q21.2 and 20q11.22 in the genome of the target cells with different copy numbers. Taken together, our findings demonstrate that PhiC31 integrase system is able to be applied as a robust tool for efficient production and secretion of soluble and active rhPH20 by HEK293T cells as a semi-adherent human cell line. KEY POINTS: • Efficient production of human recombinant PH20 in a semi-adherent human cell line • Successful application of PhiC31 integrase system for generation of stable recombinant clones • Use of a human cell line for expression of a recombinant human protein due to complex and efficient post-translational modifications and protein folding.

Multigene Transformation Through Cre-lox Mediated Site-Specific Integration in Rice

Plant transformation with multiple genes is a major challenge, rendering multi-trait engineering extremely difficult in crop plants. One of the hurdles in multigene transformation is the uncontrolled integration process that leads to low quality transgenic lines that are unsuitable for practical application. Recombinase-mediated site-specific integration has been tested and validated for developing high quality transgenic lines expressing one, two, or multiple genes. Of the numerous recombinase systems tested, Cre-lox and FLP-FRT show high efficiency in plants. Recently, Cre-lox system was successfully used to stack a set of 3 constitutive, 1 heat-induced, and 1 cold-induced gene. A number of transgenic lines were obtained through a relatively small effort, and the resulting transgenic lines all expressed the genes properly as determined by their promoter-specificity. Here, a method of Cre-lox mediated stacking of a multigene construct is described using rice as a model crop.

Targeted integration into pseudo attP sites of CHO cells using CRISPR/Cas9

Chinese hamster ovary (CHO) cells are regarded as a prominent host for manufacturing therapeutic proteins. Although conventional strategies for generating recombinant proteins in CHO cells depend on the random integration of a gene of interest (GOI), these established techniques occasionally result in genetically heterogeneous cell lines, which causes diminished expression of the recombinant proteins in the long run. Production instability can be reduced by SSI and creates stable cell lines with a consistent expression of the GOI. In this experiment, we demonstrate the targeted incorporation of a reporter cassette in two PhiC31 pseudo attP sites of CHO cells exploiting the homology-directed repair (HDR) generated by the CRISPR/Cas9 platform. Genes encoding GFP and puromycin resistance marker were precisely inserted into these loci via CRISPR/Cas9. Stable cell lines were suitably produced following antibiotic selection. Junction PCR and fluorescence assay determined targeted integration and expression homogeneity of the reporter cassette, respectively. Taken together, our results indicate the possibility of these two PhiC31 pseudo attP sites as the target sites for site-specific integration of a transgene mediated by CRISPR/Cas9. Furthermore, higher knock-in efficiency and expression homogeneity was observed in the pseudo attP site associated with chromosome 6 compared to the pseudo attP site from chromosome 3.

FLP-Mediated Site-Specific Gene Integration in Rice

Enabling precise gene integration is important for installing traits in the plants. One of the practical methods of achieving precise gene integration is by using the yeast FLP-FRT recombination system that is efficient in directing DNA integration into the "engineered" genomic sites. The critical parameters of this method include the use of the thermostable version of FLP protein and the promoter trap design to select site-specific integration clones. The resulting transgenic plants display stable expression that is transmitted to the progeny. Therefore, FLP-mediated site-specific integration method could be used for trait engineering in the crop plants or testing gene functions in the model plants.

Rapid development of stable transgene CHO cell lines by CRISPR/Cas9-mediated site-specific integration into C12orf35

Chinese hamster ovary (CHO) cells are the most widely used mammalian hosts for recombinant protein production. However, by conventional random integration strategy, development of a high-expressing and stable recombinant CHO cell line has always been a difficult task due to the heterogenic insertion and its caused requirement of multiple rounds of selection. Site-specific integration of transgenes into CHO hot spots is an ideal strategy to overcome these challenges since it can generate isogenic cell lines with consistent productivity and stability. In this study, we investigated three sites with potential high transcriptional activities: C12orf35, HPRT, and GRIK1, to determine the possible transcriptional hot spots in CHO cells, and further construct a reliable site-specific integration strategy to develop recombinant cell lines efficiently. Genes encoding representative proteins mCherry and anti-PD1 monoclonal antibody were targeted into these three loci respectively through CRISPR/Cas9 technology. Stable cell lines were generated successfully after a single round of selection. In comparison with a random integration control, all the targeted integration cell lines showed higher productivity, among which C12orf35 locus was the most advantageous in both productivity and cell line stability. Binding affinity and N-glycan analysis of the antibody revealed that all batches of product were of similar quality independent on integrated sites. Deep sequencing demonstrated that there was low level of off-target mutations caused by CRISPR/Cas9, but none of them contributed to the development process of transgene cell lines. Our results demonstrated the feasibility of C12orf35 as the target site for exogenous gene integration, and strongly suggested that C12orf35 targeted integration mediated by CRISPR/Cas9 is a reliable strategy for the rapid development of recombinant CHO cell lines.

Effect of gene order in DNA constructs on gene expression upon integration into plant genome

Several plant biotechnology applications are based on the expression of multiple genes located on a single transformation vector. The principles of stable expression of foreign genes in plant cells include integration of full-length gene fragments consisting of promoter and transcription terminator sequences, and avoiding converging orientation of the gene transcriptional direction. Therefore, investigators usually generate constructs in which genes are assembled in the same orientation. However, no specific information is available on the effect of the order in which genes should be assembled in the construct to support optimum expression of each gene upon integration in the genome. While many factors, including genomic position and the integration structure, could affect gene expression, the investigators judiciously design DNA constructs to avoid glitches. However, the gene order in a multigene assembly remains an open question. This study addressed the effect of gene order in the DNA construct on gene expression in rice using a simple design of two genes placed in two possible orders with respect to the genomic context. Transgenic rice lines containing green fluorescent protein (GFP) and β-glucuronidase (GUS) genes in two distinct orders were developed by Cre-lox-mediated site-specific integration. Gene expression analysis of transgenic lines showed that both genes were expressed at similar levels in either orientation, and different transgenic lines expressed each gene within 1-2× range. Thus, no significant effect of the gene order on gene expression was found in the transformed rice lines containing precise site-specific integrations and stable gene expression in plant cells could be obtained with altered gene orders. Therefore, gene orientation and integration structures are more important factors governing gene expression than gene orders in the genomic context.

AAV-iRFP labelling of human mesenchymal stem cells for near-infrared fluorescence imaging

Near-IR fluorescence (NIRF) imaging is a new technology using IR fluorescent protein (iRFP) gene labelling and is potentially useful for in vivo applications. In the present study, we expressed iRFP and the TNF-related apoptosis inducing ligand gene in mesenchymal stem cells (MSCs) using adeno-associated virus (AAV) and showed that iRFP-labelled MSCs can be detected by fluorescence microscopy. We injected mice with MSCs labelled with AAV-iRFP, which we were then able to detect by whole-animal NIRF imaging. Our technique provides a visualizable, convenient and sensitive platform for research on tracking the fate of transplanted MSC cells in vivo.

Progress of targeted genome modification approaches in higher plants

Transgene integration in plants is based on illegitimate recombination between non-homologous sequences. The low control of integration site and number of (trans/cis)gene copies might have negative consequences on the expression of transferred genes and their insertion within endogenous coding sequences. The first experiments conducted to use precise homologous recombination for gene integration commenced soon after the first demonstration that transgenic plants could be produced. Modern transgene targeting categories used in plant biology are: (a) homologous recombination-dependent gene targeting; (b) recombinase-mediated site-specific gene integration; (c) oligonucleotide-directed mutagenesis; (d) nuclease-mediated site-specific genome modifications. New tools enable precise gene replacement or stacking with exogenous sequences and targeted mutagenesis of endogeneous sequences. The possibility to engineer chimeric designer nucleases, which are able to target virtually any genomic site, and use them for inducing double-strand breaks in host DNA create new opportunities for both applied plant breeding and functional genomics. CRISPR is the most recent technology available for precise genome editing. Its rapid adoption in biological research is based on its inherent simplicity and efficacy. Its utilization, however, depends on available sequence information, especially for genome-wide analysis. We will review the approaches used for genome modification, specifically those for affecting gene integration and modification in higher plants. For each approach, the advantages and limitations will be noted. We also will speculate on how their actual commercial development and implementation in plant breeding will be affected by governmental regulations.

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

PhiC31 integrase-based vectors can integrate therapeutic genes selectively into attP or pseudo-attP sites in genomes, but considerable numbers of pseudo-attP sites in human genomes exist inside endogenous gene-coding regions. To avoid endogenous gene disruptions, we aimed to enhance the integration site-specificity of the phiC31 integrase-based vector using a sequence-specific DNA-binding protein containing Gal4 and LexA DNA-binding motifs. The dual DNA-binding protein was designed to tether the UAS-containing donor vector to the target sequence, the LexA operator, and restrict integration to sites close to the LexA operator. To analyze the site-specificity in chromosomal integration, a human cell line having LexA operators on the genome was established, and the cell line was transfected with donor vectors expressing the DNA-binding protein and the phiC31 integrase expression vector (helper vector). Quantitative PCR indicated that integration around the LexA operator was 26-fold higher with the UAS-containing donor vector than with the control. Sequence analysis confirmed that the integration occurred around the LexA operator. The dual DNA-binding protein-based targeted integration strategy developed herein would allow safer and more reliable genetic manipulations for various applications, including gene and cell therapies.

Targeted genome correction by a single adenoviral vector simultaneously carrying an inducible zinc finger nuclease and a donor template

Zinc finger nuclease (ZFN) technology, which can be used to induce targeted genome correction in the presence of a DNA donor template, is becoming an attractive strategy for treating monogenic diseases. This strategy requires efficient delivery of ZFN and donor template into cells, ideally, in a single viral vector to achieve efficient genome editing and to avoid unwanted mutagenesis. In this study, we successfully produced a single adenoviral (Ad) vector with high titer that carried a ZFN expression cassette and a donor template simultaneously. We then demonstrated that this single Ad system could mediate efficient site-specific genome correction in vitro and ex vivo. The gene correction efficiency of the single Ad was significantly higher than that of the double Ad system. This novel vector will be a promising ZFN and donor delivery system for treatment of monogenic diseases.

In vivo site-specific integration of transgene in silkworm via PhiC31 integrase-mediated cassette exchange

Current techniques for genetic engineering of the silkworm Bombyx mori genome utilize transposable elements, which result in positional effects and insertional mutagenesis through random insertion of exogenous DNA. New methods for introducing transgenes at specific positions are therefore needed to overcome the limitations of transposon-based strategies. Although site-specific recombination systems have proven powerful tools for genome manipulation in many organisms, their use has not yet been well established for the integration of transgenes in the silkworm. We describe a method for integrating target genes at pre-defined chromosomal sites in the silkworm via phiC31/att site-specific recombination system-mediated cassette exchange. Successful recombinase-mediated cassette exchange (RMCE) was observed in the two transgenic target strains with an estimated transformation efficiency of 3.84-7.01%. Our results suggest that RMCE events between chromosomal attP/attP target sites and incoming attB/attB sites were more frequent than those in the reciprocal direction. This is the first report of in vivo RMCE via phiC31 integrase in the silkworm, and thus represents a key step toward establishing genome manipulation technologies in silkworms and other lepidopteran species.