Identification of the safe harbor locus, AAVS1, from porcine genome and site-specific integration of recombinase-mediated cassette exchange system in porcine fibroblasts using CRISPR/Cas9

Gene integration at site-specific loci , such as safe harbor regions for s table expression via transgenesis , is a critical approach for understanding the function of a gene in cells or animals. The AAVS1 locus is a well-known safe harbor site for human and mouse studies. In the present study, we found an AAVS1-like sequence in the porcine genome using the UCSC Genome Browser and designed TALEN and CRISPR/Cas9 to target AAVS1. The efficiency of CRISPR/Cas9 for targeting the AAVS1 locus in porcine cells was superior to that of TALEN. An AAVS1-targeting donor vector containing GFP was designed and cloned. We added a loxP-lox2272 cassette sequence to the donor vector for further exchange of various transgenes in the AAVS1-targeted cell line. The donor vector and CRISPR/Cas9 components targeting AAVS1 were transfected into a porcine fibroblast cell line. Targeted cells of CRISPR/Cas9-mediated homologous recombination were identified by antibiotic selection. Gene knock-in at the AAVS1 locus was confirmed by PCR analysis. To induce recombinase-mediated cassette exchange (RMCE), another donor vector containing the loxP-lox2272 cassette and inducible (Tet-on) Cre recombinase was cloned. The Cre-donor vector was transfected into the AAVS1-targeted cell line, and RMCE was induced by adding doxycycline to the culture medium. RMCE in porcine fibroblasts was confirmed using PCR analysis. In conclusion, gene targeting at the AAVS1 locus and RMCE in porcine fibroblasts was successful. This technology will be useful for future porcine transgenesis studies and the generation of stable transgenic pigs.

CRISPR/Cas13d mediated efficient KDM5B mRNA knockdown in porcine cells and parthenogenetic embryos

An efficient mRNA knockdown strategy is needed to explore gene function in cells and embryos, especially to understand the process of maternal mRNA decay during early embryo development. Cas13, a novel RNA-targeting CRISPR effector protein, could bind and cleave complementary single-strand RNA, which has been employed for mRNA knockdown in mouse and human cells and RNA-virus interference in plants. Cas13 has not yet been reported to be used in pigs. In the current study, we explored the feasibility of CRISPR/Cas13d-mediated endogenous RNA knockdown in pigs. KDM5B, a histone demethylase of H3K4me3, was down-regulated at the transcriptional level by 50% with CRISPR/Cas13d in porcine fibroblast cells. Knockdown of KDM5B induced H3K4me3 expression and decreased the abundance of H3K27me3, H3K9me3, H3K4ac, H4K8ac, and H4K12ac. These changes affected cell proliferation and cell cycle. Furthermore, stable integration of the CRISPR/Cas13d system into the porcine genome resulted in the continuous expression of Cas13d and persistent knockdown of KDM5B. Finally, the RNA-targeting potential of Cas13d was further validated in porcine parthenogenetic embryos. By micro-injection of Cas13d mRNA and gRNA targeting KDM5B into porcine oocytes, the expression of KDM5B was down-regulated, the abundance of H3K4me3 increased as expected, and the expression of embryonic development-related genes was changed accordingly. These results indicate that CRISPR/Cas13d provides an easily programmable platform for spatiotemporal transcriptional manipulation in pigs.

Practical Approaches for Knock-Out Gene Editing in Pigs

Pigs are an important resource for meat production and serve as a model for human diseases. Due to their physiological and anatomical similarities to humans, these animals can recapitulate symptoms of human diseases, becoming an effective model for biomedical research. Although, in the past pig have not been widely used partially because of the difficulty in genetic modification; nowadays, with the new revolutionary technology of programmable nucleases, and fundamentally of the CRISPR-Cas9 systems, it is possible for the first time to precisely modify the porcine genome as never before. To this purpose, it is necessary to introduce the system into early stage zygotes or to edit cells followed by somatic cell nuclear transfer. In this review, several strategies for pig knock-out gene editing, using the CRISPR-Cas9 system, will be summarized, as well as genotyping methods and different delivery techniques to introduce these tools into the embryos. Finally, the best approaches to produce homogeneous, biallelic edited animals will be discussed.

In vitro Electroporation in the Presence of CRISPR/Cas9 Reagents as a Safe and Effective Method for Producing Biallelic Knock-Out Porcine Embryos

The production of genetically modified (GM) pigs is considered valuable in biomedical research for the development of model animals for various diseases and pigs with resistance against viral infection. The porcine genome may be modified using several methods, such as somatic cell nuclear transfer (SCNT) using GM cells as the SCNT donor, direct injection of the transgene or the genome editing components (GEC) into fertilized eggs referred to as zygotes, the in vitro electroporation (EP) of the zygotes in the presence of GECs, viral infection using retroviruses, injection of the GECs into the SCNT-treated embryos, and the in vitro EP of the SCNT-treated embryos in the presence of GECs. In our previous study, we administered a cytoplasmic injection of CRISPR/Cas9-based GEC into parthenogenetically-activated porcine oocytes (referred to as parthenotes) and observed that these oocytes comprised a mixture of genome-edited and genome-unedited cells, referred to as the “mosaic”. In contrast, when in vitro EP of the SCNT-treated embryos in the presence of GEC was performed, bi-allelic knock out (KO) of the target gene was detected in most oocytes (82%; 9/11). The production of bi-allelic KO piglets is particularly beneficial for investigating GM domestic animals as it does not require further breeding trials to obtain bi-allelic KO individuals, which would otherwise be a time-consuming and laborious task. In this context, the present study was aimed to confirm the efficiency of in vitro EP in producing bi-allelic KO porcine embryos without multiple breeding trials, for which parthenotes were subjected to EP in the presence of a ribonucleoprotein containing Cas9 protein and single-guide RNA (targeted toward GGTA1). The treated embryos were cultured until they transformed into blastocysts. The genomic DNA isolated from these blastocysts was used for molecular biology analysis to detect the possible insertion and deletion of sequences (indels) at the GGTA1 locus. Among the 32 blastocysts obtained, 21 (66%) were observed to be the bi-allelic KO ones. The remaining embryos either had a normal phenotype (25%; 8/32) or mosaic mutations (9%; 3/32). These findings confirm the efficiency of in vitro EP in producing bi-allelic KO porcine embryos.

In vitro Electroporation in the Presence of CRISPR/Cas9 Reagents as a Safe and Effective Method for Producing Biallelic Knock-Out Porcine Embryos

The production of genetically modified (GM) pigs is considered valuable in biomedical research for the development of model animals for various diseases and pigs with resistance against viral infection. The porcine genome may be modified using several methods, such as somatic cell nuclear transfer (SCNT) using GM cells as the SCNT donor, direct injection of the transgene or the genome editing components (GEC) into fertilized eggs referred to as zygotes, the in vitro electroporation (EP) of the zygotes in the presence of GECs, viral infection using retroviruses, injection of the GECs into the SCNT-treated embryos, and the in vitro EP of the SCNT-treated embryos in the presence of GECs. In our previous study, we administered a cytoplasmic injection of CRISPR/Cas9-based GEC into parthenogenetically-activated porcine oocytes (referred to as parthenotes) and observed that these oocytes comprised a mixture of genome-edited and genome-unedited cells, referred to as the “mosaic”. In contrast, when in vitro EP of the SCNT-treated embryos in the presence of GEC was performed, bi-allelic knock out (KO) of the target gene was detected in most oocytes (82%; 9/11). The production of bi-allelic KO piglets is particularly beneficial for investigating GM domestic animals as it does not require further breeding trials to obtain bi-allelic KO individuals, which would otherwise be a time-consuming and laborious task. In this context, the present study was aimed to confirm the efficiency of in vitro EP in producing bi-allelic KO porcine embryos without multiple breeding trials, for which parthenotes were subjected to EP in the presence of a ribonucleoprotein containing Cas9 protein and single-guide RNA (targeted toward GGTA1). The treated embryos were cultured until they transformed into blastocysts. The genomic DNA isolated from these blastocysts was used for molecular biology analysis to detect the possible insertion and deletion of sequences (indels) at the GGTA1 locus. Among the 32 blastocysts obtained, 21 (66%) were observed to be the bi-allelic KO ones. The remaining embryos either had a normal phenotype (25%; 8/32) or mosaic mutations (9%; 3/32). These findings confirm the efficiency of in vitro EP in producing bi-allelic KO porcine embryos.

Profiling Novel Alternative Splicing within Multiple Tissues Provides Useful Insights into Porcine Genome Annotation

Alternative splicing (AS) is a process during gene expression that results in a single gene coding for different protein variants. AS contributes to transcriptome and proteome diversity. In order to characterize AS in pigs, genome-wide transcripts and AS events were detected using RNA sequencing of 34 different tissues in Duroc pigs. In total, 138,403 AS events and 29,270 expressed genes were identified. An alternative donor site was the most common AS form and accounted for 44% of the total AS events. The percentage of the other three AS forms (exon skipping, alternative acceptor site, and intron retention) was approximately 19%. The results showed that the most common AS events involving alternative donor sites could produce different transcripts or proteins that affect the biological processes. The expression of genes with tissue-specific AS events showed that gene functions were consistent with tissue functions. AS increased proteome diversity and resulted in novel proteins that gained or lost important functional domains. In summary, these findings extend porcine genome annotation and highlight roles that AS could play in determining tissue identity.

In-Depth Analysis Reveals Production of Circular RNAs from Non-Coding Sequences

The sequencing of total RNA depleted for ribosomal sequences remains the method of choice for the study of circRNAs. Our objective was to characterize non-canonical circRNAs, namely not originating from back splicing and circRNA produced by non-coding genes. To this end, we analyzed a dataset from porcine testis known to contain about 100 intron-derived circRNAs. Labelling reads containing a circular junction and originating from back splicing provided information on the very small contribution of long non-coding genes to the production of canonical circRNAs. Analyses of the other reads revealed two origins for non-canonical circRNAs: (1) Intronic sequences for lariat-derived intronic circRNAs and intron circles, (2) Mono-exonic genes (mostly non-coding) for either a new type of circRNA (including only part of the exon: sub-exonic circRNAs) or, even more rarely, mono-exonic canonical circRNAs. The most complex set of sub-exonic circRNAs was produced by RNase_MRP (ribozyme RNA). We specifically investigated the intronic circRNA of ATXN2L, which is probably an independently transcribed sisRNA (stable intronic sequence RNA). We may be witnessing the emergence of a new non-coding gene in the porcine genome. Our results are evidence that most non-canonical circRNAs originate from non-coding sequences.