Transgenic F2 bovine embryos show stable germline transmission and maintenance of transgene expression through two generations

Cas9-expressing cattle using the PiggyBac transposon all-in-one system

BACKGROUND

Livestock, particularly cattle, are crucial for biotechnology fields, such as genetic breeding, infectious diseases, bioreactors, and specific disease models. However, genetic engineering in cattle has lagged due to long gestation periods, single embryo pregnancies, and high rearing costs. Additionally, the slow validation of germline transmission and the absence of germline-competent embryonic stem cells hinder progress. With the development of genome editing technologies like ZFN, TALEN, and CRISPR-Cas9, recent advancements have shown that Cas9-expressing pigs and chickens have been successfully produced. We hypothesize that generating CRISPR/Cas9-expressing cattle and their resources will provide a powerful resource for bovine genome editing, advancing our understanding of bovine genetics and disease resistance.

RESULTS

In this study, two types of Cas9-expressing cattle were successfully produced: Cas9-RFP-fatty acid dehydrogenase I (FatI), Cas9-GFP-sgRNA for the prion protein (sgPRNP). Somatic cells from these cattle were induced to mutate multiple target genes when single-guide RNAs (sgRNAs) were transfected into the somatic cells. Additionally, semen from Cas9 expressing male cattle was frozen and used to fertilize wild-type oocytes, successfully transmitting the transgene (Cas9, reporter genes, FatI), and sgPRNP) to the next generation. Furthermore, the gene editing capabilities of Cas9, including knockout and high-efficiency knock-in, were confirmed in embryos derived from F1 semen through in vitro production.

CONCLUSION

These data demonstrate, for the first time, that Cas9-expressing cattle were successfully born, and this transgene was transmitted to the next-generation calves (F1) and F2 embryos. In addition, somatic and germ cells derived from F0 and F1generations were used to evaluate the potential for gene editing (knockout and knock-in) in multiple genes. PRNP-mutated F1 cattle are currently being raised as a resistance model for bovine spongiform encephalopathy. These transgenic bovine models and their derivatives will serve as a valuable resource for both in vitro and in vivo genome editing, advancing our genetic understanding of bovine genomics and diseases.

Mammalian ubiquitous promoter isolated from proximal regulatory region of bovine MSTN gene

Gene therapy is a promising method for treating inherited diseases by directly delivering the correct genetic material into patient cells. However, the limited packaging capacity of vectors poses a challenge. Minimizing promoter size is a viable strategy among various approaches to address this issue. This study aims to optimize the bovine myostatin (MSTN) promoter, enhancing its utility in gene therapy applications. We identified the primary driver of activity as the proximal regulatory region. Isolated from the native promoter and termed M243, this 243-bp sequence was assessed for its potential as a ubiquitous promoter. In a variety of cell types, including bovine embryos and embryonic stem cells, the M243 promoter showed consistent expression, highlighting its suitability for applications requiring compact promoters. The isolation of a highly conserved, compact 243-bp sequence serving as a promoter suggests a solution for overcoming the size constraints of AAV vectors, suggesting potential contributions to the field of gene therapy.

Long-term (10-year) monitoring of transposon-mediated transgenic cattle

The production of transgenic animals using non-viral methods has raised questions regarding their long-term health and genomic stability. In this study, we evaluated these aspects in transgenic cattle over ten years, using transposon-mediated gene transfer. Our longitudinal analysis included a comprehensive health assessment and whole-genome DNA resequencing. We found no significant alterations in physiological parameters or health complications in transposon-mediated transgenic cattle that exceeded 10 years of age. Genomic analysis revealed that the rates of somatic mutations and copy number variations in transgenic cattle were comparable to those in non-transgenic cattle. Furthermore, structural variants were infrequent, suggesting that transposon-mediated gene insertion did not compromise genomic integrity. These findings highlight the viability of transposon systems for generating transgenic livestock, potentially expanding their applications in agriculture and biotechnology. This study contributes significantly to our understanding of the long-term implications of transgenesis in large animals and supports the safety and stability of this method.

Germline transmission of MSTN knockout cattle via CRISPR-Cas9

Although the production of several founder animals (F0) for gene editing in livestock has been reported in cattle, very few studies have assessed germline transmission to the next generation due to the long sexual maturation and gestation periods. The present study aimed to assess the germline transmission of MSTN mutations (-12bps deletion) in MSTN mutant F0 male and female cattle. For this purpose, oocytes and semen were collected after the sexual maturation of MSTN cattle, and embryos produced by in vitro fertilization were analyzed. In addition, the embryos were subjected to additional gene (PRNP) editing using electroporation. Embryos produced by in vitro fertilization with MSTN male and female cattle were transferred to a surrogate, and one calf was successfully born. MSTN heterozygous mutation was shown by sequencing of the F1 calf, which had no health issues. As a further experiment, using electroporation, additional gene-edited embryos fertilized with the MSTN male sperm showed a high mutation rate of PRNP (86.2 ± 3.4%). These data demonstrate that the cattle produced through gene editing matured without health issues and had transmitted MSTN mutation from the germ cells. Also, additional mutation of embryos fertilized with the MSTN male sperm could enable further mutagenesis using electroporation.

One-step generation of a targeted knock-in calf using the CRISPR-Cas9 system in bovine zygotes

Background

The homologous recombination (HR) pathway is largely inactive in early embryos prior to the first cell division, making it difficult to achieve targeted gene knock-ins. The homology-mediated end joining (HMEJ)-based strategy has been shown to increase knock-in efficiency relative to HR, non-homologous end joining (NHEJ), and microhomology-mediated end joining (MMEJ) strategies in non-dividing cells.

Results

By introducing gRNA/Cas9 ribonucleoprotein complex and a HMEJ-based donor template with 1 kb homology arms flanked by the H11 safe harbor locus gRNA target site, knock-in rates of 40% of a 5.1 kb bovine sex-determining region Y (SRY)-green fluorescent protein (GFP) template were achieved in Bos taurus zygotes. Embryos that developed to the blastocyst stage were screened for GFP, and nine were transferred to recipient cows resulting in a live phenotypically normal bull calf. Genomic analyses revealed no wildtype sequence at the H11 target site, but rather a 26 bp insertion allele, and a complex 38 kb knock-in allele with seven copies of the SRY-GFP template and a single copy of the donor plasmid backbone. An additional minor 18 kb allele was detected that looks to be a derivative of the 38 kb allele resulting from the deletion of an inverted repeat of four copies of the SRY-GFP template.

Conclusion

The allelic heterogeneity in this biallelic knock-in calf appears to have resulted from a combination of homology directed repair, homology independent targeted insertion by blunt-end ligation, NHEJ, and rearrangement following editing of the gRNA target site in the donor template.

This study illustrates the potential to produce targeted gene knock-in animals by direct cytoplasmic injection of bovine embryos with gRNA/Cas9, although further optimization is required to ensure a precise single-copy gene integration event.

Supplementary Information

The online version contains supplementary material available at 10.1186/s12864-021-07418-3.