The availability of tools to accurately replicate the clinical phenotype of rare human diseases is a key step toward improved understanding of disease progression and the development of more effective therapeutics. We successfully generated the first large animal model of a rare human bone disease, hypophosphatasia (HPP) using CRISPR/Cas9 to introduce a single point mutation in the tissue nonspecific alkaline phosphatase (TNSALP) gene (ALPL) (1077 C > G) in sheep. HPP is a rare inherited disorder of mineral metabolism that affects bone and tooth development, and is associated with muscle weakness. Compared to wild-type (WT) controls, HPP sheep have reduced serum alkaline phosphatase activity, decreased tail vertebral bone size, and metaphyseal flaring, consistent with the mineralization deficits observed in human HPP patients. Computed tomography revealed short roots and thin dentin in incisors, and reduced mandibular bone in HPP vs. WT sheep, accurately replicating odonto-HPP. Skeletal muscle biopsies revealed aberrant fiber size and disorganized mitochondrial cristae structure in HPP vs. WT sheep. These genetically engineered sheep accurately phenocopy human HPP and provide a novel large animal platform for the longitudinal study of HPP progression, as well as other rare human bone diseases.
Pluripotent stem cells (PSCs) have demonstrated great utility in improving our understanding of mammalian development and continue to revolutionise regenerative medicine. Thanks to the improved understanding of pluripotency in mice and humans, it has recently become feasible to generate stable livestock PSCs. Although it is unlikely that livestock PSCs will be used for similar applications as their murine and human counterparts, new exciting applications that could greatly advance animal agriculture are being developed, including the use of PSCs for complex genome editing, cellular agriculture, gamete generation and invitro breeding schemes.
Hypophosphatasia (HPP) is a rare inherited disorder that affects the development of bones and teeth. The disease is caused by mutations in the tissue‐nonspecific alkaline phosphatase (TNSALP) gene (ALPL) and accompanied by a highly variable clinical presentation. Although HPP patient studies have advanced our understanding of HPP, as well as documented disease severity, the rarity of the disease combined with a lack of sufficient animal models has significantly delayed mechanistic understanding and therapeutic development. Similar to other human disease models, current HPP models have been engineered virtually exclusively in rodents – specifically mice harboring null or loss‐of‐function mutations. Although useful for modeling some features of HPP, these murine models do not faithfully represent the broad spectrum of human HPP clinical bone, muscle and tooth (odonto‐HPP) phenotypes. However, in sheep both Haversian bone remodeling and tooth development are analogous to humans with sheep TNSALP amino acid sequence sharing 89% identity with human. Thus, our objective was to generate a sheep model of HPP and we posit that ALPL mutation‐specific replacements in the sheep genome using CRISPR/Cas9 will produce a model that accurately phenocopies the bone and tooth pathophysiology of HPP. To genetically engineer a sheep model of HPP, a total of 52 in vitro genetically manipulated embryos were generated targeting the Exon 10 c.1077G>A mutation using CRISPR/Cas9. Three embryos were implanted per recipient ewe and implantations were performed in a total of 17 recipient ewes. Nine ewe pregnancies were confirmed by the measurement of Pregnancy‐Associated Protein on post‐implantation day 35 and further validated by ultrasound. From 9 live newborn lambs, four were heterozygous for our specific point mutation (4/6), one compound heterozygous (1/6) and one homozygous (1/6) for a total mutation efficiency rate of 66.6% (6/9). Similar to HPP patients with the same mutation, mutant sheep have variable clinical expression accompanied with decreased bone formation and mineralization in tails observed by DXA as well as significantly and appropriately decreased serum alkaline phosphatase activity. Additionally, an apparent “shell tooth” phenotype is observed in mutant lambs, further suggesting a mutant exon 10 genotype/phenotype that more completely recapitulates human skeletal and odonto‐HPP.Support or Funding Information1. William Townsend Porter Pre‐doctoral Fellowship2. TAMU/Texas Heart Institute Center for Cell and Organ Biotechnology Innovation Kitchen GrantThis abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
The myostatin gene or growth differentiation factor 8 is a member of the transforming growth factor-β superfamily that acts as a negative regulator of muscle growth. Mutations inactivating this gene occur naturally in Piedmontese and Belgian Blue cattle breeds, resulting in a dramatic increase in muscle mass, albeit with unwanted consequences of increased dystocia and decreased fertility. Modulation of muscle mass increase without the unwanted effects would be of great value for improving livestock growth and economic value of livestock. The objective of our work was to use the CRISPR-Cas9 genetic engineering tool to generate deletions of different elements in the myostatin promoter in order to decrease the level of expression and obtain an attenuated phenotype without the detrimental consequences of an inactivating mutation. To achieve this objective 4 different small guide RNA (sgRNA) targeting the promoter near the mutation were designed with PAM positions from transcription starting site of −1577, −689, −555, and −116. These sgRNA were cloned individually into the Cas9 plasmids (px461, and px462; Addgene®). These plasmids allow for a dual puromycin resistance (px462) and green fluorescent protein (px461) selection. We first tested the functionality of these sgRNA in vitro by co-transfecting bovine fetal fibroblasts with a combination of both plasmids (Set 1 = sgRNA 1–4; Set 2 = sgRNA 2–3). Cells were exposed to puromycin (0.2 µg mL−1) for 72 h, then single and mixed colonies positive for green fluorescent protein expression were separated for propagation. The DNA was extracted for PCR amplification of the targeted region. Multiple deletions and a few insertion events were observed after PCR, bands were cloned into TOPO® vector (Thermo Fisher Scientific, Waltham, MA, USA) and sequenced. Sequencing results confirmed the PCR products as insertions or deletions in the myostatin promoter region. We proceeded to modify the myostatin promoter directly in bovine zygotes. For this, IVF-derived zygotes were randomly assigned to 3 different treatment groups Set 1, Set 2, or Null (no sgRNA) for microinjections. Each zygote was injected with ~100 pL of trophectoderm buffer containing 50 ng µL−1 of total sgRNA, 10 ng µL−1 of Cas9 mRNA, and 30 ng µL−1 of Cas9 protein with 1 mg mL−1 of fluorescent dextran. Day 7 post-IVF blastocysts were lysed and DNA was extracted for PCR amplification of the target region. In Set 1, 16 of 19 embryos (94.12%) were successfully edited, whereas in Set 2 there were 11 of 17 embryos (64.7%) edited. In both sets of sgRNA there was a high degree of mosaicism, with only 1 embryo demonstrating a homozygous deletion. In conclusion, CRISPR/Cas9 acts over the course of the first few cleavage divisions Further research is necessary to refine the CRISPR/Cas9 system for inducing genetic mutations in bovine embryos.
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