Abstract

Gene mutations at different gene sites will produce totally different phenotypes or biological functions in gene-edited animals. An allelic series of mutations in the myostatin (MSTN) gene can cause the ‘double-muscling’ phenotype. Although there have been many studies performed on MSTN-mutant animals, there have been few studies that have investigated the cystine-knot motif in exon 3 of MSTN in rabbits. In the current study, CRISPR/Cas9 sgRNA anchored exon 3 of a rabbit’s MSTN was used to disrupt the cystine-knot motif to change the MSTN construction and cause a loss of its function. Eleven MSTN-KO founder rabbits were generated, and all of them contained biallelic modifications. Various mutational MSTN amino acid sequences of the 11 founder rabbits were modeled to the tertiary structure using the SWISS-MODEL, and the results showed that the structure of the cystine-knot motif of each protein in the founder rabbits differed from the wild-type (WT). The MSTN-KO rabbits displayed an obvious ‘double-muscling’ phenomena, with a 20−30% increase in body weight compared with WT rabbits. In the MSTN-KO rabbits, all of the MSTN−/− rabbits showed teeth dislocation and tongue enlargement, and the percentage of rabbits having pelvic tilt was 0% in MSTN+/+, 0% in MSTN+/−, 77.78% in female MSTN−/− rabbits, and 37.50% in male MSTN−/− rabbits. The biomechanical mechanism of pelvic tilt and teeth dislocation in the MSTN-KO rabbits requires further investigation.These newly generated MSTN-KO rabbits will serve as an important animal model, not only for studying skeletal muscle development, but also for biomedical studies in pelvic tilt correction and craniofacial research.

Highlights

  • Myostatin (MSTN) can negatively regulate the growth and development of skeletal muscle

  • An analysis of the C313A and C374A mutations confirmed that it is the disruption of the cystine-knot by removal of the C313–C374 disulfide bond, and not the introduction of the tyrosine, that is the dominant factor in the decreased stability and reduced disulfide-linked dimerization of C313Y myostatin [14]

  • MSTN-KO rabbits were generated with remarkably high efficiency by microinjecting Cas9 mRNA and small guide RNA (sgRNA) into pronuclear-stage embryos

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Summary

Introduction

Myostatin (MSTN) can negatively regulate the growth and development of skeletal muscle. It is a member of the transforming growth factor β (TGF-β) superfamily of growth and differentiation factors [1,2]. Natural myostatin null animals, including cattle [4], dogs [5], humans [6], and sheep [7], shows a dramatic and widespread increase in skeletal muscle mass; namely, a ‘double-muscling’ phenomenon. A large number of variants have been identified in cattle, most of which are silent or neutral. Two of the variants in the third exon strongly affect the ‘double-muscling’ phenotype in Belgian Blue cattle [9]. An 11-bp deletion at the bovine myostatin nucleotide 821 [nt821(del11)] in the coding region results in a frameshift

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