Propagation and phenotypic analysis of mutant rabbits with <i>MSTN</i> homozygous mutation.

Liqing Shang; Shaozheng Song; Ting Zhang; Kunning Yan; Heqing Cai; Yuguo Yuan; Yong Cheng

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Propagation and phenotypic analysis of mutant rabbits with MSTN homozygous mutation.

Author: Liqing SHANG ¹ ; Shaozheng SONG ² ; Ting ZHANG ¹ ; Kunning YAN ¹ ; Heqing CAI ¹ ; Yuguo YUAN ¹ ; Yong CHENG ¹
Author Information

1. College of Veterinary Medicine, Yangzhou University, Yangzhou 225009, Jiangsu, China.
2. Department of Basic Medicine, Wuxi Taihu University, Wuxi 214064, Jiangsu, China.
Publication Type:Journal Article
Keywords: CRISPR/Cas9; New Zealand rabbits; mutation; myostatin; propagation and breeding
MeSH: Animals; CRISPR-Cas Systems/genetics*; Gene Editing; Muscle, Skeletal/metabolism*; Mutation; Myostatin/metabolism*; Phenotype; Rabbits
From: Chinese Journal of Biotechnology 2022;38(5):1847-1858
CountryChina
Language:Chinese
Abstract: Myostatin gene (MSTN) encodes a negative regulator for controlling skeletal muscle growth in animals. In this study, MSTN^-/- homozygous mutants with "double muscle" phenotypic traits and stable inheritance were bred on the basis of MSTN gene editing rabbits, with the aim to establish a method for breeding homozygous progeny from primary MSTN biallelic mutant rabbits. MSTN^-/- primary mutant rabbits were generated by CRISPR/Cas9 gene editing technology. The primary mutant rabbits were mated with wild type rabbits to produce F1 rabbits, whereas the F2 generation homozygous rabbits were bred by half-sibling mating or backcrossing with F1 generation rabbits of the same mutant strain. Sequence analysis of PCR products and its T vector cloning were used to screen homozygous rabbits. The MSTN mutant rabbits with 14-19 week-old were weighed and the difference of gluteus maximus tissue sections and muscle fiber cross-sectional area were calculated and analyzed. Five primary rabbits with MSTN gene mutation were obtained, among which three were used for homozygous breeding. A total of 15 homozygous rabbits (5 types of mutants) were obtained (M2-a: 3; M2-b: 2; M3-a: 2; M7-a: 6; M7-b: 2). The body weight of MSTN^-/- homozygous mutant rabbits aged 14-19 weeks were significantly higher than that of MSTN^+/+ wild-type rabbits of the same age ((2 718±120) g vs. (1 969±53) g, P < 0.01, a 38.0% increase). The mean cross sections of gluteus maximus muscle fiber in homozygous mutant rabbits were not only significantly higher than that of wild type rabbits ((3 512.2±439.2) μm² vs. (1 274.8±327.3) μm², P < 0.01), but also significantly higher than that of MSTN^+/- hemizygous rabbits ((3 512.2±439.2) μm² vs. (2 610.4±604.4) μm², P < 0.05). In summary, five homozygous mutants rabbits of MSTN^-/- gene were successfully bred, which showed a clear lean phenotype. The results showed that the primary breeds were non-chimeric mutant rabbits, and the mutant traits could be inherited from the offspring. MSTN^-/- homozygous mutant rabbits of F2 generation could be obtained from F1 hemizygous rabbits by inbreeding or backcrossing. The progenies of the primary biallelic mutant rabbits were separated into two single-allelic mutants, both of which showed a "double-muscle" phenotype. Thus, this study has made progress in breeding high-quality livestock breeds with gene editing technology.