RESUMO
CRISPR-Cas9 has emerged as a powerful tool in livestock breeding, enabling precise genetic modifications to address genetic diseases, enhance productivity, and develop disease-resistant animal breeds. A thorough analysis of previous research highlights the potential of CRISPR-Cas9 in overcoming genetic disorders by targeting specific mutations in genes. Furthermore, its integration with reproductive biotechnologies and genomic selection facilitates the production of gene-edited animals with high genomic value, contributing to genetic enhancement and improved productivity. Additionally, CRISPR-Cas9 opens new avenues for developing disease-resistant livestock and creating innovative breeding models for high-quality production. A key trend in the field is the development of multi-sgRNA vectors to correct mutations in various genes linked to productivity traits or certain diseases within individual genomes, thereby increasing resistance in animals. However, despite the potential advantages of CRISPR-Cas9, public acceptance of genetically modified agricultural products remains uncertain. Would consumers be willing to purchase such products? It is essential to advocate for bold and innovative research into genetically edited animals, with a focus on safety, careful promotion, and strict regulatory oversight to align with long-term goals and public acceptance. Continued advancements in this technology and its underlying mechanisms promise to improve poultry products and genetically modified livestock. Overall, CRISPR-Cas9 technology offers a promising pathway for advancing livestock breeding practices, with opportunities for genetic improvement, enhanced disease resistance, and greater productivity.
Assuntos
Animais Domésticos , Animais Geneticamente Modificados , Cruzamento , Sistemas CRISPR-Cas , Edição de Genes , Gado , Animais , Sistemas CRISPR-Cas/genética , Edição de Genes/métodos , Animais Geneticamente Modificados/genética , Gado/genética , Animais Domésticos/genética , Cruzamento/métodos , Resistência à Doença/genéticaRESUMO
In recent years, strategic plans for poultry production have emphasized quantitative traits, particularly body weight and carcass traits (meat yield), in response to overpopulation challenges. Candidate genes such as adenylosuccinate lyase (ADSL), melanocortin-4-receptor (MC4R), and calpain 1 (CAPN1) have played vital roles in this context due to their associations with muscle growth and body composition. This study aims to investigate the influence of polymorphisms and gene expressions of the aforementioned genes on body weight (BW), growth rate (GR), breast weight (BrW), and thigh weight (TW) across four distinct chicken breeds: Fayoumi, Matrouh, Mamourah, and Leghorn. The use of PCR-SSCP analysis revealed genetic polymorphisms through the identification of various patterns (genotypes) within the three examined genes. The ADSL, MC4R, and CAPN1 genes exhibited five, three, and two different genotypes, respectively. These polymorphisms displayed promising connections with enhancing economically significant production traits, particularly BW, BrW and TW. Furthermore, gene expression analyses were conducted on breast and thigh tissues obtained from the chicken breeds at 60 days of age, where ADSL and MC4R exhibited a noteworthy up-regulation in Fayoumi and Matrouh breeds, and down-regulation in Mamourah and Leghorn. In contrast, CAPN1 expression decreased across most breeds with a slight increase noted in Fayoumi breed. In conclusion, this investigation underscores the substantial impact of ADSL, MC4R, and CAPN1 genes on economically important production traits within Egyptian domestic chicken breeds. Consequently, these genes emerge as significant molecular markers, holding potential utility in avian selection and breeding programs aimed at enhancing productive performance.
Assuntos
Adenilossuccinato Liase , Galinhas , Animais , Galinhas/metabolismo , Adenilossuccinato Liase/genética , Adenilossuccinato Liase/metabolismo , Egito , Polimorfismo de Nucleotídeo Único/genética , Genótipo , Carne , Peso CorporalRESUMO
BACKGROUND: Genetic variants of the GDF9 gene were considered to be the potent gene markers for improving fecundity traits in Egyptian sheep and goats. Also, these favorable gene variants could be applied in the breeding program by gene-assisted selection (GAS), aiming towards the potential amelioration of reproduction and production in such small ruminants. The present investigation was designed to evaluate the genetic variants of the GDF9 gene on fecundity traits including the mean number of lambing "MNL" and mean number of twin production "MNTP" of Egyptian sheep and goats. RESULTS: This experiment involved 113 mothers, 83 of sheep and 30 of goats, at first, second, third, and fourth parity, and also 26 young females, 12 of sheep and 14 of goats at age of sexual maturation. T-ARMS-PCR analysis was performed on five mutation points (G1, G4, G6, G7, and G8). In sheep, the heterozygous mothers of G4 had significant elevation (P ≤ 0.05) of MNL and MNTP than wild-type homozygous ewes. However, the heterozygous mothers of G1 and G6 gave a reduction of MNL and MNTP as compared to mothers with wild-type genotypes. The ewes of G7 had heterozygous genotype (AG), and the ewes of G8 had wild type (CC). In goat, G4 and G7 were polymorphic, and G1, G6, and G8 were monomorphic type. Based on these findings, it must be selected the young sheep females of heterozygous in G4, and the young goat females of heterozygous in G4 and G7 for participating in a successful breeding program, because they will have potential high fecundity traits. CONCLUSION: The present results confirmed that the genetic variants of the GDF9 gene were considered to be the major gene markers for enhancement of the prolificacy in Egyptian sheep and goats and could be applied in a successful breeding program by gene-assisted selection (GAS) in small ruminants.
RESUMO
In the cattle breeds German Black Pied (GBP), German Simmental (GS), Holstein Friesian (HF), Aubrac (A) three transcribed allotypic variants in isotype IGLC2 and five allotypic variants in isotype IGLC3 were identified. Substitutions within the putative interface to CH1 at position 11 and 79 were noted. In IGLC2(b), K79E led to a charge conversion. In IGLC3(b) and IGLC3(c), the E79N replacement removed the charge while the T11K substitution resulted in a positively charged amino acid residue. In addition, D15 and T16 were found in IGLC2(c), IGLC3(b), and IGLC3(c). Substitutions located on the outer site of the molecule were observed in IGLC2(b) (V40, H45.5), IGLC2(c) (A1, V40, D77), IGLC3(b) (A1, D77, D109, P127), IGLC3(c) (A1, G45.5, D77, D109, P127), IGLC3(d) (D109), and IGLC3(e) (A1). Amino acid residues P83 (IGLC2(c), IGLC3(b), IGLC3(c)), N93 (IGLC2(b)), D93 (IGLC3(b)), and G93 (IGLC3(c)) were positioned in cavities but seemed to be accessible for solvents.