IN-SILINCO GENETIC ANALYSIS OF THE SEQUENCES OF MYOSTATIN GENE IN BOVIDS (CATTLE, SHEEP AND GOAT)
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Evolutionary Genetics of Myostatin Gene
- 2.2Functions of Myostatin in Bovids
- 2.3Genetic Mutations in Myostatin Gene
- 2.4Myostatin Gene Regulation
- 2.5Comparative Analysis of Myostatin Gene in Cattle, Sheep, and Goat
- 2.6Impact of Myostatin Gene Variations on Muscle Development
- 2.7Myostatin Gene Editing Technologies
- 2.8Economic Importance of Myostatin Gene Research
- 2.9Future Prospects in Myostatin Gene Studies
- 2.10Challenges in Understanding Myostatin Gene Variations
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Design and Methodology
- 3.2Sampling Techniques
- 3.3Data Collection Methods
- 3.4Data Analysis Approaches
- 3.5Bioinformatics Tools for Genetic Analysis
- 3.6Experimental Procedures for Myostatin Gene Sequencing
- 3.7Statistical Analysis for Genetic Data
- 3.8Ethical Considerations in Genetic Research
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Analysis of Myostatin Gene Sequences in Bovids
- 4.2Identification of Genetic Variations
- 4.3Phylogenetic Analysis of Myostatin Gene
- 4.4Functional Implications of Detected Mutations
- 4.5Comparison of Myostatin Gene Expression Levels
- 4.6Genetic Diversity in Cattle, Sheep, and Goat
- 4.7Association Studies with Muscle Traits
- 4.8Implications for Livestock Breeding Programs
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of Findings
- 5.2Conclusions
- 5.3Recommendations for Future Research
- 5.4Contribution to Genetic Studies in Bovids
- 5.5Implications for Livestock Industry
Project Abstract
<p> Double muscling is a heritable trait. It has been revealed that myostatin (MSTN) or growth differentiation factor 8(GDF8) is the genetic agent of this trait. The gene is a myokine, a protein that inhibits myogenesis (muscle cell growth and differentiation). In-Silico genetic analysis was done to analyze the sequences of Myostatin gene in cattle, sheep and goat. A total of thirty seven (37) nucleotides with their corresponding amino acid sequences comprising of (26 for goat, 9 for cattle and 2 for sheep) were retrieved from the Genebank. The genetic polymorphism with three variants (M180L, S276N, S279K), five (K178N, V151L, E247D, Q329L, G355I) and six (R98H, I119T, S125M, G133S, T165N, H328T) for goat, sheep and cattle respectively, appeared not to impair the gene function while three variants (K153F, T240K, L270Q), six (S191P, W203L, S205C, N222Q, D231C, R303G), seven (D110L, I158A, R175V, K193V, S205G, P301L, F353N) were deleterious. The results revealed beneficial amino acid variants which can be used as possible markers for growth and development in goats, sheep and cattle. Although Capra and Ovis family had more propinquity and organized branch in the phylogenetic tree, the Neigbour-joining showed that sequences of the three species are similar. Also, goats and sheep appeared more similar in their amino acid contents compared to cattle. However, the distribution pattern was the same for the three species in respect of (aspartate 6.1, cysteine 3.5, glutamate 6.7, methionine 2.1, phenylalanine 3.7, proline 6.4 and tyrosine 3.2 with leucine 9.9, as the highest). The results also showed that this gene has a high degree of conservation during evolution of various species, which implies that MSTN, is an essential factor in biological muscle control. Physicochemical properties also showed extinction coefficient =51630 for sheep and cattle, half life=30hours for goats, sheep and cattle and aliphatic index =84.45 for goats and sheep, other parameters varied from one species to anrother. The secondary protein structure prediction in the bovine myostatin protein showed highest alpha helix (23.20%) and random coil (44.00%) with caprine and ovine at 22.67% and 43.20%. However, the extended strand (25.87%) and beta turn (8.27%) predictions were higher in both caprine and ovine species with bovine at 25.33% and 7.47%. Tertiary protein structure prediction of goat and sheep are the same while that of cattle differed. Furthermore, the results showed that capra and ovis family are much similar in function compared to cattle. Finally, the comparative inferences of myostatin gene sequences of the species studied conferred similarity in goat and sheep than cattle. <br></p>
Project Overview