Aestivation induction and evidence of conformational differences between oxy-haemocyanin and deoxy-haemocyaninin aestivating and non-aestivating snails

 

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

  • 2.1Overview of Haemocyanin in Snails
  • 2.2Aestivation Process in Snails
  • 2.3Structural Differences in Oxy-Haemocyanin and Deoxy-Haemocyanin
  • 2.4Previous Studies on Snail Aestivation
  • 2.5Role of Haemocyanin in Aestivating Snails
  • 2.6Physiological Changes during Aestivation
  • 2.7Molecular Adaptations in Aestivating Snails
  • 2.8Comparative Studies on Haemocyanin Forms
  • 2.9Evolutionary Significance of Aestivation in Snails
  • 2.10Future Research Directions

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Design
  • 3.2Sampling Methods
  • 3.3Data Collection Techniques
  • 3.4Data Analysis Procedures
  • 3.5Ethical Considerations
  • 3.6Participant Recruitment
  • 3.7Instrumentation and Materials
  • 3.8Variables and Measurements

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Haemocyanin Levels in Aestivating Snails
  • 4.2Structural Analysis of Oxy-Haemocyanin and Deoxy-Haemocyanin
  • 4.3Comparative Study of Haemocyanin Conformations
  • 4.4Physiological Changes in Aestivating Snails
  • 4.5Molecular Adaptations in Haemocyanin Structure
  • 4.6Impact of Aestivation on Snail Health
  • 4.7Environmental Factors Influencing Aestivation
  • 4.8Discussion on Findings

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Findings
  • 5.2Conclusion
  • 5.3Implications of the Study
  • 5.4Recommendations for Future Research
  • 5.5Contribution to Scientific Knowledge

Project Abstract

<p> <p><strong>ABSTRACT</strong></p><p>Haemocyanin is a high molecular weight, dioxygen, transport, copper-glycoprotein with a di-copper active site found in the haemolymph of several marine and terrestrial invertebrates belonging to the phyla Mollusca and Arthropoda. Haemocyanin exists in two distinct conformers the T-conformer (Tense) and the R-conformer (Relaxed).Knowledge of the molecular architecture around the copper atoms in the active site of haemocyanin is important in understanding how these proteins reversibly bind oxygen. Induction of aestivation and the evidence of conformational differences between oxy-haemocyanin and deoxy-haemocyanin in aestivating and non-aestivating snails was studied.Aestivation induction was studied by treating five groups of snails (groups A, B, C, D and E) with respective volumes of oxy-haemocyanin from aestivating snails, respective volumes of oxy-haemocyanin from non-aestivating snails and respective volumes of distilled water. Evidence of conformational differences between oxy-haemocyanin and deoxy-haemocyanin was also studied by treating the haemolymph of two snail samples (Snail 1 and Snail 2) with nitrogen gas.After the induction of aestivation, it was observed that the snails in groups A, B and C administered with the respective volumes of haemolymph extracted from aestivating rsnails began to synthesize epiphragm layer on the 4th day after injection, on the 5th day after injection, the epiphragm layer was completely formed. Whereas the snails in groups D and E began to synthesize epiphragm layer on the 5th day, on the 6th day, the epiphragm layer was completely formed. It was also observed that the snails in groups A, B and C that were injected with haemolymph extracted from non-aestivating snails beganto synthesize epiphragm layer on the 4th day, on the 5th day, the epiphragm layer was completely formed. It was also observed that the snails in groups D and E that were injected with different volumes of water, began to synthesize epiphragm layer on the 3rd day, at about 4 days and 8hours after injection, the epiphragm layer was completely formed. Whereas the snails in groups A, B and C began to synthesize epiphragm layer on the 4th day, at about 5 days after injection, the epiphragm layer was completely formed. Results from the UV-Visible scanning showed that oxyhaemocyanin exhibited spectral activity both in the near-UV region and in the mid-UV region, whereas deoxyhaemocyanin only showed spectral activity in the near-UV region.</p> <br></p>

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