Thermodynamics and kinetics of thermo-inactivation and regeneration of partially purified peroxidase from gongronema latifolium leaves.

 

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 Peroxidase Enzyme
  • 2.2Extraction and Purification Techniques
  • 2.3Thermo-inactivation of Peroxidase
  • 2.4Kinetics of Peroxidase Inactivation
  • 2.5Regeneration of Partially Purified Peroxidase
  • 2.6Factors Affecting Peroxidase Activity
  • 2.7Applications of Peroxidase Enzyme
  • 2.8Comparative Studies on Peroxidase Enzymes
  • 2.9Stability Studies of Peroxidase Enzyme
  • 2.10Recent Advances in Peroxidase Research

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Methodology Overview
  • 3.2Selection of Gongronema Latifolium Leaves
  • 3.3Extraction and Partial Purification Methods
  • 3.4Thermo-inactivation Experimental Setup
  • 3.5Kinetics Study Design
  • 3.6Regeneration Procedure
  • 3.7Data Collection and Analysis Techniques
  • 3.8Statistical Analysis Methods

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Analysis of Thermo-inactivation Results
  • 4.2Kinetics Data Interpretation
  • 4.3Regeneration Efficiency Evaluation
  • 4.4Comparison with Literature Findings
  • 4.5Factors Influencing Peroxidase Activity
  • 4.6Stability Assessment of Partially Purified Peroxidase
  • 4.7Discussion on Applications in Food Industry
  • 4.8Future Research Directions

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Research Findings
  • 5.2Conclusion and Implications
  • 5.3Recommendations for Future Studies
  • 5.4Contribution to Scientific Knowledge
  • 5.5Closing Remarks

Project Abstract

<p> Peroxidase activity from G. latifolium was done to see whether it could be used in industries. Crude peroxidase was extracted from G. latifolium with 0.05M sodium phosphate buffer of pH 6.0; 70% ammonium sulphate saturation to precipitated protein with the highest G. latifolium peroxidase activity. After gel filtration, two major peaks were seen and the active fractions were pooled differently together and characterized. The optimal pH for the enzyme peaks actually were found to be 6.5 and 6.0 and the optimum temperature was 30 and 40ºC for peak A and B respectively. The Michealis-Mentenconstant (Km) and maximum velocity (Vmax) obtained from the Lineweaver-Burk plot of initial velocity of different substrate concentration were found to be 1.242 mM and 20.83 U/min for hydrogen peroxide concentration [H2O2] and 0.109 mM and 10.99 U/min for o-dianisidine concentrations. On the thermal stability assessment of the enzyme. Thermal inactivation profiles of these enzyme peaks follows first order kinetics with the time required varying with the product of the studies. The half-lives of the enzyme at the two peaks were obtained to be 770.16 mins at 30ºC for peak A and 330.07 mins at 40ºC for peak B, the activation energy for inactivation (Ea(inact)) calculated from the Arrhenius plot were found rto be 67.55 KJmol-1 and 59.58 KJmol-1 forpeaks A and B, respectively. The Z-values were obtained to be 30.21 and 34.25 for the two enzyme peaks respectively. The thermodynamics parameters obtained for the two enzyme peaks were as follows change in enthalpy of inactivation (ΔH(inact)) 65.026 KJmol-1K-1 for peak A at 30ºC and 56.982 KJmol- 1K-1 at 40ºC for peak B; the change in free energy of inactivation, (ΔG(inact)) values for the two enzyme peaks were 102.229 KJmol-1K-1 at 30 ºC and 103.483 KJmol-1K-1 at 40ºC for peak A and B respectively. The entropy of inactivation (ΔS(inact)) values for the two enzyme peaks were calculated to be -0.1228 KJmol-1K-1 at 30ºC and -0.149 KJmol-1K-1 at 40ºC. Reactivation of the Gongronema latifolium peroxidase occurred rapidly, within first 30 minutes after the heated enzyme was cooled and incubated at room temperature. The extent of reactivation varied from 0 to 20% depending on the isoenzyme and heating conditions (temperature and time). The denaturation temperature allowing the maximum reactivation was 50°C and 40°C for peaks A and B respectively. In all cases, heat treatment at high temperatures for a long period prevented reactivation of the heated enzymes. The peak A peroxidase regained activity rapidly, within 30 minutes at 30 and 40°C and within 60 minutes at 50, 60, 70 and 80°C after the heated enzyme was cooled and incubated at room temperature. However, peak B peroxidase regained activity rapidly within 60 minutes at all the study temperature after the heated enzyme was cooled and incubated at room temperature. The kinetic and thermodynamic parameters and higher activation energies from this study suggest that this enzyme could be more suitable for several industrial applications. <br></p>

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