A critical study on enzymes
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 Enzymes
- 2.2Historical Development of Enzymes
- 2.3Classification of Enzymes
- 2.4Enzyme Structure and Function
- 2.5Enzyme Kinetics
- 2.6Enzyme Regulation
- 2.7Industrial Applications of Enzymes
- 2.8Enzymes in Biotechnology
- 2.9Enzymes in Medicine
- 2.10Enzymes in Food Industry
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Design
- 3.2Sampling Techniques
- 3.3Data Collection Methods
- 3.4Data Analysis Procedures
- 3.5Research Ethics
- 3.6Validity and Reliability
- 3.7Research Limitations
- 3.8Research Assumptions
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Overview of Findings
- 4.2Analysis of Data
- 4.3Comparison of Results
- 4.4Discussion of Results
- 4.5Interpretation of Findings
- 4.6Implications of Results
- 4.7Recommendations for Future Research
- 4.8Practical Applications
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of Findings
- 5.2Conclusion
- 5.3Contributions to Knowledge
- 5.4Implications for Practice
- 5.5Recommendations for Further Study
Project Abstract
Enzymes are biological catalysts that play a crucial role in various biochemical processes in living organisms. This research project aims to conduct a critical study on enzymes, focusing on their structure, function, and importance in biological systems. The study will explore the different types of enzymes, their classification based on the reactions they catalyze, and the factors that influence their activity. The research will investigate the structure of enzymes, including their composition of amino acids and the role of cofactors and coenzymes in enzyme activity. By understanding the structural features of enzymes, insights can be gained into how they catalyze specific biochemical reactions with high efficiency and specificity. Furthermore, the project will delve into the mechanisms of enzyme action, including the induced fit model and the lock-and-key model, to elucidate how enzymes interact with substrates to facilitate chemical reactions. In addition, the study will highlight the significance of enzymes in biological systems. Enzymes are involved in a wide range of metabolic pathways, including digestion, energy production, and cellular signaling. Without enzymes, many essential biochemical reactions would occur too slowly to sustain life. The research will also explore the regulation of enzyme activity, including allosteric regulation and post-translational modifications, to understand how cells control the activity of enzymes in response to changing environmental conditions. Moreover, the project will investigate the applications of enzymes in biotechnology and industry. Enzymes are used in various industrial processes, such as food production, pharmaceuticals, and biofuel production, due to their ability to catalyze specific reactions under mild conditions. Understanding the properties of enzymes is crucial for optimizing their use in biotechnological applications. Overall, this research project will provide a comprehensive overview of enzymes, covering their structure, function, and importance in biological systems. By delving into the intricate world of enzymes, this study aims to deepen our understanding of these remarkable biological catalysts and their significance in driving essential biochemical processes.
Project Overview
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</p><p><strong>INTRODUCTION AND LITERATURE REVIEW</strong></p><p><strong>1.1 Enzyme</strong></p><p>Enzymes are large biological molecules responsible for thousands of chemical inter-conversions that sustain life (Smith, 1997). All known enzymes are proteins. They are high molecular weight compounds made up principally of chains of amino acids linked together by peptide bonds, they are denatured at high temperature and precipitated with salts, solvents and other reagents. They have molecular weights ranging from 10,000 to 2,000,000 units. Enzymes do not cause reactions to take place, but rather they enhance the rate of reactions that would <em>have been slower without their presence and still remains unused and unchanged.</em></p><p>Many enzymes require the presence of other compounds – cofactors – before their catalytic activity can be exerted. This entire active complex is referred to as the holoenzyme; i.e. apoenzyme (protein portion) plus the cofactor (coenzyme, prosthetic group or metal-ionactivator) is called the holoenzyme (Alexopoulos <em>et al.,</em> 1996)</p><p>The living cell is the site of tremendous biochemical activity called metabolism. It is the process of chemical and physical change which goes on continually in the living organism involving the build-up of new tissues, replacement of old tissue, conversion of food to energy, disposal of waste materials, reproduction – all the activities that we characterize as “life.”Thephenomenon of enzyme catalysis makes possible biochemical reactions necessary for all life processes. Catalysis is defined as the acceleration of a chemical reaction by some substance which itself undergoes no permanent chemical change. Synthetic molecules called artificial enzymes also display enzyme like catalysis (Grovesm, 1997).</p><p>The catalysts of biochemical reactions are enzymes and are responsible for bringing about almost all of the chemical reactions in living organisms. Without enzymes, these reactions take place at a rate far too slow for the pace of metabolism(Bairoch, 2000).</p><p>Enzymes actually work by lowering the activation energy of a reaction. This is achieved when it creates an alternative pathway which is faster for the reaction hence speeding it up such that products are formed faster. Enzyme catalysed reactions are million times faster than uncatalysed reactions, they alter the rates but not the equilibrium constant of the reaction being catalysed (Ashokkumar <em>et al.</em>, 2001). A few RNA molecules called ribozymes also catalyse reactions, with an important example being some parts of ribosome (Lilley, 2005).</p><p><strong>1.1.1 Types of enzymes</strong></p><p><strong>Metabolic enzymes</strong>: These have been called the spark of life, the energy of life and the vitality of life. These descriptions are not without merit. Metabolic enzymes catalyse and regulate every biochemical reaction that occurs within the human body, making them essential to cellular function and health (Sangeetha<em>et al</em>.,2005). Digestive enzymes turn the food we eat into energy and unlock this energy for use in the body. Our bodies naturally produce both digestive and metabolic enzymes as they are needed. They either speed up or slow down the chemical reactions within the cells for detoxification and energy production. The enable us to see, hear, and move and think. Every organ, every tissue and all 100 trillion cells in our body depend upon the reaction of metabolicenzymes and enjoy their energy factor. Without these metabolic enzymes, cellular life would beimpossible.</p><p><strong>Food enzymes:</strong>These are introduced to the body through the raw foods we eat and throughconsumption of supplemental enzyme products. Raw foods naturally contain enzymes providing asource of digestive enzymes when ingested(Hossain<em>et al</em>., 1984). However, raw food manifests only enough enzymesto digest that particular food, not enough to be stored in the body for later use (the exceptionsbeing pineapple and papaya, the sources of the enzymes bromelain and papain). The cooking andprocessing of food destroys all of its enzymes. Since most of the foods we eat are cooked orprocessed in some way and since the raw foods we do eat contain only enough enzymes toprocess that particular food (Persike<em> et al</em>., 2002) our bodies must produce the majority of the digestive enzymes werequire, unless we use supplemental enzymes to aid in the digestive process. A variety ofsupplemental enzymes are available through different sources. It is important to understand thedifferences between the enzyme types and ensure that one is using an enzyme product which willmeet one’s particular needs.</p><p><strong>Plant based enzymes</strong>:These are the most popular choice of enzymes. They are grown in a laboratorysetting and extracted from <em>Aspergillus</em> species. The enzymes harvested from <em>Aspergillus</em>species are called plantbased, microbial and fungal. Of all the choices, plant based enzymes are the most active. Thismeans they can break down more fat, protein and carbohydrates in the broadest pH range than any other sources (Ashokkumar <em>et al.</em>, 2001).</p><p><strong>1.1.2 </strong><strong>Characteristics of enzymes</strong></p><p><strong>Protein nature:</strong>Enzyme is a protein. The main components of an enzyme is protein.</p><p><strong>Temperature:</strong>Enzymes are sensitive to temperature. Many work best at temperatures close to body temperatures and most lose their ability to catalyse if they are heated above 60 or 70o C. (Ashokkumar <em>et al.</em>, 2001).</p><p><strong>Acidity and alkalinity:</strong>Many enzymes work best at a particular pH and stop working if the pH becomes too acidic or alkaline. </p><p><strong>Catalytic effect:</strong>It acts as catalyst, enzyme functions in accelerating chemical reaction, but the enzyme itself does not change after the reaction ends. </p><p><strong>Specificity:</strong>It functions specifically. The enzyme only catalyzes one kind of substrate and cannot function for many substrates. The term is called one enzyme one substrate. </p><p><strong>Reversibility:</strong> It means the enzyme does not determine the direction of reaction, but it only functions in accelerating reaction rate until it reaches equilibrium. The enzyme also functions in substance synthesis and substance breaking down reaction. </p><p><strong>Small quantity:</strong>It is required, in small amount. A small amount of enzyme is able to catalyze a chemical reaction (Nason, 1968).</p>
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