Biochemistry: Fundamentals and Bioenergetics E-Book

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Enzymology

It is a study of properties and biological functions of enzymes like enzymatic activity, kinetics, enzyme-substrate complex, the kinetics of the reaction, enzymatic regulation, and transition state, etc. They fulfill a multitude of functions in living organisms. They are essential for signal transmission and cellular control, usually by kinases and phosphatases. They also produce movement with ATP, which hydrolyzes myosin to induce muscle contraction as well as moves cargo in and out of the cell. Other cell membrane ATPases are active transport ion pumps [5]. Enzymes like amylases and proteases present in the intestine participate in the digestive system and breakdown of large molecules like starch and proteins into smaller ones.

Endocrinology

It is a study dealing with biosynthesis, signal process, storage and functions of hormones in living organisms. Hormones control metabolism, respiration, growth, reproduction, sensory perception, and movement and its imbalance in the body causes a wide range of medical conditions. Endocrinology deals with both hormones and the glands, also the tissues from where it is produced.

There are more than 50 different hormones produced in the human body, though they are present in small amounts and yet have a significant effect on physical function and development. Endocrine tissues include the adrenal glands, hypothalamus, ovaries, and testes. The endocrine system includes tissues such as the adrenal gland, hypothalamus, ovaries, and testes. The most common hormonal disorder found in women is polycystic ovary syndrome (PCOS) [8]. Hormonal imbalances can be caused by genetic or environmental factors. Endocrinologists generally deal- with the subsequent conditions like:

Molecular Biology

This study aims to understand the molecular and chemical processes that occur in living organisms from a molecular perspective. Here you will find detailed information on classical, biochemical and metabolic cycles and also learn about the integration and degradation of molecules in vivo. Molecular biology helps us understand the chemical properties of molecules e.g. cell metabolism. Chemical reactions occurring in the body are beneficial in sustaining life. Reproduction, structural restoration, and autonomic response to stimuli involve a number of intracellular processes. Molecular biochemists study two major types of metabolism: catabolism and anabolism. Catabolism is the process by which matter is broken down and energy is released through the respiration of cells whereas the anabolic process uses energy to make various components inside the cell.

In addition to biomolecules, molecular biochemistry also deals with the study of viruses. The virus can only develop inside the host cell, making it a form of pseudo-life. They can influence different parts of molecules, from protein synthesis to cell membrane transport and also infect all other organisms, including plants or animals. More than 5,000 varieties of viruses have been described by molecular biochemists worldwide and they have given the term ‘virology’ to the study of viruses.

Molecular Genetics and Genetic Engineering

It deals with genetic modification and the processes involving gene insertion, gene silencing, gene expressions, mutation and various properties. The goal of this study is to overcome the limits of genetic manipulation by transferring genes from one species to another species or by splicing the unwanted genes. The purpose of this study is also to model the effects of genes. Genetic engineering is used to alter the genetic make-up of cells, thus exchanging properties inside and over species to create better or new living things. The new DNA can be inserted into the host's genome by first isolating it, copying the ancestral stimulus material, creating a DNA sequence using nuclear sequencing techniques, or synthesizing the DNA and then inserting it into the host's body. Genes may be removed, or “knocked out”, using a nuclease [9]. The different methods for knockout are (1) Gene silencing (2) Conditional knockout (3) Homologous recombination (4) Gene editing and (5) Knockout by mutation. Overcoming obstacles, boundaries between species, for example, the genome of one species can be integrated into another to create new species. One of its main goals is to obtain current administrative entities and gene expression, that is, to obtain epigenetic code. It is the foundation of some other disciplines of life sciences, especially biotechnology.

Structural and Metabolic Biochemistry

The purpose of this study is to provide clear information about the biological architecture like proteins and nucleic acids (DNA and RNA) and understand different metabolic pathways at the cellular level.

Chemical reactions are mostly synchronised and occur in sequences called metabolic pathways, each of which is catalysed by a particular enzyme. These pathways are classified according to the reactions that lead to material breakdown or synthesis [9].

Importance of Biochemistry in Medicine

Importance of Biochemistry in Agriculture

Gout – It is a form of inflammatory arthritis due to the deposition of uric acid in joints, tendons and tissues.

Agricultural biochemistry deals with agricultural production, food processing, monitoring and remediation of the environment. The study emphasizes the relationships between plants, animals and bacteria and their environment [17]. Some important areas where the knowledge in agricultural biochemistry is highly useful include:

Importance of Biochemistry in Nutrition

Nutrition entails a healthy diet that can prevent diseases, reduce disease conditions and promote health. Biochemical studies help us determine the optimal amount of nutrients for good health, and the nutritional value of food and drink can also be determined by different biochemical tests. Food consists of nutrients that are categorised according to their role in the body: energy-producing macronutrients (carbohydrates, proteins and fats), essential micronutrients (vitamins, minerals and water) and many other ingredients. Although micronutrients do not provide energy for the body to make fuel, they are essential for the proper functioning of the body's metabolic and regulatory activities, as shown in Table 2.

Nonessential nutrients, such as flavonoids, phytoestrogens, carotenoids, probiotics, also have important properties for good health. The regular consumption of a variety of foods provides energy and nutrients which are important for an individual's health and well-being. The recommended daily food and their nutritional values are shown in Table 3.

The biochemistry of nutrition is the backbone for understanding the composition and function of food and nutrients in the body. Nutrients function as a cofactor for enzymes, hormonal components and metabolic processes and participate in oxidation/reduction reactions.

Nutrients are important for body growth, sexual development, reproduction, psychological wellbeing, energy level and the normal functioning oforgan systems in the body, albeit needed in small quantities.

Importance of Biochemistry in Pathology

The ultimate application of biochemistry is for the health and welfare of mankind.Clinical biochemistry or chemical pathology is a necessary laboratory service for clinical practice. The results of biochemical tests conducted can help diagnose the disease and early treatment. Biochemical screening is important in diagnosing diseases like diabetes mellitus, jaundice, myocardial infarction, arthritis, pancreatitis, rickets, cancer, acid-base imbalance, and so on. It is widely used for testing in clinical laboratories. Diagnosis creates a list of different diagnoses based on history and clinical examination. Based on this list, tests can be selected to include or exclude as many variations as possible.

Importance of Biochemistry in Pharmacy

Biochemistry has an eminent importance in pharmacy.The pharmaceutical industry relies heavily on biochemistry, as the systems in the bodywork with a wide variety of chemicals. Biochemistry works with hormones, enzymes, proteins, and cell interactions to understand what types of chemicals are needed to correct any imbalance without adversely affecting other chemicals produced in the body [18]. The important areas where biochemistry plays a major role are:

Importance of Biochemistry in Plants

Biochemistry helps in explaining the chemical reactions that have taken place in the plants and how we can optimise them to improve our productivity. Some of thesehas been discussed below:-

Human Genome Project

The Human Genome Project (HGP) was initiated in the year 1984 but was formally launched in October 1990 and completed in the year 2003. HGP was an international research project to classify the sequence of the human genome and the genes contained in it. The HGP's purpose is to classify all of the approx. 30,000 genes in human DNA but the project failed to get sequences of all human DNA. Only the ‘euchromatic’ regions which make up 92% of the human genome was sequenced [21].

The sequence of the three billion chemical base pairs that make up human DNA is calculated and this information is stored in the database. It develops data processi ng methods, transfers relevant technology to the private sector and tackles the ethical, legal and social problems that might occur in the project. Molecular medicine with HGP improves the diagnosis of disease, early detection of genetic predisposition to the disease, thus it can help in design drug, gene therapy and drug monitoring systems, and to form custompharmacokinetic drugs [22]. The ability to use the gene to treat a disease called gene therapy has captured the imagination of the biomedical community and has huge potential to treat or cure inherited and acquired diseases.

Environmental Biochemistry

Due to rapid modernization and exploitation of natural resources, there are rapid climatic changes taking place as well as an increase in environmental pollution. Therefore, Environmental biochemistry as a new discipline primarily deals with the metabolic (biochemical) responses and adaptations in man (or other organisms) due to environmental factors. It studies the microbial metabolism of contaminants with a focus on metabolite elucidation and its reactions. Every day we encounter or interact with different environmental pollutions that become highly poisonous when ingested or get absorbed in the body as shown in Fig. (4) the bio-magnification of pollutants. So studying the biochemistry of pollutants it is possible to study the behaviour, transformation of pollutants and how they can affect the biological functions of the body.

At the molecular level, the main steps that make up catalytic enzymes in the metabolism of pollutants are analyzed in terms of genetic, kinetic, and structural criteria. The knowledge gained will help us to develop tools and methods for improving and advancing the techniques for purification of wastewater, bioremediation process, formation and selection of microbes with certain physical properties and development of environmental friendly process to promote green chemistry.

Via biochemistry, we have been able to establish that some xenobiotics such as PCB, dioxinand DDT disrupt the normal function of the body by mimicking body hormones [21].

Biomarkers

Biomarkers or biological markers are observable measures of any biological condition or state. These are used to indicate exposure to xenobiotics present in the environment and species or their effect.

A biomarker can itself be an external substance (e.g., asbestos particles or NNK from tobacco), or a type of body-processed external substance (metabolite) that can usually be quantified. Biomarkers are major molecular or cellular events that associate specific environmental relationships with health outcomes. They play a significant role in understanding the relationships between exposure to environmental pollutants, chronic human disease development and detection of subgroups that are elevated risk of disease. There has been considerable progress in identifying and validating new biomarkers which can be used in population-based environmental disease studies as shown in Fig. (5), presenting various biomarkers and their applications.

Biosensors

These sensors have become very common in recent years, and they are applicable in various fields listed below:

Latest Developments in Environmentally Friendly Biosensors

For the detection and monitoring of various environmental contaminants, biosensors including immunosensors, aptasensors, genosensors, and enzymatic biosensors have been documented using antibodies, aptamers, nucleic acids, and enzymes as recognition elements [23]. Table 4 summarises recent biosensors used for monitoring the environment [23].

Gene Therapy

Gene therapy is the process of gene manipulation and insertion into cells to treat diseases. Newly introduced genes will encode proteins and repair the defect found in a genetic disorder. It involves gene manipulations in animals or humans in order to correct a disease, and maintain individual healthy. Gene therapy in theory is the ultimate solution for the treatment of genetic disease.

It involves isolating a particular gene, making its copies, injecting it into the target tissue cells to create the desired proteinas shown in Fig. (6). It is absolutely essential to verify that the gene is not harmful to the patients and is appropriately expressed. As of now due to several limitations, gene therapy has not progressed the way it should despite intensive research. But a breakthrough may come anytime, and this is only possible with persistent research. And a day may come when almost every disease will have gene therapy, as one of the treatment modalities. Hence, gene therapy can revolutionize the practice of medicine.

Gene therapy is categorized into two types: germline and somatic, which apply to humans.The purpose of germline gene therapy is to insert transgenic cells into the germ cell and somatic cell as shown in Fig. (7). This therapy cure the treated person and the gametes. Toinsert a new gene directly into a cell, scientists use a bioengineered medium called a “vector” for gene delivery.

For example, viruses have a natural tendency to transmit genetic material to cells, and so can be used as vectors. However, before a virus can be used to transfer therapeutic genes into human cells, it is modified to suppress its ability to cause infectious disease. Gene therapy can be used to alter cells within or outside the body. When performed within the body, a doctor injects the vector that contains the gene directly into the portion of the body that has faulty cells. In gene therapy that is used to change cells outside the body, a patient may take blood, bone marrow, or other tissue and isolate particular cell types in the laboratory. These cells are fed into the vector containing the desired gene. The cells are left in the laboratory to multiply and are then injected back into the patient, where they proceed to multiply and ultimately produce the desired result.