Module 2 - The Fundamentals of Building Blocks of Life PDF

Summary

The document details the fundamental building blocks of life in biology. It explores carbohydrates, proteins, lipids, and nucleic acids, explaining their structures and roles in living organisms. The document is suitable for undergraduate students studying biology or life sciences.

Full Transcript

SVKM's NMIMS University Elements of Biology

Module 2
The Fundamentals of Building Blocks of Life

Life can be conceptualized as the coexistence of all living things that adhere to the particular rules
of nature as well as the presence of a living thing. The fundamental components of all living things
are atoms, molecules at the chemical and biochemical levels and cells at the biological level.
Ancient scholars widely held the concept that the entire Universe is made up of tiny, non-divided
components like atoms, but the philosophers' viewpoints on the fundamental ingredient varied.

Nearly all life forms are largely composed of just four fundamental elements: hydrogen, oxygen,
nitrogen, and carbon. Organic materials, which have carbon elements, make up life. Carbon is
necessary for life because it combines with other atoms to produce huge, complex compounds like
protein, carbohydrates, lipids, and nucleic acid.

Proteins serve as the building blocks for cellular growth, maintenance, and reproduction in living
things. They are incredibly diverse and vital to life. Proteins are the building blocks of life's tissues,
muscles, and other structural elements. Furthermore, enzymes, which govern chemical reactions
in all living systems, are proteins.

Carbohydrates and lipids are two other essential macromolecules of living things that are required
for life. They largely provide energy for the costs of creation, maintenance, and reproduction.

Nitrogen-based substances are the building blocks of DNA, the blueprint for all life on Earth.
Nitrogen is also necessary for life. A nucleotide is the fundamental chemical unit in a nucleic acid,
which serves as the basis for both DNA and RNA (ribonucleic acid). Nucleotides, which are
composed of a pentose sugar, a phosphate group, and a nitrogen-containing base, are the
precursor to nucleic acids.

DNA is the blueprint for all life on Earth, and all major structures required for life to function and
reproduce can be built with the help of DNA.

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Unity in Diversity of Life

Despite the diversity of life, there is a fundamental unity in the molecules that make up living
organisms.

All living organisms are made up of cells, which are composed of molecules such as
carbohydrates, amino acids (building block of proteins), nucleic acids, and lipids.

These molecules are used to build and maintain the structure of cells, as well as to carry out
the chemical reactions necessary for life.

1. Carbohydrates
A class of chemical substances known as carbohydrates can be found in foods and living tissues
as starch, cellulose, and sugars. Carbohydrates contain oxygen and hydrogen in a 2:1 ratio, just
like water. Usually, it decomposes within the body of the animal to release energy.

Chemically, "optically active polyhydroxy aldehydes or ketones or the compounds which
produce units of such type on hydrolysis" is how carbohydrates are defined. This means that
carbohydrates are made up of molecules that have a specific chemical structure, with multiple
hydroxyl (-OH) groups and either an aldehyde or a ketone group.

The sucrose disaccharide, which can be obtained from either sugar cane or beets, is the
substance that most people refer to as "sugar". Sucrose is made up of glucose and fructose
molecules linked together. The sweetest disaccharide is sucrose. It has a sweetness level that
is roughly three times that of maltose and six times that of lactose.

Corn syrup, which is made when the polysaccharides in cornflour are broken down, has
recently taken the place of sucrose in numerous consumer products. Corn syrup is primarily
composed of glucose molecules, which are only around 70% as sweet as sucrose.

In addition to sucrose and glucose, other common carbohydrates found in food include
fructose, lactose, and maltose. These can be found in fruits, dairy products, and grains,
respectively. Carbohydrates are an important source of energy for the body, and they play a
critical role in various physiological processes.

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Classification of Carbohydrates:

Simple (Small) Carbohydrates:

Simple carbohydrates are a type of carbohydrate that consist of one or two sugar
molecules, also known as monosaccharides and disaccharides, respectively. These
naturally occurring sugars are found in a variety of foods, including vegetables, fruit, and
milk. Honey is a natural sugar alternative that is also considered a simple carbohydrate.

Because they are less complex than other types of carbohydrates, simple carbohydrates
are easier for the body to process. They are derived from foods that are naturally sweet,
such as fruits and sugary foods. However, consuming too many simple carbohydrates can
lead to certain health issues, such as insulin resistance and weight gain.

Monosaccharides are the smallest type of simple carbohydrate, as they contain just one
sugar unit. Examples of monosaccharides include glucose, fructose, and galactose.

Monosaccharides:

Monosaccharides are a type of carbohydrate that cannot be broken down into simpler
units of polyhydroxy aldehyde or ketone. They are the simplest form of carbohydrate
and are sometimes referred to as simple sugars.

A monosaccharide is classified as an aldose if it contains an aldehyde group and as a
ketose if it contains a keto group. Examples of aldose monosaccharides include glucose
and galactose, while examples of ketose monosaccharides include fructose.

Monosaccharides play an important role in cellular metabolism and are a primary
source of energy for the body. They are also used in the synthesis of more complex
carbohydrates, such as disaccharides and polysaccharides.

Disaccharide:

Disaccharides are a type of carbohydrate that are composed of two monosaccharide
units linked together by a glycosidic bond. Upon hydrolysis, the glycosidic bond is
broken, and the disaccharide is split into two separate monosaccharides.

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The two monosaccharides that make up a disaccharide can be either the same or
different. One of the most well-known disaccharides is sucrose, which is composed of
glucose and fructose units linked together. When sucrose is hydrolyzed, it breaks down
into its constituent monosaccharides of glucose and fructose.

Two other important disaccharides are maltose and lactose. Maltose is composed of
two glucose units linked together, while lactose is composed of a glucose unit and a
galactose unit linked together. Lactose is often referred to as milk sugar because it is
found in milk and dairy products.

In summary, disaccharides are a type of carbohydrate composed of two
monosaccharide units linked together by a glycosidic bond. Sucrose, maltose, and
lactose are three important disaccharides commonly found in foods.

Complex (Large) Carbohydrates:

Complex carbohydrates, also known as polysaccharides, are a type of carbohydrate that
consist of many sugar molecules linked together in long chains. They are found in foods
such as grains, potatoes, and beans, and can be either branched or unbranched.

Polysaccharides

Polysaccharides are a type of complex carbohydrate that consist of many sugar
molecules linked together in long chains. They can be classified based on their
composition and their function.

Based on composition, polysaccharides can be classified into two main categories:
homo- and heteropolysaccharides. Homopolysaccharides are composed of a single
type of monosaccharide unit, while heteropolysaccharides are composed of more
than one type of monosaccharide unit.

Examples of homopolysaccharides include starch, glycogen, and cellulose. Starch and
glycogen are storage polysaccharides found in plants and animals, respectively, while
cellulose is a structural polysaccharide found in plant cell walls.

Examples of heteropolysaccharides include chondroitin sulphate, which is found in
cartilage, and heparin, which is an anticoagulant found in the body.

Based on function, polysaccharides can be classified into two main categories:
structural and storage polysaccharides. Structural polysaccharides provide support
and rigidity to cells and tissues, while storage polysaccharides are used to store energy.

Examples of structural polysaccharides include cellulose, chitin, and peptidoglycan.
Cellulose is found in plant cell walls, chitin is found in the exoskeletons of insects and
crustaceans, and peptidoglycan is found in bacterial cell walls.

Examples of storage polysaccharides include starch and glycogen, which store energy
in plants and animals, respectively.

In summary, polysaccharides can be classified based on their composition as homo-
or heteropolysaccharides and based on their function as structural or storage

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polysaccharides. They play important roles in various physiological processes and are
a critical source of energy for the body.

Function of carbohydrates

Carbohydrates are essential for the proper functioning of the body and to provide it with energy. The
amount of carbohydrates a person needs may vary depending on their lifestyle, weight, and level of
activity. Consuming more complex carbohydrates and fewer refined carbohydrates can help ensure a
healthy diet. Making wise carbohydrate choices can also help maintain healthy blood glucose levels
and reduce the risk of related health problems.

Carbohydrates serve different functions in body:

Glucose, also known as blood glucose, is the primary source of energy for the body and is
present in the body as rings.
Fructose, also known as levulose, is found in foods such as fruit, honey, and corn syrup. It
enters the small intestine and travels to the liver, where it is processed by the glycolytic
pathway to become glucose.
Lactose is a disaccharide composed of glucose and galactose. It is found in milk and dairy
products and is either stored as glycogen or converted into glucose in the liver.
Ribose is a crucial sugar that is a component of ATP, which provides energy for cellular
processes, and other compounds.

Other important functions in the human body, including:

Providing energy for the body and maintaining healthy blood glucose levels.
Preventing the breakdown of fatty acids to avoid ketosis.
Playing a key role in biological recognition processes.
Serving as a sweetening and flavouring agent in foods.
Providing dietary fibre, which is important for healthy digestion and can have other health
benefits as well.

2. Proteins
Proteins are among the most important macromolecules found in living organisms,
characterized by their large size and high molecular weight. The term "protein" was coined by
Gerardus Johannes Mulder in 1802 and originates from the Greek meaning "of first rank."
Proteins constitute the second most abundant component in cells after water, accounting for
roughly 12% by weight. As a result, proteins form the majority of a cell's structural framework.

Chemically, proteins consist of carbon, hydrogen, oxygen, nitrogen and sulphur. Additional
elements like phosphorus and others occur in some proteins. Proteins exhibit a high degree of
order, comprising linear polymers of amino acids joined by peptide bonds. Polypeptides refer
to the linear amino acid polymers that make up proteins. Multiple polypeptide chains may exist
within a single protein. Many amino acids in a polypeptide are sequentially linked through a
peptide bond (-CO-NH-) formed between the carboxyl and amino groups of successive amino
acids.

Proteins are composed of monomers known as amino acids. Each amino acid contains an amino
group (-NH2), an acidic carboxyl group (-COOH), and a side chain (R group). Amino acids are

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referred to as -amino acids due to the presence of the amino group on the carbon adjacent to
the carboxylic acid group. In nature, there are 20 different amino acids that can be combined
in various ways to create numerous proteins. Each protein has a unique sequence of amino
acids.

The body can produce some amino acids, which are referred to as non-essential amino acids.
However, there are other amino acids that the body cannot synthesize and must obtain through
the diet, which are called essential amino acids. It is important to consume foods that contain
these essential amino acids to ensure proper protein synthesis in the body.

Structure Level of Protein (Protein Folding):

Proteins have four distinct structural levels: primary, secondary, tertiary, and quaternary structures.

Primary Structure:

The primary structure of a protein is determined by the sequence of amino acids in its
polypeptide chain. This sequence is
determined by the transcription
and translation processes used by
DNA.

The primary structure is essential
for a protein to function but does
not guarantee its functionality. The
locations of bends, folds, and
connections between various
lengths of the chain are
determined by the amino acid sequence.

Secondary Structure:

Polypeptide chains often exhibit a secondary structure that results from predictable coiling or
folding. This structure is maintained by intra or intermolecular hydrogen bonds between the
amino acids of the same or different polypeptide chains.

The two types of secondary structure are β-pleated sheets and α-helices. In the α-helix
structure, the polypeptide chain is spirally coiled, often in a right-handed way. The helix forms
random coils where it is less regular in some locations. In a helix, an amino acid's carbonyl (C=O)
is hydrogen linked to an amino acid's amino H (N-H) that is four amino acids along the chain.

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In contrast, the β-pleated sheet structure occurs when two or more polypeptide chain
segments align closely to each other. The structure is maintained by hydrogen bonds between
the carbonyl and amino groups of the backbone.

The term "pleated sheet" or "β-pleated sheet" is frequently used to describe this secondary
structure. The evolution, size, and geometry of secondary structure motifs are all heavily
influenced by protein secondary structure.

Tertiary Structure:

The tertiary structure of a protein refers to its overall three-dimensional structure. Further
coiling and folding of the helical polypeptide molecules lead to a complex yet distinct structure.

The protein molecule will flex and contort to find the state with the least amount of energy or
maximum stability. Tertiary structure is principally determined by the interactions between the
R groups of the amino acids that make up the protein. Hydrogen bonding, dipole-dipole
interactions, and hydrophobic interactions produce characteristic shapes, which serve as
molecular "safety pins" that firmly connect various polypeptide components. The biological
activity of a protein is heavily reliant on its tertiary structure.

Quaternary Structure:

Some proteins consist of multiple polypeptide chains, or subunits, which combine to form the
protein's quaternary structure. The quaternary structure is present in large proteins such as
hemoglobin, which has two α-chains and two β-chains, totaling four chains.

Functions of Proteins:

Proteins perform a number of functions in organisms. The main functions of proteins are as follows:

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Structural Proteins: Many proteins serve as building materials of cells and tissues. They take
part in the formation of colloidal complex of protoplast, cell membranes, organelles,
extracellular matrices, and fibres. Some proteins form supporting structures, e.g., elastin of
ligaments, collagen of tendons, cartilages, bone, and connective tissue. Keratin is the major
constituent of external protective structures of animals like hair, feathers, horny layers of skin,
nails, claws, hoofs, etc.

Enzymes: Many proteins function as enzymes to catalyze biochemical reactions that occur in
the living world. Enzymes play a key role in metabolism. Every enzyme is specific in action, e.g.,
amylase, protease, RuBisCO (Ribulose-1,5-bisphosphate carboxylase/oxygenase), which is the
most abundant enzyme found in plants and the principal enzyme involved in photosynthesis.

Carrier Proteins (Transport Proteins): Some proteins act as carriers that bind and transport
specific molecules across a membrane or in a body fluid. Haemoglobin of RBCs transports
oxygen in the body. RBCs contain haemoglobin (Hb), which is made up of 4 polypeptide chains
and contains an iron ion. Iron has a strong affinity for oxygen.

In the lungs, oxygen combines with haemoglobin to produce oxyhaemoglobin. In body cells,
oxygen is released and is able to diffuse into body cells. Other examples include proteins such
as myoglobin of muscles, which store oxygen, α-globulin of blood, which carries thyroxin and
bilirubin, and β-globulin, which transports vitamins A, D, and K, cholesterol, and ions in the
blood.

Receptors Proteins: A number of proteins present on the external surface of the cell membrane
act as receptor molecules. A receptor protein molecule receives chemical signals from outside
a cell. When such chemical signals bind to a receptor, they cause some form of cellular/tissue
response.

For example, when insulin is released in the blood, the receptor proteins present on cell
membranes bind with this insulin. This binding changes the permeability of the cell membrane,
and glucose can enter the cell through glucose channels.

Hormones: Some hormones are proteinaceous, e.g., insulin (sugar metabolism-regulating
hormone) and parathyroid hormone (calcium and phosphate transport-regulating hormone).
Hormones play a key role in the regulation of metabolism.

Contractile Proteins: Myosin and actin make the muscle fibres contractile to bring about
movements and locomotion. The contractile system is basically made up of the protein actin,
but association with myosin is essential for contraction.

Defensive Proteins: Some proteins act as antibodies (immunoglobulins) that participate in the
defence mechanism of the body.

Storage Proteins: These occur in milk, eggs, and seeds to nourish the young ones. They include
casein of milk, albumin of egg white, and glutelin in cereals.

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3. Lipids

The framework for the construction and operation of living cells is composed of lipids, which are
organic molecules containing hydrogen, carbon, and oxygen atoms. Lipids play a crucial role in the
body, making it essential to understand their structure and function to solve several metabolism-
related problems.

They constitute 18-25% of adult body mass
and are hydrophobic due to their insolubility
in polar solvents like water. Fatty substances,
lipids serve several purposes in the body.
They form a part of cell membranes and aid
in regulating the entry and exit of molecules
from cells. Lipids also support hormone
production, vitamin absorption, and energy
movement and storage.

Lipid metabolism involves oxidizing fatty
acids to generate energy and synthesizing
new lipids from smaller molecules. This metabolism is associated with carbohydrate
metabolism as glucose products are converted into lipids.

Lipids play an important role in biological systems because they are a major component of
the cell membrane, which acts as a mechanical barrier that separates a cell from its
surroundings and regulates the exchange of molecules between the cell and its
environment.

Some crucial properties of lipids are:

Lipids are greasy or oily nonpolar molecules that are stored in fat cells in the body.
A diverse class of substances known as lipids is mostly made up of hydrophobic tails
and a polar head group.
Lipids are organic compounds that are a source of energy and contribute to several
living processes.
Lipids are a class of chemicals that are characterized by their solubility in nonpolar
solvents and insolubility in water.

Types of Lipids:

Lipids are classified into two main categories: simple lipids and complex lipids. Triglycerides are a type
of simple lipid, while phospholipids, waxes, and steroids are all types of complex lipids.

1. Triglycerides: Fats and oils (simple lipid)
2. Phospholipids and sphingolipids (complex lipid)
3. Steroids (complex lipid)
4. Waxes (complex lipid)

Triglycerides: Triglycerides are a type of simple lipid that are composed of a glycerol molecule and
three fatty acids. They are the most common type of lipid found in the body and are primarily used
as a source of energy.

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Triglycerides can be classified into two main types based on the type of fatty acids they
contain: saturated and unsaturated. Saturated triglycerides have only saturated fatty acids,
which are solid at room temperature and are
typically found in animal products such as meat and
dairy. Unsaturated triglycerides have one or more
unsaturated fatty acids, which are liquid at room
temperature and are typically found in plant-based
oils such as olive oil and sunflower oil.

Triglyceride levels in the blood are often measured
as part of a lipid profile to assess the risk of
cardiovascular disease. High levels of triglycerides in the blood can be a sign of metabolic
disorders such as obesity, type 2 diabetes, and metabolic syndrome.

Some examples of foods that are high in triglycerides include fatty meats, fried foods, sugary
drinks, and processed snacks. Lifestyle changes such as a healthy diet, regular exercise, and
weight loss can help to lower triglyceride levels and reduce the risk of health complications.

Phospholipids:

Phospholipids are a type of complex lipid and a major component of cell membranes. They
have a unique structure with both hydrophobic and hydrophilic regions.

Phospholipids are found in various biological
membranes and play a critical role in
maintaining membrane structure and function.

Sphingolipids are another class of complex lipids
that are important components of cell
membranes, particularly in nerve tissue.

They are composed of a sphingosine backbone,
a fatty acid chain, and a polar head group, and
are involved in several cellular processes such
as cell signalling and membrane stability.

Steroids:

Steroids are a class of complex lipids that play important roles in the body, including regulating
metabolism, immune function, and reproductive processes.

They have a unique structure consisting of four fused rings and vary in the functional groups
attached to the rings.

Examples of steroids include cholesterol, which is important for cell membrane structure and
function, and hormone steroids such as testosterone and estrogen, which play roles in sexual
development and reproductive function.

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Steroids are synthesized from cholesterol and other precursors in various tissues, including the
adrenal glands, ovaries, and testes.

Abnormal steroid levels or function can lead to a variety of health problems, including
metabolic disorders, infertility, and cardiovascular disease.

Wax:

Waxes are a type of lipid that serve as protective coatings found on the surface of plants and
animals. They are composed of long-chain fatty acids and alcohols, and often have a high
melting point due to their highly saturated structure.

Examples of waxes include beeswax, which is produced by honeybees and used to make
honeycomb, and carnauba wax, which is derived from the leaves of a Brazilian palm tree and
used in various applications such as cosmetics, food, and automotive products.

In animals, waxes serve a variety of functions such as waterproofing feathers, fur, and skin,
and protecting against predators and parasites. In plants, waxes help to prevent water loss and
protect against UV radiation, pathogens, and herbivores.

Functions of Lipids:

Lipids provide more than twice as much energy per gram as carbohydrates and proteins.

Excess dietary carbohydrates, proteins, fats, and oils are stored in adipose tissue, which
provides thermal insulation and cushioning for the body.

Hydrogenation of triglycerides can be used to produce useful products such as cooking oil, and
saponification of triglycerides can be used to produce soaps.

Phospholipids and glycolipids are major constituents of cell membranes and are involved in
membrane structure and function. Phospholipids form lipid bilayers.

Cholesterol is an important steroid that serves as a precursor for the synthesis of other steroids
in the body.

Other important steroids include sex hormones, vitamin D, adrenocortical hormones, bile
acids, and bile salts.

Lipoproteins play an important role in transporting lipids and other molecules in the blood, as
well as in protein modification and recognition.

Waxes form protective coatings on the skin, fur, and feathers of animals, as well as on the
leaves and fruits of plants, and can help to prevent water loss and protect against
environmental damage.

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4. Nucleic acid:

Nucleic acid is a complex biomolecule that is essential for all forms of life. It is present in every cell of
an organism and plays a crucial role in the storage and transmission of genetic information. Nucleic
acid was first discovered in 1869 by Swiss biochemist Friedrich Miescher, who isolated a substance
from the nuclei of white blood cells and named it "nuclein." Nucleic acid is composed of nucleotides,
which are the building blocks of the molecule. Each nucleotide is composed of a sugar molecule (either
ribose or deoxyribose), a phosphate group, and a nitrogenous base.

Types of Nucleic Acid:

There are two types of nucleic acid: deoxyribonucleic acid (DNA) and ribonucleic acid (RNA).

DNA is a double-stranded, helical molecule composed of two complementary strands of
nucleotides. Each strand consists of a sugar-phosphate backbone with nitrogenous bases
extending from it. The nitrogenous bases in DNA are adenine (A), guanine (G), cytosine (C),
and thymine (T). The base pairing in DNA is always A paired with T and G paired with C.

DNA is the genetic material that carries the instructions for the development and function of
all living organisms. It is primarily located in the nucleus of eukaryotic cells and in the
nucleoid region of prokaryotic cells.

RNA is a single-stranded molecule composed of nucleotides. It is involved in various cellular
processes, including protein synthesis, gene regulation, and RNA processing. The nitrogenous
bases in RNA are A, G, C, and uracil (U), which replaces thymine in DNA. There are several

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types of RNA, including messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA
(rRNA).

mRNA is synthesized from DNA in the process of transcription and carries the genetic
information from the DNA to the ribosome, where proteins are synthesized.

tRNA is involved in protein synthesis by carrying amino acids to the ribosome, where they
are incorporated into the growing protein chain.

rRNA is a component of ribosomes, which are the cellular structures responsible for protein
synthesis.

RNA, on the other hand, is single-stranded and can have various structures. It is involved in
the synthesis of proteins and carries genetic information from DNA to ribosomes, where
proteins are synthesized.

Structure of Nucleic Acid:

The structure of nucleic acid is based on the arrangement of nucleotides. Each nucleotide
consists of a sugar molecule (either ribose or deoxyribose), a phosphate group, and a
nitrogenous base.

The nitrogenous bases in nucleic
acid can be either purines
(adenine and guanine) or
pyrimidines (cytosine, thymine,
and uracil). In DNA, the
nitrogenous bases are adenine,
guanine, cytosine, and thymine,
while in RNA, uracil replaces
thymine.

The sugar and phosphate groups in
nucleotides form the backbone of
the nucleic acid molecule, while
the nitrogenous bases extend
from the backbone and interact
with each other through hydrogen
bonds to form base pairs.

In DNA, the base pairs are always
adenine paired with thymine and
guanine paired with cytosine. The
base pairing in RNA is similar,
except that uracil pairs with
adenine instead of thymine.

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Function of Nucleic Acid:

Nucleic acids are biomolecules that store and transmit genetic information in cells. They are
composed of building blocks called nucleotides.

There are two types of nucleic acids: DNA and RNA. DNA is double-stranded and contains the
genetic instructions for an organism's traits. RNA is single-stranded and is involved in protein
synthesis and other cellular processes.

Nucleotides also have other functions in cells. They act as carriers of chemical energy (such as
ATP and GTP) and function as coenzymes for dehydrogenases or oxidases. These processes are
important for cellular metabolism and energy production.

Nucleotides also have a role in cellular communications and signal transduction. They can act
as intermediaries in signaling pathways and can regulate gene expression.

Overall, nucleic acids and nucleotides play a crucial role in the proper functioning of cells and
organisms.

In summary, nucleic acid is a complex biomolecule that plays a crucial role in the storage and
transmission of genetic information. Its structure and function are intimately linked, and
understanding these aspects is crucial for understanding genetics and cellular processes.

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Assignment

Q1. What are carbohydrates and how do they contribute to the body's energy needs?

Q2. What are the differences between simple and complex carbohydrates? What are some examples
of each?

Q3. How do polysaccharides like starch, cellulose, and glycogen differ in structure and function? Where
are they found in the body?

Q4. What are some health benefits of consuming complex carbohydrates like whole grains, fruits, and
vegetables? How can consuming too many refined carbohydrates contribute to health problems?

Q5. What are proteins and what are they made of? What are the different levels of protein structure?

Q6. What are the two types of secondary structure in proteins? What is the tertiary structure of a
protein and what determines it? What is the quaternary structure of a protein and when does it occur?

Q7. What are some of the functions of proteins in the body? How do proteins contribute to structural
support, enzyme catalysis, transport, and defence?

Q8. What are lipids and why are they important in the body? How are lipids classified and what are
some examples of each type?

Q9. What are phospholipids and why are they important in cell membranes? What are waxes and what
are their functions in plants and animals?

Q10. How do lifestyle changes such as a healthy diet and exercise affect triglyceride levels in the body?

Q11. What is nucleic acid and what is its role in cells? What are the two types of nucleic acid and how
do they differ in structure and function?

Q12. What are the building blocks of nucleic acid and how are they arranged to form the molecule?

Q13.What are some of the functions of nucleic acid and nucleotides in cells, including energy
production, cellular communication, and gene regulation?

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