Science - Biomolecule PDF

Summary

This document discusses biomolecules, including carbohydrates, nucleic acids, proteins, and lipids. It explains their roles in living organisms and their interrelationships. The material is suitable for a secondary school science class.

Full Transcript

Biomolecule

Chapter
Biomolecule
9
The following topics are discussed in this chapter:
5 What is Organic molecule
5 Biomolecules
5 Major organic molecules
5 carbohydrates
5 Nucleic acid
5 protein
5 lipids
5 Interrelationships of organisms

The coexistence of plants and animals forms our beautiful biosphere. You must
want to know where they all came from. Are all animals created from the same
material or are there any differences in origin between plants and animals? Again,
humans can eat green vegetables, but cannot digest grass. But the main food of
cows is grass. That means all plants and animals must have some structural
differences that set them apart. Generally, many molecules are directly involved
in the formation of living organisms, they are called biomolecules. In this chapter
we will discuss organic molecules.

9.1 Biomolecule
Living cells are made up of numerous molecules. These molecules include small
molecules and large molecules which are collectively known as biomolecules. These
biomolecules are generally composed of more than 25 elements, of which six elements
are considered as common components of biomolecules. These are carbon (C), hydrogen
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(H), nitrogen (N), oxygen (0), phosphorus (P) and sulfur (S). The abbreviation of the
English spelling of all these basic substances is CHNOPS. As you have already read
in detail about cells, all cells are made of these organic molecules. Carbon is the most
important atom among the six atoms of CHNOPS in terms of the structure of the living
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Vapor

Electric conductor

Direction of transmission
Spark

H2O CH4
NH3 H2

Gas

Cooling
System

Cool water
Water
Heat

Figure 9.1. Miller-Urey's experiments on the synthesis of organic
molecules from inorganic molecules.

world. That is why it is said that carbon is the basis of life on earth
Organisms are made up of four types of biochemical substances namely carbohydrates,
proteins, nucleic acids and lipids. Without these two organic chemicals, proteins and
nucleic acids, living things are not made. From this it can be assumed that organic
molecules were formed from the beginning of creation and as a result of various
chemical reactions they were combined to form the first cells. Scientists believe that
lightning or frequent electrical storms, and strong solar radiation accelerated some
chemical reaction that led to the formation of these organic molecules from inorganic
molecules on primeval Earth. To prove this idea, in 1953, scientists Stanley Miller
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and Harold Urey created an artificial model of an early Earth in the laboratory (Figure
9.1). Where in a completely enclosed system, a mixture of water, methane, ammonia
and hydrogen was constantly circulating on the ancient Earth. There were electrical
discharges simulating the lightning of that time. After a week, they saw the synthesis
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Lipid Nucleic acid Carbohydrate Protein

Figure 9.2. Four types of organic molecules
of organic molecules called amino acids, that is, they proved that it is possible to create
organic molecules from inorganic molecules in the natural environment.

The basic components of living organisms, carbohydrates, proteins, nucleic acids
and lipids are made up of biochemical substances called biopolymers of cells. For
example, carbohydrates are simple sugars, proteins are amino acids, nucleic acids are
mononucleotides, and lipids are biological polymers of fatty acids. In this chapter we
will discuss these four types of biomolecules (Figure 9.2).

9.2 Carbohydrates
Carbohydrates are an important
structural, storage and
energy source of the body.
Carbohydrates are complex
natural organic compounds
that mainly consist of carbon
(C), hydrogen (O) and oxygen
(O) elements. Carbohydrates
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contain carbon, hydrogen and
oxygen atoms in the ratio of Figure 9.3: C₂H₂O of glucose, type molecule: CHO
1:2:1

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Carbohydrates are produced from carbon dioxide and water in the presence of sunlight
and with the help of chlorophyll in the process of photosynthesis in the green part. A
large part of our daily diet consists of sugars or carbohydrates. Carbohydrates are one
of the main 7 nutrients (water, carbohydrates, fiber, fat, protein, vitamins and minerals)
related to nutrition in our body. Carbohydrates provide our body with necessary energy
and if present in excess, it gets stored in the body as fat. After the breakdown of sugar
in the body, it is divided into various small sugar molecules and when it reaches the
smallest part in stages, it is absorbed in various parts of the body.

You all know that carbohydrates can be classified in several ways,. A type of
carbohydrate that is sweet in taste, granular and soluble in water is known as sugar.
Glucose (Figure 9.3) is an example of a sugar. The other is starch, which is not sweet,
granular and insoluble in water. Rice, flour, potato etc. from our familiar plants contain
large amounts of starch.

Carbohydrates can be divided
into several categories
on the basis of molecular
structure, molecular weight
and chemical religion.
Monosaccharides are the
smallest and simplest units 2- Deoxyribose Ribose

among them. It serves as Figure 9.4. Two types of pentose sugars
the building block of other
complex carbohydrates. Their common symbol is CnH2nOn. If the number of carbon
atoms in their molecule is 5, it is called a pentose sugar. Figure 9.4 shows two pentose
sugar molecules, one a deoxyribose sugar and the other a ribose sugar. Ribose and
deoxyribose sugars are structurally similar but the only difference is that one carbon of
deoxyribose sugar does not have oxygen.

As you read about nucleic acids, you will see that this pentose sugar is one of the main
components of nucleic acid, a very important biological molecule in life
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Physiological role of carbohydrates:

1. Carbohydrates are the main source of energy in the body. Carbohydrates are broken
down into glucose when ingested as food, and most cells use this glucose for energy or

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store it as glycogen in the liver and muscles for future use.

2. Glucose from carbohydrates serves as the sole energy supplier for the brain and
central nervous system.

3. Carbohydrates provide energy to the body's muscles. Glycogen is one of the heart's
main sources of energy.

4. Carbohydrates ensure that protein is not diverted from its intended vital physiological
function and converted into energy.

5. Complex carbohydrates such as indigestible carbohydrates and cellulose, pectin help
in the formation and elimination of stool.

6. Adequate fiber-rich complex carbohydrates in the diet regulate blood glucose levels.

9.3 Nucleic acid
Nucleic acids are actually large organic molecules, which are essential for every living
organism. The organic molecules present in the chromosomes and ribosomes of the
nucleus are called nucleic acids. In addition to the nucleus and ribosomes, mitochondria
and plastids contain nucleic acids. Nucleic acid A type of organic molecule composed
of a pentose sugar, a nitrogenous base or base, and phosphoric acid, which controls all
activities of an organism, including the process of heredity.

There are two types of nucleic acids, DNA and RNA.

9.3.1 DNA
DNA or de-oxyribonucleic acid is the most important permanent chemical molecule in
the cell. It contains and controls all the biological functions and hereditary characteristics
of the cell or the organism as a whole. All living cells except a few viruses contain
DNA. Chromosomes are made up of DNA and some proteins. DNA is attached to
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these proteins to form long threads, known as chromosomes. DNA can also be found in
mitochondria and plastids. The amount of DNA in the cells of certain species is fixed.
DNA is a type of chemical organic compound whose molecules are made up of many
small molecules called nucleotides. Figure 9.5 shows the structure of DNA.

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Two strands of the helical
structure is made of sugar Nucleotide
and phosphate molecules
Nitrogen base
5’
Phosphate
4’ 1’
Adenine attached to Thymine (Carbon Number)
(A-T) and Guanine attached to
3’ 2’
Cytosine (G-C)
Pentose Sugar The opposite
A strands are attached
One turn in-
(3' to 5' and 5' to
cludes 10 nucle- T 3') side by side
otides (3.4 nm)
C 3' 3'→5'
G

1 nm

Major groove
0.34 nm

5'→3'
Minor groove

NH2 O O NH2

N N N NH NH N
2 nm
N N NH2 N O N O
H N H H H
Double stranded DNA dou-
Adenine (A) Guanine (G) Thymine (T) Cytosine (C)
ble helix looks like a spiral
staircase Purine Pyrimidine

Nitrogen Base
Figure 9.5 The structure of DNA.

You can see in the diagram that each nucleotide is made up of a pentose sugar, a
phosphate group and a nitrogenous base or base. Nucleic acids contain two types of
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pentose sugars. One of these is ribose sugar and the other is deoxyribose sugar. The
pentose sugar in DNA is the deoxyribose sugar. DNA has four nitrogenous bases which
are adenine, guanine, cytosine and thymine.

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DNA is a spiral structure of numerous nucleotides with two strands, one of which is a
strand complementary to the other. Two DNA strands or strands of a DNA molecule
twist around each other to form a spiral shape called a double helix structure. Scientists
James Watson and Francis Crick proposed the DNA double helix model of the physical
and chemical structure of DNA in 1953, which earned them the Nobel Prize in 1963.

Functions of DNA:
5 Possesses and controls all the characteristics of the organism.
5 Acts as a structural component of chromosomes.
5 Acts as the molecular basis of heredity.
5 Life acts as a regulator of all physiological and biological functions.
5 When the structure of DNA is disturbed, it repairs itself.
5 It plays a key role in evolution by creating variation through mutation.

9.3.2 RNA
RNA or ribonucleic acid exists in the cytoplasm of cells free or associated with
ribosomes. The main difference between RNA and DNA is that it is not double-
stranded like DNA, but a single chain of nucleotides (Figure 9.6).

In the case of some viruses (eg Covid virus or SARS-Cov-2.) DNA is missing. That
is, all viruses that are not made up of DNA have RNA as their nucleic acid. In
these cases RNA acts as the genetic material.

RNA is mainly of three types. Ribosomal RNA (Ribosomal RNA or rRNA), messenger
RNA (Messenger RNA or mRNA), and transfer RNA (Transfer RNA or tRNA). We
get an idea of the function of these RNAs when we read about the synthesis or
structure of proteins

Function of RNA :
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5 The main function of RNA is to synthesize proteins.
5 Carrying messages from DNA to ribosomes.
5 Carrying hereditary characteristics.
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9.4 Protein
Protein is one of the most important biochemical substances and large complex organic
molecules in living organisms. Gerrit Müller first used the term protein in 1838. Different
types of proteins are made inside a cell, which play many important roles in the body.
Biological reactions in cells are controlled by a variety of enzymes, antibodies, and
hormones—all of which are proteins. It is also essential for the structure, function and
regulation of body tissues and organs. Since more than one amino acid is arranged to
form a protein, before knowing about protein, we need to know a little about amino
acid.

Amino Acid 20 different types of amino acids (Figure 9.7) combine in different
arrangements to form the primary structure of a protein. Primarily proteins are long
chains made of amino acids. The primary structure of each protein differs from each
other due to differences in the arrangement of amino acids.

You already know about the arrangement of nucleotides in DNA (ATGC). The
arrangement of amino acids depends on the arrangement of these nucleotides. Usually
three bases combine to form a signal for the addition of an amino acid. The carboxyl
group of one amino acid joins with the alpha amino group of the next amino acid to form
a peptide bond. Thus a polypeptide chain or protein is formed as a result of the joining
of numerous amino acids.

It should be noted here
that out of 20 amino acids,
11 can be synthesized
in the human body, the
remaining 9 must be
obtained from food.

Protein synthesis
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Amino Acid Side Carboxyl Group
Figure 9.8 shows the Chain
process of protein
synthesis. A T nucleotide Figure 9.7 : Structure of Amino Acid

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is converted to a U when making RNA from DNA. Three nucleotides are linked by one
amino acid in a polypeptide chain.

Functions of Protein
(1) Food containing protein provides energy to our body and helps in physical growth
and maintenanc

(2) Helps in numerous biochemical reactions inside and outside the cell.

(3) Some protein hormones are chemical messengers, they help in communication
between body tissues and organs.

Amino Acid
Ribosome tRNA
Larger part Smaller part
tRNA carrying
amino acid to
tRNA left and
ribosome
amino acid is
Cytoplasm kept

Nucleus
mRNA
mRNA translation
Gene mRNA
Ribosome adding
tRNA left and translation
amino acid to protein
amino acid is kept chain
DNA

RNA
Protein Chain mRNA trans-
lation

DNA RNA mRNA Protein

Figure 9.8: Different steps of protein synthesis
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(4) Proteins play an important role in regulating and maintaining the balance of acid
and alkali concentrations in the blood and other body fluids.

(5) Proteins help our body produce antibodies to fight infections from foreign
microorganisms.
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9.5 lipids
Lipid refers to fatty substances composed of carbon, hydrogen and oxygen. Lipids are
important biochemical substances in plant and animal bodies. It plays important roles
in cell structure, energy storage, thermoregulation and intercellular communication.
In 1940 German scientist Bloor first used the term lipid. Lipids are generally found in
animal and plant oils and fats. It is abundant in various parts of plant body especially
fruits and seeds.

Lipids are almost insoluble in water but soluble in solvents such as ether, alcohol,
benzene, chloroform, acetone, petroleum etc. Lipid is colorless, tasteless and odorless,
has no specific melting point, its melting point increases with increasing molecular
weight. The relative importance of lipids is less than water, lipids float on water because
they are lighter than
water. At normal Protein spike to infect
temperatures, some host

lipids are liquid and
some lipids are solid.
Lipid membrane
Lipids that are in solid
form are called fats
and lipids that are in
liquid form are called Genetic material
oils.

Since lipids are
hydrophobic, they act Figure 9.9. Corona virus
as cell membranes.
Due to the lipid membrane of the corona virus (Figure 9.9), which is responsible for the
worldwide corona epidemic, it was possible to inactivate the virus by penetrating the
membrane very easily with soap, disinfectant or some alcohol. That's why during the
covid epidemic, a lot of importance was given to hand washing with soap or sanitizing
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hands for health protection.

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Functions of Lipids:
(1) Lipids combine with proteins to form lipoproteins, which are involved in energy
production processes.

(2) A type of lipid called phospholipids acts as a component in various membrane
structures.

(3) A type of lipid plays a special role in the photosynthesis process of plants.

(4) Lipids such as fats and oils are stored in the plant body as food. of various oilseeds.
Lipids are ingested during germination.

(5) Waxy lipids form a layer on the outer coat of leaves to prevent excessive transpiration
and it also protects the plant from various insect attacks.

9.6 Interrelationships of Biomolecules
You already know that the major biomolecules of living organisms are carbohydrates,
nucleic acids, proteins, and lipids. Each of these biomolecules is related to each other
in structure and in carrying out biological functions. Below is a brief discussion on this
topic

Carbohydrates and Nucleic Acids: We have learned in the discussion that all living
organisms. DNA controls physiological and biological functions, one example of
which is cell division. This nucleic acid called DNA contains the genetic information
of an organism. If you look at the structure of DNA, you will see that it is made up of
a peltose sugar called deoxyribose, which is a carbohydrate.

Carbohydrates and lipids: Carbohydrates are sometimes converted to glucose used as
immediate energy, or stored as glycogen in the liver or muscles. Excess glucose is
stored as long-term energy in a lipid called triglycerides.
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Carbohydrates and Proteins: Carbohydrates can be directly attached to proteins in a
process called glycosylation to convert into protein structures.

Proteins and Nucleic Acids: Proteins make up the structural components of our bodies,

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and they regulate essential reactions. The messages stored in DNA are expressed by
making proteins. A type of protein called histone helps bind nucleic acids.

Proteins and lipids: A lipid called a phospholipid is essential for building the membrane
of most cell membranes and often forms a lipid bilayer. By attaching proteins to this
lipid bilayer, it creates channels, receptors or transporters that open the way for the
movement of various types of organic molecules through the membrane..

You must realize that organic molecules are intimately related to each other in order to
keep the living world functioning. If there is a disturbance in this relationship, various
types of complications are created in the activities of the living world

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