LECTURE-1-BIO111 BIOMOLECULES-AND-CELLS ( CELLS-CYTOLOGY).pdf

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BIOMOLECULES AND
CELLS: BIO 111
Mr. Derrick Banda MSc, BSc
 How to get in touch with Mr Derrick Banda

Office: Mulungushi University, Main Campus, SSET Offices

E-mail: [email protected] or [email protected]

Phone Number: +260974420585
: +260955556060
 METHODS OF TEACHING
Lectures: Four (4) hours per week
( Two (2) hours each lecture session)

Tutorials: One (1) hour of tutorials per week

Laboratory sessions: Three (3) hours per week
 ASSESSMENT METHODS
Continuous Assessment (CA): 40%
Theory Quizzes : 5%
Two (2) tests 20%
Laboratory experiments 15%

Final Examination 60%

Maximal Score (CA + Final Exams) 100%
 COURSE GRADINGS
GRADE PERCENTAGE
A+ 86 and above
A 76-85
B+ 66-75
B 60-65
C+ 55-59
C 50-54
D Below 50
 LECTURE 1:
CELLS - CYTOLOGY
 Introduction to Cells
The living material of most organisms is organized into
discrete units called cells.

The study of cell and their features is known as cytology.

The earliest phase of cytology began with the English
scientist Robert Hooke’s microscopic investigations of
cork (plant) in 1665.
 How Did Cells Originate?
In general terms, life can only have come from one of two possible
places:

1. Spontaneous creation - Random chemical processes created the first
living cell. This is the theory that most scientists today believe
in today. It is believed by some scientists that the accidental
creation of a single molecule of self-replicating RNA (similar
to DNA) in the oceans of the world led to the eventual
creation of cells.

2. Supernatural creation - God or some other supernatural power
created the first living cell.
 Levels of Organization of Living Things
The biological levels of organization of living things arranged from the
simplest to most complex are: atom, molecules, macromolecules,
organelles, cells, tissues, organs, organ systems and organisms.

HUMAN BEING
 The Cell Theory
The history of cell theory is a history of the actual observation of
cells, because early prediction and speculation about the nature of the
cell were generally unsuccessful.

The decisive event that allowed the observation of cells was the
invention of the microscope in the 16th century, after which interest in
the “invisible” world was stimulated.

The remarkable structural complexity of the cell is more fully revealed
at the higher magnifications attainable with the electron microscope.
 The Cell Theory
English physicist Robert Hooke, who described cork and
other plant tissues in 1665, introduced the term cell because
the cellulose walls of dead cork cells reminded him of the blocks of
cells occupied by monks.

The term cells was coined by Hooke in this work, describing the pores
observed in the cork.
 The Cell Theory
The magnifying powers of the microscope and the inadequacy of
techniques for preparing cells for observation precluded a study of
the intimate details of the cell contents.
The inspired Dutch microscopist Antonie van Leeuwenhoek, beginning
in 1673, discovered blood cells, spermatozoa, and a lively world of
“animalcules.”
 The Cell Theory
German physiologist Theodor Schwann and German
biologist Matthias Schleiden clearly stated in 1839 that cells are the
“elementary particles of organisms” in both plants and
animals and recognized that some organisms are unicellular and
others multicellular.
 The Cell Theory
The cell theory was later extended by Rudolf Virchow to include the
idea that all cells arise from existing cells.

Rudolf Virchow, a German pathologist (1821–1902), famously wrote
“omnis cellula e cellula”—all cells come from other cells.
 Summary of the Cell Theory
The generally accepted modern Cell Theory is as follows:
1. The cell is the fundamental unit of structure and
function in living things.
2. All living organisms are made up of one or more
cells.
3. All new cells arise only from pre-existing cells
4. All biochemical processes are carried out by cells.
The cell theory established forms one of the unifying
principles of biology.
 Types of Cells
Cells are of two types: eukaryotic, which contain a
nucleus, and prokaryotic, which do not.

Prokaryotes are single-celled organisms, while
eukaryotes can be either single-celled or
multicellular.
Eukaryotic and Prokaryotic Cells
 Prokaryotic Cells
Prokaryotes are unicellular organisms that lack membrane-bound
structures, the most noteworthy of which is the nucleus. They have cell
membrane, cytoplasm and ribosomes.

Prokaryotic cells tend to be small, simple cells, measuring around 1-10
μm in diameter.

In prokaryotic cells, DNA bundles together in a region called the
nucleoid.
Prokaryotic organisms include bacteria and archea.
 Prokaryotic Cells
Prokaryotic cells tend to be small, simple cells, measuring around 1-10
μm in diameter.
 Eukaryotic Cells
Eukaryotic cells have a nucleus and other organelles enclosed by a
plasma membrane.

Organelles are internal structures responsible for a variety of functions,
such as energy production and protein synthesis.

Eukaryotic cells are large (around 10-100 μm) and complex. While
most eukaryotes are multicellular organisms, there are some single-cell
eukaryotes.

Eukaryotic organisms include: Protozoans, Algae, Fungi, Plants and
Animals
 Eukaryotic Cells
Eukaryotic cells are large (around 10-100 μm) and complex. While
most eukaryotes are multicellular organisms, there are some single-cell
eukaryotes.
 Prokaryotic versus Eukaryotic Cells
Prokaryotic cells and eukaryotic cells differ in a number of key features,
including:
 Organelles
An organelle is a subcellular structure that has one or more
specific jobs to perform in the cell, much like an organ does in the
body.
Cells organelles are found in the Cytoplasm. Within cells, each
structure carries out specific cellular functions.

Cell organelles are embedded in the cytoplasm and are divided into:
Membrane-bounded organelles (rough and smooth endoplasmic
reticulum, Golgi apparatus, mitochondria, chloroplasts (in plant cells)
,lysosomes, peroxisomes)

Non-membrane-restricted organelles such as ribosomes or centrioles
Cell Organelles
 Cytoplasm
The cytoplasm is the site in which the biochemical reactions of the cell take place.
It is mainly composed of water, salts, and proteins.
The primary semi-fluid component of the cytoplasm is known as the Cytosol.

All of the organelles in eukaryotic cells, such as the nucleus, endoplasmic
reticulum, and mitochondria, are located in the cytoplasm.
 Cytoplasm
In prokaryotes the cytoplasm encompasses everything within the
plasma membrane, including the cytoskeleton and genetic material.

In eukaryotic cells, the cytoplasm comprises everything between the
plasma membrane and the nuclear envelope, including the organelles.
 Nucleus
The word 'nucleus' can mean the control centre of a cell or the
centre of an atom. It is responsible for determining and controlling
what a cell look like and what it does.

The nucleus is the largest membranous organelle of the cell.

It contains the chromosomes together with the machinery
for DNA replication and RNA transcription and processing.

The nucleus directs the process of protein synthesis in
the cytoplasm by informational macromolecules (RNAs) formed in the
nucleus and transported to the cytoplasm.
 Parts of the Nucleus
Parts of the nucleus includes;
i. The nucleus envelope with nuclear pores encloses the nucleus and keeps
it separated from the rest of the cell.

ii. It contains chromatin, which is a substance within a chromosome consisting of
DNA and protein (histones).
iii. In the middle of the cell is the nucleolus which produces ribosomes, which
are key in protein synthesis.
 Nucleoid
In contrast, the smaller prokaryotic cells have no nucleus. The materials
are already fairly close to each other and there is only a "nucleoid"
which is the central open region of the cell where the DNA is located.
 Nucleoid
Nucleoid is an area in the cytoplasm which houses the prokaryotes’
genetic material (DNA). It is an irregular-shaped region.

The nucleoid is not surrounded by nuclear membranes, unlike
eukaryotic nucleus. A single, circular chromosome can be found in the
nucleoid of prokaryotes.
 Mitochondria
The mitochondria is the power house of the cell. Its only found
in eukaryotic cell.

It carries a process called aerobic respiration, which is breaking
down of food and provide energy with the help of oxygen.

They produce energy molecules called ATP (adenosine
triphosphate) which is used as an energy currency powering
everything the cell needs to do.
 Mitochondria
The mitochondrion has a fluid that fills the organelle containing
enzymes and other compounds called the matrix. Inside the
mitochondrion is the inner membrane which has folds called cristae.

Mitochondria contain their own DNA and ribosomes.
 Mitochondria
Each mitochondrion is surrounded by two membranes: outer and inner,
which define two mitochondrial compartments;

1. The intermembrane space, the compartment located between the two
membranes.
2. The matrix space, the compartment enclosed by the inner membrane.
 Chloroplasts
The chloroplast in an organelle that is unique to plants. It contains
chlorophyll, which is what make a plant green.
Chloroplasts convert light energy into chemical energy via the
photosynthetic process.
 Structure of Chloroplast
Thylakoids are small compartments found inside the chloroplast, it
contain all the chlorophyll and its main role is to absorb sunlight and
allow photosynthesis to occur. The thylakoids are surrounded by a
liquid portion of the chloroplast called stroma.
 The origin of mitochondria and chloroplasts
Mitochondria and chloroplasts likely evolved from engulfed prokaryotes that
once lived as independent organisms.

At some point, a eukaryotic cell engulfed an aerobic prokaryote, which
then formed an endosymbiotic relationship with the host eukaryote,
gradually developing into a mitochondrion. Eukaryotic cells containing
mitochondria then engulfed photosynthetic prokaryotes, which evolved
to become specialized chloroplast organelles.
 Ribosomes
Ribosomes are granules found in both eukaryotic and prokaryotic cells,
consisting of one third proteins and two thirds ribosomal RNA (rRNA).
There are two types of ribosomes - free ribsomes and attached
ribosomes. The attached ribosomes are bound to the surface of the
endoplasmic reticulum and they are the site for protein synthesis.

They are present in all cells especially abundant in cells where protein
synthesis is taking place.
 Ribosomes
Each ribosome is formed of two subunits, a small subunit, and a large
subunit.
The ribosomes of the eukaryotic cells are larger than prokaryotic
ribosomes i.e. 80S compared to 70S.
 Peroxisomes
Peroxisome, membrane-bound organelle occurring in the cytoplasm of
eukaryotic cells.They are mainly located in the liver and kidney.
Peroxisomes contain enzymes peroxidase and catalase that oxidize fatty
acids and amino acids. Those oxidation reactions produce hydrogen
peroxide, which is the basis of the name peroxisome.

Hydrogen peroxide is toxic to the cell. Peroxisome’s also catalase that
convert hydrogen peroxide to water and oxygen, thereby neutralizing the
toxicity.
 Endoplasmic reticulum
The endoplasmic reticulum forms the most extensive membrane
system in the cytoplasm.The ER has two types:

1. Rough endoplasmic reticulum (rER).

2. Smooth endoplasmic reticulum (sER).

Both types form a single membrane system but their histological
appearance, relative proportions, and functions vary in different cell types.
 Endoplasmic reticulum (ER)
The Endoplasmic Reticulum has two types:
1. Rough endoplasmic reticulum (rER).
2. Smooth endoplasmic reticulum (sER).
 Rough endoplasmic reticulum
Abundant in liver cells and protein-synthesizing and secreting cells e.g.
pancreatic acini, fibroblasts, and plasma cells

The function of Rough endoplasmic reticulum includes;
1. Synthesis of secretory proteins e.g. hormones and enzymes.
2. Synthesis of lysosomal proteins, enzymes, and proteins inserted into
the cytoplasmic membranes.
3. Modification of the newly-formed protein including folding, initial
glycosylation and sulfation.
4. Transport the newly-synthesized protein to the Golgi body by
transport vesicles.
 Smooth endoplasmic reticulum
The smooth ER is where the synthesis of lipids, phospholipids and
steroids take place and it is also where the metabolism of carbohydrate
take place.
 Smooth endoplasmic reticulum
Abundant in liver cells and steroid-secreting cells e.g. the adrenal
cortex, testis, and ovary.

The functions of smooth endoplasmic reticulum includes:
1. Synthesis of membrane lipids, phospholipids, and cholesterol.

2. Synthesis of steroid hormones.

3. Detoxification of toxic substances e.g. alcohol and drugs.

4. Stores and regulate calcium ions during muscle contraction.
 Golgi Apparatus
The Golgi apparatus also called the Golgi body, is a membrane bound organelle
within the cytoplasm. It is composed of flattened membranes called cisternae.

The Golgi apparatus works closely with the rough endoplasmic reticulum. It
receives protein from the rough endoplasmic reticulum.
They process and package proteins and other macromolecules, especially proteins
destined to be exported from the cell.
 Golgi Apparatus
Proteins produced in the Rough ER, reach the cis-Golgi by means of
transport vesicles, after which they are then modified and processed
(phosphorylation, sulfation, glycosylation) within the Golgi apparatus
and sorted with regards to their destination.

At the trans-site, the packaging in secretory granules or vesicles takes
place.
 The function of the Golgi apparatus
1. Post-translational modifications of proteins previously-synthesized in
rER through removal, addition or modification of sugars.

2. Packaging of different proteins in the membrane-bounded vesicles.

3. Sorting and targeting of vesicles to the right destination

4. Formation of lysosomes (in clathrin-coated vesicles) to remain inside
the cell.
 Lysosomes
A lysosome is a membrane-bound cell organelle that contains digestive
enzymes. A lysosome are packaged by Golgi Body.

They have an acidic pH (4.5 – 5) as well as a high content of hydrolytic
enzymes such as hydrolases, proteases, lipases, nucleases and amylases
among other things.
 Functions of Lysosomes
Lysosomes serve two major functions:
1. Intracellular Digestion
To digest food, the lysosome membrane fuses with the membrane of
food vacuole and squirts the hydrolytic enzymes inside.
The digested food then diffuses through the vacuole membrane and
enters the cell to be used for energy and growth.

2. Autolytic Action
Cell organelles that need to be get ridden are covered by vesicles or
vacuoles by the process of autophagy to form autophagosome.
The autophagosome is then destroyed by the action of lysosomal
enzymes.
 Functions of Lysosomes
Processes in which lysosomes play crucial roles include:
a. Autophagy
A normal physiological process that deals with the destruction of cells in the
body. It is essential for maintaining homeostasis, for normal functioning by protein
degradation, turnover of destroyed cell organelles for new cell formation.

b. Heterophagy
The taking into the cell of exogenous material by phagocytosis or pinocytosis and
the digestion of the ingested material after fusion of the newly formed vacuole
with a lysosome.
 Vacuoles
A vacuole is a membrane-bound cell organelle.
Vacuoles are more prominent in plant cells than that of the
animal cells.
A plant cell has only one centrally placed vacuole which helps to maintain
the cell shape.The membrane of the vacuole is called tonoplast.
 Types of Vacuoles
There are mainly four types of vacuoles based on their contents.They are:
1. Sap vacuoles: Sap (fluid) consists of water, inorganic molecules, organic
molecules and enzymes.They maintain turgidity or turgor of the plant cells.

2. Contractile vacuoles: They prevent too much water from accumulating in a
cell and swelling it to bursting point. This process is called osmoregulation.
E.g fresh water protozoans like amoeba and paramecium.

3. Food vacuoles: They help in internalization and digestion of food. E.g in
protozoan protists and sponges.

4. Gas vacuoles: They store gases and regulate buoyancy of the cell. E.g in
bacteria.
 Functions of vacuoles
Functions of vacuolar system of the cell are as below:
1. The main function of the vacuole is to store both nutrient and non-
nutrient chemicals and also break down complex molecules.

2. Isolation of harmful material from the cytoplasm of the cell.

3. Export unwanted substances from the cell

4. Maintains the pH of the cell.

5. Maintains the osmotic pressure within a cell
 Cell wall
Cell wall is specialized form of extracellular matrix that surrounds
every cell of a plant. It is responsible for many of the characteristics that
distinguish plant cells from animal cells.
The cell wall is mainly composed of cellulose, hemicellulose,
glycoproteins, pectins, chitin and lignin.

Certain prokaryotes, algae, slime molds, water molds, and fungi also have cell
walls.
 Functions of the Cell wall
The cell wall actually has a multitude of functions upon which plant life
depends. Such functions include:
1. Providing a protective layer outside the cell membrane.
2. Providing shape and support for the cell's structure.
3. Providing a porous medium for the circulation and distribution of
water, minerals, and other small nutrient molecules.
4. Providing rigid building blocks from which stable structures such
as leaves and stems, can be produced.
5. Playing a vital role in cell to cell communication.
 Cytoskeleton
This three-dimensional cytoskeleton network is generated by
microtubules, intermediate filaments and actin filaments.
The cytoskeleton is located within the cytoplasm and is responsible for
the stabilization, intracellular transport of substances as well
as migration of the cell.
 Functions of Cytoskeleton
The cytoskeleton functions includes;
1. Maintaining cell shape

2. Providing internal organization.

3. Providing mechanical support.

4. It is also paramount in movement and cell division.

5. Provide intracellular transport of substances
 Animal cell vs plant cell
They are both eukaryotic cells which contain membrane-bound
organelles, including a clearly defined nucleus, mitochondria,
chloroplasts (unique to plant cells), a Golgi apparatus, an endoplasmic
reticulum, lysosomes, and peroxisomes.
 Cell membrane or Plasma membrane
The cell membrane forms a barrier between the cytoplasm inside the cell
and the environment outside the cell.

The principal components of the plasma membrane are lipids (phospholipids
and cholesterol), proteins, and carbohydrate groups that are attached to
some of the lipids and proteins.
 Phospholipid molecule of cell membrane
Phospholipids make up the basic structure of a cell membrane. A single
phospholipid molecule has two different ends: a head and a tail. The head end
contains a phosphate group and is hydrophilic. This means that it likes or is
attracted to water molecules.

The tail end is made up of two strings of hydrogen and carbon atoms
called fatty acid chains. These chains are hydrophobic, or do not like to
mingle with water molecules.
 Protein and carbohydrate molecules of cell
membrane
The cell membrane contains proteins, lipid and carbohydrate groups in its
structure.
1. Proteins are the second major component of plasma membranes. There
are two main categories of membrane proteins: integral and
peripheral.
2. Carbohydrates are the third major component of plasma membranes. In
general, they are found on the outside surface of cells and are bound
either to proteins (forming glycoproteins) or to lipids (forming
glycolipids).
3. Lipids such as phospholipids and cholesterol. Cholesterol is
embedded among the phospholipids of the membrane, helps to minimize
the effects of temperature on fluidity.
 Protein molecules of the cell membrane
i. Integral proteins are embedded in the plasma membrane and may span all or
part of the membrane. Integral proteins may serve as channels or pumps to
move materials into or out of the cell.
ii. Peripheral proteins are found on the exterior or interior surfaces of
membranes, attached either to integral proteins or to phospholipid molecules.

Both integral and peripheral proteins may serve as enzymes, as structural
attachments for the fibers of the cytoskeleton, or as part of the cell’s
recognition sites.
 Carbohydrate molecules of the cell membrane
Carbohydrates are the third major component of plasma membranes. They
are always found on the exterior surface of cells and are bound either to
proteins (forming glycoproteins) or to lipids (forming glycolipids).

Along with peripheral proteins, carbohydrates form specialized
sites on the cell surface that allow cells to recognize each other.
 Lipid (cholesterol) molecules of the cell membrane
Cholesterol is embedded among the phospholipids of the membrane.
Cholesterol molecules are important for maintaining the consistency of the cell
membrane.

They strengthen the membrane by preventing some small molecules from
crossing it.
Cholesterol molecules also keep the phospholipid tails from coming into contact
and solidifying.This ensures that the cell membrane stays fluid and flexible.
 The Phospholipid Bilayer Cell Membrane
The phospholipids of a cell membrane are arranged in a double layer called the lipid
bilayer.
The hydrophilic phosphate heads are always arranged so that they are near
water. Watery fluids are found both inside a cell (intracellular fluid) and outside a cell
(extracellular fluid).

The hydrophobic tails of membrane phospholipids are organized in a manner that
keeps them away from water.
 Properties of the Phospholipid Bilayer
i. The hydrophobic tail regions face inwards and are shielded from the
surrounding polar fluids, while the two hydrophilic head regions
associate with the cytosolic and extracellular fluids respectively
ii. The bilayer is held together by weak hydrophobic interactions
between the tails
iii. Hydrophilic and hydrophobic layers restrict the passage of many
substances
iv. Individual phospholipids can move within the bilayer, allowing for
membrane fluidity and flexibility
v. This fluidity allows for the spontaneous breaking and reforming of
membranes (endocytosis / exocytosis)
 Fluid mosaic model of cell membrane
The fluid mosaic model describes the structure of a cell membrane. It indicates
that the cell membrane is not solid.
Membrane a fluid character refers to flexibility, and that all the individual
molecules are just floating in a fluid medium, and they are all capable of moving
sideways within the cell membrane.

Mosaic refers to something that contains many different parts. The plasma
membrane is a mosaic of phospholipids, cholesterol molecules, proteins and
carbohydrates.
 Functions of the cell membrane
The cell membrane’s functionality is decisively determined by its membrane
proteins, which include: ion channels, cell adhesion molecules, aquaporins,
membrane pumps, carrier proteins and receptor proteins.

The membrane is semi-permeable (also referred to as selective permeability),
which means it is well permeable for small-molecular substances like water,
which are able to diffuse osmotically. Higher molecular substances such as
proteins require specific transport systems in order to by-pass the cell
membrane.
 Functions of the cell membrane
The cell membrane functions include:
1. The plasma membrane provides protective barrier for a cell.

2. Regulate transport in and out of the cell (selectively permeable).

3. The cell membrane also provides structural support for a cell.

4. Provides anchoring sites for filaments of cytoskeleton.
5. Balances the internal environment of cells plasma by controlling what
enters and leaves the cell.
6. Allow cell recognition – including recognition of signalling molecules,
adhesion proteins and other host cells.
END OF LECTURE
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