Week 9-10 PHA112 Cell Structure Lecture 1 and 2 2023-24 Student Handound PB.pdf

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MPharm Programme
Cell Science ‐ Introduction to
Cellular Structure 1, 2 & 3
Dr Praveen Bhugra
PHA112

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Learning Objectives

• By the end of this lecture you should be able
to understand and be able to explain in detail
following
• Cell Theory
• Stem cells theory
• Difference between Prokaryotic and
Eukaryotic cells
• Differentiation between plant cell, animal
cell and bacteria
• Structure and function of three main parts
of cell (Plasma Membrane; Cytoplasm
[cytosol and cell organelles] and Nucleus)
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Cells Theory
The basic concept of the cell theory can be
summarized as follows;
• Cells are building blocks of all plants and animal
• All cells come from the division of preexisting cells
• Cells are the smallest units that perform all vital
physiological functions
• Each cell maintains homeostasis at the cellular
level

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Cells in the human body
10 • All the parts of your body are made up of cells

• There are an estimated 3.72x1013 cells in the body
(Bianconi et al., (2013) Ann Human Biol. 40, 463‐71)
• There is no such thing as a typical cell
• The body has many different kinds of cells
• Though they might look different under a
microscope, most cells have chemical and structural
features in common
• In humans, there are about 200 different types of
cells, and within these cells there are about 20
different types of structures or organelles
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Diversity of Human Cells
• Adult humans consist of more than 200 kinds of cells.
• They are nerve cells (neurons), muscle cells
(myocytes), skin (epithelial) cells, blood cells
(erythrocytes, monocytes, lymphocytes, etc.), bone
cells (osteocytes), and cartilage cells (chondrocytes).
• Cells essential for embryonic development but not
incorporated into the body of the embryo, include the
extra-embryonic tissues, placenta, and umbilical cord.
• All of these cells are generated from a single,
totipotent cell, the zygote, or fertilized egg

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Diversity of Human Cells
Erythrocytes
Fibroblasts
Epithelial cells
(a) Cells that connect body parts,
form linings, or transport gases
Skeletal
Smooth
Muscle
muscle cells
cell
(b) Cells that move organs and
body parts
Macrophage

Nerve cell
(e) Cell that gathers information
and control body functions

(f) Cell of reproduction

Fat cell
(c) Cell that stores(d) Cell that
nutrients
fights disease
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Sperm

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Diversity of Human Cells

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Stem cells

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- • Stem cells are undifferentiated biological cells that can
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differentiate into specialized cells and can divide (through
mitosis) to produce more stem cells
• In mammals, there are two broad types of stem cells:
– embryonic stem cells isolated from the inner cell mass of
blastocysts
– adult stem cells, which are found in various tissues
• In adults, stem cells and progenitor cells act as a repair system
for the body
• In a developing embryo, stem cells can differentiate
•

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into all the specialized cells—ectoderm, endoderm and
mesoderm (germ layers ‐ which give rise to ALL the bodies
tissues and organs)
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Stem cells

(Growth and development of the embryo)

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Stem cells

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Stem cells potency

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- • Potency specifies the differentiation potential (the potential to
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differentiate into different cell types) of the stem cell
• Totipotent (or omnipotent) stem cells can differentiate into
embryonic and extraembryonic cell types. Such cells can
construct a complete, viable organism. These cells are produced
from the fusion of an egg and sperm cell.
• Pluripotent stem cells are the descendants of totipotent cells
and can differentiate into nearly all cells, i.e. cells derived from
any of the three germ layers
• Multipotent stem cells can differentiate into a number of cell
types, but only those of a closely related family of cells
• Oligopotent stem cells can differentiate into only a few cell
types, such as lymphoid or myeloid stem cells
• Unipotent cells can produce only one cell type, their own, but
have the property of self‐renewal, which distinguishes them
from non‐stem cells
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Stem cells potency

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Stem cell division and differentiation

9
10 • A: stem cell

• B: progenitor cell
• C: differentiated cell
1. symmetric stem cell
division
2. asymmetric stem cell
division
3. progenitor division
4. terminal differentiation

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Stem cell division and differentiation

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Potential uses of stem cells

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Stem cells potency & source developmental

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Hierarchy of haemopoietin differentiation
B Cells
T Cells
NK Cells
Plasmacytoid
Dendritic Cell
Monocytoid
Dendritic Cell
Monocyte
Granulocyte

Basophil
Mast Cell
Eosinophil
RBCs
Platelets

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Characteristics of all cell types

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10 • A surrounding membrane

• Protoplasm – cell contents in thick fluid
• Organelles – structures for cell function
• Control center with DNA
• On this basis we have:
• – Prokaryotic
• – Eukaryotic

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Characteristics of all cell types

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Prokaryotic Cells

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10 • Cells that lack a nucleus or

•
•
•
•
•

•

membrane-bound organelles
Simplest type of cell
Single, circular chromosome
Nucleoid region (center)
contains the DNA
Surrounded by cell membrane
& cell wall (peptidoglycan)
Contain ribosomes (no
membrane) in their cytoplasm
to make proteins
One-celled organisms, Bacteria

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Prokaryotic Cells

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10 • Cell walls -protect the cell and

maintain cell shape
• Bacterial cell walls
- may be composed of

peptidoglycan
-may be Gram positive or Gram
negative

• Archaean cell walls lack
peptidoglycan.
• Flagella - present in some
prokaryotic cells
-used for locomotion and
-rotary motion propels the cell
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Prokaryotic Cells (Bacteria)

9
10 • Bacteria may be classified

according to their response
to Gram’s Stain
• Gram +ve
• Gram–ve
• Gram‐positive bacteria have
a thick mesh‐like cell wall
made of peptidoglycan
(50‐90% of cell wall), which
stain purple
• Gram‐negative bacteria have
a thinner layer (10% of cell
wall), which stain pink

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Prokaryotic Cells (Bacteria)

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Gram positive S. aureus

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Prokaryotic Cells (Bacteria)

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Prokaryotic Cells (Bacteria)

Comparative Characteristics of Gram Positive and Gram Negative Bacteria

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Eukaryotic Cells

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10 • Possess a membrane-bound nucleus

• More complex than prokaryotic cells
• Compartmentalize many cellular functions within
organelles and the endomembrane system
• Possess a cytoskeleton for support and to maintain
cellular structure
• Include fungi, protozoa, plant, and animal cells

Protozoan
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Eukaryotic Cells

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Plant Cell

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Animal Cell

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Cell Structure

9
10 • The three main parts of a cell

1. Plasma membrane
2. Cytoplasm: cytosol + organelles
3. Nucleus

Cytoplasm
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Cytosol
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Generalized View of Cell Structure

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Plasma Membrane
Membranes form a major structural element in cells.
 Phospholipid bilayer
 Cholesterol
 Proteins (integral and peripheral)
 Attached carbohydrates (glycolipids and glycoproteins)

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Plasma Membrane

9
10 • Functions of membranes include:






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Barrier between inside and outside of cell
Controls entry of materials: transport
Receives chemical and mechanical signals
Transmits signals between intra- and extracellular spaces

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Plasma Membrane (Phospholipids)
Phospholipids are amphipathic.
Organized into a bilayer with the nonpolar fatty acid chains in
the middle.
The polar regions of the phospholipids are oriented toward the
surfaces of the membrane as a result of their attraction to the
polar water molecules in the extracellular fluid and cytosol.

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Plasma Membrane (Phospholipids)
 Fatty acid tails
– hydrophobic
 Phosphate group
head
– hydrophilic

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Plasma Membrane (Cholesterol)

• The plasma membrane also contains cholesterol, whereas
intracellular membranes contain very little cholesterol.
• Cholesterol associates with certain classes of plasma
membrane phospholipids and proteins, forming organized
clusters that work together to pinch off portions of the
plasma membrane to form vesicles that deliver their
contents to various intracellular organelles.

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Plasma Membrane (Cholesterol)
• Cholesterol molecules are
weakly amphipathic
• The tiny —OH group is the
only polar region of
cholesterol, and it forms
hydrogen bonds with the
polar heads of phospholipids
and glycolipids.
• The stiff steroid rings and
hydrocarbon tail of
cholesterol are nonpolar; they
fit among the fatty acid tails
of the phospholipids and
glycolipids.

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Plasma Membrane (Cholesterol)
• Cholesterol has temperature dependent effects on
membrane fluidity
• Warm temperatures – restrains phospholipid movement
• Cold temperatures – maintains fluidity by preventing tight
packing

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Plasma Membrane (Glycolipids)
• The carbohydrate groups of glycolipids form a polar "head";
their fatty acid "tails" are nonpolar.
• Glycolipids appear only in the membrane layer that faces the
extracellular fluid, which is one reason the two sides of the
bilayer are asymmetric, or different.

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Plasma Membrane (Protein)

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- • There are two classes of membrane proteins: integral and
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peripheral.
Integral membrane proteins
• Closely associated with the membrane lipids, cannot be
extracted from the membrane without disrupting the lipid
bilayer, and are amphipathic.
• Most integral proteins span the entire membrane and are
referred to as transmembrane proteins.
• Most of these transmembrane proteins cross the lipid bilayer
several times.
• Some transmembrane proteins form channels through which
ions or water can cross the membrane, whereas others are
associated with the transmission of chemical signals across
the membrane or the anchoring of extracellular and
intracellular protein filaments to the plasma membrane.
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Plasma Membrane (Protein)

Peripheral membrane proteins
• Are not amphipathic and do not associate with the nonpolar
regions of the lipids in the interior of the membrane.
• Located at the membrane surface where they are bound to
the polar regions of the integral membrane proteins.

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Plasma Membrane (Protein)

• Many membrane proteins are glycoproteins, proteins with
carbohydrate groups attached to the ends that protrude into
the extracellular fluid.
• The carbohydrate portions of glycolipids and glycoproteins
form an extensive sugary coat called the glycocalyx.
• Glycocalx acts like a molecular "signature" that enables cells
to recognize one another

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Plasma Membrane (Protein)

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Plasma Membrane (Junctions)

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• Many cells are physically joined by types of
junctions: desmosomes, tight junctions, and gap
junctions.
• Integrins are transmembrane proteins in the
plasma membrane which bind to specific proteins
in the extracellular matrix and link them to
membrane proteins on adjacent cells.

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Desmosomes
- • Characterized by accumulations of
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protein known as dense plaques along
the cytoplasmic surface of the plasma
membrane.
• These proteins serve as anchoring
points for cadherins.
• Cadherins are proteins that extend
from the cell into the extracellular
space, where they link up and bind
with cadherins from an adjacent
cell.
• Desmosomes hold adjacent cells firmly
together in areas that are subject to
considerable stretching, such as the
skin.
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Tight junctions
10 • Form when the extracellular

surfaces of two adjacent plasma
membranes join together so that
no extracellular space remains
between them.

• Unlike the desmosome, which is
limited to a disk-shaped area of
the membrane, the tight
junction occurs in a band around
the entire circumference of the
cell.

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Gap junctions
9
10 • Consist of protein channels linking the
cytosols of adjacent cells.

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• Connexins from the two membranes
join, forming small, protein-lined
channels linking the two cells.
• Diameter of about 1.5 nm limits what
can pass between the cytosols of the
connected cells to small molecules and
ions, such as Na+ and K+, and excludes
the exchange of large proteins.
• Example: Muscle cells of the heart cells
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Functions of Cell Membranes

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1. Regulate the passage of substances into and out of
cells and between organelles and cystosol
2. Detect chemical messengers arriving at the cell
surface
3. Link adjacent cells together by membrane junctions
4. Anchor cells to the extracellular matrix

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Cytoplasm

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Cytoplasm (Cytosol)

9
10 • Fluid portion of cytoplasm that surrounds organelles.

• Constitutes about 55% of total cell volume.
• Cytosol is 75-90% water plus various dissolved and
suspended components (such as ions, glucose amino
acids, fatty acids, proteins, lipids, ATP, and waste
products.
• Also present in some cells are various organic
molecules that aggregate into masses for storage;
which may appear and disappear at different times in
the life of a cell.
• Cytosol site of many chemical reactions required for a
cell's existence.

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Cytoplasm (Cell Organelles)
•
•
•
•
•
•
•

Cytoskeleton
Flagella, cilia & centrioles
Endoplasmic reticulum
Golgi apparatus
Mitochondrion
Nucleus, nucleolus, nuclear envelope
Vesicles, e.g. lysosome

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Cell Organelles (Cytoskeleton)
• Maintains shape of
cell
• Positions organelles
• Changes cell shape
• Includes:
microfilaments,
intermediate
filaments,
microtubules

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Cell Organelles (Cytoskeleton)

9
10 • Microfilaments (also called Actin filaments) and

Microtubules can be assembled and disassembled
rapidly, allowing a cell to alter these components of
its cytoskeletal framework according to changing
requirements.
• Intermediate filaments, once assembled, are less
readily disassembled.

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Cell Organelles (Centrosome)

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• Structure:

– Two centrioles arranged
perpendicular to each
other
• Composed of microtubules:
9 clusters of 3 (triplets)

– Pericentriolar material
• Composed of tubulin that
grows the mitotic spindle

• Function: moves
chromosomes to ends of
cell during cell division
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Cell Organelles (Cilia and Flagella)

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• Specialized for
10

motion
• Flagellum: single tail
like structure on
sperm
– Propels sperm
forward in
reproductive tract
• Cilia: in groups
– Found in
respiratory system:
move mucus

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Doublet
microtubules

Cilium or
flagellum

Central
pair of
microtubules
Plasma
membrane

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Cell Organelles Ribosomes

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- • Made within the nucleus
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•

•
•
•

(in nucleolus)
Sites of protein synthesis
(on E.R. or freely within
cytoplasm)
Consist of ribosomal RNA
(rRNA) + proteins
Contain large and small
subunits
Can be attached to
endoplasmic reticulum or
free in cytosol

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Cell Organelles
(Endoplasmic Reticulum (E.R.))

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• Structure: network of folded membranes
• Functions: synthesis, intracellular transport
• Types of E.R.

– Rough E.R.: studded with ribosomes (sites of protein
synthesis)
– Smooth E.R. lacks ribosomes.
• Functions:
– lipid synthesis
– release of glucose in liver cells into bloodstream
– drug detoxification (especially in liver cells)
– storage and release of Ca2+ in muscle cells (where
smooth E.R. is known as sarcoplasmic reticulum or SR)
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Cell Organelles
(Endoplasmic Reticulum (E.R.))

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Cell Organelles
- • Structure:
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(Golgi Complex)

– Flattened membranes
(cisterns) with bulging
edges (like stacks of pita
bread)
• Functions:
– Modify proteins 
glycoproteins and
lipoproteins that:
• Become parts of plasma
membranes
• Are stored in lysosomes, or
• Are exported by exocytosis

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Cell
9
10 • Structure:

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Organelles (Lysosomes)

– Spherical or oval surrounded
by single membrane
– Typical cell may contain
several hundred lysosomes
• Functions:

• Contain variety of digestive enzymes
• Help in final processes of digestion within cells
• Carry out autophagy (destruction of worn out parts of
cell) and death of old cells (autolysis)
• Tay-Sachs: hereditary disorder; one missing lysosomal
enzyme leads to nerve destruction

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Cell Organelles
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(Peroxisomes)

– are moderately dense oval bodies enclosed by a
single membrane.
• Function:
– consume molecular oxygen and it undergoes
reactions that remove hydrogen from organic
molecules including lipids, alcohol, and
potentially toxic ingested substances.
• Detoxify; abundant in liver

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Cell Organelles
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10 • Structure :

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(Proteasomes)

– Tiny barrel shaped structure that contain
proteases (proteolytic enzyme).
• Function:
– Digest unneeded or faulty proteins
– Faulty proteins accumulate in brain cells in
persons with Parkinson or Alzheimer disease.

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Cell Organelles (Mitochondria)
• Structure:
– Sausage-shaped with
many folded
membranes (cristae)
and liquid matrix
containing enzymes
– Have some DNA,
ribosomes (can make
proteins)

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Cell Organelles (Mitochondria)
• Function:
– Major site of ATP
production , O2 utilization
and CO2 formation
– Contains enzyme active in
Kreb’s cycle and oxidative
phosphorylation

• Abundant in muscle,
liver, and kidney cells
– These cells require much
ATP
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Nucleus
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- • Round or oval structure surrounded by nuclear
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envelope with nuclear pores

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• Contains nucleolus: makes ribosomes that pass into
cytoplasm through nuclear pores
• Within the nucleus, DNA, in association with proteins,
forms a fine network of threads known as chromatin

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Nucleus
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10 • Most prominent structure in the nucleus is the nucleolus.

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– Densely staining filamentous region without a
membrane.
– Associated with specific regions of DNA that contain
the genes for forming the particular type of RNA found
in cytoplasmic organelles called ribosomes.
– Store genetic material (DNA) in genes arranged in 46
chromosomes (the human genome containing 30,000
genes!)
– DNA contains information for directing protein
synthesis:
• In the cell
• In new cells (formed by cell reproduction)

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Comparison of Bacterial, Animal and Plant cells

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Cells Parts and Their Functions

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Further Reading
Refer to the Following Textbooks
• Ross and Wilson Anatomy and Physiology in Health
and illness 13th Edition
• Gerard J. Tortora and Byran H. Derrickson Principles
of Anatomy and Physiology 13th Edition
• Frederic H. Martini Fundamentals of Anatomy &
Physiology 7th Edition
• Elaine N. Marieb and Katja Hoehn Human Anatomy
& Physiology 8th Edition
• VanPutte, Regan and Russo Seeley’s Anatomy and
Physiology 12th Edition

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