Lec3 Membrane Structure & Function 2 PDF

Summary

This lecture covers the structure and function of cell membranes, including various transport mechanisms such as diffusion, facilitated diffusion, osmosis, active transport, endocytosis, and exocytosis. It details the roles of different components, like proteins and lipids. The lecture includes diagrams and explanations to visualize and understand these concepts.

Full Transcript

Cell Structure and Function II

Prepared by: Dr. Omar Abdullah Bamaga
Associate. Prof. of medical parasitology

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 What is the cytoskeleton
Definition: a microscopic network of protein filaments and
tubules in the cytoplasm

Consist from 3 types of filaments (elongated chain of
protein):
(a) Microfilaments
(b) Microtubules
(c) Intermediate filaments

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 Cytoskeleton
3 Functions of the cytoskeleton:
1) Supports the cell
2) Gives a cell its shape
3) Facilitates movement.

 Has roles in molecule
transport and cell division

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 a) Microfilaments
 Called Actin filaments because they are
mostly composed of the protein actin
 Functions:
1. Aid in cytokinesis(cytoplasm division)
2. Aid in cell Motility
3. Involved in cytoplasmic streaming
4. Involved in muscle contractions
5. Maintenance of cell shape

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 b) Microtubules

 Functions:
1) Involved in chromosome
division
2) Involved in transporting
molecules within the cell
3) Maintenance of cell shape
4) Involved in cell motility

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 Cilia & Flagella
 Flagella, which are “tails” that propel a cell forward
 Cilia, which are appendages that allow the cell to move

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 c) Intermediate Filaments
 Called intermediate because they are in-between the size (8-
10 nm) of microfilaments (25 nm) and microtubules (7 nm)
 Made of different proteins such as keratin (found in hair and
nails, and also in animals with scales, horns, or hooves),
vimentin, desmin, and lamin.
 Function:
1) maintain the cell’s shape
2) play some structural or tension-bearing role
3) Provide structural support to the cell

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 Cell Membrane
 Also known as Plasma Membrane, Contains cell organelles
 Structure – Phospholipids form the basic structure of a cell
membrane, called the lipid bilayer with embedded proteins
 Five functions:
1) Protects the cell by acting as a barrier.
2) Regulates the transport of substances in and out of the
cell.
3) Receives chemical messengers from other cell.
4) Acts as a receptor.
5) Cell mobility, secretions, and absorptions of substances.

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 Structure of cell membrane
1. Channels or transporters: 4. Enzymes
Move molecules in one direction Catalyze production
2. Receptors of substances
Recognize certain chemicals 5- Glycoproteins
3. Cholesterol molecules: Identify cell type
keep the membrane fluid consistent

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 Structure of cell membrane / Phospholipids
 Hydrophilic (head): having an affinity for water forming ionic or a
hydrogen bond with the water molecule
 Hydrophobic (tail): (water-hating) because they bind poorly to water
molecules
 Interacts with water is important for the evolution of life.

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 Movement Across the Plasma Membrane
A few molecules move through cell membrane such as:
Water, Carbon dioxide, Ammonia, Oxygen

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Methods of Molecule Movement into Cells
1. Passive Transport

2. Active Transport

3. Endocytosis (phagocytosis & pinocytosis)

4. Exocytosis

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1. Passive Transport
moves biochemicals from areas of high concentration
to areas of low concentration; so it does not require
energy
Move due to gradient: differences in concentration,
pressure, charge

Move to equalize gradient: moves from High to
low concentration

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1. Passive Transport (cont.)
They are 3 kinds of passive transport :

1. Diffusion

2.facilitated diffusion

3. Osmosis

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 1.1. Diffusion
The movement of molecules from a high concentration to
a low concentration (equalize concentration)

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 Diffusion is the movement of small particles across a selectively
permeable membrane like the cell membrane until equilibrium is
reached.

These particles move from an area of high concentration to an area
of low concentration. This process is “passive” – i.e. it requires no
energy; the gradient is enough to drive the process

outside of cell

inside of cell

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 Diffusion of H2O Across A Membrane

High H2O potential Low H2O potential

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 2. Facilitated Diffusion
is the process of spontaneous passive transport of molecules or
ions across a biological membrane via specific transmembrane
integral proteins
Does not require energy but does require cell membrane
proteins which are called carrier proteins to carry the
molecules across the cell membrane from high to low
concentration area

Simple diffusion vs facilitated diffusion
Simple diffusion is the movement of molecules through a cell
membrane without using the channels formed by integral
membrane protein. Facilitated diffusion is the movement of
molecules through those channels

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 Facilitated Diffusion is the movement of larger molecules
like glucose through the cell membrane – larger molecules
must be “helped”
Glucose molecules
outside of cell

inside of cell

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 3. Osmosis
The movement of water across a semi permeable membrane
Osmosis is the movement of water (blue dots) through a
semipermeable membrane to a higher concentration of
solutes (green dots).

Semi-permeable membrane is
permeable to water only, but
not to sugar
Low saturated –high saturated

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 Osmosis vs diffusion:
Osmosis is the movement of solvent particles (water
molecules) across a semipermeable membrane from a
dilute solution into a concentrated solution....
Diffusion: Diffusion is the movement of particles (such as
oxygen in and out cell) from an area of higher concentration
to lower concentration.
The overall effect is to equalize concentration throughout
the medium.

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 How do hypotonic, hypertonic, and isotonic Solutions
Affect the Water Movement of a Cell?
 Hypotonic: Low conc of solute lower than cell. the water
diffuses into the cell, causing the cell to swell and possibly
explode.
 Hypertonic: High conc of solute greater than cell. Water
diffuses out of the cell, causing the cell to shrivel up out of
cell
Isotonic : Solutes equal inside & out of cell

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 Cell in Isotonic Solution
Isotonic Solutions: contain the same concentration of solute

What is the direction of water movement?
When a cell is placed in an isotonic solution, the water diffuses into
and out of the cell at the same rate. The fluid that surrounds the body
cells is isotonic.
10% NaCL ENVIRONMENT
90% H2O
CELL equilibrium

10% NaCL
90% H2O
NO NET
MOVEMENT23 23
 Cell in Hypotonic Solution
What is the direction of water movement?
Hypotonic Solutions: contain a low concentration of solute relative
to another solution. When a cell is placed in a hypotonic solution, the
water diffuses into the cell, causing the cell to swell and possibly
explode
10% NaCL
90% H2O

CELL

20% NaCL
80% H2O

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 Cell in Hypertonic Solution
What is the direction of water movement?
Hypertonic Solutions: contain a high concentration of solute relative
to another solution. When a cell is placed in a hypertonic solution, the
water diffuses out of the cell, causing the cell to shrivel.

15% NaCL ENVIRONMENT
85% H2O

5% NaCL
95% H2O
CELL

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 2. Active Transport
 Active transport requires chemical energy because it is the
movement of biochemicals from areas of lower concentration to
areas of higher concentration
 Active Transport creates a charge gradient in the cell membrane.

 Active transport uses energy to send substances against the
direction they would travel by simple diffusion

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 2. Active Transport (cont.)
Proteins that work as pumps are called protein pumps.

Ex: Body cells must pump carbon dioxide out into the surrounding
blood vessels to be carried to the lungs for exhale. Blood vessels are
high in carbon dioxide compared to the cells, so energy is required to
move the carbon dioxide across the cell membrane from LOW to
HIGH concentration.
outside of cell Carbon Dioxide molecules

inside of cell
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 3. Endocytosis
Movement of large material into cells
– Particles
– Organisms
– Large molecules

Types of endocytosis
– bulk-phase (nonspecific)
– receptor-mediated (specific): by using phagocytosis and
pinocytosis process

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Receptor-Mediated Endocytosis

Phagocytosis
– cell eating

Pinocytosis

– cell drinking

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Pinocytosis

Cell forms an
invagination
materials dissolve
in water to be
brought into cell
called “Cell
Drinking”

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 4. Exocytosis
Reverse of endocytosis
Cell discharges material
Vesicle moves to cell surface
Membrane of vesicle fuses
Materials expelled

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 Exocytosis
The opposite of endocytosis is exocytosis.
Large molecules that are manufactured in the cell are
released through the cell membrane.

Inside Cell Cell environment 31 32
 Endocytosis and Exocytosis is the mechanism by
which very large molecules (such as food and wastes)
get into and out of the cell

Food is moved into the
cell by Endocytosis

Wastes are moved out of
the cell by Exocytosis

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Second assignment:
Q1: What is the difference between prokaryotic and
eukaryotic cell in the following:
Structure
Chromosomes
Cell wall
Q2: Mention the organelles that is responsible for:
1-indigestion and waste removal
2- synthesis of lipid
3- synthesis of protein
4- produce energy
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Dr. Omar Bamaga