Transport Across Membrane PDF

Summary

This document is a lecture on transport across membranes. It discusses various types of membrane transport like diffusion, osmosis, facilitated diffusion, active transport, filtration, endocytosis, and exocytosis, and how they occur in biological cells. Diagrams illustrate the processes.

Full Transcript

Dr. Yousef Eshawee Plasma membrane Lecture 1

The plasma membrane surrounds the cell and has the property of selective permeability.
Selective permeability: is the ability of the plasma membrane to let some substances in
and keep others out and it is essential for maintaining cellular homeostasis.
In 1972, Singer and Nicolson developed the fluid-mosaic model of membrane
structure.
According to this model,
1) A cell membrane is a double layer (bilayer) of phospholipids surround one layer of
proteins.
- Each phospholipid molecule has one polar end (head) and one nonpolar end (tail).
 The nonpolar tail (lipid portion) is repelled by water (hydrophobic).
 The polar heads (phosphate portion) is water attracting (hydrophilic).
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2) Cholesterol molecules are embedded in the interior of the cell membrane and function in
Help to make the membrane less permeable to water-soluble substances.
The relatively rigid structure of the cholesterol molecules helps to stabilize the membrane.
3) The membrane proteins are either:
- Peripheral proteins: are situated on the inner or outer surface of the cell membrane
- Intrinsic proteins: embedded in membrane surface and span the entire width of the
membrane
The membrane’s proteins have several functions:
a) Form channels, carrier enzymes or transporter to permit movement of materials across
membrane. (Intrinsic P.)
b) With oligosaccharides on cell outer surface, they constitute antigens (markers that identify
the cells of an individual as “self”). (Peripheral P.)
c) Serve as receptor sites for hormones. (Intrinsic P.)
d) Attach the membrane to the cell’s inner scaffolding (the cytoskeleton). (Peripheral P.)

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Functions of plasma membrane
The cell membrane acts as a selective barrier, regulating the flow of substances in
and out of the cell.
It maintains the internal environment of the cell by allowing certain molecules to
enter and leave, ensuring optimal conditions for cellular activities.
It provides structural support and helps maintain cell shape.
It facilitates cell signaling, allowing cells to communicate and interact with their
external environment.
The cell membrane enables the transport of essential molecules across the
membrane, ensuring the proper balance of ions, nutrients, and waste products.

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 Plasma membrane

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 Movement across membrane

1- Simple diffusion
The features of this process:
- It transports materials from an area of higher concentration to that of lower
concentration.
- It doesn’t require energy for transport.
- It transports small and lipophilic molecules.
- It continues until equilibrium.
An example: Transport of O2 and CO2
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2- Facilitated diffusion
The features of this process:
- It transports materials from an area of higher concentration to that of lower
concentration.
- It doesn’t require energy for transport.
- It involves transporter, channel, and carrier proteins to transport molecules.
- It transports large and hydrophilic molecules.
An example: Transport of glucose and amino acids inside the cell

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3- Osmosis

It is the diffusion of water across a selectively permeable membrane from an
area of higher water concentration to an area of lower water concentration.
Thus, water will move from an area with more water present to an area with
less water.
It occurs when there is a difference in solute concentration between the
intracellular and extracellular space.
In other word, Water molecules move from an area of lower solute
concentration to an area of higher solute concentration until equilibrium is
achieved.
In general, there are three types of solution according to solute concentration in
water. 9
a) Isotonic solution:
- A solution with the same salt concentration as that in cells.
- Thus, there is no movement of water in either direction.
- E.g. The blood plasma is isotonic to red blood cells.
b) Hypotonic solution:
- A solution with a lower salt concentration than that in cells.
- Thus, water moves into a cell, which swells and may burst.
- E.g. Distilled water (0% salt) is hypotonic to human cells.
c) Hypertonic solution:
- A solution with a higher salt concentration than that in cells.
- Thus, water moves out of a cell, which shrinks.
- E.g. Seawater is hypertonic to human cells.
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Isotonic solution

Hypertonic solution

Hypotonic solution

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4- filtration
The process of filtration also requires energy, but the energy needed does not
come directly from ATP. It is the energy of mechanical pressure (hydrostatic
pressure).
Filtration means that water and dissolved materials are forced through a
membrane from an area of higher pressure to an area of lower pressure.
The blood pressure in capillaries is higher than the pressure of the surrounding
tissue fluid. Thus, it forces plasma (water) and dissolved materials through the
capillary membranes into the surrounding tissue spaces.
This is how cells receive nutrients.

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5- Active transport
Active transport process moves molecules and other substances across plasma
membrane from an area of low concentration to one of high concentration (against a
concentration gradient).
Molecules require carrier proteins (pumps) to pass across membrane.
It requires ATP energy.
Examples of active-transport mechanism include:
The calcium pump that keeps the calcium concentration hundreds of times lower
inside the cell than outside.
The sodium-potassium pump found in nerve and muscle cells.

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6- Endocytosis
Endocytosis involves bulk movement of materials across the plasma membrane, rather than movement of
individual molecules. It is a process by which cells engulf substances from the external environment
The three forms of endocytosis are:
1) Pinocytosis:
- It is nonspecific uptake of small droplets of extracellular fluid.
- These cells are stationary and may take in small molecules from extracellular space.
- The cells of the kidney tubules reabsorb small proteins by pinocytosis so that the protein is not lost
in urine.
2) Phagocytosis:
- It is similar to pinocytosis, except that the cell takes in solid material rather than liquid.
- An example of phagocytosis is a white blood cell engulfing and digesting bacteria.
3) Receptor-mediated endocytosis:
- Involves a specific receptor protein on the plasma membrane that “recognizes” an extracellular
molecule and binds with it.

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7- Exocytosis
Cells are also capable of sending materials out of the cell, enabling the
secretion or release of molecules from the cell into the extracellular
environment.
The transport of materials outside the cell membrane occurs through sac or
vesicle.
Example: Neurons release neurotransmitters through exocytosis to transmit
signals to neighboring cells

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