Transport Across Cell Membrane (BUC Lecture) PDF

Summary

This document is a lecture presentation on transport across cell membranes by Dr. Sahar Greish. It details the various types of transport, including passive transport (simple diffusion, facilitated diffusion, osmosis) and active transport (primary and secondary transport, and bulk transport, including endocytosis and exocytosis). The presentation likely includes diagrams and examples of different molecules crossing membranes. Useful for students studying cell biology.

Full Transcript

Transport across cell
membrane

Dr. Sahar Greish
 Learning Objectives

By the end of this lecture, you should be able
to:
1. Differentiate between passive and active
transport.
2. Mention types of passive transport and give
an example for each type.
3. List the mechanisms of water transport
across membranes.
4. Mention types of active transport and give
an example for each type.
5. Discuss transport of big molecules across
membranes (.i.e. bulk transport)
 Transport of molecules
Simple diffusion.
1-Passive Simple diffusion of water
transport molecules (.i.e. osmosis).
Facilitated diffusion.

2-Active Primary
transport Secondary

3-Bulk Endocytosis
transport Exocytosis
 Passive vs. Active
Passive transport
 is the net movement of molecules and ions across a
membrane from higher to lower concentration
(down a concentration gradient);
 it does not require metabolic energy.

Active transport
 is net movement across a membrane that occurs
against a concentration gradient (to the region of
higher concentration).
 Active transport requires the expenditure of
metabolic energy (ATP) and involves specific carrier
proteins.
 1-Passive transport
(Simple diffusion)
 It is the transport of a substance from high
concentration to low concentration (i.e.
downhill).
 It is a passive process (.i.e. no energy cost).
 The rate of diffusion of a substance depends on :
1. Concentration gradient of the substance across the
membrane.
2. Electrical potential difference: This factor particularly
affects the rate of diffusion of ions.
3. Surface area of the membrane.
4. Permeability of the membrane: Increased permeability
increase diffusion rate
Types of simple diffusion.
(a) simple diffusion through the double phospholipid layers of
the plasma membrane (Nonpolar molecules)
(b) simple diffusion through protein channels (polar molecules
& inorganic ions).
Simple diffusion through
lipid bi-layer
Simple diffusion through
protein channels
 Facilitated diffusion
Diffusion of a substance
with the help of a carrier
protein.

A mechanism of
transport of relatively
large organic molecules
such as glucose and
amino acids
 Osmosis
 Osmosisis the net diffusion of water from a region
of high water concentration to a region of low
water concentration through a membrane which is
permeable to water but not to the solute.
 Osmosis
Terms related to osmosis
Osmotic Pressure
 Osmosis
Terms related to osmosis

Osmotic Pressure
 The force that would have to be exerted to prevent
osmosis.
 The greater the solute concentration of a solution,
the greater its osmotic pressure.
 Pure water thus has an osmotic pressure of zero.
 360-g/L glucose solution has twice the osmotic
pressure of a 180-g/L glucose solution.
 Osmosis
Terms related to osmosis
 Osmolarity is the number of osmoles / liter of
solution

 Normal osmolarity of body fluids: 290 mosm/L

 Isotonic solution: is having the same
concentration of solutes as the extracellular
fluid.

 Hypertonic: …higher concentration than…

 Hypotonic: … lower concentration than…
 2-Active transport
it occurs against gradient (from low to
high concentration).
It needs a carrier.
It needs energy (ATP).
It has two types; Primary and secondary
A-Primary active transport

Energy is provided directly by ATP.
Phosphorylation of the carrier induce
conformational change.
The carrier then allows transport of a
molecule from low to high
concentration.
Dephosphorylation of the carrier
restore its original conformation.
This carrier protein transports Ca2+
from a lower concentration inside
the cell to a higher concentration
outside of the cell, and is thus known
as a Ca2+ pump.
(1) Ca2+ within the cell binds to
sites in the carrier protein.
(2) ATP is hydrolyzed into ADP and
phosphate (P i ), and the phosphate is
added to the carrier protein; this
phosphorylation causes a hinge like
motion of the carrier.
(3) The hinge like motion of the
carrier protein allows Ca2+ to be
released into the extracellular fluid.
B-Secondary active transport
The molecule is transported against
concentration gradient but the transporter
does not hydrolyze ATP directly.
Energy is provided by concentration gradient
of Na⁺ produced by Na⁺-K⁺ pump.
Secondary active transport
a. Co-transport (symport).
b. Counter-transport (antiport).
Co-transport (symport):
The cotransport of Na+ and
glucose. This carrier protein
transports Na+ and glucose at
the same time, moving them from
the lumen of the intestine and
kidney tubules into the lining
epithelial cells. This cotransport
requires a lower intracellular
concentration of Na+, which is
dependent on the action of other
carriers, the Na+/K+ (ATPase)
pumps.
Because ATP is needed to power
the Na+/K+ (ATPase) pumps, the
cotransport of Na+ and glucose
depends indirectly on ATP, and so
can be considered secondary
active transport.
Counter-transport (antiport):
transport of 2 solutes in
opposite directions.

Examples:
Na+/Ca+ counter-transport.
Na+/H+ counter-transport.
 Bulk Transport
Polypeptides and proteins are too large to be transported
through a membrane by carriers.
Endocytosis:It is the process by which molecules are
taken into the cell.e.g. removal of lipoprotein molecules
from blood stream by liver cells.
Exocytosis : It is the process by which the cell
SECRETES hormones or neurotransmitters or the
process by which the cell EXCRETES waste products.
Pinocytosis is cell drinking
Phagocytosis is a type of cell endocytosis in which the
cells engulf bacteria or large particles such as cell debris
from damaged tissues.