5. MEMBRANE STUCTURE AND FUNCTION.pdf

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Membrane Structure
 The plasma membrane separates the living cell from its nonliving
surroundings.
 This thin barrier, 8 nm thick, controls traffic into and out of the cell.
 Like other membranes, the plasma membrane is selectively
permeable, allowing some substances to cross more easily than
others.
 The most abundant lipids cell membrane are phospholipids.
 Phospholipids and most other membrane constituents are
amphipathic molecules.
 Amphipathic molecules have both hydrophobic regions and
hydrophilic regions.

 The phospholipids and proteins in membranes create a unique
physical environment, described by the fluid mosaic model.
 A membrane is a fluid structure with proteins embedded or attached to
a double layer of phospholipids.

The sugars attached to lipids and proteins can act as
markers due to the structural diversity of sugar chains. For
example, antigens composed of sugar chains on the surface
of red blood cells determine an individual's blood group.
These antigens are recognized by antibodies to cause an
immune response, which is why matching blood groups
must be used in blood transfusions. Other carbohydrate
markers are present in disease (e.g. specific carbohydrates
on the surface of cancer cells), and can be used by doctors
and researchers to diagnose and treat various conditions.
Amphipathic lipids form bilayers

All membrane lipids are amphipathic—that is, they contain both a
hydrophilic (water-loving) region and a hydrophobic (water-hating)
region. Thus the most favorable environment for the hydrophilic
head is an aqueous one, whereas the hydrophobic tail is more stable
in a lipid environment. The amphipathic nature of membrane lipids
means that they naturally form bilayers in which the hydrophilic
heads point outward towards the aqueous environment and the
hydrophobic tails point inward towards each other (Figure 2a).
When placed in water, membrane lipids will spontaneously form
liposomes, which are spheres formed of a bilayer with water inside
and outside, resembling a tiny cell (Figure 2b). This is the most
favourable configuration for these lipids, as it means that all of the
hydrophilic heads are in contact with water and all of the
hydrophobic tails are in a lipid environment

 The molecules in the bilayer are arranged as hydrophobic fatty
acid tails are sheltered from water while the hydrophilic phosphate
groups interact with water.

 Membrane proteins are amphipathic, with
hydrophobic and hydrophilic regions.
Fig. 8.1b

 If at the surface, the hydrophilic regions
would be in contact with water.
 In this fluid mosaic
model, the hydrophilic
a regions of proteins
and phospholipids are
in contact with water and
the hydrophobic regions
are in a nonaqueous
environment.

Membranes are mosaics of structure and function

• A membrane is a collage of different proteins embedded in
the fluid matrix of the lipid bilayer.

To work properly with
permeability, membrane
must be fluid about as fluid
as oil.

A)- The plasma membrane has a unique collection of
proteins.

•

There are two populations of MEMBRANE PROTEINS.
1.

Peripheral proteins are not embedded in the lipid bilayer at all. Instead,
they are loosely bounded to the surface of the protein, often
connected to the other population of membrane proteins.

2.

Integral proteins penetrate the hydrophobic core of the lipid bilayer,
often completely spanning the membrane (a transmembrane protein).

Where they contact the core,
they have hydrophobic regions
with nonpolar amino acids, often
coiled into alpha helices.
Where they are in contact with the
aqueous environment, they have
hydrophilic regions of polar amino
acids.

Integral
proteins

Hydrophilic
region
Peripheral
proteins

Hydrophobic
region

The proteins in the plasma membrane may provide
a variety of major cell functions.
Aquaporins (channel proteins): are transport proteins that
function by having a hydrophilic channel that facilitate the
passage of water molecules through the membrane in
certain cells. Without aquaporins, only a tiny fraction of water
molecules would pass through the cell membrane.
Carrier protein (glucose transporter): in the plasma
membrane of red blood cells transports glucose across the
membrane 50,000 time faster than glucose can pass through
on its own.
Nonpolar molecules, such as hydrocarbons, CO2, and O2,
are hydrophobic and can therefore dissolve in the lipid
and without the aid of
bilayer of the membrane and cross it easily,
membrane proteins.
Thus, the selective permeability of a membrane depends
on both the discriminating barrier of the lipid bilayer and the
specific transport proteins built into the membrane

Specific proteins facilitate passive transport
•

Many polar molecules and ions diffuse passively through the lipid bilayer
with the help of transport proteins (gated channels ‫)قنوات ُم َبوبة‬.

•

The passive movement of molecules down its concentration gradient via a
transport protein is called facilitated diffusion.

•

Many transport proteins simply provide channels allowing a specific
molecule or ion to cross the membrane.

Functions of cell membrane (Plasma membrane)
1- Selective permeability
 A steady traffic of small molecules and ions moves across the
plasma membrane in both directions.
 For example, sugars, amino acids, and other nutrients enter a muscle
cell and metabolic waste products leave it.
 The cell absorbs O2 and expels CO2.
 It also regulates concentrations of inorganic ions, like Na+, K+, Ca2+,
and Cl-, by passing them across the membrane.

 However, substances do not move across the barrier
indiscriminately ‫ عشوائيا‬as membrane is selectively permeable.
 Hydrophobic molecules, like hydrocarbons, CO2, and O2, can
dissolve in the lipid bilayer and cross easily as described in the
previous slide.
 Ions and polar molecules like H2O and glucose pass through
channel proteins as described in the previous slide.
 Thus membrane proteins assist and regulate the transport of ions
and polar molecules.

Selective Permeability

CO2

CO2
Nucleus

O2
O2

The cell is able to take up particular molecules
and exclude others

2- Passive transport

Involves the movement of molecules across the cell membrane
without an input of energy by the cell.
No ENERGY is required to move substances across membrane
(water, lipids, and other lipid soluble substances).

Rather, the CONCENTRATION GRADIENT represents potential
energy and drives diffusion

Types of Passive transport:
A. Diffusion
B. Osmosis

C. Facilitated Diffusion

A)- Diffusion:
Is the tendency of molecules of any substance to spread out in the available
space randomly.
•

For example, a permeable membrane separating a solution with sugar
molecules from pure water, sugar molecules will cross the barrier randomly.

•

The sugar molecules will cross the membrane until both solutions have equal
concentrations of the sugar (dynamic equilibrium).
Lump of sugar

dynamic equilibrium

• A substance will diffuse from where it is more concentrated to where
it is less concentrated, down its concentration gradient.

B). Osmosis : the passive transport of water
• Differences in concentration of dissolved materials in two solutions
can lead to the movement of ions from one to the other through a
selectively permeable membrane.

• If the membrane is impermeable to the solute molecules, then the
water molecules will move across this membrane against the
concentration gradient.
• The solution with the higher concentration of solutes is hypertonic.
• The solution with the lower concentration of solutes is hypotonic.
• Solutions with equal solute concentrations are isotonic.

Osmosis:
Is a passive transport in which
water diffuses across a selectively
permeable membrane from the
hypotonic solution to the hypertonic
solution until the solutions become
isotonic.

Principal of water movement

Osmosis

Isotonic

Osmosis

Selectively
permeable
membrane
Low conc. of sugar

hypotonic

High conc. of sugar

hypertonic

Types of solutions and Osmosis
• Hypertonic solution: contains high concentration of solute ‫مُذاب‬
molecules.

• Hypotonic solution: contains low concentration of solute
molecules.

• Isotonic solution: contains equal concentrations of solute
molecules

Biological
Membrane

H2O

Hypertonic

Hypotonic

Osmoregulation
LLNL

•

The cell in a hypertonic
environment will loose water,
shrivel, and die.

•

A cell in a hypotonic solution will
gain water, swell, and burst.

•

Organisms without rigid walls
have osmotic problems in either
a hypertonic or hypotonic
environment and must have
adaptations for osmoregulation
to maintain their internal
environment.

•

Example, Paramecium have a
specialized organelle (the
contractile vacuole), that
functions as a pump to force
water out of the cell.

Behavior of water when a living cell is placed in Hypertonic,
Hypotonic or Isotonic Solutions

C)- Facilitated Diffusion: Specific proteins facilitate passive transport
•

It is the passive movement of molecules down its concentration gradient via a
transport protein.

I

•

It Helps diffusion of molecules across a membrane when they are not soluble
in lipids or are too large (e.g. glucose) to pass through pores in membrane

•

Thus, a molecule binds to a carrier protein on one side of the cell membrane.

•

The carrier protein (specific for one type of molecule) then changes its shape
and transports the molecule down its concentration gradient to the other
side of the membrane.

• Other transport proteins
translocate the molecules
across the membrane as
the protein changes its
shape .

Active transport is the pumping of solutes against
their concentration gradients
• Some facilitated transport proteins can move solutes against their
concentration gradient, from the side where they are less
concentrated to the side where they are more concentrated.
• This active transport requires metabolic energy via ATP.

• Active transport is critical for a cell to maintain its internal
concentrations of small molecules.

• Active transport is performed by specific proteins embedded in
the membranes called transport protein (T. protein).
24

1)- Transport of small molecules (Ions )
• The sodium-potassium pump
actively maintains the gradient
of sodium (Na+) and potassium
ions (K+) across the membrane.
– The animal cell has higher
concentrations of K+ and lower
concentrations of Na+ inside
the cell.
– The sodium-potassium pump
(T. protein) uses the energy of
one ATP to pump 3 Na+ ions
out and 2 K+ ions in.
1ATP

00

0

Outside the cell
Na
Na
Na

Na

To

T. protein

Low conc.
+ 2
of K
High conc.
+
of Na

High conc.
+
of K
Low conc.
3 of Na+

Protein
molecule

ATP
Cellular
membrane

Inside the cell

26

Two roles of
membrane protein

Both diffusion and facilitated diffusion are forms of passive transport of
molecules down their concentration gradient, while active transport requires an
investment of energy to move molecules against their concentration gradient.