physiology of Transport mechanisms across cell membrane.ppt
DratoshKatiyar
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Nov 02, 2025
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About This Presentation
transport across cell membrane
Slide Content
Transport across cell membrane
by Vani Gupta
by Vani Gupta
Types of cell membrane transport
Factors affecting transport
Cell membrane
Chemical gradient
Electrical gradient
Rate of transport
Passive transport
Diffusion
Osmosis
Facilitated diffusion
Active transport
Pumps
phagocytosis
Endocytosis/exocytosis
Factors affecting transport
Cell membrane
Chemical gradient
Electrical gradient
Rate of transport
Passive transport
Diffusion
Osmosis
Facilitated diffusion
Active transport
Pumps
phagocytosis
Endocytosis/exocytosis
Factors affecting transport: cell membrane
The cell needs to absorb and excrete various compounds throughout its life.
These compounds need to pass through the membrane which is made from
a phospholipid bilayer
The phospholipid bilayer is formed by phospholipid molecules bipolar
molecule: the fatty acid side is hydrophobic, the phosphoric side is
hydrophilic
The cell needs to absorb and excrete various compounds throughout its life.
These compounds need to pass through the membrane which is made from
a phospholipid bilayer
The phospholipid bilayer is formed by phospholipid molecules bipolar
molecule: the fatty acid side is hydrophobic, the phosphoric side is
hydrophilic
The membrane is
permeable to:
The membrane is
impermeable to:
H2O
Gases (O2, CO2, N2)
Lipids
Small, neutral molecules (such
as urea)
Small, charged molecules
“large molecules” such as
amino acids, glucose and
larger
These compounds must go
through channels present in the
membrane in order to enter or
exit the cell
permeable to:
The membrane is
impermeable to:
H2O
Gases (O2, CO2, N2)
Lipids
Small, neutral molecules (such
as urea)
Small, charged molecules
“large molecules” such as
amino acids, glucose and
larger
These compounds must go
through channels present in the
membrane in order to enter or
exit the cell
Factors affecting transport: Chemical gradient
Compound moves from an
area of high concentration to
low concentration (or
concentration gradient)
All compounds permeable to
the phospholipid bilayer will
move this way
Compound moves from an
area of high concentration to
low concentration (or
concentration gradient)
All compounds permeable to
the phospholipid bilayer will
move this way
Factors affecting transport: Electrical force
Positive ions are attracted to
negative ions and vice versa
Ions are repelled by ions of
the same charge (+ against +
and – against -)
Positive ions are attracted to
negative ions and vice versa
Ions are repelled by ions of
the same charge (+ against +
and – against -)
Movement across the cell membrane
Both chemical and electrical forces (electrochemical
force) drive the movement of compounds across the cell
membrane
Both chemical and electrical forces (electrochemical
force) drive the movement of compounds across the cell
membrane
Factors affecting the rate of transport
The rate of transport will depend on:
The concentration gradient
The compound permeability to the membrane
The type and number of charges present on the compound
The rate of transport will depend on:
The concentration gradient
The compound permeability to the membrane
The type and number of charges present on the compound
Crossing the cell membrane
fats and oils can pass directly through
inside cell
outside cell
waste
lipid
sat
sugar aa H
2O
fats and oils can pass directly through
inside cell
outside cell
waste
lipid
sat
sugar aa H
2O
Types of Transport Proteins
Channel proteins are embedded in the cell
membrane & have a pore for materials to cross
Carrier proteins can change shape to move material
from one side of the membrane to the other
Channel proteins are embedded in the cell
membrane & have a pore for materials to cross
Carrier proteins can change shape to move material
from one side of the membrane to the other
Cell membrane channels
Need to make “doors” through membrane
protein channels allow substances in & out
specific channels allow specific material in & out
H
2O channel, salt channel, sugar channel, etc.
inside cell
outside cell
Need to make “doors” through membrane
protein channels allow substances in & out
specific channels allow specific material in & out
H
2O channel, salt channel, sugar channel, etc.
inside cell
outside cell
Protein channels
Proteins act as doors in the membrane
channels to move specific molecules through cell
membrane
HIGH
LOW
Proteins act as doors in the membrane
channels to move specific molecules through cell
membrane
HIGH
LOW
Passive transport
Compounds will move from area of high concentration toward
area of lower concentration
No ATP is needed for this type of transport
Passive transport mainly TWO types
A-Osmosis
B-Diffusion-diffusion again two types
a-simple diffusion- no energy needed
b- facilitated diffusion- no energy needed
-help through a protein channel
Compounds will move from area of high concentration toward
area of lower concentration
No ATP is needed for this type of transport
Passive transport mainly TWO types
A-Osmosis
B-Diffusion-diffusion again two types
a-simple diffusion- no energy needed
b- facilitated diffusion- no energy needed
-help through a protein channel
Osmosis
Each compound obeys the law of diffusion
diffusion of water from HIGH concentration of water to LOW
concentration of water
across a semi-permeable membrane
However, some compounds are unable to cross the cell membrane (glucose,
electrolytes…)
Water can cross will enter or exit the cell depending its concentration
gradient.
Each compound obeys the law of diffusion
diffusion of water from HIGH concentration of water to LOW
concentration of water
across a semi-permeable membrane
However, some compounds are unable to cross the cell membrane (glucose,
electrolytes…)
Water can cross will enter or exit the cell depending its concentration
gradient.
where is osmosis important
Cells in Solutions
PLASMOLYSIS
Isotonic Solution
NO NET MOVEMENT OF
H
2
O (equal amounts
entering & leaving)
Hypotonic
Solution
CYTOLYSIS
Hypertonic
Solution
PLASMOLYSIS
Isotonic Solution
NO NET MOVEMENT OF
H
2
O (equal amounts
entering & leaving)
Hypotonic
Solution
CYTOLYSIS
Hypertonic
Solution
PLASMOLYSIS
Diffusion
Simple diffusion-
no energy needed
Movement across higher to lower concentration gradient.
Facilitated diffusion-
Some compounds are unable to diffuse through the membrane.
They will be allow to cross if the membrane has proteins that
can bind these compounds and enable to cross toward the area
of lower concentration
Simple diffusion-
no energy needed
Movement across higher to lower concentration gradient.
Facilitated diffusion-
Some compounds are unable to diffuse through the membrane.
They will be allow to cross if the membrane has proteins that
can bind these compounds and enable to cross toward the area
of lower concentration
Simple and facilitated diffusion
inside cell
outside cell
lipid
inside cell
outside cell
H
2O
simple diffusion facilitated diffusion
H
2O
protein channel
inside cell
outside cell
lipid
inside cell
outside cell
H
2O
simple diffusion facilitated diffusion
H
2O
protein channel
Simple Diffusion
Doesn’t require energy
Moves high to low
concentration
Example: Oxygen or water
diffusing into a cell and carbon
dioxide diffusing out.
Doesn’t require energy
Moves high to low
concentration
Example: Oxygen or water
diffusing into a cell and carbon
dioxide diffusing out.
Simple Diffusion
The rate of diffusion will be increased when there is :
Concentration: the difference in between two areas (the gradient) causes
diffusion. The greater the difference in concentration, the faster the
diffusion.
Molecular size: smaller substances diffuse more quickly. Large molecules
(such as starches and proteins) simply cannot diffuse through.
Shape of Ion/Molecule: a substance’s shape may prevent it from diffusing
rapidly, where others may have a shape that aids their diffusion.
Viscosity of the Medium: the lower the viscosity, the more slowly molecules
can move through it.
The rate of diffusion will be increased when there is :
Concentration: the difference in between two areas (the gradient) causes
diffusion. The greater the difference in concentration, the faster the
diffusion.
Molecular size: smaller substances diffuse more quickly. Large molecules
(such as starches and proteins) simply cannot diffuse through.
Shape of Ion/Molecule: a substance’s shape may prevent it from diffusing
rapidly, where others may have a shape that aids their diffusion.
Viscosity of the Medium: the lower the viscosity, the more slowly molecules
can move through it.
Movement of the Medium: currents will aid diffusion. Like the wind
in air, cytoplasmic steaming (constant movement of the cytoplasm)
will aid diffusion in the cell.
Solubility: lipid - soluble molecules will dissolve through the
phospholipid bilayer easily, as will gases like CO
2
and O
2
.
Polarity: water will diffuse, but because of its polarity, it will not pass
through the non-polar phospholipids. Instead, water passes though
specialized protein ion channels
in air, cytoplasmic steaming (constant movement of the cytoplasm)
will aid diffusion in the cell.
Solubility: lipid - soluble molecules will dissolve through the
phospholipid bilayer easily, as will gases like CO
2
and O
2
.
Polarity: water will diffuse, but because of its polarity, it will not pass
through the non-polar phospholipids. Instead, water passes though
specialized protein ion channels
Facilitated diffusion
Doesn’t require energy
Uses transport proteins to move
high to low concentration
Examples: Glucose or amino
acids moving from blood into a
cell.
Doesn’t require energy
Uses transport proteins to move
high to low concentration
Examples: Glucose or amino
acids moving from blood into a
cell.
where is facilitated transport important
Active Transport
- Pumps
- phagocytosis
- Endocytosis/exocytosis
- Pumps
- phagocytosis
- Endocytosis/exocytosis
Active transport
ATP (energy) is needed
pump
Moves materials from LOW to
HIGH concentration
AGAINST concentration
gradient
ATP (energy) is needed
pump
Moves materials from LOW to
HIGH concentration
AGAINST concentration
gradient
Example-1 ATPase pumps
The most common: Na/K pumps reestablish membrane
potential. Present in all cells.
Two K
+
ions are exchanged with 3 Na
+
ions
The most common: Na/K pumps reestablish membrane
potential. Present in all cells.
Two K
+
ions are exchanged with 3 Na
+
ions
EXAMPLES OF ACTIVE TRANSPORT
Example 2: the thyroid gland accumulates iodine as it is
needed to manufacture the hormone thyroxin.
The iodine concentration can be as much as 25 times more
concentrated in the thyroid than in blood.
Example 2: the thyroid gland accumulates iodine as it is
needed to manufacture the hormone thyroxin.
The iodine concentration can be as much as 25 times more
concentrated in the thyroid than in blood.
Example 3: In order to make ATP in the mitochondria, a
proton pump (hydrogen ion) is required.
proton pump (hydrogen ion) is required.
where is active transport important
Endocytosis
Endocytosis: (“Endo” means “in”).
Endocytosis is the taking in of molecules or particles by invagination of
the cell membrane forming a vesicle. Integrity of plasma membrane is
maintained.
This requires energy.
Endocytosis is fallowed by exocytosis on the other side. – Transcytosis,
vesicle trafficking, or cytopempsis.
Endocytosis: (“Endo” means “in”).
Endocytosis is the taking in of molecules or particles by invagination of
the cell membrane forming a vesicle. Integrity of plasma membrane is
maintained.
This requires energy.
Endocytosis is fallowed by exocytosis on the other side. – Transcytosis,
vesicle trafficking, or cytopempsis.
There are two types of endocytosis
1. pinocytosis (cell drinking): small molecules are ingested and
a vesicle is immediately formed. This is seen in small intestine
cells (villi)
2. phagocytosis (cell eating): large particles, (visible with light
microscope) are invaginated into the cell (ie: white blood cells
‘eat’ bacteria
1. pinocytosis (cell drinking): small molecules are ingested and
a vesicle is immediately formed. This is seen in small intestine
cells (villi)
2. phagocytosis (cell eating): large particles, (visible with light
microscope) are invaginated into the cell (ie: white blood cells
‘eat’ bacteria
Phagocytosis
Used to engulf large particles such as food, bacteria, etc. into
vesicles
Called “Cell Eating
Used to engulf large particles such as food, bacteria, etc. into
vesicles
Called “Cell Eating
Capture of a Yeast Cell (yellow) by Membrane Extensions of
an Immune System Cell (blue)
an Immune System Cell (blue)
Receptor-Mediated Endocytosis
Some integral proteins have receptors on their surface to
recognize & take in hormones, cholesterol, etc.
Some integral proteins have receptors on their surface to
recognize & take in hormones, cholesterol, etc.
Exocytosis
Exocytosis: (“Exo” means “out”.)
Exocytosis is the reverse of endocytosis.
This is where a cell releases the contents of a vesicle
outside of the cell.
These contents may be wastes, proteins, hormones, or
some other product for secretion.
This also requires energy.
Example: vesicles from the Golgi fuse with the plasma
membrane and the proteins are released outside of the cell.
Exocytosis: (“Exo” means “out”.)
Exocytosis is the reverse of endocytosis.
This is where a cell releases the contents of a vesicle
outside of the cell.
These contents may be wastes, proteins, hormones, or
some other product for secretion.
This also requires energy.
Example: vesicles from the Golgi fuse with the plasma
membrane and the proteins are released outside of the cell.
Fusion of vesicle with plasma membrane is
mediated by a number of accessory proteins-
SNARE protein.
Require stimulus and Ca.
Exception- Renin from JG cells and PTH from
parathyroid gland by decrease in intracellular Ca.
Constitutive Secretion- Immunoglobulin from
plasma Cells and collagen from fibroblast.
Regulated- endocrine gland, pancreatic acinar cells
mediated by a number of accessory proteins-
SNARE protein.
Require stimulus and Ca.
Exception- Renin from JG cells and PTH from
parathyroid gland by decrease in intracellular Ca.
Constitutive Secretion- Immunoglobulin from
plasma Cells and collagen from fibroblast.
Regulated- endocrine gland, pancreatic acinar cells
Membrane Transport Proteins
1. Water Channels or Aquaporins (AQPs) –
12 types
Amount of water is regulated by No. of
AQPs
They are known as gated channel although
they are pores.
Two types a) Aquaporins- only water.
b) Aquaglyceroporins- also for
small molecules.
1. Water Channels or Aquaporins (AQPs) –
12 types
Amount of water is regulated by No. of
AQPs
They are known as gated channel although
they are pores.
Two types a) Aquaporins- only water.
b) Aquaglyceroporins- also for
small molecules.
2- Ion Channels-
All cells specially on excitable cells – Neurons and
muscle cells
Selective and non selective
Gated – voltage gated and extracellular agonist or
antagonist gated ex – acetylcholine gated cationic
specific channel at motor end plate of skeletal
muscle.
Conductance- 1-2 picosimens and > 100 picosimens.
Ex- Na, K, Ca, Cl, Anion , cation.
All cells specially on excitable cells – Neurons and
muscle cells
Selective and non selective
Gated – voltage gated and extracellular agonist or
antagonist gated ex – acetylcholine gated cationic
specific channel at motor end plate of skeletal
muscle.
Conductance- 1-2 picosimens and > 100 picosimens.
Ex- Na, K, Ca, Cl, Anion , cation.
3.Solute Carriers-
> 40 types , > 300 transporters.
three gps-1. Uniporters- single molecule across the
membrane (GLUT )
2. Symporters- Two or more molecules
Ex- Na-k-cl Symporter (Kidney)
Na - Glucose Cotransporter.
3. Antiporters- Two or more molecules in
opposite directions
Ex :Na- H antiporter ( PH regulation)
3Na- Ca , Cl- HCO3
> 40 types , > 300 transporters.
three gps-1. Uniporters- single molecule across the
membrane (GLUT )
2. Symporters- Two or more molecules
Ex- Na-k-cl Symporter (Kidney)
Na - Glucose Cotransporter.
3. Antiporters- Two or more molecules in
opposite directions
Ex :Na- H antiporter ( PH regulation)
3Na- Ca , Cl- HCO3
4.ATP DEPENDENT TRANSPORTERS
1. ATPase Ion Transporters
1. P- Type- gate phosphorylted during
transport. Na- K ATP ase.
2. V- Type- Vacuolar H- ATPase – urine
acidification on Vacules like endosomes
and lysosomes.
2. ATP – binding cassette (ABC) transporters – 7 subgroups transport
diverse group of ions ex- Cl, Cholesterol, bile acids, drugs, iron and
organic anions.
EX:- Cystic fibrosis transmembrane regulator.
Multidrug Resistance Protein.
organic Anions.
.
1. ATPase Ion Transporters
1. P- Type- gate phosphorylted during
transport. Na- K ATP ase.
2. V- Type- Vacuolar H- ATPase – urine
acidification on Vacules like endosomes
and lysosomes.
2. ATP – binding cassette (ABC) transporters – 7 subgroups transport
diverse group of ions ex- Cl, Cholesterol, bile acids, drugs, iron and
organic anions.
EX:- Cystic fibrosis transmembrane regulator.
Multidrug Resistance Protein.
organic Anions.
.
Molecular Motors:
Kinesin- over the microtubule
Dynein- retrogate transport
Myosin- over the microfilaments.- 18 types a
Kinesin- over the microtubule
Dynein- retrogate transport
Myosin- over the microfilaments.- 18 types a
Q-1 all membrane processes, such as pumping
and channelling of molecules are carried out
by.
a-lipid
b-carbohydrate
c-nucleic acid
d-protein
and channelling of molecules are carried out
by.
a-lipid
b-carbohydrate
c-nucleic acid
d-protein
47
Q-2 Which of the following statement about
membrane transport protein is incorrect
a-carrier proteins are similar to enzymes in that
they show saturation
b-carrier protein can facilitate both active and
passive transport
c-channel protein can facilitate both active and
passive transport
d-the Na
+
/Glucose transport protein carries out
secondary active transport.
Q-2 Which of the following statement about
membrane transport protein is incorrect
a-carrier proteins are similar to enzymes in that
they show saturation
b-carrier protein can facilitate both active and
passive transport
c-channel protein can facilitate both active and
passive transport
d-the Na
+
/Glucose transport protein carries out
secondary active transport.
48
Q-3 Diffusion across the plasma membrane is
more rapid if a substance is
a-a protein
b-hydrophilic
c-high in its oil : water partition coefficient
d-larger and globular in shape
Q-3 Diffusion across the plasma membrane is
more rapid if a substance is
a-a protein
b-hydrophilic
c-high in its oil : water partition coefficient
d-larger and globular in shape
49
Q-4 the difference between simple diffusion
and facilitated transport is that facilitated
transport.
a-is concentration dependent
b-occurs across plasma membrane
c-require membrane protein
d-utilize a substance moving with its
concentration gradient
Q-4 the difference between simple diffusion
and facilitated transport is that facilitated
transport.
a-is concentration dependent
b-occurs across plasma membrane
c-require membrane protein
d-utilize a substance moving with its
concentration gradient
50
Q-5 Erythrocyte glucose transporter specifically
transports glucose down its concentration
gradient and exhibit hyperbolic saturation
kinetics .This is an example of
a-active mediated transport
b-passive mediated transport
c-non- mediated transport
d-group translocation
Q-5 Erythrocyte glucose transporter specifically
transports glucose down its concentration
gradient and exhibit hyperbolic saturation
kinetics .This is an example of
a-active mediated transport
b-passive mediated transport
c-non- mediated transport
d-group translocation
51
Q-6 which one of the following is a correct
statement for Na-K ATPase.
a-it gives out 3 Na-ions and takes in 2 K-ions
b- it gives out 2 Na-ions and takes in 3 K-
ions
c- it gives out 3 Ca-ions and takes in 2 K-ions
d-it gives out 3 Na-ions and takes in 2 Ca-
ions
Q-6 which one of the following is a correct
statement for Na-K ATPase.
a-it gives out 3 Na-ions and takes in 2 K-ions
b- it gives out 2 Na-ions and takes in 3 K-
ions
c- it gives out 3 Ca-ions and takes in 2 K-ions
d-it gives out 3 Na-ions and takes in 2 Ca-
ions
52
Q7-which of the following effects of the steroid
digitalis is observed after treatment of
congestive heart failure.
a-decrease in cytosolic sodium levels
b-inhibition of Na-K ATPase
c-decrease in the force of heart muscle
contraction
d-stimulation of the plasma membrane ion
pump.
Q7-which of the following effects of the steroid
digitalis is observed after treatment of
congestive heart failure.
a-decrease in cytosolic sodium levels
b-inhibition of Na-K ATPase
c-decrease in the force of heart muscle
contraction
d-stimulation of the plasma membrane ion
pump.
53
Q8-you wish to design a new drug which will
act as an ionophore to deliver Ca
2+
across the
nerve cell membrane .This drug would most
likely be
a-hydrophobic on the outside and hydrophilic on
inside
b-insoluble in lipid
c-soluble in proteins
d-smaller than 0.001 nm in diameter
Q8-you wish to design a new drug which will
act as an ionophore to deliver Ca
2+
across the
nerve cell membrane .This drug would most
likely be
a-hydrophobic on the outside and hydrophilic on
inside
b-insoluble in lipid
c-soluble in proteins
d-smaller than 0.001 nm in diameter
54
Q9- the process by which a cell secretes macro-
molecule by fusing a vesicle to the plasma
membrane is called
a-endocytosis
b-exocytosis
c-pinocytosis
d-phagocytosis
Q9- the process by which a cell secretes macro-
molecule by fusing a vesicle to the plasma
membrane is called
a-endocytosis
b-exocytosis
c-pinocytosis
d-phagocytosis
55
Q10- free fatty acids enter cell by
a-passive diffusion
b-active diffusion
c- through carrier protein
d – Active transport
Q10- free fatty acids enter cell by
a-passive diffusion
b-active diffusion
c- through carrier protein
d – Active transport
56
Q-11 Aquaporins transport-
a. Water only
b. water and small molecules.
c. Water and Glucose
d. Water and salt.
Q-11 Aquaporins transport-
a. Water only
b. water and small molecules.
c. Water and Glucose
d. Water and salt.
57
Q-12 Which of the fallowing is responsible for PH
Regulation-
a. Antiporters.
b. Symporters
c. Uniporters.
d. Co-porters.
Q-12 Which of the fallowing is responsible for PH
Regulation-
a. Antiporters.
b. Symporters
c. Uniporters.
d. Co-porters.
58
Q-13 V type – transporters are
a. ATPase dependent.
b. Symporters.
c. Carrier Proteins.
d. Receptor Proteins.
Q-13 V type – transporters are
a. ATPase dependent.
b. Symporters.
c. Carrier Proteins.
d. Receptor Proteins.
59
Q-14 .GLUT is an example of-
a. Antiporters.
b. Symporters
c. Uniporters.
d. Co-porters.
Q-14 .GLUT is an example of-
a. Antiporters.
b. Symporters
c. Uniporters.
d. Co-porters.
60
Q-15 Presence of Ion channels are must on
a. Excitable tissue.
b. Non excitable tissue.
c. Renal tissue
d. Cardiac muscle.
Q-15 Presence of Ion channels are must on
a. Excitable tissue.
b. Non excitable tissue.
c. Renal tissue
d. Cardiac muscle.
61
Q-16 Na- K ATPase transport Na-
a. Towards Concentration gradient.
b. Against Concentration gradient.
c. Towards electro chemical gradient.
d. Against electrochemical gradient.
Q-16 Na- K ATPase transport Na-
a. Towards Concentration gradient.
b. Against Concentration gradient.
c. Towards electro chemical gradient.
d. Against electrochemical gradient.
62
Q-17. Rennin secretion from JG cells is an
example of-
a.) Exocytosis
b.) pincocytosis
c.) Vacular movement.
d.) Transcytosis.
Q-17. Rennin secretion from JG cells is an
example of-
a.) Exocytosis
b.) pincocytosis
c.) Vacular movement.
d.) Transcytosis.
63
Q.- 18. PTH secretion fro parathyroid glands require-
a.) low intracellular Ca.
b.) high Intracellular Ca.
c.) Low intracellular K.
d.) high Intracellular K.
Q.- 18. PTH secretion fro parathyroid glands require-
a.) low intracellular Ca.
b.) high Intracellular Ca.
c.) Low intracellular K.
d.) high Intracellular K.
64
Q-19. Transcytosis incudes-
a. Endocytosis and phagocytosis.
b. Endocytosis and pincocytosis.
c. Endocytosis and exocytosis.
d. Endocytosis only.
Q-19. Transcytosis incudes-
a. Endocytosis and phagocytosis.
b. Endocytosis and pincocytosis.
c. Endocytosis and exocytosis.
d. Endocytosis only.
65
Q-20. Transcytosis occurs at
a). Epethelial Cells.
b). Endocrine Cells.
c). Nerve cells.
d). None of the above.
Q-20. Transcytosis occurs at
a). Epethelial Cells.
b). Endocrine Cells.
c). Nerve cells.
d). None of the above.
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