Resting membranepotential
TeacherKrishna
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Dec 22, 2017
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About This Presentation
Describes resting membrane potential, changes to RMP, abnormalities,
Slide Content
Department of Life Sciences
University of Calicut
Kerala, India 673 635
University of Calicut
Kerala, India 673 635
Electrical potential exist cross the membranes of all cells
Some cells are excitable
K
+
concentration is greater inside the cell than outside
K
+
moves out of the cell
Negative ions remain inside which prevent further movement of K
+
to
the outside
Potential difference in large mammalian neurons is 94mv -negative
inside
Na
+
ions are more outside than inside
Membrane is highly permeable to Na
+
Na
+
moves to the inside- inside become more positive
Na
+
movement makes outside negative and inside positive
Now the potential difference is 61 mv with positive inside
Some cells are excitable
K
+
concentration is greater inside the cell than outside
K
+
moves out of the cell
Negative ions remain inside which prevent further movement of K
+
to
the outside
Potential difference in large mammalian neurons is 94mv -negative
inside
Na
+
ions are more outside than inside
Membrane is highly permeable to Na
+
Na
+
moves to the inside- inside become more positive
Na
+
movement makes outside negative and inside positive
Now the potential difference is 61 mv with positive inside
Membrane Potentials
Resting membrane potential
in a mammalian nerve cell is
-90mv
Sodium –potassium pump –
Na+ to outside and K+ to
inside
Electronegative pump- more
positive charge pumped to
outside than to inside
3Na+ to outside for 2 K+ to
inside
Large concentration gradient
of K+ and Na+ inside and
outside
Resting membrane potential
in a mammalian nerve cell is
-90mv
Sodium –potassium pump –
Na+ to outside and K+ to
inside
Electronegative pump- more
positive charge pumped to
outside than to inside
3Na+ to outside for 2 K+ to
inside
Large concentration gradient
of K+ and Na+ inside and
outside
Electrochemical gradient
Na+ (outside cell) – 142mEq/L
Na+ (inside cell) –14mEq/L
K+ (outside cell) – 4mEq/L
K+ (inside cell) –140mEq/L
Na+ (outside cell) – 142mEq/L
Na+ (inside cell) –14mEq/L
K+ (outside cell) – 4mEq/L
K+ (inside cell) –140mEq/L
Channel proteins in rest
K+ and Na+ ions leak through channel proteins
Potassium-sodium leak channels
More K+ leak – 100 times than Na+
K+ and Na+ ions leak through channel proteins
Potassium-sodium leak channels
More K+ leak – 100 times than Na+
Channels and pumps
Action potential
Nerve signals are transmitted by action potentials
AP is a rapid change in the membrane potential
AP spreads rapidly along the nerve membrane
Sudden change from negative potential to positive
potential
Resting stage
Membrane remain
polarised
Postential at this
stage is -70mV
Nerve signals are transmitted by action potentials
AP is a rapid change in the membrane potential
AP spreads rapidly along the nerve membrane
Sudden change from negative potential to positive
potential
Resting stage
Membrane remain
polarised
Postential at this
stage is -70mV
Depolarisation:
Membrane is very permeable to Na+ ions- large number of
Na+ moves into the cell
Charge inside become neutral
Potential rise in Positive direction – this is called
depolaristion
Some fibers, the
potential
overshoots and
reach positive
value
Membrane is very permeable to Na+ ions- large number of
Na+ moves into the cell
Charge inside become neutral
Potential rise in Positive direction – this is called
depolaristion
Some fibers, the
potential
overshoots and
reach positive
value
Repolarisation
The Na+ channel begin to
close
K+ channels open more
than normal
Rapid diffusion of K+ to the
exterior
Reestablish the normal
negative potential
The Na+ channel begin to
close
K+ channels open more
than normal
Rapid diffusion of K+ to the
exterior
Reestablish the normal
negative potential
Voltage gated channels
Voltage gated Na
+
channels play a major role in
depolarisation and repolarisation during action potential
Voltage gated K
+
channels also play major role in speeding
up the repolarisation
These are in addition to the Na
+
-K
+
pump and the Na
+
-K
+
leak channels
Voltage gated Na
+
channels play a major role in
depolarisation and repolarisation during action potential
Voltage gated K
+
channels also play major role in speeding
up the repolarisation
These are in addition to the Na
+
-K
+
pump and the Na
+
-K
+
leak channels
Voltage gated Na+ channels
Voltage gated Na+ channel –activation-
inactivation
AS voltage reach between -70 and -50- sudden
conformational change in activation gate
Gate opens
This is activated state of the gate
Na
+
flow into the cell
Na
+
permeability increase 500-5000 fold
After a few 10,000ths of a second the inactivation gate closes
Na
+
can not move into the cell
Repolarisation starts
channels can open only after reaching resting potential
stage
inactivation
AS voltage reach between -70 and -50- sudden
conformational change in activation gate
Gate opens
This is activated state of the gate
Na
+
flow into the cell
Na
+
permeability increase 500-5000 fold
After a few 10,000ths of a second the inactivation gate closes
Na
+
can not move into the cell
Repolarisation starts
channels can open only after reaching resting potential
stage
Voltage gated K
+
channels
During resting state the K
+
channel remain closed
K
+
can not pass out of the cell through the membrane
As membrane potential goes up from -90 – gate opens
slowly
K
+
diffuse out
As opening of K
+
is slow by the
Time they are open Na+ channels
Begin to close
This cause repolarisation
+
channels
During resting state the K
+
channel remain closed
K
+
can not pass out of the cell through the membrane
As membrane potential goes up from -90 – gate opens
slowly
K
+
diffuse out
As opening of K
+
is slow by the
Time they are open Na+ channels
Begin to close
This cause repolarisation
Action Potentials
An action potential occurs when there is a reversal of
the normal resting potential, going from negative to
positive. Also called depolarization.
Depolarization occurs when a stimulus causes the
voltage-gated Na
+
channels to open, allowing Na
+
to
rapidly influx down its concentration gradient.
The sudden in-rush of positive sodium ions reverses the
membrane potential for a few milliseconds.
Then the voltage-gated K+ channels open, allowing K
+
to rapidly efflux due to its concentration gradient. This
brings the membrane back to negative inside and is
called repolarization.
An action potential occurs when there is a reversal of
the normal resting potential, going from negative to
positive. Also called depolarization.
Depolarization occurs when a stimulus causes the
voltage-gated Na
+
channels to open, allowing Na
+
to
rapidly influx down its concentration gradient.
The sudden in-rush of positive sodium ions reverses the
membrane potential for a few milliseconds.
Then the voltage-gated K+ channels open, allowing K
+
to rapidly efflux due to its concentration gradient. This
brings the membrane back to negative inside and is
called repolarization.
Action Potentials
Even though the voltage has returned to
negative, the membrane is not at resting
potential because it now has too much Na
+
inside
and not enough K
+
ions.
The presence of high Na
+
inside causes the
Na
+
/K
+
pumps to increase by a power of 3. The
faster pump rate quickly restores the membrane
back to its steady-state resting condition.
Even though the voltage has returned to
negative, the membrane is not at resting
potential because it now has too much Na
+
inside
and not enough K
+
ions.
The presence of high Na
+
inside causes the
Na
+
/K
+
pumps to increase by a power of 3. The
faster pump rate quickly restores the membrane
back to its steady-state resting condition.
Sodium channels have 2
gates, a normal voltage
(activation) gate (which is
closed at rest) and an
inactivation gate (which
is open at rest). The rapid
opening of the voltage
gate lets Na
+
rush in and
depolarizes the cell. This
is immediately followed
by closing of the
inactivation gate which
stops the Na
+
influx. At
the same time the K
+
gate
opens letting K
+
efflux
(repolarization).
Widmaier, et al., 2006
gates, a normal voltage
(activation) gate (which is
closed at rest) and an
inactivation gate (which
is open at rest). The rapid
opening of the voltage
gate lets Na
+
rush in and
depolarizes the cell. This
is immediately followed
by closing of the
inactivation gate which
stops the Na
+
influx. At
the same time the K
+
gate
opens letting K
+
efflux
(repolarization).
Widmaier, et al., 2006
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