BIOL 1216 Week 3: The Nervous System and Neuronal Excitability (Student Notes) PDF

Summary

These lecture notes cover the nervous system and neuronal excitability, including topics such as cell signaling, blood types, and an overview of the different parts of the nervous system, including the CNS and PNS. The lecture notes also detail learning objectives.

Full Transcript

Last class: Cell Signaling
Signal transduction
◦ Second messenger
Receptor Second
◦ Kinase
messenger
◦ Phoshorylation Inactive relay
 protein
Extracellular
chemical messenger
(first messenger) Active relay ☺
protein (protein  Effector
kinase) protein

Effector protein P
(phosphorylated) ☺

Cellular response
Last Class: Cell Signaling
Lipid soluble ECMs can bind in the cell
Receptor-hormone complex
Gene expression
◦ Transcription and translation

Other types of receptors
◦ Ligand gated ion channels
◦ Enzyme receptors
◦ Enzyme-coupled receptors
◦ G-protein coupled receptors

Signal amplification and termination
Last Class: Blood
Erythrocytes (Red blood cells)
◦ Erythropoiesis (feedback loop)
◦ Blood types

Leukocytes (white blood cells)
◦ Neutrophils
◦ Basophils
◦ Eosinophils
◦ Monocytes
◦ Lymphocytes
Section 1: https://forms.gle/YnVxZtxWVfPJB2Gc6 Section 2: https://forms.gle/vAvDeAEa4S2CJH2x8

Review Questions
Which of the following is false about cell signaling?
◦ Lipid soluble hormones can pass through the cell membrane
◦ The transcription of a gene involves making a copy of a DNA sequence (called mRNA)
◦ Signal termination always occurs once the first messenger dissociates from the receptor
◦ The binding of a single messenger to a receptor could result in the production of hundreds of second
messengers

A person with type A blood might be able to receive a transfusion containing which of the
following blood types? (select all that are correct)
◦ Type A
◦ Type B
◦ Type AB
◦ Type O
The Nervous System
and Neuronal
Excitability
BI OL 1 2 1 6 – W K 3
CHA PT ER 7
DR. T R E VOR KI N G
Learning Objectives
Describe how membrane potential is produced and maintained
Predict how a change in the system might impact membrane potential
Recall the organization of the nervous system
Differentiate the roles of different cells of the nervous system
Describe how electrical signals in neurons are generated and propagated (graded and
action potentials)
Outline the process of signal transmission at synapses
Identify the functions of neurotransmitters
Distinguish the different neural circuits
Divisions of the nervous system
Central Nervous system (CNS)
◦ Brain and Spinal cord

Peripheral Nervous System (PNS)
◦ Afferent division
◦ Efferent division
Organization of the Nervous System
Central Nervous system (CNS)
◦ Brain and Spinal cord

Peripheral Nervous System
(PNS)
◦ Afferent division
◦ Input into the CNS
◦ Efferent division
◦ Info from the CNS to effectors
◦ Somatic (voluntary): skeletal
muscles
◦ Autonomic (involuntary): Smooth
muscle, cardiac muscle, glands
◦ Sympathetic and
parasympathetic

Copyright © 2014 Wolters Kluwer Health | Lippincott Williams & Wilkins
Functions of the Nervous system
Sensory
◦ detect external or internal stimuli, and relay sensory
information to the brain and spinal cord

Integrative
◦ CNS analyzes sensory information, and makes decisions
for appropriate responses

Motor
◦ Motor information is conveyed from the CNS through
cranial and spinal nerves of the PNS to appropriate
effectors (muscles and glands).

Feedback loops!
Cells of the nervous system
By the end of this part, you will be able to:
Discuss the structure and function of neurons
List the roles of neuroglia
Explain the importance of myelination
Describe the ability to repair neurons of the CNS and PNS
Neuron Structure: An overview
Nerve cells/Neurons

Soma (Cell body)
◦ Control centre
◦ Dendrite receives signals

Axon
◦ Generate and propagate action
potentials

Axon Terminal
◦ communicates with other
neurons/cells at synapse
Neuron Function
Sensory neuron
Interneuron
Motor neuron

Compare this
organization to a
feedback loop
Electrical signals in
Neurons
Many cells in the nervous system display
‘Electrical Excitability’
E.g. Follow the path of action potentials
◦ Sensory neuron
◦ Interneuron
◦ Cerebral cortex
◦ Motor cortex
◦ Motoneurons
◦ Muscle (also excitable)
Neuroglia Astrocyte

Make up half the volume of the CNS
Nourish and protect neurons
Neuroglia cannot generate or
Oligodendrocyte
propagate action potentials
If injured, neuroglia fill spaces

Astrocytes

Microglial cell

Ependymal cell
Neuroglia
CNS and PNS have different neuroglia
E.g. formation and maintenance of myelin sheath
CNS – Oligodendrocytes
PNS – Schwann cell
Myelin Sheath
Electrical insulation
◦ Increases speed of conduction

Nodes of Ranvier
◦ Gaps in the myelination
Neuron Repair
Plasticity
◦ Ability to change throughout life
◦ E.g. sprout new dendrites, change synaptic contacts

Repair
◦ Regeneration after damage
◦ Neurons have limited ability to repair

PNS repair occurs if…
◦ Cell body is still intact
◦ Schwann cell remains active (guides and stimulates regrowth)

CNS has little or no ability to repair
◦ Typically permanent
Clinical Connection: Multiple Sclerosis
Disease that causes a progressive destruction of myelin sheaths of
neurons in the CNS
◦ Multiple regions of myelin sheath deteriorate to scleroses (hardened
scars)
Slows then short-circuits action potential conduction
Autoimmune disease
Appears between ages 20 and 40
First symptoms
◦ Heaviness or weakness in muscles
◦ Abnormal sensations
◦ Double vision
Brief remission, then attack every year or two
◦ Progressive loss of function interspersed with remission
Checkpoint: Nervous
System
Sam senses the pressure of the pen using a
________ receptor/neuron, which is a
component of the ______ division of the _______
nervous system.
This information is relayed to the ______ nervous
system, where it is passed to an ____ neuron.
The brain _______ this information and decides
that Sam must increase pressure on the pen
using the ______ division of the nervous system.
A _______ neuron tells the muscles of the hand
to squeeze harder.
All of this information is relayed via _____
potentials, which move quickly through the body
because many axons are are _______
Electrical signals in Neurons:
Ion channels
Ion channels cause changes in membrane permeability
◦ Ions can flow down electrochemical gradients
◦ Resting membrane potential (difference in charges) changes
◦ Allows for electrical communication
Remember: electrochemical gradient

4 types of ion channels that allow neurons to function:
◦ Leak channels
◦ Ligand-gated channels
◦ Mechanically gates channels
◦ Voltage gated channels
Ion channels: Leak
Leak channels have gates that randomly alternate between open and closed positions
Ion channels: Ligand-gated
A ligand-gated channel opens or closes in response to a specific ligand (chemical) stimulus.
Ion channels: Mechanically-gated
Mechanically-gated channels open or close in response to mechanical stimulation
◦ Mechanical stimulation may take on the forms of touch, pressure, tissue stretching, and vibration
Ion channels: Voltage-gated
A voltage-gated channel opens in response to a change in membrane potential (voltage)
◦ K+, Ca2+, Na+
◦ Important for action potentials
Membrane potential
Voltage that exists across the plasma membrane
◦ The presence of the plasma membrane creates an unequal distribution of positive and negative changes.
◦ The unequal distribution of charge is measured in volts or millivolts

Unstimulated neuron cells + + +
-+
display a resting membrane + - -
+ - -
potential of around -70 mV + -
+ - -
+ -
- The inside of the cell
- membrane is more
This difference in charge across the
- negatively charged
membrane is called polarization
than outside
Membrane potential
The difference in charges across a membrane
Inside Cell Outside Cell
Simplification:
+
◦ Charge on inside + +
◦ 5 positive, 3 negative + +
◦ 5-3 = +2 + - +
◦ Charge on Outside
+ -
◦ 6 positive, 3 negative +
◦ 6-3 = +3 - - - -
◦ Membrane potential is difference in charges +
◦ Inside charge minus outside charge +
◦ (+2) – (+3) = -1
◦ The membrane is more positive outside the cell +2 +3
than inside, therefore the membrane potential
is negative
◦ Most neuron cells -70 mV
Inside is more negative
(less positive) than outside
Determinants of resting membrane
potential
1. Unequal distribution of
ions in the ECF and cytosol
2. Action of the Na+/K+ ATPase
◦ 3 Na+ out and 2 K+ in

3. Differences in membrane
permeability
◦ More K+ leak channels than
Na+ leak channels
Membrane potential:
+
Hypothetical K leak channel only cell
1. Na+/K+ pump creates K+ concentration
gradient Hypothetical cell begins with no membrane potential

2. K+ would flow out (down concentration

Concentration
gradient) K+ leak Outside cell
+

Electrical
channel
Voltage: -90mV
K+
3. electrical gradient would increase, -
wanting to flow back into the cell Inside cell
K+
K+ K+
4. Eventually, the electrical gradient and K+
K+
concentration gradient would be equal:
equilibrium potential K+ K+ K+ K+

5. K+ equilibrium potential close to resting
membrane potential
What does that indicate?
Membrane potential:
+
Hypothetical Na leak channel only cell
1. Na+/K+ pump creates Na+ concentration Na+
Na+ Na+
gradient Hypothetical cell begins with no Na+
membrane potential Na+
2. Na+ would flow in (down concentration Na+ Na+ Na+

Concentration
Na+
gradient) Na+ leak Outside cell
-

Electrical
channel
Voltage: +60mV
3.Na+ electrical gradient would increase, +
wanting to flow back out of the cell Inside cell

4. Eventually, the electrical gradient and
concentration gradient would be equal:
equilibrium potential

5. Na+ equilibrium potential is NOT close to
resting membrane potential
What does that indicate?
Membrane potential:
Typical cell
Membrane is more permeable to K+
◦ Still leak of Na+ into cell
Na+

Na+ Electrochemical gradient
Na+

K+ Electrochemical gradient
Na+ Na+ Na+
More net movement of positive
charge out the cell + Outside cell

-
Inside cell
Na+/K+ ATPase balances the Na+
leak in and K+ leak out K+ K+ K+
K+ K+
◦ Maintains electrochemical gradient of K+
each NOT at equilibrium potential

What is required?
Checkpoint
What would happen to membrane potential in the following hypothetical situations?
◦ A cell has more Na+ leak channels than usual
◦ Increased K+ leak channels
◦ The Na+/K+ pump was blocked (stopped working)