Midterm Review PDF

Summary

This document reviews cell signaling, blood, and the nervous system. It includes review questions related to these topics and describes processes like signal transduction and membrane potential. The document appears to be study notes or review material, not a formal exam.

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)
The Nervous System
and Neuronal
Excitability
BI OL 1 2 1 6 – W K 4 – L 1
CHA PT ER 7
DR. T R E VOR KI N G
Reminder
Midterm Thursday Oct 3
◦ In class (paper)
◦ 75 minutes
◦ MC and SA
◦ Content: Weeks 1 - 4
Last class: structure and function of
nervous system
CNS and PNS
Neurons
◦ Action potentials

Neuroglia
◦ Myelin sheath

4 types of ion channels that
allow neurons to function:
◦ Leak channels
◦ Ligand-gated channels
◦ Mechanically gates channels
◦ Voltage gated channels
Last class: Membrane potential
The difference in charges across a membrane
Inside Cell Outside Cell
◦ Inside charge minus outside charge
◦ (+1) – (+4) = -3 +
+ +
◦ In resting neurons, the membrane is more
positive outside the cell than inside, therefore + -
the membrane potential is negative + +
+ -
◦ Most neuron cells -70 mV +
◦ Difference in ion distribution - - + - -
◦ Na+/K+ pump +
+
◦ Leak channels +1 +4
Section 1: https://forms.gle/yJmeANHfbCD9sPsX8 Section 2: https://forms.gle/rbqeiDq3kgC6DAhM9

Question: Membrane potential
Sensory receptors are part of which component of the nervous system?
◦ Afferent
◦ Motor neurons
◦ Central nervous system
◦ Autonomic

How would the following situations change the membrane potential of a neuron?
◦ Opening of voltage-gated K+ channels
◦ Opening of Cl- channels to allow entrance into the cell
◦ Closing of Na+ leak channel
◦ Addition of more negatively charged proteins to the cytosol of a cell
Graded potentials
What is a graded potential?
◦ A small deviation from resting membrane potential (less or
more negative) that occurs in dendrite and cell body
◦ Graded because the amplitude varies

Depolarizing
◦ Makes the membrane potential less polarized

Hyperpolarizing
◦ Makes the membrane potential more polarized

Graded potential spreads out along dendrite and cell body,
decreasing strength with distance

Dendrites and cell
body in blue
Ion channels and
graded potentials
Graded potential occurs when
Positive ions move in
mechanically gated or ligand gated
(depolarizing)
channels open or close
◦ E.g. sensory neurons, dendrites

Positive ions move in
(depolarizing)

Negative ions move
in (hyperpolarizing)
Stimulus strength
The amplitude of a graded potential
depends on the stimulus strength
◦ E.g. small knock vs. hard stubbing of toe
Summation of graded potentials
When two or more graded potentials add together

Summated membrane potential

Resting
potential

Stimulus 1 Stimulus 2
Action Potentials
Neuron communicate cell to cell via action potentials
◦ Changes in the charges across membrane that travel down the axon

Stronger than graded potentials
◦ All or nothing

After-hyperpolarization
Generation of the action potential
Threshold must be reached
◦ Typically –55mV

A stimulus must be strong enough to
depolarize the membrane to threshold
Subthreshold stimulus
◦ Not strong enough

Suprathreshold stimulus
◦ Stronger than necessary
◦ Although action potential itself is all-or-
none
Depolarizing phase
After a stimulus reaches the threshold (from graded potentials)
The rising of phase of the action potential. This occurs until the membrane
potential goes up to +30mV

© 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
 Repolarizing phase
The falling of phase of the action potential. This occurs until the
membrane potential gets back to rest –70mV

Repolarizing
phase

© 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
After-hyperpolarizing phase
After resting membrane potential is reestablished, the undershoot that is
observed. Typically goes down to –90mV

© 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Channels and ion flow during an action
potential: Resting state
Na+
Inside more Na+ Na+ Na+
negative than
Na+ Na+ Voltage gated
outside Voltage gated
Na+ Channel K+ Channel
Potential -70 mV

Activation
Activation Inactivation gate closed
gate open K+ K+
gate closed
K+ K+
K+
Channels and ion flow during an
action potential: Depolarization
Na+
Depolarization Na+ Na+ Na+
threshold reached
Na+ Na+
(-55mV)
Na+ channel
opens
Na+ rushes in,
making cytosol
more positive
Membrane
potential: +30 mV Activation
gate closed
K+ K+

K+ K+
K+
Channels and ion flow during an
action potential: Repolarization
Na+ channel Na+
inactivation gates
close
K+ channels open
and K+ leaves cell
Inside become
more negative
Na+ activation gate
closes and
inactivation gate
opens
Membrane
potential returns to
-70 mV Na+
Na+
Na+ K+ K+
Na+
Na+ K+ K+
K+
Action potential
propagation
Action potential moves down axon
◦ Maintains strength (unlike graded potential)

Na+ ions flooding in cause adjacent ion channels to
open
Creates a ‘wave’ of depolarization that travels down
the axon

Why doesn’t an action potential undergo
decremental conduction?
 Conduction velocity – how fast an
action potential moves down an axon Current flow through ECF
between Nodes, opening
Conduction velocity Na+ channels

Saltatory conduction Kinda slow
◦ Myelinated axons – few
ion channels under myelin
◦ Faster than continuous
conduction
◦ More efficient (less ATP)

Saltat =
leaping
Synapse
The point at which one neuron communicates with
another neuron or a target tissue
Chemical Synapses: Neurotransmitter
Release
Action 1 An action potential depolarizes
potential the axon terminal.

Axon
terminal

1

Postsynaptic
cell
Neurotransmitter Release
1 An action potential depolarizes
the axon terminal.

2 The depolarization opens voltage-
gated Ca2+ channels and Ca2+
enters the cell.
Axon
terminal

1

Voltage-gated Ca2+
Ca2+
Ca2+ channel 2

Postsynaptic
cell
Neurotransmitter Release
1 An action potential depolarizes
the axon terminal.

2 The depolarization opens voltage-
gated Ca2+ channels and Ca2+
enters the cell.
Axon
terminal
Synaptic 3 Calcium entry triggers exocytosis
vesicle of synaptic vesicle contents.

Ca2+
Ca2+
1
3

2 Docking
protein

Postsynaptic
cell
Neurotransmitter Release
1 An action potential depolarizes
the axon terminal.

2 The depolarization opens voltage-
gated Ca2+ channels and Ca2+
enters the cell.
Axon
terminal
3 Calcium entry triggers exocytosis
of synaptic vesicle contents.

4 Neurotransmitter diffuses across
the synaptic cleft and binds with
receptors on the postsynaptic cell.
1
3

2 4
Receptor

Postsynaptic
cell
Neurotransmitter Release
1 An action potential depolarizes
the axon terminal.

2 The depolarization opens voltage-
gated Ca2+ channels and Ca2+
enters the cell.
Axon
terminal
3 Calcium entry triggers exocytosis
of synaptic vesicle contents.

4 Neurotransmitter diffuses across
the synaptic cleft and binds with
chemically gated Na+ channel.
1
3
5 Na+ rushes in an depolarizes the
membrane

2 4
Receptor

Postsynaptic 5 Why are most chemical
cell
synapses one way
information transfer?
 Neuron Function
Neurotransmitters released from presynaptic neuron may depolarize the postsynaptic neuron,
generating an excitatory postsynaptic potential (EPSP).
Some neurotransmitters may block depolarization, generating an inhibitory postsynaptic
potential (IPSP). How?
Why? AP
EPSP
0

Membrane potential
(EPSP) (IPSP)
-55

IPSP -70
Neuron Function – Summation Types
Demo - Summation
Multiple EPSPs in the postsynaptic neuron may summate to a threshold level to generate an AP.
Summation may be spatial or temporal, and takes into account the number of EPSPs versus
IPSPs.

If the net summation of
EPSPs and IPSPs is a
depolarization that
reaches threshold, then
an action potential
occurs at the trigger
zone of the postsynaptic
neuron

https://www.youtube.com/watch?v=Pd0IQ-Nx8dM
Neurotransmitter Receptor Types
Ionotropic receptors function as ligand-gated channels
Metabotropic receptors function through a G-protein
Same neurotransmitter can have excitatory or inhibitory effects depending on the ion channel
Termination of the signal
Neurotransmitters must be degraded or
removed in order to terminate the signal
transduction
Diffusion: neurotransmitters can diffuse away
from synaptic cleft

Enzymatic degradation: enzymes can break
down neurotransmitters (e.g.,
acetylcholinesterase)

Uptake by cells:
taken back up by the neuron that released
them or passed to neighbouring neuroglia
(neurotransmitter transporters)

© 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Regulation of neurotransmitter release
Presynaptic modulation can regulate neurotransmitter release, leading to either increased or
decreased release

LESS neurotransmitter release MORE neurotransmitter release
Neural circuits
Revisiting the 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
BIOL 1216 – Human
Physiology
DR. TREVOR KING
ASSISTANT PROFESSOR, HEALTH AND PHYSICAL EDUCATION
What is this course?
Physiology - The study of the functions of an organism and its constituent parts
Human Physiology – How does the body work?
Some subdisciplines
◦ Neurophysiology
◦ Cardiovascular Physiology
◦ Respiratory
◦ Exercise Physiology
◦ Pathophysiology
Who am I?
Exercise Physiology
Cardiovascular Health
and Function
Athletic Performance
 Who are you?
Answer these questions (anonymous)

https://forms.gle/fvKJYKDUCbKRUZfLA
Why is Physiology
Important for
Everybody?
https://forms.gle/4m4SxG9VCA2jMs3V6
What are the details I need to know?
Assessment Details Weight
Lecture midterms (80 min each) midterm 1 – Oct 3 15%
midterm 2 – Nov 7 20%
Lecture questions Completed at the beginning of most classes 5%
(D2L and Google forms)
Lab PowerPoint presentation (5%) 35%

lab exam 1 (10%)

lab exam 2 (10%)

quizzes (6%)

post lab assignments (4%)
Lecture final exam (2 hour) Exam period (dec 11-21) 25%
TOTAL 100%
Textbook
Human Physiology (2019), Bryan H. Derrickson (2nd edition). Wiley. (ISBN: 9781119497783)
◦ Useful? (yes)
◦ Necessary? (depends on note-taking, background, or research abilities)
◦ Lab uses textbook (A copy available in the lab)
◦ 1 Copy on reserve at library

Online resources: WileyPLUS
◦ Not required, but useful
Class Overview:
Lecture Online Assignments
Review followed by small participation quiz at start of each class
If you participate in 80% of quizzes = 100%
If sick and missing a few classes, let me know
Goal: to see whether the info stuck, or whether I need to revisit
◦ On your team
Streaming Classes via Google Meet
Stream classes – see how it works
◦ Won’t be a replacement for in-class, but could use if needed

meet.google.com/anr-nvsi-mgb
Contact Me
Email: [email protected]

Office: U243F

Office hours: Tuesdays 1 to 2 pm or by Appointment (can be virtual)
Class Overview: Labs
Labs Start Next Week (Wednesday or Thursday)
See myMRU for your schedule
Labs run by the biology department
◦ Contact your instructor for lab questions
◦ Your lab has its own D2L site

Lab instructors
◦ Karen Sheedy (Lab Coordinator): [email protected]
◦ Valentine Brussee-Bohn: [email protected]
◦ Jessica Eggleton: [email protected]
Learning Objectives for Today
Identify common methodologies, foundational principles, and practical applications of
physiology as a science
Recognize foundational physiology concepts acquired from previous studies (reviewing chapters
2, 3, and 4, typically covered in high school) including:
◦ Homeostasis
◦ Acids and bases
◦ ATP
◦ Macronutrients
◦ Metabolism
◦ Cellular respiration
◦ Enzymes
◦ Ligand-protein interaction
◦ Components of the cell
Physiology as a Science (Lab 1)
The process of acquiring knowledge about some aspect of the natural world in a systematic way
is known as the scientific method

Make an observation
Formulate a hypothesis
Design an experiment to test your hypothesis
Interpret the data
The Quantitative Scientific Method

Observation and question
◦ E.g. Schrutes → low levels of CVD

Hypothesis
◦ Nitrates in beets
Experiment
◦ Give nitrate supplements
Results interpretation
◦ Supported → theory
◦ Not supported → new question
Key themes in physiology
Homeostasis
Maintenance of relatively stable conditions in the body’s internal environment.
Integration
When several components work together to accomplish a particular function.
Mechanism of action
Explain how the body works by indicating the mechanisms that are involved
Communication
Cells of the body must communicate with one another in order for the body to function
 Homeostasis
Maintenance of relatively stable internal environment
Body has many controlled variables that it wants to keep stable
What are some important variables to control?

https://education.wiley.com/content/shared/media/anatomy/3D_Interactives/3d_interactive_homeostasis.html
 Homeostasis Example
Variable to maintain (controlled): Body temperature maintained at 37 degrees

3. Start to sweat

37 ֯C
6. Start to shiver

1. Running outside 5. Come inside to cold AC
Homeostasis Via
Feedback
Feedback system most common way
to maintain homeostasis in controlled
variable
Receptor:
◦ Senses change Feedback loop

Control centre:
◦ Evaluates whether outside the set point
◦ Output when needed

Effector
◦ Produces response to change the
controlled variable
Homeostasis Via
Feedback
Feedback loop is a cycle of events in
which a parameter of the internal
environment is monitored, evaluated,
changed, re-monitored, re-evaluated
Positive and negative feedback loops Feedback loop
 STIMULUS

Disrupts homeostasis by increasing

Negative Feedback CONTROLLED CONDITION
Blood pressure

Reverses a change in a controlled RECEPTORS
Baroreceptors in
variable. certain blood vessels

Input
Action potentials

CONTROL CENTER
How most variables in the body are Brain

controlled Return to homeostasis when the
response brings blood pressure
back to normal
Action potentials
Output

EFFECTORS

Heart Blood
vessels

RESPONSE
A decrease in heart rate and the dilation
(widening) of blood vessels cause blood
pressure to decrease

COPYRIGHT © 2019 JOHN WILEY & SONS, INC. ALL RIGHTS
RESERVED.
 Contractions of the wall of the uterus force the baby's
head or body into the cervix

Increasing

Positive feedback CONTROLLED CONDITION
Stretching of cervix

RECEPTORS
Strengthens or reinforces a change in a Stretch- sensitive
nerve cells in the
controlled variable cervix

Input Action potentials

CONTROL CENTER
Brain
Increased stretching of the cervix
Something external must disrupt cycle causes the release of more
oxytocin, which results in more
stretching of the cervix
Brain interprets input and
Output
releases oxytocin

Cervix EFFECTORS
Muscles in the wall
of the uterus

Contract more forcefully

RESPONSE
Baby’s body stretches the cervix more

Interruption of the cycle: The birth of the baby decreases
stretching of the cervix, thus breaking the positive feedback
cycle

Positive feedback:
https://education.wiley.com/content/shared/media/anatomy/3D_Interactives/3d_interactive_homeostasis.html
Feedforward
Events occur in anticipation of a change in a controlled variable.
Ex. Mouth watering prior to a tasty meal
Predictions
Questions to figure out your background
Reminder:
Participation – if you answer 80% of in-class questions throughout the semester, you get 5%
Correct answers not required to get the grade https://forms.gle/VNgkWo1g7zxiRX8T6
Only open when presented in class
 https://forms.gle/VNgkWo1g7zxiRX8T6

Questions
The pH of your blood is kept around 7.4. When you exercise really hard, your muscles release a
bunch of hydrogen ions into the blood. What does this do to the pH of your blood?
◦ Lowers it (more acidic)
◦ Raises it (more basic)
◦ I don’t know

Which of the following has the lowest 'set point' for pH? (i.e. where is the most acidic)
◦ Saliva
◦ Gastric Juice (Found in Stomach)
◦ Blood
 Questions
Which of the following statements regarding ATP is correct? ATP
a) Releases energy when a phosphate bond splits
b) consists of an adenine molecule, a ribose molecule, and three phosphate groups
c) Is the energy currency of the cell
d) All of these statements regarding ATP are correct.
e) I don’t know

Which of the following can the body break down to produce ATP? (select all)
a) Carbohydrates
b) Protein
c) Fat
d) Caffeine
e) I don’t know
Questions
Catalysts function by:
a) combining with other substances in a reaction to create a new product
b) raising the amount of energy needed (making it more difficult) to start the reaction
c) breaking themselves apart to provide energy for a reaction
d) lowering the amount of energy needed (making it easier) to start the reaction
e) I don’t know
 Questions
Place the following steps of the cellular respiration of glucose in the correct order:
i) electron transport chain
ii) glycolysis
iii) Krebs cycle
iv) formation of acetyl CoA
a) ii; iv; iii; i
b) ii; iii; iv; i
c) i; ii; iii; iv
d) iv; iii; ii; i
e) I don’t know
Questions
The three main parts of a human cell include all of the following EXCEPT:
a) a rigid, protective, nonliving outer cell wall
b) a flexible plasma membrane separating the cell’s internal environment from the external
environment
c) the cytoplasm including the cytosol and organelles
d) the nucleus that houses most of the cell’s DNA
e) I don’t know
For more detailed review
See chapters 2, 3, 4
Won’t be tested on content from these chapters specifically, but they may help for
understanding of future content

The remaing slides give an idea of important content from chapters 2, 3, and 4
 Acids and Bases
For proper homeostasis, acid base balance
must be maintained pH ~7.4

E.g. H+ and muscle function

Video explainer Acids and Bases
ATP: Our energy ‘currency’
Break apart bond on 3rd phosphate group to
release energy
Energy captured to do work in the body

Energy
Macronutrients
Nutrients our body can use to provide ATP (energy)
◦ Carbohydrates
◦ Lipids
◦ Proteins
Overview of cellular
metabolism Anaerobic conditions

Which steps require oxygen and which ones do not?

Aerobic conditions

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Why is knowledge of nutrients and
metabolism important for athletes?
e.g. Carbohydrate loading
▪ Maximize glycogen storage
▪ Improve endurance
performance
e.g. fueling for exercise
▪ Fat, proteins, or
carbohydrates?
 Roles of protein
Building materials
Hormones
Enzymes
Acid-Base Balance
Transporters
Antibodies
Provide glucose and energy
Many Other

ATP
Video: Enzyme Functions and ATP
Ligand–protein interaction
▪ Ligand
◦ Any molecule or ion that binds to a particular site
on a protein through weak, noncovalent
interactions

▪ Binding site
◦ The region of protein where the ligand binds

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The three main components of the cell
Plasma membrane
▪ Forms the cells outer surface

Cytoplasm
▪ Consists of the cellular contents
between the plasma membrane and
nucleus

Nucleus
▪ Large organelle that houses most of the
cell’s DNA

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The three main components of the cell
Plasma membrane
▪ Forms the cells outer surface

Cytoplasm
▪ Consists of the cellular contents
between the plasma membrane and
nucleus

Nucleus
▪ Large organelle that houses most of the
cell’s DNA

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Reminders
Labs this week – Run by the biology department in the B-wing
 STIMULUS

Disrupts homeostasis by increasing

CONTROLLED CONDITION
Blood pressure

Last Class
RECEPTORS
Baroreceptors in certain
blood vessels

Input
Action potentials

CONTROL CENTER
Brain

Homeostasis
Return to homeostasis when the

◦ Negative feedback – returns to set point Action potentials
response brings blood pressure back to
normal
Output

◦ Positive feedback – reinforces change EFFECTORS

◦ Feedforward – anticipates change Heart Blood
vessels

Acids and bases Feedback loop
RESPONSE
A decrease in heart rate and the dilation

ATP (widening) of blood vessels cause blood
pressure to decrease

◦ Macronutrients
◦ Aerobic and anaerobic ATP production

Energy
Last Class
Proteins have many functions within the body
◦ Enzymes
◦ Transporters
◦ Structures

Components of the cell

Protein – ligand interactions
Section 1: https://forms.gle/AZwvNP7yWbAr3u4k6 Section 2: https://forms.gle/YBZhhpQFtWodsUaR9

Review questions
Blood glucose is regulated within a set point around 5 mm/L. If levels go up or down, the body acts to return to
the set point. This is an example of:
◦ Positive feedback
◦ Negative Feedback
◦ Feedforward
◦ Negative feedforward
When blood glucose increases, the pancreas releases more insulin. This insulin travels to the liver and tells the
liver to take more glucose up from the blood. The liver is the:
◦ Receptor
◦ Control centre
◦ Effector
◦ Response
Protein can do all except:
◦ Be used to produce ATP aerobically
◦ Be denatured (damaged) by acidic conditions
◦ Become an enzyme
◦ Be the main structural component of a cell membrane
Transport Across Plasma
Membranes
WEEK 2
DR. TREVOR KING
Learning Outcomes:
Membrane Transport
▪ Explain why selective permeability of a plasma membrane occurs
▪ Differentiate between the different gradients across the plasma
membrane
▪ Summarize the different mechanisms of passive and active transport
▪ Predict how changes in cellular conditions might affect transport
processes.
▪ Utilize the principles of membrane transport to analyze practical
instances, particularly focusing on epithelial transport as a key example.
Transport across the Plasma Membrane
When do we need to get things from outside of a cell to inside of a cell – or vice versa?
Plasma membrane structure
The lipid bilayer

Two back-to-back layers made
up of three types of lipid
molecules
Phospholipids
Cholesterol
Glycolipids
 Selective permeability
Permeable to Impermeable to

Why?
Small gaps created with
natural movement
Charged particles cannot
cross
Cholesterol in membrane
reduces H2O permeability

Less permeable to water
But why do things move across the
membrane?
Gradients across the plasma membrane
◦ Concentration gradient
◦ Electrical gradient

Solutes want to move DOWN a gradient

Area A Area B Area A Area B
+
-- - +
-- +
- - +
Concentration gradient + +
- - - Electrical gradient +
- +
- + +
 Concentration
gradient
Difference in the concentration of a
chemical from one place to another
◦ E.g. Inside to the outside of a plasma
membrane

What direction is the concentration
gradient of CO2?
 Electrical gradient
A difference in electrical charges
between two regions, such as across
the plasma membrane

What is the direction of the
electrical gradient for a positively
charged ion (e.g. K+)?
Electrochemical gradient
Both electrical and chemical forces act on ions
The Electrochemical gradient is a combination of both driving forces
Classification of Membrane Transport
Passive
Substance moves across the plasma membrane without
any energy input from the cell
◦ Down concentration or electrochemical gradient
◦ Downhill

Active
Cellular energy, such as ATP, is used to move a substance
across the plasma membrane.
◦ Against concentration or electrochemical gradient
◦ uphill

Image: kahn academy
 Diffusion: A Type Of Passive Transport
Random mixing of particles from one location to another because of the
particles’ kinetic energy (energy of motion).

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Factors influencing diffusion
Steepness of concentration gradient
Temperature
Mass of the diffusing particle
Surface area
Diffusion distance

Diffusion rate can be calculated
Fick’s law of diffusion

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 Fick’s Law
𝐶1 − 𝐶2 ∗ 𝐴 ∗ 𝐷
𝐽=
𝑋
𝑤ℎ𝑒𝑟𝑒,
𝐽 = 𝑝𝑎𝑟𝑡𝑖𝑐𝑙𝑒 𝑓𝑙𝑜𝑤,
𝐶1 = 𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛 𝑜𝑛 𝑜𝑛𝑒 𝑠𝑖𝑑𝑒
𝐶2 = 𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛 𝑜𝑛 𝑡ℎ𝑒 𝑜𝑡ℎ𝑒𝑟 𝑠𝑖𝑑𝑒
𝑋 = 𝑑𝑖𝑠𝑡𝑎𝑛𝑐𝑒
𝐴 = 𝑠𝑢𝑟𝑓𝑎𝑐𝑒 𝑎𝑟𝑒𝑎
𝐷 = 𝑑𝑖𝑓𝑓𝑢𝑠𝑖𝑜𝑛 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡
𝐽 = 𝑝𝑎𝑟𝑡𝑖𝑐𝑙𝑒 𝑓𝑙𝑜𝑤,
𝐶1 = 𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛 𝑜𝑛 𝑜𝑛𝑒 𝑠𝑖𝑑𝑒
𝐶2 = 𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛 𝑜𝑛 𝑡ℎ𝑒 𝑜𝑡ℎ𝑒𝑟 𝑠𝑖𝑑𝑒
𝑋 = 𝑑𝑖𝑠𝑡𝑎𝑛𝑐𝑒
𝐴 = 𝑠𝑢𝑟𝑓𝑎𝑐𝑒 𝑎𝑟𝑒𝑎
𝐷 = 𝑑𝑖𝑓𝑓𝑢𝑠𝑖𝑜𝑛 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 Fick’s Law Analogy
𝐶1 − 𝐶2 ∗ 𝐴 ∗ 𝐷 Analogy: People who want into festival
𝐽= C1-C2 = number of people wanting to get in
𝑋 A = the bigger the festival area, the more areas there are to get in
D = Fence hopping ability, conditions for hopping
X = height of the wall
Types of passive diffusion
▪ Simple diffusion
▪ Facilitated diffusion
▪ Osmosis
❑ Special form of diffusion

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Simple versus facilitated diffusion

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Simple diffusion
Passive process
solutes move freely through the
lipid bilayer
without the help of membrane
transport proteins

Dependent on concentration
gradient. Larger the gradient…

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 Facilitated diffusion: Channel mediated
Solute moves down its
concentration or
electrochemical gradient
across the lipid bilayer through
a membrane channel

Typically, ion channels
(K+, Cl-, Na+, CA2+)

Channels can be “gated”

Why would channel mediated diffusion
be slower than simple diffusion?
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 Facilitated diffusion: Carrier mediated
Used to move a solute down its
concentration or
electrochemical gradient
across the plasma membrane
◦ Not a continuous pore
◦ Solute binds to carrier

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 Carrier mediated transport
▪ Exhibits certain properties
❑ Specificity
❑ Affinity
❑ Saturation
❑ Competition

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Carrier mediated transport:
Specificity and affinity
Specificity: Solute shape must match
the shape of the carrier protein

Affinity is the strength that the
solute binds to the protein site
Certain proteins have higher
affinity to certain molecules

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 Carrier mediated transport:
Saturation and Competition
Saturation: limited number of
transporters, therefore
Transport maximum (Tm)
maximum rate of transport

Rate of transport
Competition: Similar solutes
may compete with one
another for the same binding
site, reducing rate of transport Reduced rate when
competition occurs

What would happen if you increased
the number of transporters?

What would happen if you reduced the
Concentration gradient of solute
affinity of the solute binding?

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 Osmosis
The net movement of solvent
through a selectively permeable
membrane
▪ In living systems the solvent is
water

Occurs via both:
▪ Aquaporins (water channels)
▪ Simple diffusion
Area of low solute conc. to Solutes suck!
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RESERVED.
high solute conc.
 Tonicity
▪ Affect that osmolarity
has on cell shape

▪ Osmolarity: amount
of dissolved particles
pulling the water
towards it

What is the tonicity of your blood plasma?
What would happen if you put a cell in salt
water? Distilled water?
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Active Transport
Remember: The movement of substances across a membrane
against their concentration or electrochemical gradient

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Primary active
transport
Uses ATP to move solute against
electrochemical gradient
▪ E.g. sodium-potassium pump

40% of energy use in a typical cell!

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 Sodium-potassium pump
The pump maintains an
electrochemical gradient in
the cell

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 Secondary active
transport
▪ Uses energy stored in the
electrochemical gradient of an
ion
▪ Drives other solute against
electrochemical gradients.
◦ E.g. sodium-glucose transporters

IMAGE: BIONINJA
Secondary active transport

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Transepithelial transport
▪ Movement of solutes across
epithelial cells.
▪ Tight junctions connect epithelial
cells

▪ Absorption
◦ When a solute moves from the lumen of an organ
into the bloodstream

▪ Secretion
◦ When a solute moves from the bloodstream into
the lumen of an organ

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Application to practice:
Multisource Carbohydrate Beverages
Glucose:
Epithelial cell
Fast absorption
(SGLT1) GLUCOSE
GLUCOSE GLUT2
SGLT1
Fructose:
Slow absorption
(GLUT5)
INTESTINAL
LUMEN
Combined: GLUT5
FRUCTOSE GLUT2 FRUCTOSE
More total CHO
absorption
BLOODSTREAM
Describe why this works using saturation or competition
Summary: Membrane Transport
Membranes are selectively permeable
Electrochemical gradients determine motion of solutes
Diffusion – down electrochemical gradient
◦ Simple
◦ Facilitated (proteins help)
◦ Osmosis

Active transport (uses ATP)
◦ Primary
◦ Secondary
Reminders
Office hours
◦ Tuesdays 1 to 2 (let me know you’re coming)
◦ Or by appointment
Last Class: Membrane Transport
Membranes are selectively permeable
Electrochemical gradients determine motion of solutes
Diffusion – down electrochemical gradient
◦ Simple
◦ Facilitated (proteins help)
◦ Osmosis

Active transport (uses ATP)
◦ Primary
◦ Secondary
Last Class: Secondary active transport

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Transepithelial transport
▪ Movement of solutes across
epithelial cells.
▪ Tight junctions connect epithelial
cells

▪ Absorption
◦ When a solute moves from the lumen of an organ
into the bloodstream

▪ Secretion
◦ When a solute moves from the bloodstream into
the lumen of an organ

COPYRIGHT © 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Application to practice:
Multisource Carbohydrate Beverages
Glucose:
Epithelial cell
Fast absorption
(SGLT1) GLUCOSE
GLUCOSE GLUT2
SGLT1
Fructose:
Slow absorption
(GLUT5)
INTESTINAL
LUMEN
Combined: GLUT5
FRUCTOSE GLUT2 FRUCTOSE
More total CHO
absorption
Why? Describe why this works using saturation, competition, specificity, or affinity BLOODSTREAM
Section 1 : https://forms.gle/pG5n47yH6qqGsEqu5 Section 2: https://forms.gle/BStWpfGCKzgQZUru9

Review Questions
Fructose is transported into the epithelial cells using Glut5, which is a carrier protein. As a
marathon runner, you want to maximize carbohydrate absorption to use as fuel. However,
Trevor has advised you that one litre of Gatorade an hour is all you need. Why wouldn’t you
want to drink 2 or 3 litres of Gatorade per hour (other than the fact that you would probably get
some terrible gastrointestinal issues)
◦ Via competition, too much fructose would reduce your absorption of glucose
◦ Via saturation, 1 L of Gatorade already saturates your Glut5 proteins
◦ Too much Gatorade would reduce affinity of glut5 for fructose binding
◦ Glut 5 doesn’t have enough specificity to bind to fructose.
Review Questions
The sodium-potassium pump works via:
◦ Simple diffusion
◦ Facilitated diffusion
◦ Primary active transport
◦ Secondary active transport

According to Fick’s law, an increase in diffusion distance has what impact on particle flow?
◦ Increase
◦ Decrease
◦ No change
Cell Signaling
CHAPTER 6
TREVOR KING
Learning Objectives
Recall the different types of cellular communication
Predict how cellular communication would be impacted by changes in specificity, affinity,
competition, and saturation
Describe how extracellular chemical messengers can be used to transmit a signal
Classify real examples of cellular communication
Explain why signal transduction is used by cells
Using your knowledge of extracellular chemical messengers, receptors, and signal transduction,
predict how a disturbance in the system would impact the cellular response
Why is cell signaling important?
Cells must communicate with each other to coordinate body activities and maintain homeostasis
E.g.
Step on tack Oxygen levels decrease

EPO
 Types of cellular communication
1. Gap junctions

2. Cell-to-cell binding

3. Communication through extracellular chemical messengers

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 Gap Junctions
Membrane proteins called connexins form tunnels called connexons that connect neighboring
cells.
Allows for rapid diffusion and communication
Connexon tunnel

E.g., neuron, muscle
cells

Connexin

What would cause the
diffusion to occur?

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Cell-to-Cell Binding
Surface molecules on two different cells bind to one another

E.g., Leukocytes and
immunity

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 Extracellular Messengers
Most common
▪ Provide a wide variety of
responses

Steps
▪ Binding of secreted chemical
messenger onto
downstream cell receptor
▪ Signal transduction
▪ Cellular response

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 Extracellular
Messengers
1. Receptor binding: extracellular
messenger binds to a protein called a
receptor. Target cell displays receptor on
plasma membrane or in cell
2. Signal transduction: receptor binding is
converted (transduced) into a target cell
signal. Series of molecules causing a
“chain reaction”
3. Cellular response: the response carried
out by the target cells after the signal
transduction pathway is complete

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Types of Extracellular Chemical
Messengers
1. Hormones

2. Neurotransmitters

3. Local mediators

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Extracellular Chemical Messengers:
Hormones
Carried by the blood to
distant target cells
▪ E.g. glucagon – pancreas
to liver
❑ Release glucose

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Extracellular Chemical Messengers:
Neurotransmitters
Released from a neuron into a synapse to reach a nearby target cell
❑ Diffusion

e.g. dopamine

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 Local Mediators
Also known as local
regulators or local agents

Signaling to nearby cells
via diffusion

Paracrine = neighboring
cells

Autocrine = same cell
Checkpoint: Apply your
knowledge
Fill in the blanks:
Insulin is a _______ that is released from the pancreas into the
blood. It travels through the blood to the muscle cells, telling them
the extract glucose from the blood.
When insulin reaches the muscle, it attaches to a protein in the
muscle cell wall called a ______.
This starts a cascade of signals throughout the muscle cell (called
signal _____) that result in the movement of glut 4 to the cell
membrane (called the cellular ______).
Based on last class, we know that glut 4 is a protein that uses
________ diffusion to allow glucose to enter the cell.
Hormones in the Blood
Most water-soluble extracellular messengers are in
“free” form
Most lipid soluble extracellular messengers are
bound to a transport protein
◦ Increase solubility in blood
◦ Less likely to be filtered out by kidney
◦ Provides hormone reserve in blood
 Remember:

Receptors
Extracellular chemicals exhibit their effects by binding to specific
downstream cell receptors

Messenger-receptor binding exhibits several properties
▪ Specificity
▪ Affinity
▪ Saturation Where have we seen
▪ Competition these properties?

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Specificity & Affinity
Extracellular chemical
messengers need specific
receptor shape to bind to
target cell
Affinity: the strength at which the ligand
binds to the receptor
▪ Stronger affinity=more likely to bind

The extracellular messenger in this
context is the ligand (i.e., molecule
binding to a specific site of a protein)

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Saturation
Limited number of receptors
Maximum rate of binding

Why doesn’t this figure show a
linear increase with these two
variables?

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 Adenosine

ZZZZZZZZ
Competition
Two molecules are competing Adenosine
for the same receptor if both receptor
are able to bind to the site

E.g. In the brain, adenosine
(agonist) and caffeine Adenosine caffeine
(antagonist) compete for the
same receptors

What could be done to Adenosine
increase the likelihood of one receptor
molecule to bind? inhibited

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Receptor Location
1) Inside the target cell 2) on the target cell plasma membrane
◦ Lipid soluble ◦ Water Soluble

Cannot pass through membrane
Can pass through membrane
Receptor Down
Regulation
Receptor Down-regulation
When extracellular messengers are present
in excess, the number of target cell
receptors may decrease

vesicle

Two methods
-Endocytosis
- Reduces saturation level
E.g. drug tolerance
-Chemical modifications of the receptor
- Reduces function or affinity Is this an example of negative or positive feedback?
Receptor Up-Regulation
When an extracellular messenger is deficient,
the number of target cell receptors may
increase

Two methods
-Exocytosis
-Synthesis of receptors
Checkpoint
Draw a line on the graph to
represent each situation:
a) Ligand increases affinity
b) Receptor down-regulation
c) Receptor up-regulation
d) Reduced competition

Number
Signal transduction
What is signal transduction from a high
level?

Sequence of events
1) Begins with the binding of an
extracellular messenger to a receptor
2) message is sent through relay proteins
3)Ends with the cellular response
Why even have relay proteins?
 Second Messengers and Protein Kinases
Second messenger: generated Second messenger
from binding to receptor (small Receptor Inactive relay
molecule or ion)  protein

Protein kinase: enzyme that Extracellular
phosphorylates (adds phosphate chemical messenger ☺
Active relay
(first messenger)
group) to target protein protein (protein  Effector
kinase) protein
◦ Can activate or inhibit
◦ Targets effector or other relay P
protein ☺
Effector protein
(phosphorylated)
Kinases often named after what they phosphorylate
e.g. tyrosine kinase (tyrosine), protein kinase G (cGMP) Cellular response
To be continued…
The Central Nervous
System
BIOL 1216 WK4 – L2
TREVOR KING
Last class: Graded and Action Potentials
Graded potential
◦ Receive information
◦ Dendrites and cell body – dissipates across cell

Action potential
◦ Graded potential (cell body/dendrites) initiates
action potential in axon if above threshold
◦ All or nothing
◦ Moves down axon Repolarization
phase
Myelination
◦ Faster and more
efficient action potentials
Nodes required to maintain signal
Last class: Neuron
communication
Synapse
◦ Point of communication

Neurotransmitter release
◦ EPSP and IPSP
◦ Spatial summation
◦ Multiple locations graded potentials
◦ Temporal Summation
◦ Repeated graded potentials at the same location
Section 1: https://forms.gle/wbYWXkeThfakzyZK7 Section 2: https://forms.gle/bbHi2f8cU7UFWadd7

Question: Graded potentials
How would the following situations would depolarize the soma of a neuron?
◦ Binding of a neurotransmitter to the post-synaptic cell that opens ligand-gated K+ channels
◦ An inhibitory post-synaptic potential (IPSP)
◦ Temporal summation of excitatory post-synaptic potentials (EPSPs)
◦ Spatial summation of excitatory post-synaptic potentials (EPSPs)
Question
Place the following steps on the graph:

2
A. Closing of sodium inactivation gate
3
B. Opening of voltage gated potassium gates

C. Opening of voltage gated sodium gates

D. Closing of potassium gates

1
4
 Learning outcomes of this Lecture Set
▪ Identify the functions of neurotransmitters
▪ Distinguish the different neural circuits
▪ Identify the general structures and functions of the spinal cord
▪ Describe the general structures and functions of the brain
▪ Match the different areas of the cerebrum to their functions
▪ Recognize the various ways that the brain is protected
▪ Identify the roles of the sensory, motor, and association areas of
the cerebral cortex

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Termination of the signal
Neurotransmitters must be degraded or
removed in order to terminate the signal
transduction
Diffusion: neurotransmitters can diffuse away
from synaptic cleft

Enzymatic degradation: enzymes can break
down neurotransmitters (e.g.,
acetylcholinesterase)

Uptake by cells:
taken back up by the neuron that released
them or passed to neighbouring neuroglia
(neurotransmitter transporters)

© 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Regulation of neurotransmitter release
Presynaptic modulation can regulate neurotransmitter release, leading to either increased or
decreased release

LESS neurotransmitter release MORE neurotransmitter release
Neural circuits
Remember: Organization of the Nervous
System

Copyright © 2014 Wolters Kluwer Health | Lippincott Williams & Wilkins
Spinal Cord: Protection
Spinal cord is protected by Spinal cord
vertebrae and meninges Meninges:
Pia mater
Arachnoid mater
Meninges: Connective tissue Dura mater
layers that surround the spinal
cord
▪ 3 layers of meninges Vertebrae
❑ Pia mater
❑ Arachnoid mater
❑ Dura mater

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RESERVED.
Spinal cord and spinal nerves
Spinal nerves are connected to the
spinal cord
A total of 31 pairs
Jobs
◦ Bring sensory information from receptors Spinal
to the spinal cord nerves
◦ Bring motor information from spinal cord
to muscles and glands
Spinal cord and spinal nerves
Ganglion: bundle
Structure and formation of the spinal nerve of cell bodies
Dorsal roots

Roots - 2 bundles
◦ Dorsal root: sensory
◦ Ventral root: motor

motor
To remember: command
Dorsal fin
Sensory
info

Ventral roots
Spinal cord and spinal nerves:
Gray matter
Grey matter:
◦ dendrites and cell bodies of neurons Dorsal gray horns
◦ unmyelinated axons

Dorsal gray horns
◦ Cell bodies of interneurons
◦ Process sensory information

Ventral gray horns
◦ Cell bodies of somatic motor neurons
◦ Send action potentials to skeletal muscle

Ventral gray horns
Spinal cord and spinal nerves:
White matter
White matter Lateral white column
Dorsal white column
◦ Myelinated axons of neurons

Subdivided into three sections
◦ Dorsal white columns
◦ Ventral white columns
◦ Lateral white columns

Ascending
Each contains bundles of axons

Descending
called tracts
◦ Ascending tracts – send signals
toward the brain
◦ Descending tracts – send signals away
from brain
Ventral white column
 Spinal cord: Reflexes
Reflex arc components:
1. Sensory receptor
▪ Detects the stimulus
2. Sensory neuron
▪ Sends information to central nervous system
4. Motor neuron
3. Integrating center (interneurons) 3. Integrating centre
(Interneurons)
▪ Brain or spinal cord
1. Receptor 5. Effector
4. Motor neuron (muscle)
▪ Sends out signal to effector organ 2. Sensory neuron

5. Effector
▪ Organ or gland that changes function in response to
motor neuron

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RESERVED. https://www.urmc.rochester.edu/MediaLibraries/URMCMedia/life-sciences-learning-
center/documents/2013-14Neuroscience/HandOnHotStove-092513-teacher.pdf
Spinal Cord: Reflexes (another example)

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Spinal cord:
putting it together
Trace the action potentials along their paths in the
following situation:
You’re in a dark room of a haunted house. You’re
sitting still, and all of a sudden, something hairy
rubs against your arm! All at once, you jump up,
your heart races, and you pee yourself.
Summary
The Brain
By the end of this part you will be able to…
Explain the various ways that the brain is protected
Discuss the functions of the different parts of the brain
Identify the roles of the sensory, motor, and association areas of
the cerebral cortex

COPYRIGHT © 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Brain: Protection
Cranium

Meninges

Blood brain barrier

Cerebral spinal fluid

COPYRIGHT © 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
 Brain: Protection
Cranium
◦ Bony structure

Cranium
Meninges
CRANIAL MENINGES:
◦ Dura mater Dura mater
◦ Arachnoid mater Arachnoid mater
Pia mater
◦ Pia mater
Brain
 Endothelial cell of
Tight brain capillary
junction

Brain: Protection Astrocyte
process

Blood-Brain barrier
◦ Specialized capillaries

Structural component
Transport
◦ Tight junctions proteins
◦ between endothelial cells
◦ Astrocytes
◦ Secrete chemicals to maintain “tightness”

Functional component
◦ Specialized membrane transporters Brain tissue
to allow only some water soluble
substances through
◦ Very selective

(b) Blood-brain barrier
https://www.youtube.com/watch?v=sKG81gJuTLM&t=58s&ab_channel=STAT
 ARACHNOID VILLUS

SUBARACHNOID SPACE

Brain: Protection
Cerebrospinal Fluid
◦ Clear and colorless
◦ Continuously circulates through CHOROID PLEXUS
various openings in the brain
(Ventricles) and subarachnoid space
◦ Produced by choroid plexus
Functions
◦ Mechanical protection Spinal cord
◦ Shock absorbing - damping
◦ Chemical protection
SUBARACHNOID SPACE
◦ Optimal chemical environment
◦ Circulation
◦ Exchange of nutrients and waste

Path of:
CSF
Venous blood
Pathways of circulating cerebrospinal fluid
Brain: Functions

COPYRIGHT © 2019 JOHN WILEY & SONS, INC. ALL RIGHTS RESERVED.
Areas of the Brain
The brain is divided into the:
◦ cerebrum
◦ cerebellum
◦ diencephalon
◦ brainstem Cerebrum

Diencephalon
Cerebellum
Brain Stem
Midbrain
Pons
Medulla oblongata
The Cerebrum I

II
The cerebrum III
◦ The cerebral cortex (outer layer) houses the conscious mind Layers of the cerebral
cortex (gray matter) IV Dendrites
◦ left and right cortices (hemispheres)
V
◦ deep areas under the cortex.
VI Axon
The cortexes Cerebral
◦ Divided into lobes white
matter
◦ Brodmann areas - functional
Cortex contains folds
Cerebral cortex
Cerebral white matter

(d) Frontal section of cerebrum
The Cerebrum - Lobes
frontal
Central sulcus
parietal
occipital
temporal
The Cerebrum – Brodmann Areas
The most important Brodmann areas
for movement:
◦ motor cortex and premotor cortex
◦ somatosensory cortex
◦ auditory cortex
◦ visual cortex.

Frontal lobe
◦ Conscious thought and decision making
Motor and Somatosensory cortex
The motor and somatosensory cortexes can
be mapped to correspond to body areas.
◦ Why are some areas larger than others?

https://www.youtube.com/watch?v=APuiZCxDnTA
Question
Where would the motor command to grab
an object come from?

Which hand did this person grab with?

C
B D
A