PCB4843-Chapter 8 - Olfaction PDF

Summary

This document provides an overview of the olfactory system, covering key concepts such as the relationship between chemical stimuli and perception, the structure of the olfactory epithelium and its different cell types, the mechanisms by which odors activate olfactory receptor neurons, and the encoding of odor information in the olfactory bulb.

Full Transcript

Key concepts for chapter 8 (olfaction)
The relationship between the chemical stimulus and perception.

Structure of the olfactory epithelium and the different cell types.

How odors activate olfactory receptor neurons anatomically (where they bind to),
electrically (depolarize) and the transduction cascade.

Odor sensitivity of olfactory receptor neurons (very broadly selective)

The number of olfactory receptor genes, and the logic of how different
receptors are expressed in each olfactory receptor neuron.

What are glomeruli anatomically and what do they represent molecularly?

The input-output structure of a glomerular unit.

How odor information is encoded in the bulb.

Projections from the bulb to the rest of the brain.
In humans, olfaction warns of harmful substances, combines
with taste for identification and enjoyment of food

In animals (possibly humans), some odors
are used for communication (pheromones).
Although remains controversial in humans.

Two animals tracking an odor

Although we don’t commonly use olfaction for
tracking, humans can learn to do so.
Improvements with training
Olfactory stimuli are airborne volatile chemical
stimuli that are detected by the olfactory system
Volatile compounds in popcorn

3-methyl butanal (malty)
Many natural compounds contain

Furfural (nutty)

2-acetyl pyrrole (rice, bread)

Vanillin (vanilla)

The same odor presented at different
concentrations can evoke different perceptions.
Walradt et al., 1970

Indole – pleasant at low
concentrations, putrid at high. Perception

Enantiomers
of carvone.

Chemically similar molecules can have different perceptions.
 The relationship between olfactory stimuli and perception
is complicated.

Each tick is a person’s response Descriptors

Low
concentration

High
concentration
 The relationship between olfactory stimuli and perception
is complicated.

Each tick is a person’s response

Low
concentration

Descriptors
(side by side)

High
concentration
Ethyl-2-methylpentanoate smells
similar at different concentrations
 The relationship between olfactory stimuli and perception
is complicated.

Each tick is a person’s response

Low
concentration

Descriptors
(side by side)

High
concentration
3-Hexanol evokes different
perceptual experiences
 The relationship between olfactory stimuli and perception
is complicated.

Each tick is a person’s response

Low
concentration

Descriptors
(side by side)

High
concentration
Sweeter and more delicious
at higher concentrations.
Odors have distinct detection thresholds (the lowest
concentration that evokes a perceptually detectable response)

Ozone is detected at a lower concentration
than D-limonene (citrus)

Worse

Each animal has odors that
they are most sensitive to.

Better
Humans: (from the good scents company)

3-mercapto-3-methylbutyl-formate:
Sulfurous, catty, caramelized onion, roast
coffee, roast meat.
n-octanoic acid: rancid-like

n-pentanoic acid: Sweet and fruity McGann 2017
Movie: 0:03-0:14
Olfactory receptor neurons are located in the nasal cavity
and respond to odors.

Receptor neurons have cilia, which
extend into a thick layer of mucus which
comes into contact with odor molecules.

Bowman’s glands

Produces mucus that protects against
viruses and helps trap odor molecules.

Supporting cells
Contain enzymes that protect against
potentially harmful chemicals
Basal cells: ORNs are generated
continuously from dividing stem cells
maintained by basal cells.
Olfactory receptor cells continually regenerate

Basal cells are the source of newborn ORNs
Odors generate a receptor potential in the cilia, which
triggers an action potential that propagates along its axon

Odors are detected by specialized
proteins located on the cilia.

Puffing odor onto cell body does
not evoke a (strong) response.

Spiking in axon

To the brain
(olfactory bulb)

Spiking in soma
Spiking in the soma is transmitted down
the olfactory nerve to the olfactory bulb.

Current in cilia

In the nose

Odor
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Odor transduction in olfactory receptor neurons

1. Odorants bind to odorant receptor protein.

2. G-protein Golf is stimulated

3. Activates adenylyl cyclase

4. Forms cAMP

5. cAMP binds to cyclic nucleotide-gated cation channel which
allows influx of Na+ and Ca2+.

6. Opens Ca2+ activated Cl- channels.
Thought to serve as additional amplification step.
Sensory transduction cascade

1 3

5 6
4
2
Cl- mediates olfactory sensory neuron sensitivity

Typical concentrations
Cl- normally acts as a hyperpolarizing ion.
Since it is typically more
concentrated extracellularly.
Driving force to flow inside
making inside more negative.

Cl- is concentrated in ORNs.

Active transporter (NKCC) moves sodium,
potassium and chloride in the same direction.

Opening of Cl- channels causes flow of negative ions outside.
Inside of cell becomes more positive.
Olfactory receptors are found at the highest concentration in
A) Ensheathing cells
B) Olfactory cilia
C) Cribiform plate
D) Bowman’s gland cells
E) Olfactory stem cells
What would be a consequence of knocking out a protein critical in the
olfactory cAMP pathway?

A) Odorants diffuse away
B) Anosmia occurs
C) Cilia channels become sensitized
D) Receptor cells degenerate
In terms of scent detection and tracking capabilities in humans

A) The olfactory epithelium of humans is larger than that of most canines.

B) Percentage-wise, humans devote more of their cortex to
olfaction than do rats
C) Humans, like dogs, can follow scent trails by frequent
sniffing and orthogonal digressions

D) Humans can detect most chemical compounds at lower
thresholds than almost all other organisms
Movie: 2:46-4:51
Olfactory sensory neuron receptive fields are
complex and respond to many different odors

Experiments that recorded individual
ORNs in response to odor observed:

Many ORNs responded to many odorants.

Many responded to some odorants,
but not others.

Neuron 1 Neuron 2 Neuron 3
Olfactory receptor neurons exhibit broad tuning to
different odorants (actual data).

Recording from single olfactory receptor neuron
Response to different odorants

No Odor

Odor 1

Odor 2

Odor 3

Odor 4

Odor 5

Odor 6

Odor 7

Odor 8

What is its receptive field?
Duchamp-Viret et al., 1999
There are more than 1000 different odorant receptor genes.

Mature olfactory sensory neurons
Discovered by Linda Buck expressing a green marker
and Richard Axel in 1991.

2004 Nobel prize.

In mice, nearly 5% of mammalian
genome encodes odorant receptors.

Olfactory marker protein
Fewer in humans (about 400)

Still a large number, and many are present as pseudogenes
(DNA that cannot be transcribed into a stable mRNA).
Each olfactory receptor neuron only I7 receptor
expresses one receptor type.

Transgenic mouse generated to express GFP
in cells that express only one odorant receptor.

I7 vs M71 (two different receptor types).

M71 receptor
This approach allowed a more comprehensive M71 receptor
analysis of receptive fields of neurons that
express the same receptor type

The M71 OSN responds preferentially to odorants
containing a mixture of “F”, but not other compounds.

That does not mean that F is the
optimal ligand for the M71 receptor.
(would require testing a nearly infinite
number of potential ligands)

M71 activation
by odors A-F

Different odor receptors have specific tuning properties.

However, the same receptor type can respond
to many different odors.
Each odorant receptor is sensitive to a range of ligands.
Different ORs

The same odor will activate many different receptors
(different curves), but at different affinities.

Binding
They are high affinity for some
ligands, low affinity for others. Ligand Concentration

High affinity -> Binds at low concentration

Low affinity -> Needs higher concentration to bind

Explains broad tuning.

Predicts that an odorant is encoded as the
combination of activated receptors.
Olfactory receptor neurons extend long axons that target
the olfactory bulb
Olfactory receptor neurons expressing the same receptor type
converge to a single region of neuropil in the olfactory bulb

Olfactory epithelium Olfactory bulb
Mapping of olfactory receptor neurons onto the olfactory bulb

Olfactory receptors map onto
the surface of the olfactory bulb.
 The anatomical structure of the olfactory bulb

Input: Detecting Odors
↑
Input layer

Interneurons

Output neurons

↑ ↑

Output neurons

↑
Interneurons
Output: To cortex
 The neurons surrounding a glomerulus can be divided
into many different subtypes

Neuronal diversity in the olfactory bulb
The input-output organization of the bulb and retina

Input Odors coming into nose Input: Detecting Odors
↑
Odors stimulate ORs located on ORN cilia
Action potential transmitted to axon terminals
located in bulb glomeruli

Output Signal from bulb to rest of brain

Mitral/tufted cells transmit beyond the bulb. ↑
Output: To cortex

Input Light coming into eye

Rods and cones primarily carry out phototransduction.

Output Signal from retina to rest of brain

Ganglion cells provide output to the rest of the brain.
How is odor information encoded in the olfactory bulb?

Across population of glomeruli

Each glomerulus reflects the input from one olfactory receptor type.

Glomerular responses are molecularly pure!

Odorants evoke activity in distinct spatial patterns of glomeruli
(olfactory maps).

Odors can evoke different response properties in each
glomerulus (time course, adaptation, excitation vs inhibition).

Individual olfactory bulb neurons

Odorants evoke complex patterns of spiking activity
that are influenced by odor and concentration.

Neurons are tuned to different phases of the respiratory cycle.
Imaging from glomeruli
 The GFP protein can be fused to other proteins that can
modulate fluorescence

Protein calcium Baseline fluorescence
sensor (GECI)

Calcium
(GCaMP6s)

Chen et al., 2013

Calcium sensing Akerboom et al., 2012
domain
Peak ΔF/F versus [Ca2+]
Fluorescence and electrical time course
GCaMP6f

Badura et al., 2014

Log10 ([Ca2+]/M) * * * ** * Spike
Problem: 2-photon microscopy provides significantly better
resolution in the lateral (x/y) and axial (z) dimensions.

1-photon 2-photon

Chris
Xu lab

Olfactory bulb glomeruli
1p 2p
1 2
p p
Movie of two odorants presented side by side

(Deleted from ppt to reduce file size)
Peaks of activity in response to odors

Isoamyl acetate (Banana) Methyl valerate (Orbitz bubblemint)

Different odorants evoke different glomerular patterns
Recordings from many glomeruli reveal complex
excitatory and inhibitory dynamics

Time course from 3 glomeruli

Color indicates amplitude of glomerular response
Glomerulus
 Odorants cause complex changes in (single) neuron spike
rate and timing

Odor causes delay
Not responsive

More spikes
More spikes

Delayed with increase spiking
Delayed with increase spiking
Olfactory bulb neurons are sensitive to sniff phase

Sniffs from 3 of the trials
Top: Recording from mitral cell to
many odor presentations. Respiration

The rows are repeated measurements of Spikes in many trials (black ticks)
the same neuron to an odor response.
Trials
Cell responds to the odor in very confusing way. Time

Sniffs from 3 of the trials

Respiration occurs at different times Respiration
and phases relative to the odor onset.
Spikes in many trials
Normalize each sniff from 0-2pi

Black: Unaligned time vs spikes

Red: Time vs spikes when aligning respiration.
Neurogenesis also occurs in the olfactory bulb

Neurons migrate via the rostral migratory
stream continuously throughout life.

These neurons rapidly integrate into the
olfactory bulb circuit and become functional.

Begin responding to odor within hours of arrival.
Anatomical pathway beyond the olfactory bulb
Anatomical tracing of the projections from a single mitral cell

One mitral cell (yellow) can connect to 14 brain areas.

Projections from neighboring mitral cells overlapped with one another.
No apparent topography in projections out of bulb.
What is the organization beyond the bulb?

Experiment: Fill neighboring glomeruli
with differently colored dyes, examine
the projections to cortex.

Result: The projections largely
overlapped with one another.

Output of bulb seems to be random

Could reflect that odors may not
have innate meaning.
This observation is consistent with physiological
recordings from the cortex

Responses in the olfactory bulb
exhibit clear spatial organization.

Recordings from piriform cortex reveal a
distributed and somewhat random organization
of cells responding to different odorants.
Olfactory bulb receives feedback from many brain areas

Feedback to OB

Feedback to OB
Olfactory receptors are found outside of the olfactory system

The olfactory system is highly
enriched with these receptors.

Hence “olfactory” receptors.

Odor receptors are found in
many parts of the body.

“Olfactory” receptors may in fact by general chemosensors whose
functionality has been adapted by different sensory systems.
How many odor receptor genes are there in mice?

What does a glomerulus represent?

How many odor receptor genes are there in mice?
Introduction to microscopy
Imaging using brightfield transmitted light

Cheap, easy to understand, but many samples
don’t have much contrast unless they are stained
with something.

Brightfield image of Golgi
unstained human stained
A549 epithelial cells section

Lavilla…Vendrell 2018, Chemistry
Fluorescence imaging

Fluorescence is a phenomena in which the absorption of light
results in a near instantaneous (~ 1/1000000 s) emission of a longer
wavelength of light.
Fluorophore is excited by some wavelength, relaxing causes
emission (fluorescence) of a longer wavelength.
(Many materials fluoresce in response to ultraviolet light).

Abramowitz and Davidson (NHMFL)

Fluorescence is not 100% efficient – not all absorbed photons evoke fluorescence.
Fluorescence cannot be brighter than the light used to evoke fluorescence.

The fluorescence emission of an object can be completely different from any intrinsic
absorption or reflectance properties.
Green chlorophyll fluoresces red

Distinct from bioluminescence which is actually “glowing”.
e.g., D-luciferin undergoes a chemical reaction that emits visible light.
Wolfs et al., 2014 (Radiolabeling strategies for radionuclide imaging of stem cells)
If fluorescence is localized, it can be used to enhance contrast

White light 470 nm light

Fluorescence stamp

Crustacean (Lysiosquilla maculate)

Coral (Scolymia)

Marshall and Johnsen 2017 (Fluorescence as a means of colour signal enhancement)
Molecules exist that absorb and fluorescence in many
different colors
Absorption and emission spectra of two fluorophores

Excitation/emission spectra of the two fluorophores
eGFP

Absorption Emission
Sample

DAPI

Absorption Emission

Cell Bodies
The spectra of the two fluorophores are mostly non-overlapping.

All cells One Cell Type
T
 Separating excitation and emission wavelengths using
different optical filters in a fluorescence microscope

Camera Dichroic mirror

Excitation

Transmission (%)
Light source Emission Emission
filter
filter filter

Dichroic
Fluorophore
mirror Fluorophore
absorption
Excitation emission
filter Objective

Specimen Wavelength (nm)

Reflected light fluorescence microscope directs broad Filters
spectrum (white) light to the sample through the objective.

Separation of wavelengths is accomplished by
combining optical filters and mirrors.
Filter cube
Microscopes can easily change the filter sets to
accommodate different fluorophores.
In an epifluorescence microscope, which of the following separates the
light source and the fluorescence emission?
A) Emission filter
B) Dichroic mirror
C) CCD camera
D) Excitation filter
This is the absorption and emission spectra
of GFP. What would be the best choice for
an excitation and emission filter?
A) Excitation of 550 nm; emission of 488 nm
B) Excitation of 488 nm; emission of 530 nm
C) Excitation of 300nm and emission of 488 nm
D) Excitation of 515 nm and emission of 470 nm
This is the absorption and emission spectra of an Alexa Fluor dye.
What would be the best choice for an excitation and emission filter?
A) Excitation of 550 nm; emission of 488 nm
B) Excitation of 488 nm; emission of 530 nm
C) Excitation of 300nm and emission of 488 nm
D) Excitation of 550 nm; emission of 575 nm
E) Excitation of 600 nm; emission of 525 nm
In this epifluorescence microscope diagram, label
parts A and B B
A) A
B)
Draw a simple epifluorescence microscope with arrows indicating the
light path
Conclusions

Olfactory system is designed to detect airborne volatile molecules

Many different types of sensory neuron receptors, each of which is broadly
tuned with a slightly varying affinity.

Sensory neurons of the same type converge into the olfactory bulb,
forming a topographic mapping of different receptors on the surface.

Something happens in the bulb, which transmits signals to many other
brain areas.

A seemingly highly organized projection to the olfactory bulb is discarded.