The document summarizes the mechanism of smell (odor) detection in humans. It discusses: 1) How smells are detected by sensory receptors in the nasal cavity that respond to airborne chemicals and signal the brain. 2) Each sensory neuron expresses only one type of odor receptor protein that binds to specific odor molecules. The combination of activated neurons allows discrimination of thousands of smells. 3) The signal is transmitted along the olfactory nerve to the brain which interprets the pattern of activated neurons as a particular odor. This provides a mechanism for the brain to distinguish millions of different smells.

1. MECHANISM OF ODOUR

2. Why do we need smell?
 Smell is our distant chemical sense.
 For many animals, smell is the most important sense.
 Although for humans smell is not as important as say vision
or hearing, we do use smell more than we think to guide
behavior.
 Smell is an important part of taste. Many qualities of foods
that we think we taste, are actually a function of smell

3. The Sense of Smell
 Smell depends on sensory receptors that respond to airborne
chemicals.
 In humans, these chemoreceptor's are located in the olfactory
epithelium — a patch of tissue about the size of a postage stamp
located high in the nasal cavity. The olfactory epithelium is made up
of three kinds of cells:
 sensory neurons each with a primary cilium
 supporting cells between them
 basal cells that divide regularly producing a fresh crop of sensory
neurons to replace those that die (and providing an exception to the
usual rule that neurons seldom are replaced).

5. The sequence of events
 The cilia of the sensory neurons are immersed in a layer of
mucus. Odorant molecules (molecules that we can smell) dissolve
in the mucus and bind to receptors on the cilia. These are
"7 pass" transmembrane proteins.
 Binding of the odorant activates a G protein coupled to the receptor
on its cytoplasmic side.
 This activates adenylyl cyclase, an enzyme embedded in the
plasma membrane of the cilia.
 Adenylyl cyclase catalyzes the conversion of ATP to the "second
messenger" cyclic AMP (cAMP) in the cytosol

7.  cAMP opens up ligand-gated sodium channels for the facilitated
diffusion of Na+ into the cell.
 The influx of Na+ reduces the potential across the plasma
membrane.
 If this depolarization reaches threshold, it generates an action
potential.
 The action potential is conducted back along the olfactory nerve to
the brain.
 The brain evaluates this and other olfactory signals reaching it as a
particular odor.

8. How can one kind of cell enable us to
discriminate among so many different
odors?
 Humans can discriminate between hundreds, perhaps thousands, of
different odorant molecules, each with its own structure.
 The mammalian genome contains a family of about 1000 related
but separate genes encoding different odor receptors.
 The olfactory epithelium of rats expresses several hundred genes
not expressed in other tissues.
 Each gene encodes a transmembrane protein that resembles —
but is not identical to — the others.
 Each protein contains 7 regions of hydrophobic alpha helix that
allow the molecule to pass back and forth 7 times through the
plasma membrane.

9.  However, many odorant molecules are hydrophobic and could
easily enter the lipid bilayer and bind to the receptor there. This
possibility is supported by the finding that much of the sequence
variability from one receptor to another is found in the alpha
helices.
 Each olfactory neuron expresses only a single type of
receptor.
Some evidence:
 Gene probes for a single type of receptor bind to only 1 in a
1000 sensory neurons in a normal olfactory epithelium.
 However, rats made to express a single type of receptor in large
numbers of their olfactory neurons responded much more
vigorously to a single type of odorant than to any of the other 73
tested.
 Cells taken from these rats and placed in tissue culture also
responded to only that one type of odorant molecule.

10. The Mechanism:
 Olfactory transduction occurs when odorant molecules reach the
olfactory mucosa and bind to the olfactory receptor proteins on the cilia
of the olfactory receptor neurons.
 When odorants bind to the receptor site, the receptor protein changes
shape which in turn triggers the flow of ions across the receptor-cell
membrane and an electrical response is triggered in the cilium.
 Electrical responses in the cilia spread to the rest of the receptor cell,
and from there are passed onto the olfactory bulb of the brain in the
olfactory nerve.
 A total of about 10 million receptor neurons are present. Each receptor
neuron has about 1,000 similar receptor proteins. Because there are
1,000 different receptor proteins, there are also 1,000 different receptor
neurons.
 Inputs from similar receptor neurons go to similar glomeruli.
 1,000 different types of receptor neurons, there are 1,000 different types
of glomeruli.

11.  From the olfactory bulb, mitral cells and tufted cells carry olfactory
information to the olfactory cortex, and to the orbitofrontal cortex.
 Now we have a mechanism for discriminating among a thousand or
so odorants. However,
Each receptor is probably capable of binding to several different
odorants — some more tightly than others.
 Each odorant is capable of binding to several different receptors.

12. This provides the basis for combinatorial diversity. It would work
like this:
 Assume that:
 Odorant A binds to receptors on neurons #3, #427, and #886.
 Odorant B binds to receptors on neurons #2, #427, and #743.
 The brain then would interpret the two different patterns of impulses
as separate odors.
So now we have a mechanism capable of discriminating among
millions of different odorants.

13. The Neural Code for Smell
 because odorants are such complicated stimuli, we don't yet
have a complete picture of how smell is encoded by
the brain
 different areas of the mucosa are sensitive to different types of
odorants
 smells appear to be organized spatially in the olfactory bulb
(similar smells are grouped together)
 an odotope is a group of odorants that share some chemical feature
and cause similar patters of neural firing. Neurons that fire to the
same odotope are usually located near each other

14. Experience of Smell
 Humans can tell the difference between 10,000 different odors.
But often it is difficult to name the odors.
 People who are trained to recognize odors (wine experts or
perfume experts) are not necessarily any more sensitive with
their nose - just better at retrieving names of smells from
memory.
 Dogs can be 10,000 times more sensitive to odors than humans.
Yet, a individual human olfactory receptor is no less sensitive
than a dog's.
 What makes dogs so sensitive? Although their receptors aren't
any better, they have many many more of them (1 billion
receptors in dogs compared to only 10 million in humans).
 Pleasant smells (like fresh-baked bread or coffee) are used in
supermarkets to encourage customers.

15. THANK YOU