Immunology Lecture Notes PDF

Summary

These lecture notes cover the introduction to immunology, along with a brief history of Nobel Prizes related to the subject. The notes detail early experimentations of immunizations and introduce the concept of immunity. They briefly discuss the complexity of biological systems and the mechanisms of regulation within the body.

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Fregnan Giada/Conte Laura - Lesson 1 - IMMUNOLOGY (Prof. Paola Cappello) - 05/10/2021 cart.cn

INTRODUCTION TO THE IMMUNE RESPONSE
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The immune system is like the tip of the complexity of the biological systems, for the mechanisms
that regulate our body and health conditions.
Through the study of the molecular and genetic functioning of the immune system, there have been
good ideas to study and demonstrate similar mechanisms for other biological functions in our body.
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In the following table is reported the list of the Nobel Prizes won by people studying particular matters
riguardanti
regarding the immune response.

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 Fregnan Giada/Conte Laura - Lesson 1 - IMMUNOLOGY (Prof. Paola Cappello) - 05/10/2021

At the beginning of the 1900, Emil von Behring won the Nobel Prize because he was able to isolate
what was called an “anti-toxin”, which means actually “antibody against a toxin”. These antitoxins
were used to fight Diphtheria, a disease due to some toxins released by bacteria.
Then, someone discovered the complement system, someone the blood groups and someone else
the mechanisms underlying tolerance, that means that our immune system, in some way, is

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educated to recognise our molecules (proteins, lipids) as self and consequently not dangerous in
order to switch off its function against them.

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Three years ago, James Allison and Tasuku Honjo won the Nobel Prize for discovering some
negative regulator molecules in the immune system, that gave the idea to use them as targets in
fighting cancer. They developed antibodies against these molecules, that are actually used in clinical
practice for fighting lung cancer, melanoma, breast cancer. Every day the FDA (Food and Drug
Administration Federal Agency) is approving these antibodies for many types of cancer.

HISTORY OF IMMUNOLOGY
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The term “immunity” comes from a Latin word, immunitas, that means “to be exempt from”. In the

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XVI century it was already known this first concept of immunity: several writers in the past proved in
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their books that during a plague incontro
people who survived to the first encounter with the disease were
able also to survive, or at least not to become ill, at the second encounter with the same pathogen.
However, our system is preserving health conditions against both external intruders and some

I 0
internal molecules, called antigens, that are released or become available and they can contact our
system after, for example, some pathological conditions, when cells are dying or are deeply
damaged.
In 1796, an English physician called Edward Jenner was laying the foundations for the birth of the

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real immunology. He did a very important experiment, the first control experiment of immunization.
At that time the smallpox was a very dismal illness, that affected not just people but also livestock,restare
such as cows. Jenner realised that smallpox in cows presented weakened symptoms compared to
human beings. For this reason, he tried to inject the material taken from an infected cow in an 8-

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year-old boy and then, after two months, he injected the same boy with the material obtained from
the human disease. As a result, the kid did not get sick: he got immunized. In this way, without
knowing any molecular basis of the pathology, Jenner demonstrated that our immune system is able
to react and to remember. For this reason, this experiment is considered the birth of immunology.
In 1884, Robert Koch suggested the theory of microbes. He stated that germs, invisible to naked
eye, were the real responsible for our diseases. This turned to be partially true, because nowadays
we also know the importance of genetic predisposition to some diseases and DNA mutations.

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Around the same years, in 1880, Pasteur was using bacteria, weakened in lab, to immunize animals
against a viral infection, so he called this approach “vaccine” coining this word to honour Jenner
(vaccinus means “derived from cows” in Latin).

WHY DO WE NEED THE IMMUNE SYSTEM TO MAINTAIN THE HOMEOSTASIS AND THE
HEALTHY CONDITIONS?
We have many microbes around us. Indeed, humans can offer them great conditions, such as a
stable temperature (37 degrees), unlimited energy and nutrients production, a way to spread in the
body (through the blood circulation) and, since humans are so numerous, microbes have many
places to colonize, even if someone gets sick and dies.

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 Fregnan Giada/Conte Laura - Lesson 1 - IMMUNOLOGY (Prof. Paola Cappello) - 05/10/2021

HOW DO MICROBES COLONIZE HUMANS?
They had to invent different strategies to colonize and
enter our body. Bacteria generated distinct types of
relationships: many of them are beneficial for us (for
example in our mucosa or in our skin), whereas some
of them are pathogenic. These last ones can be
distinguished in extracellular and intracellular
pathogens, based on the modality of proliferation.
The extracellular pathogens are able to proliferate
even in our body fluids, in an extracellular
environment. They eventually can enter, after
proliferation, in the blood system and spread around in
different districts and organs. These are mainly
bacteria, fungi or big parasites, like worms. O
The intracellular pathogens need to enter in our cells
to proliferate and they are not able to stay long or
survive outside our cells. This is typical of viruses, but
also of some bacteria and parasites.
heenza
The process of attachment and entrance into the cells replica.pro

is called infection (usually this term is used with a
general meaning). After infecting our cells, these
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viruses or bacteria can proliferate a lot and eventually
kill these cells to spread in the neighbouring ones.
Moreover, if they infect cells, such as blood cells, or L infettaes
extravasate in the blood, even these intracellular IMMUNEN

pathogens can diffuse in our body.

HOW CAN THEY DAMAGE OUR CELLS?
Some bacteria can produce and secrete some poisonous molecules called exotoxins. Some
examples of these toxins are the ones causing Diphtheria, Tetanus, Cholera, Yellow Fever, Scarlett
Fever. What is poisonous for us is not the bacteria itself, but the toxin it secrets. They can circulate
in our fluids or in our blood.
On the other hand, some other bacteria can contain, on the surface or inside the cell, some poisoning
molecules called endotoxins. For instance, this is what triggers Sepsis (a general inflammatory
disease that affects many organs), Meningitis, Pneumonia, Viral or Bacterial Dysentery.
Viruses (and some bacteria) are able to kill the cells they enter. They infect a cell, start to proliferate
and produce more and more virions: because of their number, they wouldn’t be able to survive inside
the cell, that’s why they kill it and infect other ones.
The last way by which microbes can damage our cells is by activating a strong and deregulated
immune response. Sometimes they activate the immune system too much, so the normal immune
response actually progresses to a chronic inflammation (a condition where the immune system is
always active and fighting, even when the bacteria and the viruses are no longer present, being
effective also against our cells). In other cases, they can induce some reactions against our cell
c
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molecules, causing an autoimmune reaction. Finally, they can be very dangerous for
immunodeficient people, who do not have a complete functioning immune system able to fight the
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pathogens. In this case, even not so harmful bacteria can become very dangerous.
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Fregnan Giada/Conte Laura - Lesson 1 - IMMUNOLOGY (Prof. Paola Cappello) - 05/10/2021

This continuous pressure from microbes (in the air, in the water, almost everywhere) on our immune
system has forced the mammalian to develop some smart approaches and strategies to defend our
body.
It seems a “horse race” between the pathogens
and the immune system: the pathogen develops a
strategy to enter our cells and the immune system
has to develop something that has to block this
new strategy. So, there isn’t always a “winner”, but
città
Enge there’s a sort of co-evolution. When the pathogen
develops a new strategy, then the immune system
can adapt and, in some way, escape from this
strategy. The same happens for the viruses: they
Ieuro giornibianchi
evolve trying to better infect our cells, because, as
said before, we are a good environment to survive
and proliferate in.
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TWO TYPES OF IMMUNE RESPONSE
II 3
Until this century, there were two schools of thought:
- The first one believed that the immune response against pathogens was preferentially cell-
mediated. This meant that there were cells (they’re not always known) that were able to fight
the infection
- The other school thought that healthy conditions were maintained thanks to some soluble
factors, referred as humoral immunity (humor in Latin means “fluid”).
Nowadays we know that both responses co-exist and both are involved in any kind of fight against
pathogens. We have cells called Leukocytes (White Blood Cells), that are abundant in the blood
(through which they can reach any of our tissues), but they are mostly present in tissues and in
lymphoid organs, such as tonsils, spleen and thymus: organs made of lymphoid tissue, associated
with the mucosa (the epithelial layer that covers gastrointestinal, respiratory and urogenital systems).
On the contrary, the soluble factors, referred as humoral immunity, are mainly the antibodies. These
molecules are present in the blood and other fluids and are a sort of defence against the intruders,
even if they are not the only ones.
The cell-mediated immunity and the humoral immunity are cross-talking, thanks to other soluble
factors called cytokines. The antibodies, for example, are produced by a peculiar subpopulation of
leukocytes and they are secreted when these leukocytes are activated. This activation is mainly due
to a specific recognition, but even because of the presence of specific cytokines that alert these
leukocytes and stimulate them to get involved in the fight producing antibodies.

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Leukocytes
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The table summarizes the main features of the t.im
two categories of the immune cells:
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- the ones that are involved in the innate
immune response
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- the ones that are responsible for the
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adaptive immune response.

INNATE IMMUNE RESPONSE
Once an external pathogen has entered our body (passing through the skin), there are several
methods to activate the immune response.
The innate cells, also called native cells, since they’re present in every organism and they’re
phylogenetically very old (some of them are even present in the fungal kingdom or in invertebrate
organisms). They recognise that there’s something to fight in a very unspecific and wide way. They
can recognise when our cells are damaged by a bacterium, a virus or any other injurious stimulus
(e.g. metabolic reasons) and are dying because the plasma membrane gets broken and leaks out
its content; these released molecules, called Damage Associated Molecular Patterns (DAMPs), that
are usually inside the cell, can be recognised by the innate cells. So, with the term DAMPs we
consider all the molecules deriving from a damaged cell. Moreover, these innate cells can also
recognise Pathogen Associated Molecular Patterns (PAMPs), that are unspecific molecules present
on the surface of bacteria, virions or infected cells (after the infection).
The native cells can activate themselves after the recognition of PAMPs and DAMPs thanks to the
Pattern Recognition Molecules (PRMs), which can be soluble (when they attach the DAMPs or
PAMPs, they need to be recognised by the innate cells thanks to specific receptors to activate the
immune response). However, most of them are expressed by the innate leukocytes, on their surface
or inside them (in the endosome or in the cytoplasm) and they can recognise different common
molecules belonging to bacteria and viruses.
Since the innate cells are very abundant not only in the blood but especially in the skin and mucosae
(they can actually be residential in all our tissues) and since they’re so numerous compared to the
adaptive cells, they always respond with the same intensity: when they recognise, through the PRMs,
the DAMPs or the PAMPs, they immediately and furiously become effectors and get involved in the
fight against the pathogens. Their response is always similar, every time they encounter the same
pathogen. For this reason, the innate immune response has no memory of the encountered
pathogens. This is a peculiar feature of this system, while the opposite happens in the adaptive
immune response.
The innate response involves different categories of cells, tissues, molecules and processes.
PROTECTION FROM THE ENVIRONMENT
The first real barrier, that can be considered as an innate immunity, are the anatomical barriers: the
skin and the mucosae. They are protected by some leukocytes and they’re able, due to their intrinsic
features, to resist the invasion. There are also physiological barriers, such as low pH in our stomach
or intestine, or the secretion of lysosomal or hydrolytic enzymes in the saliva and body fluids.

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The complement system is a circulating set of proteins (proteases) which is inactive in healthy
conditions, but it can be activated to directly kill the pathogen by forming a pore into the surface
membrane of the bacteria/virions/infected cells. The complement may be considered as a part of the
innate response because it is always present and, after its activation, the cascade it starts will lead
to the killing of the pathogen.
Other players of the innate response are the PRMs, receptors expressed on the leukocytes or
soluble proteins, like the pentraxin or the C-reactive protein (its value gets high when an inflammation
occurs; it is able to bind some molecules on the surface of bacteria, so it can be considered a PRM
that will bind some receptors expressed on the leukocytes and activate them).
Three processes are important for the innate response:
- Inflammation: it involves the blood vessels. The swelling and the redness are two typical
signs of inflammation, because the blood vessels increase their calibre around the infectious
area. It’s important to make the leukocytes extravasate and getting outside in order to fight
the intruder that has invaded the cells. The inflammatory response is mainly activated by the
secretion of inflammatory cytokines, that can be secreted not only by innate cells but even
by endothelial or epithelial cells that are encountering the pathogen.
- Phagocytosis: the leukocytes that arrive in the infectious area are mainly able to phagocytise
and directly kill the pathogens or the infected cells. It is mainly performed by these kinds of
innate cells: neutrophils, macrophages or dendritic cells. Neutrophils are the Spazzini scavenger
cells, so their function is usually to clear the area from pathogens or damaged/dying cells.
The macrophages and dendritic cells, instead, beside phagocytise molecules and material,
can also present some pieces of these materials to the adaptive cells, in particular to the T-
lymphocytes. So, in some way, the macrophages and dendritic cells are the bridge between
the innate response and the adaptive response.
- Target cell lysis: innate cells that are able to directly lyse the target (pathogen or infected cell)

0
are again neutrophils, macrophages and natural killer cells (NK)
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ADAPTIVE IMMUNE RESPONSE
As well as the innate cells, the adaptive cells need to recognise the pathogens to get involved in the
fighting. However, there are many important differences between these two types of cells: the
adaptive cells specifically recognise some unique sequences/molecules on the pathogens, the so-
called antigens (this term means “generator of antibodies”, because it was first defined as a
molecule able to induce the antibodies and, therefore, the humoral response). So, the adaptive
immune cells are able to specifically recognise antigens thanks to a very peculiar receptor called
“antigen receptor”, in particular TCR (T cell receptor, when it’s expressed on T lymphocytes), or
BCR (B cell receptor, when it’s expressed on B lymphocytes). The adaptive cells are called
lymphocytes because they are mostly abundant in the lymphoid organs. There are two big
categories of lymphocytes: B and T.
Since each lymphocyte has only one type of receptor (present in thousands of copies) that can
recognise just one specific kind of antigen, and since there are uncountable antigens, there are
billions of lymphocytes, each one having a different receptor. This means that when a pathogen
enters a cell, if there’s only one lymphocyte able to recognise it, this lymphocyte will need some time
for the recognition and it has to replicate in order to create a real “army” against the pathogen. For
this reason, the response will be for sure delayed.
As said before, the innate response is immediate because of the unspecific recognition and because
there are a lot of leukocytes that are able to fight any kind of pathogen. In contrast, the lymphocytes
need to proliferate and so their response will come later. Moreover, during this proliferation most of
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them will become effectors, “soldiers” against the pathogen, but some of them will become long-live
cells that can remember what they have encountered the first time and so the second time they will
meet the same pathogen they will immediately proliferate to fight it. Therefore, the adaptive immune
response has memory of the encountered pathogens. This kind of strategy only occurs in
vertebrates, and it is more complex in mammalians such as humans.

GENERAL FEATURES OF THE ADAPTIVE IMMUNE CELLS
The adaptive cells are mainly divided into two populations: B lymphocytes and T lymphocytes and
each cell has a very specific receptor.
Lymphocytes are characterized by five important features:
1. Specificity (related to the receptors): it is warranted by the T cell receptors (TCR) and B cell
receptors (BCR). As it can be observed in the image, pathogens 1, 2 and 3 express very
common molecules on their surfaces, that can be recognised by PRMs or the receptors
expressed by the innate leukocytes. Nevertheless, each of them has also some peculiar
molecules: for example, pathogen 1 has specific molecules that are not present in pathogen
2 or 3. Each unique structure on the surface of a pathogen can be recognised by a specific
adaptive immune cell presenting a specific receptor.

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2. Task division: every cell has its specific job.
The B cells produce the antibodies, that are responsible for
engaging other leukocytes to allow the clearance of the
pathogens.

The T cells, instead, can be divided into two subpopulations: cytotoxic T cells and helper
T cells. The latter produces cytokines (soluble factors that allow the communication among
all the leukocytes). On the contrary, the cytotoxic T cells can directly kill the pathogens or the
infected cells.
A big difference among the B cells and
T cells is how they recognise the
pathogen: they both have receptors
(BCR or TCR), but the BCR is able to
recognise the native circulating
pathogens present in our fluids (through
a molecule on the pathogen’s surface or
a soluble toxin). T cells instead need to
recognise the specific molecule
presented by another molecule
expressed by our cells: the Major
Histocompatibility Complex
molecule (MHC).
In this example, on the left, there’s a cell
infected by a virus. Once the virus
enters the cell, the viral proteins are
uploaded on the MHC which can be
recognised by the TCR. The recognition
of the antigen wouldn’t have been
possible without the MHC. This is why
macrophages and dendritic cells, that
phagocytise the pathogen and then
digest it, will present the molecules of
the pathogen to the T cells. This
process is called antigen presentation.

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3. Memory: it is due to the differentiation of some lymphocytes (involved in the fighting) in
memory cells. This process is common in both B and T cells (the scheme down below is
referred to the B cells).

As it can be seen, a B cell recognises and binds, through its BCR, an antigen (toxin or
molecule on the surface of a pathogen). After that, the lymphocyte becomes active and
proliferates, producing identical (billions of) clones to get involved in the fighting. Since they’re
B cells, some will differentiate in plasma cells that will produce antibodies*, and some will
differentiate in memory cells, long-live B lymphocytes, that will be able to immediately
recognise a second/third encounter with the same pathogen and so will be instantaneously
engaged in this kind of proliferation to go against the pathogen.

*antibodies are the soluble form of the BCR that was present on the original B cell.

4. Diversity

5. Tolerance: since the lymphocytes, in a specific way, generate all these different receptors, it
is possible that some of these receptors can also be directed to some of our proteins,
because they are able to recognise uncountable antigens (indeed, in vitro, if you take blood
cells and add many different antigens, even the synthetic ones, leukocytes are able to
activate themselves). So, even if this is an advantage because we are certain to be protected
against every pathogen, it is necessary to be sure that some of these receptors are not
actually directed against our self-molecules: this is what happens during the maturation. In
this process, that takes place inside the lymphoid organs, both B and T cells are tested
against the self-molecules and if they have the wrong receptor (because they recognise the
self-molecules), they will die. This is what is called central tolerance.

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If some of these “wrong lymphocytes” manage to escape from this strict regulation and get
outside from the central lymphoid organs, reaching the peripheral areas, there’s another
mechanism that can warrant the peripheral tolerance. This is what actually maintains our
homeostasis and health conditions, even having such dangerous structures patrolling our
body.

In conclusion, the innate and the adaptive responses are overlapping in the fighting against a
pathogen. There are three different phases that are inter-connected:
The first phase occurs
when body barriers
(sentinels), once they’re
attacked by some external
pathogens, immediately
O
secrete alarm signals.

F These signals led to the
second phase, engaging
the innate cells and all the
cells of the innate immunity
that secrete other cytokines
and chemokines to
communicate each other
and with the barriers. Then,
the complement activation
takes place and the
activated innate cells can
start to phagocyte (or lyse) and kill the pathogen. All these processes happen rapidly, from hours to
few days (4-96 h).
Later, during the third phase, the delayed response by the adaptive cells occurs, because T and B
cells need the antigen presentation to recognise the antigen. Moreover, they need guiding
inflammation in order to extravasate and reach the site where the fight is happening. Once there, the
cytotoxic T cells can directly kill the pathogen or the antibodies can be produced. However, the
intervention of adaptive cells starts after at least 5 days, because they need to proliferate. Every
phase is smartly regulated: even the B and T cells secrete cytokines that help the long-lasting
activation of some innate cells.
From a clinical point of view, the immune
system is responsible for the clearance of
damaged/infected/dead cells, but it can also
recognise and disrupt cancer cells. On the
other hand, however, the immune system
can be the cause of some pathological
condition, such as immunodeficiency or
during transplantations (the immune system
is responsible for the rejection of a
transplanted organ); during hypersensitivity
or allergic reactions, when our system
respond in an exasperated way against
innocent invaders (like food) instead of pathogens; it can induce chronic inflammation and be harmful
against our cells; it can react against our cells and be responsible for the autoreactive reactions.

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INNATE IMMUNITY.
The first line of defence is represented by the anatomical barriers: the skin (2 m2 ) and the mucosae
in the respiratory system (60 m2 ), the gastrointestinal system (30 m2 ), urogenital system…

All the anatomical barriers are characterized by:

- Resistance to many kinds of traumas
- Elasticity, which allows contraction without provoking any kind of damage
- Impermeable
- Self-renewing (all the cells of the skin and mucosa proliferate a lot every day) and self-
repairing in case of damage
- Ability of responding to mechanical stress
- Ability of reacting to UV radiation, which is one of the most injurious stimuli for our skin (hence
our skin is also made up by melatonin-producing cells that counter radiation)
- Difficulty to being overcome by microbes
- mentsin our body thermo-regulation
Involvement
- Intrinsic anti-bacterial activity
The anti-bacterial activity is provided by the so-called chemical barriers, which are represented by
soluble factors secreted by the epithelial cells belonging to the anatomical barriers (and not only).
These are very small peptides with anti-microbial activity (defensin, cathelicidin, histatin and
pentraxin), but also those molecules that connect and interconnect all the immune cells (cytokines
and chemokines). When an atomical barrier is damaged by mechanical stress, metabolic stimulus
or attacked by pathogens, it secrets alarmines, which are self-component of our cells such as
HMGB1 (which is a protein binding the DNA), or the S100 protein (which is very abundant in the
lungs and the respiratory tract).

Peptides β-defensin family Disrupt microbial membranes;
attract dendritic cells
Cathelicidin family Disrupt microbial membranes
Histatin family Disrupt microbial membranes
Pentraxin family Activate phagocytosis and
microbial disruption
Cytokines Interleukin 1 (IL1) Triggers immune response
Interleukin 6 (IL6) Triggers immune response
Interleukin 10 (IL10) Dampens immune response
Interleukin 25 (IL25) Trigger immune response and
Interleukin 33 (IL33) favour Th2 cell activation
Chemokines CXC family Attract and activate immune
cells
CC family Attract and activate immune
cells
CX 3 C family Attract and activate immune
cells
Alarmins Uric acid Trigger immune response and
favour Th2 cell activation
High mobility group box1
(HMGB1)
S100 protein
All these soluble factors also give the anatomical barriers the ability to eventually immediately kill the
pathogen.

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THE SKIN.

The skin is the most external layer of our body, which underlines the importance of the presence of
a very thick stratum corneum, because it inhibits the attachment and/or penetration of any bacteria
or viruses. Indeed, this layer is the first physical barrier. Underneath the stratum corneum there is
the dermis, which contains sebaceous glands, stromal cells (fibroblasts), myofibroblastic cells and
sweat glands. The latter are very important because the sweat (as, in general, all the other body-
fluids) contains many chemical substances that are able to kill the pathogens.
About the immune cells (which are indicated in red in the previous image), they are more present in
the tissue rather than in the blood. The most abundant immune cells in our skin are:
- Langerhans cells (belonging to the dendritic cells family, which is one of the most common
one and is characterized by long dendrites)
- melanocytes (which protect our skin from radiations)
- macrophages
- neutrophils
- mast cells
Lymphocytes, even though they interact later with the pathogen (because they belong to the
adaptive immunity), can also circulate in our skin.

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The thick corneal stratum is also
necessary to protect us from mosquitoes’
bite. The female of Anopheles, for
instance, is able to introduce the
protozoans and, by doing so, they can

o
transmit Malaria. Unfortunately, this kind
of barriers isn’t always efficient because
the mosquitoes’ proboscis is so huge and
potent that it can invade the skin and
even reach the capillaries and vessels.

i

resurster
THE MUCOSA OF THE LIPS AND MOUTH.

Confronting the skin and the mucosa, the latter has a much thinner corneum layer because it doesn’t
have the same importance in those two structures. Inside the mucosa there are other structures that
are more important than the corneum layer, such as the serous mucus glands (or salivary glands,
it depends on the mucosa taken into account) because they contain the chemical substances that
are able to kill the pathogens.

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About the immune cells (indicated in red), there are:
- the Langerhans cells
- a lot of lymphocytes, however they’re not the ones belonging to the adaptive immunity
(they’re called innate lymphocytes).

Soluble factors produced by the mucosae.
Lysozyme.
The salivary glands are great producers of lysozyme (also known as muraminidase), discovered by
Sir Alexander Fleming in 1922. This enzyme is able to break the peptidoglycan component of the
cell wall of many bacteria, especially Gram-positive bacteria, by hydrolysing the 1-4 glycosidic bond
connecting N-acetilmuramic acid and N-acetylglucosamine. Saliva is the main fluid containing the
lysozyme, however it is also produced by the Paneth cells (epithelial cells present in the
gastrointestinal tract) or contained inside the granules of granulocytes and monocytes (belonging to
the adaptive immunity). Finally, lysozyme is also present in some epithelial tissues, tears and milk,
and it’s very important during breastfeeding.
Cathelicidine.
These are small peptides, defined as anti-microbial because they can kill the bacteria by destroying
their lipoprotein membrane even when the pathogen has been enveloped in phagosomes. In this
respect, it’s important to remember what the phagocytosis process is: the external bacteria are
ingulfed by the plasmatic membrane, creating a phagosome, which can fuse with the lysosome. This
process provokes the destruction of the bacteria’s membrane, and so their death.

Cathelicidine must be efficient without harming our cells, that’s why they’re produced as a precursor
(18 kDa), which is then cleaved into two active molecules only when they’re requested inside the
cells. Both the synthesis and the cleavage are stimulated by the production of cytokines, that are
released once the epithelial (or, in this case, mucosal) cells register a damage. Cytokines can alarm
the neutrophiles or the other epithelial (or mucosal) cells to cleave and activate the cathelicidine.

THE BRONCHIAL MUCOSA.

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There’s no corneal layer, which is replaced by the mucus, produced by the serous mucus glands.
The cilia on the columnar cells trap microbes in the airways. However, sometimes this mechanism
isn’t enough, that’s why the mucus is so important: this active barrier traps the microbes and allows
the residential innate cells to phagocyte them or kill them. The mucus contains some of the
cathelicidins, lysozyme and other anti-microbial molecules.

About the immune cells, the bronchial mucosa contains:
- dendritic cells
- innate lymphocytes
- a lot of mast cells, which are the most abundant residential innate cells in the circulation, as
well as the neutrophils, and they have a lot of granules containing anti-microbial substances.

THE DIGESTIVE TRACT MUCOSA.

The digestive tract doesn’t have ciliated cells; however, it is provided with Goblet cells, which
produce the mucus (even though the production of mucus is minor than the one in the bronchial
mucosa) and Paneth cells, which produce cathelicidins and so on. This structure is characterized
by some invaginations, in order to increase the surface of absorption.
Because of the presence of the microbiome (which may also be beneficial for the organism) in the
intestine, this kind of mucosa is enriched by lymphoid tissue know as Mucosa-associated lymphoid
tissue (MALT). There are also:
- Macrophages
- plasma cells (which are differentiated B-cells)
- some B-cells
- lymphocytes in the MALT

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Paneth cells are involved in the production of DEFENSINS, small peptides (29-34 aa) belonging to
two main families (α-defensins and β-defensins) that differ in the disulfide bonds. They’re able to
directly lyse any kind of pathogen (fungi, bacteria, viruses), because they interfere with the
molecules of the bacteria wall or the proteins outside of the viruses.
Defensins are produced not only by Paneth cells, but also by neutrophils (also known as PMN,
polymorphonuclear cells, which is an acronym used for all the granulocytes), NK cells and they’re
also contained inside the granules of the CTL (cytotoxic T-cells). Because of their anti-microbial
activity, defensins are also important to regulate the balance of the intestinal microbiome in order
to maintain the homeostasis: the excess of the bacterial presence may damage the mucosal or
epithelial cells.

THE RECTAL MUCOSA.

Because this type of mucosa is very close to the external environment, it has a very thin corneal
stratum. Mechanically, physically and chemically speaking, this barrier should protect our inner body.
It is characterized by:
- lymphoid tissue
- dendritic cells (Langerhans cells)

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GENITAL EPITHELIUM.

Comparing these two structures it is evident how the penis is characterized by a corneal layer,
whereas the vagina is provided with a mucous layer. In both cases, the epithelium is enriched by
residential innate cells (Langerhans cells, macrophages) and less lymphocytes than the other types
of mucosae.

This drawing resumes all the biological and
chemical barriers that cover the outside and
the inside of our body. An important
component of this barrier is represented by
the microbiome (human microbiome is
made up by about 4,5 kg of bacteria). It is
composed by more than 3000 species of
bacteria.
The balance between the bacteria and the
human cells is about 10:1. This homeostatic
state must be maintained in order to
activate the innate and adaptive cells in a
proper way, without provoking an
inflammatory reaction (this concept will be
further explored in the next lessons).

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PENTRAXIN (PRM).
Pentraxin family is made up by multimeric proteins (200 aa) made up by five monomers bound
together. They are able to bind some molecules on
the surface of the pathogens and, because of that,
they have been defined as the “ancestral
antibodies”. Thanks to this bond, these proteins
activate the innate response (for example, they
activate the complement cascade or the
phagocytosis).
This big family is divided into two sub-families:
- short-chain, for example the C-reactive protein
(whose haematic concentration rapidly increases
during an infection or inflammation process), or the
serum amyloid (SAP, an abundant anti-microbial in
the airways)
- long-chain, for example the PTX3
Both the long and short chain pentraxins are produced not only by innate cells (monocytes, dendritic
cells, macrophages), but also by the epithelial or endothelial cells.
They’re considered as a class of PRR (Pattern Recognition Receptors), however they’re PRM
(Pattern Recognition Molecules) because they’re not anchored on the cellular membrane, but they’re
secreted. Once they’ve bound the pathogen, the pentraxins activate the innate cells thanks to
specific receptors.

What happens when a barrier is broken?

Once the bacteria reach the lesion and start to invade the organism, the epithelial cells release
alarmines or cytokines and eventually even the blood coagulation cascade occurs because some
capillaries may be broken too. All these events belong to the so-called humoral response (because
there is the secretion of soluble molecules) and they activate the residential innate cells which may
control the invasion by releasing other factors allowing the healing of the damage, even before
recruiting other cells from the blood circulation.

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THE INNATE CELLS.
The innate cells are the most abundant in the tissues as well as in the blood, and so they are the
first ones to respond to a tissue damage. Their response is characteristically quick and potent.
These cells are: mastocytes, neutrophils (granulocytes in general) and the innate lymphocytes (ILC,
innate lymphoid cells).
The innate cells, together with
the epithelial cells, secrete the
alarming signals, which affect
the endothelial cells of every
capillary and vessel nearby.
This kind of factors (for
instance, histamine which is
released by mastocytes, or the
serotonin) affect the
permeability of the vessels:
the endothelial cells, as a
matter of fact, aren’t tightly
adherent one to another, but
they’re separated by some
gaps.
These gaps allow the exit of
fluids, which induces the
“stasis and rolling” allowing all the immune cells (neutrophils, monocytes, lymphocytes,
eosinophils…) circulating in the blood, to adhere to the vessel’s wall once they’re pushed against it
by the red blood cells. After adhering to the wall, these cells start to extravasate.

The picture illustrates the transversal
section of a vessel, showing the
presence of an endothelial cell, a red
blood cell. Once the alarmins are
released, some gaps appear between the
endothelial cells allowing the
extravasation of the innate cells. The
latter, of course, have to activate different
pathways in order to allow this process.

The extravasating cells are mostly
represented by the polymorphonuclear
cells and that’s not by chance: their
polylobate nucleus allows them to
squeeze the nucleus itself inside the gap.

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After the extravasation, a lot of
innate cells are recruited in the
site of damage or infection; they
try to kill all the bacteria and,
after 2 days, most of them die
provoking swelling and, in some
cases, pus (which is made up
by bacteria and neutrophils) is
released.
The extravasating cells reach
the site of infection thanks to
other inflammatory mediators,
like the cytokines and the
chemokines. These are
released creating a gradient:
the most abundant mediators
are located close to the damage
cells, whereas they’re less
present nearby the vessels.
Thanks to this gradient, these
mediators are able to recruit the requested cells (chemoattraction).

The potency and velocity of the innate response is quite efficient to rapidly kill the bacteria; however,
it’s important to consider that it’s potentially dangerous for our cells, that’s why the inflammatory
response has to end very quickly. The five features associated to an inflammatory response are:
- Rubor, which defines the damaged area
- Calor, because of the increased blood flow (which is warm)
- Tumor, which indicates the swelling
- Dolor, because some of the mediators act on neuronal cells
- Fuctio lesa, when the inflammatory response is quite intense and long-lasting, and it means
that there’s a loss of function for some cells in the tissue

The table on the left indicates the average
percentage of the immune cells: basophils,
neutrophils, eosinophils (generally called
granulocytes, or PMN) and monocytes
belong to the innate immunity, whereas the
lymphocytes belong to the adaptive
immunity. It’s evident how the most
abundant are the neutrophils and then
eventually the lymphocytes. All the other
ones are less abundant, however they can
proliferate and become abundant when
they’re needed.

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BASOPHILS AND MAST CELLS.
Basophils and mast cells (or mastocytes)
share some features:
- they both contain a lot of granules
(even though the mastocytes
present a much higher number of
these granules)
- the granules in both basophils and
mast cells may be histologically
studied by using the same stains
(basic solutions)
It’s important to remember that the mast
cells (which are mainly residential cells)
are almost twice the basophils and they’re
weaker. The mast cells are also
characterized by very small invaginations
of the membrane.

Mediators released by basophils and mast cells.
These cells release:
- Pre-formed mediators present within cytoplasmatic granules: for example, the histamine and
serotonin (which are able to increase the vessels’ permeability), some proteases (such as
the tryptase and the chymase, which breaks the bacterial wall), or the TNF-α (Tumor necrosis
factor-α) which is a cytokine that activates other innate cells. All these mediators are present
in the cell even when it isn’t active, but they’re ready to be immediately used after they
recognize some alarms coming from the mucosa or epithelium

- Mediators synthetized after degranulation: thromboxane, prostaglandins, leukotrienes, PAF
(Platelet Activating Factor), Eosinophil chemotactic factor. All these factors derive from a
leaking content that is usually contained in the plasmatic membrane. They’re ready to be
released after few hours because it’s only necessary the activation of some enzymes which
allow to release this content from the membrane and to turn it into these mediators. These
mediators also affect the blood vessels, but also other innate cells (acting like the cytokines)

- Mediators synthetized hours after activation: cytokines and chemokines, that recruit the
proper cells needed to fight against the pathogen. They’re called “later mediators”, because
they need the transcription of new genes

Effect of the mediators released by basophils and mast cells:
- Activation of endothelial cells
- Increase of vascular permeability
- Anticoagulant activity
- Attraction of neutrophils, eosinophils and monocytes (innate cells)
- Increased bone marrow production of neutrophils, eosinophils and monocytes. In addition to
that, basophils and eosinophils aren’t abundant in the circulation, that why the bone marrow
production must be increased when these cells are required
- Smooth muscle contraction
- Bronchoconstriction and increase of mucus secretion, to capture and block the pathogens
- Creation of a toxic environment for microbes and parasites
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BALZABU
6
saltare
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Laura Conte / Lucia Griva – Lezione 2 – Immunology (Prof. Paola Cappello) – 07/10/2021

NEUTROPHILS.

Neutrophils are similar to basophils,
and they’re characterized by a
polylobate nucleus.
Their name refers to one of the
properties of their granules: they’re
histologically stained by neutral
solutions. Neutrophils contain two
main types of granules:
- Primary (or azurophilic)
- Secondary
All these granules contain lysozyme,
defensins, cathepsin, some
enzymes (such as the elastase, the
enzimi
proteinase which are able to break
the bacterial wall), pentraxin, pro-
Defensin (which can be then cleaved into defensin). They also include the NADH oxidase and
myeloperoxidase which are crucial to produce radical oxidative species (ROS) creating a toxic
environment in the autophagosome or even inside the cytoplasm of the neutrophils, in order to kill
the bacteria. These ROS, thanks to the myeloperoxidase, can be associated with the chloride and
create even more toxic radical species that can directly kill the bacteria.

Neutrophils are more able to extravasate (the professor left two links to observe the process of
extravasation: https://www.youtube.com/watch?v=B9Qi7we0Ynk
https://www.sciencephoto.com/media/609709/view).

Functions of the neutrophils.
1. Sentinel activity, because they’re more abundant in the blood so they’re able to monitor
everything that’s happening inside the organism

2. Phagocytosis, which is a process in which the
plasmatic membrane invaginates and envelops
the pathogen thanks to receptors. After the
phagosome is formed, it is fused with all the
granules inside the neutrophil and all the content
inside them start to degrade the pathogen. The
materials obtained from this process will be then
discarded by exocytosis (in this way, each
neutrophil is able to phagocyte a lot of pathogens,
because all the material doesn’t interfere with the
life of the cell).

The rate of the phagocytosis is drastically increased by the C3b, is a component of the
complement belonging to the innate response. It can be immediately activated by the
presence of the bacteria. The C3b opsonises all the surface of the bacteria and the
phagosomes are provided with specific receptors for the C3b.

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(there are two links to observe this process:
https://www.youtube.com/watch?v=7VQU28itVVw ;
https://www.youtube.com/watch?v=a1xPpsxvhVA)

3. Spiderman effect, which is due to the ability of neutrophils to release a net which can trap the
bacteria. This net is made up by DNA, it
directly starts from the nucleus and it can
contain all the enzymes present inside the
neutrophil.
Thanks to this net, the bacteria may be
trapped, however after this effect the
neutrophil dies. After its action, the net is
removed from the area, otherwise it could
lead to the production of antibodies against
these molecules (the innate and adaptive
responses would be induced against self-
components and it can provoke
autoimmune diseases).
(https://www.youtube.com/watch?v=TIFmtnSdolM: link to the video of this process)

4. Kamikaze effect, because after a couple of days outside of the circulation, they die together
with the pathogen (their lifespan inside the circulation, on the other hand, lasts about 5-6
days)

Main effects of the degranulation of the neutrophils.
- Rapidly killing of invading microbes
- Establishment of a toxic environment for microbes, parasites and normal and neoplastic host
cells
- Activation of endothelial cells: increase in the expression of adhesion molecules, WBC (white
blood cells) extravasation
- Chemoattraction of immune cells
- Enhancement of Complex activity (Properdin, which is a component contained inside the
granules and it stabilizes the components of the complement on the wall of the bacteria or
parasites)
- Massive death of neutrophils, dead pathogens and damaged host cells are responsible for
Pus formation (because they are killed together with the pathogen)

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EOSINOPHILS.
They’re also granulocytes, whose granules can by
histologically stained by using acid solutions (they
become red).
Their most important characteristic is that they’re
the only cells having the Major Basic Protein
contained inside their granules. It’s the only
enzyme able to destroy the worms’ wall.
Since they’re not so abundant, when they’re
needed, they have to proliferate rapidly. Their
lifespan outside the circulation is shorter than the
neutrophils’, as a matter of fact they live just for 6-
12 hours, eventually a day.
Activities of the eosinophils:
- Phagocytosis of microbes and small particles
- When they degranulate, the eosinophils destroy the intruders as well damage of invaded
tissue
- Secretion of cytokines, enzymes and anti-microbial proteins and peptides
- Antigen presentation
- Anti-helminthic activity (they’re one of the few cells, if not the only ones, that are able to
destroy the worms’ wall, as already mentioned)
- Anti-tumor activity

MONOCYTES.

They represent 10% of our cells present in
the blood, however they’re most abundant in
the tissue (where they’re called
macrophages).
They are quite big and are characterized by
a V-shaped nucleus.

Their membrane is provided with a lot of
receptors in order to phagocytes/kill the
intruders (they’re also antigen-presenting
cells).

When in the tissues, some macrophages (even though they’re quite similar because they derive from
the same progenitor, which are the monocytes) acquire different names:
- In the epidermis -> Langerhans cells
- In the lungs -> alveolar and interstitial macrophages
- In the central nervous system -> microglia cells
- In the bones -> osteoclasts
- In the lymph organs and site of infection -> mature/immature dendritic cells (so dendritic cells
and macrophages share the same bone precursor)

The tissue macrophages are quite big cells (they can reach even a diameter of 80 μm) because
they’re rich in internal organelles (especially the endoplasmic reticulum, the Golgi apparatus).
They’re also characterized by a long life-span, in fact they’re able to live for months inside the tissue,
then they’re replaced (in some cases they’re also able to proliferate).
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Laura Conte / Lucia Griva – Lezione 2 – Immunology (Prof. Paola Cappello) – 07/10/2021

Activities of the tissue’s macrophages.
- Professional phagocytosis and
subsequent killing of microbes
- Scavenger function: they remove old
red blood cells (mainly degraded in the
spleen and liver), cell debris, dead cells
and extraneous particles of almost any
kind
- After clearing all the debris, they also
secrete some factors that immediately
start the tissue-repair process
- Secretion of cytokines and enzymes to
kill the pathogen
- As the neutrophils, they produce
(because they are provided with the NAD oxidase and the myeloperoxidase) reactive oxygen
species and other radical species, which are toxic for the bacteria
- They’re antigen-presenting cells (especially the dendritic cells), as already said

The image on the left pictures the
phagocytosis process.
There are several types of phagocytosis,
not only the receptor-mediated one, but
there is also the endocytosis, the
macropinocytosis (the name is based on
the size of the particle that is involved).

Macrophages can also trap the bacteria
thanks to the invaginations of the membrane.
They’re also provided with the receptor for
the C3b (like the neutrophils).

Once the phagosome is formed, it fuses with
the granules and the lysosomes and the
pathogens will be destroyed.

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DENDRITIC CELLS (DC).
They’re very similar to the macrophages,
however they’re characterized by an
irregular membrane, which forms
dendrites (they’re very plastic, which
means that their shape can rapidly
change).
There are different types of DC, deriving
from the monocytes (myeloid progenitors)
and lymphoid progenitors.
They are divided into:
- Conventional dendritic cells, which are
the immature ones, and they can reach the
tissue thanks to the alarmins and the
chemoattractant, otherwise they can be
residential (e.g. the Langerhans cells in
the skin). Their main function is to phagocyte everything around them (pathogens, viruses,
infected cells, tumor cells, damaged cells, dying cells) and, thanks to the phagocytosis
process, they differentiate into mature cells (their mature version is considered the best
antigen presenting cell)
- Plasmacytoid dendritic cells, which produce the interferon, IFN, type I (there are three
different types), which may be IFN-α or IFN-β. These are a specific type of cytokines that are
responsible to induce an efficient anti-viral response
Link to see a video about the morphology of the dendritic cells:
https://www.youtube.com/watch?v=w97dms9jD3I.

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