Lecture 27: Mucosal and Cutaneous Immunity PDF

Summary

These lecture notes detail mucosal and cutaneous immunity, discussing topics like barrier function, antimicrobial peptides, and different types of mucosal-associated lymphoid tissues (MALT). It also analyzes the various immune responses in different parts of the body and the effect of inflammation.

Full Transcript

Chapter 12: Mucosal and
cutaneous immunity
 Lecture outline
Mucosal Immunity
Barrier
Mucous
Antimicrobial peptides
Tight Junctions

Mucosa Associated Lymphoid Tissue (MALT)
Gut Associated Lymphoid Tissue (GALT)
Bronchial Associated Lymphoid Tissue (BALT)
Nasal Associated Lymphoid Tissue (NALT)

Skin Associated Lymphoid Tissue (SALT)
Mucosal immunity: Overview
 Mucosal and cutaneous immunity
Most human and animal pathogens gain entry to the body by
penetrating through skin or mucosal surfaces.

Both mucosa-associated lymphoid tissue (MALT) and skin-
associated lymphoid tissues (SALT) are collection of APCs &
lymphocytes under the mucosae and skin, respectively.

MALT and SALT function as independent arms of the immune
system and induce mucosal and cutaneous immune responses.
 Mucosal and cutaneous immunity
Mucosal and cutaneous immune responses are distinct from
systemic immune responses & they are mounted locally where Ag
is first encountered without involvement of draining lymph node.

The effector cells that are generated may enter efferent
lymphatics or circulation but they home specifically to mucosal or
cutaneous sites to exert their effector functions.

However, an accompanying systemic immune response can also
be induced when Ag-bearing APCs of MALT or SALT migrate to
local lymph node and activate naïve B and T cells in this location.
Epithelial and Immune Function
 Mucosal immunity: Overview
Two types of mucosae:

– Type I mucosae: occur in intestine and lung-composed of
single layer of columnar epithelium.

– Type 2 mucosae: Squamous epithelium where tougher tissue is
required such as mouth, nose and vagina.

Both types of mucosa are capable of producing mucus
which is a viscous solution of polysaccharides in water.

Pelaseyed, T., Bergström, J. H., Gustafsson, J. K., Ermund, A., Birchenough, G. M. H., Schütte,
A., et al. (2014). The mucus and mucins of the goblet cells and enterocytes provide the first
defense line of the gastrointestinal tract and interact with the immune system. Immunological
Reviews, 260(1), 8–20.
 Mucosal immunity: Overview
Mucus also contain
– Various Abs, predominantly IgA in type 1 mucosae and IgG in
type II mucosae.

– Antimicrobial molecules such as lysozyme (breaks down
bacterial cell wall components) & lactoferrin (sequesters iron
needed for bacterial growth).

Mucosae are also constantly defended against pathogen
assaults by immune responses mounted in MALT.
 Mucosal immunity: Overview
Inductive site: is a specific area
in a mucosa where an Ag is
encountered & a primary
adaptive immune response is
initiated e.g. in the gut
– Peyers’s patches (PPs) in
small intestine
– Appendix
– diffused collection of
lymphocytes or follicles under
gut epithelium.

Effector site: is a specific area in
a mucosa to which effector
lymphocytes are dispatched e.g.
– Exocrine glands: salivary &
lacrimal glands. They produce
saliva & tears that contain
antimicrobial molecules & Abs.
 Mucosal immunity: Overview
Regions of MALT linked to type 1 mucosa are more densely
populated with DCs & lymphocytes than that are underlying
type II mucosae.

In addition to constitutive induction sites such as PPs,
individual induction sites can also arise in the gut and lungs
in response to infection and injury.

These new sites are considered to be patches of induced
MALT (iMALT) and are a form of ‘tertiary lymphoid tissue’.
 Mucosal immunity: Overview
Appearance of iMALT (includes iBALT or iGALT) depends
upon the same molecules involved in generating secondary
lymphoid tissues during mammalian embryogenesis.

In particular, lymphotoxin (LT) and IL-17, whose local
production is induced by inflammation, drive the ectopic
development of lymphoid follicles and lymphatic vessels.

The cell types that produce LT and IL-17 include TH17 cells
and lymphoid tissue inducer cell (LTi) cells.

Example of MALT induction: Appearance of areas of iBALT in
lungs of mice following vaccine delivery by intranasal route.
 Mucosal immunity: Overview
After mucosal T & B cells are activated in an inductive site,
they migrate through the lymphatics & blood to various
effector sites and complete their differentiation into Th
effectors, CTLs & plasma cells in these locations.

Thus, the defense at multiple and widely separated mucosal
effector sites may occur in response to lymphocyte
activation in one inductive site.

Example: When Ag is captured in a PP (inductive site), and
Ab response may be detected not only in the intestinal
mucosa but also in the urogenital tract and in tissues as
remote as the mammary glands (effector sites).

This concept is referred as ‘common mucosal immune
system’.
 Components of the GALT
Integration of many components of GALT provides effective
immune defense against ingested pathogens & toxins.

Basic structure:
Two major sections of GALT:
– Gut epithelium
– Lamina propria

In general, the gut epithelium is not flat but rather folded
into repeated crypt (‘cave’) and villus (‘hill’) structures.

The exceptions are small flat areas of the gut epithelium
called ‘follicle associate epithelium’ (EAE), which contains
‘M cells’ and overlie intestinal follicles, interfollicular
regions and dome regions.

Lamina propria: is composed of loose connective tissue
between basolateral (tissue facing) surface of the
epithelium and the muscle layer.
 Components of the GALT
Elements of gut epithelium:
Enterocytes:
– comprise majority of gut epithelium.

– primary function is in nutrient absorption.

– Important in integrating myriad internal and external signals
and coordinating immune responses in the GALT.

Other epithelial cell types interspersed among enterocytes:
– Enteroendocrine cells: localize in the villi, produce mucus and
secrete harmone-like molecules.

– Paneth cells: located at the bottom of intestinal crypts and
produce antimicrobial peptides.

– Goblet cells: on the sides of intestinal crypts and produce both
mucus and antimicrobial molecules.

Mucus provides a strong physical and antimicrobial barrier
in the gut.
 Components of the GALT
The apical surfaces of all gut epithelial cells are protected
against pathogens by several non-induced innate barriers.

Any invader has to compete for nutrients & living space
with commensal organisms (called microbiota/microflora).

Some of these beneficial microflora secrete toxins that can
seriously impede a pathogen and positively influence the
underlying mucus layer.
 Components of the GALT
Brush border: structure formed by the folding of the
exterior surfaces of gut epithelium into dense microvilli.

Brush border is coated with the glycocalyx (a thick layer of
glue–like molecules) which bears a negative charge and
repels many pathogens.

Glycocalyx also contains several types of hydrolytic
enzymes that degrade microbes and macromolecules.

A pathogen that succeeds in penetrating the non-induced
gut innate barriers then encounters its cellular defenders.

Enterocytes interact with microbiota on apical surfaces and
with the innate & adaptive leukocytes present below.
 Components of the GALT
Enterocytes express TLRs, NLRs and RLRs that can be
engaged by components of commensals under steady state
conditions, or by PAPMs/DAMPs under stress conditions.

The response of enterocytes to PRR engagement is usually
cytokine secretion and it depends upon the nature of the
PRR ligand & factors present in the microenvironment.

Additional innate defense is provided by gd T cells present
within or near gut epithelium and produce antimicrobial
peptides (defensins & cathelicidins) that kill pathogens.

NK cells and NKT cells scattered among enterocytes also
mediate first line defense.
 Components of the GALT
Integration of many components of GALT provides effective
immune defense against ingested pathogens & toxins.

Fig 12.2
 Elements of the lamina propria of GALT
Lamina propria contains numerous macrophages &
neutrophils and low numbers of NKT cells, mast cells and
immature DCs.

Memory ab T cells (both CD4+ and CD8+cells), memory B
cells and TH17 effectors are abundant in lamina propria.

Some lymphocytes are diffusely distributed in lamina
propria, whereas others are organized into intestinal
follicles.

Intestinal follicles can occur singly or in small groups or in
larger groups of 30-40, as occur in inductive sites such as
PPs and appendix.
 Elements of the lamina propria
During a response to Ag in the
lamina propria, the activation of B
cells can lead to formation of a
germinal center (GC).

The constant attack by pathogens on
the gut mucosa means that, at any
given time, about 10-15% of lamina
propria B cells have differentiated
into plasma cells, the vast majority
of which synthesize IgA.

Total secretion of Abs by IgA-
producing plasma cells outstrips the
combined output of Abs synthesized
by plasma cells in the spleen, bone
marrow & lymph nodes.

Plate 12.1: Germinal
center in the GALT
 Antigen (Ag) sampling in the gut
Follicle associated epithelium (FAE):
– Intestinal follicles lie under small flat sections of epithelium
called ‘FAE’ which is specialized for capture of gut Ags.

– Vast majority of EAE cells are enterocytes but 10-20% of EAE
cells are large, odd shaped cells called ‘M’ cells (membranous
or microfold cells) that are expert in Ag transcytosis.

– Within the ‘dome’ region are populations of APCs that take
delivery of Ag transcytosed by the M cell while ‘interfollicular
regions’ contain high concentration of mature ab T cells.

– Apical surface of a M cell lacks glycocalyx & thick brush border,
allowing it to easily internalize Ags either by macropinocytosis,
clathrin-mediated endocytosis or phagocytosis.
 Follicle associated epithelium (FAE):
– Ags are released by M cells into an intraepithelial pocket & are
taken up by APCs (DCs & macrophages) in dome.

– Dome also contains CD4+ & CD8+ ab T cells, resting B cells &
Treg cells.

– The intestinal follicle itself is made up of a GC containing
activated B cells and follicular dendritic cells (FDCs).

Fig 12.2
 Antigen (Ag) sampling in the gut
GALT DCs: Several DC subsets have been defined in mice.
– CX3CR1 expressing DCs are found throughout the gut.

– CX3CR1+ DCs can receive Ag sampled by M cells but they also
directly sample gut Ag by extending ‘transepithelial dendrites’,
between epithelial cells into gut lumen & routinely capture
soluble food Ags, commensals and any pathogens present.

– In contrast, CCR6+ DCs are present only in domes of PPs &
acquire Ag solely by M-cell mediated transcytosis.
 Antigen (Ag) sampling in the gut
GALT DCs: continued-
– Under steady state conditions, most GALT DCs function to
tolerize or induce apoptosis in naïve T cells specific for food
Ags & commensals or promote their differentiation to Tregs.

– When inflammation is present due to injury or infection, GALT
DCs mature & activate relevant Ag-specific T cells.

– Mature CCR6+ DCs may migrate to draining mesenteric lymph
node and mount an Ag-specific systemic immune response.
 Components of NALT and BALT
NALT and BALT provide immune defense against dubious
substances and pathogens in inhaled air.

Bacterial pneumonia is the third leading cause of mortality
worldwide indicating the importance of NALT & BALT.

Basic structure:
– NALT: composed of nasal submucosal glands, the tonsils and
the epithelial layers lining the nasopharynx (upper airway).

– BALT: includes bronchial submucosal glands, epithelial layers
lining the trachea, bronchi & lungs; and the follicles & diffuse
collection of lymphocytes underlying the epithelium of the
lower airway.

– Like the gut, bronchi and lungs are covered by type I mucosae.

– In contrast, a type II mucosa protects much of nasopharynx.
 Basic structure of NALT and BALT
Nose hairs, sweeping movements of cilia in upper
respiratory tract & coughing are non-induced innate
barriers in the NALT.

Nasopharyngeal epithelial cells are not only coated with
mucous containing sIgA, lactoferrin, lysozyme and other
antimicrobial molecules but also support a normal
microbiota.

Under stress conditions, nasopharyngeal epithelial cells can
secrete inflammatory cytokines, growth factors &
chemokines that summon innate leukocytes to the site of
assault.

A similar defense strategy (presence of commensals & cilia
in lower respiratory tract) prevails in the BALT.
 Basic structure of NALT and BALT
Bronchial & bronchiolar epithelial cells are good sources of
IL-5, IL-6, IL-10 & TGF-b which promote isotype switching
to IgA & also secrete surfactants SP-A & SP-D (collectins).

In human NALT, tonsils are the most important inductive
sites and they also serve as effector sites in the NALT.

In the BALT, many of the inductive sites are structurally
similar to those in the gut.

Mucosal follicles that resemble PPs & underlie M cells are
found in lamina propria underlying the bronchial
epithelium.
 Antigen sampling in NALT and BALT
Ag uptake in the airway is easier than in the GALT as it
lacks the harsh degradative enzymes & low pH of the gut.

In areas lined by a single epithelial layer (type I mucosa),
Ag sampling can be carried out by M cells.

In the tonsils and regions of the airway covered by the
stratified epithelium (type II mucosa), Ags are conveyed to
inductive sites by DCs that can extend their dendrites
between epithelial cells into the lumen.

These DCs commence maturation and return to underlying
diffuse lymphoid tissues in the lamina propria to initiate an
immune response or migrate to the more distant draining
lymph nodes to initiate a systemic response.
 Components of NALT and BALT

Read details from
the text book. Fig 12.3
 Next Lecture
Chapter 12: Mucosal and Cutaneous immunity.