POD M&I Session 7 Organs of Immunity and Cytokines.pptx

Transcript

MICROBIOLOGY AND IMMUNOLOGY (PBBS505A&B) 2024-2025

Session -7

Organs of Immunity/Cytokines

Rahul Vijay, DVM, Ph.D
[email protected]
 Lecture Objectives

1. Difference between primary and secondary lymphoid organs.
2. Similarities and differences in the function of lymph nodes, spleen, and mucosal associated
lymphoid tissues.
3. Major cytokines in the immune system
 Lymphoid Organs

1. Central or Primary
Thymus
Bone Marrow

2. Peripheral or Secondary
Spleen
Lymph Node
Mucosal Lymphoid
Tissue such as in the
intestine, and
respiratory tract
 Lymphocytes arise from stem cells in bone marrow
and differentiate in the central lymphoid organs - B
cells in the bone marrow and T cells in the thymus.

 They migrate from these tissues and are carried in
the bloodstream to the peripheral lymphoid organs.

 The peripheral lymphoid organs are the sites of
lymphocyte- antigen encounter and thus lymphocyte
activation.

 Lymphocytes recirculate between the blood and
these organs until they encounter their specific
antigen.
Primary/Central Lymphoid Organs
 Bone marrow
 Thymus

Lymphocyte Development occurs in Primary Lymphoid Organs
Structure of the Thymus
Outer Cortex

 Dark-staining outer part packed with lymphocytes,
compartmentalized by elongated epithelial cells.

 It consists of immature T -cells.

 The process of proliferation and selection occurs mainly here.

 Inner Medulla

 Lighter central zone with fewer lymphocytes but more
epithelial reticular cells.

 It consists of mature T-cells.

 The final stages of selection may occur at the
cortico-medullary junction.

 Medulla also consists of thymic corpuscles
alternatively called Hassall’s corpuscles. They are
believed to be aged and degenerated cells.
 Thymus

 Encapsulated, lobular Lymphocyte-rich organ located behind the
sternum, above and in front of the heart.

 Maximal activity in the fetus and then undergoes atrophy at puberty
(although never totally disappearing).

 The thymus attracts (with chemokines) circulating T cell precursors
derived from hemopoietic stem cells (HSC) in the bone marrow.
 Essential for T cell maturation (‘T cell’ stands for thymus-derived cell).

 Composed of cortical and medullary epithelial cells, stromal cells, interdigitating cells and macrophages.

 Important for the differentiation and education (positive and negative selection) of the immigrating T cell
precursors prior to their migration to the secondary lymphoid tissues.
 Secondary/Peripheral Lymphoid Organs
 Lymph Node
 Spleen
 Mucosal Associated Lymphoid Tissue

Lymphocyte –Antigen encounter occurs in Peripheral Lymphoid Organs
Lymph Node

 Lymphatics drain extracellular
fluid from the peripheral tissues,
through the lymph nodes, and
into the thoracic duct, which
empties into the left
subclavian vein. This fluid,
known as lymph/lymphatic
fluid,
 Lymph carries antigen taken up
by dendritic cells and
macrophages to the lymph
nodes, as well as recirculating
lymphocytes from the lymph
nodes back into the blood.
 2
Lymph carries free
antigen or those carried 1
by dendritic cells to LN Naïve lymphocytes
populates the lymph
node

3
Activated and non
activated lymphocytes
leave the lymph node.

Activated lymphocytes
B cells differentiation and
then return to the site of
proliferate upon antigen infection.
encounter

Swollen gland you normally see following an infection is nothing but an enlarged LN
 NO connections with the lymphatics. Spleen
 Lymphocytes and antigen enter the spleen via
blood.

 Mostly functional during blood-borne infections.

 Red pulp – due red blood cell disposal

 White pulp – enriched for lymphocytes and
other immune cells (T cells, B cells dendritic
cells and macrophages)

 Periarteriolar lymphoid sheath (PALS)- T
lymphocytes reside

 Lymphoid follicles - B cells reside

 Marginal zone – some B cells, macrophages
and dendritic cells reside.
-Where blood is filtered for Blood-borne
microbes, soluble antigens and antigen:antibody
complexes.
 Mucosal Associated Lymphoid Tissue
 Most pathogens enter the body through mucosal surfaces

 Mucosal surfaces are also exposed to a vast load of other potential antigens from the air, food,
and the natural microbial flora of the body.

 Protected by an extensive system of lymphoid tissues known generally as the mucosal immune
system or mucosa-associated lymphoid tissues (MALT).

Nasal Associated
Lymphoid tissue
(NALT)

Bronchus Associated
Lymphoid tissue
(BALT)

Gut Associated
Lymphoid tissue
(GALT)
 Distinctive features of the mucosal immune system

Anatomical features Intimate interactions between mucosal epithelia and lymphoid
tissues

Discrete compartments of diffuse lymphoid tissue and more
organized structures such as Peyer’s patches and isolated
lymphoid follicles

Specialized antigen-uptake mechanisms, e.g., M cells in Peyer’s
patches

Effector mechanisms Activated/memory T cells predominate even in the absence of
infection

Secretory IgA antibodies
Presence of distinctive microbiota
Immunoregulatory environment Active downregulation of immune responses (e.g., to food and
other innocuous antigens) predominates
GALT
 Peyer’s Patches – only in small intestine
 Isolated lymphoid follicles – entire intestine
 Appendix
 Tonsil and adenoid – in throat
Peyer’s Patches
 Important sites for the initiation of immune responses in the gut.
Peyer’s Patches
 100–200 Peyer’s patches in the human small intestine

 Visible to the naked eye, dome like structure project into the intestinal lumen.

 Contain a large number of B cells in B cell follicles, intercalated by T cell zones
and dendritic cells.

 Follicle-associated epithelium separates the lymphoid tissue from the gut
lumen - conventional intestinal epithelial cells known as enterocytes and
a smaller number of specialized epithelial cells called microfold cells (M cells).

M cells

-have a folded luminal surface instead of microvilli.

- do not secrete digestive enzymes or mucins, and so lack the thick layer of
surface mucus (the glycocalyx) found covering conventional epithelial cells.

- directly exposed to microorganisms and particles within the gut lumen and are
the preferred route by which antigens enter the Peyer’s patch from the lumen.
  “Microfold” due to ruffled or folded appearance in the epithelial layer
 Apical membrane has adhesive properties to allow capture; basolateral surrounds
a pocket filled with antigen presenting cells and lymphocytes

 Bind microbes and internalize them by transcytosis

 M cells provide a conduit for the passage of luminal microbes into the GALT and
connected lymphatics

 a number of pathogens target M cells to gain access to the subepithelial space, even
though they then find themselves in the heart of the intestinal adaptive immune
system

 Macrophages and dendritic cells take up the transported material released from the M
cells and process it for presentation to T lymphocytes.
 Together, the dendritic cells and primed T cells then activate B cells and initiate class
switching to IgA.
 Thousands of isolated lymphoid follicles can be identified microscopically throughout the small and large
intestines,

 More frequent in the large intestine, correlating with the load of local microorganisms.

 These follicles have an epithelium containing M cells that lies over the organized lymphoid tissue.

 However, they contain mainly B cells and develop only after birth in response to antigen stimulation due to
colonization of the gut by commensal microorganisms.

 Peyer’s patches, in contrast, are already present in the fetal gut, although their full development is not
completed until after birth.

 The tissues of the small intestine drain to the mesenteric lymph nodes.
- The largest lymph nodes in the body and play a crucial role in initiating and shaping immune
responses to intestinal antigens.

 The mucosal surface and lymphoid aggregates of the large intestine drain to the mesenteric lymph nodes and
to a separate node known as the caudal lymph node, found close to the bifurcation of the aorta.
 The mucosal immune system contains large numbers of effector lymphocytes even in the absence of
disease.

 In the intestine, effector cells are found in two main compartments: the epithelium and the lamina propria

 The lymphoid component of the epithelium
consists mainly of lymphocytes, which in the
small intestine are virtually all CD8 T cells-
also called intraepithelial lymphocytes
(IEL).

 The lamina propria - IgA-producing plasma
cells, conventional CD4 and CD8 T cells
innate lymphoid cells, dendritic cells,
macrophages, and mast cells.

 The circulation of lymphocytes within the
mucosal immune system is controlled by
tissue-specific adhesion molecules and
chemokine receptors.
 Intraepithelial lymphocytes (IEL)
There are two main subsets of
CD8 intraepithelial T cells—
o type a (‘inducible’)
o type b (‘natural’)

 Type a express α:β T-cell
receptors and the CD8α:β
heterodimer.
o Cytolytic function
o Anti viral activity
o Secrete IFN-γ

 Type b express α:β or γ:δ
T-cell receptors and the
CD8α:α heterodimer.
o repair of the mucosa
after inflammatory
damage
o stimulate the release of
antimicrobial peptides
 IgA
 The dominant class of antibody in the mucosal
immune system is IgA, which is produced locally by
plasma cells in the mucosal wall.

 The nature of IgA differs between the two main
compartments in which it is found—the blood and
mucosal secretions.

o IgA in the blood is mainly in the form of a
monomer.
o In mucosal tissues, IgA is produced almost
exclusively as a polymer, usually as a dimer

 To reach its target antigen in the gut lumen, the IgA
has to be transported across the epithelium by the
polymeric immunoglobulin receptor (pIgR) via
process termed transcytosis.
IgA can function in different ways
 Innate immunity in the gut
Physical barrier – thin layer of permeable epithelium protects the underlying tissues. Tight junction proteins help
maintain paracellular permeability where disruption can lead to leakage

Mucus layer – large glycoproteins (secreted and membrane-bound) called mucins are responsible for viscosity
and protective properties.

Epithelial cells themselves have immunological functions:
 Sloughing – IECs turnover every 4-5 days, enabling clearance of attached pathogens.

 Mucus production – viscous barrier to prevent bacteria from attaching and crossing the epithelium

 Antimicrobial peptides (AMPs) – “defensins” that selectivelyt target certain classes of bacteria

 Cytokines and chemokines – recruitment and activation of granulocytes, myeloid cells, and lymphocytes in
the presence of danger

 T cell-like cytokines – potent inflammatory and repair cytokines such as IL-17 and IL-22 to protect the
crypts.
Intestinal epithelial cells (IECs)

Immunity by IECs
– Enterocytes: absorption, mucus,
digestive enzymes

– Enteroendocrine cells: hormone
production, stem cell factors

– Goblet cells: specialized mucus
producers

– Paneth cells: specialized cells
defending the crypts in the SI and
colon.

– M cells: antigen and microbe
passage to GALT
Intestinal Epithelial Cells (IEC)
have a crucial role in innate
defense against pathogens.
 Epithelial cells bear Toll Like Receptors (TLR) on
both their apical and basal surfaces, from which they
can sense bacteria in the gut lumen and those that
have penetrated across the epithelium.

 Sensors include the nucleotide-binding
oligomerization domain (NOD) proteins NOD1 and
NOD2.

o NOD1 recognizes a diaminopimelic acid-
containing peptide that is found only in the cell
walls of Gram-negative bacteria.

o NOD2 recognizes a muramyl dipeptide found in
the peptidoglycans of most bacteria.

NOD2 dysfunction is associated with Crohn’s
disease
Immune priming and
tolerance are different
outcomes of intestinal
exposure to antigen.
 Gut microbiota and functions

 1014 microbes colonize the GI tract

 Immune response against these microbes is proactive, involving a constant
adaptive response against all organisms in the lumen. Inflammation is used
sparingly.
 Cytokines

 Cytokines are defined operationally as polypeptides secreted by leukocytes and other cells that act principally
on hematopoietic cells, the effects of which include modulation of immune and inflammatory responses.
 Cytokine receptors

Five major cytokine receptor families based on the type of receptor they bind:
Signaling through cytokine receptors
Inflammatory Cytokines

(IL-8)
Cytokines and T helper subsets
Anti-inflammatory cytokine: TGF-beta
Role of IL-6
 Type I IFNs (IFN-α and IFN-β)

 IFN-α are a family of many proteins produced by macrophages, IFN-β a single protein
produced by many cells

 Both IFNs inhibit viral replication

 Both activate Natural Killer cells

 Binds to the same IFN-α/β receptor - The receptor is a heterodimer composed of two
subunits termed IFNAR1 and IFNAR2.
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No need to memorize
 Chemokines

 Chemotactic proteins

 Important roles in inflammation and lymphocyte movement though lymphoid organs.

 Four major families – CC, CXC, CX3C and XC

 CXC primarily activates and attracts neutrophils--(IL-8) is among its members

 The CC family activates T cells, monocytes, and eosinophils.
CC Families of Chemokines and Chemokine Receptors.
CXC, CX3C, and XC Families of Chemokines and
Chemokine Receptors.
 To remember…

* Pro-inflammatory cytokines: IL-1, IL-6, IL-8, IL-12, TNF-alpha

* Anti-inflammatory cytokines: TGF-beta, IL-10

* Th1 Cytokine: IFN-γ (interferon gamma)
* Th2 Cytokine: IL-4, IL-5, IL-13
* Th17 Cytokines: IL-17, IL-22

* Interferons with antiviral effects (produced by many virally infected cells):
 IFN-alpha
 IFN-beta
No need to memorize