Lymphoid System Organs PDF

Summary

This document provides a detailed analysis of lymphoid organs, including lymph nodes, thymus, tonsils, and spleen. It explains their structure, function, and role in the immune response. The document also covers topics such as MALT, GALT, and BALT.

Full Transcript

The Immune System & Lymphoid
Organs
Fevziye Figen Kaymaz M.D., Ph.D.
Prof. of Histology & Embryology
[email protected]

Learning goals
• Identify lenfoid organs such as thymus, lymph node, tonsilla, spleen

Lymph Nodes
Lymph nodes are bean-shaped, encapsulated structures, generally
only 10 mm by 2.5 cm in size, distributed throughout
the body along the lymphatic vessels
A total of of 400 to 450 lymph nodes are present, most abundantly in
the axillae (armpits), along the major vessels of the neck, and in the
thorax and abdomen, especially in mesenteries.
• The nodes constitute a series of in-line filters of lymph that defend
against microorganisms and tumor cells and provide enclosed
environments that facilitate production of plasma cells
• Before merging with the bloodstream, all lymph is filtered and has
antibodies added by at least one lymph node.
•
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• Embedded in loose connective tissue
• convex surface where afferent lymphatics enter
• Concave depression, the hilum, where an efferent
lymphatic leaves and where an artery, vein, and nerve
penetrate the organ
• A dense connective tissue capsule surrounds the lymph
node, extending trabeculae internally through which the
blood vessels branch.
• Valves in the lymphatics ensure that lymph flow is
unidirectional.
• The most abundant cells of lymph nodes are lymphocytes
of all types, plasma cells, dendritic cells, macrophages, and
other APCs. FDCs are present within lymphoid nodules.
• All of these cells are arranged in a stroma of reticulin fibers
and reticular cells to form three major regions: an outer
cortex, a central medulla, and a smaller area between
these two called the paracortex
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Cortex
• A subcapsular sinus, immediately inside the capsule,receives lymph
from the afferent lymphatics
• lined by a very thin, discontinuous endothelium penetrated by
reticulin fibers and processes of dendritic cells.
• Lymph containing antigens, lymphocytes, and APCs

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• Lymphoid nodules, with or without
germinal centers, fill most cortical
areas
• proliferating B lymphoblasts
• Each nodule is organized around the
long, interdigitating processes of
follicular dendritic cells
• (FDCs),
• Numerous macrophages are also
present for removal of newly formed
defective B cells.

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Cortex- outer cortex

.

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paracortex
• lack of B-cell lymphoid nodules
• lymphoid tissue rich T cells
• Specialized postcapillary venules, high endothelial venules (HEVs)
represent an important entry point for most (90%) lymphocytes into
lymph nodes.
• endothelial lining – cuboidal cells,
• HEVs also occur in the large accumulations of MALT

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Paracortex

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medulla
• Medullary cords are branched cordlike masses of lymphoid tissue extending from the
paracortex.
• contain T and B lymphocytes and many plasma cells.
• Medullary sinuses are dilated spaces lined by discontinuous endothelium that separate
the medullary cords.
• the lumens of medullary sinuses include a meshwork of processes from reticular cells,
macrophages and sometimes
• They are continuous with the cortical sinuses and converge at the hilum as the efferent
lymphatic vessel

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Role of Lymph Nodes in the Immune Response
• The lymph arriving at a lymph node draining from an infected
or inflamed region, lymph may also contain microorganisms
and cytokines. Antigens not yet phagocytosed will be
internalized by APCs in the lymph nodes and presented on
MHC class II molecules.
• Circulating B and T lymphocytes traffic from node to
node, entering via the lymph or HEVs, where B cells contact
antigens on FDCs and T cells sample antigens presented on
dendritic cells and other APCs.

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• Lymphocytes whose receptors recognize such antigens will be
activated. B cells will proliferate rapidly in germinal centers of
follicles with the help of Th cells, often enlarging the entire
lymph node.
• Activated cytotoxic T cells in the paracortex proliferate to a
much lesser extent without forming follicles.
• Many newly made B cells, now activated against a specific
antigen, differentiate as plasma cells and move to the medulla
or to downstream sites beyond the lymph node where they
produce antibodies. Specific Th cells, CTLs, and Tregs also
recirculate in the efferent lymph and with the antibodies
spread the immune defenses against those microorganisms

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Clinical correlations
• In the presence of antigens or bacteria, lymphocytes of the lymph
node rapidly proliferate, and the node may increase to several times
its normal size, becoming hard and palpable to the touch.

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Clinical correlations
• Lymph nodes are located along the paths of lymph vessels and form a
chain of lymph nodes so that lymph flows from one node to the next.
For this reason, infection can spread and malignant cells may
metastasize through a chain of nodes to remote regions of the body

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Clinical correlations
• Metastatic cancer cells detached from a primary tumor can
enter lymphatics and are carried to nearby lymph nodes,
• Cells from well-established tumors are often
immunosuppressive themselves and may continue growth as a
secondary tumor within lymph nodes. During cancer surgery
lymph nodes in the lymphatics draining the tumor area are
examined by pathologists for the presence of cancer cells. The
presence of such metastatic cells in lymph nodes is a key
determinant in most staging systems for various types of
cancer and an important prognostic indicator.

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MUCOSA-ASSOCIATED LYMPHOID TISSUE
(MALT)
• GALT / BALT / NALT
• The mucosa or inner lining of the digestive, respiratory, and genitourinary tracts is
a common site of invasion by pathogens because their lumens open to the
external environment.
• To protect against such invaders mucosal connective tissue of these tracts contains
large and diffuse collections of lymphocytes, IgA-secreting plasma cells, APCs, and
lymphoid nodules, all of which comprise the MALT.
• Lymphocytes are also present within the epithelial lining of such mucosae.
• tonsils, the Peyer patches in the ileum, and the appendix.
• the MALT is one of the largest lymphoid organs, containing
• up to 70% of all the body’s immune cells. Most of the lymphocytes
• here are B cells; among T cells, CD4+ helper T cells predominate.
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GALT – İleum – Peyer patches
• MALT extends from the
pharynx along the entire
gastrointestinal tract
• the ileum. - the Peyer
patches

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• M cells; (microfold cells)
• The simple columnar
epithelium that covers the
lymphoid nodules of Peyer
patches includes large
epithelial M cells with
apical microfolds
• On the basal side of
lymphocytes and dendritic
cells

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• Antigens in the intestinal lumen are transferred to the immune cells in the
pockets. Lymphocytes and dendritic cells leaving the M cell pockets through
the basement membrane pores interact and initiate adaptive responses to
the antigens, which results in formation of the secondary lymphoid nodules.
• Locally produced B cells give rise to plasma cells secreting IgA, which is
transported by enterocytes into the intestinal lumen to
• bind and neutralize potentially harmful antigens.
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appendix

• Another significant collection of
MALT occurs in the mucosa of the
appendix, a short, small-diameter
projection from the cecum. Typically
the mucosa of the appendix is
almost completely filled with
lymphoid tissue,
• The lumen contains the normal
bacterial flora of the large intestine
and may serve to retain some of
these beneficial bacteria there
during diarrheal illnesses.

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BALT

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• BALT is located in the walls of bronchi, especially in
regions where bronchi and bronchioles bifurcate.
• the epithelial cover over these lymphoid nodules
changes from a pseudostratified ciliated columnar
with goblet cells to M cells.
• Afferent lymph vessels are absent, although lymph
drainage has been demonstrated.

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Tonsils

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Named by their location
• Palatine tonsils
• Lingual tonsils
• pharyngeal tonsils
• (Waldeyer‘s lymphatic ring

PA: Pharyngopalatine arches
PTo: Palatine tonsil
GA: Glossopalatine

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Palatine tonsils
• located posteriorly on the soft
palate, are covered by stratified
squamous epithelium.
• The surface area of each is
enlarged with 10-20 deep
invaginations or tonsillar crypts in
which the epithelial lining is
densely infiltrated with
lymphocytes and other leukocytes,
many secondary lymphoid nodules
around the crypts.

AROUND

• This tissue is underlain by dense
connective tissue that acts as a
partial capsule.

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pharyngeal tonsil
• situated in the posterior wall
of the nasopharynx, is
covered by pseudostratified
ciliated columnar epithelium,
and has a thin underlying
capsule. The mucosa with
diffuse lymphoid tissue and
lymphoid nodules is
invaginated with shallow
infoldings but lacks crypts.

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Lingual tonsils
• situated along the base of
the tongue, are also
covered by stratified
squamous epithelium
with crypts, and have
many of the same
features as palatine
tonsils but lack distinct
capsules.

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Medical aplications
• Inflammation of the tonsils, tonsillitis, is more common in children
than adults.
• Chronic inflammation of the pharyngeal lymphoid tissue and tonsils
of children often produces hyperplasia and enlargement of the tonsils
to form “adenoids,” which can obstruct the eustachian tube and lead
to middle ear infections.

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Spleen
•
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•
•
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•
•
•
•

Largest lymphoid organ İmmulogical filter of the blood
idefense against blood-borne antigens.
he main site of old erythrocyte destruction.
Capsula / trabeculae -dense CT- miyofibroblast
White pulp Red pulp
White pulp : PALS (periarteriolar lymphoid sheath), germinal centers
No cortex and medulla
Red pulp: irreguler branching venous sinuses, pulp cords ( Cords of Billroth)
Marginal zone
Special blood circulation (open and/ or closed type)

• filled with reticular tissue
containing reticular cells and
fibers, many lymphocytes and
other blood cells, macrophages,
and APCs.
• Splenic pulp has two components:
the white pulp (20% of the spleen)
and the red pulp.
• The small masses of white pulp
consist of lymphoid nodules and
the periarteriolar lymphoid
sheaths
• the red pulp consists of bloodfilled sinusoids and splenic cords.

• Splenic a. - Branching from the
hilum, small trabecular arteries
leave the trabecular connective
tissue and enter the parenchyma as
arterioles enveloped by the PALS,
which consists primarily of T cells
with some macrophages, DCs, and
plasma cells as part of the white
pulp. Surrounded by the PALS, these
vessels are known as central
arterioles
• Each central arteriole eventually
leaves the white pulp and enters the
red pulp, losing its sheath of
lymphocytes and branching as
several short straight penicillar
arterioles that continue as
capillaries. Some of these capillaries
are sheathed with APCs for
additional immune surveillance of
blood.

Figure 14—30. Lymphoid nodule of the spleen surrounded by red pulp. A germinative center (1) and the
(eccentric) central artery (2), which is characteristic of the spleen, are clearly visible. Two small sections of
sheathed arteries are seen to the right of the nodule. H&E stain. Medium magnification. (Courtesy of PA
Abrahamsohn.)

• B cells located within the PALS may be
activated by a trapped antigen from the
blood and form a temporary lymphoid
nodule like those of other secondary
lymphoid organs
• In growing nodules the arteriole is
pushed to an eccentric position but is still
called the central arteriole. These
arterioles send capillaries throughout the
white pulp and to small sinuses in a
peripheral marginal zone of developing B
cells around each lymphoid nodule

• The red pulp is composed almost
entirely of splenic cords (of Billroth)
and splenic sinusoids and is the site
where effete RBCs in blood are
removed.
• The splenic cords contain a network of
reticular cells and fibers filled with T
and B lymphocytes, macrophages,
other leukocytes, and red blood cells.
• The splenic cords are separated by the
sinusoids. Unusual elongated
endothelial cells called stave cells line
these sinusoids, oriented parallel to
the blood flow and sparsely wrapped
in reticular fibers and highly discontinuous basal lamina

• Blood flow through the splenic red pulp
can take either of two routes
• In the closed circulation, capillaries
branching from the penicillar arterioles
connect directly to the sinusoids and the
blood is always enclosed by endothelium.
• In the open cırculation, capilleries from
penicillar arterioles are uniquely openended, dumping blood into the stroma of
the splenic cords. In this route plasma and
all the formed elements of blood must
reenter the vasculature by passing through
narrow slits between the stave cells into
the sinusoids . Swollen RBCs at their
normal life span of 120 days are blocked
from passing between the stave cells and
undergo selective removal by macrophages

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• From the sinusoids blood proceeds to small red pulp veins that
converge as the trabecular veins, which in turn form the splenic vein.
The trabecular veins lack significant smooth muscle and resemble
endothelium-lined channels hollowed out in the trabecular
connective tissue.

• Removal of defective RBCs and recycling of their iron are
major functions of the red pulp. Iron released from
hemoglobin during the degradation of RBCs is stored by
macrophages within complexes of ferritin proteins or bound
to transferrin, returned to the circulation, and reused
primarily for erythropoiesis. Iron-free heme is either bound
to its transport protein, hemopexin, or is metabolized to
bilirubin and excreted in the bile by liver cells. After surgical
removal of the spleen (splenectomy), the number of
abnormal erythrocytes in the circu- lation increases
although most such cells are then removed by macrophages
in sinusoids of the bone marrow and liver.

MEDICAL APPLICATION
• enlargement of the spleen, splenomegaly, can occur from a
variety of causes, including lymphoma or other malignant
growth, infections such as mononucleosis, or sickle cell
disease and other types of anemia. The splenic capsule
traumatic rupture, a potentially life-threatening occurrence
due to loss of blood into the abdominal cavity. Such rupture
may require prompt surgical removal of the spleen,
splenectomy, after which most functions of the organ are
carried out by other lymphoid organs, with erythrocyte
removal occurring in the liver and bone marrow.

Thymus
• Primary lymphoid organ form a specific microenvironmet
for the development/ maturation of T lymphocytes
• a bilobed structure in the mediastinum,
• Stroma consist of a capsula and septa which divide the
parenchyme into many incomplete lobules
• Each lobule has a cortex and a medulla
• T cell pecursors slowly migrates from C To M by making
intimate contacts with epithelial reticular cells, bone
marrow derived IDC
• Maturation continues in the medulla ( more mature cells
in medulla

Thymus
• Immature B lymphocytes emerge from the bone marrow,
• the primary lymphoid organ in which T cells are produced
is the thymus
• A main function of the thymus is induction of central
tolerance, which along with regulatory T cells prevents
autoimmunity.
• The organ originates from the embryo’s third pair of
pharyngeal pouches (endoderm), with precursor
lymphoblasts circulating from the bone marrow to invade
and proliferate in this unique thymic epithelium during its
development.

• Fully formed and
functional at birth, the
thymus remains large
and very active in T-cell
production until puberty,
during which it
undergoes involution,
decreasing greatly in size
and activity and
becoming largely filled
with adipose tissue

Components
• Developing /maturing T
lymphocytes or (thymocytes)
• Epithelial reticular cells(
endoderm 3 pharyngeal
pouch and ectoderm)
• Macrophages
• Bone marrow derived IDC at
the corticomedullary boundry
• No reticuler stroma

Epithelial reticular cells
(thymic epithelial cells)
• Form a cytoreticulum in a very close
association with thymocytes
• Type I (Squamous ) subcapsular and
perivasculer
joined by desmosomes and occluding
junctions,
line the connective tissue of the capsule
and septa and surround the
microvasculature.This creates an isolated
cortical compartment and, together with the
vascular endothelial cells and pericytes, form
Blood thymus barrier

Type II Thymic nurse cells in the
mid cortex
• processes containing keratin
tonofilaments joined by
desmosomes, form a
cytoreticulum to which
macrophages and developing
lymphocytes attach instead of
to reticulin fibers
• APCs, expressing MHC class II
molecules in addition to MHC
class I. They also secrete
numerous cytokines for T-cell
development and other
immune functions

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Type III
cortical TECs also express MHC class II molecules but
form a sheetlike structure contributing to a functional
corticomedullary barrier between these two regions of
each lobule.
Type IV A second layer
of the boundary
between cortex and
medulla

TypeV in medulla. A cytoreticulum that (1) supports
less densely packed T lymphocytes, dendritic cells, and
macrophages, and (2) expresses many specialized
proteins specific to cells of other organs.
typeVI in medulla. Hassall corpuscles secrete several
cytokines that control activity of local dendritic cells,
including factors that promote development of
regulatory T cells for peripheral tolerance.

Tip VI hücreler:
birbirlerinin üzerine
sarılarak Hassall cisimlerini
ypr. Yaş ile sayıları artar.
Sitokin salgılayarak yerel
dendritik hücrelerin
aktivitesini ve periferik
tolerans için gerekli
Regulatuvar (düzenleyici) T
lenfositlerin farklanmasını
kontrol eder. Medulla da
hücre ölüm alanları
olabileceği düşünülüyor.

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T lymphoblasts arriving in
the thymus do not yet
express CD4, CD8, or a
TCR . These cells
populate the cortex and
begin to proliferate,
recombine variable
regions of the TCR α and
β chain genes, and then
express these TCR
proteins as well as both
CD4 and CD8.

• two-stage selection process of
quality control, which ensures
that mature T cells have TCRs
that are fully functional but do
not recognize and strongly
bind MHC with self-antigens.
• The selection process for each
pre–T lymphocyte begins in
the cortex, ends in the
medulla, and lasts about 2
weeks.

• TECs in the cytoreticulum of the cortex present the
developing thymocytes with peptides on both MHC
class I and class II proteins, which are important for
development of CD8 and CD4 T cells, respectively.
This interaction determines whether the newly made
TCR proteins of these cells are functional. The cells
are examined by positive selection, with a cell’s
survival depending on whether its TCRs can recognize
and bind antigens on the MHC molecules properly.

• nonfunctional and
completely useless cells (as
many as 80% of the total)
undergo apoptosis and are
removed by the
macrophages. T cells with
normal binding to antigens
on either MHC class I or class
II are positively selected and
move to the medullary
compartment

• In the medulla T cells with
functional TCRs encounter
antigens presented on
both cytoreticular TECs
and dendritic cells. Here
the focus is on removing T
cells whose TCRs strongly
bind self-antigens, a
process called negative
selection because survival
depends on a cell not
binding to MHC molecules
with such peptides

• T cells that strongly bind MHCs containing these selfpeptides undergo apoptosis, which is important
because release of any such cells from the thymus
would lead to a damaging autoimmune response.
Only about 2% of all developing T lymphocytes pass
both the positive and negative selection ests and
survive to exit the thymus as immunocompetent T
cells. Depending on which class of MHC they
interacted with, most of these lymphocytes will have
stopped expressing either CD8 or CD4, and become
either helper T cells or cyto- toxic T cells

• Deletion of self-reactive helper
and cytotoxic T lympho- cytes in
the thymus is the basis for the
central immunotolerance
produced there. Supplementing
this throughout the body is the
peripheral tolerance mediated
by regulatory T cells, which also
develop initially in the thymic
medulla under the influence of
cytokines from Hassall
corpuscles.

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•

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•

•

•
•

Early thymocytes at the periphery of the cortex begin to
synthesize TCR also proliferation markers
Genes encoding TCR show somatic recombination random
assortment a large number of gene segments to produce
functional receptors capable of recognizing all possible
antigens
CD4 and CD 8 appear double positive
Cortical epıthelial cells present MHCI and MHCII
Cells carrying receptors which make adequate bındıng with
self MHC positively selected are allowed to differentiate
further. Rest are eliminated by apoptosıs and are
phagocytosed by macrophages
İf positively selected thymocytes have receptörs that recognize
self commponents presented to them by largely İDC or by
some epıthelial cells at the CM boundry and in the medulla
negatively selected -eliminated
Entry of self reactive cells to general circulation causes
autoimmunıty
Central peripheric tolerance

Medulla
• More mature
thymocytes
• Prominent
cytoreticulum of
epıthelial cells
• Hassall’s corpuscles
• Macrophages