immune system

Dr.Hameda abdulmahdi College of Medicine /Dep. of anatomy

histology 2nd stage

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Objectives  

1. Briefly describe the cellular and humoral components of the innate and

adaptive immune systems.

2. Describe the main differences between the innate and adaptive immune

responses.

3. Briefly describe the classes of classes of Antibodies

The  immune  system  provides  defense  or  immunity  against  infectious
agents ranging from viruses to multicellular parasites. Histologically this system
consists of a large, diverse population of leukocytes located within every tissue
of  the  body  and  lymphoid  organs  interconnected  only  by  the  blood  and
lymphatic circulation.

Immunologists recognize two partially overlapping lines of defense against
invaders and/or other abnormal, potentially harmful cells: innate immunity and
adaptive immunity . The first of these is nonspecific, involves a wide variety of
effector  mechanisms,  and  is  evolutionarily  older  than  the  second  type.  Among
the  cells  mediating  innate  immunity  are  most  of  the  granulocytes  and  other
leukocytes described in adaptive immunity aims at specific microbial invaders, is
mediated  by  lymphocytes  and  antigen‐presenting  cells  (APCs)  and  produces
memory cells that permit a similar, very rapid response if that specific microbe
appears again.

The  lymphocytes  and  APCs  for  adaptive  immunity  are  distributed
throughout the body in the blood, lymph, and epithelial and connective tissues,
lymphocytes  are  formed  initially  in  primary  lymphoid  organs  (the  thymus  and
bone  marrow),  but  most  lymphocyte  activation  and  proliferation  occur  in
secondary lymphoid organs (the lymph nodes, the spleen, and diff use lymphoid
tissue found in the mucosa of the digestive system, including the tonsils, Peyer
patches, and appendix).

The immune cells located diffusely in the digestive, respiratory, or urogenital
mucosae  comprise  what  is  collectively  known  as  mucosa‐associated  lymphoid
tissue (MALT) , proliferating B lymphocytes in the secondary structures of MALT
are  arranged  in  small  spherical  lymphoid  nodules  .  The  wide  distribution  of
immune system cells and the constant traffic of lymphocytes through the blood,
lymph, connective tissues, and secondary lymphoid structures provide the body
with an elaborate and efficient system of surveillance and defense.

Dr.Hameda abdulmahdi College of Medicine /Dep. of anatomy

histology 2nd stage

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Innate and Adaptive immunity

The  system  of  defenses  termed  innate  immunity  involves  immediate,
nonspecific  actions,  including  physical  barriers  such  as  the  skin  and  mucous
membranes  of  the  gastrointestinal,  respiratory,  and  urogenital  tracts  that
prevent infections or penetration of the host body, Bacteria, fungi, and parasites
that manage to penetrate these barriers are quickly removed by neutrophils and
other leukocytes in the adjacent connective tissue.

Other  leukocytes  orchestrate  the  defenses  at  sites  of  penetration  natural
killer ( NK ) cells destroy various unhealthy host cells, including those infected
with virus or bacteria, as well as certain potentially tumorigenic cells.

Leukocytes and specific cells of the tissue barriers also produce a wide variety
of  antimicrobial  chemicals  that  Adaptive  immunity,  acquired  gradually  by
exposure  to  microorganisms,  is  more  specific,  slower  to  respond,  and  an
evolutionarily  more  recent  development  than  innate  immunity.  The  adaptive
immune response involves B and T lymphocytes, which become activated against
specific invaders by being presented with specific molecules from those cells by
APCs, which are usually derived from monocytes.

Unlike  innate  immunity,  adaptive  immune  responses  are  aimed  at  specific
microbial  invaders  and  involve  production  of  memory  lymphocytes  so  that  a
similar response can be mounted very rapidly if that invader ever appears again.

Antigens and Antibodies
A  molecule  that  is  recognized  by  cells  of  the  adaptive  immune  system  is
called an antigen and typically elicits a response from these cells, antigens may
consist of soluble molecules (such as proteins or polysaccharides) or molecules
that  are  still  components  of  intact  cells  (bacteria,  protozoa,  or  tumor  cells),
immune  cells  recognize  and  react  to  small  molecular  domains  of  the  antigen
known as antigenic determinants or epitopes.

Classes of Antibodies
Immunoglobulins of humans fall into five major classes, with their structural
features,  abundance  in  plasma,  major  locations,  and  functions.  The  classes  are
called immunoglobulin G (IgG), IgA, IgM, IgE, and IgD, and key aspects for each
include the following:
 
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 IgG  is  the  most  abundant  class  representing  75%  to  85%  of  the

immunoglobulin  in  blood.  Production  increases  during  immune  responses
following  infections,  etc.  Unlike  the  other  classes  of  antibodies,  IgG  is  highly
soluble,  stable  (half‐life  >3  weeks),  and  crosses  the  placental  barrier  into  the

Dr.Hameda abdulmahdi College of Medicine /Dep. of anatomy

histology 2nd stage

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fetal  circulation.  This  confers  passive  immunity  against  certain  infections  until
the newborn’s own adaptive immune system is acquired.
 
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 IgA  is  present  in  almost  all  exocrine  secretions,  IgA  is  produced  by  plasma

cells  in  mucosae  of  the  digestive,  respiratory,  and  reproductive  tracts,  another
protein bound to this immunoglobulin, the secretory component, is released by
the  epithelial  cells  as  IgA  undergoes  transcytosis,  the  resulting  structure  is
relatively resistant to proteolysis and reacts with microorganisms in milk, saliva,
tears, and mucus coating the mucosae in which it is made.
 
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 IgM  constitutes  5%  to  10%  of  blood  immunoglobulin  and  IgM  is  mainly

produced in an initial response to an antigen. IgM bound to antigen is the most
effective antibody class in activating the complement system.
 
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IgE, usually a monomer, is much less abundant in the circulation and exists

bound  receptors  on  the  surface  of  mast  cells  and  basophils.  When  this  IgE
encounters the antigen that elicited its production, the antigen‐antibody complex
triggers  the  liberation  of  several  biologically  active  substances,  such  as
histamine, heparin, and leukotrienes.

Antigen‐Presenting Cells
Most  specialized  antigen‐presenting  cells  (APCs)  are  part  of  mononuclear
phagocyte system, including all types of macrophages and specialized dendritic
cells in lymphoid organs. Features common to all APCs are an active endocytotic
system  and  expression  of  MHC  class  II  molecules  for  presenting  peptides  of
exogenous  antigens.  Besides  dendritic  cells  (not  to  be  confused  with  cells  of
nervous tissue) and all monocyte‐derived cells, “professional” APCs include the
epithelial reticular cells of the thymus and B lymphocytes. During inflammation
transient  expression  of  MHC  class  II  is  induced  by  interferon‐γ  in  certain  local
cells  that  can  be  considered  “nonprofessional”  APCs,  including  fibroblasts  and
vascular endothelial cells.

Lymphocytes
Lymphocytes both regulate and carry out adaptive immunity. In adults stem cells
for  all  lymphocytes  are  located  in  the  red  bone  marrow,  but  cells  of  the  major
lymphoid lineages mature
and become functional in two different central or primary lymphoid organs. Cells
destined to become B lymphocytes remain and differentiate further in the bone
marrow.  Progenitors  of  T  lymphocytes  move  via  the  circulation  into  the
developing thymus. After maturation in these primary structures,
B  and  T  cells  circulate  to  the  peripheral  secondary  lymphoid  organs,  which
include  the  MALT,  the  lymph  nodes,  and  the  spleen  (see  Figure  14–1).
Lymphocytes  do  not  stay  long  in  the  lymphoid  organs;  they  continuously

Dr.Hameda abdulmahdi College of Medicine /Dep. of anatomy

histology 2nd stage

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recirculate through the body in connective tissues, blood, and lymph. Because of
the  constant  mobility  of  lymphocytes  and  APCs,  the  cellular  locations  and
microscopic details of lymphoid organs differ from one day to the next. However,
the relative percentages
of T and B lymphocytes in these compartments are relatively steady (Table 14–
3).  Lymphoid  tissue  is  usually  reticular  connective  tissue  filled  with  large
numbers of lymphocytes. It can be either diffuse within areas of loose connective
tissue  or  surrounded  by  capsules,  forming  discrete  (secondary)  lymphoid
organs.  Because  lymphocytes  have  prominent  basophilic  nuclei  and  very  little
cytoplasm, lymphoid tissue packed with such cells usually stains dark blue . In all
secondary  lymphoid  tissue  the  lymphocytes  are  supported  by  a  rich  reticulin
fiber  network  of  type  III  collagen  .  The  fibers  are  produced  by  fibroblastic
reticular  cells,  which  extend  numerous  processes  along  and  around  the  fibers.
Besides  lymphocytes  and  reticular  cells,  lymphoid  tissue  typically  contains
various APCs and plasma cells. Although most lymphocytes are morphologically
indistinguishable  in  either  the  light  or  electron  microscope,  various  surface
proteins  (“cluster  of  differentiation”  or  CD  markers)  allow  them  to  be
distinguished  as  B  cells  and  subcategories  of  T  cells  by  immunocytochemical
methods.
Key  features  of  B  and  T  lymphocytes  also  include  the  surface  receptors
involved in activating their different responses to antigens. Receptors of B cells
are immunoglobulins that bind antigens directly; those on T cells react only with
antigen on MHC molecules and this requires the additional cell surface proteins
CD4 or CD8.