The document discusses immunodeficiency, which is a defect in the immune system that leads to failure to protect against disease. It describes primary/congenital immunodeficiency caused by genetic defects impairing immune system development or function. Secondary/acquired immunodeficiency is caused by factors like cancer treatment, burns, aging or HIV infection damaging immune cells. Specific primary immunodeficiencies discussed include combined antibody and T-cell deficiencies, T-cell deficiencies like DiGeorge Syndrome, and B-cell deficiencies like X-linked agammaglobulinemia. Defects can occur in hematopoietic stem cells, lymphoid progenitors or individual immune cell types.
2. Immunodeficiency
Defect in 1 or more components of immune system and lead to
failure of the immune system to protect against disease or
malignancy
Types:
ī Primary or Congenital:
ī Caused by genetic defects that lead to impaired maturation or
function of different components of the immune system.
ī Frequently manifested in infancy and early childhood but is
sometimes clinically detected later in life.
ī Secondary or Acquired:
ī Loss or decreased function of various components of the immune
cells due to disseminated cancer, treatment with
immunosuppressive drugs, burns, trauma, radiation,
chemotherapy, surgery, aging, malnutrition or infection of cells of
the immune system, most notably with the human
immunodeficiency virus (HIV).
3. Types of inheritance in immunodeficiency
īAutosomal recessive (most AA normal; Aa carrier; aa
affected) A genetic condition can occur when the child inherits
one copy of a mutated (changed) gene from each parent. â
majority of immunodeficiency
īAutosomal dominant (Aa affected; aa is normal)
A genetic condition can occur when the child inherits the
abnormal gene from only one parent. e.g. DiGeorge syndrome
īX-linked (XX carrier daughter; XY affected son)
Means that the gene causing the trait or the disorder is located
on the X chromosome. e.g. X-Linked Agammaglobulinemic
(XLA)
4. Congenital (Primary) immunodeficiency
īIn different primary immunodeficiency, the
causative abnormality may be in components of the
innate immune system, or different stages of
lymphocyte development and activation
īprimary immunodeficiency include:
īCombined T- & B-Cell Deficiency
īT-Cell Deficiencies
īB-Cell Deficiencies
īdefects in components of the innate immune
system
5.
6. Defect in hematopoietic Stem Cell (HSC)
ī HSC are multipotent (differentiate into all blood cell types)
ī Self renewing cells
ī Defect in HSC results in immunodeficiency known as Reticular
Dysgenesis:
īIs a rare, inherited autosomal recessive disease that results in
immunodeficiency.
īCaused by mutations in both copies of the AK2 gene(lead to
absence of AK2 protein).
īAffects development of all leukocytes
īPatients are susceptible to all infections (bacterial, viral, and fungal).
ī This disease is classified as a severe combined immunodeficiency
disease (SCID)
īTreated with bone marrow or HSC transplantation.
8. Defect in Lymphoid Progenitor
ī If the lymphoid progenitor cells are defective, results
both the T and B cell lineages are affected and result in
the Severe Combined Immunodeficiency (SCID):
īLack T, B and/or NK cells
īDefects in both humoral and cell-mediated immune
responses
īSusceptible to bacterial, viral and fungal infections.
īMutations in genes involved in different steps in
lymphocyte development may cause SCID.
īLive attenuated vaccines (e.g. Sabin polio) can cause
disease.
9. Types of SCID
īRAG-1/2 (Recombinase activating gene) deficiency:
Genes that encode the recombinase enzymes that catalyze the
recombination of the DNA required to generate the T-cell antigen
receptor and the IgM monomer on the B cell that acts as the antigen
receptor.
īIL-2R Îŗ gene defect (X-linked):
âĸ Is caused by mutations in the one gene encoding the common Îŗ (Îŗc)
chain shared by the receptors for the cytokines IL-2, IL-4, IL-7, IL-9,
and IL-15, that are responsible for proliferation and development of
lymphocyte
ī Adenosine deaminase (ADA) deficiency:
âĸ Enzyme responsible for converting adenosine to inosine
âĸ ADA deficiency (due to mutations in the ADA gene) leads to
accumulation of adenosine which results in production of toxic
metabolites that accumulation in lymphocytes.
10. Defect in T cell (T cell deficiency)
âĸT cell deficiency affects not only cell-mediated
immunity but also humoral immunity.
âĸ The patients are susceptible to viral, protozoal and
fungal infections as well as to intracellular bacterial
infections.
âĸThere are many of diseases that are associated with
T cell deficiency:
ī(DiGeorgeâs syndrome)
īAtaxia-telangiectasia
īWiskott-Aldrich syndrome
īBare lymphocyte syndrome
12. DiGeorgeâs syndrome
īAutosomal dominant trait characterized by cellular (T-cell)
deficiency results from deletion of a region on chromosome 22
during development of 3rd and 4th pharyngeal pouch. The
patients with DiGeorge Syndrome may have:
âĸ Thymic aplasia (leading to deficient T cell maturation)
âĸ Congenital heart problems
âĸ hypocalcemia/hypoparathyroidism (due to defect development
in parathyroid glands)
âĸ Cleft palate
âĸ low set notched ears and fish-shaped mouth
âĸ Developmental delays
īAbout 90% of cases occur due to a new mutation during early
development, while 10% are inherited from a person's parents.
īTreatment is with a thymic graft.
14. Ataxia-telangiectasia
īIt is an autosomal recessive that affects the nervous system,
immune system, and other body systems disease caused by
mutations in the ATM genes that encode DNA repair enzymes.
īAtaxia meaning (difficulty in maintaining balance) and
telangiectasia (enlarged small blood vessels of the conjunctivas
and skin).
ī About two-thirds of patients have lymphopenia and low
immunoglobulins, particularly IgA, which results in recurrent
pyogenic upper respiratory infections.
īPatients with Ataxia may have:
âĸ Ataxia (difficulty with control of movement) in early childhood.
âĸ Oculomotor apraxia (difficulty with coordination of head and
eye movement)
âĸ Slowed rate of growth, decreasing mental development,
15. Wiskott-Aldrich syndrome
īIt is an X-linked disease caused by mutations in the
WAS gene (lead to lack of any functional WAS protein),
leading to a defect in actin filament assembly that is
important for T cells to respond to antigen presentation
and for B cells to be activated by signals from the B-cell
receptor.
īWiskott-Aldrich syndrome is characterized:
âĸAbnormal or nonfunctional immune system cells
âĸPoorly responds to polysaccharide infection
âĸEczema
âĸlow platelets (thrompocytopenia)
âĸpurpura, or variably sized rashes made up of tiny red
spots called petechiae
16. Bare lymphocyte syndrome
īIS a rare recessive genetic condition characterized
defective MHC class II expression due to defects in
transcription factors that regulating MHC class II
gene expression like (CIITA), causing inability to
display antigens to T cells.
īDeficiency in CD4+ T cells; defective cell-mediated
immunity and T-dependent humoral immune
responses.
īIt is a form of severe combined immunodeficiency
(SCID)
18. X-linked Agammaglobulinemia (x-LA)
īIs caused by mutations or deletions in the gene
encoding an enzyme called Bruton tyrosine kinase
(Btk) that result in a failure of B cells to mature.
īThe disease is characterized by decreased in all
serum Ig isotypes and reduced B cell numbers.
īT cellâmediated reactions are normal.
19. Selective IgA deficiency
īIt is the disease that characterized by decreased
level of IgA
īIgA deficiency results from a defect in the class
switching, due to mutations in TACI (transmembrane
activator and calcium modulator and cyclophilin
ligand interactor), in some patients.
īRecurrent respiratory, gastrointestinal and/or
genitourinary infection
20. Common variable immunodeficiency
(CVID)
īIs a group of heterogeneous disorders
characrtrized by reduced levels of serum Ig,
impaired antibody responses to infection and
vaccines, and increased incidence of infections.
īOccur due to fail of B cell to differentiation into
plasma cell (Due mutations in ICOS and TACI )
īPatents become susceptible to pyogenic bacteria
and intestinal protozoa.
21. Hyper-IgM Syndrome
īIt condition that characterized with high level of IgM
,but exhibit deficiency in IgG, IgA and IgE
ī Occur due to a defect in the differentiation
(switching) of IgM producing cells to cells producing
other Igs.
ī Defect of switching of IgM are due to defect in gene
encoding CD40L.
ī Treatment with pooled gamma globulin.
23. . Defects in Myeloid progenitor
īļCauses immunodeficiency that effect on non
specific immune system like
īPhagocytes
īNK cells
īComplement
24. Congenital Agranulomatosis
īPatients have a decrease in the neutrophil count.
It is due to a defect in the myeloid progenitor cell
that differentiation into neutrophils.
īThese patients are treated with granulocyte-
macrophage colony stimulating factor (GM-CSF) or
granulocyte colony stimulating factor (G-CSF).
25. Chronic Granulomatous Disease
īDefective production of reactive oxygen species
(ROS) by phagocytes; due to defects in NADPH
oxidase and results in a failure to kill phagocytosed
microbes.
īThis is an autosomal recessive or X-linked trait.
īHave recurrent bacterial and fungal infections.
īTreated with antibiotics/IFN-g against infections.
26. Leukocyte Adhesion Deficiencies
īAre a group of autosomal recessive disorders caused by
defects in leukocyte and endothelial adhesion molecules
like(integrins).
īThese diseases are characterized by a failure of
leukocyte, particularly neutrophil, recruitment to sites
of infection, adhesion to endothelial cells, and rolling
due to mutations in different genes.
īTreated with BM transplantation or with gene therapy.
27. ChÊdiak-Higashi syndrome
īIs a rare autosomal recessive result in defective
phagosome lysosome fusion and lysosomal function
in neutrophils, macrophages, dendritic cells, NK
cells, cytotoxic T cells, and many other cell types;
due to mutation in LYST gene.
28. Complement Deficiencies
īPatients with C3 deficiency are particularly
susceptible to sepsis with pyogenic bacteria
such as S. aureus.
īPatients with deficiencies C6, C7, or C8 (which
form the membrane attack complex) become
susceptible Neisseria meningitidis or Neisseria
gonorrhoeae.
29. Pattern-Recognition Receptor Deficiency
īOccur due to mutations in the genes that encoding
the pattern recognition receptors (PRRs) on the
surface of cells (e.x TLR-5) and within the cells (e.x
RIG,NOD) of the innate immune system result in
susceptibility to severe infections
30. Secondary or Acquired Immunodeficiency
īDeficiencies of the immune system often
develop because of abnormalities that are not
genetic but acquired during life.