Transplantation immunology
2,747 views
51 slides
Dec 02, 2019
Slide 1 of 51
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
About This Presentation
Description of various immunological mechanisms involved in the rejection of transplants. Lecture notes for medical, dental and allied health sciences undergraduate medical students.
Slide Content
Transplantation immunology
Transplantation
❑Graft or Transplant: Transfer of living
cells, tissues and organs from one part
of the body to another or from one
individual to another.
❑Graft or Transplant: Transfer of living
cells, tissues and organs from one part
of the body to another or from one
individual to another.
Types of grafts
•Autologous graft (autograft)–in the same individual: from one site to
another one
•Isogenic (isograft)–between genetically identical individuals
•Allogeneic (allograft or homograft)–between different members of the
same species
•Xenogeneic (xenograft)–between mmbers of different species
•Autologous graft (autograft)–in the same individual: from one site to
another one
•Isogenic (isograft)–between genetically identical individuals
•Allogeneic (allograft or homograft)–between different members of the
same species
•Xenogeneic (xenograft)–between mmbers of different species
Autograft
•The transfer of self tissue from one body site to another in the same
individual
•Due to the genetic homology of the tissue, the immune system does not
respond to it
•Use: synthetic implantation
➢skin grafts
➢bone marrow transplantation
➢hair
•The transfer of self tissue from one body site to another in the same
individual
•Due to the genetic homology of the tissue, the immune system does not
respond to it
•Use: synthetic implantation
➢skin grafts
➢bone marrow transplantation
➢hair
Allograft
•Definition:The transfer of organs or tissue from human to
human.
•Allografting transplantation has many applications.
•Definition:The transfer of organs or tissue from human to
human.
•Allografting transplantation has many applications.
Xenotransplantation
Definition:–the transfer of tissue from one
species to another
Usually refers to the implantation of animal
tissue in humans
➢provides a new source of organs for humans
➢many different types of tissue can be
transplanted:
e.g. heart, kidney, liver or lung
Definition:–the transfer of tissue from one
species to another
Usually refers to the implantation of animal
tissue in humans
➢provides a new source of organs for humans
➢many different types of tissue can be
transplanted:
e.g. heart, kidney, liver or lung
Immunological basis of graft rejection
Transplantation antigens
•Major histocompatibility antigens (MHC molecules)
•Minor histocompatibility antigens
•Other alloantigens
•Major histocompatibility antigens (MHC molecules)
•Minor histocompatibility antigens
•Other alloantigens
Histocompatibility Complex (MHC)
–gene complex whose alleles encode polymorphic cell surface
glycoproteins
–nomenclature
•HLA: human leukocyte antigen
•SLA: porcine leukocyte antigen
•H-2: mouse MHC
•RT1: rat MHC
–gene complex whose alleles encode polymorphic cell surface
glycoproteins
–nomenclature
•HLA: human leukocyte antigen
•SLA: porcine leukocyte antigen
•H-2: mouse MHC
•RT1: rat MHC
Major histocompatibility antigens
•Main antigens of grafts rejection
•Cause fast and strong rejection
•Difference of HLA types is the main cause of human grafts
rejection
•Main antigens of grafts rejection
•Cause fast and strong rejection
•Difference of HLA types is the main cause of human grafts
rejection
Major Histocompatibility Complex
(MHC):
–Class Iantigens: constitutively expressed on
surface of most cells
–Class IIantigens: expressed on cells of
lymphoid system
–Expression of MHC molecules can be
upregulated by ischemia, etc.
–nomenclature
•HLA (human) class I: A, B, C; class II: DR, DQ
•H-2 (mouse) class I: K, D, L; class II: IA, IE
(MHC):
–Class Iantigens: constitutively expressed on
surface of most cells
–Class IIantigens: expressed on cells of
lymphoid system
–Expression of MHC molecules can be
upregulated by ischemia, etc.
–nomenclature
•HLA (human) class I: A, B, C; class II: DR, DQ
•H-2 (mouse) class I: K, D, L; class II: IA, IE
Short arm of Chromosome 6
Comparing MHC Class I and II
PropertiesClass I Class II
ANTIGENS HLA-A, B, C HLA-D-DR/Q/P
TISSUE On virtually B-cell, dendritic
DISTRIBUTIONall cellscell, macrophage
FUNCTIONS Endogenous Ag Exogenous Ag
presented to CD8presented to
(cytotoxic) T-cellsCD4 (T-helpers)
PropertiesClass I Class II
ANTIGENS HLA-A, B, C HLA-D-DR/Q/P
TISSUE On virtually B-cell, dendritic
DISTRIBUTIONall cellscell, macrophage
FUNCTIONS Endogenous Ag Exogenous Ag
presented to CD8presented to
(cytotoxic) T-cellsCD4 (T-helpers)
Minor histocompatibility antigens
•Also cause grafts rejection, but slow and weak
•Mouse H-Y antigens encoded by Y chromosome
•HA-1~HA-5 linked with non-Y chromosome
•Also cause grafts rejection, but slow and weak
•Mouse H-Y antigens encoded by Y chromosome
•HA-1~HA-5 linked with non-Y chromosome
Other alloantigens
•Human ABO blood group antigens
•Some tissue specific antigens
•Human ABO blood group antigens
•Some tissue specific antigens
•Cell-mediated Immunity
•Humoral Immunity
•Role of NK cells
Mechanism of allograft rejection
•Humoral Immunity
•Role of NK cells
Mechanism of allograft rejection
Cell-mediated Immunity
•Recipient's T cell-mediated cellular immune response against
alloantigenson grafts
•Recipient's T cell-mediated cellular immune response against
alloantigenson grafts
Features of CMI
•Slow and weak
•Late phase of acute rejection and chronic rejection
•Coordinated function with direct recognition in early
phase of acute rejection
•Slow and weak
•Late phase of acute rejection and chronic rejection
•Coordinated function with direct recognition in early
phase of acute rejection
•Important role in hyperacute rejection
(Preformed antibodies)
–Complements activation
–ADCC
–Opsonization
Humoral immunity
(Preformed antibodies)
–Complements activation
–ADCC
–Opsonization
Humoral immunity
Role of NK cells
•Cytokines secreted by activated Th cells can promote NK
activation
•Cytokines secreted by activated Th cells can promote NK
activation
•Host versus graft reaction (HVGR)
–Conventional organ transplantation
•Graft versus host reaction (GVHR)
–Bone marrow transplantation
–Immune cells transplantation
Classification of Allograft Rejection
–Conventional organ transplantation
•Graft versus host reaction (GVHR)
–Bone marrow transplantation
–Immune cells transplantation
Classification of Allograft Rejection
Host versus graft reaction (HVGR)
•Hyperacute rejection
•Acute rejection
•Chronic rejection
•Hyperacute rejection
•Acute rejection
•Chronic rejection
•Occurrence time
–Occurs within minutes to hours after host blood
vessels are anastomosed to graft vessels
Hyperacute rejection
–Occurs within minutes to hours after host blood
vessels are anastomosed to graft vessels
Hyperacute rejection
•Mechanisms
–Preformed antibodies
•Antibody against ABO blood type antigen
•Antibody against HLA antigen
–Preformed antibodies
•Antibody against ABO blood type antigen
•Antibody against HLA antigen
•Occurrence time
–Occurs within days to 2 weeks after
transplantation, 80-90% of cases occur within 1
month
Acute rejection
–Occurs within days to 2 weeks after
transplantation, 80-90% of cases occur within 1
month
Acute rejection
•Mechanisms
–Vasculitis
•IgG antibodies against alloantigenson endothelial cell
–Parenchymal cell damage
•Delayed hypersensitivity mediated by CD4+Th1
•Killing of graft cells by CD8+Tc
–Vasculitis
•IgG antibodies against alloantigenson endothelial cell
–Parenchymal cell damage
•Delayed hypersensitivity mediated by CD4+Th1
•Killing of graft cells by CD8+Tc
•Occurrence time
–Develops months or years after acute rejection
reactions have subsided
Chronic rejection
–Develops months or years after acute rejection
reactions have subsided
Chronic rejection
•Mechanisms
–Not clear
–Extension and results of cell necrosis in acute rejection
–Chronic inflammation mediated by CD4+T cell/activated
macrophages
–Organ degeneration induced by non immune factors
–Not clear
–Extension and results of cell necrosis in acute rejection
–Chronic inflammation mediated by CD4+T cell/activated
macrophages
–Organ degeneration induced by non immune factors
Graft versus host reaction (GVHR)
•Graft versus host reaction (GVHR)
–Allogeneticbone marrow transplantation
–Rejection to host alloantigens
–Mediated by immune competent cells in bone marrow
•Graft versus host disease (GVHD)
–A disease caused by GVHR, which can damage the host
•Graft versus host reaction (GVHR)
–Allogeneticbone marrow transplantation
–Rejection to host alloantigens
–Mediated by immune competent cells in bone marrow
•Graft versus host disease (GVHD)
–A disease caused by GVHR, which can damage the host
Graft versus host disease
Conditions
•Enough immune competent cells in grafts
•Immunocompromised host
•Histocompatabilitydifferences between host and
graft
•Enough immune competent cells in grafts
•Immunocompromised host
•Histocompatabilitydifferences between host and
graft
•Bone marrow transplantation
•Thymus transplantation
•Spleen transplantation
•Thymus transplantation
•Spleen transplantation
Acute GVHD
•Endothelial cell death in the skin, liver, and
gastrointestinal tract
•Rash, jaundice, diarrhea, gastrointestinal
hemorrhage
•Mediated by mature T cells in the grafts
•Endothelial cell death in the skin, liver, and
gastrointestinal tract
•Rash, jaundice, diarrhea, gastrointestinal
hemorrhage
•Mediated by mature T cells in the grafts
•Acute graft-versus-host reaction with
vivid palmar erythema
vivid palmar erythema
Chronic GVHD
•Fibrosis and atrophy of one or more of the organs
•Eventually complete dysfunction of the affected organ
•Fibrosis and atrophy of one or more of the organs
•Eventually complete dysfunction of the affected organ
Both acute and chronic GVHD are commonly
treated with intense immuno-suppresion
•Uncertain
•Fatal
treated with intense immuno-suppresion
•Uncertain
•Fatal
Tissue matching
•ABO and Rh blood typing
•Crossmatching (Preformed antibodies)
•HLA typing
–HLA-A and HLA-B
–HLA-DR
–Microcytoxicityassay
•ABO and Rh blood typing
•Crossmatching (Preformed antibodies)
•HLA typing
–HLA-A and HLA-B
–HLA-DR
–Microcytoxicityassay
•Microcytoxicity assay for
MHC haplotypes
•If antigen is present on
cell, complement will
lyse it, and it will uptake
dye (blue)
•Donor 1 has antigens in
common with recepient
MHC haplotypes
•If antigen is present on
cell, complement will
lyse it, and it will uptake
dye (blue)
•Donor 1 has antigens in
common with recepient
Mixed Lymphocyte Reaction:
DonorRecipient
(Irradiate) Cell Proliferation
❑Strong Proliferation--->High incompatibility
❑Weak proliferation--->Low incompatibility
❑No proliferation---> 100% compatibility
❑Helps to identify any antigenic differences between
donor and recipient
+
DonorRecipient
(Irradiate) Cell Proliferation
❑Strong Proliferation--->High incompatibility
❑Weak proliferation--->Low incompatibility
❑No proliferation---> 100% compatibility
❑Helps to identify any antigenic differences between
donor and recipient
+
Immunosuppressive Therapy
•Cyclosporine
–Inhibit NFAT transcription factor
•Azathioprine, Cyclophosphamide
–Block the proliferation of lymphocytes
•Ab against T cell surface molecules
–Anti-CD3 monoclonal Ab----Deplete T cells
•Anti-inflammatory agents
–Corticosteroids----Block the synthesis and secretion
of cytokines
•Cyclosporine
–Inhibit NFAT transcription factor
•Azathioprine, Cyclophosphamide
–Block the proliferation of lymphocytes
•Ab against T cell surface molecules
–Anti-CD3 monoclonal Ab----Deplete T cells
•Anti-inflammatory agents
–Corticosteroids----Block the synthesis and secretion
of cytokines
Monoclonal antibodies
•an antibody produced by a single clone of cells or cell line and
consisting of identical antibody molecules.
•an antibody produced by a single clone of cells or cell line and
consisting of identical antibody molecules.
Producing Monoclonal Antibodies
1.Inject a mouse with a specific antigen to stimulate its immune
system to produce necessary antibodies.
2.Extract mouse spleen cells (containing B-lymphocytes) and
culture them in the lab.
3.Extract mouse tumour cells, which grow continuously, and
culture them in the lab.
4.Mix spleen cells and tumour cells on the same plate and
culture.
1.Inject a mouse with a specific antigen to stimulate its immune
system to produce necessary antibodies.
2.Extract mouse spleen cells (containing B-lymphocytes) and
culture them in the lab.
3.Extract mouse tumour cells, which grow continuously, and
culture them in the lab.
4.Mix spleen cells and tumour cells on the same plate and
culture.
Producing Monoclonal Antibodies
5.Add polyethylene glycol –this causes some B-lymphocytes to fuse
with tumour cells to produce a hybrid cell called a hybridoma.
6.Grow the cells under conditions that allow only hybridoma cells to
survive.
7.Extract the cells, culture them separately and test the medium
around each cell for the specific antibody of interest.
8.Culture the cells making the desired antibody and use as needed.
5.Add polyethylene glycol –this causes some B-lymphocytes to fuse
with tumour cells to produce a hybrid cell called a hybridoma.
6.Grow the cells under conditions that allow only hybridoma cells to
survive.
7.Extract the cells, culture them separately and test the medium
around each cell for the specific antibody of interest.
8.Culture the cells making the desired antibody and use as needed.
Categories
HealthcareDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 2,747
- Slides 51
- Favorites 5
- Age 2193 days
Related Slideshows
36
Clinical approach Dyspnoea A simple and practical approach.pptx
ShajahanPS
25 views
238
Cancer Awareness therapy for public by Dr Kanhu Charan Patro
kanhucpatro
25 views
41
Prof Satyadas Memorial oration Kozhikode.pptx
ShajahanPS
20 views
26
Viral Conjunctivitis and it;s managment.pptx
ZaidAzhar
34 views
30
Essential Thrombocythemia 15 Years of Experience at the Hematology Department, Algies, Algeria.pdf
sbelakehal
30 views
10
Hypertension sign symptoms cmdt style with regime
androiddabest
31 views