tests in organ transplantation

Post on 11-May-2015

753 Views

Category:

Health & Medicine

0 Downloads

Preview:

Click to see full reader

TRANSCRIPT

Relevant tests in organ transplantation

• Human MHC Gene Locus• Human MHC Gene Locus

CLASS 1

Encodes glycoproteins expressed on surface of nearly all nucleated cells and platelets

Main function is presentation of antigen to cytotoxic T cells

Encoded by 3 closely linked loci – HLA A,B,C

CLASS II

Designated as HLA D

Expressed on macrophages , B lymphocytes, activated T cell

Specialised in processing & presenting extracellular antigens to T lymphocytes

CLASS III

Diverse group of molecules with variety of functions

Include complement proteins responsible for immune response , inflammatory cytokines , TNF , HSP

1

3

2

MHC-encoded -chain of 56kDa

Structure of MHC class I molecules

2m

- heavy chain anchored to the cell membrane

Beta 2 microglobulin light chain encoded by chr 15 ; 12kDa , non-MHC encoded , non-transmembrane, non covalently bound to -chain

Extramembranous portion of chain – 3 domainsAlpha 1 & 2 - confer antigen specificityAlpha 3 attaches to cytotoxic T cell

2

1

Molecular wt of 63kD

Consists of 2 dissimilar Gp chains alpha & beta ; both which traverse the membrane

2

1

Structure of MHC class II molecules

Extramembranous portion of each chain has 2 amino acid domains

No b-2 microglobulin

Biologic Function

• Self –nonself discrimination

• Interaction of T lymphocytes with peptide antigens

• T lymphocytes interact with the peptide antigen only when the TCR for antigen engages both the HLA molecule & the antigenic peptide

• This limitation is “MHC RESTRICTION”

Tissue/Organ Transplantation • Represents one of the most challenging goals in medical science.

• Renal transplantation is the therapy of choice for most patients with end-stage renal disease.

• Hematopoietic progenitor cell, heart, lung, liver, and pancreas transplantation is gaining wide acceptance as a therapeutic procedure with successful outcomes.

• The primary obstacle is immunologically mediated rejection of the foreign tissue.

• Allograft Rejection• Allograft Rejection

Type:

Hyperacute

Accelerated

Acute

Chronic

Type:

Hyperacute

Accelerated

Acute

Chronic

Time:

0-48 hrs

5-7 days

Early/delayed

>60 daysImmuneNon-immune

Time:

0-48 hrs

5-7 days

Early/delayed

>60 daysImmuneNon-immune

Mediated by:

Abs

Abs/cells

Cells/Abs

Abs/cellsTrauma

Mediated by:

Abs

Abs/cells

Cells/Abs

Abs/cellsTrauma

• Transplant Considerations:

• ABO compatibility

• Matching for HLA

• Pre-sensitization

• Transplant Considerations:

• ABO compatibility

• Matching for HLA

• Pre-sensitization

• Histocompatibility Systems:

• 1) ABO – Red blood cells

• 2) HLA – White blood cells

and most body cells

• Histo (tissue) Compatibility

• Histocompatibility Systems:

• 1) ABO – Red blood cells

• 2) HLA – White blood cells

and most body cells

• Histo (tissue) Compatibility

• HLA Ab Sensitization• HLA Ab Sensitization

Pregnancy

Blood transfusions

Failed allograft

Some types of bacterial infections

Pregnancy

Blood transfusions

Failed allograft

Some types of bacterial infections

Types of solid organ transplants:KidneyLiverHeart LungPancreasIntestine

Deceased donors (D-D): formerly cadaveric donors (CAD)

Living donors: Living related donors (LRD) Living unrelated donors

(LURD)

Types of solid organ transplants:KidneyLiverHeart LungPancreasIntestine

Deceased donors (D-D): formerly cadaveric donors (CAD)

Living donors: Living related donors (LRD) Living unrelated donors

(LURD)

• Blood Transfusion Success• Blood Transfusion Success

Yes

No

Yes

No

A

B

AB

O

A

B

AB

O

Recipient:Recipient:Donor:Donor:

A

• Success of allografting may be accomplished by – (1) histocompatibility matching between the

donor and the recipient; – (2) immunosuppressive therapy of the recipient

and – (3) ultimately achieving specific unresponsiveness

to donor alloantigen

GENETIC BASIS OF TRANSPLANTATION

• The genetic basis of transplantation was first determined in 1916 as a result of tumor transplantation experiments in mice and was subsequently extended to transplants of normal tissue

12-08

HISTOCOMPATIBILITY MATCHING

• HLA Matching– DNA based typing

• Sequence specific priming• Sequence specific oligonucleotide hybridization• Sequence specific conformational polymorphism/ heteroduplex analysis• Nucleic acid sequencing

– Serological detection– Cellular detection

• HLA- Specific Ab detection in Recipient serum– Serum screening – Donor specific cross matching

HLA Matching• Histocompatibility matching is different in different

settings, and strategies for matching vary. Criteria differ with variables that include:– type of graft (e.g., solid vascularized organ vs.

hematopoietic progenitor cell)– the disease (e.g., chronic myelogenous leukemia vs.

aplastic anemia)– the age of the patient– the clinical protocol (e.g., marrow vs. umbilical cord

blood; T cell depletion of marrow vs. non–T cell depletion)

• Matching usually includes evaluation of at least three loci: HLA-A, HLA-B, and HLA-DR.

– Zero mismatches (a term used in solid organ transplantation) refer to donor/recipient pairs where the donor has no detectable HLA differences from the recipient

Techniques for Identifying HLA Polymorphism

• Uses specialized procedures and reagents.

• Commercially available kits can be obtained for both DNA-based and serologic testing

• Interpretation of the test results requires considerable experience and knowledge

1.DNA-BASED TYPING OF CLASS I AND CLASS II ALLELES

• With the advent of rapid and reliable methods for the isolation and characterization of class I and II genes and the determination of nucleotide sequences of class I and II alleles

• DNA-based typing of HLA alleles is now a commonly used technique

• 1. It is specific. – The specificity of each DNA typing reagent (i.e.,

synthetic oligonucleotide primers and probes) is clearly defined and is based on a specific, known nucleotide sequence

• 2. It is flexible. – New reagents can be designed as new alleles are

discovered and unique nucleotide sequences identified

• 3. Robust than other techniques. – Does not require viable lymphocytes and is not influenced by the

health of the patient– highly reproducible

• 4. Used for large-scale typing– facilitated by automated and computerized methods reduces cost and

errors. – Applicable for the HLA typing of large numbers of volunteers for donor

registries.

• 5. It can discriminate by detecting the full extent of HLA diversity.

Preparation and Amplification of DNA

• Any cell with a nucleus can be used as a source of DNA. – lymphocytes, are a good source of DNA.– Cell lines such as Epstein-Barr virus– transformed

B lymphocytes are also a good source of DNA. • transformed cells can be grown in culture in the

laboratory, provide replenishable supply of DNA and used for quality control of typing procedures.

• DNA is usually prepared from a small quantity (0.2–1 mL) of whole blood.

• Many different protocols can be used to isolate DNA from cells, and commercial kits are available for the preparation of DNA.

• The sensitivity of detection of HLA types is enhanced greatly by the amplification of DNA-encoding HLA genes using the PCR technique

• Sequence-specific Primer (PCR-SSP)• Sequence-specific Primer (PCR-SSP)

The SSP utilizes DNA primers that are specific for individual or similar groups of Class II alleles.

The primers are used with PCR to amplify relevant genomic DNA

The SSP utilizes DNA primers that are specific for individual or similar groups of Class II alleles.

The primers are used with PCR to amplify relevant genomic DNA

• Sequence-specific Oligonucleotide Probes (PCR-SSOP)

• Sequence-specific Oligonucleotide Probes (PCR-SSOP)

Uses locus-specific or group-specific primers to amplify the desired genomic DNA.

This is followed by application of a labeled oligonucleotide probe that binds to an allele-specific sequence.

Highly accurate, specific and reliable

Uses locus-specific or group-specific primers to amplify the desired genomic DNA.

This is followed by application of a labeled oligonucleotide probe that binds to an allele-specific sequence.

Highly accurate, specific and reliable

Sequence-Specific Conformational Polymorphism or Heteroduplex Analysis

• Analyzes the mobility of amplified DNA, either denatured or as a renatured DNA duplex, following electrophoresis

• The mobility of the DNA is compared with the mobility of amplified DNA from known HLA alleles to define an HLA allele.

• Useful in typing a small number of samples, particularly in comparisons between individuals

Nucleic Acid Sequencing

• Involves direct determination of the DNA sequences of the HLA alleles carried by an individual (sequence-based typing [SBT]).

• Identified following PCR amplification to separate the alleles based on SSPs, or as a mixture of two alleles.

• Sequencing is labor-intensive and highly complex

• Determine the HLA match at an allele level between hematopoietic progenitor cell transplant patients and their prospective

• Efforts to develop automated SBT methods have yielded several potentially promising high-throughput approaches.

– Denaturing high-performance liquid chromatography (HPLC)

– Pyrosequencing technique• real-time, nonelectrophoretic DNA sequencing method

that uses luciferase–luciferin light emission as a detection signal as nucleotides are incorporated into target DNA.

2.SEROLOGIC DETECTION OF CLASS I AND CLASS II MOLECULES

• Lymphocyte microcytotoxicity

• Reproducible under controlled, standardized conditions

• Large-scale testing (e.g., for registries),

• Error rates may increase

• Fairly widely for class I specificities (HLA-A, -B) but has been supplanted by DNA-based testing for HLA-C and for class II specificities (HLA-DR, -DQ, -DP) in most typing laboratories.

Lymphocyte Preparation

• Obtained from peripheral whole blood by layering onto a Ficoll-Hypaque gradient to separate the blood cells by density centrifugation.

• (PBLs) can be used for HLA-A, -B, -C typing.

• To test for HLA-DR, -DQ serologic specificities, – it is necessary to enrich for B lymphocytes, or – to use a special two-color fluorescent technique

• Done to simultaneously differentiate between unseparated B cells and T cells.

Lymphocyte Microcytotoxicity Assay

• Determined by testing– the unseparated lymphocyte preparation (PBL) – or T lymphocytes (for HLA-A, -B, -C) or – the enriched B lymphocytes (for HLA-DR, -DQ)

• against a panel of well-characterized HLA alloantisera.

• The assay is a two-stage test.

• Reactions are read for percentage lysis and are numerically graded.

3.CELLULAR DETECTION OF CLASS II MOLECULES

• The response of one cell in tissue culture to the alloantigens on the surface of a second cell is called the mixed leukocyte culture or mixed lymphocyte reaction

• The MLC is considered an in vitro measure of class II disparity between individuals that recognizes determinants found on class II molecules, which are known collectively as HLA-D.

• Use of the MLC has declined because of limitations inherent in the technique– influenced by the health of the patient, the type of disease

• MLC is used to identify renal allograft recipients with specific hyporeactivity to donor HLA molecules following transplantation as a guideline for tapering of immunosuppression

• HLA Matching– DNA based typing

• Sequence specific priming• Sequence specific oligonucleotide hybridization• Sequence specific conformational polymorphism/ heteroduplex analysis• Nucleic acid sequencing

– Serological detection– Cellular detection

• HLA- Specific Ab detection in Recipient serum– Serum screening – Donor specific cross matching

HLA-Specific Antibody Detection in Recipient Serum

• At the time of transplantation, the recipient serum is tested with the prospective donor lymphocytes to identify specific reactivity to the potential donor in the donor-specific crossmatch.

• To measure panel reactive antibody (PRA).

• Binding of antibody in the serum of the recipient to the T lymphocytes of the donor is a contraindication to renal transplantation.

Serum Screening (PRA) • The goals of a PRA screen are as follows:

• 1. To identify the level of presensitization of the patient to HLA antigens

• 2. To identify the HLA specificity of the antibodies to predict the HLA antigen(s) to be avoided when donors are selected.

• 3. To identify patients with irrelevant antibodies (e.g., immunoglobulin [Ig]M autoantibodies) – to avoid false-positive readings at the time of the donor-specific

crossmatch.

• Crossmatch• Crossmatch

Recipient serum + Donor cells = RXNRecipient serum + Donor cells = RXN

Donor-Specific Crossmatch

• In the crossmatch test, the lymphocyte is the target cell of choice because it expresses high levels of HLA molecules and is easy to isolate.

• This test is probably the most important contribution of the HLA tissue typing laboratory to clinical renal transplantation

• The purpose of the crossmatch is to detect clinically relevant IgG anti-donor antibodies to prevent hyperacute, accelerated or chronic rejection.

• The purpose of the crossmatch is to detect clinically relevant IgG anti-donor antibodies to prevent hyperacute, accelerated or chronic rejection.

Antibody Detection Techniques

• Direct Complement-Dependent Cytotoxicity

• Indirect Crossmatch Techniques

Direct Complement-Dependent Cytotoxicity

• Includes all assays that use the addition of complement to detect the direct binding of antibody to lymphocytes.

• Fixation of complement by the antibody–antigen complexes on the cell surface results in cell death or cytotoxicity..

• Advantages – reproducible, – correlation with the incidence of hyperacute rejection is excellent.

Indirect Crossmatch Techniques

• Include the anti-globulin augmented lymphocytotoxicity assay technique (anti-human globulin cytotoxicity assay) and flow cytometry.

• Advantages of the flow cytometry assay include – discrimination of the subclass of the cell-bound

immunoglobulin (IgG vs. IgM) and – characterization of the target cell binding the

alloantibody (T lymphocyte vs. B lymphocyte vs. monocyte).

Autoantibodies

• The presence of circulating autoantibodies in the recipient is not known to be deleterious.

• If autoantibodies are present, the sera used for donor crossmatching should have the autoreactivity removed.

• Autoantibodies are primarily IgM, and HLA-specific antibodies are primarily IgG

B Cell Antibodies

• A crossmatch using donor B lymphocytes (B cell crossmatch) may be performed in sensitized patient

• A positive donor-specific B cell crossmatch is not a contraindication to transplantation.

• The clinical significance has not been resolved, but a positive test may be a risk factor, particularly in patients who have previously been transplanted.

Selection of Recipient Serum Samples for Donor Crossmatch

• No detectable sensitization (i.e., 0% PRA), – the most recent serum sample available can be

used for the donor-specific crossmatch.

• Preexisting antibodies or has had a recent sensitizing event, – a current serum sample (i.e., within 48 hours of

transplantation) should be collected.

RENAL TRANSPLANTATION

• Current practice is to select donors for recipients who are ABO compatible, T cell, donor specific, crossmatch negative with appropriate recipient sera and the best available HLA match.

NONRENAL ORGAN TRANSPLANTATION

• Survival of heart, liver, lung, and pancreas grafts is good

• Donors usually are not matched for HLA type, and a pretransplant donor crossmatch is not routinely performed.

• Serum antibody screens are recommended to identify the state of sensitization as an immunologic risk factor for the recipient

• Recent international CTS data show no effect of HLA matching on outcomes of liver transplantation; however, the CTS data do show a significant impact of matching for HLA-A, -B, and -DR on outcomes of first heart transplants

ALLOGENEIC HEMATOPOIETIC PROGENITOR CELL TRANSPLANTATION

• Performed for – hematologic malignancies and disorders,– bone marrow failure, – certain inherited metabolic disorders such as lipid

storage diseases, – and congenital immunodeficiency syndrome

• From a histocompatibility standpoint, the best donor is either self (autogeneic transplant), if the malignancy is not one that involves the bone marrow or the disease is not genetic, or an identical twin (syngeneic transplant)

• Progenitor cells from an HLA-identical sibling donor are a frequent source.

• Hematopoietic progenitor cell grafts are among the most difficult of all clinical procedures for several reasons

– First, at the time of transplantation, the recipients are nearly totally immunodeficient, • inherited deficiency (severe combined immunodeficiency) or • pretransplantation conditioning (cytotoxic chemotherapy and

irradiation)

– second risk is the potential for immunologic attack of the recipient by the transplanted allogeneic progenitor cells, resulting in GVHD.

HLA Typing for Progenitor Cell Transplantation

• The pretransplantation workup includes

– HLA-A, -B, and -DR typing of all available members of the immediate family • to identify a matched related donor and • to establish inheritance of haplotypes.

– DNA-based typing for class II genes has become standard, and DNA-based typing for class I genes has been implemented in many centers.

Other typings/tests done

• Typing of the extended family

• Allele-level (i.e., high-resolution) typing of specific HLA class I and class II loci

• Typing of other loci within the MHC (i.e., short tandem repeats or complement loci)

• Crossmatching, cytotoxic T cell precursor measurements

Thank you !!

top related