Histocompatibility

The discovery of the MHC and role of histocompatibility in transplantation was a combined effort of many scientists in the 20th century. A genetic basis for transplantation rejection was proposed in a 1914 Nature paper by C.C. Little and Ernest Tyyzer, which showed that tumors transplanted between genetically identical mice grew normally, but tumors transplanted between non-identical mice were rejected and failed to grow. The role of the immune system in transplant reject was proposed by Peter Medawar, whose skin graft transplants in World War II victims showed that skin transplants between individuals had much higher rejection rates than self-transplants within an individual, and that suppressing the immune system delayed skin transplant rejection. Medawar shared the 1960 Nobel Prize in part for this work. In the 1930s and 1940s, George Snell and Peter Gorer individually isolated the genetic factors that when similar allowed transplantation between mouse strains, naming them H and antigen II respectively. These factors were in fact one and the same, and the locus was named H-2. Snell coined the term "histocompatibility" to describe the relationship between the H-2 cell-surface proteins and transplant acceptance. The human version of the histocompatibility complex was found by Jean Dausset in the 1950s, when he noticed that recipients of blood transfusions were producing antibodies directed against only the donor cells. The target of these antibodies, or the human leukocyte antigens (HLA), were discovered to be the human homologue of Snell and Gorer's mouse MHC. Snell, Dausset and Baruj Benacerraf shared the 1980 Nobel Prize for the discovery of the MHC and HLA. == Major histocompatibility complex (MHC) ==

HLA, the human form of the major histocompatibility complex (MHC), is located on chromosome 6 at 6p21.3. Individuals inherit two different HLA haplotypes, one from each parent, each containing more than 200 genes relevant to helping the immune system recognize foreign invaders. These genes include MHC class I and class II cell-surface proteins. MHC Class I molecules—HLA-A, HLA-B, and HLA-C—are present on all nucleated cells and are responsible for signaling to an immune cell that an antigen is inside the cell. The MHC genes are highly polymorphic, with thousands of versions of the MHC receptors in the population, though any one individual can have no more than two versions for any one locus. MHC receptors are codominantly expressed, meaning all inherited alleles are expressed by the individual. The wide variety of potential alleles and multiple loci in the HLA allow for many unique combinations in individuals. == Role in transplantation ==

After receiving a transplant, the recipient's T cells will become activated by foreign MHC molecules on the donor tissue and trigger the immune system to attack the donated tissue The number and selection of MHC molecules to be considered when determining whether two individuals are histocompatible fluctuates based on application, however matching HLA-A, HLA-B, and HLA-DR has been shown to improve patient outcomes. Histocompatibility has a measurable effect on whole organ transplantation, increasing life expectancy of both the patient and organ. The degree of histocompatibility required is dependent on individual factors, including the type of tissue or organ and the medical condition of the recipient. While whole organ transplants can be successful between unmatched individuals, increased histocompatibility lowers rates of rejection, result in longer lifespans, and overall lower associated hospital costs. The impact of HLA matching differs even among whole organ transplants, with some studies reporting less importance in liver transplants as compared to heart, lung, and other organs. Some transplanted tissue is not exposed to T cells that could detect foreign MHC molecules, such as corneas, and thus histocompatibility is not a factor in transplantation. Individual factors such as age sometimes factors into matching protocol, as the immune response of older transplant patients towards MHC proteins is slower and therefore less compatibility is necessary for positive results. Post-operative immunosuppressant therapy is often used to lessen the immune response and prevent tissue rejection by dampening the immune system's response to the foreign HLA molecules, and can increase the likelihood of successful transplantation in non-identical transplant recipients. == Testing ==

Because of the clinical significance of histocompatibility in tissue transplants, several methods of typing are used to check for HLA allele expression. Serological Typing Serological typing involves incubating lymphocytes from the recipient with serum containing known antibodies against the varying HLA alleles. If the serum contains an antibody specific for a HLA allele that is present on the recipient's lymphocyte, the antibodies will bind to the cell and activate a complement signaling cascade resulting in cell lysis. A lysed cell will take up an added dye such as trypan blue allowing for identification. Comparing which serums triggers cell lysis allows identification of HLA alleles present on the cell surface of the recipients cells. Serological typing has the benefit of quickly identifying expressed HLA alleles, and ignores any non-expressed alleles that could be of little immunological significance. However, it does not recognize subclasses of alleles, which are sometimes necessary for matching. Molecular Typing HLA alleles can be determined by directly analyzing the HLA loci on chromosome 6. Sequence specific oligonucleotide probes, sequence specific primer PCR amplification, and direct sequencing can all be used to identify HLA alleles, often providing amino acid level resolution. Molecular methods can more accurately identify rare and unique alleles, but do not provide information about expression levels. == See also ==