complexed with
MHC-I and
MHC-II MHC class I MHC class I molecules are expressed in all
nucleated cells and also in
platelets—in essence all cells but
red blood cells. It presents epitopes to killer
T cells, also called
cytotoxic T lymphocytes (CTLs). A CTL expresses CD8 receptors, in addition to
T-cell receptors (TCRs). When a CTL's CD8 receptor docks to a MHC class I molecule, if the CTL's TCR fits the epitope within the MHC class I molecule, the CTL triggers the cell to undergo programmed cell death by
apoptosis. Thus, MHC class I helps mediate
cellular immunity, a primary means to address
intracellular pathogens, such as
viruses and some
bacteria, including bacterial
L forms, bacterial
genus Mycoplasma, and bacterial genus
Rickettsia. In humans, MHC class I comprises
HLA-A,
HLA-B, and
HLA-C molecules. The first crystal structure of Class I MHC molecule, human HLA-A2, was published in 1989. The structure revealed that MHC-I molecules are
heterodimers. They have a polymorphic heavy α-subunit whose gene occurs inside the MHC locus and small invariant
β2 microglobulin subunit whose gene is usually located outside of it. Polymorphic heavy chain of MHC-I molecule contains N-terminal extra-cellular region composed by three domains, α1, α2, and α3, transmembrane helix to hold MHC-I molecule on the cell surface and short cytoplasmic tail. Two domains, α1 and α2, form deep peptide-binding groove between two long α-helices and the floor of the groove formed by eight β-strands. Immunoglobulin-like domain α3 involved in the interaction with
CD8 co-receptor.
β2 microglobulin provides stability of the complex and participates in the recognition of peptide-MHC class I complex by
CD8 co-receptor. The peptide is non-covalently bound to MHC-I, it is held by the several pockets on the floor of the
peptide-binding groove. Amino acid side-chains that are most polymorphic in human alleles fill the central and widest portion of the binding groove, while conserved side-chains are clustered at the narrower ends of the groove.
Classical MHC molecules present epitopes to the TCRs of CD8+ T lymphocytes.
Nonclassical molecules (MHC class IB) exhibit limited polymorphism, expression patterns, and presented antigens; this group is subdivided into a group encoded within MHC loci (e.g., HLA-E, -F, -G), as well as those not (e.g.,
stress ligands such as ULBPs, Rae1, and H60); the antigen/ligand for many of these molecules remain unknown, but they can interact with each of CD8+ T cells, NKT cells, and NK cells. The oldest evolutionary nonclassical MHC class I lineage in humans was deduced to be the lineage that includes the CD1 and PROCR (also known as
EPCR) molecules. This lineage may have been established before the origin of tetrapod species. However, the only nonclassical MHC class I lineage for which evidence exists that it was established before the evolutionary separation of Actinopterygii (ray-finned fish) and Sarcopterygii (lobe-finned fish plus tetrapods) is lineage Z of which members are found, together in each species with classical MHC class I, in lungfish and throughout ray-finned fishes; why the Z lineage was well conserved in ray-finned fish but lost in tetrapods is not understood.
MHC class II MHC class II can be conditionally expressed by all cell types, but normally occurs only on "professional"
antigen-presenting cells (APCs):
macrophages,
B cells, and especially
dendritic cells (DCs). An APC takes up an
antigenic protein, performs
antigen processing, and returns a molecular fraction of it—a fraction termed the
epitope—and displays it on the APC's surface coupled within an MHC class II molecule (
antigen presentation). On the cell's surface, the epitope can be recognized by immunologic structures like
T-cell receptors (TCRs). The molecular region which binds to the epitope is the
paratope. On surfaces of helper T cells are CD4 receptors, as well as TCRs. When a naive helper T cell's CD4 molecule docks to an APC's MHC class II molecule, its TCR can meet and bind the epitope coupled within the MHC class II. This event primes the
naive T cell. According to the local milieu, that is, the balance of
cytokines secreted by APCs in the microenvironment, the naive
helper T cell (Th0) polarizes into either a memory Th cell or an effector Th cell of
phenotype either type 1 (Th1), type 2 (Th2), type 17 (Th17), or regulatory/suppressor (Treg), as so far identified, the Th cell's terminal differentiation. MHC class II thus mediates immunization to—or, if APCs polarize Th0 cells principally to Treg cells,
immune tolerance of—an
antigen. The polarization during primary exposure to an antigen is key in determining a number of
chronic diseases, such as
inflammatory bowel diseases and
asthma, by skewing the immune response that memory Th cells coordinate when their memory recall is triggered upon secondary exposure to similar antigens. B cells express MHC class II to present antigens to Th0, but when their
B cell receptors bind matching epitopes, interactions which are not mediated by MHC, these
activated B cells secrete soluble immunoglobulins:
antibody molecules mediating
humoral immunity. Class II MHC molecules are also heterodimers, genes for both α and β subunits are polymorphic and located within MHC class II subregion. The peptide-binding groove of MHC-II molecules is formed by the N-terminal domains of both subunits of the heterodimer, α1 and β1, unlike MHC-I molecules, where two domains of the same chain are involved. In addition, both subunits of MHC-II contain transmembrane helix and immunoglobulin domains α2 or β2 that can be recognized by
CD4 co-receptors. In this way, MHC molecules guide the type of lymphocytes that may bind to the given antigen with high affinity, as different lymphocytes express different T-Cell Receptor (TCR) co-receptors. MHC class II molecules in humans have five to six
isotypes.
Classical molecules present peptides to CD4+ lymphocytes.
Nonclassical molecules, also known as accessories, have intracellular functions. They are not exposed on cell membranes, but are found in internal membranes, where they assist with the loading of antigenic peptides onto classic MHC class II molecules. The important nonclassical MHC class II molecule DM is only found from the evolutionary level of lungfish, although also in more primitive fishes both classical and nonclassical MHC class II are found.
MHC class III Unlike classes I and II, Class III molecules have physiological roles and are encoded between classes I and II on the short arm of human chromosome 6. Class III molecules include several secreted proteins with immune functions: components of the
complement system (such as
C2,
C4, and
B factor), cytokines (such as
TNF-α,
LTA, and
LTB), and
heat shock proteins.
Function MHC is the tissue-antigen that allows the immune system (more specifically T cells) to bind to, recognize, and tolerate itself (autorecognition). MHC is also the chaperone for intracellular peptides that are complexed with MHCs and presented to
T cell receptors (TCRs) as potential foreign antigens. MHC interacts with TCR and its co-receptors to optimize binding conditions for the TCR-antigen interaction, in terms of antigen binding affinity and specificity, and signal transduction effectiveness. Essentially, the MHC-peptide complex is a complex of auto-antigen/allo-antigen. Upon binding, T cells should in principle tolerate the auto-antigen, but activate when exposed to the allo-antigen. Disease states occur when this principle is disrupted.
Antigen presentation: MHC molecules bind to both
T cell receptor and
CD4/
CD8 co-receptors on
T lymphocytes, and the antigen
epitope held in the peptide-binding groove of the MHC molecule interacts with the
variable Ig-Like domain of the TCR to trigger T-cell activation
Autoimmune reaction: The presence of certain MHC molecules can increase the risk of autoimmune diseases more than others.
HLA-B27 is an example. It is unclear how exactly having the HLA-B27 tissue type increases the risk of
ankylosing spondylitis and other associated inflammatory diseases, but mechanisms involving aberrant antigen presentation or T cell activation have been hypothesized. Tissue
allorecognition: MHC molecules in complex with peptide epitopes are essentially ligands for TCRs. T cells become activated by binding to the peptide-binding grooves of any MHC molecule that they were not trained to recognize during
positive selection in the
thymus. == Antigen processing and presentation ==