Epitope
An epitope, also known as antigenic determinant, is the part of an antigen that is recognized by the immune system, specifically by antibodies, B cells, or T cells. The part of an antibody that binds to the epitope is called a paratope. Although epitopes are usually non-self proteins, sequences derived from the host that can be recognized are also epitopes.
The epitopes of protein antigens are divided into two categories, conformational epitopes and linear epitopes, based on their structure and interaction with the paratope. Conformational and linear epitopes interact with the paratope based on the 3-D conformation adopted by the epitope, which is determined by the surface features of the involved epitope residues and the shape or tertiary structure of other segments of the antigen. A conformational epitope is formed by the 3-D conformation adopted by the interaction of discontiguous amino acid residues. In contrast, a linear epitope is formed by the 3-D conformation adopted by the interaction of contiguous amino acid residues. A linear epitope is not determined solely by the primary structure of the involved amino acids. Residues that flank such amino acid residues, as well as more distant amino acid residues of the antigen affect the ability of the primary structure residues to adopt the epitope's 3-D conformation. 90% of epitopes are conformational.
Function
T cell epitopes
epitopes are presented on the surface of an antigen-presenting cell, where they are bound to major histocompatibility complex molecules. In humans, professional antigen-presenting cells are specialized to present MHC class II peptides, whereas most nucleated somatic cells present MHC class I peptides. T cell epitopes presented by MHC class I molecules are typically peptides between 8 and 11 amino acids in length, whereas MHC class II molecules present longer peptides, 13–17 amino acids in length, and non-classical MHC molecules also present non-peptidic epitopes such as glycolipids.B cell epitopes
The part of the antigen that immunoglobulin or antibodies bind to is called a B-cell epitope. B cell epitopes can be divided into two groups: conformational or linear. B cell epitopes are mainly conformational. There are additional epitope types when the quaternary structure is considered. Epitopes that are masked when protein subunits aggregate are called cryptotopes. Neotopes are epitopes that are only recognized while in a specific quaternary structure and the residues of the epitope can span multiple protein subunits. Neotopes are not recognized once the subunits dissociate.Cross-activity
Epitopes are sometimes cross-reactive. This property is exploited by the immune system in regulation by anti-idiotypic antibodies. If an antibody binds to an antigen's epitope, the paratope could become the epitope for another antibody that will then bind to it. If this second antibody is of IgM class, its binding can upregulate the immune response; if the second antibody is of IgG class, its binding can downregulate the immune response.Epitope mapping
T cell epitopes
MHC class I and II epitopes can be reliably predicted by computational means alone, although not all in-silico T cell epitope prediction algorithms are equivalent in their accuracy. There are two main methods of predicting peptide-MHC binding: data-driven and structure-based. Structure based methods model the peptide-MHC structure and require great computational power. Data-driven methods have higher predictive performance than structure-based methods. Data-driven methods predict peptide-MHC binding based on peptide sequences that bind MHC molecules. By identifying T-cell epitopes, scientists can track, phenotype, and stimulate T-cells.B cell epitopes
There are two main methods of epitope mapping: either structural or functional studies. Methods for structurally mapping epitopes include X-ray crystallography, nuclear magnetic resonance, and electron microscopy. X-ray crystallography of Ag-Ab complexes is considered an accurate way to structurally map epitopes. Nuclear magnetic resonance can be used to map epitopes by using data about the Ag-Ab complex. This method does not require crystal formation but can only work on small peptides and proteins. Electron microscopy is a low-resolution method that can localize epitopes on larger antigens like virus particles.Methods for functionally mapping epitopes often use binding assays such as western blot, dot blot, and/or ELISA to determine antibody binding. Competition methods look to determine if two monoclonal antibodies can bind to an antigen at the same time or compete with each other to bind at the same site. Another technique involves high-throughput mutagenesis, an epitope mapping strategy developed to improve rapid mapping of conformational epitopes on structurally complex proteins. Mutagenesis uses randomly/site-directed mutations at individual residues to map epitopes. B-cell epitope mapping can be used for the development of antibody therapeutics, peptide-based vaccines, and immunodiagnostic tools.