These factors enable CD8+ T cells to kill cells displaying pathogen-derived peptides presented by MHC class I molecules, for example a virus-infected cell. By killing cells expressing high levels of virus-derived peptides at
their surface, CD8+ cells are able to eliminate infected cells before the completion of a viral replication cycle, thus limiting viral spread within an infected individual. In addition, CD8+ T cells can http://www.selleckchem.com/products/wnt-c59-c59.html inhibit viral replication without destroying the target cells by producing cytokines that are able to interfere with pathogen replication. CD8+ cytolytic cells can also eliminate cells displaying abnormal host peptides, such as those presented by tumour cells, p38 MAPK assay and therefore play an important role in the immune control of aberrant cell growth. Although CD8+ T cells can directly react to cells expressing the appropriate antigen/MHC class I complexes, their optimal activation
programme (proliferation and acquisition of full cytolytic potential) is best achieved in the presence of cytokines produced by type 1 CD4+ T helper cells. Antibodies represent a highly diverse set of soluble proteins secreted by the subset of lymphocytes referred to as B cells. B cells develop in the bone marrow before undergoing a process of differentiation and maturation in the spleen. As with T lymphocytes, each B lymphocyte expresses a unique antigen receptor (B-cell receptor [BCR]) enabling the cells to react to a specific antigen. In marked contrast to TCRs, BCRs can directly bind to molecules expressed by pathogens, with no need for previous internalisation and presentation by APCs or other innate immune cells. Upon antigen encounter, B cells expressing the cognate BCR are induced to proliferate and differentiate into plasma cells, which can secrete large amounts of a soluble form of the BCR that we know as an antibody. This soluble protein is thus released in the blood Pomalidomide in vivo and other body
fluids (referred to as the ‘humors’) enabling them to fight infection at distant sites. Antibodies play multiple roles in the control and elimination of pathogens, and in the response to vaccination. Binding of targets by antibodies is often sufficient to initiate processes that render the pathogen harmless. Antibodies can be viewed as bifunctional molecules, able to both recognise and eliminate a given antigen or pathogen. Antibody molecules consist of a ‘constant’ fragment, a structural feature common to all antibodies of a given isotype, and a ‘variable’ region, which includes the portion that gives the antigen specificity (or antigen-binding characteristics) of the antibody. The variable region of the antibody can exist in a huge number of molecular configurations, and an individual’s BCR repertoire is generated to maximise capability to produce antibodies that are useful against diverse potential pathogenic threats.