Exogenous antigens

One type of foreign antigen is typified by the invading bacteria that grow in the tissues and extracellular fluid. These live outside cells and so are called exogenous antigens. Exogenous antigens must first be captured, processed, and presented in the correct fashion to helper T cells if they are to be recognized as foreign. This is the responsibility of specialized antigen-processing cells.

The number of dendritic cells varies considerably among tissues. Thus DCs are present in high numbers within the dermis. As a result, intradermally administered vaccines are readily recognized. Likewise circulating DCs are common in well-vascularized muscles, the preferred site of injection for many vaccines. There are fewer DCs in the subcutis and adipose tissue, thus explaining why these are usually a less effective routes for vaccine administration.

Because helper T cells must recognize MHC-antigen complexes to respond to an antigen, MHC class II molecules effectively determine whether an animal can mount an immune response. Class II molecules can bind some, but not all, peptides created during antigen processing so they select those antigen fragments that are to be presented to the T cells. The response to vaccines is thus controlled by an animal’s set of MHC genes—its MHC haplotype.

Endogenous antigens

A second type of invading organism is typified by viruses that invade cells and force them to make new viral proteins. These “endogenous antigens” are processed by the cells in which they are synthesized.

Living cells continually break up and recycle the proteins they produce. As a first step, the protein is tagged with a small protein called ubiquitin. These ubiquinated proteins are recognized by proteasomes, powerful tubular complex proteases. Ubiquinated proteins are inserted into the inner channel of the proteasome, where they are broken into 8 to 15 amino acid peptides like a meat grinder. Some of these peptide fragments are rescued from further destruction by attachment to transport proteins. These fragments are then transported to a newly formed MHC class I molecule. If they fit the MHC antigen-binding site, they will be bound. Once loaded onto the MHC, the MHC-peptide complex is carried to the cell surface and displayed to any passing T cells.

A cell can express about 10⁶ MHC-peptide complexes at any one time. A minimum of about 200 MHC class I molecules loaded with the same viral peptide is required to activate a cytotoxic T cell. Thus the MHC-peptide complexes can provide passing T cells with fairly complete information on virtually all the proteins being made by a cell. Analyses of peptide binding indicate that the binding groove of a class I molecule can bind over a million different peptides with various levels of affinity. The number is not unlimited, however, and binding is not always strong. As a result, not all of the antigens within a vaccine may induce a protective immune response. Thus these MHC molecules also determine whether an animal can respond to a specific antigen.

Helper T cells

T cell antigen receptors (TCRs) form a large diverse repertoire. Any foreign antigen that enters the body will probably encounter and be able to bind to the receptors on at least one T cell. Each T cell has receptors of a single specificity. T cell antigen receptors only recognize antigens attached to MHC molecules. They cannot recognize or respond to free antigen molecules.

The binding of an antigen-MHC complex to a T cell antigen receptor is usually not sufficient by itself to trigger a helper T cell response. Additional signals are needed for the T cell to respond fully. For example, adhesion molecules must bind the T cells and antigen-presenting cells firmly together and permit prolonged, strong signaling between them. TCR-antigen binding triggers the initial signaling steps. Receptors on antigen-presenting cells bind to their ligands on T cells and amplify these signals. T cells must also be stimulated by cytokines secreted by the antigen-presenting cells. These cytokines determine the way in which a T cell responds to antigen by turning on some pathways and turning off others.

When DCs present their antigen load to helper T cells, they generate three signals. The first signal is delivered when T cell antigen receptors bind antigen fragments attached to MHC class II molecules. The second signal provides the cells with additional critical costimulation through contact with other cell surface receptors such as adhesion molecules. The third signal determines the direction in which naïve helper T cells will develop and is provided by secreted cytokines. For example, some microbial antigens trigger DCs to secrete interleukin-12 (IL-12). These are called DC1 cells because their IL-12 activates Th1 cells and so triggers type 1 responses. Other microbial antigens can cause DCs to secrete IL-4, and IL-6. These cytokines stimulate Th2 differentiation and are produced by DC2 cells. They stimulate type 2 responses. It may also be that the same dendritic cell can promote a type 1 or a type 2 response, depending on the dose and type of antigen it encounters. The response may also depend on its location. For example, DCs from the intestine or airways seem to preferentially secrete IL-4 and thus promote type 2 antibody responses.

Because MHC molecules can bind many different antigenic peptides, any individual peptide will only be displayed in small amounts. T cells must be able to recognize these few specific peptide-MHC complexes among a vast excess of MHC molecules carrying irrelevant peptides. The number of MHC-peptide complexes signaling to the T cell is also important because the stimulus needed to trigger a T cell response varies. For example, at least 8000 TCRs must bind antigen for a helper T cell to become activated in the absence of a molecule called CD28, but only about 1000 TCRs need be engaged if CD28 is present. The duration of signaling also determines a T cell’s response. In the presence of appropriate antigens, T cells need to bind DCs for less than 15 seconds. T cells can make 30 to 40 DC contacts within a minute. Sustained signaling is however required for maximal T cell activation. Thus during prolonged cell interactions, each MHC-peptide complex may trigger up to 200 TCRs. This serial triggering depends on the kinetics of TCR-ligand interaction. CD28, for example, reduces the time needed to trigger a T cell and lowers the threshold for TCR triggering. Adhesion molecules stabilize the binding of T cells to antigen-processing cells and allow the signal to be sustained for hours.

B cell responses

As described earlier, the division of the adaptive immune system into two major components is based on the need to recognize two distinctly different forms of foreign invaders: exogenous and endogenous. Antibodies deal with the microbe. They attack bacteria and free virus particles and parasites. Antibodies also provide the first line of defense against organisms that can survive and grow within cells. However, once these organisms succeed in entering cells then cytotoxic T cells are needed to kill the infected cell, release cytokines that inhibit microbial growth, or prevent pathogen survival within cells.

In general, B cell responses are affected by the dose of antigen administered. At priming, higher antigen doses favor the induction of plasma cells over memory cells. Lower doses generally favor memory cell production. At revaccination, higher doses of antigen favor stronger responses. Thus increased doses of antigen, within limits, promote greater B cell responses. On the other hand, very high doses of antigen exert less selective pressure on B cell responses so that cells do not have to compete for limited amounts of antigen and hence lower affinity antibodies can be produced. Adjuvants, by providing the required “danger” signals reduce the dose of antigen needed to induce a protective response. Modified live vaccines that cause local inflammation are “naturally adjuvanted” and are thus more immunogenic than killed/inactivated vaccines. Very few killed vaccines can induce high, sustained antibody responses after a single dose.

B cells are activated within the lymph nodes draining the vaccine injection site. When a B cell encounters an exogenous antigen that binds its receptors, with appropriate costimulation it will respond by secreting these receptors into body fluids, where they are called antibodies. Each B cell is covered with about 200,000 to 500,000 identical antigen receptors (BCRs). Unlike the TCRs, however, BCRs can bind soluble antigens. Antibodies are simply BCRs released into body fluids; they all belong to the family of proteins called immunoglobulins.

Although the binding of antigen to a BCR is an essential first step, this alone is usually insufficient to activate B cells. Complete activation of a B cell also requires multiple costimulatory signals from helper T cells and their cytokines.