A neutralizing antibody (NAb) is an antibody that defends a cell from a pathogen or infectious particle by neutralizing any effect it has biologically. Neutralization renders the particle no longer infectious or pathogenic.
Neutralizing antibodies are part of the humoral response of the adaptive immune system against viruses, intracellular bacteria and microbial toxin. By binding specifically to surface structures (antigen) on an infectious particle, neutralizing antibodies prevent the particle from interacting with its host cells it might infect and destroy.
In order to enter cells, pathogens, such as circulating viral particles or extracellular bacteria, use molecules on their surfaces to interact with the cell surface receptors of their target cell which allows them to enter the cell and start their replication cycle. Neutralizing antibodies can inhibit infectivity by binding to the pathogen and blocking the molecules needed for cell entry. This can be due to the antibodies statically interfering with the pathogens, or toxins attaching to host cell receptors. In case of a viral infection, NAbs can bind to glycoproteins of enveloped viruses or capsid proteins of non-enveloped viruses.
Furthermore, neutralizing antibodies can act by preventing particles from undergoing structural changes often needed for successful cell entry. For example, neutralizing antibodies can prevent conformational changes of viral proteins that mediate the membrane fusion needed for entry into the host cell. In some cases, the virus is unable to infect even after the antibody dissociates. The pathogen-antibody complex is eventually taken up and degraded by macrophages.
Neutralizing antibodies are also important in neutralizing the toxic effects of bacterial toxins. An example of a neutralizing antibody is diphtheria antitoxin, which can neutralize the biological effects of diphtheria toxin. Neutralizing antibodies are not effective against extracellular bacteria, as the binding of antibodies does not prevent bacteria from replicating.
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