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Cross-reactivity, in a general sense, is the reactivity of an observed agent which initiates reactions outside the main reaction expected. This has implications for any kind of test or assay, including diagnostic tests in medicine, and can be a cause of false positives. In immunology, the definition of cross-reactivity refers specifically to the reaction of the immune system to antigens. There can be cross-reactivity between the immune system and the antigens of two different pathogens, or between one pathogen and proteins on non-pathogens, which in some cases can be the cause of allergies.

In medical testing

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In medical tests, including rapid diagnostic tests, cross-reactivity can be either confounding or helpful, depending on the instance. An example of confounding that yields a false positive error is in a latex fixation test when agglutination occurs with another antigen rather than the antigen of interest. An example of helpful cross-reactivity is in heterophile antibody tests, which detect Epstein-Barr virus using antibodies with specificity for other antigens. Cross-reactivity is also a commonly evaluated parameter for the validation of immune and protein binding based assays such as ELISA and RIA. In this case it is normally quantified by comparing the assay's response to a range of similar analytes and expressed as a percentage. In practice, calibration curves are produced using fixed concentration ranges for a selection of related compounds and the midpoints (IC50) of the calibration curves are calculated and compared. The figure then provides an estimate of the response of the assay to possible interfering compounds relative to the target analyte.

Applications in drug development

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Tissue cross-reactivity assay is a standard method based on immunohistochemistry, required prior to phase I human studies for therapeutic antibodies.

In drug screening, because many urine drug screens use immunoassays there is a certain amount of cross-reactivity. Certain drugs or other chemicals can give a false positive for another category of drug.[1]

In immunology

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In immunology, cross-reactivity has a more narrow meaning of the reaction between an antibody and an antigen that differs from the immunogen. It is sometimes also referred to as cross-immunity or cross-protective immunity,[2] although cross-reactivity does not necessarily confer cross-protection. In some cases, the cross-reactivity can be destructive, and immune response to one pathogen can interfere with or lower the immune response to a different pathogen.

An adaptive immune response is specific to the antigen that stimulated it (called the immunogen). However, many naturally occurring apparent antigens are actually a mixture of macromolecules (for example, from pathogens, toxins, proteins, or pollen) comprising several epitopes. Contact with a complex antigen such as a virus will stimulate multiple immune responses to the virus' different macromolecules as well as the individual epitopes of each macromolecule. For example, the tetanus toxin is a single protein macromolecular antigen but will stimulate many immune responses due to the tertiary structure of the protein yielding many different epitopes. The toxin that creates the immune response will have an epitope on it that stimulates the response. Denaturing the protein may 'disarm' its function but allow the immune system to have an immune response thus creating an immunity without harming the patient.

Cross reactivity has implications for flu vaccination because of the large number of strains of flu, as antigens produced in response to one strain may confer protection to different strains.[3] Cross-reactivity need not be between closely related viruses, however; for example, there is cross-reactivity between influenza virus-specific CD8+ T cells and hepatitis C virus antigens.[4]

Allergies

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Cross reactivity may also occur between a pathogen and a protein found on a non-pathogen (i.e. food.) There may even be cross reactivity between two non-pathogens;[5] for example, Hevein-like protein domains are a possible cause for allergen cross-reactivity between latex and banana.[6]

Cross-reactivity may be caused by identical carbohydrate structures on unrelated proteins from the same or different species. Such cross-reactive carbohydrate determinants (CCDs) are an issue in allergy diagnosis, where about a fifth of all patients displays IgE antibodies against Asn-linked oligosaccharides (N-glycans) containing core α1,3-linked fucose.[7] As CCDs apparently do not elicit allergic symptoms, a positive in vitro test based on IgE binding to CCDs must be rated as false positive.

References

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  1. ^ Saitman A, Park HD, Fitzgerald RL (September 2014). "False-positive interferences of common urine drug screen immunoassays: a review". Journal of Analytical Toxicology. 38 (7): 387–96. doi:10.1093/jat/bku075. PMID 24986836.
  2. ^ Porrozzi R, Teva A, Amaral VF, Santos da Costa MV, Grimaldi G (September 2004). "Cross-immunity experiments between different species or strains of Leishmania in rhesus macaques (Macaca mulatta)". The American Journal of Tropical Medicine and Hygiene. 71 (3): 297–305. doi:10.4269/ajtmh.2004.71.297. PMID 15381810.
  3. ^ Mandelboim M, Bromberg M, Sherbany H, Zucker I, Yaary K, Bassal R, et al. (June 2014). "Significant cross reactive antibodies to influenza virus in adults and children during a period of marked antigenic drift". BMC Infectious Diseases. 14: 346. doi:10.1186/1471-2334-14-346. PMC 4107950. PMID 24950742.
  4. ^ Kasprowicz V, Ward SM, Turner A, Grammatikos A, Nolan BE, Lewis-Ximenez L, Sharp C, Woodruff J, Fleming VM, Sims S, Walker BD, Sewell AK, Lauer GM, Klenerman P (March 2008). "Defining the directionality and quality of influenza virus-specific CD8+ T cell cross-reactivity in individuals infected with hepatitis C virus". The Journal of Clinical Investigation. 118 (3): 1143–53. doi:10.1172/JCI33082. PMC 2214846. PMID 18246203.
  5. ^ Negi SS, Braun W (2017). "Cross-React: a new structural bioinformatics method for predicting allergen cross-reactivity". Bioinformatics. 33 (7): 1014–1020. doi:10.1093/bioinformatics/btw767. PMC 5860227. PMID 28062447.
  6. ^ Mikkola JH, Alenius H, Kalkkinen N, Turjanmaa K, Palosuo T, Reunala T (December 1998). "Hevein-like protein domains as a possible cause for allergen cross-reactivity between latex and banana". The Journal of Allergy and Clinical Immunology. 102 (6 Pt 1): 1005–12. doi:10.1016/S0091-6749(98)70339-2. PMID 9847442.
  7. ^ Altmann F (2007). "The role of protein glycosylation in allergy". International Archives of Allergy and Immunology. 142 (2): 99–115. doi:10.1159/000096114. PMID 17033195.
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