Jump to content

Inborn errors of immunity

From Wikipedia, the free encyclopedia
(Redirected from Inborn Errors of Immunity)
Inborn errors of immunity
SpecialtyClinical immunologist
Usual onsetNewborns, children, and, uncommonly, adults
CausesDefects in specific genes
Diagnostic methodGenetic testing
PrognosisVariable
FrequencyRare but becoming much more common

Inborn errors of immunity (IEI) are a heterogenous group of disorders in which a mutation in any one of various genes that regulate the immune system causes increases in the susceptibility of individuals to develop a dysfunction in their immune system.[1][2] (As used here, mutations include deletions or other changes in any part of a gene that causes it to be dysfunctional.) Depending on the gene involved, this dysfunction may induce the development of an: a) autoinflammatory disease by causing a malfunction in the innate immune system; b) autoimmune disease by causing a malfunction in the adaptive immune system;[3] c) viral, bacterial, fungal, or mycobacterial infection by causing a malfunction in one of the various components of the immune system that combat these pathogens;[3][4] d) allergic disease by causing a hypersensitive immune system that overreacts to otherwise harmless substances; e) lose of one or more types of circulating blood cells by causing a failure of the bone marrow to produce the circulating blood cell type(s); f) hematological cancers by causing a mutation in any one of various oncogenes (i.e., genes with the potential to cause a cancer); g) non-hematological cancers as well as hematological cancers by causing a mutation in the ATM serine/threonine kinase gene (these cancers are mainly pancreatic cancer, prostate cancer, stomach cancer and invasive ductal carcinoma of the breast;[5] see cancers in ATM serine/threonine kinase gene defects);[3][6][7] and h) non-malignant lymphoproliferative disorders by causing the excessive proliferation of T-cell or B-cell lymphocytes in the lymph nodes, gastrointestinal tract, liver, skin, or more than one of these organs.[8]

A human immune disease that would later be classified as an IEI was first defined by Ogden Bruton. In the early 1950s, he examined an 8-year-old boy who had 19 episodes of pneumonia over a period of 4 years. Expecting that individuals with such a history of repeated infections would have high levels of infection-fighting antibodies in their serum, Dr. Bruton was surprised to find that the boy had hypogammaglobulinemia, i.e., his serum lacked detectible levels of circulating antibodies which attack infection-causing microorganisms and virus.[9][10] That same year, Dr. Bruton and colleagues published on two other infection-prone patients who also lacked detectable levels of these serum antibodies[10][11] This particular from of hypogammaglobulinemia, now termed X-linked agammaglobulinemia and characterized as an IEI, occurs in about 1 per 379,000 live births.[12][13] It is also termed Bruton's agammaglobulinemia and the gene that when mutated causes this disease is termed the Bruton's tyrosine kinase, i.e., BKT, gene. The product of this gene, the BTK protein, contributes indirectly to promoting the production of all the antibody subtypes, i.e., IgG, IgA, IgM, and IgE.[14]

Impairments in the immune system's protective actions have been referred to as primary immunodeficiencies (PID), i.e., immune deficiencies that are present at birth and not caused by secondary factors such as other diseases or exposure to genotoxic agents.[15] The PID disorders (see List of primary immunodeficiencies) and its subgroup, the primary immune regulatory disorders (PIRDs; i.e., disorders of immunity characterized as excessive proliferations of lymphocytes and the development of immune responses against one's own normal tissues[16]), are immune disorders similar to those in IEI.[2][17] Finally, inborn errors of metabolism (i.e., IEM) are a group of about 1700 disorders caused by a mutation in any one of about 1500 genes that causes a defect in a pathway that metabolizes proteins, fats, or carbohydrates or that impairs the function of a subcellular organelle. This mutation usually causes a complicated medical condition involving several human organ systems.[18][19] When any one of the disorders in the PID, PIRDs, or IEM classifications is caused by a single gene mutation that disrupts the immune system, it is termed an IEI. Consequently, many IEIs are also termed a PID, PIRDs, and/or IEM.[2][17][18][19]

In 1973, the World Health Organization (WHO) established the Inborn Errors of Immunity Committee for the purpose of classifying and identifying immune defects in humans. The committee focused on rare immune diseases. In the 1990s, the WHO decided to focus on more common diseases, and the committee was taken on by the International Union of Immunological Societies (i.e., IUIS). This relationship was made official in 2008.[20] The number of genes that when mutated to cause specific IEI disorders has steadily rose from less than 10 in the 1980s[21] to the IUIS expert committee's 2022 classification of 485 mutated genes causing these disorders.[22] These numbers are expected to increase further as DNA sequencing using automated methods (e.g., massive parallel sequencing), further studies of less severe immune disorders, and analyses of multiple tissues in individuals that may have carry the dysfunctional gene in some but not their tissues (see mosaicism). Thus, the prevalence of IEIs in 2023 was estimated to be between 1 in 1,000 and 1 in 5,000 individuals but this may be an underestimate: its true prevalence may turn out to be as high as 1 in 500 individuals.[2][23][24]

Expression of IEI genes

[edit]

As with other human genes, an IEI gene may be defective because it is not expressed (see gene expression), is under expressed, is overexpressed, or directs the formation of a product with reduced, increased, or no activity. Furthermore, the defective IEI gene in parents may not be expressed in their offspring depending on the IEI gene's dominant or recessive activity or may not be present in offspring depending on its location in the X chromosome, Y chromosome, or one of 46 remaining non-sex chromosomes (termed autosomes; see sex linkage).[1][25] Individuals who do inherit an IEI gene may still not exhibit symptoms because: a) the gene is under expressed (termed reduced penetrrance) or not expressed (termed non-penetrance) in males or females (these different expression patterns are also termed gender-related penetrance), b) the presence of other genes which modify the activity of the inherited IEI gene (termed genetic modifiers), c) exposure to environmental factors with modify the activity of the inherited IEI gene (termed environmental modifiers), and/or d) epigenetic, i.e., caused by factors which regulate the expression of the IEI gene without changing this gene's nucleic acid sequence (termed epigenetic regulation). Mosaicism, i.e., an IEI mutation arising after fertilization of an egg, has been shown to lead to offsspring with two different cell populations, one with and one without the IEI gene. Individuals with this mosaicism may develop a mild IEI disorder, an IEI disorder much later in life, or no IEI disorder.[23]

International Union of Immunological Societies classification of IEI

[edit]

The International Union of Immunological Societies (2022) has classified IEI disorders into the following 10 categories:[22][24]

1). Cellular and hormonal immunodeficiencies consisting of 66 defective genes causing 58 different diseases. These diseases include severe combined immunodeficiency diseases that are associated with low levels of CD3 protein-expressing T cells plus low levels of T-cell receptor excision circles (low levels of the circles indicate that the T cells have not matured); less severe forms of the combined immunodeficiencies are also included in this category.
2). Combined immunodeficiencies with associated or syndromic features consisting of 69 defective genes causing 68 diseases. These diseases are a set of signs and symptoms characteristic of a particular immune disorder and tend to occur together in people with the same disorder. These disorders include combined immunodeficiencies of T cells and B cells (i.e., gene defects that alter the development and function of the immune system).
3). Predominantly antibody disorders consisting of 45 defective genes causing 51 diseases. These antibody disorders include hypogammaglobulinemia, i.e., reductions in one or more of the four antibody classes, and other types of antibody deficiencies.
4). Diseases of immune dysregulation consisting of 52 defective genes causing 51 diseases. These diseases include hemophagocytic lymphohistiocytosis and defects that cause an increases in the susceptibility of individuals to develop Epstein–Barr virus-induced immunity disorders. (About 50% of all five-year-old children and 90% of adults have evidence of previous infection with this virus;[26] see Epstein–Barr virus–associated lymphoproliferative diseases).
5). Congenital defects of phagocyte number or function consisting of 42 gene defects causing 35 diseases. These diseases include neutropenia not caused by antibodies directed against neutrophils and functional defects in phagocyte function.
6). Defects in intrinsic and innate immunity consisting of 74 gene defects causing 63 diseases. These diseases include a predisposition to develop bacterial, fungal, parasite and/or viral infections.
7). Autoinflammatory disorders consisting of 56 defective genes causing 59 diseases. These diseases include various types of autoinflammatory diseases, e.g., familial Mediterranean fever and Blau syndrome.
8). Complement deficiencies consisting of 36 defective genes causing 30 diseases. These diseases involve decreases in the levels of a component protein in the complement system (i.e., a system of proteins the increases the ability of antibodies and phagocytic cells to clear infecting microbes) and thereby increases an individual susceptibility to acquire Neisseria and pus-forming bacterial infections.
9). Bone marrow failure disorders consisting of 44 defective genes that cause 43 cases of Bone marrow failure. These disorders are losses in the levels of circulating red blood cells, white blood cells, and/or platelets due to the failure of the bone marrow to produce sufficient level of one or more of these cells.
10). Phenocopies of inborn errors of immunity consisting of 15 genes that cause 15 cases of various primary immunodeficiency diseases (i.e., PID) such as the chronic mucocutaneous candidiasis and the VEXAS syndrome. These phenocopy cases are due to somatic mutations that occur after fertilization of an ovum, i.e., they are mosaicism in which individuals developing from these post-fertilized ova have cells that do and do not have the altered gene that is responsible for a immune disorder. Depending on the amount and type of cells that express the dysfunctional gene, individuals may not develop the disorder or develop it in varying degrees of severity and/or develop it at a later age than individuals that have the dysfunctional gene in all cells. Usually, individuals with this mosaicism do not pass the defective gene to their offspring.

See also

[edit]

References

[edit]
  1. ^ a b Notarangelo LD, Bacchetta R, Casanova JL, Su HC (July 2020). "Human inborn errors of immunity: An expanding universe". Science Immunology. 5 (49). doi:10.1126/sciimmunol.abb1662. PMC 7647049. PMID 32651211.
  2. ^ a b c d Gray PE, David C (June 2023). "Inborn Errors of Immunity and Autoimmune Disease". The Journal of Allergy and Clinical Immunology. In Practice. 11 (6): 1602–1622. doi:10.1016/j.jaip.2023.04.018. PMID 37119983.
  3. ^ a b c Tangye SG, Al-Herz W, Bousfiha A, Cunningham-Rundles C, Franco JL, Holland SM, Klein C, Morio T, Oksenhendler E, Picard C, Puel A, Puck J, Seppänen MR, Somech R, Su HC, Sullivan KE, Torgerson TR, Meyts I (October 2022). "Human Inborn Errors of Immunity: 2022 Update on the Classification from the International Union of Immunological Societies Expert Committee". Journal of Clinical Immunology. 42 (7): 1473–1507. doi:10.1007/s10875-022-01289-3. PMC 9244088. PMID 35748970.
  4. ^ Moratti M, Conti F, Giannella M, Ferrari S, Borghesi A (November 2022). "How to: Diagnose inborn errors of intrinsic and innate immunity to viral, bacterial, mycobacterial, and fungal infections". Clinical Microbiology and Infection. 28 (11): 1441–1448. doi:10.1016/j.cmi.2022.07.021. PMID 35934195.
  5. ^ Hall MJ, Bernhisel R, Hughes E, Larson K, Rosenthal ET, Singh NA, Lancaster JM, Kurian AW (April 2021). "Germline Pathogenic Variants in the Ataxia Telangiectasia Mutated (ATM) Gene are Associated with High and Moderate Risks for Multiple Cancers". Cancer Prevention Research. 14 (4): 433–440. doi:10.1158/1940-6207.CAPR-20-0448. PMC 8026745. PMID 33509806.
  6. ^ Delavari S, Wang Y, Moeini Shad T, Pashangzadeh S, Nazari F, Salami F, Abolhassani H (January 2023). "Clinical and Immunologic Characteristics of Non-Hematologic Cancers in Patients with Inborn Errors of Immunity". Cancers. 15 (3): 764. doi:10.3390/cancers15030764. PMC 9913767. PMID 36765721.
  7. ^ Delavari S, Rasouli SE, Fekrvand S, Chavoshzade Z, Mahdaviani SA, Shirmast P, Sharafian S, Sherkat R, Momen T, Aleyasin S, Ahanchian H, Sadeghi-Shabestari M, Esmaeilzadeh H, Barzamini S, Tarighatmonfared F, Salehi H, Esmaeili M, Marzani Z, Fathi N, Abolnezhadian F, Rad MK, Saeedi-Boroujeni A, Shirkani A, Bagheri Z, Salami F, Shad TM, Marzbali MY, Mojtahedi H, Razavi A, Tavakolinia N, Cheraghi T, Tavakol M, Shafiei A, Behniafard N, Ebrahimi SS, Sepahi N, Ghaneimoghadam A, Rezaei A, Kalantari A, Abolhassani H, Rezaei N (February 2024). "Clinical heterogeneity in families with multiple cases of inborn errors of immunity". Clinical Immunology (Orlando, Fla.). 259: 109896. doi:10.1016/j.clim.2024.109896. PMID 38184287.
  8. ^ Cheng J, Dávila Saldaña BJ, Chandrakasan S, Keller M (September 2024). "Pediatric lymphoproliferative disorders associated with inborn errors of immunity". Clinical Immunology (Orlando, Fla.). 266: 110332. doi:10.1016/j.clim.2024.110332. PMID 39069111.
  9. ^ BRUTON OC (June 1952). "Agammaglobulinemia". Pediatrics. 9 (6): 722–8. doi:10.1542/peds.9.6.722. PMID 14929630.
  10. ^ a b Tsilifis C, Slatter MA, Gennery AR (2023). "Too much of a good thing: a review of primary immune regulatory disorders". Frontiers in Immunology. 14: 1279201. doi:10.3389/fimmu.2023.1279201. PMC 10645063. PMID 38022498.
  11. ^ BRUTON OC, APT L, GITLIN D, JANEWAY CA (November 1952). "Absence of serum gamma globulins". A.M.A. American Journal of Diseases of Children. 84 (5): 632–6. PMID 12984834.
  12. ^ Darmawan D, Raychaudhuri S, Lakshminrusimha S, Dimitriades VR (July 2024). "Hypogammaglobulinemia in neonates: illustrative cases and review of the literature". Journal of Perinatology. 44 (7): 929–934. doi:10.1038/s41372-023-01766-6. PMID 37667006.
  13. ^ Nishimura A, Uppuluri R, Raj R, Swaminathan VV, Cheng Y, Abu-Arja RF, Fu B, Laberko A, Albert MH, Hauck F, Bucciol G, Bigley V, Elcombe S, Kharya G, Pronk CJ, Wehr C, Neven B, Warnatz K, Meyts I, Morio T, Gennery AR, Kanegane H (November 2023). "An International Survey of Allogeneic Hematopoietic Cell Transplantation for X-Linked Agammaglobulinemia". Journal of Clinical Immunology. 43 (8): 1827–1839. doi:10.1007/s10875-023-01551-2. PMID 37454339.
  14. ^ Cardenas-Morales M, Hernandez-Trujillo VP (August 2022). "Agammaglobulinemia: from X-linked to Autosomal Forms of Disease". Clinical Reviews in Allergy & Immunology. 63 (1): 22–35. doi:10.1007/s12016-021-08870-5. PMC 8269404. PMID 34241796.
  15. ^ Tangye, Stuart G.; Al-Herz, Waleed; Bousfiha, Aziz; Chatila, Talal; Cunningham-Rundles, Charlotte; Etzioni, Amos; Franco, Jose Luis; Holland, Steven M.; Klein, Christoph; Morio, Tomohiro; Ochs, Hans D.; Oksenhendler, Eric; Picard, Capucine; Puck, Jennifer; Torgerson, Troy R. (2020). "Human Inborn Errors of Immunity: 2019 Update on the Classification from the International Union of Immunological Societies Expert Committee". Journal of Clinical Immunology. 40 (1): 24–64. doi:10.1007/s10875-019-00737-x. ISSN 0271-9142. PMC 7082301. PMID 31953710.
  16. ^ Flinn AM, Gennery AR (March 2022). "Primary immune regulatory disorders: Undiagnosed needles in the haystack?". Orphanet Journal of Rare Diseases. 17 (1): 99. doi:10.1186/s13023-022-02249-1. PMC 8895571. PMID 35241125.
  17. ^ a b Palva T, Lehtinen T (December 1987). "Pneumococcal antigens and endotoxin in effusions from patients with secretory otitis media". International Journal of Pediatric Otorhinolaryngology. 14 (2–3): 123–8. doi:10.1016/0165-5876(87)90022-x. PMID 3436716.
  18. ^ a b Agana M, Frueh J, Kamboj M, Patel DR, Kanungo S (December 2018). "Common metabolic disorder (inborn errors of metabolism) concerns in primary care practice". Annals of Translational Medicine. 6 (24): 469. doi:10.21037/atm.2018.12.34. PMC 6331353. PMID 30740400.
  19. ^ a b Patterson AR, Needle GA, Sugiura A, Jennings EQ, Chi C, Steiner KK, Fisher EL, Robertson GL, Bodnya C, Markle JG, Sheldon RD, Jones RG, Gama V, Rathmell JC (August 2024). "Functional overlap of inborn errors of immunity and metabolism genes defines T cell metabolic vulnerabilities". Science Immunology. 9 (98): eadh0368. doi:10.1126/sciimmunol.adh0368. PMID 39151020.
  20. ^ "Inborn Errors of Immunity Committee (IEI)". International Union of Immunological Societies. 22 July 2019. Retrieved 11 July 2020.
  21. ^ Staels F, Collignon T, Betrains A, Gerbaux M, Willemsen M, Humblet-Baron S, Liston A, Vanderschueren S, Schrijvers R (2021). "Monogenic Adult-Onset Inborn Errors of Immunity". Frontiers in Immunology. 12: 753978. doi:10.3389/fimmu.2021.753978. PMC 8635491. PMID 34867986.
  22. ^ a b Bousfiha A, Moundir A, Tangye SG, Picard C, Jeddane L, Al-Herz W, Rundles CC, Franco JL, Holland SM, Klein C, Morio T, Oksenhendler E, Puel A, Puck J, Seppänen MR, Somech R, Su HC, Sullivan KE, Torgerson TR, Meyts I (October 2022). "The 2022 Update of IUIS Phenotypical Classification for Human Inborn Errors of Immunity". Journal of Clinical Immunology. 42 (7): 1508–1520. doi:10.1007/s10875-022-01352-z. PMID 36198931.
  23. ^ a b Akalu YT, Bogunovic D (March 2024). "Inborn errors of immunity: an expanding universe of disease and genetic architecture". Nature Reviews. Genetics. 25 (3): 184–195. doi:10.1038/s41576-023-00656-z. PMID 37863939.
  24. ^ a b Yu JE (February 2024). "New primary immunodeficiencies 2023 update". Current Opinion in Pediatrics. 36 (1): 112–123. doi:10.1097/MOP.0000000000001315. PMID 38001560.
  25. ^ Casanova JL, Abel L (January 2021). "Lethal Infectious Diseases as Inborn Errors of Immunity: Toward a Synthesis of the Germ and Genetic Theories". Annual Review of Pathology. 16: 23–50. doi:10.1146/annurev-pathol-031920-101429. PMC 7923385. PMID 32289233.
  26. ^ "About 90% of adults have antibodies that show that they have a current or past EBV infection". National Center for Infectious Diseases. US CDC. 28 September 2020. Archived from the original on 2016-08-08.