Biology:Immune repertoire

From HandWiki

The immune repertoire encompasses the different sub-types an organism's immune system makes of immunoglobulins or T-cell receptors. These help recognise pathogens in most vertebrates. The sub-types, all differing slightly from each other, can amount to tens of thousands, or millions in a given organism. Such a wide variety increases the odds of having a sub-type that recognises one of the many pathogens an organism may encounter. Too few sub-types and the pathogen can avoid the immune system, unchallenged, leading to disease.

Development

Lymphocytes generate the immune repertoire by recombining the genes encoding immunoglobulins and T cell receptors through V(D)J recombination. Although there are only a few of these genes, all their possible combinations can result in a wide variety of immune repertoire proteins. Through selection, cells with autoreactive proteins (and thus may cause autoimmunity) are removed, while cells that may actually detect an invading organism are kept. The immune repertoire is affected by several factors:

  • Age: as the immune system develops over life, lymphocytes generate their own unique gene sequences. Developed cells eventually die, but may not be replaced by new subtypes.[1]
  • Exposure to diseases triggers further development of the immune repertoire, and thus fine-tunes the immune response. Memory B cells and memory T cells ensure the persistence of the immune repertoire after a disease has passed.
  • Genetic diseases (primary immunodeficiency may impede the creation and development of immune repertoire proteins).
  • Treatments affecting the immune system e.g. hematopoietic stem cell transplantation, where the immune repertoire has to be regenerated from scratch.

Size

Due to technical difficulties, measuring the immune repertoire was seldom attempted. Estimates depend on the precise type or 'compartment' of immune cells and the protein studied, but the expected billions of combinations may be an over-estimation. The genetic spatio-temporal rule governing the TCR locus rearrangements imply that V(D)J rearrangements are not random, hence resulting in a smaller V(D)J diversity.[2]

  • TCR gamma genes, in CD8+CD45RO+ memory T cells in blood: estimates range from 40,000 to 100,000 sub-types in healthy young adults and from 3,600 to 97,000 in healthy old adults.[3]
  • TCR alpha and TCR beta in CD4+/CD8+ T-cells are estimated at approximately 100,000 sub-types.[4]

Future developments

Next generation sequencing may have a large impact.[5] This can obtain thousands of DNA sequences, from different genes, quickly, at the same time, relatively cheaply. Thus it may be possible, to take a large sample of cells from someones immune system, and look quickly at the range of sub-types present in the sample. The ability to obtain data quickly from tens or hundreds of thousands of cells, one cell at a time, should provide a good idea, of the size of the person's immune repertoire. These large-scale adaptive immune receptor repertoire sequencing (AIRR-seq) data require specialized bioinformatics pipelines to be analyzed effectively.[6] Many computational tools are being developed for this purpose, including:

  • The MiXCR is one of the most widely cited platforms for the analysis of high-throughput T cell and B cell receptor sequencing data.[7]
  • The Immcantation framework provides a start-to-finish analytical ecosystem for high-throughput AIRR-seq data analysis.[8][9]
  • The Cell Ranger software for the analysis of single-cell sequencing data, including T and B cell receptor data.[10]

The AIRR Community is community-driven organization that is organizing and coordinating stakeholders in the use of next-generation sequencing technologies to study immune repertoires.[11] In 2017, the AIRR Community published recommendations for a minimal set of metadata that should be used to describe an AIRR-seq data set when published and deposited in a public repository.[12]

See also

References

  1. Blackman, MA; Woodland, DL (2011). "The narrowing of the CD8 T cell repertoire in old age". Current Opinion in Immunology 23 (4): 537–42. doi:10.1016/j.coi.2011.05.005. PMID 21652194. 
  2. Pasqual, N; Gallagher, M; Aude-Garcia, C; Loiodice, M; Thuderoz, F; Demongeot, J; Ceredig, R; Marche, PN et al. (2002). "Quantitative and qualitative changes in V-J alpha rearrangements during mouse thymocytes differentiation: implication for a limited T cell receptor alpha chain repertoire". J. Exp. Med. 196 (9): 1163–73. doi:10.1084/jem.20021074. PMID 12417627. 
  3. Dare, R; Sykes, PJ; Morley, AA; Brisco, MJ (2006). "Effect of age on the repertoire of cytotoxic memory (CD8+CD45RO+) T cells in peripheral blood: The use of rearranged T cell receptor gamma genes as clonal markers". Journal of Immunological Methods 308 (1–2): 1–12. doi:10.1016/j.jim.2005.08.016. PMID 16325196. 
  4. Arstila, TP; Casrouge, A; Baron, V; Even, J; Kanellopoulos, J; Kourilsky, P (1999). "A direct estimate of the human alphabeta T cell receptor diversity". Science 286 (5441): 958–61. doi:10.1126/science.286.5441.958. PMID 10542151. 
  5. "Accurate and predictive antibody repertoire profiling by molecular amplification fingerprinting". Sci. Adv. 2 (3): e1501371. 2016. doi:10.1126/sciadv.1501371. PMID 26998518. Bibcode2016SciA....2E1371K. 
  6. Yaari, Gur; Kleinstein, Steven H. (2015-11-20). "Practical guidelines for B-cell receptor repertoire sequencing analysis". Genome Medicine 7: 121. doi:10.1186/s13073-015-0243-2. ISSN 1756-994X. PMID 26589402. 
  7. Bolotin, Dmitry; Poslavsky, Stanislav; Mitrophanov, Igor; Shugay, Mikhail; Mamedov, Ilgar; Putintseva, Ekaterina; Chudakov, Dmitriy (2015-04-29). "MiXCR: software for comprehensive adaptive immunity profiling". Nature Methods 12 (5): 380–381. doi:10.1038/nmeth.3364. https://www.nature.com/articles/nmeth.3364. Retrieved 2023-04-30. 
  8. Heiden, Vander; A, Jason; Yaari, Gur; Uduman, Mohamed; Stern, Joel N. H.; O’Connor, Kevin C.; Hafler, David A.; Vigneault, Francois et al. (2014-07-01). "pRESTO: a toolkit for processing high-throughput sequencing raw reads of lymphocyte receptor repertoires" (in en). Bioinformatics 30 (13): 1930–1932. doi:10.1093/bioinformatics/btu138. ISSN 1367-4803. PMID 24618469. 
  9. Gupta, Namita T.; Heiden, Vander; A, Jason; Uduman, Mohamed; Gadala-Maria, Daniel; Yaari, Gur; Kleinstein, Steven H. (2015-10-15). "Change-O: a toolkit for analyzing large-scale B cell immunoglobulin repertoire sequencing data" (in en). Bioinformatics 31 (20): 3356–3358. doi:10.1093/bioinformatics/btv359. ISSN 1367-4803. PMID 26069265. 
  10. Zheng, G; Terry, J; Belgrader, P (2017-01-16). "Massively parallel digital transcriptional profiling of single cells". Nature Communications 8: 14049. doi:10.1038/ncomms14049. PMID 28091601. 
  11. Breden, Felix; Prak, Luning; T, Eline; Peters, Bjoern; Rubelt, Florian; Schramm, Chaim A.; Busse, Christian E.; Heiden, Vander et al. (2017). "Reproducibility and Reuse of Adaptive Immune Receptor Repertoire Data" (in English). Frontiers in Immunology 8: 1418. doi:10.3389/fimmu.2017.01418. ISSN 1664-3224. PMID 29163494. 
  12. Rubelt, Florian; Busse, Christian E; Bukhari, Syed Ahmad Chan; Bürckert, Jean-Philippe; Mariotti-Ferrandiz, Encarnita; Cowell, Lindsay G; Watson, Corey T; Marthandan, Nishanth et al. (2017-11-16). "Adaptive Immune Receptor Repertoire Community recommendations for sharing immune-repertoire sequencing data" (in En). Nature Immunology 18 (12): 1274–1278. doi:10.1038/ni.3873. PMID 29144493. 

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