Literature DB >> 36068459

Human Leukocyte Antigen (HLA) Testing in Pharmacogenomics.

Ann M Moyer1, Manish J Gandhi2.   

Abstract

The genetic region on the short arm of chromosome 6 where the human leukocyte antigen (HLA) genes are located is the major histocompatibility complex. The genes in this region are highly polymorphic, and some loci have a high degree of homology with other genes and pseudogenes. Histocompatibility testing has traditionally been performed in the setting of transplantation and involves determining which specific alleles are present. Several HLA alleles have been associated with disease risk or increased risk of adverse drug reaction (ADR) when treated with certain medications. Testing for these applications differs from traditional histocompatibility in that the desired result is simply presence or absence of the allele of interest, rather than determining which allele is present. At present, the majority of HLA typing is done by molecular methods using commercially available kits. A subset of pharmacogenomics laboratories has developed their own methods, and in some cases, query single nucleotide variants associated with certain HLA alleles rather than directly testing for the allele. In this chapter, a brief introduction to the HLA system is provided, followed by an overview of a variety of testing technologies including those specifically used in pharmacogenomics, and the chapter concludes with details regarding specific HLA alleles associated with ADR.
© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.

Entities:  

Keywords:  HLA antigens; HLA typing; Hypersensitivity reactions; Immune-mediated adverse drug reaction; MHC; Pharmacogenetics; Pharmacogenomics

Mesh:

Substances:

Year:  2022        PMID: 36068459     DOI: 10.1007/978-1-0716-2573-6_2

Source DB:  PubMed          Journal:  Methods Mol Biol        ISSN: 1064-3745


  101 in total

1.  The DNA sequence and analysis of human chromosome 6.

Authors:  A J Mungall; S A Palmer; S K Sims; C A Edwards; J L Ashurst; L Wilming; M C Jones; R Horton; S E Hunt; C E Scott; J G R Gilbert; M E Clamp; G Bethel; S Milne; R Ainscough; J P Almeida; K D Ambrose; T D Andrews; R I S Ashwell; A K Babbage; C L Bagguley; J Bailey; R Banerjee; D J Barker; K F Barlow; K Bates; D M Beare; H Beasley; O Beasley; C P Bird; S Blakey; S Bray-Allen; J Brook; A J Brown; J Y Brown; D C Burford; W Burrill; J Burton; C Carder; N P Carter; J C Chapman; S Y Clark; G Clark; C M Clee; S Clegg; V Cobley; R E Collier; J E Collins; L K Colman; N R Corby; G J Coville; K M Culley; P Dhami; J Davies; M Dunn; M E Earthrowl; A E Ellington; K A Evans; L Faulkner; M D Francis; A Frankish; J Frankland; L French; P Garner; J Garnett; M J R Ghori; L M Gilby; C J Gillson; R J Glithero; D V Grafham; M Grant; S Gribble; C Griffiths; M Griffiths; R Hall; K S Halls; S Hammond; J L Harley; E A Hart; P D Heath; R Heathcott; S J Holmes; P J Howden; K L Howe; G R Howell; E Huckle; S J Humphray; M D Humphries; A R Hunt; C M Johnson; A A Joy; M Kay; S J Keenan; A M Kimberley; A King; G K Laird; C Langford; S Lawlor; D A Leongamornlert; M Leversha; C R Lloyd; D M Lloyd; J E Loveland; J Lovell; S Martin; M Mashreghi-Mohammadi; G L Maslen; L Matthews; O T McCann; S J McLaren; K McLay; A McMurray; M J F Moore; J C Mullikin; D Niblett; T Nickerson; K L Novik; K Oliver; E K Overton-Larty; A Parker; R Patel; A V Pearce; A I Peck; B Phillimore; S Phillips; R W Plumb; K M Porter; Y Ramsey; S A Ranby; C M Rice; M T Ross; S M Searle; H K Sehra; E Sheridan; C D Skuce; S Smith; M Smith; L Spraggon; S L Squares; C A Steward; N Sycamore; G Tamlyn-Hall; J Tester; A J Theaker; D W Thomas; A Thorpe; A Tracey; A Tromans; B Tubby; M Wall; J M Wallis; A P West; S S White; S L Whitehead; H Whittaker; A Wild; D J Willey; T E Wilmer; J M Wood; P W Wray; J C Wyatt; L Young; R M Younger; D R Bentley; A Coulson; R Durbin; T Hubbard; J E Sulston; I Dunham; J Rogers; S Beck
Journal:  Nature       Date:  2003-10-23       Impact factor: 49.962

2.  Fetomaternal leukocyte incompatibility.

Authors:  R PAYNE; M R ROLFS
Journal:  J Clin Invest       Date:  1958-12       Impact factor: 14.808

3.  The HLA class I gene family includes at least six genes and twelve pseudogenes and gene fragments.

Authors:  D E Geraghty; B H Koller; J A Hansen; H T Orr
Journal:  J Immunol       Date:  1992-09-15       Impact factor: 5.422

4.  Seeds of time: fifty years ago Peter A. Gorer discovered the H-2 complex.

Authors:  J Klein
Journal:  Immunogenetics       Date:  1986       Impact factor: 2.846

Review 5.  Factors affecting HLA expression: A review.

Authors:  B Sean Carey; Kay Victoria Poulton; Anthony Poles
Journal:  Int J Immunogenet       Date:  2019-06-10       Impact factor: 1.466

Review 6.  The class II molecules of the human and murine major histocompatibility complex.

Authors:  J F Kaufman; C Auffray; A J Korman; D A Shackelford; J Strominger
Journal:  Cell       Date:  1984-01       Impact factor: 41.582

Review 7.  Biochemistry of MHC class II molecules.

Authors:  R C Giles; J D Capra
Journal:  Tissue Antigens       Date:  1985-02

Review 8.  Inheritable variable sizes of DNA stretches in the human MHC: conserved extended haplotypes and their fragments or blocks.

Authors:  E J Yunis; C E Larsen; M Fernandez-Viña; Z L Awdeh; T Romero; J A Hansen; C A Alper
Journal:  Tissue Antigens       Date:  2003-07

Review 9.  Simplifying genetic locus assignment of HLA-DRB genes.

Authors:  G Andersson; L Andersson; D Larhammar; L Rask; S Sigurdardóttir
Journal:  Immunol Today       Date:  1994-02

Review 10.  Gene map of the extended human MHC.

Authors:  Roger Horton; Laurens Wilming; Vikki Rand; Ruth C Lovering; Elspeth A Bruford; Varsha K Khodiyar; Michael J Lush; Sue Povey; C Conover Talbot; Mathew W Wright; Hester M Wain; John Trowsdale; Andreas Ziegler; Stephan Beck
Journal:  Nat Rev Genet       Date:  2004-12       Impact factor: 53.242
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.