Loss of heterozygosity explained

Loss of heterozygosity (LOH) is a type of genetic abnormality in diploid organisms in which one copy of an entire gene and its surrounding chromosomal region are lost.[1] Since diploid cells have two copies of their genes, one from each parent, a single copy of the lost gene still remains when this happens, but any heterozygosity (slight differences between the versions of the gene inherited from each parent) is no longer present.

In cancer

The loss of heterozygosity is a common occurrence in cancer development. Originally, a heterozygous state is required and indicates the absence of a functional tumor suppressor gene copy in the region of interest. However, many people remain healthy with such a loss, because there still is one functional gene left on the other chromosome of the chromosome pair. The remaining copy of the tumor suppressor gene can be inactivated by a point mutation or via other mechanisms, resulting in a loss of heterozygosity event, and leaving no tumor suppressor gene to protect the body. Loss of heterozygosity does not imply a homozygous state (which would require the presence of two identical alleles in the cell). The exact targets for LOH are not characterised for all chromosomal losses in cancer, but certain are very well mapped. Some examples are 17p13 loss in multiple cancer types where a copy of TP53 gene gets inactivated, 13q14 loss in retinoblastoma with RB1 gene deletion or 11p13 in Wilms' tumor where WT1 gene is lost.[2] Other commonly lost chromosomal loci are still being investigated in terms of potential tumor suppressors located in those regions.

Knudson two-hit hypothesis of tumorigenesis

See main article: article and Knudson hypothesis.

Copy-neutral LOH

Copy-neutral LOH is thus called because no net change in the copy number occurs in the affected individual. Possible causes for copy-neutral LOH include acquired uniparental disomy (UPD) and gene conversion. In UPD, a person receives two copies of a chromosome, or part of a chromosome, from one parent and no copies from the other parent due to errors in meiosis I or meiosis II. This acquired homozygosity could lead to development of cancer if the individual inherited a non-functional allele of a tumor suppressor gene.

In tumor cells copy-neutral LOH can be biologically equivalent to the second hit in the Knudson hypothesis.[3] Acquired UPD is quite common in both hematologic and solid tumors, and is reported to constitute 20 to 80% of the LOH seen in human tumors.[4] [5] [6] [7] Determination of virtual karyotypes using SNP-based arrays can provide genome-wide copy number and LOH status, including detection of copy-neutral LOH. Copy-neutral LOH cannot be detected by arrayCGH, FISH, or conventional cytogenetics. SNP-based arrays are preferred for virtual karyotyping of tumors and can be performed on fresh or paraffin-embedded tissues.

Retinoblastoma

The classical example of such a loss of protecting genes is hereditary retinoblastoma, in which one parent's contribution of the tumor suppressor Rb1 is flawed. Although most cells will have a functional second copy, chance loss of heterozygosity events in individual cells almost invariably lead to the development of this retinal cancer in the young child.

Breast cancer and BRCA1/2

The genes BRCA1 and BRCA2 show loss of heterozygosity in samplings of tumors from patients who have germline mutations. BRCA1/2 are genes that produce proteins which regulate the DNA repair pathway by binding to Rad51.

Homologous recombination repair

In breast, ovarian, pancreatic, and prostate cancers, a core enzyme employed in homologous recombination repair (HRR) of DNA damage is often defective due to LOH, that is genetic defects in both copies (in the diploid human genome) of the gene encoding an enzyme necessary for HRR.[8] Such LOH in these different cancers was found for DNA repair genes BRCA1, BRCA2, BARD1, PALB2, FANCC, RAD51C and RAD51D.[8] Reduced ability to accurately repair DNA damages by homologous recombination may lead to compensating inaccurate repair, increased mutation and progression to cancer.

Detection

Loss of heterozygosity can be identified in cancers by noting the presence of heterozygosity at a genetic locus in an organism's germline DNA, and the absence of heterozygosity at that locus in the cancer cells. This is often done using polymorphic markers, such as microsatellites or single-nucleotide polymorphisms, for which the two parents contributed different alleles. Genome-wide LOH status of fresh or paraffin embedded tissue samples can be assessed by virtual karyotyping using SNP arrays.

In asexual organisms

It has been proposed that LOH may limit the longevity of asexual organisms.[9] [10] The minor allele in heterozygous areas of the genome is likely to have mild fitness consequences compared to de-novo mutations because selection has had time to remove deleterious alleles. When allelic gene conversion removes the major allele at these sites organisms are likely to experience a mild decline in fitness. Because LOH is much more common than de-novo mutation, and because the fitness consequences are closer to neutrality, this process should drive Muller's ratchet more quickly than de-novo mutations. While this process has received little experimental investigation, it is known that major signature of asexuality in metazoan genomes appears to be genome wide LOH, a sort of anti-meselson effect.

See also

External links

Notes and References

  1. Association of the autoimmune diseases scleroderma with an immunologic response to cancer,
  2. Book: Encyclopedia of cancer . 2002 . Academic Press . 978-0-12-227555-5 . Bertino . Joseph R. . 2nd . San Diego, Calif.
  3. Mao X, Young BD, Lu YJ. The application of single-nucleotide polymorphism microarrays in cancer research. Curr Genomics. 2007 Jun;8(4):219–28.
  4. Gondek LP, Tiu R, O'Keefe CL, Sekeres MA, Theil KS, Maciejewski JP. Chromosomal lesions and uniparental disomy detected by SNP arrays in MDS, MDS/MPD, and MDS-derived AML. Blood. 2008 Feb 1;111(3):1534–42.
  5. Beroukhim R, Lin M, Park Y, Hao K, Zhao X, Garraway LA, et al. Inferring loss-of-heterozygosity from unpaired tumors using high-density oligonucleotide SNP arrays. PLoS Comput. Biol. 2006 May;2(5):e41.
  6. Ishikawa S, Komura D, Tsuji S, Nishimura K, Yamamoto S, Panda B, et al. Allelic dosage analysis with genotyping microarrays. Biochem Biophys Res Commun. 2005 Aug 12;333(4):1309–14.
  7. Lo KC, Bailey D, Burkhardt T, Gardina P, Turpaz Y, Cowell JK. Comprehensive analysis of loss of heterozygosity events in glioblastoma using the 100K SNP mapping arrays and comparison with copy number abnormalities defined by BAC array comparative genomic hybridization. Genes Chromosomes Cancer. 2008 Mar;47(3):221–37.
  8. Westphalen CB, Fine AD, André F, Ganesan S, Heinemann V, Rouleau E, Turnbull C, Garcia Palacios L, Lopez JA, Sokol ES, Mateo J. Pan-cancer Analysis of Homologous Recombination Repair-associated Gene Alterations and Genome-wide Loss-of-Heterozygosity Score. Clin Cancer Res. 2022 Apr 1;28(7):1412-1421. doi: 10.1158/1078-0432.CCR-21-2096. PMID 34740923; PMCID: PMC8982267
  9. Tucker AE, Ackerman MA, Eads BD, Xu S, Lynch M. Population-genomic insights into the evolutionary origin and fate of obligately asexual Daphnia pulex. PNAS. 2013; 110:15740.
  10. Archetti M. Recombination and loss of complementation: A more than two-fold cost for parthenogenesis. J Evol Biol 2004; 17(5):1084–1097.