Misplaced Pages

Medical genetics of Jews

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Medical genetics of Ashkenazi Jews) Autosomal recessive conditions that affect ethnic Jews more frequently

The medical genetics of Jews have been studied to identify and prevent some rare genetic diseases that, while still rare, are more common than average among people of Jewish descent. There are several autosomal recessive genetic disorders that are more common than average in ethnically Jewish populations, particularly Ashkenazi Jews, because of relatively recent population bottlenecks and because of consanguineous marriage (marriage of second cousins or closer). These two phenomena reduce genetic diversity and raise the chance that two parents will carry a mutation in the same gene and pass on both mutations to a child.

The genetics of Ashkenazi Jews have been particularly well studied, because the phenomenon affects them the most. This has resulted in the discovery of many genetic disorders associated with this ethnic group. The medical genetics of Sephardic Jews and Mizrahi Jews are more complicated, because they are genetically more diverse, and therefore no genetic disorders are more common in these groups as a whole; instead, they tend to have the genetic diseases common in their various countries of origin.

Several organizations, such as Dor Yeshorim, offer screening for Ashkenazi genetic diseases, and these programs have done much, particularly by reducing the instance of Tay–Sachs disease.

History and purpose

Different ethnic groups tend to have different rates of hereditary diseases, with some being more common, and some less common. Hereditary diseases, particularly hemophilia, were recognized early in Jewish history, even being described in the Talmud. However, the scientific study of hereditary disease in Jewish populations was initially hindered by scientific racism, which was based on racial supremacism.

However, modern studies on the genetics of particular ethnic groups have the tightly defined purpose of avoiding the birth of children with genetic diseases, or identifying people at particular risk of developing a disease in the future. Consequently, some members of the Jewish community have been very supportive of modern genetic testing programs; this high level of cooperation has raised concerns that conclusions may lead to stigmatization of the Jewish community.

Genetics of Jewish populations

Further information: Genetic studies on Jews

Most populations contain hundreds of alleles that could potentially cause disease, and most people are heterozygotes for one or two recessive alleles that would be lethal in a homozygote. Although the overall frequency of disease-causing alleles does not vary much between populations, the practice of consanguineous marriage (marriage between second cousins or closer relatives) has been common in some Jewish communities, which produces a small increase in the number of children with congenital defects.

According to Daphna Birenbaum Carmeli at the University of Haifa, Jewish populations have been studied thoroughly because:

  • Jewish populations, and particularly the large Ashkenazi Jewish population, are ideal for such research studies, because they exhibit a high degree of endogamy, and at the same time are a large group.
  • Jewish populations are overwhelmingly urban and are concentrated near biomedical centers where such research has been carried out.

The result is a form of ascertainment bias. This has sometimes created an impression that Jews are more susceptible to genetic disease than other populations. Carmeli writes, "Jews are over-represented in human genetic literature, particularly in mutation-related contexts."

This set of advantages have led to Ashkenazi Jews in particular being used in many genetic studies, not just in the study of genetic diseases. For example, a series of publications on Ashkenazi centenarians established their longevity was strongly inherited and associated with lower rates of age-related diseases. This "healthy aging" phenotype may be due to higher levels of telomerase in these individuals.

Ashkenazi diseases

Because of centuries of endogamy, today's 10 million Ashkenazi Jews descend from a population of 350 who lived about 600–800 years ago. That population derived from both Europe and the Middle East. Some evidence shows that the population bottleneck may have allowed deleterious alleles to increase in the population by genetic drift.

This group has therefore been particularly intensively studied, and many mutations have been found to be common in Ashkenazim. Of these diseases, many also occur in other Jewish groups and in non-Jewish populations, although the specific mutation that causes the disease may vary among populations. For example, two mutations in the glucocerebrosidase gene each cause Gaucher's disease in Ashkenazim, which is that group's most common genetic disease, but only one of these mutations is found in non-Jewish groups. A few diseases are unique to this group; familial dysautonomia, for example, is almost unknown in other peoples.

Genetic disorders common in Ashkenazi Jews
Disease Subspecialty Mode of inheritance Gene Carrier frequency
 Favism Medical genetics X-linked G6PD
 Bloom syndrome Medical genetics Autosomal recessive BLM 1/100
 Breast cancer and ovarian cancer Oncology Autosomal dominant BRCA1 or BRCA2 1/100 and 1/75, respectively
 Canavan disease Endocrinology, neurology Autosomal recessive ASPA 1/60
 Congenital deafness Neurology, otorhinolaryngology, audiology Autosomal recessive GJB2 or GJB6 1/25
 Cystic fibrosis Pulmonology, hepatology Autosomal recessive CFTR 1/25
 Haemophilia C Hematology Autosomal recessive F11 1/12
 Familial dysautonomia Neurology Autosomal recessive IKBKAP 1/30
 Familial hypercholesterolemia Endocrinology, chemical pathology Autosomal dominant LDLR 1/69
 Familial hyperinsulinism Gastroenterology, endocrinology, pediatrics Autosomal recessive ABCC8 1/125–1/160
 Fanconi anemia C Hematology Autosomal recessive FACC 1/100
 Gaucher disease Endocrinology, neurology Autosomal recessive GBA 1/7–1/18
 Glycogen Storage Disease type 1a Endocrinology, hematology, immunology Autosomal recessive G6PC 1/71
 Mucolipidosis IV Endocrinology Autosomal recessive MCOLN1 1/110
 Niemann–Pick (type A) Medical genetics Autosomal recessive SMPD1 1/90
 Nonclassical 21 OHase deficiency Endocrinology Autosomal recessive CPY21 1/6
 Parkinson's disease Neurology Autosomal dominant LRRK2 1/42
 Tay–Sachs Medical genetics Autosomal recessive HEXA 1/25–1/30
 Torsion dystonia Neurology Autosomal dominant DYT1 1/4000
 Usher syndrome Ophthalmology Autosomal recessive PCDH15 1/72
 Warsaw breakage syndrome Medical genetics, pediatrics Autosomal recessive DDX11 1/50

Tay–Sachs disease

Tay–Sachs disease, which can present as a fatal illness of children that causes mental deterioration prior to death, was historically extremely common among Ashkenazi Jews, with lower levels of the disease in some Pennsylvania Dutch, Italian, Irish Catholic, and French Canadian descent, especially those living in the Cajun community of Louisiana and the southeastern Quebec. Since the 1970s, however, proactive genetic testing has been quite effective in eliminating Tay–Sachs from the Ashkenazi Jewish population.

Lipid transport diseases

Gaucher's disease, in which lipids accumulate in inappropriate locations, occurs most frequently among Ashkenazi Jews; the mutation is carried by roughly one in every 15 Ashkenazi Jews, compared to one in 100 of the general American population. Gaucher's disease can cause brain damage and seizures, but these effects are not usually present in the form manifested among Ashkenazi Jews; while those affected still bruise easily, and it can still potentially rupture the spleen, it generally has only a minor impact on life expectancy.

Ashkenazi Jews are also highly affected by other lysosomal storage diseases, particularly in the form of lipid storage disorders. Compared to other ethnic groups, they more frequently act as carriers of mucolipidosis and Niemann–Pick disease, the latter of which can prove fatal.

The occurrence of several lysosomal storage disorders in the same population suggests the alleles responsible might have conferred some selective advantage in the past. This would be similar to the hemoglobin allele which is responsible for sickle-cell disease, but solely in people with two copies; those with just one copy of the allele have a sickle cell trait and gain partial immunity to malaria as a result. This effect is called heterozygote advantage.

Familial dysautonomia

Familial dysautonomia (Riley–Day syndrome), which causes vomiting, speech problems, an inability to cry, and false sensory perception, is almost exclusive to Ashkenazi Jews; Ashkenazi Jews are almost 100 times more likely to carry the disease than anyone else.

Other Ashkenazi diseases and disorders

Diseases inherited in an autosomal recessive pattern often occur in endogamous populations. Among Ashkenazi Jews, a higher incidence of specific genetic disorders and hereditary diseases has been verified, including:

Sephardi and Mizrahi diseases

In contrast to the Ashkenazi population, Sephardic and Mizrahi Jews are much more divergent groups, with ancestors from Spain, Portugal, Morocco, Tunisia, Algeria, Italy, Libya, the Balkans, Iran, Kurdistan, Turkey, India, and Yemen, with specific genetic disorders found in each regional group, or even in specific subpopulations in these regions.

Genetic disorders common in Sephardic Jews
Disease Mode of inheritance Gene or enzyme Carrier frequency Populations
 Oculocutaneous albinism Ophthalmology, dermatology Autosomal recessive TYR 1/30 Morocco
 Ataxia–telangiectasia Neurology, medical genetics Autosomal recessive ATM 1/80 Morocco, Tunisia
 Creutzfeldt–Jakob disease Neurology Autosomal dominant PRNP 1/24,000 Libya
 Cerebrotendinous xanthomatosis Medical genetics, endocrinology Autosomal recessive CYP27A1 1/70 Morocco
Cystinuria Endocrinology Autosomal recessive SLC7A9 1/25 Libya
Familial Mediterranean fever Rheumatology, immunology Autosomal recessive MEFV 1/5–7 All MENA (Middle Eastern and North African countries).
 Glycogen storage disease III Endocrinology Autosomal recessive AGL 1/35 Morocco, North Africa
 Limb girdle muscular dystrophy Neurology Autosomal recessive DYSF 1/10 Libya
 Tay–Sachs disease Neurology Autosomal recessive HEXA 1/110 Morocco
 11-β-hydroxylase deficiency Endocrinology Autosomal recessive CYP11B1 1/30–1/128 Morocco
Genetic disorders common in Mizrahi (Oriental) Jews
Disease Mode of inheritance Gene or enzyme Carrier frequency Populations
 Beta-thalassemia Hematology Autosomal recessive HBB 1/6 Iran, Kurdistan, Syria
 Factor VII deficiency Hematology, medical genetics Autosomal recessive F7 1/40 Iran
 Familial Mediterranean fever Rheumatology, immunology Autosomal recessive, but heterozygous carriers also can show clinical manifestations. MEFV 1/5–1/7 Iran, Kurdistan, Armenia, Azerbaijan, North African Jews, Ashkenazi
 Glucose-6-phosphate dehydrogenase deficiency Medical genetics X-linked G6PD 1/4 Iran, esp. Kurdistan, Syria and all MENA countries. Female heterozygotes can also show clinical symptoms due to lyonization (X-inactivation) especially during pregnancy.
 Inclusion body myopathy Neurology Autosomal recessive GNE 1/12 Iran
 Metachromatic leukodystrophy Endocrinology, neurology Autosomal recessive ARSA 1/50 Yemen
 Oculopharyngeal muscular dystrophy Neurology Autosomal, recessive or dominant PABPN1 1/7 Bukhara
 Phenylketonuria Medical genetics, pediatrics, dietetics Autosomal recessive PAH 1/35 Yemen

Genetic testing in Jewish populations

One of the first genetic testing programs to identify heterozygote carriers of a genetic disorder was a program aimed at eliminating Tay–Sachs disease. This program began in 1970, and over one million people have now been screened for the mutation. Identifying carriers and counseling couples on reproductive options have had a large impact on the incidence of the disease, with a decrease from 40 to 50 per year worldwide to only four or five per year. Screening programs now test for several genetic disorders in Jews, although these focus on the Ashkenazi Jews, since other Jewish groups cannot be given a single set of tests for a common set of disorders. In the US, these screening programs have been widely accepted by the Ashkenazi community, and have greatly reduced the frequency of the disorders.

Prenatal testing for several genetic diseases is offered as commercial panels for Ashkenazi couples by both CIGNA and Quest Diagnostics. The CIGNA panel is available for testing for parental/preconception screening or following chorionic villus sampling or amniocentesis and tests for Bloom syndrome, Canavan disease, cystic fibrosis, familial dysautonomia, Fanconi anemia, Gaucher disease, mucolipidosis IV, Neimann-Pick disease type A, Tay-Sachs disease, and torsion dystonia. The Quest panel is for parental/preconception testing and tests for Bloom syndrome, Canavan disease, cystic fibrosis, familial dysautonomia, Fanconi anemia group C, Gaucher disease, Neimann-Pick disease types A and B, and Tay-Sachs disease.

The official recommendations of the American College of Obstetricians and Gynecologists is that Ashkenazi individuals be offered screening for Tay-Sachs disease, Canavan disease, cystic fibrosis, and familial dysautonomia as part of routine obstetrical care.

In the orthodox community, an organization called Dor Yeshorim carries out anonymous genetic screening of couples before marriage to reduce the risk of children with genetic diseases being born. The program educates young people on medical genetics and screens school-aged children for any disease genes. These results are then entered into an anonymous database, identified only by a unique ID number given to the person who was tested. If two people are considering getting married, they call the organization and tell them their ID numbers. The organization then tells them if they are genetically compatible. It is not divulged if one member is a carrier, so as to protect the carrier and his or her family from stigmatization. However, this program has been criticized for exerting social pressure on people to be tested, and for screening for a broad range of recessive genes, including disorders such as Gaucher disease.

Criticism

Hebrew University Professor Raphael Falk published a criticism of studies identifying genetic disorders as being the result of hereditary endogamy.

Dr. Sherry Brandt-Rauf of the University of Illinois and Sheila Rothman of Columbia University co-authored a critique of the methodologies as well as condemning those who worked on the eugenic studies which attributed genetic disorders to religious demographics in paper which explored the ramifications of such concepts entering the workplace stating, "such linkages 'exaggerate genetic differences among ethnic groups' and may result in 'health disparities' in groups not targeted for screening. There has been a tendency to consider Tay-Sachs an exclusively "Jewish" genetic disorder and, as a result of this bias, non-Jewish children with Tay-Sachs may not initially have their disease properly diagnosed and non-Jewish heterozygous carriers may not be aware that they still could carry one of its genetic variants. In a peer-reviewed medical study, a team of researchers from 23andMe, one of whom (Noura Abul-Husn) is an Associate Professor of Medicine and Genetics at the Icahn School of Medicine at Mount Sinai, criticized guidelines and policies that restrict Tay-Sachs genetic screening to Jews, French Canadians, and Cajuns. This team found that 59.4 percent of their data pool of 22,681 participants who carry one Tay-Sachs-causing variant on one side of their pair of relevant chromosomes "did not self-report qualifying ethnicity" (one of the three aforementioned populations). They also found that 51.3 percent of participants who carry one Ashkenazi-associated pathogenic variant for 15 different diseases had less than 20 percent Ashkenazi autosomal admixture as calculated by 23andMe. They concluded that restrictive testing "leads to the under detection of heterozygotes and associated reproductive risk" of having a child with a serious disease.

See also

References

  1. ^ Paul DB, Spencer HG (December 2008). Keller EF (ed.). ""It's ok, we're not cousins by blood": the cousin marriage controversy in historical perspective". PLOS Biology. 6 (12): 2627–30. doi:10.1371/journal.pbio.0060320. PMC 2605922. PMID 19108607.
  2. ^ Rosner G, Rosner S, Orr-Urtreger A (2009). "Genetic testing in Israel: an overview". Annual Review of Genomics and Human Genetics. 10: 175–92. doi:10.1146/annurev.genom.030308.111406. PMID 19453249. S2CID 8964636.
  3. ^ Bloch T (21 August 2009). "Sephardi Jews lack screening programs for their genetic diseases". Haaretz.
  4. ^ Kolata G (7 December 1993). "Nightmare or the Dream Of a New Era in Genetics?". New York Times.
  5. ^ Ostrer H (November 2001). "A genetic profile of contemporary Jewish populations". Nature Reviews. Genetics. 2 (11): 891–8. doi:10.1038/35098506. PMID 11715044. S2CID 3938664.
  6. ^ Levin M (1999). "Screening Jews and genes: a consideration of the ethics of genetic screening within the Jewish community: challenges and responses". Genetic Testing. 3 (2): 207–13. doi:10.1089/gte.1999.3.207. PMID 10464669.
  7. ^ Abel 2001, p. 7
  8. Bachrach S (July 2004). "In the name of public health--Nazi racial hygiene". The New England Journal of Medicine. 351 (5): 417–20. doi:10.1056/NEJMp048136. PMID 15282346.
  9. Modell B, Darr A (March 2002). "Science and society: genetic counselling and customary consanguineous marriage". Nature Reviews. Genetics. 3 (3): 225–9. doi:10.1038/nrg754. PMID 11972160. S2CID 3329927.
  10. ^ Carmeli DB (September 2004). "Prevalence of Jews as subjects in genetic research: figures, explanation, and potential implications". American Journal of Medical Genetics. Part A. 130A (1): 76–83. doi:10.1002/ajmg.a.20291. PMID 15368499. S2CID 23251307.
  11. Atzmon G, Schechter C, Greiner W, Davidson D, Rennert G, Barzilai N (February 2004). "Clinical phenotype of families with longevity". Journal of the American Geriatrics Society. 52 (2): 274–7. doi:10.1111/j.1532-5415.2004.52068.x. PMID 14728640. S2CID 31740586.
  12. Atzmon G, Cho M, Cawthon RM, Budagov T, Katz M, Yang X, et al. (January 2010). "Evolution in health and medicine Sackler colloquium: Genetic variation in human telomerase is associated with telomere length in Ashkenazi centenarians". Proceedings of the National Academy of Sciences of the United States of America. 107 Suppl 1 (suppl_1): 1710–7. Bibcode:2010PNAS..107.1710A. doi:10.1073/pnas.0906191106. PMC 2868292. PMID 19915151.
  13. Carmi S, Hui KY, Kochav E, Liu X, Xue J, Grady F, et al. (9 September 2014). "Sequencing an Ashkenazi reference panel supports population-targeted personal genomics and illuminates Jewish and European origins". Nature Communications. 5 (1): 4835. Bibcode:2014NatCo...5.4835C. doi:10.1038/ncomms5835. PMC 4164776. PMID 25203624.
  14. Schuster, Ruth (9 September 2014). "Ashkenazi Jews Descend From 350 People, Scientists Say". The Forward.
  15. Behar DM, Hammer MF, Garrigan D, Villems R, Bonne-Tamir B, Richards M, Gurwitz D, Rosengarten D, Kaplan M, Della Pergola S, Quintana-Murci L, Skorecki K, et al. (May 2004). "MtDNA evidence for a genetic bottleneck in the early history of the Ashkenazi Jewish population". European Journal of Human Genetics. 12 (5): 355–64. doi:10.1038/sj.ejhg.5201156. PMID 14722586.
  16. Wade N (4 March 2003). "Diseases Common in Ashkenazim May Be Random". New York Times.
  17. Orr-Urtreger A, Shifrin C, Rozovski U, Rosner S, Bercovich D, Gurevich T, Yagev-More H, Bar-Shira A, Giladi N, et al. (October 2007). "The LRRK2 G2019S mutation in Ashkenazi Jews with Parkinson disease: is there a gender effect?". Neurology. 69 (16): 1595–602. doi:10.1212/01.wnl.0000277637.33328.d8. PMID 17938369. S2CID 22029316.
  18. "Warsaw Breakage Syndrome". GOV.IL. Retrieved 9 April 2023.
  19. "Tay–Sachs Disease Information Page". National Institute of Neurological Disorders and Stroke. 14 February 2007. Archived from the original on 2 December 2016. Retrieved 25 May 2008.
  20. Sutton VR (June 2002). "Tay-Sachs disease screening and counseling families at risk for metabolic disease". Obstetrics and Gynecology Clinics of North America. 29 (2): 287–96. doi:10.1016/S0889-8545(01)00002-X. PMID 12108829.
  21. Buckles J (20 August 2001). "The Success Story of Gene Tests". Genome News Network, J. Craig Venter Institute. Retrieved 14 April 2008.
  22. Diaz GA, Gelb BD, Risch N, Nygaard TG, Frisch A, Cohen IJ, Miranda CS, Amaral O, Maire I, Poenaru L, Caillaud C, Weizberg M, Mistry P, Desnick RJ, et al. (June 2000). "Gaucher disease: the origins of the Ashkenazi Jewish N370S and 84GG acid beta-glucosidase mutations". American Journal of Human Genetics. 66 (6): 1821–32. doi:10.1086/302946. PMC 1378046. PMID 10777718.'
  23. "National Gaucher Foundation". Archived from the original on 17 May 2007. Retrieved 30 May 2007.
  24. "Diseases: Mucolipidosis". Mount Sinai – Center for Jewish Genetic Diseases – Department of Human Genetics. Archived from the original on 17 February 2007.
  25. "Ashkenazi Disorders: Mendelian – Niemann–Pick disease". The Chicago Center for Jewish Genetic Disorders.
  26. Boas FE (August 2000). "Linkage to Gaucher mutations in the Ashkenazi population: effect of drift on decay of linkage disequilibrium and evidence for heterozygote selection". Blood Cells, Molecules & Diseases. 26 (4): 348–59. doi:10.1006/bcmd.2000.0314. PMID 11042036. S2CID 9665010.
  27. Harpending H, Cochran G (March 2006). "Genetic diversity and genetic burden in humans". Infection, Genetics and Evolution. 6 (2): 154–62. Bibcode:2006InfGE...6..154H. doi:10.1016/j.meegid.2005.04.002. PMID 16246638.
  28. "Ashkenazi Disorders: Mendelian – Familial dysautonomia". The Chicago Center for Jewish Genetic Disorders.
  29. about one in 30 Ashkenazi Jews carry the disease, compared to 1 in 3000 of the general population
  30. Webb, B. D.; Brandt, T.; Liu, L.; Jalas, C.; Liao, J.; Fedick, A.; Linderman, M. D.; Diaz, G. A.; Kornreich, R.; Trachtman, H.; Mehta, L.; Edelmann, L. (2014). "A founder mutation in COL4A3 causes autosomal recessive Alport syndrome in the Ashkenazi Jewish population". Clinical Genetics. 86 (2): 155–160. doi:10.1111/cge.12247. PMID 23927549. S2CID 29058203.
  31. "Ashkenazi Jews and Colorectal Cancer". The Chicago Center for Jewish Genetic Disorders.
  32. "Ashkenazi Disorders: Mendelian – Non-Classical Adrenal Hyperplasia". Jewish Genetic Disorders Organization.
  33. Shalimar A, Sharaf I, Farah Wahida I, Ruszymah BH (December 2007). "Congenital insensitivity to pain with anhydrosis in a Malaysian family: a genetic analysis" (PDF). Journal of Orthopaedic Surgery. 15 (3): 357–60. doi:10.1177/230949900701500323. PMID 18162686. Type III is familial dysautonomia or Riley–Day syndrome. It is multisystemic and affects mainly Ashkenazi Jews.
  34. Shugart YY, Silverberg MS, Duerr RH, Taylor KD, Wang MH, Zarfas K, et al. (March 2008). "An SNP linkage scan identifies significant Crohn's disease loci on chromosomes 13q13.3 and, in Jewish families, on 1p35.2 and 3q29". Genes and Immunity. 9 (2): 161–7. doi:10.1038/sj.gene.6364460. PMC 3858857. PMID 18246054.
  35. "Large multicenter study suggests new genetic markers for Crohn's disease". EurekAlert!.
  36. Gutkind L, Kennedy P (10 October 2013). An Immense New Power to Heal: The Promise of Personalized Medicine. Underland Press. pp. 36–. ISBN 978-1-937163-07-5.
  37. Weissmann A, Linn S, Weltfriend S, Friedman-Birnbaum R (March 2000). "Epidemiological study of classic Kaposi's sarcoma: a retrospective review of 125 cases from Northern Israel". Journal of the European Academy of Dermatology and Venereology. 14 (2): 91–5. doi:10.1046/j.1468-3083.2000.00022.x. PMID 10972092. S2CID 22736133.
  38. "Ashkenazi Jewish Diseases". Tufts Medical Center.
  39. "Ashkenazi Disorders: Mendelian – Mucolipidosis IV". The Chicago Center for Jewish Genetic Disorders.
  40. "Myeloproliferative Neoplasms". Cancer Network. Archived from the original on 1 May 2020. Retrieved 14 September 2018.
  41. "Ashkenazi Disorders: Mendelian – Nonsyndromic Hearing Loss and Deafness, DFNB1 (Connexin 26)". The Chicago Center for Jewish Genetic Disorders.
  42. Bonifati V (October 2006). "Parkinson's disease: the LRRK2-G2019S mutation: opening a novel era in Parkinson's disease genetics". European Journal of Human Genetics. 14 (10): 1061–2. doi:10.1038/sj.ejhg.5201695. PMID 16835587.
  43. Lesage S, Patin E, Condroyer C, Leutenegger AL, Lohmann E, Giladi N, et al. (May 2010). "Parkinson's disease-related LRRK2 G2019S mutation results from independent mutational events in humans". Human Molecular Genetics. 19 (10): 1998–2004. doi:10.1093/hmg/ddq081. PMID 20197411.
  44. Zimprich A, Biskup S, Leitner P, Lichtner P, Farrer M, Lincoln S, et al. (November 2004). "Mutations in LRRK2 cause autosomal-dominant parkinsonism with pleomorphic pathology". Neuron. 44 (4): 601–7. doi:10.1016/j.neuron.2004.11.005. PMID 15541309. We have previously linked families with autosomal-dominant, late-onset parkinsonism to chromosome 12p11.2-q13.1 (PARK8)...
  45. Klein J, Sato A (September 2000). "The HLA system. Second of two parts". The New England Journal of Medicine. 343 (11): 782–6. doi:10.1056/NEJM200009143431106. PMID 10984567.
  46. Efrati I (26 November 2013). "Scientists Discover Gene That Predisposes Ashkenazi Jews to Schizophrenia". Haaretz Newspaper.
  47. "Glycogen Storage Disease Type Ia Mutation Analysis (Ashkenazi Jewish)". Archived from the original on 6 March 2016. Retrieved 11 November 2011.
  48. Ahn JK, Lev D, Leshinsky-Silver E, Ginzberg M, Lerman-Sagie T (June 2003). "A new autosomal recessive syndrome with Zellweger-like manifestations". American Journal of Medical Genetics. Part A. 119A (3): 352–5. doi:10.1002/ajmg.a.20124. PMID 12784304. S2CID 26432877. A son and daughter of consanguineous Ashkenazi Jewish parents presented with phenotypic features that are typically seen in Zellweger syndrome...
  49. Marek-Yagel D, Berkun Y, Padeh S, Abu A, Reznik-Wolf H, Livneh A, Pras M, Pras E (June 2009). "Clinical disease among patients heterozygous for familial Mediterranean fever". Arthritis and Rheumatism. 60 (6): 1862–6. doi:10.1002/art.24570. PMID 19479871.
  50. "Women with G6PD Deficiency". g6pd-deficiency.org.
  51. Kaback MM (December 2000). "Population-based genetic screening for reproductive counseling: the Tay-Sachs disease model". European Journal of Pediatrics. 159 (Suppl 3): S192-5. doi:10.1007/PL00014401. PMID 11216898. S2CID 5808156.
  52. Kronn D, Jansen V, Ostrer H (April 1998). "Carrier screening for cystic fibrosis, Gaucher disease, and Tay-Sachs disease in the Ashkenazi Jewish population: the first 1000 cases at New York University Medical Center, New York, NY". Archives of Internal Medicine. 158 (7): 777–81. doi:10.1001/archinte.158.7.777. PMID 9554684.
  53. ACOG committee on genetics (October 2009). "ACOG Committee Opinion No. 442: Preconception and prenatal carrier screening for genetic diseases in individuals of Eastern European Jewish descent". Obstetrics and Gynecology. 114 (4): 950–3. doi:10.1097/AOG.0b013e3181bd12f4. PMID 19888064. S2CID 13136589.
  54. ^ Ekstein J, Katzenstein H (2001). "23. The Dor Yeshorim story: Community-based carrier screening for Tay-Sachs disease". Tay-Sachs Disease. Advances in Genetics. Vol. 44. pp. 297–310. doi:10.1016/S0065-2660(01)44087-9. ISBN 978-0-12-017644-1. PMID 11596991.
  55. Falk, Raphael (23 May 2014). "Genetic markers cannot determine Jewish descent". Frontiers in Genetics. 5: 462. doi:10.3389/fgene.2014.00462. PMC 4301023. PMID 25653666.
  56. Brandt-Rauf, Paul W.; Brandt-Rauf, Sherry I. (23 May 2004). "Genetic testing in the workplace: ethical, legal, and social implications". Annual Review of Public Health. 25: 139–153. doi:10.1146/annurev.publhealth.25.101802.123012. PMID 15015916.
  57. ^ Llorin, Hannah; Tennen, Ruth; Laskey, Sarah; Zhan, Jianan; Detweiler, Stacey; Abul-Husn, Noura S. (16 July 2024). "Shortcomings of ethnicity-based carrier screening for conditions associated with Ashkenazi Jewish ancestry". Genetics in Medicine Open. 2: 101869. doi:10.1016/j.gimo.2024.101869. PMC 11613755.

Further reading

External links

Categories: