Your search keyword '"Medical genetics of Jews"' showing total 22 results

1. Experiences from a pilot program bringing BRCA1/2 genetic screening to the

Author

Chana Wiesman, Allison Grant, Nicole Schreiber-Agus, Esther D. Rose, Susan Klugman, and Adam Zimilover

Subjects

0301 basic medicine, Genetics, education.field_of_study, medicine.medical_specialty, business.industry, Population, Brca testing, 030105 genetics & heredity, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, Family medicine, Pilot program, Medicine, Ashkenazi Jewish, Population screening, business, education, Genetics (clinical), Medical genetics of Jews

Abstract

Experiences from a pilot program bringing BRCA1/2 genetic screening to theUS Ashkenazi Jewish population

Published

2017

2. Correction: Population screening for BRCA1/BRCA2 founder mutations in Ashkenazi Jews: proactive recruitment compared with self-referral

Author

Sari Lieberman, Bella Kaufman, Aviad E. Raz, Ephrat Levy-Lahad, Itzhak Glick, Oded Olsha, Avi Ben-Chetrit, Karen Djemal, Miri Sklair, Ariela Tomer, Sivan Koka, Todd Zalut, Rachel Beeri, Shalom Strano, Hila Fridman, Shlomo Segev, and Amnon Lahad

Subjects

0301 basic medicine, Genetics, Self Referral, medicine.medical_specialty, business.industry, Genetic counseling, Ashkenazi jews, 03 medical and health sciences, Distress, 030104 developmental biology, 0302 clinical medicine, 030220 oncology & carcinogenesis, Internal medicine, medicine, Anxiety, Family history, medicine.symptom, business, Psychosocial, Genetics (clinical), Medical genetics of Jews

Abstract

Population screening of three common BRCA1/BRCA2 mutations in Ashkenazi Jews (AJ) apparently fulfills screening criteria. We compared streamlined BRCA screening via self-referral with proactive recruitment in medical settings. Unaffected AJ, age ≥25 years without known familial mutations, were either self-referred or recruiter-enrolled. Before testing, participants received written information and self-reported family history (FH). After testing, both non-carriers with significant FH and carriers received in-person genetic counseling. Psychosocial questionnaires were self-administered 1 week and 6 months after enrollment. Of 1,771 participants, 58% were recruiter-enrolled and 42% were self-referred. Screening uptake was 67%. Recruited enrollees were older (mean age 54 vs. 48, P 90%). At 6 months, carriers had significantly increased distress and anxiety, greater knowledge, and similar satisfaction; 90% of participants would recommend general AJ BRCA screening. Streamlined BRCA screening results in high uptake, very high satisfaction, and no excess psychosocial harm. Proactive recruitment captured older women less selected for FH. Further research is necessary to target younger women and assess other populations. Genet Med advance online publication 08 December 2016

Published

2020

3. Knowledge, attitudes, and barriers to carrier screening for the Ashkenazi Jewish panel: a Florida experience

Author

Elizabeth Herman, Jessica R. L. Warsch, Sean Warsch, L. Zakarin, Deborah Wasserman, Jodi D. Hoffman, Adele Schneider, and Deborah Barbouth

Subjects

Gerontology, education.field_of_study, medicine.medical_specialty, Epidemiology, business.industry, Public health, Population, Public Health, Environmental and Occupational Health, Test (assessment), Likert scale, medicine, Original Article, Young adult, Carrier screening, education, business, Genetics (clinical), Medical genetics of Jews, Demography

Abstract

The knowledge, attitudes, and barriers to Jewish genetic diseases (JGDs) and screening and their relative importance in reproductive decision-making were assessed in a population-based sample of Ashkenazi Jewish young adults in Florida. These adults attended educational screening fairs hosted by The Victor Center for the Prevention of Jewish Genetic Diseases at the University of Miami. Parametric and nonparametric tests were used as appropriate to analyze data from a single group pretest/posttest design. Four hundred twelve individuals (mean age = 24.9; 54.7 % female, 45.3 % male) completed the questionnaires. Participants' level of knowledge increased from pre- to post-intervention (81.4 vs. 91.0 %; p

Published

2014

4. Diabetes and RACE A Historical Perspective

Author

Arleen Marcia Tuchman

Subjects

Gerontology, medicine.medical_specialty, Epidemiology, Population, Type 2 diabetes, Disease, Criminology, Race (biology), medicine, Humans, Narrative, Sociology, education, Stereotyping, Government, education.field_of_study, Public Health Then and Now, Public health, Racial Groups, Public Health, Environmental and Occupational Health, History, 20th Century, medicine.disease, United States, Diabetes Mellitus, Type 2, Jews, Medical genetics of Jews

Abstract

Today, US government sources inform us that Native Americans, Blacks, and Hispanics/Latinos run the greatest risk of developing type 2 diabetes. One hundred years ago, however, Jews were thought to be the population most likely to develop this disease. I evaluated the evidence that the medical and public health communities provided to support the purported link between diabetes and Jews. Diabetes was conceptualized as a Jewish disease not necessarily because its prevalence was high among this population, but because medicine, science, and culture reinforced each other, helping to construct narratives that made sense at the time. Contemporary narratives are as problematic as the erstwhile depiction of diabetes as a disease of Jews.

Published

2011

5. Development of Genomic DNA Reference Materials for Genetic Testing of Disorders Common in People of Ashkenazi Jewish Descent

Author

Louis Geller, Arlene Buller, Jean Amos Wilson, William Edward Highsmith, Kasinathan Muralidharan, Tina Sellers, Ruth Kornreich, Elizabeth M. Rohlfs, Toby L. Payeur, Lisa Edelmann, Leonard M. Holtegaard, Lisa V. Kalman, Lorraine Toji, and John Dixon

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, medicine.medical_specialty, Canavan Disease, Population, Disease, Pathology and Forensic Medicine, Fanconi anemia, Dysautonomia, Familial, medicine, Humans, Genetic Testing, education, Alleles, Genetic testing, Niemann-Pick Diseases, Genetics, education.field_of_study, Gaucher Disease, Tay-Sachs Disease, medicine.diagnostic_test, business.industry, Tay-Sachs disease, nutritional and metabolic diseases, medicine.disease, Canavan disease, Fanconi Anemia, Jews, Molecular Medicine, Medical genetics, business, Bloom Syndrome, Medical genetics of Jews, Regular Articles

Abstract

Many recessive genetic disorders are found at a higher incidence in people of Ashkenazi Jewish (AJ) descent than in the general population. The American College of Medical Genetics and the American College of Obstetricians and Gynecologists have recommended that individuals of AJ descent undergo carrier screening for Tay Sachs disease, Canavan disease, familial dysautonomia, mucolipidosis IV, Niemann-Pick disease type A, Fanconi anemia type C, Bloom syndrome, and Gaucher disease. Although these recommendations have led to increased test volumes and number of laboratories offering AJ screening, well-characterized genomic reference materials are not publicly available. The Centers for Disease Control and Prevention-based Genetic Testing Reference Materials Coordination Program, in collaboration with members of the genetic testing community and Coriell Cell Repositories, have developed a panel of characterized genomic reference materials for AJ genetic testing. DNA from 31 cell lines, representing many of the common alleles for Tay Sachs disease, Canavan disease, familial dysautonomia, mucolipidosis IV, Niemann-Pick disease type A, Fanconi anemia type C, Bloom syndrome, Gaucher disease, and glycogen storage disease, was prepared by the Repository and tested in six clinical laboratories using three different PCR-based assay platforms. A total of 33 disease alleles was assayed and 25 different alleles were identified. These characterized materials are publicly available from Coriell and may be used for quality control, proficiency testing, test development, and research.

Published

2009

6. Type 2 Gaucher disease occurs in Ashkenazi Jews but is surprisingly rare

Author

Ian J. Cohen, Yisaac Yaniv, Joseph Attias, Avinoam Rachmel, Ben-Zion Garty, Hagit N. Baris, Avinoam Shuffer, Ellen Sidransky, and Shraga Aviner

Subjects

Proband, Genetics, congenital, hereditary, and neonatal diseases and abnormalities, education.field_of_study, endocrine system diseases, business.industry, Judaism, Population, nutritional and metabolic diseases, Cell Biology, Hematology, Ashkenazi jews, Genotype, Molecular Medicine, Medicine, Allele, skin and connective tissue diseases, business, education, Molecular Biology, Glucocerebrosidase, Medical genetics of Jews

Abstract

Patients with Gaucher disease (GD) are divided into three types based on the presence and rate of progression of the neurologic manifestations. While type 1 GD has a strong predilection in the Jewish Ashkenazi population, both other types lack such a propensity. We report the occurrence of type 2 GD (GD2) in four pregnancies in two Jewish families in Israel (in one case the mother was not Ashkenazi but was from a Sfaradi Jewish family) and also review seven additional cases of GD2 in Ashkenazi Jewish families reported in the literature. Phenotypically, GD2 in Ashkenazi Jews does not differ significantly from this form in other ethnic groups. Genotypic analysis of probands from the two Israeli families demonstrates that each carried two heterozygous glucocerebrosidase mutations. We could find no explanation why GD2 is so rare in the Jewish Ashkenazi population but we could hypothesize that homozygosity for certain Ashkenazi alleles might be lethal, leading to a lower than expected frequency of GD2 and noted that no cases of homozygous L444P has ever been described in Ashkenazi Jews

Published

2009

7. Genetic contribution to multiple sclerosis risk among Ashkenazi Jews

Author

Jorge R. Oksenberg, Pouya Khankhanian, Jayaji M. Moré, Takuya Matsushita, Antoine Lizee, Stephen L. Hauser, Lennox Din, Lohith Madireddy, Sergio E. Baranzini, and Pierre-Antoine Gourraud

Subjects

Proband, Male, endocrine system diseases, Population genetics, Genome-wide association study, Neurodegenerative, Gene Frequency, Risk Factors, 2.1 Biological and endogenous factors, Genetics(clinical), skin and connective tissue diseases, Genetics (clinical), Genetics, Genetics & Heredity, Single Nucleotide, HLA-B38 Antigen, Ashkenazi jews, 3. Good health, Neurological, Female, Medical genetics of Jews, Research Article, congenital, hereditary, and neonatal diseases and abnormalities, Multiple Sclerosis, Clinical Sciences, HLA-C Antigens, Biology, Polymorphism, Single Nucleotide, Autoimmune Disease, Clinical Research, Genetic predisposition, Humans, Genetic Predisposition to Disease, Family, Allele, Polymorphism, Alleles, HLA-A Antigens, Prevention, Haplotype, Human Genome, Neurosciences, nutritional and metabolic diseases, Brain Disorders, Haplotypes, Case-Control Studies, Jews

Abstract

Background Multiple sclerosis (MS) is an autoimmune disease of the central nervous system, with a strong genetic component. Over 100 genetic loci have been implicated in susceptibility to MS in European populations, the most prominent being the 15:01 allele of the HLA-DRB1 gene. The prevalence of MS is high in European populations including those of Ashkenazi origin, and low in African and Asian populations including those of Jewish origin. Methods Here we identified and extracted a total of 213 Ashkenazi MS cases and 546 ethnically matched healthy control individuals from two previous genome-wide case-control association analyses, and 72 trios (affected proband and two unaffected parents) from a previous genome-wide transmission disequilibrium association study, using genetic data to define Ashkenazi. We compared the pattern of genetic risk between Ashkenazi and non-Ashkenazi Europeans. We also sought to identify novel Ashkenazi-specific risk loci by performing association tests on the subset of Ashkenazi cases, controls, probands, and parents from each study. Results The HLA-DRB1*15:01 allele and the non-HLA risk alleles were present at relatively low frequencies among Ashkenazi and explained a smaller fraction of the population-level risk when compared to non-Ashkenazi Europeans. Alternative HLA susceptibility alleles were identified in an Ashkenazi-only association study, including HLA-A*68:02 and one or both genes in the HLA-B*38:01-HLA-C*12:03 haplotype. The genome-wide screen in Ashkenazi did not reveal any loci associated with MS risk. Conclusion These results suggest that genetic susceptibility to MS in Ashkenazi Jews has not been as well established as that of non-Ashkenazi Europeans. This implies value in studying large well-characterized Ashkenazi populations to accelerate gene discovery in complex genetic diseases. Electronic supplementary material The online version of this article (doi:10.1186/s12881-015-0201-2) contains supplementary material, which is available to authorized users.

Published

2015

8. A Population-Genetic Test of Founder Effects and Implications for Ashkenazi Jewish Diseases

Author

Montgomery Slatkin

Subjects

Linkage disequilibrium, Population, Population genetics, Biology, Identity by descent, Linkage Disequilibrium, 03 medical and health sciences, 0302 clinical medicine, Gene Frequency, Mucolipidoses, Genetics, Humans, Genetics(clinical), education, Allele frequency, Genetics (clinical), 030304 developmental biology, 0303 health sciences, education.field_of_study, Gaucher Disease, Articles, Founder Effect, Ashkenazi jews, Adenomatous Polyposis Coli, Data Interpretation, Statistical, Jews, 030217 neurology & neurosurgery, Medical genetics of Jews, Founder effect

Abstract

A founder effect can account for the presence of an allele at an unusually high frequency in an isolated population if the allele is selectively neutral and if all copies are identical by descent with a copy that either was carried by a founder individual or arose by mutation later. Here, a statistical test of both aspects of the founder-effect hypothesis is developed. The test is performed by a modified version of a program that implements the Slatkin-Bertorelle test of neutrality. The test is applied to several disease-associated alleles found predominantly in Ashkenazi Jews. Despite considerable uncertainty about the demographic history of Ashkenazi Jews and their ancestors, available genetic data are consistent with a founder effect resulting from a severe bottleneck in population size between a.d. 1100 and a.d. 1400 and an earlier bottleneck in a.d. 75, at the beginning of the Jewish Diaspora. The relatively high frequency of alleles causing four different lysosomal storage disorders, including Tay-Sachs disease and Gaucher disease, can be accounted for if the disease-associated alleles are recessive in their effects on reproductive fitness.

Published

2004

9. DNA-based carrier screening in the Ashkenazi Jewish population

Author

Bailing Zhang, Linda Dearing, and Jean Amos

Subjects

Heterozygote, medicine.medical_specialty, Genetic counseling, DNA Mutational Analysis, Population, Genetic Counseling, Carrier testing, Pathology and Forensic Medicine, Risk Factors, Fanconi anemia, Genetics, medicine, Humans, Ashkenazi Jewish, Europe, Eastern, Genetic Testing, education, Molecular Biology, Genetic testing, education.field_of_study, medicine.diagnostic_test, business.industry, Tay-Sachs disease, Genetic Diseases, Inborn, medicine.disease, Molecular Diagnostic Techniques, Jews, Family medicine, Mutation, Molecular Medicine, business, Medical genetics of Jews

Abstract

Several relatively rare genetic diseases are found at greater frequencies in Ashkenazi Jewish populations. Most of these conditions are untreatable and shorten life expectancy. Genetic screening using molecular detection of a few common mutations for each of these diseases facilitates their prevention by identification of carrier couples. Conversely, couples with negative results are reassured by reduced carrier risks. Using a standardized format, a brief overview for each of the nine genetic diseases is presented. Known mutations, a short clinical summary, clinical and laboratory diagnostic methods and information on supportive treatments is provided for each. Finally, a brief discussion of available DNA testing technologies and a review of platforms for expanded testing options for Ashkenazi Jewish diseases under development are presented.

Published

2004

10. Evaluation of two-year Jewish genetic disease screening program in Atlanta: insight into community genetic screening approaches

Author

Yunru Shao, Karen A. Grinzaid, and Shuling Liu

Subjects

education.field_of_study, medicine.medical_specialty, medicine.diagnostic_test, Descriptive statistics, Epidemiology, business.industry, Medical record, Public health, Population, Public Health, Environmental and Occupational Health, Bioinformatics, Outreach, Disease Screening, Family medicine, medicine, Original Article, education, business, Genetics (clinical), Medical genetics of Jews, Genetic testing

Abstract

Improvements in genetic testing technologies have led to the development of expanded carrier screening panels for the Ashkenazi Jewish population; however, there are major inconsistencies in current screening practices. A 2-year pilot program was launched in Atlanta in 2010 to promote and facilitate screening for 19 Jewish genetic diseases. We analyzed data from this program, including participant demographics and outreach efforts. This retrospective analysis is based on a de-identified dataset of 724 screenees. Data were obtained through medical chart review and questionnaires and included demographic information, screening results, response to outreach efforts, and follow-up behavior and preferences. We applied descriptive analysis, chi-square tests, and logistic regression to analyze the data and compare findings with published literature. The majority of participants indicated that they were not pregnant or did not have a partner who was pregnant were affiliated with Jewish organizations and reported 100 % AJ ancestry. Overall, carrier frequency was 1 in 3.9. Friends, rabbis, and family members were the most common influencers of the decision to receive screening. People who were older, had a history of pregnancy, and had been previously screened were more likely to educate others (all p

Published

2014

11. Age Estimate of the N370S Mutation Causing Gaucher Disease in Ashkenazi Jews and European Populations: A Reappraisal of Haplotype Data

Author

Roberto Colombo

Subjects

Genetics, Linkage disequilibrium, education.field_of_study, Population, Haplotype, Locus (genetics), Gaucher disease, Biology, Founder effect, Ashkenazi jews, Report, Mutation(s), Age of, Genetics(clinical), education, Allele frequency, Population(s), Ashkenazi, Genetics (clinical), Medical genetics of Jews

Abstract

SummaryThe N370S mutation at the GBA locus on human chromosome 1q21, which causes Gaucher disease (GD), has a high frequency in the Ashkenazim and is the second-most-widespread GD mutation in the European non-Jewish population. A common ancient origin for the N370S mutation in the Ashkenazi Jewish and Spanish populations has been proposed on the basis of both a similar haplotype for associated markers and an age estimate that suggests that this mutation appeared several thousand years ago. However, a reappraisal of haplotype data, using the Risch formula properly along with a Luria-Delbrück setting of the genetic clock, allows identification of the likely origin of the N370S mutation in Ashkenazi Jews between the 11th and 13th centuries. This result is consistent with the estimated ages of other mutations that are frequent among Ashkenazim, with the exception of type II (Glu117Stop) factor XI deficiency, which is deemed to be >3000 years old, predating the separation of the Ashkenazi and Iraqi Jews. The present finding supports the hypothesis of a more recent origin for the N370S mutation and is consistent with both a founder chromosome transfer from Ashkenazim who assimilated in some European populations and a non-Jewish origin of the European N370S-bearing chromosomes.

Published

2000

12. Mendelian Diseases among Roman Jews: Implications for the Origins of Disease Alleles

Author

Carole Oddoux, Michael A. Nardi, H Nelson, E Dicave, Harry Ostrer, Khedoudja Nafa, Margaret Karpatkin, H Peretz, Maria Roberta Cilio, C Ditivoli, Daniel L. Kastner, Kyriakie Sarafoglou, Encarna Guillén-Navarro, U Seligsohn, Felicia B. Axelrod, Ivona Aksentijevich, N McCain, C M Clayton, and Lucio Luzzatto

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Cystic Fibrosis, endocrine system diseases, Endocrinology, Diabetes and Metabolism, Rome, Clinical Biochemistry, Familial Mediterranean fever, Biology, Biochemistry, Connexins, symbols.namesake, Endocrinology, Gene Frequency, Fanconi anemia, medicine, Humans, Allele, Alleles, Genetics, Gaucher Disease, Biochemistry (medical), Haplotype, Genetic Diseases, Inborn, nutritional and metabolic diseases, medicine.disease, humanities, Ashkenazi jews, Connexin 26, Endogamy, Jews, Mutation, Mendelian inheritance, symbols, Medical genetics of Jews

Abstract

The Roman Jewish community has been historically continuous in Rome since pre-Christian times and may have been progenitor to the Ashkenazi Jewish community. Despite a history of endogamy over the past 2000 yr, the historical record suggests that there was admixture with Ashkenazi and Sephardic Jews during the Middle Ages. To determine whether Roman and Ashkenazi Jews shared common signature mutations, we tested a group of 107 Roman Jews, representing 176 haploid sets of chromosomes. No mutations were found for Bloom syndrome, BRCA1, BRCA2, Canavan disease, Fanconi anemia complementation group C, or Tay-Sachs disease. Two unrelated individuals were positive for the 3849 + 10C->T cystic fibrosis mutation; one carried the N370S Gaucher disease mutation, and one carried the connexin 26 167delT mutation. Each of these was shown to be associated with the same haplotype of tightly linked microsatellite markers as that found among Ashkenazi Jews. In addition, 14 individuals had mutations in the familial Mediterranean fever gene and three unrelated individuals carried the factor XI type III mutation previously observed exclusively among Ashkenazi Jews. These findings suggest that the Gaucher, connexin 26, and familial Mediterranean fever mutations are over 2000 yr old, that the cystic fibrosis 3849 + 10kb C->T and factor XI type III mutations had a common origin in Ashkenazi and Roman Jews, and that other mutations prevalent among Ashkenazi Jews are of more recent origin.

Published

1999

13. The Possibility of a Selection Process in the Ashkenazi Jewish Population

Author

Gideon Bach and Joël Zlotogora

Subjects

Genetics, education.field_of_study, Population, Small population size, Biology, medicine.disease, Ashkenazi jews, Genetic drift, medicine, Genetics(clinical), Mucolipidosis type IV, Allele, education, Allele frequency, Genetics (clinical), Medical genetics of Jews

Abstract

To the Editor: In a recent article, Risch et al. (2003) analyzed the frequencies of the various inherited disorders that are found in relatively high frequency among Ashkenazi Jews. By comparing three parameters—namely, the numbers of allelic mutations, allele frequency distribution, and estimated coalescence dates of mutations—Risch et al. (2003) demonstrated a similar pattern of these parameters between lysosomal storage disorders (LSDs) and 14 prevalent nonlysosomal disorders (NLSDs) that are prevalent among Ashkenazi Jews. Their conclusion, therefore, was that the LSDs are not unique in this population and the relatively high prevalence of LSDs stems from a genetic drift, rather than a selection process in favor of the LSDs in this population, as suggested elsewhere (Zlotogora et al. 1988). However, although we agree on the importance of the genetic drift to explain the high frequency of mutation in the Ashkenazi Jewish population, we still think that selective advantage for carriers of LSDs was apparently another important factor. Among >10,000 established gene loci (MIM Statistics, March 2003), >20 are responsible for disorders found with an increased prevalence among Ashkenazi Jews. As expected in a random process, there is no known relationship between most of the genes responsible for these disorders. The exceptions are the four prevalent LSDs among Ashkenazim—namely, Tay-Sachs disease (TSD [MIM 272800]), Gaucher disease (GD1 [MIM 230800]), Niemann-Pick disease (NPD [MIM 257200]), and mucolipidosis type IV (MLIV [MIM 252650])—in which the mutations are in genes that encode for enzymes from a common biochemical pathway. In all cases, the main storage substances are sphingolipids: GM2 ganglioside in TSD, glucosylceramide in GD, sphingomyelin in NPD, and various gangliosides in MLIV. A further indication of a nonrandom process is the number of mutations responsible for each disorder. As expected for random events, in almost all the NLSDs, one mutation is prevalent, and, if more than one mutation is found, its frequency is significantly 10% prevalent, when compared with the frequency of the major mutation. For instance, in NPD, three mutations are found in equal frequencies, and, in MLIV, there are two common mutations with a ratio of ∼2:1. In TSD, the ratio of the three common mutations is 73:18:3.5. In GD, the ratio between the two common mutations is 77:13 (Zlotogora et al. 2000). Furthermore, it should be noted that the data for allelic frequencies in the Risch et al. (2003) paper was partially based on the frequencies obtained by the Dor Yeshorim screening program, which uses mutation analysis. That program is aimed at the detection of heterozygotes for some eight prevalent severe disorders among Ashkenazim and is designed for a specific section of that population, the ultraorthodox community. We have shown elsewhere (Bach et al. 2001) that the frequency of TSD and allelic distribution of the three common mutations, in a sample of 32,000 individuals in the Dor Yeshorim program, is significantly different from the distribution found in the Ashkenazi population at large. We have seen a similar trend with other disorders as well, including familial dysautonomy (FD [MIM 223900]), MLIV, and others (G. Bach, unpublished data). Indeed, this community represents a relatively close section in which most individuals originated from specific locations in Europe. Thus, the data for allelic distribution in the Ashkenazi population, as reported in the article (Risch et al. 2003), does not fully represent the true picture. Risch et al. (2003) demonstrated a diverse geographic distribution of allelic mutations in some of the Ashkenazim with LSDs; certain mutations originated in Central Europe, whereas others originated in Eastern Europe. We suggest that this does not contradict a selection process, but that it may point to a secondary genetic drift. A well-known selection process by malaria in favor of heterozygotes has been demonstrated for sickle cell anemia (HBB [MIM 603903]) and is suspected for other blood disorders, such as thalassemia (HBB [MIM 141900]). If we focus on β thalassemia as an example, many mutations have been described in the populations that were exposed to malaria for centuries. Comparing the allelic distribution among Jews who originated from a relatively small geographic region, the mutations were significantly different in the Iranian, Turkish, and Iraqi parts of the Kurdistan Mountains (Rund et al. 1991). Nowadays, the high prevalence of thalassemia among the Kurdish Jews in Israel is due to several mutations, as a result of two processes: selection and genetic drift. Determining the forces that led to the present observations in the Ashkenazi Jews is complicated, and there is no clear data for the nature of the selection process in favor of the carriers of LSDs, if that process occurred. It was suggested that certain lung disorders (i.e., pneumonia and tuberculosis) conferred a heterozygous advantage for these disorders (Myrianthopoulos and Melnick 1977). If this is indeed the basis for the selection phenomenon or, in fact, any other similar environmental factor, the occurrence of different geographic origins of the various allelic mutations or different coalescence dates does not contradict a selection process but, rather, strengthens it. Regarding Ashkenazi Jews, although we have no clear evidence for the selection force, we can safely assume that the environmental factor lasted for centuries and that there is no reason to doubt that this selection force was effective in Central Europe as well as in the eastern part. Medical care for the Jewish people was not basically different in these regions. Thus, we would expect to find diverse distributions of allelic mutations for a selection process. Although the four LSDs are recessive, it can be postulated that, under extreme conditions, such as lung disorders, heterozygotes might undergo even a slight lysosomal storage of these substances, which might confer beneficial resistance to these conditions. To try to understand the past, one can look at the present and foresee the future. This can be done for genetic diseases found nowadays in populations whose living conditions are similar to those of the Ashkenazi Jews in Europe. One example is the Arab population living in the Middle East, in which the preference is for consanguineous marriages, as was the case for the Ashkenazi Jews. For the Jews who lived in Europe, like the Arabs living nowadays in Israel, further reasons to marry within the community were religious and geopolitical. In these populations, many genetic diseases are found with a high prevalence, and, although most are due to a single random mutation, others present a different distribution. For instance, among Arabs in Galilee, several diseases are found with an increased prevalence. On a molecular basis, in most cases, a single founder mutation explains the relatively high frequency for each disease. However, for other diseases—such as metachromatic leukodystrophy (MLD [MIM 250100]), Hurler syndrome (MPS1 [MIM 252800]), hyperoxaluria (HP1 [MIM 259900]), or ataxia telangiectasia (AT [MIM 208900])—many different mutations were found (Zlotogora 2002). In each case, all the patients were homozygous for a single mutation that was frequent, in general, in one village only. Another example is the high frequency of Mendelian disorders among the Bedouins of the Negev, owing to, in most cases, random founder mutations (Sheffield et al. 1998). However, Bardet-Biedl syndrome (BBS [MIM 209900]) is present among the Bedouins of the Negev in a very high prevalence, owing to mutations in three different genes. These observations, of either several mutations in the same gene or mutations in different genes responsible for the high prevalence of some genetic diseases in relatively small populations, cannot be explained as a random phenomenon. The possibility of a selective phenomenon must be raised, even though it has not yet been characterized. It may be expected that, in the future, with the expansion and mixing of the population, some of these mutations will be lost, whereas others will remain. Some mutations that are the result of genetic drift will be relatively prevalent in the general Arab population. One may wonder why the selection phenomenon was restricted primarily to the Ashkenazim and not to the non-Jewish people around them. Two, equally plausible, assumptions might explain this phenomenon. (a) The Jews in Europe, particularly in earlier periods (i.e., the 10th–17th centuries) lived for the most part in an extremely poor socioeconomic status with poor medical management. Thus, a selection force by heterozygous advantage might have been more effective for that population. (b) The genetic background of Jews was shown to be unique and different from that of other European people. It can be postulated that this particular genetic structure might have conferred a higher sensitivity or susceptibility to certain lung disorders, when compared with other people in the same region. We, therefore, conclude that the LSDs among Ashkenazim represent a unique group indicating a nonrandom phenomenon that might be explained by a selection process. This does not contradict a genetic drift, as was indicated by Risch et al. (2003)

Published

2003

14. Population-based BRCA1/BRCA2 screening in Ashkenazi Jews: a call for evidence

Author

Ephrat Levy-Lahad

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, endocrine system diseases, Population, Breast Neoplasms, Population based, Brca1 brca2, Medicine, Humans, Ashkenazi Jewish, Genetic Predisposition to Disease, Genetic Testing, skin and connective tissue diseases, education, Genetics (clinical), Genetics, BRCA2 Protein, Ovarian Neoplasms, education.field_of_study, business.industry, BRCA1 Protein, nutritional and metabolic diseases, Ashkenazi jews, Deleterious alleles, Jews, Female, business, Medical genetics of Jews, Demography

Abstract

testing in the Ashkenazi Jewish population,aimed at reducing morbidity and mortality of breast/ovariancancer, is seemingly an obvious candidate for such a screeningprogram. In Ashkenazi Jews, three common, easily tested mu-tations account for the majority of deleterious alleles, effectivepreventive measures for

Published

2009

15. Carrier screening in individuals of Ashkenazi Jewish descent

Author

Susan J. Gross, Kristin G. Monaghan, and Beth A. Pletcher

Subjects

Genetics, medicine.medical_specialty, business.industry, media_common.quotation_subject, Genetic Carrier Screening, Disclaimer, Geneticist, Guideline, Carrier testing, Research Personnel, United States, Test (assessment), Family medicine, Jews, Health care, Medicine, Humans, Quality (business), Genetic Testing, business, Genetics (clinical), Medical genetics of Jews, media_common

Abstract

Disclaimer: This guideline is designed primarily as an educational resource for medical geneticists and other health care providers to help them provide quality medical genetic services. Adherence to this guideline does not necessarily assure a successful medical outcome. This guideline should not be considered inclusive of all proper procedures and tests or exclusive of other procedures and tests that are reasonably directed to obtaining the same results. In determining the propriety of any specific procedure or test, the geneticist should apply his or her own professional judgment to the specific clinical circumstances presented by the individual patient or specimen. It may be prudent, however, to document in the patient's record the rationale for any significant deviation from this guideline.

Published

2008

16. Ashkenazi Jews and Breast Cancer: The Consequences of Linking Ethnic Identity to Genetic Disease

Author

Jill A. Conte, Nathan F. Drummond, Sherry Brandt-Rauf, Sheila M. Rothman, and Victoria H. Raveis

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Genetic Research, Genes, BRCA2, Ethnic group, Genes, BRCA1, Judaism, Breast Neoplasms, Disease, Gene mutation, Interviews as Topic, Breast cancer, Medicine, Humans, Genetic Predisposition to Disease, Genetic Testing, Social identity theory, skin and connective tissue diseases, Tay-Sachs Disease, Social Identification, business.industry, Framing Health Matters, Public Health, Environmental and Occupational Health, Cancer, nutritional and metabolic diseases, medicine.disease, Genealogy, Ashkenazi jews, Founder Effect, Research Personnel, Genetics, Population, Jews, Mutation, Female, business, Medical genetics of Jews, Demography

Abstract

We explored the advantages and disadvantages of using ethnic categories in genetic research. With the discovery that certain breast cancer gene mutations appeared to be more prevalent in Ashkenazi Jews, breast cancer researchers moved their focus from high-risk families to ethnicity. The concept of Ashkenazi Jews as genetically unique, a legacy of Tay–Sachs disease research and a particular reading of history, shaped this new approach even as methodological imprecision and new genetic and historical research challenged it. Our findings cast doubt on the accuracy and desirability of linking ethnic groups to genetic disease. Such linkages exaggerate genetic differences among ethnic groups and lead to unequal access to testing and therapy.

Published

2006

17. Ashkenazi Jewish genetic disease carrier screening

Author

Kristin G Monaghan, Susan J Gross, and Beth A. Pletcher

Subjects

business.industry, Medicine, Genetic disease carrier, Ashkenazi Jewish, business, Genetics (clinical), Genealogy, Medical genetics of Jews

Published

2008

18. Cystic fibrosis heterozygote screening in the Orthodox Community of Ashkenazi Jews: the Dor Yesharim approach and heterozygote frequency

Author

Elyezer Rubinstein, Dvorah Abeliovich, Adina Quint, Galia Verchezon, Joseph Ekstein, Israela Lerer, and Neomi Weinberg

Subjects

Genetics, Male, education.field_of_study, Adolescent, Cystic Fibrosis, business.industry, Judaism, Genetic Carrier Screening, Population, Heterozygote advantage, medicine.disease, Cystic fibrosis, Ashkenazi jews, Gene Frequency, Jews, Medicine, Humans, Female, Genetic Testing, business, ΔF508, education, Genetics (clinical), Medical genetics of Jews

Abstract

In the community of the Orthodox Jews most of the marriages are arranged a screening program that is aimed at preventing the marriage of two carriers of autosomal recessive disorders is conducted by the Dor Yesharim organization. A random sample of 6,076 individuals of the Orthodox Jewish Ashkenazi community, were screened for the five mutations common in Ashkenazi patients (delta F508, W1282X, G542X, N1303K, 3849 + 10Kb C--T). Two hundred thirty-two carriers were identified, giving a heterozygote frequency of 1:26. The relative frequencies of the individual mutations in the general population were comparable to those in the patients.

Published

1996

19. Ashkenazi Jewish genetic disease carrier screening

Author

Lee Z Mays, Michael L. Begleiter, Andrea M. Atherton, Molly M. Lund, Meghan E Strenk, and Janda L Buchholz

Subjects

medicine.medical_specialty, education.field_of_study, business.industry, Population, Ethnic group, Genetic disease carrier, Disease, Mucolipidosis IV, Family medicine, medicine, Ashkenazi Jewish, business, Carrier screening, education, Genetics (clinical), Medical genetics of Jews

Abstract

To the Editor: We read with interest and much concern the recent recommendation of the College regarding carrier screening in individuals of Ashkenazi Jewish (AJ) descent (Genet Med 2008;10: 54 –56). Specifically, we felt that Recommendation 4, “if only one member of a couple is of AJ background, testing should still be offered,” is quite problematic. As stated in the Guidelines, the cumulative probability of being a carrier for one of the conditions in the panel is between 20 and 25%. One in 4 or 1 in 5 couples where only one member is of AJ descent will be identified as at increased risk to have an affected child and offered testing for that specific condition for the non-AJ partner. The screening of the non-AJ partner for the mutations that occur in the AJ population is an exercise in unknown probabilities (Table 1). Since the frequency of those mutations that occur more often in the AJ population is unknown in non-AJ populations, there is no way to revise a couple’s risk after screening the non-AJ member for the AJ mutations. Counseling a couple that the non-AJ member does not carry any of the AJ mutations does not provide much solace (or information) regarding their risk for a child with one of the AJ genetic conditions. In the case of cystic fibrosis (where gene frequencies are known in various populations) and in the case of Tay-Sachs disease (where enzyme analysis is informative regardless of ethnicity) the Practice Guidelines do provide useful information that would aid a family in their decision-making process. Even without testing the non-AJ member, counselors can be reassuring to those couples where the AJ member is a carrier for Dysautonomia, Bloom syndrome, or Mucolipidosis IV, as these conditions are either extremely rare or unreported in non-AJ populations. So the question remaining (with the exception of cystic fibrosis and Tay-Sachs screening) is what do we accomplish by the implementation of these Guidelines in couples where only one member is of AJ descent? Michael L. Begleiter, MS, CGC Janda L. Buchholz, MS, CGC Andrea M. Atherton, MS, CGC Lee Z. Mays, MS, CGC Molly M. Lund, MS, CGC Meghan E. Strenk, MS Genetics, Dysmorphology and Metabolism, The Children’s Mercy Hospitals & Clinics, Kansas City, Missouri, The University of Missouri-Kansas City, School of Medicine, Kansas City, Missouri

Published

2008

20. Prevalence of Bloom Syndrome Heterozygotes among Ashkenazi Jews

Author

Carole Oddoux, Harry Ostrer, Carlos Mark Clayton, and Holly Reid Nelson

Subjects

Heterozygote, Letter, InformationSystems_INFORMATIONSTORAGEANDRETRIEVAL, Gene Frequency, medicine, Prevalence, Genetics, Humans, Bloom syndrome, Genetics(clinical), Genetic Testing, health care economics and organizations, Genetics (clinical), Automated sequencing, Genetic testing, Adenosine Triphosphatases, medicine.diagnostic_test, RecQ Helicases, DNA Helicases, Heterozygote testing, Mutant cell, medicine.disease, University hospital, Control cell, humanities, Genealogy, Ashkenazi jews, Ashkenazi Jews, Geography, Carrier screening, Jews, Mutation, ComputerApplications_GENERAL, Medical genetics of Jews

Abstract

This work was funded in part by a grant from the National Foundation for Jewish Genetic Diseases. We thank Dr. Robert Pergolizzi (North Shore University Hospital, Manhasset, NY), for the automated sequencing, and the NIGMS Human Genetic Mutant Cell Repository (Camden, NJ), for generously supplying the control cell lines used in this study.

21. Tay-Sachs disease and the role of reproductive compensation in the maintenance of ethnic variations in the incidence of autosomal recessive disease

Author

S. R. Schach and J. H. Koeslag

Subjects

Genetics, Tay-Sachs Disease, Genetic equilibrium, Tay-Sachs disease, Racial Groups, Infant, Biology, Compound heterozygosity, medicine.disease, Ashkenazi jews, Fertility, Gene Frequency, Infant Mortality, Mutation, medicine, Humans, Allele, Child, Genetics (clinical), Medical genetics of Jews, Reproductive compensation, Founder effect

Abstract

Summary Several deleterious and lethal autosomal recessive genes appear to exist in equilibrium with their normal alleles at a variety of stable, or near stable frequencies of considerable antiquity. One person in 25 is, for instance, a carrier of the Tay-Sachs gene among Ashkenazi Jews, compared with 1 in 300 among Sephardic and Oriental Jews and non-Jews. The explanations offered for t his phenomenon have generally not been entirely satisfactory. It has been shown that parents replace fortuitous infant and childhood deaths with, on average, approximately two surviving sibs each. When mutation rates are low, this practice, which has also been shown to occur among other animals, can maintain considerable variations in the stable incidence of autosomal recessive disease, should such ethnic polymorphism arise through genetic drift, the founder effect or hitch-hiking. High mutation rates would appear to preclude ethnic variations in the stable incidence of genetic disease.

Published

1984

22. Incidence of mucopolysaccharidoses in Israel: is Hunter disease a 'Jewish disease'?

Author

Tamar Schaap and G. Bach

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Heterozygote, X Chromosome, Hunter disease, Adolescent, Judaism, Mucopolysaccharidosis I, Disease, Biology, White People, Asian People, Gene Frequency, Genetics, Humans, Israel, skin and connective tissue diseases, Child, Genetics (clinical), Mucopolysaccharidosis II, Incidence (epidemiology), nutritional and metabolic diseases, social sciences, Mucopolysaccharidoses, humanities, Human genetics, Ashkenazi jews, Pedigree, Child, Preschool, Jews, Female, Genes, Lethal, Medical genetics of Jews, Demography

Abstract

Hunter disease in Israel occurs among Ashkenazi, Oriental, and Sephardic Jews and is by far more frequent than Hurler disease. None of the other mucopolysaccharidoses has been diagnosed in Ashkenazi Jews. The possibility of Hunter disease being a “Jewish” disease is discussed.

Published

1980