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Query: UMLS:C0039730 (
thalassemia
)
10,305
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Over the last 10 years, the explosion of molecular biology and molecular genetic techniques have allowed major advances in the diagnosis and management of a wide variety of human disorders. These range from accurate and simple screening for carriers of
thalassemia
(Old JM, Varawalla NY, Weatherall DJ: Lancet 2:834-837, 1990) to the use of preimplantation diagnosis of embryos at risk for untreatable congenital defects (Monk M, Holding C: Lancet 1:985-988, 1990) and the development of gene therapy for treatment of disorders such as adenosine deaminase deficiency (Sharp D: Lancet 1:1277-1278, 1991). These same molecular techniques have also been applied to pediatric lipid disorders with some notable successes, both in their diagnosis and understanding the mechanisms of the resulting pathology, including the recent experiments (Wilson JM, Grossman M, Wu CH, Chowdhury NR, Wu GY, Chowdhury JR: J Biol Chem 267:963-967, 1992) that have led to proposals to treat homozygous
familial hypercholesterolemia
by gene therapy. The purpose of this review is to detail this molecular genetic progress for two of the disorders that result in disturbed triglyceride metabolism in infants, lipoprotein lipase deficiency and apo CII deficiency, and four disorders that lead to disturbed cholesterol levels in infancy, abetalipoproteinemia, hypobetalipoproteinemia, familial defective apo B, and
familial hypercholesterolemia
. We will also address the question of how knowledge of the mutation causing the defect in a particular patient could be clinically useful and highlight areas of research for the future.
...
PMID:The molecular genetics of pediatric lipid disorders: recent progress and future research directions. 825 68
One of the genetic features of the Sardinian population is the high prevalence of hemoglobin disorders. It has been estimated that 13% to 33% of Sardinians carry a mutant allele of the alpha-globin gene (alpha-thalassemia trait) and that 6% to 17% are beta-
thalassemia
carriers. In this population, a single mutation of beta-globin gene (Q39X, beta(0) 39) accounts for >95% of beta-
thalassemia
cases. Because previous studies have shown that Sardinian beta-
thalassemia
carriers have lower total and low density lipoprotein (LDL) cholesterol than noncarriers, we wondered whether this LDL-lowering effect of the beta-thalassemia trait was also present in subjects with
familial hypercholesterolemia
(FH). In a group of 63 Sardinian patients with the clinical diagnosis of FH, we identified 21 unrelated probands carrying 7 different mutations of the
LDL receptor
gene, 2 already known (313+1 g>a and C95R) and 5 not previously reported (D118N, C255W, A378T, T413R, and Fs572). The 313+1 g>a and Fs572 mutations were found in several families. In cluster Fs572, the plasma LDL cholesterol level was 5.76+/-1.08 mmol/L in subjects with beta(0)-thalassemia trait and 8.25+/-1.66 mmol/L in subjects without this trait (P<0.001). This LDL-lowering effect was confirmed in an FH heterozygote of the same cluster who had beta(0)-thalassemia major and whose LDL cholesterol level was below the 50th percentile of the distribution in the normal Sardinian population. The hypocholesterolemic effect of beta(0)-thalassemia trait emerged also when we pooled the data from all FH subjects with and without beta(0)-thalassemia trait, regardless of the type of mutation in the
LDL receptor
gene. The LDL-lowering effect of beta(0)-
thalassemia
may be related to (1) the mild erythroid hyperplasia, which would increase the LDL removal by the bone marrow, and (2) the chronic activation of the monocyte-macrophage system, causing an increased secretion of some cytokines (interleukin-1, interleukin-6, and tumor necrosis factor-alpha) known to affect the hepatic secretion and the receptor-mediated removal of apolipoprotein B-containing lipoproteins. The observation that our FH subjects with beta(0)-thalassemia trait (compared with noncarriers) have an increase of blood reticulocytes (40%) and plasma levels of interleukin-6 (+60%) supports these hypotheses. The lifelong LDL-lowering effect of beta(0)-thalassemia trait might slow the development and progression of coronary atherosclerosis in FH.
...
PMID:Influence of beta(0)-thalassemia on the phenotypic expression of heterozygous familial hypercholesterolemia : a study of patients with familial hypercholesterolemia from Sardinia. 1063 24
The population of Quebec, Canada (7.3 million) contains approximately 6 million French Canadians; they are the descendants of approximately 8500 permanent French settlers who colonized Nouvelle France between 1608 and 1759. Their well-documented settlements, internal migrations, and natural increase over four centuries in relative isolation (geographic, linguistic, etc.) contain important evidence of social transmission of demographic behavior that contributed to effective family size and population structure. This history is reflected in at least 22 Mendelian diseases, occurring at unusually high prevalence in its subpopulations. Immigration of non-French persons during the past 250 years has given the Quebec population further inhomogeneity, which is apparent in allelic diversity at various loci. The histories of Quebec's subpopulations are, to a great extent, the histories of their alleles. Rare pathogenic alleles with high penetrance and associated haplotypes at 10 loci (CFTR, FAH, HBB, HEXA, LDLR, LPL, PAH, PABP2, PDDR, and SACS) are expressed in probands with cystic fibrosis, tyrosinemia, beta-
thalassemia
, Tay-Sachs,
familial hypercholesterolemia
, hyperchylomicronemia, PKU, oculopharyngeal muscular dystrophy, pseudo vitamin D deficiency rickets, and spastic ataxia of Charlevoix-Saguenay, respectively) reveal the interpopulation and intrapopulation genetic diversity of Quebec. Inbreeding does not explain the clustering and prevalence of these genetic diseases; genealogical reconstructions buttressed by molecular evidence point to founder effects and genetic drift in multiple instances. Genealogical estimates of historical meioses and analysis of linkage disequilibrium show that sectors of this young population are suitable for linkage disequilibrium mapping of rare alleles. How the population benefits from what is being learned about its structure and how its uniqueness could facilitate construction of a genomic map of linkage disequilibrium are discussed.
...
PMID:Human genetics: lessons from Quebec populations. 1170 44
Familial hypercholesterolemia (FH) is a codominant disorder due to a variety of mutations of the low-density lipoprotein (LDL) receptor gene that result in an elevation of plasma LDL-cholesterol (LDL-C). Plasma levels of LDL-C show large interindividual variation even in subjects carrying the same mutation of the
LDL receptor
gene. This variability may be due to genetic factors (modifier genes). Several surveys indicate that the overall contribution of common polymorphisms of modifier genes (such as the genes encoding apolipoproteins E and B) to this variability is less than 10%. In contrast, beta-
thalassemia
has a profound LDL-lowering effect. This was documented in FH patients identified on the island of Sardinia, in Italy, where 12% of the inhabitants are carriers of beta-
thalassemia
due to a single mutation (Q39X) of the beta-globin gene that abolishes the synthesis of beta-globin chain of hemoglobin (beta(o)-
thalassemia
). Plasma LDL-C in FH heterozygotes carrying the beta(o)-thalassemia trait is 25% lower than in noncarriers, regardless of the
LDL receptor
gene mutation. It is likely that this effect is due to two main mechanisms: (1) increased uptake of LDL by the bone marrow to provide cholesterol for the increased proliferation of erythroid progenitor cells and (2) increased production of inflammatory cytokines that reduce the hepatic secretion and increase the catabolism of LDL. In view of its LDL-C-lowering effect, beta-thalassemia trait may protect FH heterozygotes against premature coronary atherosclerosis.
...
PMID:Beta-thalassemia is a modifying factor of the clinical expression of familial hypercholesterolemia. 1563 Jun 28
