Two mutations in the same low-density lipoprotein receptor allele act in synergy to reduce receptor function in heterozygous familial hypercholesterolemia

Mutations in genes are not necessarily pathogenic. Expression of mutant genes in cells can therefore be required to demonstrate that mutations in fact disturb protein function. This applies especially to missense mutations, which cause an amino acid to be replaced by another amino acid. In the present study of two families with familial hypercholesterolemia in the heterozygous form, we found two mutations in the same allele of the low-density lipoprotein (LDL) receptor gene: a missense Asn⁵⁴³-His mutation (N543H) in exon 11, and an in-frame 9-bp deletion (2393del9) in exon 17. The two mutations were identified in heterozygous FH index patients in whom no other pathogenic mutations were detected by SSCP analysis of the remaining 16 exons and the promoter region. Both mutations cosegregated with hypercholesterolemia within the families. Each of these mutations had little or no effect on receptor function in transfected COS cells, but when both mutations were present simultaneously, receptor function, as assessed by flow cytometric measurement of fluorescent LDL uptake in cells, was reduced by 75%. Immunostainable receptors on the cell surface were decreased by 80% as measured by flow cytometry. The two mutations therefore acted in synergy to affect receptor function, possibly during intracellular receptor transport, since Northern blot analysis suggested that mRNA levels were unaffected. Without screening of the entire coding regions of the gene, the synergistic action of these two LDL receptor mutations would not have been detected. Hum Mutat 9:437–444, 1997. © 1997 Wiley-Liss, Inc.     

Mutation analysis in 46 German families with familial hypercholesterolemia: identification of 8 new mutations. Mutations in brief no. 226. Online

In order to obtain a survey of the mutations being prevalent in Northern Germany and to enable molecular genetic testing for families with clinically diagnosed familial hypercholesterolemia (FH), we screened 46 unrelated German individuals with elevated LDL levels for mutations in the 18 exons and their flanking intron sequences including the promotor region of the LDL receptor (LDLR) gene. In addition, we tested all patients for the presence of mutations in the gene coding for apolipoprotein B-100 (apoB-100). We detected 15 mutations affecting the LDLR gene, 8 of which, designated A29S, 195insAT, 313+1insG, 553insG, 680insGGACAAATCTG, D200N, E267K and L411V have not yet been reported. One patient is heterozygous for the double mutant N543H and 2393del9Bp. Two patients carried the mutation R3500Q (Arg-->Glu) within the apoB-100 gene.     

Mutation analysis in 46 German families with familial hypercholesterolemia: Identification of 8 new mutations

In order to obtain a survey of the mutations being prevalent in Northern Germany and to enable molecular genetic testing for families with clinically diagnosed familial hypercholesterolemia (FH), we screened 46 unrelated German individuals with elevated LDL levels for mutations in the 18 exons and their flanking intron sequences including the promotor region of the LDL receptor (LDLR) gene. In addition, we tested all patients for the presence of mutations in the gene coding for apolipoprotein B‐100 (apoB‐100). We detected 15 mutations affecting the LDLR gene, 8 of which, designated A29S, 195insAT, 313+1insG, 553insG, 680insGGACAAATCTG, D200N, E267K and L411V have not yet been reported. One patient is heterozygous for the double mutant N543H and 2393del9Bp. Two patients carried the mutation R3500Q (Arg→Glu) within the apoB‐100 gene. © 1999 Wiley‐Liss, Inc.     

Mutation analysis in 36 unrelated Spanish subjects with familial hypercholesterolemia: identification of 3 novel mutations in the LDL receptor gene

We used the single strand conformation polymorphism (SSCP) method to investigate 36 apparently unrelated Spanish patients with familial hypercholesterolemia (FH) for mutations in the promoter region and the 18 exons and their flanking intron sequences of the low density lipoprotein receptor (LDLR) gene. Nineteen aberrant SSCP patterns were found, and the underlying mutations were characterized by DNA sequencing. In addition, we tested all patients for the presence of mutations in the gene coding for apolipoprotein B (apo B). Five missense mutations (Q71E, S156L, E256K, N543H and T705I), four nonsense mutations (W(-18)X, E10X, Q133X and C255X), six frameshift mutations (211delG, 518delG, 1045delC, 2085del19, 2207insT and 2393del9) and five splicing mutations (313+1G->C, 1061-8T->C, 1845+1G->C, 2140+5G->A and 2390-1G->C) were identified in the LDLR gene. In total, we detected 20 mutations, 3 of which, designated 1045delC, 1845+1G->C and 2207insT, have not been previously described. Seven patients were found to carry two different mutations in the same allele: W(-18)X and E256K (one patient), Q71E and 313+1G->C (two patients), 1061-8T->C and T705I (two patients), 518delG and 2140+5G->A (one patient) and N543H and 2393del9 (one patient). As we expected, there is a broad spectrum of mutations in the LDLR gene, given the genetic heterogeneity of the Spanish population.     

Molecular genetic testing for familial hypercholesterolemia: spectrum of LDL receptor gene mutations in The Netherlands

Mutations in the LDL receptor are responsible for familial hypercholesterolemia (FH). At present, more than 600 mutations of the LDL receptor gene are known to underlie FH. However, the array of mutations varies considerably in different populations. Therefore, the delineation of essentially all LDL receptor gene mutations in a population represents a prerequisite for the implementation of nation-wide genetic testing for FH. In this study, the frequency and geographical distribution of 13 known mutations were evaluated in a cohort of 1223 FH patients. We identified 358 mutation carriers, representing 29% of the FH cohort. Four mutations (N543H-2393de19, 1359--1G-->A, 313 + 1 G-->A and W23X) occurred with a relatively high frequency, accounting for 22.4% of the entire study cohort. Two of these common FH mutations (N543H-2393de19 and 1359 - 1G-->A) showed a preferential geographic distribution. Second, to further expand the array of LDL receptor gene mutations, we conducted mutation analysis by denaturing gradient gel electrophoresis (DGGE) in 141 children with definite FH. A mutation was identified in 111 patients, involving 16 new single base substitutions and four small deletions and insertions, which brings the number of different FH-causing mutations in our country up to 61. Our data indicate that an estimate of the prevalence of specific mutations, as well as the compilation of a database of all FH-causing mutations in a given country, can facilitate selection of the most appropriate molecular diagnostic approach.     

The molecular genetic basis and diagnosis of familial hypercholesterolemia in Denmark

Normal function of the hepatic low-density lipoprotein (LDL) receptor is obligate for normal levels of plasma LDL cholesterol. The LDL receptor regulates the concentration of plasma LDL cholesterol by internalizing apolipoprotein B-100- and apolipoprotein E-containing lipoproteins by receptor-mediated endocytosis. Mutations in the gene encoding the LDL receptor protein give rise to one of the most common classical autosomal dominant inherited disorders in man, familial hypercholesterolemia (FH). The estimated prevalence of heterozygous FH is 0.2% (1:500) in most populations of the world including the Danish. Worldwide, an estimated ten million people are afflicted with FH and in Denmark there are approximately 10,000 subjects with heterozygous FH. Persons with heterozygous FH are characterized by a severely elevated concentration of LDL cholesterol in plasma starting in early childhood, tendon xanthomas and a markedly increased risk of premature coronary heart disease (CHD). Adequate control of plasma LDL cholesterol levels can be achieved in most patients with heterozygous FH, and to a lesser extent in the very rare cases with homozygous FH, using combinations of diet, drug therapy and selective LDL-apheresis. So, it is very important that physicians be aware of this relatively common disorder since there is good evidence that early diagnosis and cholesterol-lowering therapy will delay or even prevent CHD in persons with FH. A large majority of these persons, however, are still not diagnosed or adequately treated. It is believed that the diagnostic abilities molecular biology has to offer will provide the impetus for correcting this situation. The aims of the studies behind the present thesis, therefore, were to obtain important knowledge about current mutation detection technology, prevalence and spectrum of LDL receptor gene mutations in Denmark, methods to evaluate pathogenicity of LDL receptor gene mutations, relationship between FH genotype-phenotype, and clinical versus DNA diagnosis in the Danish FH population. Among different relative laborious and expensive scanning methods for unknown gene mutations we have shown that the polymerase chain reaction (PCR) single-strand conformation polymorphism (SSCP) analysis is a highly efficient and sensitive technique for detection of mutations in the 18 exons including intronic splice-site sequences and the promoter region of the LDL receptor gene, reserving DNA sequencing to the exons revealing variant SSCP patterns. Southern blot analysis or long distance PCR analysis are necessary to identify large gene re-arrangements in the LDL receptor gene in FH patients in whom SSCP analysis did not reveal any smaller sequence alterations. Worldwide, about 700 different mutations in the LDL receptor gene have been reported and in the Danish FH population we have so far identified 60 different mutations localized throughout the LDL receptor gene. In certain populations a small number of mutations predominate due to founder effects. The spectrum of LDL receptor mutations in Danish FH patients is intermediate between such specific founder populations with 5 predominant mutations (W23X, W66G, W556S, 313 + 1G-->A, 1846-1G-->A) accounting for about 40-50% of FH. These frequent mutations can easily and inexpensively be tested for by specific PCR based assays using restriction enzyme cleavage. Future analysis of LDL receptor mutations in heterozygous FH subjects, therefore, should be based on the mutational spectrum present in each relevant specific subset. Most mutations in the LDL receptor gene cause the classical heterozygous form of FH, but a small proportion seem to result in mild or moderate forms of autosomal, dominantly inherited hypercholesterolemia. Differentiation between harmless sequence variations and disease-causing mutations is not always easy without additional work. We have experienced that large re-arrangements, frame-shift and nonsense mutations obviously are pathogenic, but full pathogenicity should not be ascribed to missense mutations and small in-frame deletions, e.g. the N543H and 2393del9 mutations, unless in vitro gene expression in eukaryotic cells have been studied, or to splice-site mutations, e.g. the 1592 + 5G-->A mutation, before mRNA studies in patient cells have been performed. The cumulated LDL cholesterol exposure, mainly determined by the defect LDL receptor, plays a crucial role for the clinical manifestation of FH. The phenotypic expression of homozygous FH appears to be dominated by the consequences of the LDL receptor gene mutations. In heterozygous FH, however, the underlying mutational LDL receptor type determines only to a much lesser extent, if any, the variable phenotypic expression as seen in Danish patients. Extreme low fat dietary habits or major gene interactions may influence the lipid profile and the excess cardiovascular mortality observed in heterozygous FH, whereas minor gene determinants do not seem to play any significant role. The clinical diagnosis of heterozygous FH should be based on an elevated plasma LDL cholesterol concentration above the 95th percentiles for the general population together with either the presence of tendon xanthomas or an autosomal dominant transmission of hypercholesterolemia in the family or a child with hypercholesterolemia. Our studies illustrate clearly that molecular genetics can strengthen an equivocal clinical diagnosis and assist decision-making in diagnosis and tracing family members. If demonstration of a pathogenic mutation in the LDL receptor gene fails, other causes of autosomal dominant inherited hypercholesterolemia should be sought. Familial defective apolipoprotein B (FDB) caused by the R3500Q apolipoprotein B gene mutation may mimic FH but the clinical course, however, is often milder than that seen in patients with LDL receptor gene mutations. A newly discovered third major locus at chromosome 1 may also be of future diagnostic importance although the exact gene remains to be identified. The overall molecular genetic knowledge obtained about FH in Denmark forms the basis for the implementation and use of molecular genetic diagnostics of FH in daily clinical practice.     

A novel point mutation in a splice acceptor site of intron 1 of the human low density lipoprotein receptor gene which causes severe hypercholesterolemia: an unexpected absence of exon skipping. Mutations in brief no. 139. Online

Familial hypercholesterolemia (FH) is a genetic disorder caused by mutations in the low density lipoprotein (LDL)-receptor gene. We found a new mutation in the splice acceptor site of intron 1 of the LDL receptor gene, which is designated as 68-1 G->C according to the nomenclature suggested by Beaudet and Tsui (1993), in a Japanese FH homozygote. She was born from consanguineous marriage and has this mutation as a true homozygous form. Her cultured fibroblasts showed no LDL receptor protein synthesis. This mutation caused activation of a cryptic splice acceptor side in the downstream exon 2, leading to frameshift and appearance of premature in-frame stop codon. The mutation was detected by Dde I restriction enzyme. The identical mutation was not found among 24 patients with homozygous and 120 patients with heterozygous FH. The mutation was very rare among the Japanese population.     

Homozygous familial hypercholesterolemia in Lebanon: a genotype/phenotype correlation

Familial hypercholesterolemia (FH) is an inherited disease characterized by the deposition of LDL in tissues causing premature atherosclerosis. Many genes are implicated in FH resulting in a large variability in the phenotype. DNA sequencing of the LDLR gene was done for forty patients clinically diagnosed with homozygous FH and forty family members variably affected. Patients underwent noninvasive heart and vascular studies. Statistical and pedigree analyses were used to correlate the different genotypes with the phenotypes. The prevalence of homozygosity at the Lebanese allele (2043C>A) is 45%. However, 27.5% of the patients have no mutations at all in the LDLR gene, and 27.5% are either heterozygous for the 2043C>A mutation, heterozygous for a mutation in another exon of the LDLR gene, or combined heterozygous for two different mutations. We confirm previous reports on the higher prevalence of FH in Lebanon. Our results do, however contradict previous reports on an assumed higher prevalence among the Christian Lebanese. Mutations in the LDLR especially combined heterozygosity can cause a severe phenotype similar to the homozygous mutation in the Lebanese allele. This information is particularly important in targeting the more prevalent heterozygotes in the general population with early diagnosis and intervention.     

Identification of recurrent and novel mutations in the LDL receptor gene in Japanese familial hypercholesterolemia

We used the denaturing gradient gel electrophoresis (DGGE) method to investigate 120 Japanese patients with familial hypercholesterolemia (FH) for mutations in the promoter region and the 18 exons and their flanking intron sequence of the low density lipoprotein (LDL) receptor gene. Fourteen aberrant DGGE patterns were found, and the underlying mutations were characterized by DNA sequencing. Five novel missense mutations (C317S, F382L A410T, L547V, and E693K), two nonsense mutations (W512X and K790X), four frameshift mutation (355del7, 1246ins5, 1687ins1, and 2035ins1), one splicing mutation (1845+2 T→C), and two inframe mutations (661ins21 and 1115del9/ins6) were identified. Six of these mutations (L547V, E693K, W512X, 355del7, 1687ins1, and 20354ins1) have not been described before in FH. These newly identified mutations cosegregated in their family members with defective LDL receptor activity and hypercholesterolemia, and are thought to be causal for the FH phenotype. These results demonstrate that there is a broad spectrum of mutations in the LDL receptor gene in the Japanese population. Hum Mutat 14:87, 1999. © 1999 Wiley‐Liss, Inc.     

Inheritance of two different alleles of the low-density lipoprotein (LDL)-receptor gene carrying the recurrent Pro664Leu mutation in a patient with homozygous familial hypercholesterolaemia

Familial hypercholesterolaemia (FH) is caused by mutations in the low-density lipoprotein (LDL)-receptor gene that result in impaired clearance of plasma LDL and increased risk of coronary heart disease. Numerous different mutations have been found in FH patients worldwide, the majority of which are infrequent in out-bred populations and account for 2% or less of patients with the disorder in large cohorts. Thus, it was surprising to find that two homozygous FH patients referred to a single hospital in the UK were both apparently homozygous for the Pro664Leu mutation. One, an Asian patient, was a true homozygote. The other, of English origin, had inherited two different alleles of the LDL-receptor gene with the same mutation from unrelated parents, as inferred from the haplotype of polymorphic markers. A third, clinically homozygous FH patient, despite being the offspring of first cousins, had inherited one 'Asian' Pro664Leu allele, but an allele with a 1-bp deletion in exon 5 from the other parent. The Pro664Leu mutation in the LDL-receptor gene has now been described in heterozygous patients of very different ethnic origin and is associated with different haplotypes, suggesting that the same base change at a CpG may have recurred as many as six times.     

The molecular basis of familial hypercholesterolemia in Lebanon: Spectrum of LDLR mutations and role of PCSK9 as a modifier gene

Autosomal dominant hypercholesterolemia (ADH), a major risk for coronary heart disease, is associated with mutations in the genes encoding the low‐density lipoproteins receptor (LDLR), its ligand apolipoprotein B (APOB) or PCSK9 (Proprotein Convertase Subtilin Kexin 9). Familial hypercholesterolemia (FH) caused by mutation in the LDLR gene is the most frequent form of ADH. The incidence of FH is particularly high in the Lebanese population presumably as a result of a founder effect. In this study we characterize the spectrum of the mutations causing FH in Lebanon: we confirm the very high frequency of the LDLR p.Cys681X mutation that accounts for 81.5 % of the FH Lebanese probands recruited and identify other less frequent mutations in the LDLR. Finally, we show that the p.Leu21dup, an in frame insertion of one leucine to the stretch of 9 leucines in exon 1 of PCSK9, known to be associated with lower LDL‐cholesterol levels in general populations, is also associated with a reduction of LDL‐cholesterol levels in FH patients sharing the p.C681X mutation in the LDLR. Thus, by studying for the first time the impact of PCSK9 polymorphism on LDL‐cholesterol levels of FH patients carrying a same LDLR mutation, we show that PCSK9 might constitute a modifier gene in familial hypercholesterolemia. © 2009 Wiley‐Liss, Inc.     

Characterization of a disease-causing Glu119-Lys mutation in the low-density lipoprotein receptor gene in two Danish families with heterozygous familial hypercholesterolemia

Mutations in the gene for the low-density lipoprotein receptor (LDL receptor) cause the autosomal dominant inherited disease familial hypercholesterolemia (FH). In 15 Danish patients with heterozygous FH we have screened exon 4 of the LDL receptor gene for point mutations and small rearrangements employing genomic DNA amplification and bidirectional solid-phase sequencing. Two subjects were found to be heterozygous for a guanine to adenine base substitution at nucleotide position 418 of the LDL receptor cDNA. This point mutation results in an amino acid change from glutamic acid to lysine at amino acid residue 119 in the third repeat of the cysteine-rich ligand binding domain of the mature LDL receptor. Disruption of LDL receptor function by the Glu¹¹⁹-Lys mutation was confirmed by site-directed rnutagenesis and expression in COS-7 cells. By Western blotting the mutation was found to affect the processing of the LDL receptor protein. Using flow cytometric analysis of the transfected cells a decreased binding and internalization of LDL by the mutant receptor was documented. By means of a mutation-specific PCR-based assay the Glu¹¹⁹-Lys mutation was not detected in another 85 apparently unrelated Danish heterozygous FH patients. We identified six persons in the index families with the Glu¹¹⁹-Lys mutation cosegregating with the clinical syndrome of FH in these families. Furthermore, haplotype analysis revealed that the haplotype [SfaNI+, StuI+, AvaII–, (dTA)₇] of the mutation carrying allele was the same in the two apparently unrelated patients. This indicates that the mutation has been inherited from a common ancestor. © 1994 Wiley-Liss, Inc.     

Haplotype analysis suggests a single Balkan origin for the Gaucher disease [D409H;H255Q] double mutant allele

Gaucher disease is an autosomal recessive lysosomal storage disease that is mainly due to mutations in the GBA gene. Most of the mutant alleles described so far bear a single mutation. However, there are a few alleles bearing two or more DNA changes. It has been reported that patients homozygous for the [D409H;H255Q] double mutant allele (HGVS-approved nomenclature, p.[D448H;H294Q]) present a more severe phenotype than patients homozygous for the relatively common D409H mutation. In this study, we confirmed the detrimental cumulative effect of these two mutations at the enzymatic activity level by the heterologous expression of the single and double mutant alleles. Additionally, we found a high frequency of the [D409H;H255Q] allele in patients from the Balkans and the Adriatic area of Italy. This prompted us to perform a haplotype analysis, using five microsatellite polymorphisms close to the GBA gene, to determine the origin of this allele. The results of the 37 chromosomes analysed showed that most of them share a common haplotype and are consistent with a single origin in the Balkans and the Adriatic area of Italy for the [D409H;H255Q] allele.     

家族性高胆固醇血症家系低密度脂蛋白受体基因剪接突变的研究

目的　检测中国汉族家族性高胆固醇血症 (familial hypercholesterolemia,FH)大家系低密度脂蛋白受体 (low density lipoprotein receptor,L DL R)基因突变 ,探讨 FH发病的分子机理。方法　首先采用聚合酶链反应 -限制性片段长度多态性 (polymerase chain reaction- restriction fragment lengthpolymorphism,PCR- RFL P)技术检测载脂蛋白 B1 0 0 (apo B1 0 0 )基因 Q35 0 0 R突变 ,排除家族性 apo B1 0 0 缺陷症 ,再采用 PCR扩增结合核苷酸序列分析检测 1例临床诊断为 FH纯合子患儿及其家系成员 L DL R基因启动子和全部 18个外显子片段 ,结果与 Gen Bank公布的该基因正常序列对比找出突变 ,并在家系其他成员中证实该突变。结果　该患儿 L DL R基因第 3内含子剪接供体处存在 IN 5′GT→AT纯合剪接突变 ,并且在家系中得到证实 ,一级和二级亲属中各发现 2例相同位点和相同形式的杂合子 ,其基因型表现为野生型和突变型杂合现象。同时未检测出患儿及其父母 apo B1 0 0 Q35 0 0 R突变。结论　发现 L DL R基因第 3内含子 G→ A纯合剪接突变 ,可能是该 FH家系发病的分子基础 ;检测该突变对临床干预和遗传指导有参考价值。     

Identification of a common low density lipoprotein receptor mutation (C163Y) in the west of Scotland.

Familial hypercholesterolaemia (FH) is an autosomal codominant disorder characterised by high levels of LDL cholesterol and a high incidence of coronary artery disease. Our aims were to track the low density lipoprotein receptor (LDLR) gene in individual families with phenotypic FH and to identify and characterise any mutations of the LDLR gene that may be common in the west of Scotland FH population using single strand conformational polymorphism analysis (SSCP). Patient samples consisted of 80 heterozygous probands with FH, 200 subjects who were related to the probands, and a further 50 normal, unrelated control subjects. Tracking of the LDLR gene was accomplished by amplification of a 19 allele tetranucleotide microsatellite that is tightly linked to the LDLR gene locus. Primers specific for exon 4 of the LDLR gene were used to amplify genomic DNA and used for SSCP analysis. Any PCR products with different migration patterns as assessed by SSCP were then sequenced directly. In addition to identifying probands with a common mutation, family members were screened using a forced restriction site assay and analysed using microplate array diagonal gel electrophoresis (MADGE). Microsatellite D19S394 analysis was informative in 20 of 23 families studied. In these families there was no inconsistency with segregation of the FH phenotype with the LDLR locus. Of the FH probands, 15/80 had a mutant allele as assessed by SSCP using three pairs of primers covering the whole of exon 4 of the LDLR gene. Direct DNA sequencing showed that 7/15 of the probands had a C163Y mutation. Using a PCR induced restriction site assay for the enzyme RsaI and MADGE, it was determined that the C163Y mutation cosegregated with the FH phenotype in family members of the FH probands. This mutant allele was not present in any of the control subjects. Microsatellite analysis has proven useful in tracking the LDLR gene and could be used in conjunction with LDL cholesterol levels to diagnose FH, especially in children and young adults where phenotypic diagnosis can be difficult.     

Molecular characterization of familial hypercholesterolemia in Spain: identification of 39 novel and 77 recurrent mutations in LDLR

Mutations in the low-density lipoprotein receptor (LDLR) gene cause familial hypercholesterolemia (FH), an autosomal dominant inherited disorder associated with an increased risk of premature atherosclerosis. The aim of this study was to characterize the LDLR mutations in a group of 476 apparently non-related Spanish FH patients. The promoter region and the 18 exons with their flanking intron sequences of the LDLR gene were screened by PCR-SSCP analysis and DNA sequencing. In addition, we tested for the presence of the mutation p.R3500Q in the gene coding for apolipoprotein B-100 (apo B-100). We found 77 mutations previously described, and 39 novel mutations affecting the LDLR gene: 8 missense, 5 nonsense, 15 frameshift, 5 splicing, 4 in frame, one nucleotide change in the non-coding sequence of exon 1, and one silent variant. We have identified al least one of these LDLR gene mutations in 329 subjects (69%). Four patients were homozygous, 4 patients were compound heterozygous, 48 patients were found to carry two different sequence variants in the same allele and 4 patients carried three different sequence variants in the same allele. Additionally, 4 subjects were carriers of the p.R3500Q mutation in the apo B gene. All of these findings indicate that there is a broad spectrum of mutations and sequence variants in the LDLR gene causing FH in Spain.     

Three novel small deletion mutations of the LDL receptor gene in Korean patients with familial hypercholesterolemia.

The low-density lipoprotein (LDL) receptor gene from 80 unrelated Korean patients with familial hypercholesterolemia (FH) was analyzed to screen for small structural rearrangements that could not be detected by Southern blot hybridization. Three different small deletions were detected in exon 11 of 3 FH patients and were characterized by DNA sequence analysis. Of them two mutations are in-frame 36-bp (FH 2) and 9-bp (FH 34) deletions that result in the loss of twelve amino acids (from Met510 to Ile521) and three amino acids (Thr513, Asp514 and Trp515), respectively. Both mutations are located in the third of the five YWTD motifs of the LDL receptor gene. The third mutation (FH 400) is a 2-bp deletion that shifts the translational reading frame and results in a prematurely terminated receptor protein. The generation of a 36-bp deletion can be explained by the formation of a hairpin-loop structure mediated by inverted repeat sequences. On the other hand, the mechanism responsible for the 9- and the 2-bp deletions is probably strand-slippage mispairing mediated by short direct repeats. All of these three deletions are novel mutations. Each of the three deletions was detected only in a single pedigree out of 80 FH families analyzed.