Identification of the 408 valine to methionine mutation in the low density lipoprotein receptor in a German family with familial hypercholesterolemia

Familial hypercholesterolemia (FH) is caused by different mutations in the gene encoding the low density lipoprotein receptor (LDLR). In Caucasian patients, at least three single point mutations have been identified causing FH. The asparagine₂₀₆ to glutamine, and valine₄₀₈ to methionine mutations were originally described in Afrikaners and recently identified in Dutch FH patients. The proline₆₆₄ to leucine mutations was previously identified in an FH homozygote of Asian Indian origin and later identified in patients from London. Any of these mutations can be identified using direct amplification of genomic DNA by the polymerase chain reaction (PCR) and restriction enzyme digestion of PCR products. In this study, 100 unrelated German FH patients were screened for these three mutations. The valine₄₀₈ to methionine mutation was identified in one individual and subsequently in the hypercholesterolemic child of the proband. Haplotype analysis with 7 restriction fragment length polymorphisms (RFLPs) revealed that the mutant allele carried the same haplotype as the previously described patients in South Africa and the Netherlands. Our finding supports the previous assumption of the European origin of the mutation.     

LDL-R and Apo-B-100 gene mutations in Polish familial hypercholesterolemias

A group of 30 Polish families with clinical signs of familial hypercholesterolemia was studied for the presence of germ-line mutations in the LDL-R and ApoB-100 genes. Screening of the LDL-R gene was performed at the genomic DNA level by single-strand conformation polymorphism analysis of all 18 exons and extended by sequencing of polymerase chain reaction (PCR) products showing abnormalities. The occurrence of large LDL-R gene alterations was evaluated by analysis of restriction enzyme patterns on Southern blots and using the long-PCR technique. The ApoB-100 gene was studied by combined allele-specific and asymmetric PCR for the occurrence of the common B-3500 missense mutation G to A at nucleotide position 10,708. Germ-line mutations were found in 17 families. In 12 of them LDL-R gene mutations were detected. Three of 11 different mutations had previously been described in other populations (3-bp deletion of codon 197; Ser156Leu; Gly571Glu). Of the mutations not previously recognized and identified in Polish families, there were three small deletions (2-bp deletion AG at codon 291; 4-bp deletion CCCT at codons 661–662; 1-bp deletion A at codon 830), and four point mutations (Arg239Stop, Cys331Stop, Asn543Ser, Gln665Stop). Additionally, one large (∼1-kb) LDL-R gene deletion between exons 6 and 9 was identified. In five families, the B-3500 mutation within the ApoB-100 gene was revealed. Received: 15 September 1997 / Accepted: 10 February 1998     

Multiplex ligation-dependent probe amplification of LDLR enhances molecular diagnosis of familial hypercholesterolemia

Autosomal dominant (AD) familial hypercholesterolemia [FH; Mendelian Inheritance in Man (MIM) 143890] typically results from mutations in the LDL receptor gene (LDLR), which are now commonly diagnosed using exon-by-exon screening methods, such as exon-by-exon sequence analysis (EBESA) of genomic DNA (gDNA). However, many patients with FH have no LDLR mutation identified by this method. Part of the diagnostic gap is attributable to the genetic heterogeneity of AD FH, but another possible explanation is inadequate sensitivity of EBESA to detect certain mutation types, such as large deletions or insertions in LDLR. Multiplex ligation-dependent probe amplification (MLPA) is a new method that detects larger gDNA alterations that are overlooked by EBESA. We hypothesized that some FH patients with no LDLR mutation detectable by EBESA would have an abnormal LDLR MLPA pattern. In 70 unrelated FH patients, 44 had LDLR mutations detected by EBESA, including missense, RNA splicing, nonsense, or small deletion mutations, and 5 had the APOB R3500Q mutation. Among the remaining 21 AD FH patients with no apparent LDLR mutation, we found abnormal LDLR MLPA patterns in 12 and then demonstrated the deleted sequence in 5 of these. These findings indicate that MLPA may be a useful new adjunctive tool for the molecular diagnosis of FH.     

Two partial deletion mutations involving the same Alu sequence within intron 8 of the LDL receptor gene in Korean patients with familial hypercholesterolemia

Twenty-eight unrelated persons heterozygous for familial hypercholesterolemia (FH) were screened to assess the frequency and nature of major structural rearrangements at the low-density lipoprotein (LDL) receptor gene in Korean FH patients. Genomic DNA was analyzed by Southern blot hybridization with probes encompassing exons 1–18 of the LDL receptor gene. Two different deletion mutations (FH29 and FH110) were detected in three FH patients (10.7%). Each of the mutations was characterized by the use of exon-specific probes and detailed restriction mapping mediated by long-PCR (polymerase chain reaction). Mutation FH29 was a 3.83-kb deletion extending from intron 6 to intron 8 and FH110 was a 5.71-kb deletion extending from intron 8 to intron 12. In FH29, the translational reading frame was preserved and the deducible result was a cysteine-rich A and B repeat truncated protein that might be unable to bind LDL but would continue to bind β-VLDL. FH110 is presumed to be a null allele, since the deletion shifts the reading frame and results in a truncated protein that terminates in exon 13. Sequence analysis revealed that both deletions have occurred between two Alu-repetitive sequences that are in the same orientation. This suggested that in these patients the deletions were caused by an unequal crossing over event following mispairing of two Alu sequences on different chromatids during meiosis. Moreover, in both deletions, the recombinations were related to an Alu sequence in intron 8 and the deletion breakpoints are found within a specific sequence, 27 bp in length. This supports the hypothesis that this region might have some intrinsic instability, and act as one of the important factors in large recombinational rearrangements. Received: 3 April 1996 / Revised: 19 August 1996     

Molecular genetic testing for familial hypercholesterolemia in the Netherlands: a stepwise screening strategy enhances the mutation detection rate

Familial hypercholesterolemia (FH) has been identified as a major risk factor for coronary vascular disease and is associated with mutations in the low-density liporotein receptor (LDLR) and apolipoprotein B (APOB) gene. The molecular basis of FH in the Dutch population is well understood. Approximately 160 different LDLR and APOB gene defects have been identified with a panel of 9 LDLR gene and 1 APOB gene frequently occurring mutations accounting for approximately 30% of all clinically diagnosed FH cases. As molecular diagnosis of FH is becoming increasingly widely applied, a variety of mutation detection rates is reported, ranging from as low as 30% and up to 80%. This variability appears to depend on the clinical criteria applied to identify patients with FH and on the strategies and methodologies used for mutation screening. In this study we describe the application of a stepwise screening approach, combining different methodologies, to detect mutations of the LDLR gene and APOB gene in 1465 patients with FH. A mutation was found in approximately 44% of the patients, which demonstrates that this is an effective strategy for the molecular diagnosis of FH.     

Quantitative PCR analysis reveals a high incidence of large intragenic deletions in the FANCA gene in Spanish Fanconi anemia patients

Fanconi anaemia is an autosomal recessive disease characterized by chromosome fragility, multiple congenital abnormalities, progressive bone marrow failure and a high predisposition to develop malignancies. Most of the Fanconi anaemia patients belong to complementation group FA-A due to mutations in the FANCA gene. This gene contains 43 exons along a 4.3-kb coding sequence with a very heterogeneous mutational spectrum that makes the mutation screening of FANCA a difficult task. In addition, as the FANCA gene is rich in Alu sequences, it was reported that Alu-mediated recombination led to large intragenic deletions that cannot be detected in heterozygous state by conventional PCR, SSCP analysis, or DNA sequencing. To overcome this problem, a method based on quantitative fluorescent multiplex PCR was proposed to detect intragenic deletions in FANCA involving the most frequently deleted exons (exons 5, 11, 17, 21 and 31). Here we apply the proposed method to detect intragenic deletions in 25 Spanish FA-A patients previously assigned to complementation group FA-A by FANCA cDNA retroviral transduction. A total of eight heterozygous deletions involving from one to more than 26 exons were detected. Thus, one third of the patients carried a large intragenic deletion that would have not been detected by conventional methods. These results are in agreement with previously published data and indicate that large intragenic deletions are one of the most frequent mutations leading to Fanconi anaemia. Consequently, this technology should be applied in future studies on FANCA to improve the mutation detection rate.     

Molecular characterization of minor gene rearrangements in Finnish patients with heterozygous familial hypercholesterolemia: identification of two common missense mutations (Gly823-->Asp and Leu380-->His) and eight rare mutations of the LDL receptor gene.

Two deletions of the low-density lipoprotein (LDL) receptor gene were previously shown to account for about two thirds of all mutations causing familial hypercholesterolemia (FH) in Finland. We screened the DNA samples from a cohort representing the remaining 30% of Finnish heterozygous FH patients by amplifying all the 18 exons of the receptor gene by PCR and searching for DNA variations with the SSCP technique. Ten novel mutations were identified, comprising two nonsense and seven missense mutations as well as one frameshift mutation caused by a 13-bp deletion. A single nucleotide change, substituting adenine for guanidine at position 2533 and resulting in an amino acid change of glycine to aspartic acid at codon 823, was found in DNA samples from 14 unrelated FH probands. This mutation (FH-Turku) affects the sequence encoding the putative basolateral sorting signal of the LDL receptor protein; however, the exact functional consequences of this mutation are yet to be examined. The FH-Turku gene and another point mutation (Leu380-->His or FH-Pori) together account for approximately 8% of the FH-causing genes in Finland and are particularly common among FH patients from the southwestern part of the country (combined, 30%). Primer-introduced restriction analysis was applied for convenient assay of the FH-Turku and FH-Pori point mutations. In conclusion, this paper demonstrates the unique genetic background of FH in Finland and describes a commonly occurring FH gene with a missense mutation closest to the C terminus thus far reported.     

South African founder mutations in the low-density lipoprotein receptor gene causing familial hypercholesterolemia in the Dutch population

In South African Afrikaners, three point mutations in the gene coding for the low-density lipoprotein (LDL)-receptor are responsible for more than 95% of the cases of familial hypercholesterolemia (FH). To investigate whether one or more of these mutations originated in The Netherlands, a large group of Dutch heterozygous FH patients was screened for the presence of these three mutations. Of these, a missense mutation in exon 9 of the LDL-receptor gene, resulting in a substitution of Met for Val⁴⁰⁸, responsible for 15% of FH in Afrikaners, was found in 19 (1.5%) of 1268 FH patients of Dutch descent. Nine of the patients carrying the exon 9 mutation on one allele shared the LDL-receptor DNA haplotype with an FH patient from South Africa, who was homozygous for the same mutation. This would suggest that the mutation in these patients and in the South African patient have a common ancestral background. The remaining ten FH patients all shared a common haplotype, partly identical to the Afrikaner haplotype, which chould have arisen from a single recombinational event. This mutation has not been described in persons other than of Dutch ancestry and supports the hypothesis that this mutation in exon 9 originated in The Netherlands and, in all likelihood, was introduced into South Africa by early Dutch settlers in the seventeenth century.     

Strategy for comprehensive molecular testing for Duchenne and Becker muscular dystrophies

Comprehensive molecular testing for mutations in the DMD gene causing Duchenne and Becker muscular dystrophy (DMD/BMD) is challenging because of the large size of the gene and the variety of mutation types. There is an increasing demand for comprehensive DMD gene molecular testing, including deletion/duplication testing of 79 exons and direct sequencing of the 14-kb coding region from genomic DNA, to provide confirmation of clinical diagnoses in affected patients and to determine carrier risk for family members. To determine an efficient strategy to prioritize patients for comprehensive molecular testing of the DMD gene, we tested a consecutive cohort of 165 males referred over a 4-year period because of a suspicion of DMD or BMD using: (1) a new quantitative multiplex polymerase chain reaction (PCR) assay designed to detect deletions or duplications in all exons of the gene and the brain promoter and (2) direct sequencing of the coding region and intron/exon boundaries. For the patients being tested because of a suspicion of DMD, deletion/duplication testing followed by direct sequencing detected pathogenic mutations in 98% (106/108 total patients). However, of the patients tested because of a suspicion of BMD, only 60% (34/57 total patients) had causative mutations identified, all of which were deletions or duplications. Our results suggest that direct genomic sequence analysis of the DMD gene is a useful addition to deletion/duplication testing for diagnosis of DMD, but does not provide an improved sensitivity compared to deletion/duplication analysis alone for the diagnosis of BMD. In addition, due to the relatively common finding of single exon deletions and duplications (22%, 27 of 125 total patients with deletions/duplications), methods to examine all exons of the gene for deletions/duplications should be used as the initial molecular quantitative test for DMD and BMD.     

Two mutations in LDLR gene were found in two Chinese families with familial hypercholesterolemia

Familial hypercholesterolemia (FH) (OMIM 143890) is an autosomal dominantly inherited disease mainly caused by mutations of the gene encoding the low density lipoprotein receptor (LDLR) and Apolipoprotein (Apo) B. First the common mutation R3500Q in ApoB gene was determined using PCR/RFLP method. Then the LDLR gene was screened for mutations using Touch-down PCR, SSCP and sequencing techniques. Furthermore, the secondary structure of the LDLR protein was predicted with ANTHEPROT5.0. The R3500Q mutation was absent in these two families. A heterozygous p.W483X mutation of LDLR gene was identified in family A which caused a premature stop codon, while a homozygous mutation p.A627T was found in family B. The predicted secondary structures of the mutant LDLR were altered. We identified two known mutations (p.W483X, p.A627T) of the LDLR gene in two Chinese FH families respectively.     

Three novel partial deletions of the low-density lipoprotein (LDL) receptor gene in familial hypercholesterolemia

Summary The low-density lipoprotein (LDL) receptor genes from 18 unrelated Japanese heterozygotes and 1 homozygote with classical familial hypercholesterolemia were analyzed by Southern blot hybridization using fragments of the human LDL receptor cDNA as probes. Four different deletion mutations were detected among 20 mutant LDL receptor genes (20%); they were characterized by restriction mapping. None of these mutations has previously been reported in Caucasian patients with FH: three of the mutations were novel and one was similar to the detetion mutation of FH-Tonami described previously in Japanese patients. In three of the four deletion mutations, the rearrangements were related to intron 15 of the LDL receptor gene, in which many Alu sequences exist. The data suggest that a wide range of molecular heterogeneity exists even in major rearrangements resulting in deletions in the LDL receptor gene. The data also support the hypothesis that there are preferential sites within the LDL receptor gene for major rearrangements resulting in deletions. The possibility that a higher frequency of deletion mutations occurs in classical FH than previously suspected is discussed.     

Prenatal diagnosis of familial hypercholesterolemia: importance of DNA analysis in the high-risk South African population

In this report on the outcome of the first prenatal diagnosis performed for familial hypercholesterolemia (FH) in a South African family, we aim to demonstrate the value of a population-directed screening strategy to identify FH patients in populations with an enrichment for certain low-density lipoprotein receptor (LDLR) gene mutations. Prenatal diagnosis was offered to an Afrikaner couple, both partners heterozygous for the FH mutation D206E, whose first child was diagnosed with heterozygous FH and the second with homozygous FH. Genomic DNA isolated from parental peripheral blood and subsequently amniotic fluid was amplified by the polymerase chain reaction (PCR) and subjected to mutation analysis. Heterozygosity for mutation D206E was confirmed in both parents, whilst this mutation was not detected in DNA directly amplified from amniotic fluid. To exclude the possibility of a false-negative result due to the limited number of cells in the uncultured amniotic fluid sample, cells were also cultured in vitro, and the DNA extracted and subjected to a second round of analysis. This confirmed the absence of mutation D206E in the fetus. This case illustrates the application of a DNA-based mutation detection technique as a simple and rapid diagnostic aid that can be carried out at a relatively early gestational stage. Prenatal diagnosis of FH, aimed at the detection of homozygous cases, is particularly feasible in populations and families with molecularly defined LDLR gene mutations.     

An efficient screening procedure detecting six novel mutations in the LDL receptor gene in Swedish children with hypercholesterolemia

Familial hypercholesterolemia (FH) is an autosomal semi-dominant disorder caused by defects in the low density lipoprotein receptor (LDLR) gene and is a well-documented risk factor for developing cardiovascular disease. The LDLR genes of five Swedish children with FH were examined in this study. Initial mutation screening was performed by denaturing gradient gel electrophoresis (DGGE) with enzymatically amplified exon-sized fragments, each containing a tailing GC-rich requence. The GC-clamped fragments had been synthesized with a restriction site adjacent to the intron-corresponding sequence to allow detachment of the clamps, thereby rendering the fragments suitable for subsequent analysis by single-strand conformation polymorphism (SSCP) analysis of samples from patients with no DGGE-detectable mutations. In addition, all the LDLR genes of the patients were screened for large alterations by restriction fragment length polymorphism analysis. Following this strategy, seven different, potentially disease-causing mutations were detected in the five children with FH. Six of the alterations, five single-base substitutions and one dinucleotide deletion, have not previously been described. DGGE detected six of the mutations and SSCP the seventh.     

Intronic mutations outside of Alu-repeat-rich domains of the LDL receptor gene are a cause of familial hypercholesterolemia

Familial hypercholesterolemia (FH), a frequent monogenic condition complicated by premature cardiovascular disease, is characterized by high allelic heterogeneity at the low-density lipoprotein receptor ( LDLR) locus. Despite more than a decade of genetic testing, knowledge about intronic disease-causing mutations has remained limited because of lack of available genomic sequences. Based on the finding from bioinformatic analysis that Alu repeats represent 85% of LDLR intronic sequences outside exon-intron junctions, we designed a strategy to improve the exploration of genomic regions in the vicinity of exons in 110 FH subjects from an admixed population. In the first group of 42 patients of negative mutation carriers, as previously established by former screening strategies (denaturing gradient gel electrophoresis, DNA sequencing with former primers overlapping splice-sites, Southern Blotting), about half ( n=22) were found to be carriers of at least one heterozygous mutation. Among a second group of 68 newly recruited patients, 27% of mutation carriers ( n=37) had a splicing regulatory mutation. Overall, out of the 54 mutations identified, 13 were intronic, and 18 were novel, out of which nearly half were intronic. Two novel intronic mutations (IVS8-10G-->A within the polypyrimidine tract and IVS7+10G-->A downstream of donor site) might create potential aberrant splice sites according to neural-network computed estimation, contrary to 31 common single nucleotide variations also identified at exon-intron junctions. This new strategy of detecting the most likely disease-causing LDLR mutations outside of Alu-rich genomic regions reveals that intronic mutations may have a greater impact than previously reported on the molecular basis of FH.     

Novel and recurrent rearrangements in the CFTR gene: clinical and laboratory implications for cystic fibrosis screening

Because standard techniques used to detect mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene do not detect single or multiple exonic rearrangements, the importance of such rearrangements may be underestimated. Using an in-house developed, single-tube, semi-quantitative fluorescent PCR (SQF PCR) assay, we analyzed 36 DNA samples submitted for extensive CFTR sequencing and identified ten samples with rearrangements. Of 36 patients with classic CF, 10 (28%) harbored various deletions in the CFTR gene, accounting for 14% of CF chromosomes. A deletion encompassing the CFTR promoter and exons 1 and 2 was detected in a sample from one proband, and in the maternal DNA as well. In another family, a deletion of the promoter and exon 1 was detected in three siblings. In both of these cases, the families were African American and the 3120+1G>A splice site mutation was also identified. These promoter deletions have not been previously described. In a third case, a deletion of exons 17a, 17b, and 18 was identified in a Caucasian female and the same mutation was detected in the paternal DNA. In the other seven cases, we identified the following deletions: exons 2 and 3 (n=2); exons 4, 5, and 6a; exons 17a and 17b; exons 22 and 23; and exons 22, 23, and 24 (n=2). In our series, the frequency of CFTR rearrangements in classic CF patients, when only one mutation was identified by extensive DNA sequencing, was >60% (10/16). Screening for exon deletions and duplications in the CFTR gene would be beneficial in classic CF cases, especially when only one mutation is identified by standard methodologies. An erratum to this article can be found at     

A common Lithuanian mutation causing familial hypercholesterolemia in Ashkenazi Jews.

Familial hypercholesterolemia (FH) is an autosomal dominant disease caused by mutations in the low-density-lipoprotein (LDL) receptor. Here we characterize an LDL-receptor founder mutation that is associated with a distinct LDL-receptor haplotype and is responsible for FH in 35% of 71 Jewish-Ashkenazi FH families in Israel. Sixty four percent (16/25) of the Ashkenazi patients who carry this mutant allele were of Lithuanian origin. The mutation was not found in 47 non-Ashkenazi FH families. This mutation was prevalent (8/10 FH cases) in the Jewish community in South Africa, which originated mainly from Lithuania. The mutation, a 3-bp in-frame deletion that would result in the elimination of Gly197, has been previously designated FH-Piscataway. PCR amplification of a DNA fragment that includes the mutation in heterozygous individuals results in the formation of a heteroduplex that can be demonstrated by PAGE and used for molecular diagnosis.     

Analysis of low density lipoprotein receptor gene mutations and microsatellite haplotypes in Greek FH heterozygous children: six independent ancestors account for 60% of probands

This study reports the characterization of 60% of low density lipoprotein receptor (LDLR) gene mutations in 150unrelated Greek familial hypercholes-terolaemia (FH) heterozygous children by the analysis of six LDLR gene mutations. The linkage disequilibrium of two polymorphic microsatellites (D19S394 and D19S221) flanking the LDLR gene on chromosome19 to the four most common mutations strongly suggests that each mutation is identical-by-descent in the probands included in this study (this is also supported by the geographical distribution of FH families with these mutations throughout Greece) and permits an estimation of the number of generations from a common ancestor for each mutation. The characterization of 60% of LDLR mutations in a representative sample of Greek FH heterozygotes provides a basis for the diagnosis of FH through DNA analysis in Greece, by using single-strand conformation polymorphism analysis followed by allele-specific oligonucleotide hybridization (exon6 mutations) or restriction endonuclease analysis (C152R, V408M). A rapid diagnostic assay positive for the mutation has been developed for the most common mutation, G528D. The application of simple DNA diagnostic assays for LDLR mutation analysis are appropriate for the early identification of FH heterozygotes in Greece and are useful for the primary prevention of coronary artery disease. Received: 7 July 1997 / Accepted: 5 November 1997     

Founder effect in a Belgian-Dutch fragile X population

For many years, the high prevalence of the fragile X syndrome was thought to be caused by a high mutation frequency. The recent isolation of the FMR1 gene and identification of the most prevalent mutation enable a more precise study of the fragile X mutation. As the vast majority of fragile X patients show amplification of an unstable trinucleotide repeat, DNA studies can now trace back the origin of the fragile X mutation. To date, de novo mutations leading to amplification of the CGG repeat have not yet been detected. Recently, linkage disequilibrium was found in the Australian and US populations between the fragile X mutation and adjacent polymorphic markers, suggesting a founder effect of the fragile X mutation. We present here a molecular study of Belgian and Dutch fragile X families. No de novo mutations could be found in 54 of these families. Moreover, we found significant (P < 0.0001) linkage disequilibrium in 68 unrelated fragile X patients between the fragile X mutation and an adjacent polymorphic microsatellite at DXS548. This suggests that a founder effect of the fragile X mutation also exists in the Belgian and Dutch populations. Both the absence of new mutations and the presence of linkage disequilibrium suggest that a few ancestral mutations are responsible for most of the patients with fragile X syndrome.     

Novel and recurrent LDLR gene mutations in Pakistani hypercholesterolemia patients

The majority of patients with the autosomal dominant disorder familial hypercholesterolemia (FH) carry novel mutations in the low density lipoprotein receptor (LDLR) that is involved in cholesterol regulation. In different populations the spectrum of mutations identified is quite different and to date there have been only a few reports of the spectrum of mutations in FH patients from Pakistan. In order to identify the causative LDLR variants the gene was sequenced in a Pakistani FH family, while high resolution melting analysis followed by sequencing was performed in a panel of 27 unrelated sporadic hypercholesterolemia patients. In the family a novel missense variant (c.1916T > G, p.(V639G)) in exon 13 of LDLR was identified in the proband. The segregation of the identified nucleotide change in the family and carrier status screening in a group of 100 healthy subjects was done using restriction fragment length polymorphism analysis. All affected members of the FH family carried the variant and none of the non-affected members nor any of the healthy subjects. In one of the sporadic cases, two sequence changes were detected in exon 9, one of these was a recurrent missense variant (c.1211C > T; p.T404I), while the other was a novel substitution mutation (c.1214 A > C; N405T). In order to define the allelic status of this double heterozygous individual, PCR amplified fragments were cloned and sequenced, which identified that both changes occurred on the same allele. In silico tools (PolyPhen and SIFT) were used to predict the effect of the variants on the protein structure, which predicted both of these variants to have deleterious effect. These findings support the view that there will be a novel spectrum of mutations causing FH in patients with hypercholesterolaemia from Pakistan.     

Identification and characterization of the familial adenomatous polyposis coli gene.

DNA from 61 unrelated patients with adenomatous polyposis coli (APC) was examined for mutations in three genes (DP1, SRP19, and DP2.5) located within a 100 kb region deleted in two of the patients. The intron-exon boundary sequences were defined for each of these genes, and single-strand conformation polymorphism analysis of exons from DP2.5 identified four mutations specific to APC patients. Each of two aberrant alleles contained a base substitution changing an amino acid to a stop codon in the predicted peptide; the other mutations were small deletions leading to frameshifts. Analysis of DNA from parents of one of these patients showed that his 2 bp deletion is a new mutation; furthermore, the mutation was transmitted to two of his children. These data have established that DP2.5 is the APC gene.