Mutation analysis in Norwegian families with hereditary hemorrhagic telangiectasia: founder mutations in ACVRL1.

Hereditary hemorrhagic telangiectasia (HHT, Osler-Weber-Rendu disease) is an autosomal dominant inherited disease defined by the presence of epistaxis and mucocutaneous telangiectasias and arteriovenous malformations (AVMs) in internal organs. In most families (~85%), HHT is caused by mutations in the ENG (HHT1) or the ACVRL1 (HHT2) genes. Here, we report the results of genetic testing of 113 Norwegian families with suspected or definite HHT. Variants in ENG and ACVRL1 were found in 105 families (42 ENG, 63 ACVRL1), including six novel variants of uncertain pathogenic significance. Mutation types were similar to previous reports with more missense variants in ACVRL1 and more nonsense, frameshift and splice-site mutations in ENG. Thirty-two variants were novel in this study. The preponderance of ACVRL1 mutations was due to founder mutations, specifically, c.830C>A (p.Thr277Lys), which was found in 24 families from the same geographical area of Norway. We discuss the importance of founder mutations and present a thorough evaluation of missense and splice-site variants.

X-linked congenital ptosis and associated intellectual disability, short stature, microcephaly, cleft palate, digital and genital abnormalities define novel Xq25q26 duplication syndrome.

Submicroscopic duplications along the long arm of the X-chromosome with known phenotypic consequences are relatively rare events. The clinical features resulting from such duplications are various, though they often include intellectual disability, microcephaly, short stature, hypotonia, hypogonadism and feeding difficulties. Female carriers are often phenotypically normal or show a similar but milder phenotype, as in most cases the X-chromosome harbouring the duplication is subject to inactivation. Xq28, which includes MECP2 is the major locus for submicroscopic X-chromosome duplications, whereas duplications in Xq25 and Xq26 have been reported in only a few cases. Using genome-wide array platforms we identified overlapping interstitial Xq25q26 duplications ranging from 0.2 to 4.76 Mb in eight unrelated families with in total five affected males and seven affected females. All affected males shared a common phenotype with intrauterine- and postnatal growth retardation and feeding difficulties in childhood. Three had microcephaly and two out of five suffered from epilepsy. In addition, three males had a distinct facial appearance with congenital bilateral ptosis and large protruding ears and two of them showed a cleft palate. The affected females had various clinical symptoms similar to that of the males with congenital bilateral ptosis in three families as most remarkable feature. Comparison of the gene content of the individual duplications with the respective phenotypes suggested three critical regions with candidate genes (AIFM1, RAB33A, GPC3 and IGSF1) for the common phenotypes, including candidate loci for congenital bilateral ptosis, small head circumference, short stature, genital and digital defects.

Vaccine-associated varicella and rubella infections in severe combined immunodeficiency with isolated CD4 lymphocytopenia and mutations in IL7R detected by tandem whole exome sequencing and chromosomal microarray.

In areas without newborn screening for severe combined immunodeficiency (SCID), disease-defining infections may lead to diagnosis, and in some cases, may not be identified prior to the first year of life. We describe a female infant who presented with disseminated vaccine-acquired varicella (VZV) and vaccine-acquired rubella infections at 13 months of age. Immunological evaluations demonstrated neutropenia, isolated CD4 lymphocytopenia, the presence of CD8(+) T cells, poor lymphocyte proliferation, hypergammaglobulinaemia and poor specific antibody production to VZV infection and routine immunizations. A combination of whole exome sequencing and custom-designed chromosomal microarray with exon coverage of primary immunodeficiency genes detected compound heterozygous mutations (one single nucleotide variant and one intragenic copy number variant involving one exon) within the IL7R gene. Mosaicism for wild-type allele (20-30%) was detected in pretransplant blood and buccal DNA and maternal engraftment (5-10%) demonstrated in pretransplant blood DNA. This may be responsible for the patient's unusual immunological phenotype compared to classical interleukin (IL)-7Rα deficiency. Disseminated VZV was controlled with anti-viral and immune-based therapy, and umbilical cord blood stem cell transplantation was successful. Retrospectively performed T cell receptor excision circle (TREC) analyses completed on neonatal Guthrie cards identified absent TREC. This case emphasizes the danger of live viral vaccination in severe combined immunodeficiency (SCID) patients and the importance of newborn screening to identify patients prior to high-risk exposures. It also illustrates the value of aggressive pathogen identification and treatment, the influence newborn screening can have on morbidity and mortality and the significant impact of newer genomic diagnostic tools in identifying the underlying genetic aetiology for SCID patients.

A translocation between Xq21.33 and 22q13.33 causes an intragenic SHANK3 deletion in a woman with Phelan-McDermid syndrome and hypergonadotropic hypogonadism.

Chromosome 22q13 monosomy has been described as a contiguous gene syndrome. Localized in the critical region, SHANK3 is likely to play a key role in the expression of the clinical phenotype. SHANK3 mutations have also been reported in autistic patients without a syndromic phenotype. We report on a 20-year-old woman with mental retardation carrying a de novo translocation between chromosome Xq21.33 and 22q13.33, associated with a duplication on Xq21.33 and deletion on 22q13.33. As a child her development was characterized by disturbed social interaction, stereotypic hand movements and ritualistic behavior and she was considered at one time to have autistic features. All these traits match the 22q13 deletion syndrome (Phelan-McDermid syndrome, OMIM 606232), likely due to the deletion overlapping the last two exons of the SHANK3 gene. Our patient harbors the smallest and most distal SHANK3 deletion described to date, yet resulting in the full spectrum of the Phelan-McDermid syndrome. In addition, she has hypergonadotropic hypogonadism with low estrogen level, high FSH level, and irregular menstruation. Intriguingly, chromosome translocations affecting the chromosome band Xq21 can result in premature ovarian failure.

Transcriptional response to ionizing radiation in human radiation sensitive cell lines.

BACKGROUND AND PURPOSE: Radiation is a common treatment of cancer, but some patients show severe side effects when exposed to small doses of radiation. The aim of this study was to explore the underlying cause of radiation sensitivity in a group of radiation sensitive patients. MATERIALS AND METHODS: Lymphoblastoid cell lines from 5 normal individuals, 4 Ataxia Telangiectasia (AT), and 12 non-AT radiation sensitive (RS) patients were irradiated. RNA was isolated before and after radiation and hybridized to 15k cDNA microarrays and gene expression was recorded. RESULTS AND CONCLUSION: The RS cell lines showed an expression phenotype different from both the AT and normal cell lines. Six of the RS cell lines had a distinct expression profile before radiation. This implies that the RS patients are a heterogeneous group, but that six of the patients may have a common cause of radiation sensitivity.

Two founder mutations in the LDL receptor gene in Norwegian familial hypercholesterolemia subjects.

DNA from 20 unrelated familial hypercholesterolemia (FH) subjects were studied by analysis of single-strand conformation polymorphisms (SSCP) for mutations in exon 3 of the low density lipoprotein (LDL) receptor gene. Four different SSCP patterns were observed. The underlying mutations were characterized by DNA sequencing. One pattern represented the wild-type sequence. Another pattern represented a C-->G mutation (FH-Svartor) that changes codon 78 into the amber stop codon. The two other patterns represented heterozygosity and homozygosity, respectively, for a G-->A splice donor mutation (FH-Elverum) in intron 3. Based upon two PCR-based assays, the frequencies of FH-Svartor and FH-Elverum among 267 unrelated FH subjects, were 8% and 25%, respectively. FH Svartor was located on a chromosome with haplotype 3 in all five families where haplotype analysis were performed. FH Elverum was located on haplotype 2 in 16 out of 20 families. The two mutations must be considered founder mutations in the Norwegian population, and their existence will be clinically useful in diagnosing FH. The presence of two founder mutations together with previously published data on the prevalence of FH in Norway, indicate that FH may be a more common disease in Norway than previously thought.

Screening for point mutations by semi-automated DNA sequencing using sequenase and magnetic beads.

We have established an improved method for detecting point mutations by semi-automated DNA sequencing of PCR fragments generated from genomic DNA. The method employs magnetic beads to create immobilized single-stranded DNA templates, and the sequencing reaction is performed with Sequenase. This method is superior to sequencing with Taq DNA polymerase because the uniform peak height with Sequenase makes heterozygosity easily detectable as double peaks that are half the normal height. Detection of heterozygosity by this method is illustrated by sequencing a 180-bp fragment of the human apolipoprotein B gene. This fragment contains codon 3500, where a point mutation (3500CGG-->CAG) is found in subjects with the autosomal dominant disease familial defective apolipoprotein B. The nonuniform peak height with Taq DNA polymerase makes it more difficult to detect heterozygosity. This is also illustrated by sequencing a 278-bp fragment of the low-density lipoprotein receptor gene.

The genetic algorithm applied to haplotype data at the LDL receptor locus.

Conventional statistical methods based upon single restriction fragment length polymorphisms often prove inadequate in studies of genetic variation. Cladistic analysis has been suggested as an alternative, but requires basic assumptions that usually cannot be met. We wanted to test whether it could be a workable approach to apply the genetic algorithm, an artificial intelligence method, to haplotype data. The genetic algorithm creates in-computer artificial 'individuals', all having 'genes' coding for solutions to a problem. The individuals are allowed to compete and 'mate', individuals with genes coding for better solutions mating more often. Genes coding for good solutions survive through generations of the genetic algorithm. At the end of the run, the best solutions can be extracted. We applied the genetic algorithm to data consisting of cholesterol values and haplotypes made up of seven restriction sites at the LDL receptor locus. The persons included were 114 FH (familial hypercholesterolemia) patients and 61 normals. The genetic algorithm found the restriction sites 1 (Sph1 in intron 6), 2 (StuI in exon 8), and 7 (ApaLI site in the 3' flanking region) were associated with high cholesterol levels. As a validity check we used runs of the genetic algorithm applied to 'artificial patients', i.e. artificially generated haplotypes linked to artificially generated cholesterol values. This demonstrated the genetic algorithm consistently found the appropriate haplotype. We conclude that the genetic algorithm may be a useful tool for studying genetic variation.

Microdeletions including FMR1 in three female patients with intellectual disability - further delineation of the phenotype and expression studies.

Fragile X syndrome (FXS) is one of the most common causes of intellectual disability/developmental delay (ID/DD), especially in males. It is caused most often by CGG trinucleotide repeat expansions, and less frequently by point mutations and partial or full deletions of the FMR1 gene. The wide clinical spectrum of affected females partly depends on their X-inactivation status. Only few female ID/DD patients with microdeletions including FMR1 have been reported. We describe 3 female patients with 3.5-, 4.2- and 9.2-Mb de novo microdeletions in Xq27.3-q28 containing FMR1. X-inactivation was random in all patients, yet they presented with ID/DD as well as speech delay, macrocephaly and other features attributable to FXS. No signs of autism were present. Here, we further delineate the clinical spectrum of female patients with microdeletions. FMR1 expression studies gave no evidence for an absolute threshold below which signs of FXS present. Since FMR1 expression is known to be highly variable between unrelated females, and since FMR1 mRNA levels have been suggested to be more similar among family members, we further explored the possibility of an intrafamilial effect. Interestingly, FMR1 mRNA levels in all 3 patients were significantly lower than in their respective mothers, which was shown to be specific for patients with microdeletions containing FMR1.

15q11.2 microdeletion - seven new patients with delayed development and/or behavioural problems.

15q11.2 microdeletion has been suggested as a new microdeletion syndrome and several patients have been described in the literature. We report seven new patients belonging to six families, age 9-24 years old, with a 350 kb 15q11.2 deletion of the four highly conserved genes (TUBGCP5, NIPA1, NIPA2 and CYFIP1) earlier reported. All our patients had some degree of learning difficulties, delayed development and/or behavioural problems. Common dysmorphic features and congenital malformations were not characteristics of our patients. The deletion was inherited from a mildly affected parent in all cases tested (5/6 families available for testing both parents). These seven new cases confirm some of the features earlier reported to be associated with 15q11.2 deletion, and help to further delineate the phenotype associated with 15q11.2 deletion.

Application of long polymerase chain reaction in the study of the LDL receptor gene.

In this report we have applied an improved method of the polymerase chain reaction (PCR) in order to detect structural aberrations and point mutations in the low density lipoprotein receptor (LDLR) gene. Except from intron 1, we were able to amplify the entire gene in two fragments of 16.1 and 20.0 kb, respectively. We were also able to detect a 9.6-kb deletion, known as FH Helsinki, as well as a restriction fragment length polymorphism in the 2.7-kb intron 6. We conclude that PCR can almost completely replace Southern blot analysis in molecular genetic studies of the LDLR gene.

Evaluation of running conditions for SSCP analysis: application of SSCP for detection of point mutations in the LDL receptor gene.

We have performed analyses of single-strand conformation polymorphisms (SSCP) of the promoter region and the translated parts of the 18 exons of the low-density lipoprotein receptor (LDLR) gene. DNA from 20 unrelated familial hypercholesterolemia (FH) patients was studied. Four different running conditions were used for the nondenaturing gel electrophoresis to systematically evaluate how differences in the running conditions affect the sensitivity of the assay. These conditions were 15 W, 40 W, and 50 W in the absence of glycerol, and 50 W in the presence of 10% glycerol. SSCP analyses of the 18 PCR fragments for the 20 subjects revealed a total of 46 genotypes at 15 W, 45 at 50 W, 42 at 40 W, and 41 at 50 W with 10% glycerol. A total of 53 different genotypes were observed when the results of the four conditions were considered together. Assuming that the four conditions together detected 100% of the different genotypes, the sensitivity of the four individual conditions ranged between 87% (15 W) and 77% (50 W with 10% glycerol). There were marked differences among the different running conditions to detect abnormal SSCP patterns of individual exons. Therefore, different conditions should be used for the different exons of the LDLR gene.

Identification of the apo B-3500 mutation in the Norwegian population.

Familial defective apolipoprotein B-100 (FDB) is caused by a mutation in codon 3500 of the apo B gene. It is inherited in a co-dominant fashion and is characterized by hypercholesterolaemia. Thus, FDB has similar features to familial hypercholesterolaemia (FH). In order to investigate whether some of the Norwegian subjects diagnosed as having FH actually have FDB, we have screened 208 Norwegian FH heterozygotes for the apo B-3500 mutation. One of the subjects possessed the mutation which was on a haplotype compatible with the mutation-bearing haplotype found in other populations. Although, hypercholesterolaemia segregated with haplotypes both at the apolipoprotein B and low density lipoprotein (LDL) receptor loci in the proband's family, LDL receptor analysis revealed that the proband was not doubly heterozygous for FDB and FH.

Two novel point mutations in the EGF precursor homology domain of the LDL receptor gene causing familial hypercholesterolemia.

Familial hypercholesterolemia is caused by mutations in the low density lipoprotein (LDL) receptor gene. Analysis of single-strand conformation polymorphisms of exons 10 and 11 of the LDL receptor gene from familial hypercholesterolemia heterozygotes indicated the presence of two mutations, which were characterized by DNA sequencing. One mutation (delta N466) was a 3-bp deletion in exon 10 that deletes Asn in codon 466. The other (intron 11 +1, G-->T) was a splice donor mutation at position +1 of intron 11.

Familial hypercholesterolaemia caused by a non-sense mutation in codon 329 of the LDL receptor gene.

Analysis of single-strand conformation polymorphisms (SSCP) was employed to screen familial hypercholesterolaemia (FH) subjects for point mutations in exon 7 of the low density lipoprotein receptor (LDLR) gene. An abnormal band pattern was found in one out of 100 unrelated FH subjects. The underlying mutation was found by DNA sequencing to be due to heterozygosity (C/T) at nucleotide 1048. Nucleotide 1048 is the first nucleotide of codon 329, and is located within the domain that has a high degree of homology with the precursor for epidermal growth factor. The C-->T transition, referred to as FH-Fossum, changes codon 329 from CGAArg to TGAStop. The mutation is expected to cause a class 1 receptor defect.

Mutant transcripts of the LDL receptor gene: mRNA structure and quantity.

mRNA of the low-density lipoprotein receptor (LDLR) gene from 22 heterozygous familial hypercholesterolemic subjects possessing different mutations in this gene was analyzed by Northern blot analysis and reverse transcription-polymerase chain reaction (RT-PCR) in order to detect abnormally spliced transcripts. These analyses revealed abnormally spliced transcripts for the two splice-site mutations 1359-1G-->A and 1705 + 1G-->T. The abnormally spliced transcript for mutation 1359-1G-->A was caused by activation of a cryptic acceptor splice site in exon 10. As a result, seven nucleotides of exon 10 were deleted. For mutation 1705 + 1G-->T, two mutant transcripts were observed. In the first transcript, exon 10 was spliced to exon 13, and in the second transcript intron 11 was retained. The relative amount of mutant transcripts from 14 of the 22 subjects was determined by use of an RT-PCR-based method. Quantitation of the relative amounts of mutant transcripts for five missense mutations resulted in a mean value (+/-SD) of 52.8% (+/-4.55). In comparison, quantitation of the relative amounts of mutant transcripts for five nonsense mutations resulted in a mean value of 31.8% (+/-6.91). This value was significantly lower than the value of 54.2% (+/-2.38) obtained for nine healthy subjects (P < 0.0001). The relative amount of mutant transcripts for the 1705 + 1G-->T mutation was 36%. Thus, transcripts from alleles containing premature stop codons are present in reduced amounts, whereas transcripts from alleles containing missense mutations are present in normal amounts. These findings underscore the importance of determining how mutations affect mRNA structure and quantity in order to understand how mutations cause disease.

A 9.6 kilobase deletion in the low density lipoprotein receptor gene in Norwegian familial hypercholesterolemia subjects.

Haplotype analysis of the low density lipoprotein receptor (LDLR) gene was performed in Norwegian subjects heterozygous for familial hypercholesterolemia (FH). Southern blot analysis of genomic DNA, using an exon 18 specific probe and the restriction enzyme NcoI, showed that two out of 57 unrelated FH subjects had an abnormal 3.6 kb band. Further analyses revealed that this abnormal band was due to a 9.6 kb deletion that included exons 16 and 17. The 5' deletion breakpoint was after 245 bp of intron 15, and the 3' deletion breakpoint was in exon 18 after nucleotide 3390 of cDNA. Thus, both the membrane-spanning and cytoplasmatic domains of the receptor had been deleted. A polymerase chain reaction (PCR) method was developed to identify this deletion among other Norwegian FH subjects. As a result of this screening one additional subject was found out of 124 subjects screened. Thus, three out of 181 (1.7%) unrelated Norwegian FH subject possessed this deletion. The deletion was found on the same haplotype in the three unrelated subjects, suggesting a common mutagenic event. The deletion is identical to a deletion (FH-Helsinki) that is very common among Finnish FH subjects. However, it is not yet known whether the mutations evolved separately in the two countries.

Effects of a 9.6-kb deletion of the LDL receptor gene (FH Helsinki) on structure and levels of mRNA.

FH Helsinki is a deletion of the low-density lipoprotein receptor (LDLR) gene that deletes 9.6 kb from intron 15 to exon 18. Screening for mutant transcripts by Northern blot analysis from a patient heterozygous for FH Helsinki revealed two mutant transcripts. One was a transcript where the proximal part of intron 15 was retained in mRNA. The second was a transcript where exon 15 was spliced to nucleotide 4186 of exon 18. Thus, this transcript was generated using the normal donor splice site in intron 15, and a cryptic AG acceptor splice site in exon 18. Translation of the two mutant transcripts is predicted to give nonfunctional proteins, as both the membrane-spanning domain and the cytoplasmic domain of the receptor are deleted. Scanning of the autoradiograms showed that the amounts of each of the two mutant transcripts were approximately 10 times higher than that of the normal transcript in our heterozygous patient. The finding of higher levels of mutant transcripts was confirmed by an allele-specific transcript quantitation method, in which the amount of the two mutant transcripts together was approximately 5 times higher than the amount of the normal transcript. Deletion of destabilizing elements (AU-rich elements) by FH Helsinki are proposed to cause the increased levels of mutant transcripts.

Haplotype analysis at the low density lipoprotein receptor locus in normal and familial hypercholesterolemia Norwegian subjects.

We have performed haplotype analysis at the low density lipoprotein receptor (LDLR) locus in order to investigate the molecular genetics of familial hypercholesterolemia (FH) in Norway. Haplotypes were constructed using 7 restriction fragment length polymorphisms (RFLPs) in 194 subjects from 48 unrelated Norwegian FH families. Hypercholesterolemia co-segregated with haplotypes at the LDLR locus in all 48 families. Unambiguous haplotypes could be established for 190 independent chromosomes from 51 FH heterozygotes and 44 healthy normal subjects. A total of 20 different haplotypes was found. The most frequent haplotype was haplotype 3, which accounted for 32.4% or 43.1% of the normal and defective haplotypes, respectively. Haplotype 2 was significantly more frequent among the defective alleles than among the normal alleles (33.3% and 5.8%, respectively, p < 0.0001). Thus, haplotypes 2 and 3 accounted for 76.4% of the defective haplotypes. More data are needed to determine the possible existence of founder genes in the Norwegian population. Haplotypes 1, 2, 3, 5 and 8 accounted for 88.2% of the normal haplotypes. Based upon the cumulative heterozygosity index, the SphI, NcoI and 3' ApaLI RFLPs are the most informative markers in the Norwegian population.

Screening for point mutations in exon 10 of the low density lipoprotein receptor gene by analysis of single-strand conformation polymorphisms: detection of a nonsense mutation-FH469-->Stop.

DNA from 40 unrelated familial hypercholesterolemia (FH) heterozygotes were subjected to analyses of single-strand conformation polymorphisms (SSCPs) of exon 10 of the low density lipoprotein receptor (LDLR) gene. Four different SSCP patterns were observed. The underlying mutations were characterized by DNA sequencing. Three of the patterns represented the three genotypes of a recently described sense mutation in codon 450. A method based upon the polymerase chain reaction (PCR) was developed to analyze this mutation. The frequencies of the wild-type (G at nucleotide 1413) and mutant (A at nucleotide 1413) alleles were 0.56 and 0.44, respectively. The fourth pattern was found in only one FH heterozygote and was caused by heterozygosity at nucleotide 1469 (G/A). Nucleotide 1469 is the second base of codon 469Trp(TGG). The G-->A mutation changes this codon into the amber stop codon, and is referred to as FH469-->Stop. The mutant receptor consists of the amino terminal 468 amino acids. Because the truncated receptor has lost the membrane-spanning domain, it will not be anchored in the cell membrane. FH469-->Stop destroys an AvaII restriction site, and this characteristic was used to develop a PCR method to establish its frequency in Norwegian FH subjects. Two out of 204 (1%) unrelated FH heterozygotes possessed the mutation.