Mutational screening of EXT1 and EXT2 genes in Polish patients with hereditary multiple exostoses

Hereditary multiple exostoses (HME) also known as multiple osteochondromas represent one of the most frequent bone tumor disorder in humans. Its clinical presentation is characterized by the presence of multiple benign cartilage-capped tumors located most commonly in the juxta-epiphyseal portions of long bones. HME are usually inherited in autosomal dominant manner, however de novo mutations can also occur. In most patients, the disease is caused by alterations in the EXT1 and EXT2 genes. In this study we investigated 33 unrelated Polish probands with the clinical and radiological diagnosis of HME by means of Sanger sequencing and MLPA for all coding exons of EXT1 and EXT2. We demonstrated EXT1 and EXT2 heterozygous mutations in 18 (54.6 %) and ten (30.3 %) probands respectively, which represents a total of 28 (84.9 %) index cases. Sequencing allowed for the detection of causative changes in 26 (78.8 %) probands, whereas MLPA showed intragenic deletions in two (6.1 %) further cases (15 mutations represented novel changes). Our paper is the first report on the results of exhaustive mutational screening of both EXT1/EXT2 genes in Polish patients. The proportion of EXT1/EXT2 mutations in our group was similar to other Caucasian cohorts. However, we found that EXT1 lesions in Polish patients cluster in exons 1 and 2 (55.6 % of all EXT1 mutations). This important finding should lead to the optimization of cost-effectiveness rate of HME diagnostic testing. Therefore, the diagnostic algorithm for HME should include EXT1 sequencing (starting with exons 1–2), followed by EXT2 sequencing, and MLPA/qPCR for intragenic copy number changes.     

Identification of a novel 15.5 kb <Emphasis Type="Italic">SHOX</Emphasis> deletion associated with marked intrafamilial phenotypic variability and analysis of its molecular origin

Haploinsufficiency of the short stature homeobox contaning SHOX gene has been shown to result in a spectrum of phenotypes ranging from Leri–Weill dyschondrosteosis (LWD) at the more severe end to SHOX-related short stature at the milder end of the spectrum. Most alterations are whole gene deletions, point mutations within the coding region, or microdeletions in its flanking sequences. Here, we present the clinical and molecular data as well as the potential molecular mechanism underlying a novel microdeletion, causing a variable SHOX-related haploinsufficiency disorder in a three-generation family. The phenotype resembles that of LWD in females, in males, however, the phenotypic expression is milder. The 15523-bp SHOX intragenic deletion, encompassing exons 3–6, was initially detected by array-CGH, followed by MLPA analysis. Sequencing of the breakpoints indicated an Alu recombination-mediated deletion (ARMD) as the potential causative mechanism.     

KIT Proto-oncogene Exon 8 Deletions at Codon 419 are Highly Frequent in Acute Myeloid Leukaemia with Inv(16) in Indian Population

The KIT gene is a receptor tyrosine kinase class III expressed by early hematopoietic progenitor cells and plays a significant role in hematopoietic stem cell proliferation, differentiation and survival which is considered to be a remarkable feature in the course of growth of acute myeloid leukaemia (AML). Owing to insufficient study of mutations in the KIT gene, the diagnosis and rate of recurrence of these mutations with divergent subtypes in AML cases in India is of concern. In order to find out the frequency of mutations of KIT gene exon 8 in 109 AML cases, we have performed polymerase chain reaction–single-strand conformation polymorphism (PCR–SSCP) followed by DNA sequencing and have identified 24 mutations in exon 8 in 13 cases, including deletions at codon 418 (n = 3), 419 (n = 11) and 420 (n = 5) as well as point mutations at codon 417 (n = 1) and 421 (n = 4). In eleven AML cases, exon 8 deletion and point mutations involved the loss at codon Asp419 immoderately conserved cross species placed in the receptor extracellular domain. Frequency elevation of the KIT proto-oncogene exon 8 deletion and point mutations in AML cases allude a crucial function for this region of the receptor extracellular domain. Thus, we report the incidence of acquired mutations in exon 8, with consistent loss at codon Asp419, in 10.09 % of AML cases in a selected Indian population.     

Analysis of severely affected patients with dihydropyrimidine dehydrogenase deficiency reveals large intragenic rearrangements of DPYD and a de novo interstitial deletion del(1)(p13.3p21.3)

Dihydropyrimidine dehydrogenase (DPD) deficiency is an infrequently described autosomal recessive disorder of the pyrimidine degradation pathway and can lead to mental and motor retardation and convulsions. DPD deficiency is also known to cause a potentially lethal toxicity following administration of the antineoplastic agent 5-fluorouracil. In an ongoing study of 72 DPD deficient patients, we analysed the molecular background of 5 patients in more detail in whom initial sequence analysis did not reveal pathogenic mutations. In three patients, a 13.8 kb deletion of exon 12 was found and in one patient a 122 kb deletion of exon 14–16 of DPYD. In the fifth patient, a c.299_302delTCAT mutation in exon 4 was found and also loss of heterozygosity of the entire DPD gene. Further analysis demonstrated a de novo deletion of approximately 14 Mb of chromosome 1p13.3–1p21.3, which includes DPYD. Haploinsufficiency of NTNG1, LPPR4, GPSM2, COL11A1 and VAV3 might have contributed to the severe psychomotor retardation and unusual craniofacial features in this patient. Our study showed for the first time the presence of genomic deletions affecting DPYD in 7% (5/72) of all DPD deficient patients. Therefore, screening of DPD deficient patients for genomic deletions should be considered.     

Molecular characterization of two deletion events involving Alu-sequences, one novel base substitution and two tentative hotspot mutations in the hypoxanthine phosphoribosyltransferase (HPRT) gene in five patients with Lesch-Nyhan syndrome

Mutations identified in the hypoxanthine phosphoribosyltransferase (HPRT) gene of patients with Lesch-Nyhan (LN) syndrome are dominated by simple base substitutions. Few hotspot positions have been identified, and only three large genomic rearrangements have been characterized at the molecular level. We have identified one novel mutation, two tentative hot spot mutations, and two deletions by direct sequencing of HPRT cDNA or genomic DNA from fibroblasts or T-lymphocytes from LN patients in five unrelated families. One is a missense mutation caused by a 610C→T transition of the first base of HPRT exon 9. This mutation has not been described previously in an LN patient. A nonsense mutation caused by a 508C→T transition at a CpG site in HPRT exon 7 in the second patient and his younger brother is the fifth mutation of this kind among LN patients. Another tentative hotspot mutation in the third patient, a frame shift caused by a G nucleotide insertion in a monotonous repeat of six Gs in HPRT exon 3, has been reported previously in three other LN patients. The fourth patient had a tandem deletion: a 57-bp deletion in an internally repeated Alu-sequence of intron 1 was separated by 14 bp from a 627-bp deletion that included HPRT exon 2 and was flanked by a 4-bp repeat. This complex mutation is probably caused by a combination of homologous recombination and replication slippage. Another large genomic deletion of 2969 bp in the fifth patient extended from one Alu-sequence in the promoter region to another Alu-sequence of intron 1, deleting the whole of HPRT exon 1. The breakpoints were located within two 39-bp homologous sequences, one of which overlapped with a well-conserved 26-bp Alu-core sequence previously suggested as promoting recombination. These results contribute to the establishment of a molecular spectrum of LN mutations, support previous data indicating possible mutational hotspots, and provide evidence for the involvement of Alu-mediated recombination in HPRT deletion mutagenesis. Received: 21 April 1998 / Accepted: 16 July 1998     

Mitochondrial DNA 4977-bp deletion in endometriosis

Endometriosis is a multifactorial gynecological condition characterized by the presence of ectopic endometrial and stromal tissue outside the uterus. Free radicals and Oxidative stress have been proposed to be involved in the pathogenesis of the endometriosis. It has been shown that mitochondrial DNA (mtDNA) is particularly susceptible to oxidative damage and mutations due to the high rate of reactive oxygen species production and limited DNA repair capacity in mitochondria. While a number of deletions can occur, the most commonly studied in human is a 4977-bp deletion that removes all or parts of the genes for NADH dehydrogenase subunits 3, 4, 4L and 5, cytochrome C oxidase subunit III and ATP synthase subunits 6 and 8.” We evaluated whether mtDNA common deletion is related with the susceptibility to endometriosis in northern Iran. In this study 80 endometriosis cases and 100 controls were enrolled. Total DNA was extracted from endometrial tissue samples. The mitochondrial common deletion was determined by Gap- polymerase chain reaction (Gap-PCR). It was found that the mitochondrial common deletion was more likely to be present in patients with endometriosis. Assessing indicate that 60 % of patients and 8 % of controls show mtDNA 4977-bp deletion (Odds Ratio [OR] = 17.25, P < 0.0001, confidence interval [CI] = 5.18–57.36). The mtDNA 4977 deletion may play a role in endometriosis. Further studies with larger numbers of patients are required for further evaluation and confirmation of our finding.     

Mucopolysaccharidosis type IVA: common double deletion in the N-acetylgalactosamine-6-sulfatase gene (GALNS)

Mucopolysaccharidosis IVA (MPS IVA) is an autosomal recessive disorder caused by a deficiency in N-acetylgalactosamine-6-sulfatase (GALNS). We found two separate deletions of nearly 8.0 and 6.0 kb in the GALNS gene, including some exons. There are Alu repetitive elements near the breakpoints of the 8.0-kb deletion, and this deletion resulted from an Alu—Alu recombination. The other 6.0-kb deletion involved illegitimate recombinational events between incomplete short direct repeats of 8 bp at deletion breakpoints. The same rearrangement has been observed in a heteroallelic state in four unrelated patients. This is the first documentation of a common double deletion a gene that is not a member of a gene cluster.     

A large Alu-mediated deletion, identified by PCR, as the molecular basis for glycogen storage disease Type II (GSDII)

Glycogen storage disease type II (GSDII) is an autosomal recessive disorder resulting from inherited deficiency of the enzyme lysosomal acid α-glucosidase. Over 40 different mutations have been described but no large deletions have been previously identified. We now describe a homozygous large (9-kb) deletion extending from IVS15 to 4 kb downstream of the terminal exon (exon 20), detected by polymerase chain reaction (PCR)-based methods. The deletion was initially suspected because of failure to amplify a contiguous group of exons by PCR. We hypothesized an Alu/Alu recombination, based on our prior demonstration by Southern blotting of Alu elements in the regions potentially flanking the deletion. Additional sequence analysis of genomic fragments confirmed the presence of Alu elements and allowed the design of flanking primers for PCR amplification. Amplification resulted in a smaller than normal fragment (0.7 vs 10 kb) in homozygosity in the proband and in heterozygosity in her parents. Cloning and sequencing of the smaller than normal 0.7-kb deletion fragment revealed an Alu/Alu deletion junction. In heterozygosity this deletion would not be detected by currently standard PCR mutation detection methods. Based on other Alu-mediated deletions, this deletion is likely to be recurrent and should be screened for in all non-consanguineous GSDII patients, particularly when only one mutation has been identified and none of the 12 single-nucleotide polymorphisms in the deleted region are heterozygous. These observations also suggest that initial characterization of genes at disease-causing loci should include a search for Alu and other repetitive elements to facilitate subsequent PCR-based mutation analysis. Received: 24 August 1998 / Accepted: 13 November 1998     

Recombinations between Alu repeat sequences that result in partial deletions within the C1 inhibitor gene

Genomic DNA sequence analysis was used to define the extent of deletions within the C1 inhibitor gene in two families with type I hereditary angioneurotic edema. Southern blot analysis initially indicated the presence of the partial deletions. One deletion was approximately 2 kb and included exon VII, whereas the other was approximately 8.5 kb and included exons IV–VI. Genomic libraries from an affected member of each family were constructed and clones containing the deletions were analyzed. Sequence analysis of the deletion joints of the mutants and corresponding regions of the normal gene in the two families demonstrated that both deletion joints resulted from recombination of two Alu repetitive DNA elements. Alu repeat sequences from introns VI and VII combined to make a novel Alu in family A, and Alu sequences in introns III and VI were spliced to make a new Alu in family B. The splice sites in the Alu sequences of both mutants were located in the left arm of the Alu element, and both recombination joints overlapped one of the RNA polymerase III promoter sequences. Because the involved Alu sequences, in both instances, were oriented in the same direction, unequal crossingover is the most likely mechanism to account for these mutations.     

No correlation between <Emphasis Type="Italic">NF1</Emphasis> mutation position and risk of optic pathway glioma in 77 unrelated NF1 patients

Neurofibromatosis type 1 (NF1) is a common monogenic disorder whereby affected individuals are predisposed to developing CNS tumors, including optic pathway gliomas (OPGs, occurring in ~15 to 20 % of cases). So far, no definite genotype–phenotype correlation determining NF1 patients at risk for tumor formation has been described, although enrichment for mutations in the 5′ region of the NF1 gene in OPG patients has been suggested. We used whole exome sequencing, targeted sequencing, and copy number analysis to screen 77 unrelated NF1 patients with (n = 41) or without (n = 36; age ≥10 years) optic pathway glioma for germline NF1 alterations. We identified germline NF1 mutations in 69 of 77 patients (90 %), but no genotype–phenotype correlation was observed. Our data using a larger patient cohort did not confirm the previously reported clustering of mutations in the 5′ region of the NF1 gene in patients with OPG. Thus, NF1 mutation location should not currently be used as a clinical criterion to assess the risk of developing OPGs.     

Evidence of statistical epistasis between DISC1, CIT and NDEL1 impacting risk for schizophrenia: biological validation with functional neuroimaging

The etiology of schizophrenia likely involves genetic interactions. DISC1, a promising candidate susceptibility gene, encodes a protein which interacts with many other proteins, including CIT, NDEL1, NDE1, FEZ1 and PAFAH1B1, some of which also have been associated with psychosis. We tested for epistasis between these genes in a schizophrenia case–control study using machine learning algorithms (MLAs: random forest, generalized boosted regression and Monte Carlo logic regression). Convergence of MLAs revealed a subset of seven SNPs that were subjected to 2-SNP interaction modeling using likelihood ratio tests for nested unconditional logistic regression models. Of the ⁷C₂ = 21 interactions, four were significant at the α = 0.05 level: DISC1 rs1411771–CIT rs10744743 OR = 3.07 (1.37, 6.98) p = 0.007; CIT rs3847960–CIT rs203332 OR = 2.90 (1.45, 5.79) p = 0.003; CIT rs3847960–CIT rs440299 OR = 2.16 (1.04, 4.46) p = 0.038; one survived Bonferroni correction (NDEL1 rs4791707–CIT rs10744743 OR = 4.44 (2.22, 8.88) p = 0.00013). Three of four interactions were validated via functional magnetic resonance imaging (fMRI) in an independent sample of healthy controls; risk associated alleles at both SNPs predicted prefrontal cortical inefficiency during the N-back task, a schizophrenia-linked intermediate biological phenotype: rs3847960–rs440299; rs1411771–rs10744743, rs4791707–rs10744743 (SPM5 p < 0.05, corrected), although we were unable to statistically replicate the interactions in other clinical samples. Interestingly, the CIT SNPs are proximal to exons that encode the DISC1 interaction domain. In addition, the 3′ UTR DISC1 rs1411771 is predicted to be an exonic splicing enhancer and the NDEL1 SNP is ~3,000 bp from the exon encoding the region of NDEL1 that interacts with the DISC1 protein, giving a plausible biological basis for epistasis signals validated by fMRI.     

Gross deletions/duplications in <Emphasis Type="Italic">PROS1</Emphasis> are relatively common in point mutation-negative hereditary protein S deficiency

Hereditary protein S (PS) deficiency is an autosomal disorder caused by mutations in the PS gene (PROS1). Conventional PCR-based mutation detection identifies PROS1 point mutations in approximately 50% of the cases. To verify if gross copy number variations (CNVs) are often present in point mutation-negative hereditary PS deficiency we used multiplex ligation-dependent probe amplification (MLPA) as a detection tool in samples from individuals with a high probability of having true PS deficiency. To this end, DNA samples from nine PS deficient probands with family members (seven type I and two type III) and nine isolated probands (three type I and six type III), in whom PROS1 mutations were not found by DNA sequencing, were evaluated. An independent quantitative PCR (qPCR) was performed to confirm the findings of the MLPA assay. Family members were also tested when DNA was available. Gross abnormalities of PROS1 were found in six out of eighteen probands. In three probands complete deletion of the gene was detected. Two probands had a partial deletion involving different parts of the gene (one from exon 4 through 9 and another from exon 9 through 11). One family showed a duplication of part of PROS1. qPCR analysis was in accordance with these results. In conclusion, this study substantiates that gross gene abnormalities in PROS1 are relatively common in hereditary PS deficient patients and that MLPA is a useful tool for direct screening of CNVs in PROS1 point mutation-negative individuals.     

A genetic and functional analysis of the unusually large variable region in the M·Alu I DNA-(cytosine C5 )-methyltransferase

The M·AluI DNA-(cytosine C5)-methyltransferase (5mC methylase) acts on the sequence 5′-AGCT-3′. The amino acid sequences of known 5mC methylases contain ten conserved motifs, with a variable region between Motifs VIII and IX that contains one or more “target-recognizing domains” (TRDs) responsible for DNA sequence specificity. Monospecific 5mC methylases are believed to have only one TRD, while multispecific 5mC methylases have as many as five. M·AluI has the second-largest variable region of all known 5mC methylases, and sequence analysis reveals five candidate TRDs. In testing whether M·AluI is in fact monospecific it was found that AGCT methylation represents only 80–90% of the methylating activity of this enzyme, while control experiments with the enzyme M·HhaI gave no unexplained activity. Because individual TRDs can be deleted from multispecific methylases without general loss of activity, a series of insertion and deletion mutants of the M·AluI variable region were prepared. All deletions that removed more than single amino acids from the variable region caused significant loss of activity; a sensitive in vivo assay for methylase activity based on McrBC restriction suggested that the central portion of the variable region is particularly important. In some cases, multispecific methylases can accommodate a TRD from another multispecific methylase, thereby acquiring an additional specificity. When TRDs were moved from a multispecific methylase into two different locations in the variable region of M·AluI, all hybrid enzymes had greatly reduced activity and no new specificities. M·AluI thus behaves in most respects as a monospecific methylase despite the remarkable size of its variable region.     

Intragenic deletion patterns of dystrophin gene in Duchenne and Becker muscular dystrophy patients from Algeria

Duchenne and Becker muscular dystrophies (DMD and BMD) represent the most frequent neuromuscular diseases in humans (1/3,500–6,000 live male births), characterized by an X-linked recessive pattern of inheritance and therefore affecting mainly male individuals. DMD and BMD are allelic disorders resulting from genetic defects, mostly intragenic deletions, in the dystrophin gene. Using multiplex polymerase chain reaction (PCR), we have analyzed 170 male patients from unrelated families originating from Algeria, showing that 68 % of them harbored deletion events affecting the known 5′ or 3′ hot spot regions. The distal portion was predominantly involved (85 %), whereas 37 distinctive patterns of deletion were identified in our panel. The extent of deletion varied from 1 to 32 exons, although the average number was about four exons. The lack of seven exons (45, 46, 47, 48, 50, 51 and 52), each alone or in combination, represented about 78 % of the alterations encountered, while exon 48 was most frequently involved (50 %). The effect of the deletions showed that the reading frame rule proved mostly true, correlating with the clinical diagnosis suggested. Moreover, the c.525delT mutation in the γ-sarcoglycan gene was present in non-deleted patients (7 %), suggesting that clinical features can still be misleading. Finally, multiplex PCR proved to be a simple, fast and low-cost approach for the molecular diagnosis of dystrophinopathies in Algeria, whereas our data could contribute to the creation of a national registry of DMD/BMD patients in our country, which would give them hope to an access to already available genotype-based therapies.     

Alpha 1-antitrypsin Null(isola di procida): an alpha 1-antitrypsin deficiency allele caused by deletion of all alpha 1-antitrypsin coding exons.

alpha 1-Antitrypsin (alpha 1AT) deficiency, a common hereditary disorder responsible for emphysema in Caucasians of northern European descent, is caused by single base substitutions, deletions, or additions in the seven exons (IA-IC and II-V), of the 12.2-kb alpha 1AT gene located on chromosome 14 at q31-32.3. Of the five known representatives of the "null" group of alpha 1AT-deficiency alleles (alpha 1AT genes incapable of producing alpha 1AT protein detectable in serum) evaluated at the gene level, all result from mutations causing the formation of stop codons in coding exons of the alpha 1AT gene. The present study identifies an alpha 1AT allele (referred to as "Null(isola di procida")) caused by complete deletion of the alpha 1AT coding exons. The Null(isola di procida) allele was identified in an individual with heterozygous inheritance of M(procida) (an allele associated with alpha 1AT deficiency) and a null allele. Although results of karyotypic analysis were normal, quantification of the copies of alpha 1AT genes in this individual revealed that the index case had only half the normal copies of alpha 1AT genes. Cloning and mapping of the Null(isola di procida) gene demonstrated a deletion of a 17-kb fragment that included exons II-V of the alpha 1AT structural gene. As a consequence of the deletion, the normal noncoding exons (IA-IC) were followed by exons II-V of the downstream alpha 1AT-like gene. Sequence analysis of the deletion demonstrated a 7-bp repeat sequence (GAGGACA) both 5' to the deletion and at the 3' end of the deletion, a 4-bp palindromic sequence (ACAG vs. CTGT) bracketing the deletion, and a novel inserted 4-bp sequence (CCTG) at the breakpoint, suggesting that the mechanism of the deletion may have been "slipped mispairing."     

A novel 18-bp deletion mutation of the AMPD1 gene affects carcass traits in Qinchuan cattle

The objectives of the present study were focused on detecting deletion mutation in bovine AMPD1 gene, and analyzing its effect on body measurement and carcass traits in Qinchuan cattle by using DNA sequencing and agarose electrophoresis methods. The 198-bp PCR products of AMPD1 gene exhibited three genotypes and two alleles were revealed: A and B. The frequencies of genotype AA/AB/BB in Qinchuan populations was 0.7163, 0.2233 and 0.0605. The χ²-test analysis demonstrated that the breed was not in agreement with Hardy–Weinberg equilibrium (P < 0.05). The association of the 18-bp deletion mutation of AMPD1 gene with body measurement and carcass traits of Qinchuan cattle were analyzed. The cattle with AA genotype had slaughter weight and carcass weight than those with genotype AB (P < 0.01 or P < 0.05). These results suggest that the 18-bp deletion mutation may influence the carcass traits in Qinchuan cattle.     

Gas chromatography–mass spectrometry analysis of fatty acid profiles of Antarctic and non-Antarctic yeasts

The fatty acid profiles of Antarctic (n = 7) and non-Antarctic yeasts (n = 7) grown at different temperatures were analysed by gas chromatography–mass spectrometry. The Antarctic yeasts were enriched in oleic 18:1 (20–60 %), linoleic 18:2 (20–50 %) and linolenic 18:3 (5–40 %) acids with lesser amounts of palmitic 16:0 (<15 %) and palmitoleic 16:1 (<10 %) acids. The non-Antarctic yeasts (n = 4) were enriched in 18:1 (20–55 %, with R. mucilaginosa at 75–80 %) and 18:2 (10–40 %) with lesser amounts of 16:0 (<20 %), 16:1 (<20 %) and stearic 18:0 (<10 %) acids. By contrast, Saccharomyces cerevisiae strains (n = 3) were enriched in 16:1 (30–50 %) and 18:1 (20–40 %) with lesser amounts of 16:0 (10–25 %) and 18:0 (5–10 %) acids. Principal component analysis grouped the yeasts into three clusters, one belonging to the S. cerevisiae strains (enriched in 16:0, 16:1 and 18:1), one to the other non-Antarctic yeasts (enriched in 18:1 and 18:2) and the third to the Antarctic yeasts (enriched in 18:2 and 18:3).