Single, short in-del, and copy number variations detection in monogenic dyslipidemia using a next-generation sequencing strategy.

Optimal molecular diagnosis of primary dyslipidemia is challenging to confirm the diagnosis, test and identify at risk relatives. The aim of this study was to test the application of a single targeted next-generation sequencing (NGS) panel for hypercholesterolemia, hypocholesterolemia, and hypertriglyceridemia molecular diagnosis. NGS workflow based on a custom AmpliSeq panel was designed for sequencing the most prevalent dyslipidemia-causing genes (ANGPTL3, APOA5, APOC2, APOB, GPIHBP1, LDLR, LMF1, LPL, PCSK9) on the Ion PGM Sequencer. One hundred and forty patients without molecular diagnosis were studied. In silico analyses were performed using the NextGENe software and homemade tools for detection of copy number variations (CNV). All mutations were confirmed using appropriate tools. Eighty seven variations and 4 CNV were identified, allowing a molecular diagnosis for 40/116 hypercholesterolemic patients, 5/13 hypocholesterolemic patients, and 2/11, hypertriglyceridemic patients respectively. This workflow allowed the detection of CNV contrary to our previous strategy. Some variations were found in previously unexplored regions providing an added value for genotype-phenotype correlation and familial screening. In conclusion, this new NGS process is an effective mutation detection method and allows better understanding of phenotype. Consequently this assay meets the medical need for individualized diagnosis of dyslipidemia.

Identification and characterization of three large deletions and a deletion/polymorphism in the CFTR gene.

Cystic fibrosis (CF) is mainly caused by small molecular lesions of the CFTR gene; mutation detection methods based on conventional PCR do not allow the identification of all CF alleles in a population and large deletions may account for a number of these unidentified molecular lesions. It is only recently that the availability of quantitative PCR methodologies made the search for large gene rearrangements easier in autosomal diseases. Using a combination of different methods, nine of the 37 unidentified CF alleles (24%) were found to harbor large deletions in our cohort of 1600 CF alleles. Three are new deletions, and we report the breakpoints of the previously described EX4_EX10del40kb deletion. An intronic deletion polymorphism affecting intron 17b was also found on almost 1% of "normal" chromosomes. Examination of the breakpoint sequences confirmed that intron 17b is indeed a hot spot for deletions, and that most of these rearrangements are caused by non-homologous recombination.

Mucopolysaccharidosis type II--genotype/phenotype aspects.

UNLABELLED: Establishing correlations between a patient's genotype and clinical phenotype is based on the assumption that the same clinical consequences will be observed in individuals with the same residual function of a specific metabolic step. In mucopolysaccharidosis type II (MPS II; Hunter disease), patients present with a wide clinical spectrum. Furthermore, current methods for measuring the activity of the deficient enzyme in MPS II--iduronate-2-sulphatase (IDS)--are insufficiently sensitive to differentiate between complete absence of activity and the presence of residual activity. Attempts have therefore been made to establish genotype-phenotype correlations in order to explain the large degree of heterogeneity and to serve as a better guide to prognosis on which to base genetic counselling and treatment options. Using MPS II as an example, this paper illustrates the difficulties and potential advantages of determining genotype-phenotype correlations in lysosomal storage diseases. The response of patients with MPS II to allogenic bone marrow transplantation provides some insight into the likely influence of certain genotypes on therapeutic efficacy. CONCLUSIONS: Evaluation of residual activity of IDS in MPS II using gene analysis, expression studies and transcript analysis does not always allow prediction of a patient's phenotype. The variable response to bone marrow transplantation, however, illustrates the potential importance of determining the genotype for selecting the most appropriate therapy for individual patients.

Spectrum of CFTR mutations in cystic fibrosis and in congenital absence of the vas deferens in France.

We have collated the results of cystic fibrosis (CF) mutation analysis conducted in 19 laboratories in France. We have analyzed 7, 420 CF alleles, demonstrating a total of 310 different mutations including 24 not reported previously, accounting for 93.56% of CF genes. The most common were F508del (67.18%; range 61-80), G542X (2.86%; range 1-6.7%), N1303K (2.10%; range 0.75-4.6%), and 1717-1G>A (1.31%; range 0-2.8%). Only 11 mutations had relative frequencies >0. 4%, 140 mutations were found on a small number of CF alleles (from 29 to two), and 154 were unique. These data show a clear geographical and/or ethnic variation in the distribution of the most common CF mutations. This spectrum of CF mutations, the largest ever reported in one country, has generated 481 different genotypes. We also investigated a cohort of 800 French men with congenital bilateral absence of the vas deferens (CBAVD) and identified a total of 137 different CFTR mutations. Screening for the most common CF defects in addition to assessment for IVS8-5T allowed us to detect two mutations in 47.63% and one in 24.63% of CBAVD patients. In a subset of 327 CBAVD men who were more extensively investigated through the scanning of coding/flanking sequences, 516 of 654 (78. 90%) alleles were identified, with 15.90% and 70.95% of patients carrying one or two mutations, respectively, and only 13.15% without any detectable CFTR abnormality. The distribution of genotypes, classified according to the expected effect of their mutations on CFTR protein, clearly differed between both populations. CF patients had two severe mutations (87.77%) or one severe and one mild/variable mutation (11.33%), whereas CBAVD men had either a severe and a mild/variable (87.89%) or two mild/variable (11.57%) mutations.

Identification of 5 novel mutations in the AGXT gene.

In order to identify additional genotypes in primary hyperoxaluria type 1, we sequenced the AGXT genes of 9 patients. We report 5 new mutations. Three are splice-site mutations situated at the end of intron 4 and 8 (647-1G>A, 969-1G>C, 969-3C>G), one is a missense mutation in exon 5 (D183N), and one is a short duplication in exon 2 (349ins7). Their consequence is always a lack of enzymatic activity of the Alanine-Glyoxylate Aminotransferase (AGT); for 4 of them, we were able to deduce that they were associated to the absence of AGT protein. These mutations are rare, as they have been found on one allele in our study (except 969-3C>G present in 2 unrelated families), and have not been previously reported.

Creatine kinase isoenzymes specificities: histidine 65 in human CK-BB, a role in protein stability, not in catalysis.

Creatine kinases (CK) play a prominent role in cell energy distribution through an energy shuttle between mitochondria and other organelles. Human brain CK was cloned and overexpressed in COS-7 cells. We then deleted His-65 and/or Pro-66 situated near the center of a flexible loop as shown by X-ray crystallography on mitochondrial and cytosolic CK. The DeltaH65 mutant had nearly the same affinity for its substrates as wild isoenzyme, but its stability was very low. Unlike DeltaH65, DeltaH65P66 had a eightfold decreased affinity for creatine phosphate and was unable to dephosphorylate cyclocreatine phosphate. Our results demonstrate that, despite an overall similar shape of the proteins, this loop accounts for some subtle differences in isoenzyme functions.

Partial deletion of the AGXT gene (EX1_EX7del): A new genotype in hyperoxaluria type 1.

Primary hyperoxaluria type 1 (PH1) is a rare autosomal (2q37.3) recessive metabolic disease caused by a deficiency of the hepatic peroxisomal enzyme alanine:glyoxylate amino transferase. Molecular heterogeneity is important in PH1 as most of the patients (if the parents are unrelated) are compound heterozygotes for rare mutations. We describe the first large deletion in the AGXT gene, removing exons 1 to 7 (EX1_EX7del) that was responsible for one case of severe PH1. This 10 kb deletion was identified by Southern blotting of genomic DNA digested by Xba I and hybridized with different exonic probes. Both parents (from Turkey) are first cousin and carry the deletion. It is of note that the presently reported patient did not exhibit any AGT catalytic activity and even so, he progressed towards end-stage renal disease only at 19 years old.

Combined liver-kidney transplantation in primary hyperoxaluria type 1.

Primary hyperoxaluria type 1 (PH1) is a rare autosomal recessive disorder characterised by an increased urinary excretion of calcium oxalate, leading to recurrent urolithiasis, nephrocalcinosis and accumulation of insoluble oxalate throughout the body (oxalosis) when the glomerular filtration rate falls to below 40-20 mL/min per 1.73 m(2). The disease is due to a functional defect of the liver-specific peroxisomal enzyme alanine: glyoxylate aminotransferase (AGT), the gene of which is located on chromosome 2q37.3. The diagnosis is based on increased urinary oxalate and glycollate, increased plasma oxalate and AGT measurement in a liver biopsy. AGT mistargeting may be investigated by immuno-electron microscopy and DNA analysis. End-stage renal failure is reached by the age of 15 years in 50% of PH1 patients and the overall death rate approximates 30%. The conservative treatment includes high fluid intake, pyridoxine and crystallisation inhibitors. Since the kidney is the main target of the disease, isolated kidney transplantation (Tx) has been proposed in association with vigorous peri-operative haemodialysis in an attempt to clear plasma oxalate at the time of Tx. However, because of a 100% recurrence rate, the average 3-year graft survival is 15%-25% in Europe, with a 5-10-year patient survival rate ranging from 10% to 50%. Since the liver is the only organ responsible for the detoxification of glyoxylate by AGT, deficient host liver removal is the first rationale for enzyme replacement therapy. Subsequent orthotopic liver Tx aims to supply the missing enzyme in its normal cellular and subcellular location and thus can be regarded as a form of gene therapy. Because of the usual spectrum of the disease, isolated liver Tx is limited to selected patients prior to having reached an advanced stage of chronic renal failure. Combined liver-kidney Tx has therefore become a conventional treatment for most PH1 patients: according to the European experience, patient survival approximates 80% at 5 years and 70% at 10 years. In addition, the renal function of survivors remains stable over time, between 40 and 60 mL/min per 1.73 m(2) after 5 to 10 years. In addition, liver Tx may allow the reversal of systemic storage disease (i.e. bone, heart, vessels, nerves) and provide valuable quality of life. Whatever the transplant strategy, the outcome is improved when patients are transplanted early in order to limit systemic oxalosis. According to the European experience, it appears that combined liver-kidney Tx is performed in PH1 patients with encouraging results, renal Tx alone has little role in the treatment of this disease, and liver Tx reverses the underlying metabolic defect and its clinical consequences.

The 2.1-, 5.4- and 5.7-kb transcripts of the IDS gene are generated by different polyadenylation signals.

Deficiency of the lysosomal enzyme iduronate-2-sulfatase (IDS) is responsible for mucopolysaccharidosis type II (OMIM 309900). The IDS gene (Xq28) has been completely sequenced (accession number L35485). Northern blot analysis of poly(A(+)) RNA from different tissues, hybridized with the total IDS cDNA, has revealed three major species of 2.1, 5.4 and 5.7 kb and one minor of 1.4 kb. The 1.4-kb mRNA has been previously described and we show that the three major IDS mRNA are the result of alternative polyadenylation site selection: a non-canonical ATTAAA signal at genomic position 23631 for the 2.1-kb mRNA, a AATAAA signal at position 27156 for the 5.4-kb mRNA and a AATAAA signal at position 27399 for the 5.7-kb mRNA. The different IDS mRNA encode for the same polypeptide and the most abundant transcripts have a long 3'-untranslated region (3'-UTR). The absence of obvious correlation between transcripts content and size, IDS protein amount and IDS activity in the four human fetal tissues tested suggests that it is IDS protein processing that may be regulated rather than IDS gene transcription.

Complex allele [-102T>A+S549R(T>G)] is associated with milder forms of cystic fibrosis than allele S549R(T>G) alone.

We recently reported a novel complex allele in the cystic fibrosis transmembrane regulator (CFTR) gene, combining a sequence change in the minimal CFTR promoter (-102T>A) and a missense mutation in exon 11 [S549R(T>G)]. Here we compare the main clinical features of six patients with cystic fibrosis (CF) carrying the complex allele [-102T>A+S549R(T>G)] with those of 16 CF patients homozygous for mutation S549R(T>G) alone. Age at diagnosis was higher, and current age was significantly higher (P=0.0032) in the group with the complex allele, compared with the S549R/S549R group. Although the proportion of patients with lung colonization was similar in both groups, the age at onset was significantly higher in the group with the complex allele (P=0.0022). Patients with the complex allele also had significantly lower sweat test chloride values (P=0.0028) and better overall clinical scores (P=0.004). None of the 22 patients reported in this study had meconium ileus. All 16 patients homozygous for S549R(T>G), however, were pancreatic insufficient, as compared with 50% of patients carrying the complex allele (P=0.013). Moreover, the unique patient homozygous for [-102T>A+S549R(T>G)] presented with a mild disease at 34 years of age. These observations strongly suggest that the sequence change (-102T>A) in the CFTR minimal promoter could attenuate the severe clinical phenotype associated with mutation S549R(T>G).

Identification of iduronate sulfatase gene alterations in 70 unrelated Hunter patients.

We studied 70 unrelated Hunter patients and found a gene alteration in every patient. The molecular heterogeneity was very important. Large gene rearrangements were identified in 14 patients. Forty-three different mutations were identified in the 56 other patients and 31 were not previously described. Deletions and insertions, splice site mutations were associated with a severe phenotype as nonsense mutations except Q531X. Only a few mutations were present in several patients making difficult genotype-phenotype correlations. Mutation identification allows accurate carrier detection improving prenatal diagnosis. The mother was not found to be a carrier in five cases among the 44 sporadic cases. Haplotype analysis demonstrated a higher frequency of mutations in male meiosis.

COS cell expression studies of P86L, P86R, P480L and P480Q Hunter's disease-causing mutations.

Three missense mutations identified in the IDS gene of our Hunter's disease patients (P86L, P480L and P480Q) and the previously described P86R mutation were expressed in COS cells to evaluate their functional consequence on iduronate-2-sulfatase (IDS) activity and processing. The 86-proline residue belongs to the highly conserved pentapeptide C-X-P-S-R in which cysteine modification to a formylglycine is required for sulfatase activity. The substitution of the 86-proline residue led to a severe mutation as no mature form was targeted to the lysosome in agreement with the severe phenotype observed in patients carrying P86L and P86R mutations. Expression studies with P480L and P480Q mutant cDNAs showed the presence of a small amount of 55 kDa mature form in the lysosomes of transfected COS cells. IDS activity of the P480L and P480Q mutants in cell extracts represents 16.6% and 5.4% of the wild-type, respectively.

Characterization of iduronate sulphatase mutants affecting N-glycosylation sites and the cysteine-84 residue.

Iduronate sulphatase (IDS) is responsible for mucopolysaccharidosis type II, a rare recessive X-linked lysosomal storage disease. The aim of this work was to evaluate the functional importance of each N-glycosylation site, and of the cysteine-84 residue. IDS mutant cDNAs, lacking one of the eight potential N-glycosylation sites, were expressed in COS cells. Although each of the potential sites was used, none of the eight glycosylation sites appeared to be essential for lysosomal targeting. Another important sulphatase co- or post-translational modification for generating catalytic activity involves the conversion of a cysteine residue surrounded by a conserved sequence C-X-P-S-R into a 2-amino-3-oxopropionic acid residue [Schmidt, Selmer, Ingendoh and von Figura (1995) Cell 82, 271-278]. This conserved cysteine, located at amino acid position 84 in IDS, was replaced either by an alanine (C84A) or by a threonine (C84T) using site-directed mutagenesis. C84A and C84T mutant cDNAs were expressed either in COS cells or in human lymphoblastoid cells deleted for the IDS gene. C84A had a drastic effect both for IDS processing and for catalytic activity. The C84T mutation produced a small amount of mature forms but also abolished enzyme activity, confirming that the cysteine residue at position 84 is required for IDS activity.

Germline and somatic mosaicism in a female carrier of Hunter disease.

Carrier detection in a mucopolysaccharidosis type II family (Hunter disease) allowed the identification of germline and somatic mosaicism in the patient's mother: the R443X mutation was found in a varying proportion in tested tissue (7% in leucocytes, lymphocytes, and lymphoblastoid cells, and 22% in fibroblasts). The proband's sister carries the at risk allele (determined by haplotype analysis), but not the mutation. In sporadic cases of X linked diseases, germline mosaicism of the proband's mother is difficult to exclude and should be considered in genetic counselling.

IDS transfer from overexpressing cells to IDS-deficient cells.

Iduronate sulfatase (IDS) is responsible for mucopolysaccharidosis type II, a rare recessive X-linked lysosomal storage disease. The aim of this work was to test the ability of overexpressing cells to transfer IDS to deficient cells. In the first part of our work, IDS processing steps were compared in fibroblasts, COS cells, and lymphoblastoid cell lines and shown to be identical: the two precursor forms (76 and 90 kDa) were processed by a series of intermediate forms to the 55- and 45-kDa mature polypeptides. Then IDS transfer to IDS-deficient cells was tested either by incubation with cell-free medium of overexpressing cells or by coculture. Endocytosis and coculture experiments between transfected L beta and deleted fibroblasts showed that IDS transfer occurred preferentially by cell-to-cell contact as IDS precursors are poorly secreted by transfected L beta. The 76- and 62-kDa IDS polypeptides transferred to deleted fibroblasts were correctly processed to the mature 55- and 45-kDa forms. L beta were not able to internalize the 90-kDa phosphorylated precursor forms excreted in large amounts in the medium of overexpressing fibroblasts. Enzyme transfer occurred only by cell-to-cell contact, but the precursor forms transferred in L beta after cell-to-cell contact were not processed. This absence of maturation was probably due to a mistargeting of IDS precursors in these cells.

A novel gly290asp mitochondrial cytochrome b mutation linked to a complex III deficiency in progressive exercise intolerance.

We have identified a new mitochondrial (mt) cytochrome b mutation in a 29-year-old man with progressive exercise muscle intolerance associated with a marked deficiency of complex III activity and a decreased amount of mitochondrial-encoded cytochrome b. This G to A transition at mtDNA position 15615 leads to the substitution (G290D) of a very highly conserved amino acid of cytochrome b during evolution. The mutant mtDNA was heteroplasmic (80% mutant) in patient muscle but was undetectable in blood from the patient and his healthy mother and sisters. A maternally inherited cytochrome b polymorphism was also identified in this patient. Molecular screening of 150 individuals showed that the G290D mutation associated with the described phenotype. We suggest that this molecular defect is the primary cause of the muscle disease in this patient.