Telomere shortening by mutations in the RTEL1 helicase cause severe form of dyskeratosis congenita,Hoyerall‐Hreidarsson syndrome

Germline mutations of regulator of telomere elongation helicase 1, RTEL1, in Dyskeratosis congenital Ballew et al. (2013) Journal of Human Genetics 132: 473–480. Constitutional mutations in RTEL1 cause severe dyskeratosis congenita Walne et al. (2013) American Journal of Human Genetics 92 (3): 448–453.     

Carrier screening of RTEL1 mutations in the Ashkenazi Jewish population

Hoyeraal–Hreidarsson syndrome (HH) is a clinically severe variant of dyskeratosis congenita (DC), characterized by cerebellar hypoplasia, microcephaly, intrauterine growth retardation, and severe immunodeficiency in addition to features of DC. Germline mutations in the RTEL1 gene have recently been identified as causative of HH. In this study, the carrier frequency for five RTEL1 mutations that occurred in individuals of Ashkenazi Jewish descent was investigated in order to advise on including them in existing clinical mutation panels for this population. Our screening showed that the carrier frequency for c.3791G>A (p.R1264H) was higher than expected, 1% in the Ashkenazi Orthodox and 0.45% in the general Ashkenazi Jewish population. Haplotype analyses suggested the presence of a common founder. We recommend that the c.3791G>A RTEL1 mutation be considered for inclusion in carrier screening panels in the Ashkenazi population.     

The association of telomere length and genetic variation in telomere biology genesa

Telomeres cap chromosome ends and are critical for genomic stability. Many telomere‐associated proteins are important for telomere length maintenance. Recent genome‐wide association studies (GWAS) have identified single nucleotide polymorphisms (SNPs) in genes encoding telomere‐associated proteins (RTEL1 and TERT‐CLPTM1) as markers of cancer risk. We conducted an association study of telomere length and 743 SNPs in 43 telomere biology genes. Telomere length in peripheral blood DNA was determined by Q‐PCR in 3,646 participants from the Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial and Nurses' Health Study. We investigated associations by SNP, gene, and pathway (functional group). We found no associations between telomere length and SNPs in TERT‐CLPTM1L or RTEL1. Telomere length was not significantly associated with specific functional groups. Thirteen SNPs from four genes (MEN1, MRE11A, RECQL5, and TNKS) were significantly associated with telomere length. The strongest findings were in MEN1 (gene‐based P=0.006), menin, which associates with the telomerase promoter and may negatively regulate telomerase. This large association study did not find strong associations with telomere length. The combination of limited diversity and evolutionary conservation suggest that these genes may be under selective pressure. More work is needed to explore the role of genetic variants in telomere length regulation. Hum Mutat 31:1050–1058, 2010. Published 2010 Wiley‐Liss, Inc.     

Rothmund‐Thomson syndrome due to RECQ4 helicase mutations: Report and clinical and molecular comparisons with Bloom syndrome and Werner syndrome

Rothmund‐Thomson syndrome (RTS), an autosomal recessive disorder, comprises poikiloderma, growth deficiency, some aspects of premature aging, and a predisposition to malignancy, especially osteogenic sarcomas. Two kindreds with RTS were recently shown to segregate for mutations in the human RECQL4 helicase gene. We report identification of a new RTS kindred in which both brothers developed osteosarcomas. Mutation analysis of the RECQL4 gene was performed on both brothers and both parents. The brothers were shown to be compound heterozygotes for mutations in the RECQL4 gene, including a single base‐pair deletion in exon 9 resulting in a frameshift and early termination codon and a base substitution in the 3‐prime splice site in the intron‐exon boundary of exon 8, which would be predicted to cause a deletion of at least part of a consensus helicase domain. Each parent was shown to be a heterozygote carrier for one mutation. This report strengthens the association between mutations in RECQL4 helicase gene and RTS. Two other recessive disorders, Bloom syndrome and Werner syndrome, are known to be due to other human RECQ helicase gene mutations. These three disorders all manifest abnormal growth, premature aging, and predisposition to site‐specific malignancies. The clinical and molecular aspects of RTS, Bloom syndrome, and Werner syndrome are compared and contrasted. Am. J. Med. Genet. 90:223–228, 2000. © 2000 Wiley‐Liss, Inc.     

From Whole Gene Deletion to Point Mutations of EP300‐Positive Rubinstein–Taybi Patients: New Insights into the Mutational Spectrum and Peculiar Clinical Hallmarks

Rubinstein–Taybi syndrome (RSTS) is a rare congenital neurodevelopmental disorder characterized by growth deficiency, skeletal abnormalities, dysmorphic features, and intellectual disability. Causative mutations in CREBBP and EP300 genes have been identified in ～55% and ～8% of affected individuals. To date, only 28 EP300 alterations in 29 RSTS clinically described patients have been reported. EP300 analysis of 22 CREBBP‐negative RSTS patients from our cohort led us to identify six novel mutations: a 376‐kb deletion depleting EP300 gene; an exons 17–19 deletion (c.(3141+1_3142‐1)_(3590+1_3591‐1)del/p.(Ile1047Serfs*30)); two stop mutations, (c.3829A>T/p.(Lys1277*) and c.4585C>T/p.(Arg1529*)); a splicing mutation (c.1878‐12A>G/p.(Ala627Glnfs*11)), and a duplication (c.4640dupA/p.(Asn1547Lysfs*3)). All EP300‐mutated individuals show a mild RSTS phenotype and peculiar findings including maternal gestosis, skin manifestation, especially nevi or keloids, back malformations, and a behavior predisposing to anxiety. Furthermore, the patient carrying the complete EP300 deletion does not show a markedly severe clinical picture, even if a more composite phenotype was noticed. By characterizing six novel EP300‐mutated patients, this study provides further insights into the EP300‐specific clinical presentation and expands the mutational repertoire including the first case of a whole gene deletion. These new data will enhance EP300‐mutated cases identification highlighting distinctive features and will improve the clinical practice allowing a better genotype–phenotype correlation.     

Fifteen novel mutations in PKLR associated with pyruvate kinase (PK) deficiency: Structural implications of amino acid substitutions in PK

Pyruvate kinase (PK) deficiency is a rare disease but an important cause of hereditary nonspherocytic hemolytic anemia. The disease is caused by mutations in the PKLR gene and shows a marked variability in clinical expression. We report on the molecular characterization of 38 PK‐deficient patients from 35 unrelated families. Twenty‐nine different PKLR mutations were detected, of which 15 are reported here for the first time. Two novel deletions are reported: c.142_159del18 is the largest in‐frame deletion described thus far and predicts the loss of six consecutive amino acids (p.Thr48_Thr53del) in the N‐terminal domain of red blood cell PK. The other deletion removes nearly 1.5 kb of genomic DNA sequence (c.1618+37_2064del1477) and is one of a few large deletional mutants in PKLR. In addition, 13 novel point mutations were identified: one nonsense mutant, p.Arg488X, and 12 missense mutations, predicting the substitution of a single amino acid: p.Arg40Trp, p.Leu73Pro, p.Ile90Asn, p.Gly111Arg, p.Ala154Thr, p.Arg163Leu, p.Gly165Val, p.Leu272Val, p.Ile310Asn, p.Val320Leu, p.Gly358Glu, and p.Leu374Pro. We used the three‐dimensional (3D) structure of recombinant human tetrameric PK to evaluate the protein structural context of the affected residues. In addition, in selected patients red blood cell PK antigen levels were measured by enzyme‐linked immunosorbent assay (ELISA). Collectively, the results provided us with a rationale for the observed enzyme deficiency and contribute to both a better understanding of the genotype‐to‐phenotype correlation in PK deficiency as well as the enzyme's structure and function. Hum Mutat 0, 1–8, 2008. © 2008 Wiley‐Liss, Inc.     

Novel LMNA mutations in patients with Emery‐Dreifuss muscular dystrophy and functional characterization of four LMNA mutations

Mutations in LMNA cause a variety of diseases affecting striated muscle including autosomal Emery‐Dreifuss muscular dystrophy (EDMD), LMNA‐associated congenital muscular dystrophy (L‐CMD), and limb‐girdle muscular dystrophy type 1B (LGMD1B). Here, we describe novel and recurrent LMNA mutations identified in 50 patients from the United States and Canada, which is the first report of the distribution of LMNA mutations from a large cohort outside Europe. This augments the number of LMNA mutations known to cause EDMD by 16.5%, equating to an increase of 5.9% in the total known LMNA mutations. Eight patients presented with either p.R249W/Q or p.E358K mutations and an early onset EDMD phenotype: two mutations recently associated with L‐CMD. Importantly, 15 mutations are novel and include eight missense mutations (p.R189P, p.F206L, p.S268P, p.S295P, p.E361K, p.G449D, p.L454P, and p.W467R), three splice site mutations (c.IVS4 + 1G>A, c.IVS6 ? 2A>G, and c.IVS8 + 1G>A), one duplication/in frame insertion (p.R190dup), one deletion (p.Q355del), and two silent mutations (p.R119R and p.K270K). Analysis of 4 of our lamin A mutations showed that some caused nuclear deformations and lamin B redistribution in a mutation specific manner. Together, this study significantly augments the number of EDMD patients on the database and describes 15 novel mutations that underlie EDMD, which will contribute to establishing genotype–phenotype correlations. Hum Mutat 31:–16, 2011. © 2011 Wiley‐Liss, Inc.     

Hoyeraal-Hreidarsson syndrome caused by a germline mutation in the TEL patch of the telomere protein TPP1

Germline mutations in telomere biology genes cause dyskeratosis congenita (DC), an inherited bone marrow failure and cancer predisposition syndrome. DC is a clinically heterogeneous disorder diagnosed by the triad of dysplastic nails, abnormal skin pigmentation, and oral leukoplakia; Hoyeraal-Hreidarsson syndrome (HH), a clinically severe variant of DC, also includes cerebellar hypoplasia, immunodeficiency, and intrauterine growth retardation. Approximately 70% of DC cases are associated with a germline mutation in one of nine genes, the products of which are all involved in telomere biology. Using exome sequencing, we identified mutations in Adrenocortical Dysplasia Homolog (ACD) (encoding TPP1), a component of the telomeric shelterin complex, in one family affected by HH. The proband inherited a deletion from his father and a missense mutation from his mother, resulting in extremely short telomeres and a severe clinical phenotype. Characterization of the mutations revealed that the single-amino-acid deletion affecting the TEL patch surface of the TPP1 protein significantly compromises both telomerase recruitment and processivity, while the missense mutation in the TIN2-binding region of TPP1 is not as clearly deleterious to TPP1 function. Our results emphasize the critical roles of the TEL patch in proper stem cell function and demonstrate that TPP1 is the second shelterin component (in addition to TIN2) to be implicated in DC.     

Revealing the functions of novel mutations in RAB3GAP1 in Martsolf and Warburg micro syndromes

Purpose: Martsolf (MS) and Warburg micro syndromes (WARBM) are rare autosomal recessive inherited allelic disorders, which share similar clinical features including microcephaly, intellectual disability, brain malformations, ocular abnormalities, and spasticity. Here, we revealed the functions of novel mutations in RAB3GAP1 in a Turkish female patient with MS and two siblings with WARBM. We also present a review of MS patients as well as all reported RAB3GAP1 pathogenic mutations in the literature. Methods: We present a female with MS phenotype and two siblings with WARBM having more severe phenotypes. We utilized whole‐exome sequencing to identify the molecular basis of these syndromes and confirmed suspected variants by Sanger sequencing. Quantitative (q) RT‐PCR analysis was carried out to reveal the functions of novel splice site mutation detected in MS patient. Results: We found a novel homozygous c.2607‐1G>C splice site mutation in intron 22 of RAB3GAP1 in MS patient and a novel homozygous c.2187_2188delinsCT, p.(Met729_Lys730delinsIleTer) mutation in exon 19 of RAB3GAP1 in the WARBM patients. We showed exon skipping in MS patient by Sanger sequencing and gel electrophoresis. qRT‐PCR analysis demonstrated the reduced expression of RAB3GAP1 in the patient with the c.2607‐1G>C splice site mutation compared to a healthy control individual. Conclusion: Here, we have studied two novel RAB3GAP1 mutations in two different phenotypes; a MS associated novel splice site mutation, and a WARBM1 associated novel deletion–insertion mutation. Our findings suggest that this splice site mutation is responsible for milder phenotype and the deletion–insertion mutation presented here is associated with severe phenotype.     

Telomere Phenotypes in Females with Heterozygous Mutations in the Dyskeratosis Congenita 1 (DKC1) Gene

Dyskeratosis congenita (DC) is a telomere‐mediated syndrome defined by mucocutaneous features. The X‐linked mode of inheritance accounts for half the cases, and is thought to predominantly manifest in childhood as bone marrow failure. We identified two male probands who presented in the fifth decade with idiopathic pulmonary fibrosis and cancer. Their pedigrees displayed consecutively affected generations. Five of six females (83%) manifested mucocutaneous features of DC, and two had wound‐healing complications. No mutations in autosomal dominant telomere genes were present, but exome sequencing revealed novel variants in the X‐chromosome DKC1 gene that predicted missense mutations in conserved residues, p.Thr49Ser and p.Pro409Arg. Variants segregated with the telomere phenotype, and affected females were heterozygotes, showing skewed X‐inactivation. Telomerase RNA levels were compromised in cells from DKC1 mutation carriers, consistent with their pathogenic role. These findings indicate that females with heterozygous DKC1 mutations may be at increased risk for developing penetrant telomere phenotypes that, at times, may be associated with clinical morbidity.     

Identification and characterization of three novel mutations in the CASQ1 gene in four patients with tubular aggregate myopathy

Here, we report the identification of three novel missense mutations in the calsequestrin‐1 (CASQ1) gene in four patients with tubular aggregate myopathy. These CASQ1 mutations affect conserved amino acids in position 44 (p.(Asp44Asn)), 103 (p.(Gly103Asp)), and 385 (p.(Ile385Thr)). Functional studies, based on turbidity and dynamic light scattering measurements at increasing Ca²⁺ concentrations, showed a reduced Ca²⁺‐dependent aggregation for the CASQ1 protein containing p.Asp44Asn and p.Gly103Asp mutations and a slight increase in Ca²⁺‐dependent aggregation for the p.Ile385Thr. Accordingly, limited trypsin proteolysis assay showed that p.Asp44Asn and p.Gly103Asp were more susceptible to trypsin cleavage in the presence of Ca²⁺ in comparison with WT and p.Ile385Thr. Analysis of single muscle fibers of a patient carrying the p.Gly103Asp mutation showed a significant reduction in response to caffeine stimulation, compared with normal control fibers. Expression of CASQ1 mutations in eukaryotic cells revealed a reduced ability of all these CASQ1 mutants to store Ca²⁺ and a reduced inhibitory effect of p.Ile385Thr and p.Asp44Asn on store operated Ca²⁺ entry. These results widen the spectrum of skeletal muscle diseases associated with CASQ1 and indicate that these mutations affect properties critical for correct Ca²⁺ handling in skeletal muscle fibers.     

Development of a new multiplex quantitative real‐time PCR assay for the detection of the mtDNA4977 deletion in coronary artery disease patients: A link with telomere shortening

Mitochondrial DNA (mtDNA) and telomere shortening have been proposed as important contributors to vascular disease and atherogenesis. The role of mitochondrial and telomere alterations has been examined frequently, but usually separately. Recently, an integrated model in which DNA damage and metabolic pathways intersect in age‐associated cardiovascular disease has been proposed. In this study we developed a fast and reliable real‐time PCR‐based procedure to investigate relative quantification of the 4,977 bp mitochondrial DNA deletion (also indicated as “mtDNA⁴⁹⁷⁷ deletion”), employing TaqMan probes with a multiplex approach. As a validation of the assay, a nested PCR coamplification was performed. Telomere shortening was evaluated by a real‐time monochrome multiplex PCR technique employing a SybrGreen‐based analysis. The study of mtDNA⁴⁹⁷⁷ deletion and telomere shortening was carried out in atrial biopsies from 11 patients undergoing coronary artery (n = 5) and valve surgery (n = 6). The relative quantifications showed that the amount of mtDNA⁴⁹⁷⁷ deletion was greater in tissue of patients with coronary artery disease (CAD) (P = 0.01) and that telomere length (expressed as telomere length relative to a single copy reference gene) was significantly shorter in tissue of CAD patients, compared to patients without CAD (P = 0.03). Moreover, most conventional risk factors were significantly more frequent in CAD patients, smoking and dyslipidemia having the strongest association with the degree of mtDNA⁴⁹⁷⁷deletion and a significant correlation with telomere attrition (P = 0.02 and P = 0.006, respectively). In conclusion, the present study suggests that mtDNA⁴⁹⁷⁷ deletion and telomere shortening may represent additional and synergic major risk factors for the pathogenesis of CAD and its complications. Environ. Mol. Mutagen. 54:299–307, 2013. © 2013 Wiley Periodicals, Inc.     

Mutations in RIT1 cause Noonan syndrome – additional functional evidence and expanding the clinical phenotype

RASopathies are a clinically heterogeneous group of conditions caused by mutations in 1 of 16 proteins in the RAS‐mitogen activated protein kinase (RAS‐MAPK) pathway. Recently, mutations in RIT1 were identified as a novel cause for Noonan syndrome. Here we provide additional functional evidence for a causal role of RIT1 mutations and expand the associated phenotypic spectrum. We identified two de novo missense variants p.Met90Ile and p.Ala57Gly. Both variants resulted in increased MEK‐ERK signaling compared to wild‐type, underscoring gain‐of‐function as the primary functional mechanism. Introduction of p.Met90Ile and p.Ala57Gly into zebrafish embryos reproduced not only aspects of the human phenotype but also revealed abnormalities of eye development, emphasizing the importance of RIT1 for spatial and temporal organization of the growing organism. In addition, we observed severe lymphedema of the lower extremity and genitalia in one patient. We provide additional evidence for a causal relationship between pathogenic mutations in RIT1, increased RAS‐MAPK/MEK‐ERK signaling and the clinical phenotype. The mutant RIT1 protein may possess reduced GTPase activity or a diminished ability to interact with cellular GTPase activating proteins; however the precise mechanism remains unknown. The phenotypic spectrum is likely to expand and includes lymphedema of the lower extremities in addition to nuchal hygroma.     

Functional Characterization and Classification of Frequent Low‐Density Lipoprotein Receptor Variants

Familial hypercholesterolemia (FH) is an autosomal‐dominant disorder mostly caused by mutations in the low‐density lipoprotein receptor (LDLR) gene leading to increased risk for premature cardiovascular diseases. According to functional studies, LDLR mutations may be classified into five classes. The main objective of this study was to characterize seven LDLR variants previously detected in FH patients. Analysis by flow cytometry and confocal microscopy of LDLR activity demonstrate that all the studied variants are pathogenic. Among the mutations located in β‐propeller, p.Trp577Gly and p.Ile624del were classified as class 2, whereas p.Arg416Trp and p.Thr454Asn as class 5. p.Phe800Glyfs*129 (located in the cytoplasmic domain), p.Cys155Tyr (located in the binding domain), and p.Asn825Lys (inside FxNPxY motif) were classified as class 2, 3, and 4, respectively. The results also show that LDLR activity of these class 4 and 5 variants is not completely abolished, showing a milder phenotype. We have also determined that statin response is more efficient lowering total cholesterol in heterozygous patients carrying p.Ile624del (class 2) compared with p.Arg416Trp and p.Thr454Asn (class 5) variants. In conclusion, these findings emphasize the importance of characterizing LDLR pathogenic variants to provide an indisputable FH diagnosis and to gain insight into the statin response depending on the LDLR class mutation.     

Both PIGA and PIGL mutations cause GPI‐a deficient isolates in the Tk6 cell line

Molecular analysis of proaerolysin selected glycosylphosphatidylinositol anchor (GPI‐a) deficient isolates in the TK6 cell line was performed. Initial studies found that the expected X‐linked PIGA mutations were rare among the spontaneous isolates but did increase modestly after ethyl methane sulfate (EMS) treatment (but to only 50% of isolates). To determine the molecular bases of the remaining GPI‐a deficient isolates, real‐time analysis for all the 25 autosomal GPI‐a pathway genes was performed on the isolates without PIGA mutations, determining that PIGL mRNA was absent for many. Further analysis determined these isolates had several different homozygous deletions of the 5′ region of PIGL (17p12‐p22) extending 5′ (telomeric) through NCOR1 and some into the TTC19 gene (total deletion >250,000 bp). It was determined that the TK6 parent had a hemizygous deletion in 17p12‐p22 (275,712 bp) extending from PIGL intron 2 into TTC19 intron 7. Second hit deletions in the other allele in the GPI‐a deficient isolates led to the detected homozygous deletions. Several of the deletion breakpoints including the original first hit deletion were sequenced. As strong support for TK6 having a deletion, a number of the isolates without PIGA mutations nor homozygous PIGL deletions had point mutations in the PIGL gene. These studies show that the GPI‐a mutation studies using TK6 cell line could be a valuable assay detecting point and deletion mutations in two genes simultaneously. Environ. Mol. Mutagen. 56:663–673, 2015. © 2015 Wiley Periodicals, Inc.     

Heterozygous mutations in the PALB2 hereditary breast cancer predisposition gene impact on the three‐dimensional nuclear organization of patient‐derived cell lines

PALB2/FANCN is a BRCA1‐ and BRCA2‐interacting Fanconi Anemia (FA) protein crucial for key BRCA2 genome caretaker functions. Heterozygous germline mutations in PALB2 predispose to breast cancer and biallelic mutations cause FA. FA proteins play a critical role in the telomere maintenance pathway, with telomeric shortening observed in FA cells. Less is known about telomere maintenance in the heterozygous state. Here, we investigate the roles of PALB2 heterozygous mutations in genomic instability, an important carcinogenesis precursor. Patient‐derived lymphoblastoid (LCL) and fibroblast (FCL) cell lines with monoallelic truncating PALB2 mutations were investigated using a combination of molecular imaging techniques including centromeric FISH, telomeric Q‐FISH and spectral karyotyping (SKY). Mitomycin C and Cisplatin sensitivity was assayed via cellular metabolism of WST‐1. The PALB2 c.229delT FCL showed increases in telomere counts associated with increased mean intensity compared with two wild‐type FCLs generated from first‐degree relatives (P =1.04E‐10 and P =9.68E‐15) and it showed evidence of chromosomal rearrangements. Significant differences in centromere distribution were observed in one of three PALB2 heterozygous FCLs analyzed when compared with PALB2 wild‐type, BRCA1 and BRCA2 heterozygous FCLs. No significant consistently increased sensitivity to Mitomycin C or Cisplatin was observed in LCLs. Our results are suggestive of an altered centromere distribution profile and a telomere instability phenotype. Together, these may indicate critical nuclear organization defects associated with the predisposition to transformation and early stage development of PALB2‐related cancers. © 2013 Wiley Periodicals, Inc.     

Molecular analyses of novel ASAH1 mutations causing Farber lipogranulomatosis: analyses of exonic splicing enhancer inactivating mutation

Farber lipogranulomatosis is a rare autosomal recessive lysosomal storage disorder caused by mutations in the ASAH1 gene. In the largest ever study, we identified and characterized ASAH1 mutations from 11 independent Farber disease (FD) families. A total of 13 different mutations were identified including 1 splice, 1 polypyrimidine tract (PPT) deletion and 11 missense mutations. Eleven mutations were exclusive to the Indian population. The IVS6+4A>G splice and IVS5‐16delTTTTC PPT deletion mutations resulted in skipping of exon 6 precluding thereby the region responsible for cleavage of enzyme precursor. A missense mutation (p.V198A) resulted in skipping of exon 8 due to inactivation of an exonic splicing enhancer (ESE) element. This is the first report of mutations affecting PPT and ESE in the ASAH1 gene resulting in FD.