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Objective:
To determine the survival in a population of German patients with Duchenne muscular dystrophy.
Patients and methods:
Information about 94 patients born between 1970 and 1980 was obtained by telephone interviews and questionnaires. In addition to age of death or actual age during the investigation, data concerning clinical course and medical interventions were collected.
Results:
67 patients with molecularly confirmed diagnoses had a median survival of 24.0 years. Patients without molecular confirmation (clinical diagnosis only) had a chance of 67 % to reach that age. Grouping of our patient cohort according to the year of death (before and after 2000), ventilation was recognized as main intervention affecting survival with ventilated reaching a median survival of 27.0 years. For those without ventilation it was 19.0 years.
Conclusion and clinical relevance:
our study provides survival data for a cohort of DMD patients in Germany stratified by year of death. Median survival was 24.0 years in patients confirmed by molecular testing. Ventilated patients had a median survival of 27 years. We consider this piece of information helpful in the medical care of DMD patients.
We describe monozygotic twins discordant for childhood leukemia and secondary thyroid carcinoma. We used bisulfite pyrosequencing to compare the constitutive promoter methylation of BRCA1 and several other tumor suppressor genes in primary fibroblasts. The affected twin displayed an increased BRCA1 methylation (12%), compared with her sister (3%). Subsequent bisulfite plasmid sequencing demonstrated that 13% (6 of 47) BRCA1 alleles were fully methylated in the affected twin, whereas her sister displayed only single CpG errors without functional implications. This between-twin methylation difference was also found in irradiated fibroblasts and untreated saliva cells. The BRCA1 epimutation may have originated by an early somatic event in the affected twin: approximately 25% of her body cells derived from different embryonic cell lineages carry one epigenetically inactivated BRCA1 allele. This epimutation was associated with reduced basal protein levels and a higher induction of BRCA1 after DNA damage. In addition, we performed a genome-wide microarray analysis of both sisters and found several copy number variations, i.e., heterozygous deletion and reduced expression of the RSPO3 gene in the affected twin. This monozygotic twin pair represents an impressive example of epigenetic somatic mosaicism, suggesting a role for constitutive epimutations, maybe along with de novo genetic alterations in recurrent tumor development.
Introduction
Miyoshi myopathy, a type of distal myopathy with predominant involvement of the posterior calf muscles, has been assigned to mutations in the dysferlin gene. However, many of the late-onset limb-girdle and distal myopathies that resemble dysferlinopathy or Miyoshi myopathy remain unclassified, even after extensive immunohistological and genetic analysis.
Case presentation
We report the case of a 59-year-old Caucasian man with distal myopathy and exercise-induced myalgia, preferentially of the leg muscles, closely resembling the Miyoshi phenotype. Magnetic resonance imaging of his calf muscles showed typical fatty replacement of the medial heads of the gastrocnemius muscles and soleus muscles, with progression to the adductor longus muscles over a time course of two years. However, genetic analysis revealed that the phenotype of our patient was not related to a mutation in the dysferlin gene but to a novel homozygous splice mutation in the anoctamin 5 gene. Mutations in the anoctamin 5 gene have so far been identified only in some cases of limb-girdle and distal myopathy. Mutations in the anoctamin 5 gene have been assigned to limb-girdle muscular dystrophy type 2L, while distal Miyoshi-like phenotypes have been classified as Miyoshi myopathy type 3.
Conclusion
The case presented in this report further strengthens the underlying genetic heterogeneity in Miyoshi myopathy-like phenotypes and adds another family to non-dysferlin, Miyoshi myopathy type 3 of late-onset. Furthermore, our case supports the recent observation that anoctamin 5 mutations are a primary cause of distal non-dysferlin myopathies. Therefore, given the increasing number of anoctamin 5 mutations in Miyoshi-like phenotypes, genetic analysis should include an anoctamin 5 screen in late-onset limb-girdle and distal myopathies.
Fanconi anemia (FA) is a rare genomic instability syndrome. Disease-causing are biallelic mutations in any one of at least 15 genes encoding members of the FA/BRCA pathway of DNA-interstrand crosslink repair. Patients are diagnosed based upon phenotypical manifestationsand the diagnosis of FA is confirmed by the hypersensitivity of cells to DNA interstrand crosslinking agents. Customary molecular diagnostics has become increasingly cumbersome, time-consuming and expensive the more FA genes have been identified. We performed Whole Exome Sequencing (WES) in four FA patients in order to investigate the potential of this method for FA genotyping. In search of an optimal WES methodology we explored different enrichment and sequencing techniques. In each case we were able to identify the pathogenic mutations so that WES provided both, complementation group assignment and mutation detection in a single approach. The mutations included homozygous and heterozygous single base pair substitutions and a two-base-pair duplication in FANCJ, -D1, or - D2. Different WES strategies had no critical influence on the individual outcome. However, database errors and in particular pseudogenes impose obstacles that may prevent correct data perception and interpretation, and thus cause pitfalls. With these difficulties in mind, our results show that WES is a valuable tool for the molecular diagnosis of FA and a sufficiently safe technique, capable of engaging increasingly in competition with classical genetic approaches.
Fanconi anemia (FA) is an autosomal recessive or X-chromosomal inherited disorder, which is not only phenotypically but also genotypically very heterogeneous. While its hallmark feature is progressive bone marrow failure, many yet not all patients suffer additionally from typical congenital malformations like radial ray defects and growth retardation. In young adulthood the cumulative risk for developing hematological or other malignancies is compared to the general population several hundred-fold increased. The underlying molecular defect is the deficiency of DNA interstrand crosslink (ICL) repair. ICLs are deleterious lesions, which interfere with crucial cellular processes like transcription and replication and thereby can lead to malignant transformation, premature senescence or cell death. To overcome this threat evolution developed a highly complex network of interacting DNA repair pathways, which is conserved completely only in vertebrates. The so called FA/BRCA DNA damage response pathway is able to recognize ICLs on stalled replication forks and promotes their repair through homologous recombination (HR). Today we know 15 FA genes (FANCA, -B, -C, -D1, -D2, -E, -F, -G, -I, -J, -L, -M, -N, -O and -P) whose products are involved in this pathway. Although more than 80% of FA patients carry biallelic mutations in either FANCA, FANCC or FANCG, there are still some who cannot be assigned to any of the known complementation groups. This work aimed to indentify the di¬sease causing mutations in a cohort of those unassigned patients. Initial screens of the candidate genes FAN1, MHF1 and MHF2 did not reveal any pathogenic alterations. Moreover, FAN1 could be excluded as FA candidate gene because patients carrying a homozygous microdeletion including the FAN1 locus did not show a phenotype comparable to FA patients. In the case of MHF1 and MHF2 the reason for the negative screening result is not clear. Mutation carriers might be rare or, regarding the diverse and also FA pathway independent protein functions, phenotypically not comparable to FA patients. Nevertheless, this study contri¬buted to the identification and characterization of the most recent members of the FA pathway - RAD51C (FANCO), SLX4 (FANCP) and XPF (FANCQ). FANCO is one of the RAD51 paralogs and is involved in crucial steps of HR. But since the only reported FA-O patient has so far not developed any hematological anomalies, FANCO is tentatively designated as gene underlying an FA-like disorder. In contrast, patients carrying biallelic mutations in FANCP do not only show hematological anomalies, but as well congenital malformations typical for FA. The distinct role of FANCP in the FA pathway could not be determined, but it is most likely the coordination of structure-specific nucleases during ICL excision. One of these nucleases is the heterodimer XPF/ERCC1. XPF is probably disease causing in the complementation group FA-Q and is the first FA gene, which was identified by Next Generation Sequencing (NGS). Extraordinarily is that mutations in this gene had previously been reported to cause two other disorders, xeroderma pigmentosum and segmental progeria. Despite some overlaps, it was shown that the divergent phenotypes could clearly be distinguished and are caused by distinct functional defects of XPF. Additionally, this work aimed to improve and accelerate the genotyping process of FA patients in general. Therefore, classical approaches should be complemented or fully replaced by approa¬ches using NGS. Massively parallel sequencing of the whole exome proved to be most appro¬priate and the establishment of an FA-specific analysis pipeline facilitated improved molecular diagnostics by combining complementation group assignment and mutation analysis in one step. Consequently two NGS studies revealed the pathogenic defect in several previously unassigned FA patients and thereby added another patient to one of the most recent subtypes, FA-P. In summary, this work contributed not only to further completion of the FA/BRCA DNA repair network by adding three novel genes, it also showed that classical molecular approaches for re¬search as well as for diagnostics could be replaced by NGS.
Die proximale infantile und juvenile spinale Muskelatrophie (SMA) ist die zweithäufigste autosomal rezessive Erbkrankheit nach der Mukoviszidose. Das hauptsächlich verantwortliche Gen, das survival motor neuron (SMN1) Gen, ist auf Chromosom 5 lokalisiert. Man unterscheidet Normalallele (mit einer oder zwei SMN1-Kopien) und Defektallele (einfache Deletion, große Deletion oder Punktmutation). Für die vorliegende Arbeit wurden zahlreiche in der Literatur verfügbare Daten zur SMA Typ I-III zusammengetragen und in ihrer Abhängigkeit in ein genetisches Modell gebracht, um so fehlende Parameter berechnen zu können. Etwa einer von 9.693 Lebendgeborenen ist von der Erkrankung betroffen, während einer von 6.117.733 Feten aufgrund von homozygoter großer Deletion pränatal verstirbt. Mit einer berechneten unvollständigen Penetranz von etwa 0,8418 ergibt sich, dass einer von 51.572 homozygot Deletierten oder compound-Heterozygoten nicht erkrankt. Dies ergibt eine Genfrequenz von etwa 1:90 und eine Heterozygotenwahrscheinlichkeit von 1:46. Die einzelnen Allelfrequenzen konnten wie folgt berechnet werden: einfache Deletion a (0-SMN1-Kopien): ≈ 0,0104; Normalallel b (1-SMN1-Kopie): ≈ 0,9527; Normalallel c (2-SMN1-Kopien): ≈ 0,0362; Punktmutation d (1-SMN1-Kopie): ≈ 0,0003; große Deletion g (0-SMN1-Kopien): ≈ 0,0004. Die Hardy-Weinberg-Regel ist eine wichtige Grundlage, um A-priori-Wahrscheinlichkeiten zu bestimmen. Es wird demonstriert, wie sich unter Berücksichtigung gesunder Angehörige, den Ergebnissen molekularer Tests sowie des genetischen Modells mit Hilfe des Bayesschen Rechnetableaus genauere Risikoberechnungen als bisher durchführen lassen.
Es werden die Parameter Summe-G2/GF und G0/G1 der hochauflösenden, zweiparametrigen Zellzyklusanalyse von Lymphozyten bei Fanconi-Anämie-Patienten, bei denen mehrere Meßwerte vorliegen, im Hinblick auf Schwankungen untersucht. Nach Auswertung der Daten stellen die Werte keine konstanten Parameter für den einzelnen Patienten dar. Die Langzeitanalyse des Zellzyklusverhaltens peripherer Blutlymphozyten reflektiert jedoch weitgehend die klinische Situation der Patienten.
Genetic defects in breast cancer (BC) susceptibility genes, most importantly BRCA1 and BRCA2, account for ∼40% of hereditary BC and ovarian cancer (OC). Little is known about the contribution of constitutive (soma-wide) epimutations to the remaining cases. We developed bisulfite pyrosequencing assays to screen >600 affected BRCA1/BRCA2 mutation-negative patients from the German Consortium for Hereditary Breast and Ovarian Cancer for constitutive hypermethylation of ATM, BRCA1, BRCA2, RAD51C, PTEN and TP53 in blood cells. In a second step, patients with ≥6% promoter methylation were analyzed by bisulfite plasmid sequencing to demonstrate the presence of hypermethylated alleles (epimutations), indicative of epigenetic gene silencing. Altogether we identified nine (1.4%) patients with constitutive BRCA1 and three (0.5%) with RAD51C hypermethylation. Epimutations were found in both sporadic cases, in particular in 2 (5.5%) of 37 patients with early-onset BC, and familial cases, in particular 4 (10%) of 39 patients with OC. Hypermethylation was always confined to one of the two parental alleles in a subset (12–40%) of the analyzed cells. Because epimutations occurred in cell types from different embryonal layers, they most likely originated in single cells during early somatic development. We propose that analogous to germline genetic mutations constitutive epimutations may serve as the first hit of tumor development. Because the role of constitutive epimutations in cancer development is likely to be largely underestimated, future strategies for effective testing of susceptibility to BC and OC should include an epimutation screen.
Introduction: Several common alleles have been shown to be associated with breast and/or ovarian cancer risk for BRCA1 and BRCA2 mutation carriers. Recent genome-wide association studies of breast cancer have identified eight additional breast cancer susceptibility loci: rs1011970 (9p21, CDKN2A/B), rs10995190 (ZNF365), rs704010 (ZMIZ1), rs2380205 (10p15), rs614367 (11q13), rs1292011 (12q24), rs10771399 (12p11 near PTHLH) and rs865686 (9q31.2).
Methods: To evaluate whether these single nucleotide polymorphisms (SNPs) are associated with breast cancer risk for BRCA1 and BRCA2 carriers, we genotyped these SNPs in 12,599 BRCA1 and 7,132 BRCA2 mutation carriers and analysed the associations with breast cancer risk within a retrospective likelihood framework.
Results: Only SNP rs10771399 near PTHLH was associated with breast cancer risk for BRCA1 mutation carriers (per-allele hazard ratio (HR) = 0.87, 95% CI: 0.81 to 0.94, P-trend = 3 x 10\(^{-4}\)). The association was restricted to mutations proven or predicted to lead to absence of protein expression (HR = 0.82, 95% CI: 0.74 to 0.90, P-trend = 3.1 x 10\(^{-5}\), P-difference = 0.03). Four SNPs were associated with the risk of breast cancer for BRCA2 mutation carriers: rs10995190, P-trend = 0.015; rs1011970, P-trend = 0.048; rs865686, 2df P = 0.007; rs1292011 2df P = 0.03. rs10771399 (PTHLH) was predominantly associated with estrogen receptor (ER)-negative breast cancer for BRCA1 mutation carriers (HR = 0.81, 95% CI: 0.74 to 0.90, P-trend = 4 x 10\(^{-5}\)) and there was marginal evidence of association with ER- negative breast cancer for BRCA2 mutation carriers (HR = 0.78, 95% CI: 0.62 to 1.00, P-trend = 0.049).
Conclusions: The present findings, in combination with previously identified modifiers of risk, will ultimately lead to more accurate risk prediction and an improved understanding of the disease etiology in BRCA1 and BRCA2 mutation carriers.
Bei einem kleinen Prozentsatz (2–3 %) aller molekulargenetisch untersuchten Hä-mophilie-A-Fälle konnte bislang keine kausale Mutation innerhalb der F8-Gen-Region aufgedeckt werden. Die molekularen Ursachen der Hämophilie dieser Patienten sollten im ersten Teil der vorliegenden Doktorarbeit mittels zusätzlicher Methoden aufgeklärt werden. Bei zwei Patienten mit milder Hämophilie A konnte je ein Basenaustausch im Promotorbereich des F8-Gens identifiziert werden. Um die Kausalität dieser Austausche zu überprüfen, wurden für diese und zwei weitere bereits publizierte Promotor-Mutationen Luciferase-Assays durchgeführt. Diese Ergebnisse machten deutlich, dass die nachgewiesenen Promotor-Mutationen die Aktivität des Promotors deutlich herabsetzen und daher als ursächlich einzustufen sind. Weiterhin wurden die übrigen Patienten auf epigenetische Veränderungen in fünf CpG-Inseln im 5’UTR und Intron 1 des F8-Gens untersucht. Hierbei konnten bei drei Patienten auffällige Methylierungsmuster nachgewiesen werden, wobei diese auf ein Klinefelter-Syndrom und genomische Veränderungen im Intron 1 zurückzuführen sind, nicht jedoch auf einen aberranten Methylierungsstatus, der die FVIII-Expression beeinflussen könnte. Mit Hilfe von mRNA-Untersuchungen konnten bei vier Patienten mit mutmaßlichen F8-Spleißmutationen aberrante F8-Transkripte nachgewiesen werden und somit die Kausalität der Mutationen geklärt werden. Des Weiteren wurden aus der Literatur alle bisher als kausal identifizierten stillen Mutationen und Spleißmutationen zusammengestellt, um mit diesen Ergebnissen die Spleißvorhersage-Software Alamut zu validieren. Die große Mehrzahl (78 %) der Spleißvorhersagen stimmte mit den Resultaten der mRNA-Untersuchungen (zumindest im Trend) überein, während es bei 22 % der Vorhersagen und mRNA-Analysen zu unterschiedlichen Resultaten kam. Innerhalb einer vorangegangenen Diplomarbeit konnten zehn Duplikationsbruch-punkte im F8-Gen von nicht verwandten Hämophilie-A-Patienten aufgeklärt werden. Diese wurden nun mit verschiedenen in-silico-Programmen analysiert, um die Sequenzumgebung der Bruchpunkt genauer zu beschreiben. Die Untersuchung ergab, dass verschiedene Mechanismen zur Entstehung von Duplikationen führen können und vermutlich mehrere Sequenzmotive in direkter Nähe der Bruchpunkte hierzu beitragen. Im Rahmen der molekulargenetischen Hämophilie-A-Diagnostik zum Nachweis von Intron-1- bzw. Intron-22-Inversionen sind einige Patienten mit schwerer Hämophilie A aufgefallen, welche ungewöhnliche Bandenmuster in den analytischen PCRs bzw. Southern-Blots aufwiesen. Mittels MLPA-Analysen wurden bei diesen Patienten Deletionen oder Duplikationen (CNVs) aufgedeckt, die meist allein die auffälligen Bandenmuster nicht erklären konnten. Weitere Long-Range-PCR-Untersuchungen belegten dagegen, dass fünf der untersuchten Fälle auf ein kombiniertes Inversions- und Duplikations- bzw. Deletionsereignis zurückzuführen sind. Als zweiter Teil der Arbeit wurden Transkriptions- und Translationsuntersuchungen von Nonsense-Mutationen des F8-Gens in einem zellulären Expressionssystem durchgeführt. Es konnte nachgewiesen werden, dass trotz Nonsense-Mutation eine komplette F8-Tran¬skrip¬tion stattfindet. Antigenanalysen konnten die Expression von trunkierten Proteinen nachweisen, wenn die Nonsense-Mutationen in der leichten Kette, d.h. den distalen Domänen A3, C1 oder C2, lag. Bei Nonsense-Mutationen in der schweren Kette (den proximalen Domänen A1, A2 oder B) war keine Proteinexpression nachweisbar. Diese Daten konnte durch intrazelluläre Immunlokalisation der trunkierten Proteine bestätigt werden. Die Ergebnisse deuten darauf hin, dass die B-Domäne eine wichtige Rolle bei der Proteinprozessierung spielt, vermutlich indem sie die Bindung von Chaperonen ermöglicht und das FVIII-Protein vor Degradation schützt.