RESUMEN
Epilepsy is common in early childhood. In this age group it is associated with high rates of therapy-resistance, and with cognitive, motor, and behavioural comorbidity. A large number of genes, with wide ranging functions, are implicated in its aetiology, especially in those with therapy-resistant seizures. Identifying the more common single-gene epilepsies will aid in targeting resources, the prioritization of diagnostic testing and development of precision therapy. Previous studies of genetic testing in epilepsy have not been prospective and population-based. Therefore, the population-incidence of common genetic epilepsies remains unknown. The objective of this study was to describe the incidence and phenotypic spectrum of the most common single-gene epilepsies in young children, and to calculate what proportion are amenable to precision therapy. This was a prospective national epidemiological cohort study. All children presenting with epilepsy before 36 months of age were eligible. Children presenting with recurrent prolonged (>10 min) febrile seizures; febrile or afebrile status epilepticus (>30 min); or with clusters of two or more febrile or afebrile seizures within a 24-h period were also eligible. Participants were recruited from all 20 regional paediatric departments and four tertiary children's hospitals in Scotland over a 3-year period. DNA samples were tested on a custom-designed 104-gene epilepsy panel. Detailed clinical information was systematically gathered at initial presentation and during follow-up. Clinical and genetic data were reviewed by a multidisciplinary team of clinicians and genetic scientists. The pathogenic significance of the genetic variants was assessed in accordance with the guidelines of UK Association of Clinical Genetic Science (ACGS). Of the 343 patients who met inclusion criteria, 333 completed genetic testing, and 80/333 (24%) had a diagnostic genetic finding. The overall estimated annual incidence of single-gene epilepsies in this well-defined population was 1 per 2120 live births (47.2/100 000; 95% confidence interval 36.9-57.5). PRRT2 was the most common single-gene epilepsy with an incidence of 1 per 9970 live births (10.0/100 000; 95% confidence interval 5.26-14.8) followed by SCN1A: 1 per 12 200 (8.26/100 000; 95% confidence interval 3.93-12.6); KCNQ2: 1 per 17 000 (5.89/100 000; 95% confidence interval 2.24-9.56) and SLC2A1: 1 per 24 300 (4.13/100 000; 95% confidence interval 1.07-7.19). Presentation before the age of 6 months, and presentation with afebrile focal seizures were significantly associated with genetic diagnosis. Single-gene disorders accounted for a quarter of the seizure disorders in this cohort. Genetic testing is recommended to identify children who may benefit from precision treatment and should be mainstream practice in early childhood onset epilepsy.
Asunto(s)
Epilepsia/epidemiología , Epilepsia/genética , Preescolar , Estudios de Cohortes , Femenino , Humanos , Incidencia , Lactante , Recién Nacido , Masculino , Fenotipo , Estudios Prospectivos , Escocia/epidemiologíaRESUMEN
Expansions of trinucleotide CAG/CTG repeats in somatic tissues are thought to contribute to ongoing disease progression through an affected individual's life with Huntington's disease or myotonic dystrophy. Broad ranges of repeat instability arise between individuals with expanded repeats, suggesting the existence of modifiers of repeat instability. Mice with expanded CAG/CTG repeats show variable levels of instability depending upon mouse strain. However, to date the genetic modifiers underlying these differences have not been identified. We show that in liver and striatum the R6/1 Huntington's disease (HD) (CAG)â¼100 transgene, when present in a congenic C57BL/6J (B6) background, incurred expansion-biased repeat mutations, whereas the repeat was stable in a congenic BALB/cByJ (CBy) background. Reciprocal congenic mice revealed the Msh3 gene as the determinant for the differences in repeat instability. Expansion bias was observed in congenic mice homozygous for the B6 Msh3 gene on a CBy background, while the CAG tract was stabilized in congenics homozygous for the CBy Msh3 gene on a B6 background. The CAG stabilization was as dramatic as genetic deficiency of Msh2. The B6 and CBy Msh3 genes had identical promoters but differed in coding regions and showed strikingly different protein levels. B6 MSH3 variant protein is highly expressed and associated with CAG expansions, while the CBy MSH3 variant protein is expressed at barely detectable levels, associating with CAG stability. The DHFR protein, which is divergently transcribed from a promoter shared by the Msh3 gene, did not show varied levels between mouse strains. Thus, naturally occurring MSH3 protein polymorphisms are modifiers of CAG repeat instability, likely through variable MSH3 protein stability. Since evidence supports that somatic CAG instability is a modifier and predictor of disease, our data are consistent with the hypothesis that variable levels of CAG instability associated with polymorphisms of DNA repair genes may have prognostic implications for various repeat-associated diseases.
Asunto(s)
Enfermedad de Huntington/genética , Proteínas/genética , Expansión de Repetición de Trinucleótido/genética , Repeticiones de Trinucleótidos/genética , Animales , Cuerpo Estriado/metabolismo , Modelos Animales de Enfermedad , Inestabilidad Genómica , Humanos , Ratones , Proteína 3 Homóloga de MutS , Distrofia Miotónica/genética , Distrofia Miotónica/metabolismo , Neostriado/metabolismo , Proteínas del Tejido Nervioso/genética , Proteínas del Tejido Nervioso/metabolismo , Polimorfismo Genético , Estabilidad ProteicaRESUMEN
Expansions of (CTG)·(CAG) repeated DNAs are the mutagenic cause of 14 neurological diseases, likely arising through the formation and processing of slipped-strand DNAs. These transient intermediates of repeat length mutations are formed by out-of-register mispairing of repeat units on complementary strands. The three-way slipped-DNA junction, at which the excess repeats slip out from the duplex, is a poorly understood feature common to these mutagenic intermediates. Here, we reveal that slipped junctions can assume a surprising number of interconverting conformations where the strand opposite the slip-out either is fully base paired or has one or two unpaired nucleotides. These unpaired nucleotides can also arise opposite either of the nonslipped junction arms. Junction conformation can affect binding by various structure-specific DNA repair proteins and can also alter correct nick-directed repair levels. Junctions that have the potential to contain unpaired nucleotides are repaired with a significantly higher efficiency than constrained fully paired junctions. Surprisingly, certain junction conformations are aberrantly repaired to expansion mutations: misdirection of repair to the non-nicked strand opposite the slip-out leads to integration of the excess slipped-out repeats rather than their excision. Thus, slipped-junction structure can determine whether repair attempts lead to correction or expansion mutations.
Asunto(s)
Reparación del ADN , ADN/química , ADN/metabolismo , Repeticiones de Trinucleótidos , Emparejamiento Base , Secuencia de Bases , ADN/genética , Proteínas de Unión al ADN/metabolismo , Endonucleasas/metabolismo , Proteína HMGB1/metabolismo , Células HeLa , Humanos , Datos de Secuencia Molecular , Proteína MutS de Unión a los Apareamientos Incorrectos del ADN/metabolismo , Proteínas Nucleares/metabolismo , Conformación de Ácido Nucleico , Oligonucleótidos/química , Oligonucleótidos/genética , Oligonucleótidos/metabolismo , Unión Proteica , Factores de Transcripción/metabolismoRESUMEN
Mismatch repair (MMR) is required for proper maintenance of the genome by protecting against mutations. The mismatch repair system has also been implicated as a driver of certain mutations, including disease-associated trinucleotide repeat instability. We recently revealed a requirement of hMutSß in the repair of short slip-outs containing a single CTG repeat unit (1). The involvement of other MMR proteins in short trinucleotide repeat slip-out repair is unknown. Here we show that hMutLα is required for the highly efficient in vitro repair of single CTG repeat slip-outs, to the same degree as hMutSß. HEK293T cell extracts, deficient in hMLH1, are unable to process single-repeat slip-outs, but are functional when complemented with hMutLα. The MMR-deficient hMLH1 mutant, T117M, which has a point mutation proximal to the ATP-binding domain, is defective in slip-out repair, further supporting a requirement for hMLH1 in the processing of short slip-outs and possibly the involvement of hMHL1 ATPase activity. Extracts of hPMS2-deficient HEC-1-A cells, which express hMLH1, hMLH3, and hPMS1, are only functional when complemented with hMutLα, indicating that neither hMutLß nor hMutLγ is sufficient to repair short slip-outs. The resolution of clustered short slip-outs, which are poorly repaired, was partially dependent upon a functional hMutLα. The joint involvement of hMutSß and hMutLα suggests that repeat instability may be the result of aberrant outcomes of repair attempts.
Asunto(s)
Enzimas Reparadoras del ADN/metabolismo , Reparación del ADN/fisiología , Repeticiones de Trinucleótidos/fisiología , Proteínas Adaptadoras Transductoras de Señales/genética , Proteínas Adaptadoras Transductoras de Señales/metabolismo , Enzimas Reparadoras del ADN/genética , Células HEK293 , Humanos , Homólogo 1 de la Proteína MutL , Proteínas MutL , Proteínas de Neoplasias/genética , Proteínas de Neoplasias/metabolismo , Proteínas Nucleares/genética , Proteínas Nucleares/metabolismo , Mutación Puntual , Estructura Terciaria de ProteínaRESUMEN
Expansions of CTG/CAG trinucleotide repeats, thought to involve slipped DNAs at the repeats, cause numerous diseases including myotonic dystrophy and Huntington's disease. By unknown mechanisms, further repeat expansions in transgenic mice carrying expanded CTG/CAG tracts require the mismatch repair (MMR) proteins MSH2 and MSH3, forming the MutSbeta complex. Using an in vitro repair assay, we investigated the effect of slip-out size, with lengths of 1, 3, or 20 excess CTG repeats, as well as the effect of the number of slip-outs per molecule, on the requirement for human MMR. Long slip-outs escaped repair, whereas short slip-outs were repaired efficiently, much greater than a G-T mismatch, but required hMutSbeta. Higher or lower levels of hMutSbeta or its complete absence were detrimental to proper repair of short slip-outs. Surprisingly, clusters of as many as 62 short slip-outs (one to three repeat units each) along a single DNA molecule with (CTG)50*(CAG)50 repeats were refractory to repair, and repair efficiency was reduced further without MMR. Consistent with the MutSbeta requirement for instability, hMutSbeta is required to process isolated short slip-outs; however, multiple adjacent short slip-outs block each other's repair, possibly acting as roadblocks to progression of repair and allowing error-prone repair. Results suggest that expansions can arise by escaped repair of long slip-outs, tandem short slip-outs, or isolated short slip-outs; the latter two types are sensitive to hMutSbeta. Poor repair of clustered DNA lesions has previously been associated only with ionizing radiation damage. Our results extend this interference in repair to neurodegenerative disease-causing mutations in which clustered slip-outs escape proper repair and lead to expansions.
Asunto(s)
Distrofia Miotónica/genética , Repeticiones de Trinucleótidos/genética , Animales , Análisis por Conglomerados , ADN/genética , ADN/metabolismo , Reparación de la Incompatibilidad de ADN , Humanos , Ratones , Ratones Transgénicos , Mutación , Proteínas/genéticaRESUMEN
While DNA repair proteins are generally thought to maintain the integrity of the whole genome by correctly repairing mutagenic DNA intermediates, there are cases where DNA "repair" proteins are involved in causing mutations instead. For instance, somatic hypermutation (SHM) and class switch recombination (CSR) require the contribution of various DNA repair proteins, including UNG, MSH2 and MSH6 to mutate certain regions of immunoglobulin genes in order to generate antibodies of increased antigen affinity and altered effector functions. Another instance where "repair" proteins drive mutations is the instability of gene-specific trinucleotide repeats (TNR), the causative mutations of numerous diseases including Fragile X mental retardation syndrome (FRAXA), Huntington's disease (HD), myotonic dystrophy (DM1) and several spinocerebellar ataxias (SCAs) all of which arise via various modes of pathogenesis. These healthy and deleterious mutations that are induced by repair proteins are distinct from the genome-wide mutations that arise in the absence of repair proteins: they occur at specific loci, are sensitive to cis-elements (sequence context and/or epigenetic marks) and transcription, occur in specific tissues during distinct developmental windows, and are age-dependent. Here we review and compare the mutagenic role of DNA "repair" proteins in the processes of SHM, CSR and TNR instability.
Asunto(s)
Enzimas Reparadoras del ADN/fisiología , Reparación del ADN , Proteínas de Unión al ADN/fisiología , Cambio de Clase de Inmunoglobulina , Hipermutación Somática de Inmunoglobulina , Expansión de Repetición de Trinucleótido , Animales , Diversidad de Anticuerpos/genética , Humanos , Región de Cambio de la Inmunoglobulina/genética , Modelos Biológicos , MutaciónRESUMEN
Typically disease-causing CAG/CTG repeats expand, but rare affected families can display high levels of contraction of the expanded repeat amongst offspring. Understanding instability is important since arresting expansions or enhancing contractions could be clinically beneficial. The MutSß mismatch repair complex is required for CAG/CTG expansions in mice and patients. Oddly, by unknown mechanisms MutSß-deficient mice incur contractions instead of expansions. Replication using CTG or CAG as the lagging strand template is known to cause contractions or expansions respectively; however, the interplay between replication and repair leading to this instability remains unclear. Towards understanding how repeat contractions may arise, we performed in vitro SV40-mediated replication of repeat-containing plasmids in the presence or absence of mismatch repair. Specifically, we separated repair from replication: Replication mediated by MutSß- and MutSα-deficient human cells or cell extracts produced slipped-DNA heteroduplexes in the contraction- but not expansion-biased replication direction. Replication in the presence of MutSß disfavoured the retention of replication products harbouring slipped-DNA heteroduplexes. Post-replication repair of slipped-DNAs by MutSß-proficient extracts eliminated slipped-DNAs. Thus, a MutSß-deficiency likely enhances repeat contractions because MutSß protects against contractions by repairing template strand slip-outs. Replication deficient in LigaseI or PCNA-interaction mutant LigaseI revealed slipped-DNA formation at lagging strands. Our results reveal that distinct mechanisms lead to expansions or contractions and support inhibition of MutSß as a therapeutic strategy to enhance the contraction of expanded repeats.
Asunto(s)
Replicación del ADN/genética , ADN/genética , Proteína MutS de Unión a los Apareamientos Incorrectos del ADN/deficiencia , Expansión de Repetición de Trinucleótido/genética , Animales , Reparación de la Incompatibilidad de ADN , Haplorrinos , Células HeLa , HumanosRESUMEN
Mismatch repair (MMR) proteins have critical roles in the maintenance of genomic stability, both class-switch recombination and somatic hypermutation of immunoglobulin genes and disease-associated trinucleotide repeat expansions. In the genetic absence of MMR, certain tissues are predisposed to mutations and cancer. MMR proteins are involved in various functions including protection from replication-associated and non-mitotic mutations, as well as driving programmed and deleterious mutations, including disease-causing trinucleotide repeat expansions. Here we have assessed the levels of MSH2, MSH3, and MSH6 expression in a large number of murine tissues by transcript analysis and simultaneous Western blotting. We observed that MMR expression patterns varied widely between 14 different tissue types, but did not vary with age (13-84 weeks). MMR protein expression is highest in testis, thymus and spleen and lowest in pancreas, quadriceps and heart, with intermediate levels in liver, kidney, intestine, colon, cortex, striatum and cerebellum. By equalizing antibody signal intensity to represent levels found in mMutSα and mMutSß purified proteins, we observed that mMSH3 protein levels are greater than mMSH6 levels in the multiple tissues analyzed, with more MSH6 in proliferating tissues. In the intestinal epithelium MSH3 and MSH6 are more highly expressed in the proliferative undifferentiated cells of the crypts than in the differentiated villi cells, as reported for MSH2. This finding correlates with the higher level of MMR expression in highly proliferative mouse tissues such as the spleen and thymus. The relative MMR protein expression levels may explain the functional and tissue-specific reliance upon the roles of each MMR protein.