Sita Reddy

Mice lacking the myotonic dystrophy protein kinase develop a late onset progressive myopathy.

Myotonic dystrophy (DM) is an autosomal dominant disorder resulting from the expansion of a CTG repeat in the 3′ untranslated region of a putative protein kinase (DMPK). To elucidate the role of DMPK in DM pathogenesis we have developed DMPK deficient (DMPK−/−) mice. DMPK−/− mice develop a late-onset, progressive skeletal myopathy that shares some pathological features with DM. Muscles from mature mice show variation in fibre size, increased fibre degeneration and fibrosis. Adult DMPK−/− mice show ultrastructural changes in muscle and a 50% decrease in force generation compared to young mice. Our results indicate that DMPK may be necessary for the maintenance of skeletal muscle structure and function and suggest that a decrease in DMPK levels may contribute to DM pathology.

RNA CUG Repeats Sequester CUGBP1 and Alter Protein Levels and Activity of CUGBP1

An RNA CUG triplet repeat binding protein, CUGBP1, regulates splicing and translation of various RNAs. Expansion of RNA CUG repeats in the 3′-untranslated repeat of the mutant myotonin protein kinase (DMPK) mRNA in myotonic dystrophy (DM) is associated with alterations in binding activity of CUGBP1. To investigate whether CUGBP1 is directly affected by expansion of CUG repeats in DM tissues, we examined the intracellular status of CUGBP1 in DM patients as well as in cultured cells over expressing RNA CUG repeats. The analysis of RNA·protein complexes showed that, in control tissues, the majority of CUGBP1 is free of RNA, whereas in DM patients the majority of CUGBP1 is associated with RNA containing CUG repeats. Similarly to DM patients, overexpression of RNA CUG repeats in cultured cells results in the re-allocation of CUGBP1 from a free state to the RNA·protein complexes containing CUG repeats. CUG repeat-dependent translocation of CUGBP1 into RNA·protein complexes is associated with increased levels of CUGBP1 protein and its binding activity. Experiments with cyclohexamide-dependent block of protein synthesis showed that the half-life of CUGBP1 is increased in cells expressing CUG repeats. Alteration of CUGBP1 in DM is accompanied by alteration in translation of a transcription factor CCAAT/enhancer-binding protein β (C/EBPβ), which has been previously described to be a target of CUGBP1. Analysis of C/EBPβ isoforms in DM patients with altered levels of CUGBP1 showed that translation of a dominant negative isoform, LIP, is induced by CUGBP1. Results of this paper demonstrate that the expansion of CUG repeats in DM affects RNA-binding proteins and leads to alteration in RNA processing.

DMPK dosage alterations result in atrioventricular conduction abnormalities in a mouse myotonic dystrophy model

Myotonic dystrophy (DM) is the most common form of muscular dystrophy and is caused by expansion of a CTG trinucleotide repeat on human chromosome 19. Patients with DM develop atrioventricular conduction disturbances, the principal cardiac manifestation of this disease. The etiology of the pathophysiological changes observed in DM has yet to be resolved. Haploinsufficiency of myotonic dystrophy protein kinase (DMPK), DM locus-associated homeodomain protein (DMAHP) and/or titration of RNA-binding proteins by expanded CUG sequences have been hypothesized to underlie the multi-system defects observed in DM. Using an in vivo murine electrophysiology study, we show that cardiac conduction is exquisitely sensitive to DMPK gene dosage. DMPK-/- mice develop cardiac conduction defects which include first-, second-, and third-degree atrioventricular (A-V) block. Our results demonstrate that the A-V node and the His-Purkinje regions of the conduction system are specifically compromised by DMPK loss. Importantly, DMPK+/- mice develop first-degree heart block, a conduction defect strikingly similar to that observed in DM patients. These results demonstrate that DMPK dosage is a critical element modulating cardiac conduction integrity and conclusively link haploinsufficiency of DMPK with cardiac disease in myotonic dystrophy.

Interaction of musleblind, CUG-BP1 and hnRNP H proteins in DM1-associated aberrant IR splicing

In myotonic dystrophy (DM1), both inactivation of muscleblind proteins and increased levels of CUG‐BP1 are reported. These events have been shown to contribute independently to aberrant splicing of a subset RNAs. We demonstrate that steady‐state levels of the splice regulator, hnRNP H, are elevated in DM1 myoblasts and that increased hnRNP H levels in normal myoblasts results in the inhibition of insulin receptor (IR) exon 11 splicing in a manner similar to that observed in DM1. In normal myoblasts, overexpression of either hnRNP H or CUG‐BP1 results in the formation of an RNA‐dependent suppressor complex consisting of both hnRNP H and CUG‐BP1, which is required to maximally inhibit IR exon 11 inclusion. Elevated levels of MBNL1 show RNA‐independent interaction with hnRNP H and dampen the inhibitory activity of increased hnRNP H levels on IR splicing in normal myoblasts. In DM1 myoblasts, overexpression of MBNL1 in conjunction with si‐RNA mediated depletion of hnRNP H contributes to partial rescue of the IR splicing defect. These data demonstrate that coordinated physical and functional interactions between hnRNP H, CUG‐BP1 and MBNL1 dictate IR splicing in normal and DM1 myoblasts.

CTG Repeats Show Bimodal Amplification in E. coli

Trinucleotide repeats in human genetic disorders showing anticipation follow two inheritance patterns as a function of length. Inheritance of 35-50 repeats show incremental changes, while tracts greater than 80 repeats show large saltatory expansions. We describe a bacterial system that recapitulates this striking bimodal pattern of CTG amplification. Incremental expansions predominate in CTG tracts < Okazaki fragment size, while saltatory expansions increase in repeat tracts > or = Okazaki fragment size. CTG amplification requires loss of SbcC, a protein that modulates cleavage of single-stranded DNA and degradation of duplex DNA from double-strand breaks. These results suggest that noncanonical single strand-containing secondary structures in Okazaki fragments and/or double-strand breaks in repeat tracts are intermediates in CTG amplification.

WRN Controls Formation of Extrachromosomal Telomeric Circles and Is Required for TRF2ΔB-Mediated Telomere Shortening

ABSTRACT Telomere dysfunction has been proposed to contribute to the pathogenesis of Werner syndrome (WS), a premature-aging disorder. The WS protein WRN binds TRF2, a telomere-specific factor that protects chromosome ends. TRF2 possesses an amino-terminal domain that plays an essential role in preventing telomere shortening, as expression of TRF2ΔB, which lacks this domain, leads to the formation of telomeric circles, telomere shortening, and cell senescence. Our data show that the TRF2ΔB-induced telomeric-loop homologous-recombination pathway requires WRN helicase. In addition, we show that WRN represses the formation of spontaneous telomeric circles, as demonstrated by the increased levels of telomeric circles observed in telomerase-positive WS fibroblasts. The mechanism of circle formation in WS cells does not involve XRCC3 function. Circle formation in WS cells is reduced by reconstitution with wild-type WRN but not mutant forms lacking either exonuclease or helicase activity, demonstrating that both enzymatic activities of WRN are required to suppress telomeric-circle formation in normal cells expressing telomerase reverse transcriptase. Thus, WRN has a key protective function at telomeres which influences telomere topology and inhibits accelerated attrition of telomeres.

Progressive Atrioventricular Conduction Block in a Mouse Myotonic Dystrophy Model

Introduction: Myotonic dystrophy is caused by expansion of a CTG trinucleotide repeat on human chromosome 19, and leads to progressive skeletal myopathy and atrioventricular conduction disturbances. A murine model of myotonic dystrophy has been designed by targeted disruption of the myotonic dystrophy protein kinase (DMPK) gene. The DMPK-deficient mice display abnormalities in A-V conduction characteristics, similar to the human cardiac phenotype. The purpose of this study was to determine whether age-related progression of A-V block occurs in a mouse model of DMPK-deficiency.Methods and Results: Surface ECGs and intracardiac electrophysiology (EP) studies were performed in 60 immature and 90 adult homozygous (DMPK), heterozygous (DMPK), and wild-type (WT) DMPK control mice. Complete studies were obtained on 141 of 150 mice. The RR, PR, QRS, and QT intervals were measured on ECG. Sinus node recovery time, AV refractory periods, paced AV Wenckebach and 2:1 block cycle lengths, atrial and ventricular effective refractory periods were compared between genotypes and age groups. There were no differences in ECG intervals or EP findings in the young mutant mice, but progressive PR prolongation in older mice. The A-V conduction defects are also sensitive to DMPK gene dosage. Adult DMPK mice develop 1°, 2° and 3° A-V block, whereas DMPK mice develop only 1° heart block.Conclusion: These data demonstrate that both age and DMPK dose are important factors regulating cardiac conduction in myotonic dystrophy. This mouse model of DM is remarkably similar to the human phenotype, with age-related progression in atrioventricular conduction defects.

Muscleblind-like 1 (Mbnl1) Promotes Insulin Receptor Exon 11 Inclusion via Binding to a Downstream Evolutionarily Conserved Intronic Enhancer

The insulin receptor exists as two isoforms, IR-A and IR-B, which result from alternative splicing of exon 11 in the primary transcript. These two isoforms show a cell-specific distribution, and their relative proportions also vary during development, aging, and in different disease states. We have previously demonstrated that both intron 10 and the alternatively spliced exon 11 contain regulatory sequences that affect insulin receptor splicing both positively and negatively and that these sequences bind the serine/arginine-rich (SR) proteins SRp20 and SF2/ASF and the CELF protein CUG-BP1. In this study, we describe a new intronic splicing element within intron 11 that is highly conserved across species. Using minigenes carrying deletion mutations within intron 11, we demonstrated that this sequence functions as an intronic splicing enhancer. We subsequently used RNA affinity chromatography to identify Mbnl1 as a splicing factor that recognizes this enhancer. By ribonucleoprotein immunoprecipitation, we also established that Mbnl1 binds specifically to the INSR (insulin receptor gene) RNA. Overexpression or knockdown of Mbnl1 in hepatoma and embryonic kidney cells altered the levels of exon 11 inclusion. Finally, we showed that deletion of the intronic enhancer eliminates the ability of Mbnl1 to promote exon inclusion. Collectively, these findings demonstrate a role for Mbnl1 in controlling insulin receptor exon 11 inclusion via binding to a downstream intronic enhancer element.

Lamin A, farnesylation and aging.

Lamin A is a component of the nuclear envelope that is synthesized as a precursor prelamin A molecule and then processed into mature lamin A through sequential steps of posttranslational modifications and proteolytic cleavages. Remarkably, over 400 distinct point mutations have been so far identified throughout the LMNA gene, which result in the development of at least ten distinct human disorders, collectively known as laminopathies, among which is the premature aging disease Hutchinson-Gilford progeria syndrome (HGPS). The majority of HGPS cases are associated with a single point mutation in the LMNA gene that causes the production of a permanently farnesylated mutant lamin A protein termed progerin. The mechanism by which progerin leads to premature aging and the classical HGPS disease phenotype as well as the relationship between this disorder and the onset of analogous symptoms during the lifespan of a normal individual are not well understood. Yet, recent studies have provided critical insights on the cellular processes that are affected by accumulation of progerin and have suggested that cellular alterations in the lamin A processing pathway leading to the accumulation of farnesylated prelamin A intermediates may play a role in the aging process in the general population. In this review we provide a short background on lamin A and its maturation pathway and discuss the current knowledge of how progerin or alterations in the prelamin A processing pathway are thought to influence cell function and contribute to human aging.

Localization of the Sites of Conduction Abnormalities in a Mouse Model of Myotonic Dystrophy

Heart Block in a Mouse Model of Myotonic Dystrophy. Introduction: A mouse strain lacking functional myotonic dystrophy protein kinase (DMPK) has recently been developed. DMPK‐/‐ mice exhibit muscular and conduction abnormalities consistent with the disease; however, the site of abnormal cardiac conduction is unknown.