Veronica A. Raker scite author profile

DNA methylation of tumor suppressor genes is a frequent mechanism of transcriptional silencing in cancer. The molecular mechanisms underlying the specificity of methylation are unknown. We report here that the leukemia-promoting PML-RAR fusion protein induces gene hypermethylation and silencing by recruiting DNA methyltransferases to target promoters and that hypermethylation contributes to its leukemogenic potential. Retinoic acid treatment induces promoter demethylation, gene reexpression, and reversion of the transformed phenotype. These results establish a mechanistic link between genetic and epigenetic changes during transformation and suggest that hypermethylation contributes to the early steps of carcinogenesis.

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Crystal Structures of Two Sm Protein Complexes and Their Implications for the Assembly of the Spliceosomal snRNPs

Kambach

Walke

Young

et al. 1999

Cell

430

506

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The U1, U2, U4/U6, and U5 small nuclear ribonucleoprotein particles (snRNPs) involved in pre-mRNA splicing contain seven Sm proteins (B/B', D1, D2, D3, E, F, and G) in common, which assemble around the Sm site present in four of the major spliceosomal small nuclear RNAs (snRNAs). These proteins share a common sequence motif in two segments, Sm1 and Sm2, separated by a short variable linker. Crystal structures of two Sm protein complexes, D3B and D1D2, show that these proteins have a common fold containing an N-terminal helix followed by a strongly bent five-stranded antiparallel beta sheet, and the D1D2 and D3B dimers superpose closely in their core regions, including the dimer interfaces. The crystal structures suggest that the seven Sm proteins could form a closed ring and the snRNAs may be bound in the positively charged central hole.

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A p53-p66Shc signalling pathway controls intracellular redox status, levels of oxidation-damaged DNA and oxidative stress-induced apoptosis

et al. 2002

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Correlative evidence links stress, accumulation of oxidative cellular damage and ageing in lower organisms and in mammals. We investigated their mechanistic connections in p66Shc knockout mice, which are characterized by increased resistance to oxidative stress and extended life span. We report that p66Shc acts as a downstream target of the tumour suppressor p53 and is indispensable for the ability of stress-activated p53 to induce elevation of intracellular oxidants, cytochrome c release and apoptosis. Other functions of p53 are not in¯uenced by p66Shc expression. In basal conditions, p66Shc7/7 and p537/7 cells have reduced amounts of intracellular oxidants and oxidation-damaged DNA. We propose that steady-state levels of intracellular oxidants and oxidative damage are genetically determined and regulated by a stress-induced signal transduction pathway involving p53 and p66Shc.

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The snRNP core assembly pathway: identification of stable core protein heteromeric complexes and an snRNP subcore particle in vitro.

1996

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Stable association of the eight common Sm proteins with U1, U2, U4 or U5 snRNA to produce a spliceosomal snRNP core structure is required for snRNP biogenesis, including cap hypermethylation and nuclear transport. Here, the assembly of snRNP core particles was investigated in vitro using both native HeLa and in vitro generated Sm proteins. Several RNA‐free, heteromeric protein complexes were identified, including E.F.G, B/B’.D3 and D1.D2.E.F.G. While the E.F.G complex alone did not stably bind to U1 snRNA, these proteins together with D1 and D2 were necessary and sufficient to form a stable U1 snRNP subcore particle. The subcore could be chased into a core particle by the subsequent addition of the B/B’.D3 protein complex even in the presence of free competitor U1 snRNA. Trimethylation of U1 snRNA's 5′ cap, while not observed for the subcore, occurred in the stepwise‐assembled U1 snRNP core particle, providing evidence for the involvement of the B/B′ and D3 proteins in the hypermethylation reaction. Taken together, these results suggest that the various protein heterooligomers, as well as the snRNP subcore particle, are functional intermediates in the snRNP core assembly pathway.

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The Life Span Determinant p66Shc Localizes to Mitochondria Where It Associates with Mitochondrial Heat Shock Protein 70 and Regulates Trans-membrane Potential

Orsini

Migliaccio

Moroni

et al. 2004

Journal of Biological Chemistry

260

237

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P66Shc regulates life span in mammals and is a critical component of the apoptotic response to oxidative stress. It functions as a downstream target of the tumor suppressor p53 and is indispensable for the ability of oxidative stress-activated p53 to induce apoptosis. The molecular mechanisms underlying the apoptogenic effect of p66Shc are unknown. Here we report the following three findings. (i) The apoptosome can be properly activated in vitro in the absence of p66Shc only if purified cytochrome c is supplied. (ii) Cytochrome c release after oxidative signals is impaired in the absence of p66Shc. (iii) p66Shc induces the collapse of the mitochondrial trans-membrane potential after oxidative stress. Furthermore, we showed that a fraction of cytosolic p66Shc localizes within mitochondria where it forms a complex with mitochondrial Hsp70. Treatment of cells with ultraviolet radiation induced the dissociation of this complex and the release of monomeric p66Shc. We propose that p66Shc regulates the mitochondrial pathway of apoptosis by inducing mitochondrial damage after dissociation from an inhibitory protein complex. Genetic and biochemical evidence suggests that mitochondria regulate life span through their effects on the energetic metabolism (mitochondrial theory of aging). Our data suggest that mitochondrial regulation of apoptosis might also contribute to life span determination.

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snRNP Sm proteins share two evolutionarily conserved sequence motifs which are involved in Sm protein-protein interactions.

Hermann¹,

Fabrizio²,

Raker³

et al. 1995

The EMBO Journal

227

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The spliceosomal small nuclear ribonucleoproteins (snRNPs) U1, U2, U4/U6 and U5 share eight proteins B’, B, D1, D2, D3, E, F and G which form the structural core of the snRNPs. This class of common proteins plays an essential role in the biogenesis of the snRNPs. In addition, these proteins represent the major targets for the so‐called anti‐Sm auto‐antibodies which are diagnostic for systemic lupus erythematosus (SLE). We have characterized the proteins F and G from HeLa cells by cDNA cloning, and, thus, all human Sm protein sequences are now available for comparison. Similar to the D, B/B’ and E proteins, the F and G proteins do not possess any of the known RNA binding motifs, suggesting that other types of RNA‐protein interactions occur in the snRNP core. Strikingly, the eight human Sm proteins possess mutual homology in two regions, 32 and 14 amino acids long, that we term Sm motifs 1 and 2. The Sm motifs are evolutionarily highly conserved in all of the putative homologues of the human Sm proteins identified in the data base. These results suggest that the Sm proteins may have arisen from a single common ancestor. Several hypothetical proteins, mainly of plant origin, that clearly contain the conserved Sm motifs but exhibit only comparatively low overall homology to one of the human Sm proteins, were identified in the data base. This suggests that the Sm motifs may also be shared by non‐spliceosomal proteins. Further, we provide experimental evidence that the Sm motifs are involved, at least in part, in Sm protein‐protein interactions. Specifically, we show by co‐immunoprecipitation analyses of in vitro translated B’ and D3 that the Sm motifs are essential for complex formation between B’ and D3. Our finding that the Sm proteins share conserved sequence motifs may help to explain the frequent occurrence in patient sera of anti‐Sm antibodies that cross‐react with multiple Sm proteins and may ultimately further our understanding of how the snRNPs act as auto‐antigens and immunogens in SLE.

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Essential Role for the Tudor Domain of SMN in Spliceosomal U snRNP Assembly: Implications for Spinal Muscular Atrophy

Bühler

Raker²,

Lührmann³

et al. 1999

Human Molecular Genetics

231

226

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Spinal muscular atrophy (SMA) is a neurodegenerative disease of spinal motor neurons caused by reduced levels of functional survival of motor neurons (SMN) protein. SMN is part of a macromolecular complex that contains the SMN-interacting protein 1 (SIP1) and spliceosomal Sm proteins. Although it is clear that SIP1 as a component of this complex is essential for spliceosomal uridine-rich small ribonucleoprotein (U snRNP) assembly, the role of SMN and its functional interactions with SIP1 and Sm proteins are poorly understood. Here we show that the central region of SMN comprising a tudor domain facilitates direct binding to Sm proteins. Strikingly, the SMA-causing missense mutation E134K within the tudor domain severely reduced the ability of SMN to interact with Sm proteins. Moreover, antibodies directed against the tudor domain prevent Sm protein binding to SMN and abolish assembly of U snRNPs in vivo. Thus, our data show that SMN is an essential U snRNP assembly factor and establish a direct correlation between defects in the biogenesis of U snRNPs and SMA.

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Spliceosomal U snRNP Core Assembly: Sm Proteins Assemble onto an Sm Site RNA Nonanucleotide in a Specific and Thermodynamically Stable Manner

Raker

Hartmuth

Kastner

et al. 1999

Molecular and Cellular Biology

133

163

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The association of Sm proteins with U small nuclear RNA (snRNA) requires the single-stranded Sm site (PuAU 4-6 GPu) but also is influenced by nonconserved flanking RNA structural elements. Here we demonstrate that a nonameric Sm site RNA oligonucleotide sufficed for sequence-specific assembly of a minimal core ribonucleoprotein (RNP), which contained all seven Sm proteins. The minimal core RNP displayed several conserved biochemical features of native U snRNP core particles, including a similar morphology in electron micrographs. This minimal system allowed us to study in detail the RNA requirements for Sm protein-Sm site interactions as well as the kinetics of core RNP assembly. In addition to the uridine bases, the 2 hydroxyl moieties were important for stable RNP formation, indicating that both the sugar backbone and the bases are intimately involved in RNA-protein interactions. Moreover, our data imply that an initial phase of core RNP assembly is mediated by a high affinity of the Sm proteins for the single-stranded uridine tract but that the presence of the conserved adenosine (PuAU. . .) is essential to commit the RNP particle to thermodynamic stability. Comparison of intact U4 and U5 snRNAs with the Sm site oligonucleotide in core RNP assembly revealed that the regions flanking the Sm site within the U snRNAs facilitate the kinetics of core RNP assembly by increasing the rate of Sm protein association and by decreasing the activation energy.Small nuclear ribonucleoproteins (snRNPs) mediate essential RNA processing events, including pre-mRNA splicing (reviewed in references 43 and 45). The major spliceosomal snRNP particles consist of snRNA (U1, U2, U4/U6, or U5) and numerous proteins, which can be classified as either snRNP specific or common to each snRNP particle. The common proteins are collectively referred to as Sm proteins and were originally identified due to their antigenicity in the autoimmune disease systemic lupus erythematosus (26). The best characterized of these are the seven HeLa Sm proteins, which are named B/BЈ, D1, D2, D3, E, F, and G and range in size from 241 (for BЈ) to 76 (for G) amino acids (reference 16 and references therein). B and BЈ are alternatively spliced products of the same gene, differing only in 11 amino acids at their C termini (42), and are referred to here as B/BЈ.Association of the Sm proteins with U snRNA plays a pivotal role in the further biogenesis of U snRNP particles. The metabolic stability of the U snRNP particles is dependent on the Sm protein association (10,20,37). Following export from the nucleus, each U snRNA (with the exception of U6) assembles cytoplasmically with a set of Sm proteins, resulting in its core RNP particle. Hypermethylation of the U snRNA 5Ј cap structure from monomethyl guanosine (m 7 G) to trimethylguanosine (m 3 G) is dependent upon formation of the core RNP domain, and in particular requires the presence of the B/BЈ and D3 Sm proteins (30,34,36). These Sm proteins are the last to assemble (36, 38), linking cap hypermethylation to th...

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Veronica A. Raker

Methyltransferase Recruitment and DNA Hypermethylation of Target Promoters by an Oncogenic Transcription Factor

Crystal Structures of Two Sm Protein Complexes and Their Implications for the Assembly of the Spliceosomal snRNPs

A p53-p66Shc signalling pathway controls intracellular redox status, levels of oxidation-damaged DNA and oxidative stress-induced apoptosis

The snRNP core assembly pathway: identification of stable core protein heteromeric complexes and an snRNP subcore particle in vitro.

The Life Span Determinant p66Shc Localizes to Mitochondria Where It Associates with Mitochondrial Heat Shock Protein 70 and Regulates Trans-membrane Potential

snRNP Sm proteins share two evolutionarily conserved sequence motifs which are involved in Sm protein-protein interactions.

Essential Role for the Tudor Domain of SMN in Spliceosomal U snRNP Assembly: Implications for Spinal Muscular Atrophy

Spliceosomal U snRNP Core Assembly: Sm Proteins Assemble onto an Sm Site RNA Nonanucleotide in a Specific and Thermodynamically Stable Manner

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