Johanna M. Avis scite author profile

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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Solution Structure of the N-terminal RNP Domain of U1A Protein: The Role of C-terminal Residues in Structure Stability and RNA Binding

Avis

Allain

Howe

et al. 1996

Journal of Molecular Biology

167

217

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The RNP domain: a sequence-specific RNA-binding domain involved in processing and transport of RNA

Nagai

Oubridge

Ito

et al. 1995

Trends in Biochemical Sciences

210

182

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Crystallization of RNA-protein complexes I. Methods for the large-scale preparation of RNA suitable for crystallographic studies

Price

Ito

Oubridge

et al. 1995

Journal of Molecular Biology

186

126

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In vitro transcription using bacteriophage RNA polymerases and linearised plasmid or oligodeoxynucleotide templates has been used extensively to produce RNA for biochemical studies. This method is, however, not ideal for generating RNA for crystallisation because efficient synthesis requires the RNA to have a purine rich sequence at the 5' terminus, also the subsequent RNA is heterogenous in length. We have developed two methods for the large scale production of homogeneous RNA of virtually any sequence for crystallization. In the first method RNA is transcribed together with two flanking intramolecularly-, (cis-), acting ribozymes which excise the desired RNA sequence from the primary transcript, eliminating the promoter sequence and heterogeneous 3' end generated by run-off transcription. We use a combination of two hammerhead ribozymes or a hammerhead and a hairpin ribozyme. The RNA-enzyme activity generates few sequence restrictions at the 3' terminus and none at the 5' terminus, a considerable improvement on current methodologies. In the second method the BsmAI restriction endonuclease is used to linearize plasmid template DNA thereby allowing the generation of RNA with any 3' end. In combination with a 5' cis-acting hammerhead ribozyme any sequence of RNA may be generated by in vitro transcription. This has proven to be extremely useful for the synthesis of short RNAs.

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General plasmids for producing RNA in vitro transcripts with homogeneous ends

Walker

Avis

Conn

2003

Nucleic Acids Research

112

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In vitro transcripts of bacteriophage RNA polymerases (RNAPs), such as T7 RNAP, often suffer from a considerable degree of 3'-end heterogeneity and, with certain promoter sequences, 5'-end heterogeneity. For some applications, this transcript heterogeneity poses a significant problem. A potential solution is to incorporate ribozymes into the transcripts at the 5'- and/or 3'-end of the target RNA sequence. This approach has been used quite widely but has required the generation of new transcription vectors or PCR-derived templates for each new RNA to be studied. To overcome this limitation, we have created two general plasmids for producing homogeneous RNA transcripts: one encodes a 3'- hepatitis delta virus (HDV) ribozyme and the other, used in combination with a two-step PCR, allows the production of double [5'-hammerhead (HH) and 3'-HDV] ribozyme constructs. A choice of cloning and run-off transcription linearisation restriction enzyme sites ensures that virtually any RNA sequence can be cloned and transcribed from these plasmids. For all the RNA sequences tested, good yields of transcript were obtained. These plasmids provide the tools for the simple, rapid creation of new RNA-coding plasmids to produce milligram quantities of homogeneous in vitro transcripts for all applications.

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Johanna M. Avis

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

Solution Structure of the N-terminal RNP Domain of U1A Protein: The Role of C-terminal Residues in Structure Stability and RNA Binding

The RNP domain: a sequence-specific RNA-binding domain involved in processing and transport of RNA

Crystallization of RNA-protein complexes I. Methods for the large-scale preparation of RNA suitable for crystallographic studies

General plasmids for producing RNA in vitro transcripts with homogeneous ends

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