ATP can be dispensable for prespliceosome formation in yeast.

The first ATP-dependent step in pre-mRNA splicing involves the stable binding of U2 snRNP to form the prespliceosome. We show that a prespliceosome-like complex forms in the absence of ATP in yeast extracts lacking the U2 suppressor protein CUS2. These complexes display the same pre-mRNA and U snRNA requirements as authentic prespliceosomes and can be chased through the splicing pathway, indicating that they are a functional intermediate in the spliceosome assembly pathway. ATP-independent prespliceosome-like complexes are also observed in extracts containing a mutant U2 snRNA. Loss of CUS2 does not bypass the role of PRP5, an RNA helicase family member required for ATP-dependent prespliceosome formation. Genetic interactions between CUS2 and a heat-sensitive prp5 allele parallel those observed between CUS2 and U2, and suggest that CUS2 mediates functional interactions between U2 RNA and PRP5. We propose that CUS2 enforces ATP dependence during formation of the prespliceosome by brokering an interaction between PRP5 and the U2 snRNP that depends on correct U2 RNA structure.

Circular mRNA can direct translation of extremely long repeating-sequence proteins in vivo.

Many proteins with unusual structural properties are comprised of multiple repeating amino acid sequences and are often fractious to expression in recombinant systems. To facilitate recombinant production of such proteins for structural and engineering studies, we have produced circular messenger RNAs with infinite open reading frames. We show that a circular mRNA containing a simple green fluorescent protein (GFP) open reading frame can direct GFP expression in Escherichia coli. A circular mRNA with an infinite GFP open reading frame produces extremely long protein chains, proving that bacterial ribosomes can internally initiate and repeatedly transit a circular mRNA. Only the monomeric forms of GFP produced from circular mRNA are fluorescent. Analysis of the translation initiation region shows that multiple sequences contribute to maximal translation from circular mRNA. This technology provides a unique means of producing a very long repeating-sequence protein, and may open the way for development of proteinaceous materials with novel properties.

CUS2, a yeast homolog of human Tat-SF1, rescues function of misfolded U2 through an unusual RNA recognition motif.

A screen for suppressors of a U2 snRNA mutation identified CUS2, an atypical member of the RNA recognition motif (RRM) family of RNA binding proteins. CUS2 protein is associated with U2 RNA in splicing extracts and interacts with PRP11, a subunit of the conserved splicing factor SF3a. Absence of CUS2 renders certain U2 RNA folding mutants lethal, arguing that a normal activity of CUS2 is to help refold U2 into a structure favorable for its binding to SF3b and SF3a prior to spliceosome assembly. Both CUS2 function in vivo and the in vitro RNA binding activity of CUS2 are disrupted by mutation of the first RRM, suggesting that rescue of misfolded U2 involves the direct binding of CUS2. Human Tat-SF1, reported to stimulate Tat-specific, transactivating region-dependent human immunodeficiency virus transcription in vitro, is structurally similar to CUS2. Anti-Tat-SF1 antibodies coimmunoprecipitate SF3a66 (SAP62), the human homolog of PRP11, suggesting that Tat-SF1 has a parallel function in splicing in human cells.

Conservation of structure and subunit interactions in yeast homologues of splicing factor 3b (SF3b) subunits.

Human SAP 49, a subunit of the multimeric splicing factor 3b (SF3b), contains two RNA recognition motifs (RRMs) and binds another SF3b subunit called SAP 145, whose yeast homologue is CUS1. Here we show that the predicted yeast open reading frame YOR319w (HSH49) encodes an essential yeast splicing factor. Using bacterially expressed proteins, we find that yeast HSH49 binds CUS1. Mutations that alter putative RNA-binding residues of either HSH49 RRM are lethal in vivo, but do not prevent binding to CUS1 in vitro, suggesting that the predicted RNA-binding surfaces of HSH49 are not required for interaction with CUS1. In vivo interaction tests show that HSH49 and CUS1 associate primarily through the N-terminal RRM of HSH49. Recombinant HSH49 protein has a general RNA-binding activity that does not require CUS1. The parallels in structure and interaction between two SF3b subunits from yeast implies that the mechanism of SF3b action is highly conserved.

Effective ribozyme delivery in plant cells.

Hammerhead ribozyme sequences were incorporated into a tyrosine tRNA (tRNA(Tyr)) and compared with nonembedded molecules. To increase the levels of ribozyme and control antisense in vivo, sequences were expressed from an autonomously replicating vector derived from African cassava mosaic geminivirus. In vitro, the nonembedded ribozyme cleaved more target RNA, encoding chloramphenicol acetyltransferase (CAT), than the tRNA(Tyr) ribozyme. In contrast, the tRNA(Tyr) ribozyme was considerably more effective in vivo than either the nonembedded ribozyme or antisense sequences, reducing CAT activity to < 20% of the control level. A target sequence (CM2), mutated to be noncleavable, showed no reduction in CAT activity in the presence of the tRNA(Tyr) ribozyme beyond that for the antisense construct. The reduction in full-length CAT mRNA and the presence of specific cleavage products demonstrated in vivo cleavage of the target mRNA by the tRNA(Tyr) ribozyme. The high titer of tRNA(Tyr) ribozyme was a result of transcription from the RNA polymerase III promoter and led to the high ribozyme/substrate ratio essential for ribozyme efficiency.

A ribozyme that enhances gene suppression in tobacco protoplasts.

Site-directed mutagenesis has been used to produce two hammerhead ribozyme molecules targeting the chloramphenicol acetyltransferase gene (CAT). One ribozyme has a single catalytic domain between two 12-nucleotide arms that can hybridize 5' and 3' of the GUC target site of the CAT RNA transcript. The second ribozyme is a full-length antisense RNA with four catalytic domains inserted along the length, each targeting a specific GUC site within the CAT mRNA. Our results show that both ribozymes can produce almost equivalent rates of cleavage of the CAT mRNA in vitro (T1/2 of 18 or 15 min, respectively). In tobacco protoplasts we show consistently greater gene suppression in the presence of the long ribozyme molecule, compared with the equivalent antisense (22% gene reduction for antisense compared with 44% with the long ribozyme). These results suggest that hammerhead ribozymes may be developed for the inactivation of gene activity in plant cells.

Extended target-site specificity for a hammerhead ribozyme.

In vitro mutagenesis has been used to systematically mutate the GUC target site cleaved by a synthetic ribozyme based on the catalytic domain of the satellite RNA of tobacco ringspot virus. Amongst the spectrum of changes, it is found that GUC, UUC, CUC, GUA and GUU targets show equivalent rates of cleavage. An AUC target does not cleave, in contrast to observations from other studies. For a GUG target site, the normal ribozyme cannot induce cleavage, but an alteration of the stem-loop in the catalytic domain leads to the formation of a weakly active ribozyme. Certain double mutations, not previously studied, showed slow but discernable cleavage. This mutational approach shows that general rules for cleavage at NUY triplets for the target site of hammerhead ribozymes should be modified. Not all NUY targets cleave under all circumstances, and there are some targets with nucleotides other than U in the centre position which show significant, discernable cleavage.