Selection of cleavage site by mammalian tRNA 3' processing endoribonuclease

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) removes 3' trailers from pre-tRNAs by cleaving the RNA immediately downstream of the discriminator nucleotide. Although 3' tRNase can recognize and cleave any target RNA that forms a pre-tRNA-like complex with another RNA, in some cases cleavage occurs at multiple sites near the discriminator. We investigated what features of pre-tRNA determine the cleavage site using various pre-tRNAArg variants and purified pig enzyme. Because the T stem-loop and the acceptor stem plus a 3' trailer are sufficient for recognition by 3' tRNase, we constructed variants that had additions and/or deletions of base-pairs in the T stem and/or the acceptor stem. Pre-tRNAs lacking one and two acceptor stem base-pairs were cleaved one and two nucleotides and two and three nucleotides, respectively, downstream of the discriminator. On the other hand, pre-tRNA variants containing extra acceptor stem base-pairs were cleaved only after the discriminator. The cleavage site was shifted to one and two nucleotides downstream of the discriminator by deleting one base-pair from the T stem, but was not changed by additional base-pairs in the T stem. Pre-tRNA variants that contained an eight base-pair acceptor stem plus a six base-pair T stem, an eight base-pair acceptor stem plus a four base-pair T stem, or a six base-pair acceptor stem plus a six base-pair T stem were all cleaved after the original nucleotide. In general, pre-tRNA variants containing a total of more than 11 bp in the acceptor stem and the T stem were cleaved only after the discriminator, and pre-tRNA variants with a total of N bp (N is less than 12) were cleaved 12-N and 13-N nt downstream of the discriminator. Cleavage efficiency of the variants decreased depending on the degree of structural changes from the authentic pre-tRNA. This suggests that the numbers of base-pairs of both the acceptor stem and the T stem are important for recognition and cleavage by 3' tRNase.     

Tri-partite assay for studying exon ligation by the ai5gamma group II intron

Group II introns self-splice via a two-step mechanism: cleavage at the 5' splice site followed by exon ligation at the 3' splice site. The second step has been difficult to study in vitro because it is generally faster than the first. Herein we describe development and partial kinetic characterization of a novel assay for studying the second step in isolation. In this system, a truncated linear intron (nucleotides 1-881) mediates exon ligation between two oligonucleotide substrates: a 19 nt 5' exon and a 3' substrate consisting of the last 6 nucleotides of the intron plus a 6 nucleotide 3' exon. We found that neither the exact structure of domain 6 nor the identity of nucleotides flanking the 3' splice site is critical for accurate 3' splice site choice by the ai5gamma group II intron. The multiple turnover k(cat) (0.14 min(-)(1)) is slower than the single turnover k(obs) (0.6-0.7 min(-)(1)), consistent with rate-limiting product release under steady-state conditions. Decreased single turnover rates at lower pHs were more consistent with loss of catalytic activity than with rate-limiting chemistry. Binding of the 3' substrate (K(m) = 2.6 microM) could be improved by changing a long-range A:U base pair involving the last intronic nucleotide (the gamma-gamma' interaction) to G:C (K(m(3)(')(substrate)) = 1 microM).     

U5 snRNA interacts with exon sequences at 5' and 3' splice sites.

U5 snRNA is an essential pre-mRNA splicing factor whose function remains enigmatic. Specific mutations in a conserved single-stranded loop sequence in yeast U5 snRNA can activate cleavage of G1----A mutant pre-mRNAs at aberrant 5' splice sites and facilitate processing of dead-end lariat intermediates to mRNA. Activation of aberrant 5' cleavage sites involves base pairing between U5 snRNA and nucleotides upstream of the cleavage site. Processing of dead-end lariat intermediates to mRNA correlates with base pairing between U5 and the first two bases in exon 2. The loop sequence in U5 snRNA may therefore by intimately involved in the transesterification reactions at 5' and 3' splice sites. This pattern of interactions is strikingly reminiscent of exon recognition events in group II self-splicing introns and is consistent with the notion that U5 snRNA may be related to a specific functional domain from a group II-like self-splicing ancestral intron.     

In vitro evolution of the hammerhead ribozyme to a purine-specific ribozyme using mutagenic PCR with two nucleotide analogues

The conventional hammerhead ribozyme cleaves RNA 3' to nucleotide triplets with the general formula NUH, where N is any nucleotide, U is uridine and H is any nucleotide except guanosine. In order to isolate hammerhead ribozyme sequences capable of cleaving 3' to the GUG triplet, we performed a mutagenic selection protocol starting with the conventional sequence of an NUH-cleaving ribozyme. The 22 nucleotides in the core and the stem-loop II region were subjected to mutagenic PCR using the two nucleotide analogues 6-(2-deoxy-beta-d-ribofuranosyl)-3,4-dihydro-8H-pyrimido-[4,5-C)][1, 2] oxazin-7-one and of 8-oxo-2'-deoxyguanosine. After five repetitions of the selection cycle, several clones showed cleavage activity. One sequence, having one deletion, showed at least a 90 times higher in trans cleavage rate than the starting ribozyme. It cleaved 3' to GUG and GUA. The sequence of this ribozyme is essentially identical with that obtained previously by selection for AUG cleavage starting with a randomised core and stem-loop II region. This identical result of two independent selection procedures supports the notion that sequences for NUR cleavage, where R is a purine nucleotide, are not compatible with the classical hammerhead structure, and that the sequence space for this cleavage specificity is very limited. The cleavage of NUR triplets is not restricted to the sequence of the substrate that was used for selection but is sequence-independent for in trans cleavage, although the sequence context influences the value for the cleavage rate somewhat. Analysis of cleavage activities indicates the importance of A at position L2.5 in loop II.     

Linearization and transposition of circular molecules of insertion sequence IS3.

IS3 transposase has been shown to promote production of characteristic circular and linear IS3 molecules from the IS3-carrying plasmid; IS3 circles have the entire IS3 sequence with terminal inverted repeats, IRL and IRR, which are separated by a three base-pair sequence originally flanking either end in the parental plasmid, whereas linear IS3 molecules have three nucleotide overhangs at their 5' ends. Here, we showed that a plasmid carrying an IS3 derivative, which is flanked by different sequences at both ends, generated IS3 circles and linear IS3 molecules owing to the action of transposase. Cloning and sequencing analyses of the linear molecules showed that each had the same 5'-protruding three nucleotide overhanging sequences at both ends, suggesting that the linear molecules were not generated from the parental plasmid by the two double-strand breaks at both end regions of IS3. The plasmid carrying IS3 with a two base-pair mutation in the terminal dinucleotide, which would be required for transposase to cleave the 3' end of IS3, could still generate linear molecules as well as circles. Plasmids bearing an IS3 circle were cleaved by transposase and gave linear molecules with the same 5'-protruding three nucleotide overhanging sequences. These show that the linear molecules are generated from IS3 circles via a double-strand break at the three base-pair intervening sequence. Plasmids carrying an IS3 circle with the two base-pair end mutation still were cleaved by transposase, though with reduced efficiencies, suggesting that IS3 transposase has the ability to cleave not only the 3' end of IS3, but a site three nucleotides from the 5' end of IS3. IS3 circles also were shown to transpose to the target plasmids. The end mutation almost completely inhibited this transposition, showing that the terminal dinucleotides are important for the transfer of the 3' end of IS3 to the target as well as for the end cleavage.     

Origin of the phosphate at the ligation junction produced by self-splicing of Tetrahymena thermophila pre-ribosomal RNA

The exons of the self-splicing pre-ribosomal RNA of Tetrahymena thermophila are joined accurately in vitro, even when only 33 nucleotides of the natural 5' exon and 38 nucleotides of the natural 3' exon remain. RNA fingerprint analysis was used to identify the unique ribonuclease T1 oligonucleotide generated by exon ligation. Secondary digests of the ligation junction oligonucleotide with ribonuclease A confirmed the identity of the fragment and demonstrated that the phosphate group that forms the phosphodiester bond at the ligation junction is derived from the 5' position of a uridine nucleotide in the RNA. This observation supports the prediction that the splice junction phosphate is derived from the 3' splice site. These results emphasize the mechanistic similarities of RNA splicing reactions of the group I introns, group II introns and nuclear pre-mRNA introns.     

Group II intron domain 5 facilitates a trans-splicing reaction.

A self-splicing group II intron of yeast mitochondrial DNA (aI5g) was divided within intron domain 4 to yield two RNAs that trans-spliced in vitro with associated trans-branching of excised intron fragments. Reformation of the domain 4 secondary structure was not necessary for the trans reaction, since domain 4 sequences were shown to be dispensable. Instead, the trans reaction depended on a previously unpredicted interaction between intron domain 5, the most highly conserved region of group II introns, and another region of the RNA. Domain 5 was shown to be essential for cleavage at the 5' splice site. It stimulated that cleavage when supplied as a trans-acting RNA containing only 42 nucleotides of intron sequence. The relevance of our findings to in vivo trans-splicing mechanisms is discussed.     

The complete nucleotide sequence of the RNA coding for the primary translation product of foot and mouth disease virus.

The complete nucleotide sequence of the coding region of foot and mouth disease virus RNA (strain A1061) is presented. The sequence extends from the primary initiation site, approximately 1200 nucleotide from the 5' end of the genome, in an open translational reading frame of 6,999 nucleotides to a termination codon 93 nucleotides from the 3' terminal poly (A). Available amino acid sequence data correlates with that predicted from the nucleotide sequence. The amino acid sequence around cleavage sites in the polyprotein shows no consistency, although a number of the virus-coded protease cleavage sites are between glutamate and glycine residues.     

Thermodynamics of unpaired terminal nucleotides on short RNA helixes correlates with stacking at helix termini in larger RNAs.

Free energies for stacking of unpaired nucleotides (dangling ends) at the termini of oligoribonucleotide Watson-Crick helixes (DeltaG(0)37,stack) depend on sequence for 3' ends but are always small for 5' ends. Here, these free energies are correlated with stacking at helix termini in a database of 34 RNA structures determined by X-ray crystallography and NMR spectroscopy. Stacking involving GA pairs is considered separately. A base is categorized as stacked by its distance from (相似文献   

The nucleotide sequence of the chick cytoplasmic beta-actin gene

The nucleotide sequence of the chick beta-actin gene was determined. The gene contains 5 introns; 4 interrupt the translated region at codons 41/42, 120/122, 267, 327/328 and a large intron occurs in the 5' untranslated region. The gene has a 97 nucleotide 5'-untranslated region and a 594 nucleotide 3'-untranslated region. A slight heterogeneity in the position of the poly A addition site exists; polyadenylation can occur at either of two positions two nucleotides apart. The gene codes for an mRNA of 1814 or 1816 nucleotides, excluding the poly(A) tail. In contrast to the chick skeletal muscle actin gene the beta-actin gene lacks the Cys codon between the initiator ATG and the codon for the N-terminal amino acid of the mature protein. In the 5' flanking DNA, 15 nucleotides downstream from the CCAAT sequence, is a tract of 25 nucleotides that is highly homologous to the sequence found in the same region of the rat beta-actin gene.     

Micrococcal nuclease as a DNA structural probe: its recognition sequences, their genomic distribution and correlation with DNA structure determinants

We have analyzed micrococcal nuclease (MNase) DNA cleavage patterns at the sequence level by examining 2.3 X 10(3) base-pairs of data derived from the Drosophila melanogaster 44D larval cuticle locus. Within this region, MNase preferentially cleaved 140 sites. Clusters of these sites appear to generate the preferential MNase eukaryotic DNA cleavage sites seen on agarose gels at roughly 100 to 300 base-pair intervals. These clusters of preferential cleavage sites rarely occur within gene coding regions. The analysis revealed that duplex DNA sequences preferentially cleaved by MNase are generally determined by a single strand sequence: d(A-T)n, where n greater than or equal to 1, flanked by a 5' dC or dG. Cleavage of the other strand is generally staggered 5' by several nucleotides and occurs even if such sequences are absent on that strand. An empirical predictive DNA cleavage model derived from a statistical analysis of the sequence level data was applied to seven eukaryotic gene loci of known sequence. The predicted patterns were in good general agreement with the previously observed eukaryotic gene/spacer cleavage pattern. Statistical analysis also revealed that sites of predicted preferential DNA cleavage occur less frequently in protein coding regions than for randomized sequences of the same length and nucleotide content. Comparison of the MNase cleavage patterns to the sequence-dependent pattern of binding energies between duplex DNA strands indicates that MNase preferentially cleaves sequences with low helix stability.     

Comparative and functional anatomy of group II catalytic introns--a review

The 70 published sequences of group II introns from fungal and plant mitochondria and plant chloroplasts are analyzed for conservation of primary sequence, secondary structure and three-dimensional base pairings. Emphasis is put on structural elements with known or suspected functional significance with respect to self-splicing: the exon-binding and intron-binding sites, the bulging A residue involved in lariat formation, structural domain V and two isolated base pairs, one of them involving the last intron nucleotide and the other one, the first nt of the 3' exon. Separate sections are devoted to the 29 group II-like introns from Euglena chloroplasts and to the possible relationship of catalytic group II introns to nuclear premessenger introns. Alignments of all available sequences of group II introns are provided in the APPENDIX.     

Role of intron-contained sequences in formation of moloney murine leukemia virus env mRNA.

Formation of the Moloney murine leukemia virus envelope mRNA involves the removal of a 5,185-base pair-long intron. Deletion analysis of two Moloney murine leukemia virus-derived expression vectors revealed the existence of two short regions within the viral intron which are required for the efficient formation of the spliced RNA species. One region was present upstream from the 3' splice junction, extended at least 85 nucleotides beyond the splice site, and was not more than 165 nucleotides long. As yeast polymerase II introns, the Moloney murine leukemia virus intron contains the sequence 5'-TACTAAC-3' 15 nucleotides upstream from the 3' splice site. A second region located in the middle of the intron, within a 560-nucleotide-long sequence, was also essential for formation of the spliced RNA species. The efficient splicing of the env mRNA in the absence of expression of viral genes raises the possibility that similar mechanisms are used to remove introns of (some) cellular genes.     

mRNA processing in Dictyostelium: sequence requirements for termination and splicing

Criteria for the identification of termination regions in Dictyostelium discoideum genes have been established and the sequence requirements for termination in 33 genes have been analyzed. A canonical hexamer signal AATAAA was present 15-30 nucleotides upstream of the cleavage site, usually a TA, and was embedded in a particularly A-rich environment. T- or GT-rich downstream elements characteristic of animal cells could not be identified. In a sample of 102 introns we have established the consensus AG/GTAAGT and ATAG/ for the 5' and 3' splice sites, respectively. Most introns are 75-150 nucleotides long and the A+T content is high (90%). A putative branch point was identified in half of the introns 20-60 nucleotides upstream of the 3' splice site and the consensus TACTAAY was derived. A polypyrimidine tract required for branching in vertebrates was not identified, but weak preference for pyrimidine was found 10-45 nucleotides upstream of the 3' splice site.     

The primary structure of the Saccharomyces cerevisiae gene for alcohol dehydrogenase

The DNA sequence of the gene for the fermentative yeast alcohol dehydrogenase has been determined. The structural gene contains no introns. The amino acid sequence of the protein as determined from the nucleotide sequence disagrees with the published alcohol dehydrogenase isozyme I (ADH-I) sequence for 5 of the 347 amino acid residues. At least one, and perhaps as many as four, of these differences is probably due to ADH-I protein heterogeneity in different yeast strains and not to sequencing errors. S1 nuclease was used to map the 5' and 3' ends of the ADH-I mRNA. There are two discrete, mature 5' ends of the mRNA, mapping 27 and 37 nucleotides upstream of the translation initiating ATG. These two equally prevalent termini are 101 and 91 nucleotides, respectively, downstream from a TATAAA sequence. Analysis of the 3' end of ADH-I mRNA disclosed two minor ends upstream of the major poly(A) addition site. These three ends map 24, 67, and 83 nucleotides, respectively, downstream from the translation-terminating TAA triplet. The sequence AA-TAAG is found 28 to 34 nucleotides upstream of each ADH-I mRNA poly(A) addition site. Sequence comparisons of these three 3' ends with those for four other yeast mRNAs yielded a 13-nucleotide consensus sequence to which TAAATAAGA is central. All of the known yeast poly(A) addition sites map at or near the A residue of a CTA site 25 to 40 nucleotides downstream from this consensus octamer.