Plant nonsense suppressor tRNA(Tyr) genes are expressed at very low levels in vitro due to inefficient splicing of the intron-containing pre-tRNAs.

Oligonucleotide-directed mutagenesis was used to generate amber, ochre and opal suppressors from cloned Arabidopsis and Nicotiana tRNA(Tyr) genes. The nonsense suppressor tRNA(Tyr) genes were efficiently transcribed in HeLa and yeast nuclear extracts, however, intron excision from all mutant pre-tRNAs(Tyr) was severely impaired in the homologous wheat germ extract as well as in the yeast in vitro splicing system. The change of one nucleotide in the anticodon of suppressor pre-tRNAs leads to a distortion of the potential intron-anticodon interaction. In order to demonstrate that this caused the reduced splicing efficiency, we created a point mutation in the intron of Arabidopsis tRNA(Tyr) which affected the interaction with the wild-type anticodon. As expected, the resulting pre-tRNA was also inefficiently spliced. Another mutation in the intron, which restored the base-pairing between the amber anticodon and the intron of pre-tRNA(Tyr), resulted in an excellent substrate for wheat germ splicing endonuclease. This type of amber suppressor tRNA(Tyr) gene which yields high levels of mature tRNA(Tyr) should be useful for studying suppression in higher plants.     

Structure-function analysis of the trypanosomatid spliced leader RNA.

In trypanosomes, all mRNAs possess a spliced leader (SL) at their 5' end. SL is added to pre-mRNA via trans -splicing from a small RNA, the SL RNA. To examine structure-function aspects of the trypanosomatid SL RNA, an in vivo system was developed in the monogenetic trypanosomatid Leptomonas collosoma to analyze the function of chimeric and site-directed SL RNA mutants in trans -splicing. Stable cell lines expressing chimeric and mutated SL RNA from the authentic SL RNA regulatory unit were obtained. The chimeric RNA was expressed and assembled into an SL RNP particle, but could not serve as a substrate in splicing. Mutations in loop II and III of L.collosoma SL RNA formed the Y structure intermediate. In addition, a double SL RNA mutant in loop II, and positions 7 and 8 of the intron, also formed the Y structure intermediate, suggesting that these intron positions, although proposed to participate in the interaction of SL RNA with U5, may not be crucial for the first step of the trans -splicing reaction. A mutation in the exon located in loop I was not utilized in splicing, suggesting the importance of exon sequences for trans -splicing in trypanosomes. However, a double SL RNA mutant in loop II and exon position 31 was utilized in both steps of splicing; the mutant thus provides a model molecule for further analysis of positions essential for the function of the SL RNA.     

Splicing of Arabidopsis tRNAMet precursors in tobacco cell and wheat germ extracts

Intron-containing tRNA genes are exceptional within nuclear plant genomes. It appears that merely two tRNA gene families coding for tRNA^Tyr _{G A} and elongator tRNA^Met _CmAU contain intervening sequences. We have previously investigated the features required by wheat germ splicing endonuclease for efficient and accurate intron excision from Arabidopsis pre-tRNA^Tyr. Here we have studied the expression of an Arabidopsis elongator tRNA^Met gene in two plant extracts of different origin. This gene was first transcribed either in HeLa or in tobacco cell nuclear extract and splicing of intron-containing tRNA^Met precursors was then examined in wheat germ S23 extract and in the tobacco system. The results show that conversion of pre-tRNA^Met to mature tRNA proceeds very efficiently in both plant extracts. In order to elucidate the potential role of specific nucleotides at the 3 and 5 splice sites and of a structured intron for pre-tRNA^Met splicing in either extract, we have performed a systematic survey by mutational analyses. The results show that cytidine residues at intron-exon boundaries impair pre-tRNA^Met splicing and that a highly structured intron is indispensable for pre-tRNA^Met splicing. tRNA precursors with an extended anticodon stem of three to four base pairs are readily accepted as substrates by wheat and tobacco splicing endonuclease, whereas pre-tRNA molecules that can form an extended anticodon stem of only two putative base pairs are not spliced at all. An amber suppressor, generated from the intron-containing elongator tRNA^Met gene, is efficiently processed and spliced in both plant extracts.     

In vitro genetic analysis of the structural features of the pre-tRNA required for determination of the 3' splice site in the intron excision reaction.

During processing of intron-containing pre-tRNAs, the Xenopus laevis splicing endonuclease binds the precursor and cleaves it at both the 5' and 3' splice sites. In vitro selection was used to determine structural features characteristic of precursor tRNA molecules that are active in this reaction. We performed two types of selection, one for molecules that are not cut, the other for molecules that are cut at only one site. The results shed light on various aspects of the intron excision reaction, including the importance of the three-dimensional structure of the mature domain for recognition and binding of the enzyme, the active role played by the single-stranded region of the intron, and the importance of the cardinal positions which, although not necessarily occupied by the same base in all precursors, nevertheless play a fundamental role in the splicing reaction. A precursor can be cut at the 3' site if a base in the single-stranded loop of the intron is allowed to pair (A-I pair) with the base of the 5' exon situated at the position immediately following the anticodon stem [first cardinal position (CP1)]. The nature of the bases involved in the A-I pair is important, as is the position of the base in the single-stranded loop of the intron. We discuss the role of the cardinal positions in the reaction.     

Mutations in the anticodon stem affect removal of introns from pre-tRNA in Saccharomyces cerevisiae.

To evaluate the role of exon domains in tRNA splicing, the anti-codon stem of proline pre-tRNAUGG from Saccharomyces cerevisiae was altered by site-directed mutagenesis of the suf8 gene. Sixteen alleles were constructed that encode mutant pre-tRNAs containing all possible base combinations in the last base pair of the anticodon stem adjacent to the anticodon loop (positions 31 and 39). The altered pre-tRNAs were screened by using an in vitro endonucleolytic cleavage assay to determine whether perturbations in secondary structure affect the intron excision reaction. The pre-tRNAs were cleaved efficiently whenever secondary structure in the anticodon stem was maintained through standard base pairing or G.U interactions. However, most of the pre-tRNAs with disrupted secondary structure were poor substrates for intron excision. We also determined the extent to which the suf8 alleles produce functional products in vivo. Each allele was integrated in one to three copies into a yeast chromosome or introduced on a high-copy-number plasmid by transformation. The formation of a functional product was assayed by the ability of each allele to suppress the +1 frameshift mutation his4-713 through four-base codon reading, as shown previously for the SUF8-1 suppressor allele. We found that alleles containing any standard base pair or G.U pair at position 31/39 in the anticodon stem failed to suppress his4-713. We could not assess in vivo splicing with these alleles because the tRNA products, even if they are made, would be expected to read a normal triplet rather than a quadruplet codon. However, all of the alleles that contained a disrupted base pair at position 31/ 39 in the anticodon stem altered the structure of the tRNA in a manner that caused frameshift suppression. Suppression indicated that splicing must have occurred to some extent in vivo even though most of the suppression alleles produced pre-tRNAs that were cleaved with low efficiency or not at all in vitro. These results have important implications for the interpretation of in vitro cleavage assays in general and for the potential use of suppressors to select mutations that affects tRNA splicing.     

Splicing of a yeast proline tRNA containing a novel suppressor mutation in the anticodon stem

The intron-containing proline tRNAUGG genes in Saccharomyces cerevisiae can mutate to suppress +1 frameshift mutations in proline codons via a G to U base substitution mutation at position 39. The mutation alters the 3' splice junction and disrupts the bottom base-pair of the anticodon stem which presumably allows the tRNA to read a four-base codon. In order to understand the mechanism of suppression and to study the splicing of suppressor pre-tRNA, we determined the sequences of the mature wild-type and mutant suppressor gene products in vivo and analyzed splicing of the corresponding pre-tRNAs in vitro. We show that a novel tRNA isolated from suppressor strains is the product of frameshift suppressor genes. Sequence analysis indicated that suppressor pre-tRNA is spliced at the same sites as wild-type pre-tRNA. The tRNA therefore contains a four-base anticodon stem and nine-base anticodon loop. Analysis of suppressor pre-tRNA in vitro revealed that endonuclease cleavage at the 3' splice junction occurred with reduced efficiency compared to wild-type. In addition, reduced accumulation of mature suppressor tRNA was observed in a combined cleavage and ligation reaction. These results suggest that cleavage at the 3' splice junction is inefficient but not abolished. The novel tRNA from suppressor strains was shown to be the functional agent of suppression by deleting the intron from a suppressor gene. The tRNA produced in vivo from this gene is identical to that of the product of an intron+ gene, indicating that the intron is not required for proper base modification. The product of the intron- gene is a more efficient suppressor than the product of an intron+ gene. One interpretation of this result is that inefficient splicing in vivo may be limiting the steady-state level of mature suppressor tRNA.     

Spontaneous splicing mutations at the dihydrofolate reductase locus in Chinese hamster ovary cells.

We isolated and characterized three spontaneous mutants of Chinese hamster ovary cells that were deficient in dihydrofolate reductase activity. All three mutants contained no detectable enzyme activity and produced dihydrofolate reductase mRNA species that were shorter than those of the wild type by about 120 bases. Six exons are normally represented in this mRNA; exon 5 was missing in all three mutant mRNAs. Nuclease S1 analysis of the three mutants indicated that during the processing of the mutant RNA, exon 4 was spliced to exon 6. The three mutant genes were cloned, and the regions around exons 4 and 5 were sequenced. In one mutant, the GT dinucleotide at the 5' end of intron 5 had changed to CT. In a second mutant, the first base in exon 5 had changed from G to T. In a revertant of this mutant, this base was further mutated to A, a return to a purine. Approximately 25% of the mRNA molecules in the revertant were spliced correctly to produce an enzyme with one presumed amino acid change. In the third mutant, the AG at the 3' end of intron 4 had changed to AA. A mutation that partially reversed the mutant phenotype had changed the dinucleotide at the 5' end of intron 4 from GT to AT. The splicing pattern in this revertant was consistent with the use of cryptic donor and acceptor splice sites close to the original sites to produce an mRNA with three base changes and a protein with two amino acid changes. These mutations argue against a scanning model for the selection of splice site pairs and suggest that only a single splice site need be inactivated to bring about efficient exon skipping (a regulatory mechanism for some genes). The fact that all three mutants analyzed exhibited exon 5 splicing mutations indicates that these splice sites are hot spots for spontaneous mutation.     

The group II intron ribonucleoprotein precursor is a large, loosely packed structure

Group II self-splicing introns are phylogenetically diverse retroelements that are widely held to be the ancestors of spliceosomal introns and retrotransposons that insert into DNA. Folding of group II intron RNA is often guided by an intron-encoded protein to form a catalytically active ribonucleoprotein (RNP) complex that plays a key role in the activity of the intron. To date, possible structural differences between the intron RNP in its precursor and spliced forms remain unexplored. In this work, we have trapped the native Lactococcus lactis group II intron RNP complex in its precursor form, by deleting the adenosine nucleophile that initiates splicing. Sedimentation velocity, size-exclusion chromatography and cryo-electron microscopy provide the first glimpse of the intron RNP precursor as a large, loosely packed structure. The dimensions contrast with those of compact spliced introns, implying that the RNP undergoes a dramatic conformational change to achieve the catalytically active state.     

A conditional lethal yeast phosphotransferase (tpt1) mutant accumulates tRNAs with a 2'-phosphate and an undermodified base at the splice junction.

tRNA splicing is essential in yeast and humans and presumably all eukaryotes. The first two steps of yeast tRNA splicing, excision of the intron by endonuclease and joining of the exons by tRNA ligase, leave a splice junction bearing a 2'-phosphate. Biochemical analysis suggests that removal of this phosphate in yeast is catalyzed by a highly specific 2'-phosphotransferase that transfers the phosphate to NAD to form ADP-ribose 1"-2" cyclic phosphate. 2'-Phosphotransferase catalytic activity is encoded by a single essential gene, TPT1, in the yeast Saccharomyces cerevisiae. We show here that Tpt1 protein is responsible for the dephosphorylation step of tRNA splicing in vivo because, during nonpermissive growth, conditional lethal tpt1 mutants accumulate 2'-phosphorylated tRNAs from eight different tRNA species that are known to be spliced. We show also that several of these tRNAs are undermodified at the splice junction residue, which is always located at the hypermodified position one base 3' of the anticodon. This result is consistent with previous results indicating that modification of the hypermodified position occurs after intron excision in the tRNA processing pathway, and implies that modification normally follows the dephosphorylation step of tRNA splicing in vivo.     

Intron-dependent formation of pseudouridines in the anticodon of Saccharomyces cerevisiae minor tRNA(Ile).

We have isolated and sequenced the minor species of tRNA(Ile) from Saccharomyces cerevisiae. This tRNA contains two unusual pseudouridines (psi s) in the first and third positions of the anticodon. As shown earlier by others, this tRNA derives from two genes having an identical 60 nt intron. We used in vitro procedures to study the structural requirements for the conversion of the anticodon uridines to psi 34 and psi 36. We show here that psi 34/psi 36 modifications require the presence of the pre-tRNA(Ile) intron but are not dependent upon the particular base at any single position of the anticodon. The conversion of U34 to psi 34 occurs independently from psi 36 synthesis and vice versa. However, psi 34 is not formed when the middle and the third anticodon bases of pre-tRNA(Ile) are both substituted to yield ochre anticodon UUA. This ochre pre-tRNA(Ile) mutant has the central anticodon uridine modified to psi 35 as is the case for S.cerevisiae SUP6 tyrosine-inserting ochre suppressor tRNA. In contrast, neither the first nor the third anticodon pseudouridine is formed, when the ochre (UUA) anticodon in the pre-tRNA(Tyr) is substituted with the isoleucine UAU anticodon. A synthetic mini-substrate consisting of the anticodon stem and loop and the wild-type intron of pre-tRNA(Ile) is sufficient to fully modify the anticodon U34 and U36 into psi s. This is the first example of the tRNA intron sequence, rather than the whole tRNA or pre-tRNA domain, being the main determinant of nucleoside modification.     

Assembly in an in vitro splicing reaction of a mouse insulin messenger RNA precursor into a 60-40S ribonucleoprotein complex.

An SP6/mouse insulin RNA precursor containing two exons and one intron can be spliced in a partially purified nuclear extract isolated from MOPC-315 mouse myeloma cells. We have detected the putative RNA splicing intermediate (intron-3'exon) in a lariat form, the excised intron in a lariat form, and the mRNA spliced product. The in vitro splicing reaction of gel-purified RNA precursors requires ATP and Mg2+ and was accompanied by the formation of a 60-40S ribonucleoprotein complex. The formation of the 60S complex requires ATP. At least two Sm snRNPs containing U1 and U2 RNAs are components of the 60-40S complex. The assemble of those snRNPs occurs early during the splicing reaction and it requires ATP and intron containing pre-mRNAs.     

Identification of the sequences responsible for the splicing phenotype of the regulatory intron of the L1 ribosomal protein gene of Xenopus laevis.

Splicing of the regulated third intron of the L1 ribosomal protein gene of Xenopus laevis has been studied in vivo by oocyte microinjection of wild-type and mutant SP6 precursor RNAs and in vitro in the heterologous HeLa nuclear extract. We show that two different phenomena combine to produce the peculiar splicing phenotype of this intron. One, which can be defined constitutive, shows the same features in the two systems and leads to the accumulation of spliced mRNA, but in very small amounts. The low efficiency of splicing is due to the presence of a noncanonical 5' splice site which acts in conjunction with sequences present in the 3' portion of the intron. The second leads to the massive conversion of the pre-mRNA into site specific truncated molecules. This has the effect of decreasing the concentration of the pre-mRNA available for splicing. We show that this aberrant cleavage activity occurs only in the in vivo oocyte system and depends on the presence of an intact U1 RNA.     

Transfer RNA splicing in Saccharomyces cerevisiae. Secondary and tertiary structures of the substrates

Secondary and tertiary structures of four yeast tRNA precursors that contain introns have been elucidated using limited digestion with a variety of single-strand- and double-strand-specific nucleases. The pre-tRNAs, representing the variety of intron sizes and potential structures, were: pre-tRNALeuCAA, pre-tRNALeuUAG, pre-tRNAIleUAU, and pre-tRNAPro-4UGG. Conventional tRNA cloverleaf structure is maintained in these precursors except that the anticodon loop is interrupted by the intron. The intron contains a sequence which is complementary to a portion of the anticodon loop and allows the formation of a double helix often extending the anticodon stem. The 5' and 3' splicing cleavage sites are located at either end of this helix and are single-stranded. The intron is the most sensitive region to nuclease cleavage, suggesting that it is on the surface of the molecule and available for interaction with the splicing endonuclease. Absence of Mg2+ or spermidine renders the dihydrouridine and T psi C loops of these precursors highly sensitive to nuclease digestion. These ionic effects mimic those observed for tRNAPhe and suggest that the tRNA portion of these precursors has native tRNA structure. We propose consensus secondary and tertiary structures which may be of significance to eventual understanding of the mechanism of yeast tRNA splicing.