The yeast Hansenula wingei U3 snoRNA gene contains an intron and its coding sequence co-evolved with the 5' ETS region of the pre-ribosomal RNA.

The 5' external transcribed spacer (ETS) region of the pre-rRNA in Saccharomyces cerevisiae contains a sequence with 10 bp of perfect complementarity to the U3 snoRNA. Base pairing between these sequences has been shown to be required for 18S rRNA synthesis, although interaction over the full 10 bp of complementarity is not required. We have identified the homologous sequence in the 5' ETS from the evolutionarily distant yeast Hansenula wingei; unexpectedly, this shows two sequence changes in the region predicted to base pair to U3. By PCR amplification and direct RNA sequencing, a single type of U3 snoRNA coding sequence was identified in H. wingei. As in the S. cerevisiae U3 snoRNA genes, it is interrupted by an intron with features characteristic of introns spliced in a spliceosome. Consequently, this unusual property is not restricted to the yeast genus Saccharomyces. The introns of the H. wingei and S. cerevisiae U3 genes show strong differences in length and sequence, but are located at the same position in the U3 sequence, immediately upstream of the phylogenetically conserved Box A region. The 3' domains of the H. wingei and S. cerevisiae U3 snoRNAs diverge strongly in primary sequence, but have very similar predicted secondary structures. The 5' domains, expected to play a direct role in pre-ribosomal RNA maturation, are more conserved. The sequence predicted to base pair to the pre-rRNA contains two nucleotide substitutions in H. wingei that restore 10 bp of perfect complementarity to the 5' ETS. This is a strong phylogenetic evidence for the importance of the U3/pre-rRNA interaction.     

Identification and functional analysis of two U3 binding sites on yeast pre-ribosomal RNA.

It has long been known that U3 can be isolated hydrogen bonded to pre-ribosomal RNAs, but the sites of interaction are poorly characterized. Here we show that yeast U3 can be cross-linked to 35S pre-rRNA both in deproteinized extracts and in living cells. The sites of cross-linking were localized to the 5' external transcribed spacer (ETS) and then identified at the nucleotide level. Two regions of U3 near the 5' end are cross-linked to pre-rRNA in vivo and in vitro; the evolutionarily conserved box A region and a 10 nucleotide (nt) sequence with perfect complementarity to an ETS sequence. Two in vivo cross-links are detected in the ETS, at +470, within the region complementary to U3, and at +655, close to the cleavage site at the 5' end of 18S rRNA. A tagged rDNA construct was used to follow the effects of mutations in the ETS in vivo. A small deletion around the +470 cross-linking site in the ETS prevents the synthesis of 18S rRNA. This region is homologous to the site of vertebrate ETS cleavage. We propose that this site may be evolutionarily conserved to direct the assembly of a pre-rRNA processing complex required for the cleavages that generate 18S rRNA.     

The primary and secondary structure of yeast 26S rRNA.

We present the sequence of the 26S rRNA of the yeast Saccharomyces carlsbergensis as inferred from the gene sequence. The molecule is 3393 nucleotides long and consists of 48% G+C; 30 of the 43 methyl groups can be located in the sequence. Starting from the recently proposed structure of E. coli 23S rRNA (see ref. 25) we constructed a secondary structure model for yeast 26S rRNA. This structure is composed of 7 domains closed by long-range base pairings as n the bacterial counterpart. Most domains show considerable conservation of the overall structure; unpaired regions show extended sequence homology and the base-paired regions contain many compensating base pair changes. The extra length of the yeast molecule is due to a number of insertions in most of the domains, particularly in domain II. Domain VI, which is extremely conserved, is probably part of the ribosomal A site. alpha-Sarcin, which apparently inhibits the EF-1 dependent binding of aminoacyl-tRNA, causes a cleavage between position 3025 and 3026 in a conserved loop structure, just outside domain VI. Nearly all of the located methyl groups, like in E. coli, are present in domain II, V and VI and clustered to a certain extent mainly in regions with a strongly conserved primary structure. The only three methyl groups of 26S rRNA which are introduced relatively late during the processing are found in single stranded loops in domain VI very close to positions which have been shown in E. coli 23S rRNA to be at the interface of the ribosome.     

Two distinct recognition signals define the site of endonucleolytic cleavage at the 5''-end of yeast 18S rRNA.

Three of the four eukaryotic ribosomal RNA molecules (18S, 5.8S and 25-28S rRNA) are transcribed as a single precursor, which is subsequently processed into the mature species by a complex series of cleavage and modification reactions. Early cleavage at site A1 generates the mature 5'-end of 18S rRNA. Mutational analyses have identified a number of upstream regions in the 5' external transcribed spacer (5' ETS), including a U3 binding site, which are required in cis for processing at A1. Nothing is known, however, about the requirement for cis-acting elements which define the position of the 5'-end of the 18S rRNA or of any other eukaryotic rRNA. We have introduced mutations around A1 and analyzed them in vivo in a genetic background where the mutant pre-rRNA is the only species synthesized. The results indicate that the mature 5'-end of 18S rRNA in yeast is identified by two partially independent recognition systems, both defining the same cleavage site. One mechanism identifies the site of cleavage at A1 in a sequence-specific manner involving recognition of phylogenetically conserved nucleotides immediately upstream of A1 in the 5' ETS. The second mechanism specifies the 5'-end of 18S rRNA by spacing the A1 cleavage at a fixed distance of 3 nt from the 5' stem-loop/pseudoknot structure located within the mature sequence. The 5' product of the A1 processing reaction can also be identified, showing that, in contrast to yeast 5.8S rRNA, the 5'-end of 18S rRNA is generated by endonucleolytic cleavage.     

DNA sequence and functional analysis of homologous ARS elements of Saccharomyces cerevisiae and S. carlsbergensis.

ARS elements of Saccharomyces cerevisiae are the cis-acting sequences required for the initiation of chromosomal DNA replication. Comparisons of the DNA sequences of unrelated ARS elements from different regions of the genome have revealed no significant DNA sequence conservation. We have compared the sequences of seven pairs of homologous ARS elements from two Saccharomyces species, S. cerevisiae and S. carlsbergensis. In all but one case, the ARS308-ARS308(carl) pair, significant blocks of homology were detected. In the cases of ARS305, ARS307, and ARS309, previously identified functional elements were found to be conserved in their S. carlsbergensis homologs. Mutation of the conserved sequences in the S. carlsbergensis ARS elements revealed that the homologous sequences are required for function. These observations suggested that the sequences important for ARS function would be conserved in other ARS elements. Sequence comparisons aided in the identification of the essential matches to the ARS consensus sequence (ACS) of ARS304, ARS306, and ARS310(carl), though not of ARS310.     

Separate structural elements within internal transcribed spacer 1 of Saccharomyces cerevisiae precursor ribosomal RNA direct the formation of 17S and 26S rRNA.

Structural features of Internal Transcribed Spacer 1 (ITS1) that direct its removal from Saccharomyces cerevisiae pre-rRNA during processing were identified by an initial phylogenetic approach followed by in vivo mutational analysis of specific structural elements. We found that S. cerevisiae ITS1 can functionally be replaced by the corresponding regions from the yeasts Torulaspora delbrueckii, Kluyveromyces lactis and Hansenula wingei, indicating that structural elements required in cis for processing are evolutionarily conserved. Despite large differences in size, all ITS1 regions conform to the secondary structure proposed by Yeh et al. [Biochemistry 29 (1990) 5911-5918], showing five domains (I-V; 5'-->3') of which three harbour an evolutionarily highly conserved element. Removal of most of domain II, including its highly conserved element, did not affect processing. In contrast, highly conserved nucleotides directly downstream of processing site A2 in domain III play a major role in production of 17S, but not 26S rRNA. Domain IV and V are dispensable for 17S rRNA formation although an alternative, albeit inefficient, processing route to mature 17S rRNA may be mediated by a conserved region in domain IV. Each of these two domains is individually sufficient for efficient production of 26S rRNA, suggesting two independent processing pathways. We conclude that ITS1 is organized into two functionally and structurally distinct halves.     

Conservation of ARS elements and chromosomal DNA replication origins on chromosomes III of Saccharomyces cerevisiae and S. carlsbergensis.

DNA replication origins, specified by ARS elements in Saccharomyces cerevisiae, play an essential role in the stable transmission of chromosomes. Little is known about the evolution of ARS elements. We have isolated and characterized ARS elements from a chromosome III recovered from an alloploid Carlsberg brewing yeast that has diverged from its S. cerevisiae homeologue. The positions of seven ARS elements identified in this S. carlsbergensis chromosome are conserved: they are located in intergenic regions flanked by open reading frames homologous to those that flank seven ARS elements of the S. cerevisiae chromosome. The S. carlsbergensis ARS elements were active both in S. cerevisiae and S. monacensis, which has been proposed to be the source of the diverged genome present in brewing yeast. Moreover, their function as chromosomal replication origins correlated strongly with the activity of S. cerevisiae ARS elements, demonstrating the conservation of ARS activity and replication origin function in these two species.