Methylated nucleosides in polyadenylate-containing yeast messenger ribonucleic acid

Messenger RNA degradation in Saccharomyces cerevisiae

The analysis of 17 functional mRNAs and two recombinant mRNAs in the yeast Saccharomyces cerevisiae suggests that the length of an mRNA influences its half-life in this organism. The mRNAs are clearly divisible into two populations when their lengths and half-lives are compared. Differences in ribosome loading amongst the mRNAs cannot account for this division into relatively stable and unstable populations. Also, specific mRNAs seem to be destabilized to differing extents when their translation is disrupted by N-terminus-proximal stop codons. The analysis of a mutant mRNA, generated by the fusion of the yeast PYK1 and URA3 genes, suggests that a destabilizing element exists within the URA3 sequence. The presence of such elements within relatively unstable mRNAs might account for the division between the yeast mRNA populations. On the basis of these, and other previously published observations, a model is proposed for a general pathway of mRNA degradation in yeast. This model may be relevant to other eukaryotic systems. Also, only a minor extension to the model is required to explain how the stability of some eukaryotic mRNAs might be regulated.

Messenger RNA stability in Saccharomyces cerevisiae: the influence of translation and poly(A) tail length

A comparison between the half-lives of 10 specific yeast mRNAs and their distribution within polysomes (fractionated on sucrose density gradients) was used to test the relationship between mRNA translation and degradation in the eukaryote Saccharomyces cerevisiae. Although the mRNAs vary in their distribution across the same polysome gradients, there is no obvious correlation between the stability of an mRNA and the number of ribosomes it carries in vivo. This suggests that ribosomal protection against nucleolytic attack is not a major factor in determining the stability of an mRNA in yeast. The relative lengths of the poly(A) tails of 9 yeast mRNAs were analysed using thermal elution from poly(U)-Sepharose. No dramatic differences in poly(A) tail length were observed amongst the mRNAs which could account for their wide ranging half-lives. Minor differences were consistent with shortening of the poly(A) tail as an mRNA ages.

The actin gene in yeast Saccharomyces cerevisiae: 5' and 3' end mapping, flanking and putative regulatory sequences

The 5' and 3' flanking regions of the yeast actin gene have been sequenced and the ends of the actin mRNA were determined by the single-strand nuclease mapping procedure. The mRNA starts with a pyrimidine residue 141 (or 140) nucleotides upstream from the initiation codon. The actin gene lacks a typical "TATA" box 30 base pairs upstream from the mRNA start site but it contains a region homologous to the canonical sequence 5'-GGCTCAATCT-3' which is found in several eukaryotic genes 70 to 80 bp upstream from the mRNA cap site. Judging from the S1 nuclease mapping, there are two populations of actin mRNA terminating 98 and 107 nucleotides downstream from the stop codon. The 3' termini are preceded by three AATAAA sequences found in most eukaryotic polyadenylated mRNAs.

The modified nucleotide constituents of human prostatic cancer cell (MA-160) poly(A)-containing RNA

Cytoplasmic poly A(+) RNA from human prostatic cancer cells grown in the presence of 32P was isolated by affinity chromatography on columns of oligo(dT)-cellulose. The RNA was digested with RNAase T2 and the products of digestion were fractionated by two-dimensional electrophoresis. The resulting autoradiograms revealed the presence of many different cap groups as well as two internal modified nucleotide components. 19 different type 1 and type 2 'cap' groups were identified. The internal modified nucleotides were N6-methyl adenosine and a 2'-O-methyl nucleotide possessing an unusual modified base.

Structure of a split yeast gene: complete nucleotide sequence of the actin gene in Saccharomyces cerevisiae

The complete nucleotide sequence of the actin gene from Saccharomyces cerevisiae has been determined. The coding region is interrupted by a 304-base-pair intervening sequence that is located within the triplet coding for amino acid 4. DNA sequences of the intron-exon junctions are similar to those found in higher eukaryotes and can be aligned such that the intron starts with the dinucleotide 5'-G-T-3' and ends with 5'-A-G-3'. Regions fo homology within the sequences upstream from the initiation codon and those following the termination codon have been detected between the yeast iso-1-cytochrome c gene and the actin gene. As deduced from the nucleotide sequence, yeast actin has 374 amino acid residues. Its primary structure, especially the NH2-terminal third of the protein, is highly conserved during evolution.

Methylated blocked 5' terminal sequences of sea urchin embryo messenger RNA classes containing and lacking poly(A)

Sea urchin embryo mRNAs of three distinct classes--histone mRNA, nonhistone mRNA containing poly(A), "[+A] mRNA," and nonhistone mRNA lacking poly(A), "[-A]mRNA"--all contain blocked 5' terminal sequences in which 7-methylguanosine is linked 5'-5' via a triphosphate bridge to a 2'-0-methylated nucleotide. Only one general type of 5' terminal structure, 7mGpppXmpYp, is present. Additional 2'-0-methylation in the Y residue has not been found either in early or late stage embryos. A substantial proportion of the polyribosomal mRNAs in all three classes contain this blocked structure. Whereas both classes of nonhistone mRNAs have internal base methylations, histone mRNAs lack such modifications.

Kinetics of Novikoff cytoplasmic messenger RNA methylation

Methylation patterns of Novikoff cytoplasmic mRNA were determined as a function of labeling time with L-[methyl-3H]methionine. The 5'-terminal m7G could be released from whole mRNA by treatment with nucleotide pyrophosphatase. Subsequent alkaline phosphatase treatment of this mRNA, followed by KOH digestion, yielded N'mpNp and N'mpNp from cap 1 (m7GpppN'mpN) and cap 2 (m7GpppN'mpN''mpN), respectively. Our results indicate that the relative amounts of labeled cap structures do change with time and that the amount of internal N6-methyladenosine decreases, relative to 5'-cap structures, as the cytoplasmic mRNAs age and the average size decreases. The formation of cap-2 structures by the addition of second 2'-O-methyl group at position N''m appears to be cytoplasmic event. Thus, after very short labeling times, greater than 80% of the labeled methyl groups in cap 2 are found in this position. These results, along with earlier data obtained on L-cell heterogeneous nuclear RNA methylation, are consistent with a model in which the nucleus is the cellular site of three mRNA methylation events producing 5'-terminal m7G, the first 2'-O-methylnucleoside (N'm) found in cap-1 structures and internal N6-methyladenosine. Subsequently, these nuclear methylations are followed by the cytoplasmic methylation at N''m. Analysis of the methynucleoside composition of cap-1 structures, along with comparable "core" structures (m7GpppN'm) generated from cap-2 by removal of N''m, indicates that at any single labeling time the methylnucleoside composition of a given cap-1 and the cap-2 "core" structure is remarkably similar. On the other hand, comparisons of the methylnucleoside composition of the cap structures at different labeling times indicate an increase in Cm in the first 2'-O-methylnucleoside (N'm) with time.