Association of messenger ribonucleic acid with 70S monosomes from down-shifted Escherichia coli.

The complexed 70S ribosomes (monosomes) that accumulate in Escherichia coli after an energy source shift-down were examined in an electron microscope. In all cases, the ribosomes lie at or near one end of a ribonucleic acid (RNA) strand. This messenger RNA (mRNA) has a mean length of 168 nm and a length-average length of 200 nm, sufficient to code for polypeptides of a weight-average molecular weight of 20,000. The length distribution indicates that these strands are a reasonable representation of the population of monocistronic mRNA's of E. coli. The mRNA strands disappear entirely upon digestion with pancreatic ribonuclease, phosphodiesterase I, or polynucleotide phosphorylase. The susceptibility to digestion by 3'-exonucleases indicate that the ribosomes lie at the 5' end of the mRNA strands. These results are consistent with the hypothesis that down-shifted cells have a translational defect at a point subsequent to the binding of ribosomes to mRNA but prior to the formation of the first peptide bond, such that ribosomes remain bound at or near their points of initial attachment to mRNA.     

Area of 16S ribonucleic acid at or near the interface between 30S and 50S ribosomes of Escherichia coli.

To determine the region of 16S ribonucleic acid (RNA) at the interface between 30 and 50S ribosomes of Escherichia coli, 30 and 70S ribosomes were treated with T1 ribonuclease (RNase). The accessibility of 16S RNA in the 5' half of the molecule is the same in 30 and 70S ribosomes. The interaction with 50S ribosomes decreases the sensitivity to T1 RNase of an area in the middle of 16S RNA. A large area near the 3' end of 16S RNA is completely protected in 70S ribosomes. The RNA near the 3' end of the molecule and an area of RNA in the middle of the molecule appear to be at the interface between 30 and 50S ribosomes. One site in 16S RNA, 13 to 15 nucleotides from the 3' end, normally inaccessible to T1 RNase in 30S ribosomes, becomes accessible to T1 RNase in 70S ribosomes. This indicates a conformational change at the 3' end of 16S RNA when 30S ribosomes are associated with 50S ribosomes.     

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.     

Specific endonucleolytic cleavage sites for decay of Escherichia coli mRNA

The polycistronic lac mRNA of Escherichia coli contains three messages. The rate of degradation of the second (lacY) message was observed to be equal to that of the third (lacA), and each decayed twice as fast as did the first (lacZ). Specific 5'- and 3'-ended lacY mRNA molecules could be recovered from cells; most likely, they are generated from endonucleolytic cleavages that are a part of the degradative process. They were observed by S1 nuclease mapping, and the exact 5'- and 3'-end oligonucleotides of many of them were identified by direct sequencing. Almost all of the molecules started with a 5' adenosine that would be preceded by a pyrimidine. The specificity was further restricted by neighboring nucleotides, and analysis of the data suggested that 5'-U-U decreases-A-U- is especially vulnerable. Also, computer analyses predicted the most stable secondary structures of selected segments of the mRNA and suggested that cleavages may only occur in regions of single strandedness. A model of mRNA degradation is proposed based on these observations and earlier ones. There is no unique target on a message for the initial inactivating attack: any region free of ribosomes is vulnerable, but for statistical reasons the initial attack of most molecules is near the ribosome-loading site. With no further ribosome loading, the newly unprotected 5' ends are "chopped off" at one of the next preferred target sites almost as fast as the last ribosomes moves down the mRNA.     

Binding of ribosomes to the 5' leader sequence (N = 258) of RNA 3 from alfalfa mosaic virus.

RNA 3 of alfalfa mosaic virus (AlMV) contains information for two genes: near the 5' end an active gene coding for a 35 Kd protein and, near the 3' end, a silent gene coding for viral coat protein. We have determined a sequence of 318 nucleotides which contains the potential initiation codon for the 35 Kd protein at 258 nucleotides from the 5' end. This long leader sequence can form initiation complexes containing three 80 S ribosomes. A shorter species of RNA, corresponding to a molecule of RNA 3 lacking the cap and the first 154 nucleotides (RNA 3') has been isolated. The remaining leader sequence of 104 nucleotides in RNA 3' forms a single 80 S initiation complex with wheat germ ribosomes. The location of the regions of the leader sequence of RNA 3 involved in initiation complex formation with 80 S ribosomes is reported.     

Localization of 5' and 3' ends of the ribosome-bound segment of template polynucleotides by immune electron microscopy

Poly(U) with an average chain length of 40-70 nucleotides was modified at the 5'- or 3'-terminal residues with 2,4-dinitrophenyl derivatives. The modified poly(U) was used to form 30S.poly(U) or 70S.poly(U).Phe-tRNA complexes. Localization of the 5' and 3' ends of the template polynucleotide on the 30S subunit and the 70S ribosome was performed by immune electron microscopy using antibodies against dinitrophenyl haptens. The 5' and 3' ends of poly(U) (putative entry and exit sites of the message) were found in the same region both on the 30S subunit and the 70S ribosome. They were located on the dorsal side of the 30S subunit between the head and the body near the groove bordering the side ledge (platform). Comparison of the size of this region with the possible length of the polynucleotide chain covered by the ribosome allowed us to suggest that the message makes a 'U-turn" (or forms a 'loop') as it passes through the ribosome.     

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.     

Localization of the elongation factor Tu binding site on Escherichia coli ribosomes

Fluorescent techniques were used to study binding of peptide elongation factor Tu (EF-Tu) to Escherichia coli ribosomes and to determine the distances of the bound factor to points on the ribosome. Thermus thermophilus EF-Tu was labeled with 3-(4-maleimidylphenyl)-4-methyl-7-(diethyl-amino)coumarin (CPM) without loss of activity. In the presence of Phe-tRNA and a nonhydrolyzable analogue of GTP, 70S ribosomes bind the CPM-EF-Tu [Kb = (3 +/- 1.2) X 10(6) M-1] causing a decrease of CPM fluorescence. Binding of CPM-EF-Tu to 50S subunits was at least 1 order of magnitude lower than with 70S ribosomes, and binding to 30S subunits could not be detected. Reconstituted 70S ribosomes containing either S1 labeled with fluoresceinmaleimide or ribosomal RNAs labeled at their 3' ends with fluorescein thiosemicarbazide were used for energy transfer from CPM-EF-Tu. The distances between CPM-EF-Tu bound to the ribosomes and the 3' ends of 16S RNA, 5S RNA, 23S RNA, and the closest sulfhydryl group of S1 were calculated to be 82, 70, 73, and 62-68 A, respectively.     

Location of oligo(uridylic acid) sequences within messenger ribonucleic acid molecules of HeLa cells

A significant fraction of the polyadenylated mRNAs of HeLa cells contain an oligo(uridylic acid) [oligo(U)] sequence of 15-30 nucleotides. Several different experimental approaches were used to determine if these oligo(U)'s occupied similar sites within all mRNAs. In one approach, poly(adenylic acid)-containing mRNAs [poly(A+) mRNAs] averaging 2800 nucleotides in length were reduced to an average size of 500 nucleotides by controlled alkaline hydrolysis. Over 20% of the oligo(U)-containing fragments isolated from the hydrolysate retained a poly(A) sequence, showing that oligo(U)'s were not exclusively located near 5' ends of mRNA although 20% were apparently close to 3' ends. To confirm these observations, oligo(U)-containing mRNA [oligo(U+) mRNA] was exposed to the 3'-exonucleolytic activity of polynucleotide phosphorylase to produce fragments containing the 5' regions of mRNA. Each of a set of fragments of decreasing length generated by increased times of exposure of the mRNAs to the enzyme was found to have about the same oligo(U) content, including the shortest that averaged 550 nucleotides. These data not only eliminated an exclusive location for oligo(U) in either 3' or 5' ends of mRNA but also suggested that oligo(U)'s might be close to the 5' ends of some mRNAs. To verify this last observation, periodate-oxidized poly(A+) mRNA was labeled at the 5' caps and at 3'-adenosine residues by sodium [3H]borohydride reduction before it was nicked 3-5 times with alkali to produce 5' and 3' end-labeled pieces that could be separated with oligo(thymidylic acid)-cellulose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Action of Ribonuclease T1 on 30S Ribosomes of Escherichia coli and Its Role in Sequence Studies on 16S Ribonucleic Acid

Two large ribonucleic acid (RNA) fragments have been obtained from T1-RNase-treated 30S ribosomes of Escherichia coli. One fragment, about 475 nucleotides long, contains all the unique oligonucleotides found by Fellner and associates in sections of 16S RNA designated P, E, E', and K, and one-half the large oligonucleotides of section A. The other large fragment is about 300 nucleotides long and contains the oligonucleotides found in sections C, C', C'. The isolation of these large fragments seems to confirm the arrangement of sections within 16S RNA. There are also recovered from nuclease-treated ribosomes three small fragments, one (120 nucleotides long) from the 5' end, one (26 nucleotides long) from the 3' OH end of the chain, and another section (66 nucleotides long) from the middle of the 16S RNA chain. Small molecular weight material is also generated by nuclease treatment, and about half this material is derived from a region close to the 3' OH end of the 16S RNA chain. This indicates that the most accessible part of the rRNA of E. coli 30S ribosomes is a region 100 to 150 nucleotides long near the 3' end of the chain. A general scheme is proposed to explain the generation of the various-sized RNA products from the rRNA of the 30S ribosome.     

Interaction of bovine mitochondrial ribosomes with messenger RNA

The gene for subunit II of cytochrome oxidase (CoII) from bovine mitochondria has been cloned behind a T7 promoter and the corresponding mRNA synthesized in vitro. The RNA transcribed from this vector has a single nucleotide 5' to the start AUG and, thus, corresponds closely to the native mRNA. It binds to the small 28 S ribosomal subunit of bovine mitochondria but not to the large (39 S) subunit or to 55 S ribosomes. The binding occurs readily in the absence of auxiliary initiation factors or initiator tRNA. The complex formed appears to contain 1 mRNA/28 S subunit. The observed binding is specific for mRNA since neither tRNA nor ribosomal RNA can act as competitive inhibitors. The interaction of the mRNA with the 28 S subunit does not require an AUG codon near the 5' end and constructs containing 5' leaders of more than 100 nucleotides still bind efficiently. About 5% of the bound mRNA is protected from digestion by T1 RNase. The protected fragments do not arise from a specific region of the mRNA since they hybridize to several restriction fragments of the cloned CoII gene.     

The nucleotide sequence at the 5'' end of foot and mouth disease virus RNA.

Foot and mouth disease virus RNA has been treated with RNase H in the presence of oligo (dG) specifically to digest the poly(C) tract which lies near the 5' end of the molecule (10). The short (S) fragment containing the 5' end of the RNA was separated from the remainder of the RNA (L fragment) by gel electrophoresis. RNA ligase mediated labelling of the 3' end of S fragment showed that the RNase H digestion gave rise to molecules that differed only in the number of cytidylic acid residues remaining at their 3' ends and did not leave the unique 3' end necessary for fast sequence analysis. As the 5' end of S fragment prepared form virus RNA is blocked by VPg, S fragment was prepared from virus specific messenger RNA which does not contain this protein. This RNA was labelled at the 5' end using polynucleotide kinase and the sequence of 70 nucleotides at the 5' end determined by partial enzyme digestion sequencing on polyacrylamide gels. Some of this sequence was confirmed from an analysis of the oligonucleotides derived by RNase T1 digestion of S fragment. The sequence obtained indicates that there is a stable hairpin loop at the 5' terminus of the RNA before an initiation codon 33 nucleotides from the 5' end. In addition, the RNase T1 analysis suggests that there are short repeated sequences in S fragment and that an eleven nucleotide inverted complementary repeat of a sequence near the 3' end of the RNA is present at the junction of S fragment and the poly(C) tract.     

Distances between 3' ends of ribosomal ribonucleic acids reassembled into Escherichia coli ribosomes

The three ribonucleic acids (RNAs) from Escherichia coli ribosomes were isolated and then labeled at their 3' ends by oxidation with periodate followed by reaction with thiosemicarbazides of fluorescein or eosin. Ribosomal subunits reconstituted with the labeled RNAs were active for polyphenylalanine synthesis. The distances between the 3' ends of the RNAs in 70S ribosomes were estimated by nonradiative energy transfer from fluorescein to eosin. The percentage of energy transfer was calculated from the decrease in fluorescence lifetime of fluorescein in the quenched sample compared to the unquenched sample. Fluorescence lifetime was measured in real time by using a mode-locked laser for excitation and a high-speed electrostatic photomultiplier tube for detection of fluorescence. The distances between fluorophores attached to the 3' ends of 16S RNA and 5S RNA or 23S RNA were estimated to be about 55 and 71 A, respectively. The corresponding distance between the 5S RNA and 23S RNA was too large to be measured reliably with the available probes but was estimated to be greater than 65 A. Comparison of the quantum yields of the labeled RNAs free in solution and reconstituted into ribosomal subunits suggests that the 3' end of 16S RNA does not interact appreciably with other ribosomal components and may be in a relatively exposed position, whereas the 3' ends of the 5S RNA and 23S RNA may be buried in the 70S ribosomal subunit.     

Ribosome stacking defines CGS1 mRNA degradation sites during nascent peptide-mediated translation arrest

Expression of the Arabidopsis CGS1 gene that codes for cystathionine gamma-synthase is feedback-regulated at the step of mRNA degradation in response to S-adenosyl-L-methionine (AdoMet). This regulation occurs during translation and involves AdoMet-induced temporal translation arrest prior to the mRNA degradation. Here, we have identified multiple intermediates of CGS1 mRNA degradation with different 5' ends that are separated by approximately 30 nucleotides. Longer intermediates were found to be produced as the number of ribosomes loaded on mRNA was increased. Sucrose density gradient centrifugation experiments showed that the shortest mRNA degradation intermediate was associated with monosomes, whereas longer degradation intermediates were associated with multiple ribosomes. Immunoblot analyses revealed a ladder of premature polypeptides whose molecular weights corresponded to products of ribosomes in a stalled stack. An increase in smaller premature polypeptides was observed as the number of ribosomes loaded on mRNA increased. These results show that AdoMet induces the stacking of ribosomes on CGS1 mRNA and that multiple mRNA degradation sites probably correspond to each stacked ribosome.     

A fluorescent derivative of ribosomal protein S18 which permits direct observation of messenger RNA binding.

70 S Escherichia coli ribosomes were reacted with the fluorescent dye N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonic acid for 10 min under mild conditions. The resulting ribosomes were fully active. 30 S subunits isolated from these particles were also fully active. They contain approximately 0.7 eq of fluorescent dye. Nearly all of it is attached to protein S18. Competitive reaction with N-ethylmaleimide implies that the fluorescent dye is located at cysteine 10 of the protein. The labeled 30 S particles will recombine with 50 S subunits to form stable 70 S particles. Thus the procedures we have developed allow the large scale preparation of an active fluorescent conjugate of the 70 S ribosome. The fluorescence of the 70 S particles is sensitive to the binding of mRNA, showing both quenching and a shift in emission spectra. Thus it affords a simple way to quantitate mRNA binding directly. In pilot studies without tRNA, the binding constant of the initiation triplet codon adenylyl-(3' leads to 5')-uridylyl-(3' leads to 5')-guanosine to 70 S ribosome was found to be an order of magnitude larger than that of polyuridylic acid.