The secondary structure and poly(A) content of globin messenger RNA as a pure RNA and in polyribosome-derived ribonucleoprotein complexes

E. coli metabolic protein aldehyde-alcohol dehydrogenase-E binds to the ribosome: a unique moonlighting action revealed

It is becoming increasingly evident that a high degree of regulation is involved in the protein synthesis machinery entailing more interacting regulatory factors. A multitude of proteins have been identified recently which show regulatory function upon binding to the ribosome. Here, we identify tight association of a metabolic protein aldehyde-alcohol dehydrogenase E (AdhE) with the E. coli 70S ribosome isolated from cell extract under low salt wash conditions. Cryo-EM reconstruction of the ribosome sample allows us to localize its position on the head of the small subunit, near the mRNA entrance. Our study demonstrates substantial RNA unwinding activity of AdhE which can account for the ability of ribosome to translate through downstream of at least certain mRNA helices. Thus far, in E. coli, no ribosome-associated factor has been identified that shows downstream mRNA helicase activity. Additionally, the cryo-EM map reveals interaction of another extracellular protein, outer membrane protein C (OmpC), with the ribosome at the peripheral solvent side of the 50S subunit. Our result also provides important insight into plausible functional role of OmpC upon ribosome binding. Visualization of the ribosome purified directly from the cell lysate unveils for the first time interactions of additional regulatory proteins with the ribosome.

Dwell-Time Distribution, Long Pausing and Arrest of Single-Ribosome Translation through the mRNA Duplex

Proteins in the cell are synthesized by a ribosome translating the genetic information encoded on the single-stranded messenger RNA (mRNA). It has been shown that the ribosome can also translate through the duplex region of the mRNA by unwinding the duplex. Here, based on our proposed model of the ribosome translation through the mRNA duplex we study theoretically the distribution of dwell times of the ribosome translation through the mRNA duplex under the effect of a pulling force externally applied to the ends of the mRNA to unzip the duplex. We provide quantitative explanations of the available single molecule experimental data on the distribution of dwell times with both short and long durations, on rescuing of the long paused ribosomes by raising the pulling force to unzip the duplex, on translational arrests induced by the mRNA duplex and Shine-Dalgarno(SD)-like sequence in the mRNA. The functional consequences of the pauses or arrests caused by the mRNA duplex and the SD sequence are discussed and compared with those obtained from other types of pausing, such as those induced by "hungry" codons or interactions of specific sequences in the nascent chain with the ribosomal exit tunnel.

A unified model of nucleic acid unwinding by the ribosome and the hexameric and monomeric DNA helicases

DNA helicases are enzymes that use the chemical energy to separate DNA duplex into their single-stranded forms. The ribosome, which catalyzes the translation of messenger RNAs (mRNAs) into proteins, can also unwind mRNA duplex. According to their structures, the DNA helicases can fall broadly into hexameric and monomeric forms. A puzzling issue for the monomeric helicases is that although they have similar structures, in vitro biochemical data showed convincingly that in the monomeric forms some have very weak DNA unwinding activities, some have relatively high unwinding activities while others have high unwinding activities. However, in the dimeric or oligomeric forms all of them have high unwinding activities. In addition, in the monomeric forms all of them can translocate efficiently along the single-stranded DNA (ssDNA). Here, we propose a model of the translocation along the ssDNA and DNA unwinding by the monomeric helicases, providing a consistent explanation of these in vitro experimental data. Moreover, by comparing the present model for the monomeric helicases with the model for the hexameric helicases and that for the ribosome which were proposed before, a unified model of nucleic acid unwinding by the three enzymes is proposed.

Following translation by single ribosomes one codon at a time

We have followed individual ribosomes as they translate single messenger RNA hairpins tethered by the ends to optical tweezers. Here we reveal that translation occurs through successive translocation--and-pause cycles. The distribution of pause lengths, with a median of 2.8 s, indicates that at least two rate-determining processes control each pause. Each translocation step measures three bases--one codon-and occurs in less than 0.1 s. Analysis of the times required for translocation reveals, surprisingly, that there are three substeps in each step. Pause lengths, and thus the overall rate of translation, depend on the secondary structure of the mRNA; the applied force destabilizes secondary structure and decreases pause durations, but does not affect translocation times. Translocation and RNA unwinding are strictly coupled ribosomal functions.

mRNA helicase activity of the ribosome

Most mRNAs contain secondary structure, yet their codons must be in single-stranded form to be translated. Until now, no helicase activity has been identified which could account for the ability of ribosomes to translate through downstream mRNA secondary structure. Using an oligonucleotide displacement assay, together with a stepwise in vitro translation system made up of purified components, we show that ribosomes are able to disrupt downstream helices, including a perfect 27 base pair helix of predicted T(m) = 70 degrees . Using helices of different lengths and registers, the helicase active site can be localized to the middle of the downstream tunnel, between the head and shoulder of the 30S subunit. Mutation of residues in proteins S3 and S4 that line the entry to the tunnel impairs helicase activity. We conclude that the ribosome itself is an mRNA helicase and that proteins S3 and S4 may play a role in its processivity.

An extended RNA/RNA duplex structure within the coding region of mRNA does not block translational elongation

RNA/RNA duplex formation involving the 5'untranslated region of a mRNA can efficiently block translation. Here we investigated the effect on translation of an RNA/RNA duplex between part of the coding region and sequences of the 3'untranslated region of lysozyme mRNA. A cDNA was constructed which contained 2 identical sequences of 150 nucleotides, one of which was an inverted repeat of the other. Cell-free transcription of this cDNA with T7 RNA polymerase resulted in a mRNA with an extended RNA/RNA duplex within the coding region. The presence of the double stranded structure was confirmed by the accessibility of complementary oligonucleotides to this region. mRNA was cleaved by RNaseH, endogenous to the wheat germ lysate, when hybridization of a complementary oligonucleotide occurred outside but not within the predicted double stranded structure. When this mRNA was translated in a cell-free wheat germ translation system, the translation product was found to be of the size of full-length prelysozyme and not arrested. We conclude that the extend of a secondary structure within the coding region of a mRNA does not restrict the ability of the ribosome to translate this mRNA efficiently. Our data are consistent with the presence of an activity unwinding RNA/RNA duplexes, which is associated with the translating ribosome.

Evidence for tertiary structure in natural single stranded RNAs in solution

Binding isotherms (20 degrees C) of ethidium bromide to a number of tRNA species at various ionic strengths indicate that i) the number ni of intercalation sites is high 7 to 11 per molecule, in the low salt form III, but small, 2 to 1, at high Mg2+ or Na+ when form I predominates. ii) modification of tRNA at strategic positions for 3D folding prevents full expression of intercalation restriction iii) maximal restriction is obtained at salt concentrations higher than needed for full conversion to form I. It is inferred that restriction, which is not observed with bihelical RNA (or DNA), requires the native tRNA 3D structure but also some physical coupling between the region of 3D folding and bihelical arms. Ribosomal RNAs, some viral RNAs, mRNA from sheep mammary gland as well as the random copolymers Poly UG, Poly AUG, Poly AUCG all exhibit intercalation restriction. Hence 3D folding of the polyribonucleotide chains appears to be a feature common to single-stranded RNAs when free in solution under physiological conditions.

Use of oligodeoxynucleotide probes for quantitative in situ hybridization to actin mRNA

We have employed an analytical approach for the development of an in situ hybridization methodology using synthetic oligodeoxynucleotide probes for actin messenger RNA detection in cultures of chicken fibroblasts and myoblasts. The methodology developed shows that oligonucleotides can complement the use of nick-translated probes in specific situations. Since they can be made to specific nucleic acid regions independent of restriction enzyme sites, they may be the most convenient approach for analysis of gene families among which sequences are highly conserved. However, it was found that oligonucleotides synthesized to different regions of a messenger RNA behave in situ with differing efficiencies, indicating that not all target sequences are equivalent. Therefore it was necessary to screen several oligonucleotide probes to a target molecule to find the optimal one. The convenience of using synthetic DNA probes makes it worthwhile to explore some of these characteristic properties so as to increase the sensitivity of this approach beyond its application to targets in high abundance.

Hybridization histochemistry

The location of gene expression by hybridization histochemistry is being applied in many areas of research and diagnosis. The aim of this technique is to detect specific mRNA in cells and tissues by hybridization with a complementary DNA or RNA probe. Requirements for optimal specificity, sensitivity, resolution and speed of detection may not all be encompassed in one simple technique suitable for all applications, thus appropriate procedures should be selected for specific objectives. With reference to published procedures and our own extensive experience, we have evaluated fixatives, probes, labels and other aspects of the technique critical to the preservation and hybridization in situ of mRNA and detection and quantitation of hybrids.

Quantitative analysis of in situ hybridization methods for the detection of actin gene expression

We have implemented an efficient, quantitative approach for the optimization of in situ hybridization using double-stranded recombinant DNA probes. The model system studied was actin mRNA expression in chicken embryonic muscle cultures. Actin and control (pBR322) probes were nick-translated with p32 labeled nucleotides, hybridized to cells grown on coverslips, and quantitated in a scintillation counter. Cellular RNA retention was monitored via the incorporation of H3-Uridine into RNA prior to cell fixation. Over a thousand samples were analyzed, and among the technical variables examined were the fixation protocol, proteolytic cell pretreatment, the time course of hybridization, saturation kinetics, hybridization efficiency, and effect of probe size on hybridization and network formation. Results have allowed us to develop a reproducible in situ hybridization methodology which is simpler and less destructive to cellular RNA and morphology than other protocols. Moreover, this technique is highly sensitive and efficient in detection of cellular RNAs. Lastly, the rapid quantitative approach used for this analysis is valuable in itself as a potential alternative to filter or solution hybridizations.

Electron microscopic evidence of circular molecules in 9-S globin mRNA from rabbit reticulocytes

9S globin mRNA prepared by the proteinase K method from polysomes of rabbit reticulocytes consists of 40% circular molecules as revealed by electron microscopy, if spreading of the molecules is performed from a solution of 50% formamide, 0.5 M NaCl, 25 mM Tris, 10 mM EDTA, pH 8, after 16 h incubation at 42 degrees C. We assume a noncovalent nature of the circularization because of the fact that a total transformation into the well known linear form occurs if strong denaturing conditions for spreading were used. The biological significance of the circular globin mRNA molecules is unknown.

Fractionation and characterization of polyadenylated RNA from broad bean meristematic root cells

Several populations of polyadenylated RNA from Vicia faba méristematic root cells were fractionated by stepwise thermal elution from poly(U)-Sepharose following sequential phenol extraction. Analysis of these fractions showed that the size of the poly(A) segment could influence this fractionation, but in some cases other characteristics of the molecule are involved. Evidence was obtained that 45-60% of the nucleotides of plant polyadenylated RNA are in base paired regions, as was previously demonstrated for mammalian mRNA.

Effect of freezing and thawing on the structure of turnip yellow mosaic virus

The uncoating of turnip yellow mosaic virus in vitro induced by freezing and thawing has been investigated using a variety of biochemical techniques including the aminoacylation capacity of the viral RNA and the ability of the RNA to stimulate protein synthesis, as well as physico-chemical techniques such as sucrose gradient centrifugation and electron microscopy by negative staining. In particular a fluorescence test has been developed that can serve as a routine method to quantify the RNA liberated during the freeze-thaw process. Escape of the viral RNA is a highly cooperative phenomenon: it depends critically on the virus concentration during freezing and thawing. Increasing the ionic strength or including foreign proteins diminish the escape of the RNA. The RNA is not damaged by this treatment and its liberation occurs without disruption of the viral capsid.

Ribonucleotide sequences non-adjacent to poly(A) participate in the poly(A)-protein complex in 15S duck globin mRNP particles

The study of the interaction between mRNA and proteins in the polyribosomal 15 S duck globin messenger ribonucleoprotein complex showed that proteins protect specific mRNA sequences against digestion by the nonspecific micrococcal nuclease (Nucleic Acids Research 6 (8) 2787, 1979). Here we report the isolation of the poly(A)-protein RNP complex from nuclease digested 15 S mRNP by two different methods: sucrose gradient sedimentation and oligo(dT)-cellulose chromatography. We show by fingerprint analysis, that aprt from the periodically fragmented poly(A) segment, mRNA sequences adjacent and non-adjacent to the poly(A) segment are protected by the poly(A) binding proteins against nuclease digestion. The duck globin poly(A)-protein RNP complex, with a sedimentation coefficient between 7 S and 10 S, shows a characteristic protein composition, with a major 73,000 MW polypeptide and some minor components. The results are discussed in view of a dynamic ribonucleoprotein structure.

Secondary structure of mouse and rabbit alpha- and beta-globin mRNAs: differential accessibility of alpha and beta initiator AUG codons towards nucleases

The nucleotide sequence from the 5' terminus inward of one third of mouse alpha- and beta maj-globin messenger RNAs has been established. In addition, using 5' 32P end-labeled mRNAs as substrates and S1 and T1 nucleases as probes for single-stranded regions, the secondary structures of mouse and rabbit alpha- and beta-globin mRNAs have been analyzed. Our results indicate that the AUG initiator codon in both mouse and rabbit beta-globin mRNA is quite susceptible to cleavage with S1 and T1 nucleases, suggesting that it resides in a single-stranded exposed region. In contrast, the initiator AUG in the alpha-globin mRNA of both species is inaccessible to cleavage, indicating that it is either buried by tertiary structure or is base-paired. Since the rate of initiation of protein synthesis with beta-globin mRNA in rabbit reticulocyte is 30--40% faster than for alpha-globin mRNA, these results imply a possible correlation between the differential rates of initiation with these two mRNAs and the accessibility of the respective AUG initiator codons.

Secondary structure of MS2 phage RNA and bias in code word usage

Based on the secondary structural model of MS2 RNA, it is shown that, in base-pairing regions of the RNA, there is a bias in the use of synonymous codons which favours C and/or G over U and/or A in the third codon positions, and that in non-pairing regions, there is an opposite bias which favours U and/or A over C and/or G. This nature is interpreted as a result of selective constraint which stabilises the secondary structure of the single-stranded RNA genome of the MS2 phage.

Energy utilization and RNA transport: their interdependence

The interdependence of RNA transport and the metabolism of nucleotide additives was investigated. Rat-liver RNA was radioactively labeled in vivo for 45 min before isolation of liver nuclei, and the concentration dependence of RNA transport on nucleotide additives was determined. In a parrallel investigation, using nucleotide additives labeled in the base moiety, the distributions of label in the tri-, di-, and monophosphate forms were examined after various intervals of incubation. Analysis of results revealed that RNA transport was linearly related to the decline in energy charge of nucleotide additives, whith high statistical correlation. Kinetic analysis of labeled-nucleotide metabolism led to a simple schematic model for pathways for the utilization of high-energy phosphate bonds, and predictions of the scheme were confirmed by studies examining the effects of nucleotide analogues upon RNA transport. Data concerning inhibitors and chelators intimated that multiple avenues of inhibition and stimulation may potentially influence RNA transport. On the basis of previous data and the results presented in this communication, we conclude that nucleocytoplasmic RNA transport is dependent upon high-energy phosphate-bond hydrolysis and that nucleotides do not stimulate RNA transport via a simple chelation mechanism.

Influence of a few coat protein subunits on the base-paired structure of the RNA species of alfalfa mosaic virus

Differentiated thermal melting profiles were made of all the three RNA species (RNAs 1, 2 and 3), constituting the genome of alfalfa mosaic virus and of the subgenomic coat protein messenger RNA (RNA 4) of this virus. Whereas all profiles showed multiphasicity the profile of RNA 4 was most clearly subdivided showing three clear transitions with tm values of 25.5, 35.5 and 53 degrees C. The first transition disappeared upon addition of 6 coat protein molecules per molecule of RNA 4. The effect of coat protein on the melting profiles of the genome RNAs was much less clear.

Electron microscopic studies of purified eukaryote messenger RNA

Rat liver mRNA, hen and rabbit globin messenger RNA (mRNA) were investigated by electron microscopy. No secondary structures were visible in the molecules of these mRNAs under conditions where short secondary structures of other types of RNA, i.e. MS2 phage RNA and 28 S rRNA, were clearly demonstrated. The contour lengths of these mRNAs were also determined by electron microscopy and compared with the sizes estimated by other techniques. The contour lengths of rabbit short and long globin mRNA are 0.1498 +/- 0.0019 and 0.1908 +/- 0.0021 micrometer, respectively. The former is assumed to be globin mRNA for alpha chain and the latter for beta chain. Similarly, hen "alpha" and "beta" globin mRNA have mean lengths of 0.1449 +/- 0.0011 and 0.1891 +/- 0.0017 micrometer, respectively. Hen and rabbit reticulocytes contain 1.8-2.0 times as much mRNA for alpha globin chains as for beta.

Specific hydrolysis of rabbit globin messenger RNA by S1 nuclease

S1 nuclease isolated from Aspergillus oryzae has been used to investigate the secondary structure of rabbit globin messenger RNA (mRNA). The enzyme, which is specific for single stranded nucleotides, digests globin mRNA to a limited extent, with 65-75% of the mRNA nucleotides resistant to digestion under mild conditions. This limited digestion is not due to enzyme inactivation, but rather to the normal activity of the single-strand nuclease. The reaction was studied as a function of temperature, salt and enzyme concentration. Analysis of the products of digestion on 20% acrylamide- 7M urea slab gels reveals a stable pattern of unique fragments ranging in size from 9 to 71 nucleotides. Separated alpha and beta globin mRNAs show similar, but not identical gel patterns, indicating strong structural similarities between the two species. The high degree of nuclease resistance, along with the fragment patterns seen on polyacrylamide gels, gives evidence to support a model of rabbit globin mRNA which contain specific, rather than random, helical structure.

The primary structure of rabbit beta-globin mRNA as determined from cloned DNA

The rabbit beta-globin DNA insertion of the hybrid plasmid PbetaG1 (Maniatis et al., 1976) was sequenced by the method of Maxam and Gilbert (1977). A sequence of 576 nucleotides was determined and verified by pyrimidine tract analysis of double-stranded DNA, synthesized in vitro starting from beta-globin mRNA. The derived sequence is in complete agreement with previously reported partial mRNA sequencing data and with the predictions from the primary structure of the protein. Moreover, the globin DNA insertion is missing only 13 nucleotides corresponding to the 5' terminal sequence of the mRNA. The rabbit beta-globin mRNA consists of a coding region of 438 nucleotides, flanked by a 5' noncoding region of 56 nucleotides (including the initiation codon AUG but not the 7-methyl-guanine of the "cap structure") and by a 3' noncoding region of 95 nucleotides (including a UGA termination codon). The features of the mRNA sequence are discussed with specific attention to the selective use of particular codons, the probable existence extensively base-paired segments at the 5' terminal region and the ribosome binding site. The faithful representation of beta-globin mRNA in the PbetaG1 DNA insertion establishes the validity of used cloned DNA, initially derived from double-stranded DNA transcripts of mRNA, for studying the structure of eucaryotic genes.

Effect of homopolyribonucleotides on messenger ribonucleoprotein particles

A discrete set of polypeptides copurify with and appear to be specifically attached to mRNA from polysomes of eukaryotic cells. This report describes the effect of homopolyribonucleotides on mRNA-protein complexes separated from ribosome subunits by oligo(dT)-cellulose chromatography. It is shown that poly (U) and poly (A) can release mRNA-protein complexes adsorbed to oligo(dT)-cellulose, whereas poly (C) and poly(I) are much less effective in this process. Analysis of polyribonucleotide released material showed that poly(U) effectively dissociated the mRNA-protein complexes while poly(A) caused no or only partial derangement of these particles. The specificities seen in the polyribonucleotide effects in turn suggest a high degree of specificity in the interaction between the proteins and mRNA.

Characterization of mRNA-protein complexes from mammalian cells

In a previous report we described the use of oligo(dT)-cellulose for the isolation of mRNA-protein complexes from EDTA-dissociated polysomes extracted from normally growing or adenovirus infected KB-cells (I). Experiments presented here provide evidence that proteins involved in these complexes bind specifically to mRNA since: a) the proteins and mRNA cosediment through sucrose gradients, b) they adsorb and elute from oligo(dT)-cellulose together, and c) analysis of the products from ribonuclease digestion experiments show that the poly (A) end and a separate small fraction of the mRNA are resistant to the enzymes and attached to protein.

Autodegradation of pre-mRNA containing nuclear ribo-nucleoprotein particles. The effect of autodegradation on the double-stranded RNA sequences and on the protein composition of particles

The quantitative changes of double-stranded RNA components of nuclear ribonucleo-protein particles containing pre-mRNA was investigated in the course of incubation of particles at 37 degrees C. The incubation of purified nuclear particles revealed the fragmentation of long double-stranded RNA sequences into shorter stretches. The presence of nuclear sap in the incubation mixture resulted in degradation of the double-stranded RNAs into acid soluble products. Autodegradation and/or ribonuclease treatment of nuclear RNP particles is accompanied by quantitative changes in the minor protein constituents of informofer.

Globin messenger RNA from anaemic rabbit spleen. Size of its polyadenylate segment

The size of the polyadenylate segment of globin messenger RNA isolated from spleens of anaemic rabbits was estimated by comparison of its electrophoretic migration in polyacrylamide gels to that of synthetic poly(A) segments of known lengths. Conditions of enzymic degradation of mRNA with pancreatic ribonuclease and T1 ribonuclease were carefully established in order to ensure complete degradation of the heteropolymeric part of mRNA without affecting the polyadenylate sequence. The poly (A) segments of spleen globin mRNA were found to be 25-90 nucleotides long whilst those of peripheral blood reticulocytes from the same animals were only 10-30 residues long. Since spleen contains young erythroid cells and since anucleated blood reticulocytes constitute a statistically older population of the same cell line, these results support the idea that the poly(A) segment of mRNA shortens when the message ages.

Molecular-weight determination of animal-cell RNA by electrophoresis in formamide under fully denaturing conditions on exponential polyacrylamide gels

A method for electrophoretic analysis of RNA under fully denaturing conditions on exponential gradient polyacrylamide gels is described. Full denaturation, and strand separation of DNA - RNA hybrids and double-stranded RNA is obtained in dry formamide only if electrophoresis is carried out at 45 degrees and 55 degrees C, respectively. In such conditions, the effects of secondary structure of RNA, important in aqueous medium, are suppressed and a linear correlation is obtained between the logarithm of the molecular weight of an RNA and its final position in the gel over the entire molecular weight range of 10(4) - 10(7). Based on absolute molecular weight standards, obtained from sequenced rRNA of Escherichia coli and tRNA and extrapolating to higher molecular weights the size of animal cell was reexamined. Precursor tRNA from HeLa cells migrates according to a molecular weight of 4.1 x 10(6). Nascent precursor mRNA has molecular weights of up to 5 x 10(6) in the case of duck erythroblasts and of up to 10(7) in HeLa cells. This seems to represent the largest size of non-viral animal-cell RNA molecules.