The psu1+ amber suppressor gene of bacteriophage T4: identification of its amino acid and transfer RNA

Previous work identified the psu⁺₁ amber suppressor gene of bacteriophage T4. Analysis of protein arising from suppression now shows that psu⁺₁ specifies the insertion of serine in response to the amber triplet. The efficiency of suppression is 70%.The psu₁⁺ gene affects a serine transfer RNA coded by bacteriophage T4. Comparative ribonuclease T₁ fingerprint analysis of the serine transfer RNAs made by wild type T4 and psu⁺₁ strains shows a specific alteration in the patterns, presumably reflecting a mutational alteration in the anticodon of the transfer RNA. Mutations which result in the loss of suppressor activity define two genes: one is apparently the structural gene for the serine transfer RNA; the function of the second gene, M1, is less clear. Mutational inactivation of either gene prevents the appearance of the serine transfer RNA and a second transfer RNA, which has not yet been associated with its cognate amino acid. M1 mutants are also deficient in the production of several additional transfer RNA species, as well as several larger RNAs. The significance of these results in relation to transfer RNA biosynthesis is discussed.     

Amine-catalyzed elimination of beta-phosphoric esters from aldehydes derived from ribonucleic acid and model substrates.

The kinetics have been measured for several steps of the diamine-catalyzed elimination of the terminal nucleoside from periodate-oxidized RNA and from several model substrates. The general-acid-catalyzed, rate-determining step has a k_HA of 0.13 M^?1 min^?1 (HA = RNH₃⁺) for primary amines, and the specific-base-catalyzed reaction has a k_HH of 0.35 min^?1 (0.2 mm RNA) with ornithine catalysis and a k_HH of 0.077 min^? (0.2 mm RNA) with lysine catalysis. Lysine has a third catalysis component, with a k_AH of 12 min^?1 M^?2. The diamino acid α,γ-diaminobutyrate is not effective as a catalyst, due to cyclic gem diamine formation. Substituents on the 5′-phosphoric ester group do not affect the kinetics unless the substituent is a proton (e.g., as in AMP); thus, AMP is not an accurate model for this type of sequential degradation of RNA.There are two degradative pathways, the β-elimination path and a route that involves cleavage of the C-1′-0-C-4′ ether linkage before the phosphoric ester is eliminated. The direct β-elimination path predominates below pH 7.5, with a maximum near pH 6, and yields only one set of end products. Because of its rapid and predictable course, the latter reaction is preferred for sequential degradation of RNA. The structure of the catalytically active intermediate (general-acid-catalyzed reaction series) involves the primary amino group of ornithine (lysine) condensed with the dialdehyde terminus to form the carbinolamine, aldimine, and enamine intermediates leading to the elimination.The ether cleavage path is controlled by a specific-base (k_HB) intramolecular catalysis above pH 7, and a side reaction leads to lowered yields of phosphoric ester cleavage. A primary amine group is required, since 3-dimethylamino propylamine does not catalyze the ether cleavage.     

Purification and characterization of two tyrosyl-tRNA synthetase activities from soybean cotyledons

The tyrosyl-tRNA synthetases located in cytoplasm and chloroplasts of soybean cotyledons were purified to near homogeneity by ammonium sulfate precipitation, DEAE-cellulose chromatography, hydroxylapatite chromatography, and DEAE-Sephadex A-25 chromatography. Purified cytoplasmic tyrosyl-tRNA synthetase shows only a single band in acrylamide gel electrophoresis which corresponds to a MW of 126000. In SDS-acrylamide gel electrophoresis the enzyme again shows only a single band which corresponds to a MW of 61 000. Chloroplast tyrosyl-tRNA synthetase shows only one band in both acrylamide and SDS-acrylamide gel electrophoresis with MWs being 98 000 and 43 000, respectively. For cytoplasmic tyrosyl-tRNA synthetase the apparent K_ms determined are 6.8 μM L-tyrosine, 49 μM ATP, and 8.9 × 10^?8 M tRNA (as total tRNA). Apparent K_ms for chloroplast tyrosyl-tRNA synthetase are 4.9 μM L-tyrosine, 214 μM ATP and 2.2 × 10^?8 M tRNA (as BDC-ethanol fraction tRNA). Fractionation of soybean cotyledon-tRNA on RPC-5 columns gives 4 tyrosyl-tRNA species, the first two species (tRNA_{1 and 2}^Tyr) are acylated only by cytoplasmic tyrosyl-tRNA synthetase while the last two species (tRNA_{3 and 4}^Tyr) are acylated only by chloroplast tyrosyl-tRNA synthetase.     

Relative stabilities of RNA/DNA hybrids: effect of RNA chain length in competitive hybrization

Escherichia coli DNA and fragmented rRNA were used as a model system to study the effect of RNA fragment size in hybridization-competition experiments. Though no difference in hybridization rates was observed, the relative stabilities of the RNA/DNA hybrids were found to be largely affected by the fragment size of the RNA molecule. Intact rRNA was shown to replace shorter homologous rRNA sequences in their hybrids, the rate of the displacement being dependent on the molecular size of the RNA fragments. Hybridization-competition experiments between molecules of different lengths are expected to be complicated by the displacement reaction. The synthesis of tRNA^Tyr-like sequences transcribed in vitro on φ80psu₃⁺ bacteriophage DNA was measured by hybridization competition assays. Indirect competition with labelled E. coli tRNA^Tyr hybridization revealed that the in vitro-synthesized RNA contained significant amounts of tRNA^Tyr; these sequences could not, however, be detected by the direct competition method in which labelled in vitro-synthesized RNA competes with E. coli tRNA^Tyr for hybridization to φ80psu₃⁺ DNA. These contradictory results can be traced to the differences in size of the competing molecules in the hybridization-competition reaction. Indeed, in vitro-transcribed tRNA^Tyr-like sequences, longer than mature tRNA, were found to displace efficiently E. coli tRNA^Tyr from its hybrids with φ80psu₃⁺ DNA. These findings explain why such sequences could not be detected by direct competition with E. coli tRNA^Tyr.     

Application of the Deoxyribonucleic Acid/Ribonucleic Acid Hybridization Technique in Bdellovibrio as a Model for Studying Ribonucleic Acid Turnover in Host-Parasite Systems

The kinetics of host ribonucleic acid (RNA) degradation and its resynthesis into Bdellovibrio-specific polyribonucleotides has been studied. The kinetics of RNA turnover was followed during a one-step synchronous growth cycle of Bdellovibrio growing within ³²PO₄-labeled Escherichia coli host cells. The species of labeled RNA present at any given time was ascertained through the specificity of the deoxyribonucleic acid (DNA)/RNA hybridization technique. At nearsaturating levels of RNA and at zero time, 7% of the host DNA sequences and only 0.04% of the Bdellovibrio DNA became hybridized with ³²P-labeled host cell RNA (greater than 99% host specific). At the end of the burst, 98% of the labeled RNA sequences were specific for Bdellovibrio DNA. About 74% of the initial labeled host cell RNA became turned over into Bdellovibrio-specific sequences. We provide data indicating that host cell ribosomal RNA is assimilated by Bdellovibrio. Degradation of host cell RNA occurs in a gradual fashion over most of the Bdellovibrio developmental growth cycle. This application of the DNA/RNA hybridization technique and its general concept should be of value in elucidating the kinetics of nucleic acid turnover in other types of host-parasite systems.     

Mg2+-induced conformational changes in the btuB riboswitch from E. coli

Mg²⁺ has been shown to modulate the function of riboswitches by facilitating the ligand-riboswitch interactions. The btuB riboswitch from Escherichia coli undergoes a conformational change upon binding to its ligand, coenzyme B₁₂ (adenosyl-cobalamine, AdoCbl), and down-regulates the expression of the B₁₂ transporter protein BtuB in order to control the cellular levels of AdoCbl. Here, we discuss the structural folding attained by the btuB riboswitch from E. coli in response to Mg²⁺ and how it affects the ligand binding competent conformation of the RNA. The btuB riboswitch notably adopts different conformational states depending upon the concentration of Mg²⁺. With the help of in-line probing, we show the existence of at least two specific conformations, one being achieved in the complete absence of Mg²⁺ (or low Mg²⁺ concentration) and the other appearing above ∼0.5 mM Mg²⁺. Distinct regions of the riboswitch exhibit different dissociation constants toward Mg²⁺, indicating a stepwise folding of the btuB RNA. Increasing the Mg²⁺ concentration drives the transition from one conformation toward the other. The conformational state existing above 0.5 mM Mg²⁺ defines the binding competent conformation of the btuB riboswitch which can productively interact with the ligand, coenzyme B₁₂, and switch the RNA conformation. Moreover, raising the Mg²⁺ concentration enhances the ratio of switched RNA in the presence of AdoCbl. The lack of a AdoCbl-induced conformational switch experienced by the btuB riboswitch in the absence of Mg²⁺ indicates a crucial role played by Mg²⁺ for defining an active conformation of the riboswitch.     

Differential accumulation of two size classes of poly(A) associated with messenger RNA during oogenesis in Xenopus laevis

The RNA of full-grown oocytes of Xenopus laevis contains two distinct size classes of poly(A), designated poly(A)_S and poly(A)_L, which contain 15–30 (mean = 20) and 40–80 (mean = 61) A residues, respectively. Both poly(A)_L and poly(A)_S are associated with RNA which is heterogeneous in size. The two classes of poly(A)⁺ RNA can be separated by affinity chromatography: Only poly(A)_L⁺ RNA binds to oligo(dT)-cellulose under appropriate conditions, but up to 50% of the poly(A)_S⁺ RNA can be isolated from the void fraction by binding to poly(U)-Sepharose. Both classes of poly(A)⁺ RNA are active as messenger RNA in an in vitro system and yield identical patterns of in vitro protein products. Previtellogenic oocytes contain almost exclusively poly(A)_L, which accumulates up to vitellogenesis but remains almost constant in amount (molecules/oocyte) during vitellogenesis and in the full-grown oocyte. Poly(A)_S accumulates (molecules/oocyte) from early vitellogenesis up to the full-grown oocyte. The total number of poly(A)⁺ RNA molecules per oocyte increases throughout oogenesis from 2 × 10¹⁰/previtellogenic oocyte [80–90% poly(A)_L] to 20 × 10¹⁰/full-grown oocyte (25–40% poly(A)_L). It is argued that poly(A)_S is protected from degradation in the oocyte, thus stabilizing the “maternal” poly(A)⁺ mRNA.     

Structural features unique to the 5 S ribosomal RNAs of the thermophilic cyanobacterium Synechococcus lividus III and the green plant chloroplasts

The complete nucleotide sequence of the 5 S ribosomal RNA from the thermophilic cyanobacterium Synechococcus lividus III was determined. The sequence is: ^5′U-C- C-U-G-G-U-G-G-U-G-A-U-G-G-C-G-A-U-G-U-G-G-A-C-C-C-A-C-A-C-U-C-A-U-C- C-A-U-C-C-C-G-A-A-C-U-G-A-G-U-G-G-U-G-A-A-A-C-G-C-A-U-U-U-G-C-G-G-C- G-A-C-G-A-U-A-G-U-U-G-G-A-G-G-G-U-A-G-C-C-U-C-C-U-G-U-C-A-A-A-A-U-A- G-C-U-A-A-C-C-G-C-C-A-G-G-G-U_OH^3′This 5 S RNA has regional structural characteristics that are found in the green plant chloroplast 5 S RNAs and not in other known sequences of 5 S ribosomal RNAs. These homologies suggest a close phylogenetic relationship between S. lividus and the green plant chloroplasts.     

Effect of 5-fluoroorotic acid administration of the 32 P base composition, DNA-RNA hybridization properties, and labeling of polyadenylate-rich RNA in the cytoplasm of rat liver cells

5-Fluoroorotic acid treatment lowered the (Guanine + Cytosine)/(Adenine + Uracil) base ratio of ³²P-labeled microsomal RNA from a control value of 1.36 to 1.00. Low doses of actinomycin D, which are effective in inhibiting ribosomal RNA synthesis without significantly affecting messenger RNA synthesis, caused a similar decrease in the base ratio. Microsomal RNA labeled by [³H]orotate in the presence of 5-fluoroorotic acid had approximately $\text{1}\text{2}$ the specific radioactivity but twice the hybridization efficiency of RNA labeled in its absence. Evidence is presented that this RNA (1) has a different structure from that of ribosomal RNA, (2) hybridizes to DNA with an efficiency consistent with that of other published studies of polysome-associated messenger RNA, and (3) possesses sequences which are present in other samples of liver microsomal RNA but not in kidney microsomal RNA. These properties differ from those known to be exhibited by 18 S and 28 S ribosomal RNA. Electrophoretic analysis of this [³H]orotate-labeled microsomal RNA indicated that the analogue greatly inhibited precursor incorporation into ribosomal RNA but had little or no effect on incorporation into messenger RNA. Ribosomal RNA and polyadenylate-rich nonribosomal RNA were prepared from total polyribosomes by phenol extraction at pH 7.6 and pH 9.0, respectively. 5-Fluoroorotic acid inhibited [³H]orotate or ³²P_i incorporation into the pH 7.6 fraction much more effectively than incorporation into the pH 9.0 fraction. A subfraction of the pH 9.0 RNA which was retained by a polythymidylate-cellulose column had a greatly increased adenylate content.     

Occurrence of heat-dissociable ribosomal RNA in insects: the presence of three polynucleotide chains in 26 S RNA from cultured Aedes aegypti cells

When RNA extracted from a mixture of cultured mosquito (Aedes aegypti) and hamster (BHK) cells is heated at 60 °C for five minutes the 26 S mosquito RNA but not the 28 S BHK RNA is converted to 18 S products. These products are not separable from each other or from pre-existent 18 S RNA on 2.4% acrylamide gels and have molecular weights near 0.7 × 10⁶. The large ribosomal RNA from insects belonging to ten different orders shows a similar conversion, although this property is absent in two species of aphid.A. aegypti 26 S RNA dissociates over a narrow temperature range. The reaction equilibrium favours dissociation and is dependent on ionic strength, showing a 6 deg. C change in T_m′ (the temperature of 50% dissociation) with tenfold change in salt concentration. Although the T_m of 26 S RNA from Drosophila melanogaster and A. aegypti is markedly different, reflecting the difference in base composition, the T_m′ of the two RNA species was virtually the same.High molecular weight ribosomal RNA from Escherichia coli, BHK cells and A. aegypti cells was terminally labelled with [³H]isonicotinic acid hydrazide. The specific activities of the large RNA species show the presence of one, two and three polynucleotide chains in 23 S, 28 S and 26 S RNA, respectively. A. aegypti 26 S RNA contains a small, heat-dissociable “IRNA” similar in relative amount and mobility to that found in BHK cells.     

Studies on Independent Synthesis of Cytoplasmic Ribonucleic Acids in Acetabularia mediterranea

1. The RNA content of anucleate and nucleate fragments of Acetabularia has been measured. It was found that there is a net synthesis of RNA in nucleate fragments. On the other hand, the RNA content of anucleate fragments did not change significantly after enucleation. 2. Anucleate fragments, however, can readily incorporate ¹⁴C-labeled adenine, orotic acid, and carbon dioxide into their cytoplasmic RNA. 3. The results of experiments on ¹⁴CO₂ incorporation into the RNA of anucleate and nucleate fragments suggest that there is a mechanism for de novo synthesis of RNA in anucleate cytoplasm. 4. In Acetabularia, 81 per cent of the cytoplasmic RNA is bound to a large granule fraction, consisting mainly of chloroplasts. Even after removal of the nucleus, RNA is synthesized in this "chloroplast" fraction. The chloroplasts are thus a major site of RNA synthesis in the cytoplasm of these algae. Synthesis of "chloroplastic" RNA, in anucleate fragments, possibly occurs at the expense of the RNA present in other fractions (microsomes and supernatant). 5. 8-Azaguanine stimulates regeneration and cap formation in anucleate fragments and does not inhibit RNA synthesis in these fragments.     

Amino acid substrate specificity of asparaginyl-,aspartyl- and glutaminyl-tRNA synthetase isolated from higher plants

AspNH₂-, Asp- and GluNH₂-tRNA synthetases were purified from Phaseolus aureus; their optimum assay conditions, substrate specificities and salt sensitivities were investigated. AspNH₂-tRNA synthetase from β-cyanoalanine-producing (Vicia sativa), and non-producing (P. aureus and V. faba) species was able to utilize the analogue as a substrate irrespective of the source of the enzyme. Asp-tRNA synthetase from P. aureus was able to utilize α-aminomalonate and threo-β-hydroxy Asp as a substrate. The transfer of ¹⁴C-GluNH₂ to tRNA, catalyzed by GluNH₂-tRNA synthetase, was only inhibited by high concentrations of those analogues tested; albizziine was the most efficient, but no difference could be demonstrated between the substrate specificities of the enzyme isolated from an albizziine-producer (A. julibrissin and a non-producer (P. aureus) species.     

Characterization of ribosomes from the seed of Pinus lambertiana

Ribosomes isolated from seeds of the sugar pine, Pinus lambertiana, have been characterized: The ribosome has a sedimentation coefficient (s_20,w⁰) of 78·2 S and contains 41 % RNA and 58 % protein. On dialysis against buffer containing 0·5-1 mM MgCl₂, the ribosome was reversibly transformed into an intermediate form (60 S). Further removal of Mg²⁺ causes the intermediate ribosome to dissociate into subunits (30 S and 40 S). Treatment of the intermediate ribosome with p-chloromercuribenzoic acid caused the dissociation of the particle into subunits. Incubating the 80 S ribosome with the sulfhydryl reagent caused a rapid transformation of the particle into an intermediate type particle. These results suggest that sulfhydryl groups are involved not only in associating the subunits but also in maintaining the compact structure of the ribosomes. The ribosome contains three ribosomal RNA components of 28 S, 18 S and 5 S. The base compositions of the three ribosomal RNA components are different.     

The naturally trans-acting ribozyme RNase P RNA has leadzyme properties

Divalent metal ions promote hydrolysis of RNA backbones generating 5′OH and 2′;3′P as cleavage products. In these reactions, the neighboring 2′OH act as the nucleophile. RNA catalyzed reactions also require divalent metal ions and a number of different metal ions function in RNA mediated cleavage of RNA. In one case, the LZV leadzyme, it was shown that this catalytic RNA requires lead for catalysis. So far, none of the naturally isolated ribozymes have been demonstrated to use lead to activate the nucleophile. Here we provide evidence that RNase P RNA, a naturally trans-acting ribozyme, has leadzyme properties. But, in contrast to LZV RNA, RNase P RNA mediated cleavage promoted by Pb²⁺ results in 5′ phosphate and 3′OH as cleavage products. Based on our findings, we infer that Pb²⁺ activates H₂O to act as the nucleophile and we identified residues both in the substrate and RNase P RNA that most likely influenced the positioning of Pb²⁺ at the cleavage site. Our data suggest that Pb²⁺ can promote cleavage of RNA by activating either an inner sphere H₂O or a neighboring 2′OH to act as nucleophile.     

The roles of RNA polymerase and RNAase I in stable RNA degradation in Escherichia coli carrying the srnB+ gene

In Escherichia coli cells carrying the srnB⁺ gene of the F plasmid, rifampin, added at 42°C, induces the extensive rapid degradation of the usually stable cellular RNA (Ohnishi, Y., (1975) Science 187, 257–258; Ohnishi, Y., Iguma, H., Ono, T., Nagaishi, H. and Clark, A.J. (1977) J. Bacteriol. 132, 784–789). We have studied further the necessity for rifampin and for high temperature in this degradation. Streptolidigin, another inhibitor of RNA polymerase, did not induce the RNA degradation. Moreover, the stable RNA of some strains in which RNA polymerase is temperature-sensitive did not degrade at the restrictive temperature in the absence of rifampin. These data suggest that rifampin has an essential role in the RNA degradation, possibly by the modification of RNA polymerase function. A protein (M_r 12 000) newly synthesized at 42°C in the presence of rifampin appeared to be the product of the srnB⁺ gene that promoted the RNA degradation. In a mutant deficient in RNAase I, the extent of the RNA degradation induced by rifampin was greatly reduced. RNAase activity of cell-free crude extract from the RNA-degraded cells was temperature-dependent. The RNAase was purified as RNAase I in DEAE-cellulose column chromatography and Sephadex G-100 gel filtration. Both in vivo and with purified RNAase I, a shift of the incubation mixture from 42 to 30°C, or the addition of Mg²⁺ ions, stopped the RNA degradation. Thus, an effect on RNA polymerase seems to initiate the expression of the srnB⁺ gene and the activation of RNAase I, which is then responsible for the RNA degradation of E. coli cells carrying the srnB⁺ gene.     

Physical measurements on the lipid-containing bacteriophage φ6

Bacteriophage φ6 has been studied by small-angle X-ray scattering, intensity-fluctuation spectroscopy, analytical ultracentrifugation, and spectroscopy. The sedimentation coefficient (s₂₀⁰, w) is 375 S, the diffusion coefficient (D₂₀⁰, w) is 2.66 · 10^?8 cm²/s. Using the Svedberg equation and an estimate of the partial specific volume, the M_r is 1.49 ± 0.32 · 10⁸.A simple model which describes φ6, is a central sphere consisting of RNA and protein of radius 330 Å and an outer shell of low electron density 40 Å thick. The RNA may form five concentric shells in the region $\text{r = 140?290}\text{A}\text{?}$