The molecular mechanism of benzimidazole mutagenicity: In vitro studies on transcription and translation

Benzimidazoles are weak mutagens acting through base substitutions; they are incorporated into nucleic acids. Experiments with deoxyribohomopolymers as templates demonstrated that benzimidazole nucleoside triphosphate is polymerized by RNA polymerase only in the presence of poly dC, i.e., instead of guanine. In plasmolyzed Escherichia coli cells, benzimidazole ribonucleoside diphosphate is polymerized by polynucleotide phosphorylase and can, after blocking of the normal mRNA synthesis with actinomycin D, be used as a messenger for polypeptide formation. The addition of radioactive amino acids to this system showed that benzimidazole is not read preferentially as guanine, as would have been expected from the RNA polymerase results. Instead, the reading was position dependent and benzimidazole is recognized (1) in the first codon position as adenine, (2) in the second as purine, and (3) in the third possibly only as base. Benzimidazole mutagenicity is thus explained as a G » A transition.     

Detection of RNA nucleoside modifications with the uridine-specific ribonuclease MC1 from Momordica charantia

A codon-optimized recombinant ribonuclease, MC1 is characterized for its uridine-specific cleavage ability to map nucleoside modifications in RNA. The published MC1 amino acid sequence, as noted in a previous study, was used as a template to construct a synthetic gene with a natural codon bias favoring expression in Escherichia coli. Following optimization of various expression conditions, the active recombinant ribonuclease was successfully purified as a C-terminal His-tag fusion protein from E. coli [Rosetta 2(DE3)] cells. The isolated protein was tested for its ribonuclease activity against oligoribonucleotides and commercially available E. coli tRNA^{Tyr I}. Analysis of MC1 digestion products by ion-pairing reverse phase liquid-chromatography coupled with mass spectrometry (IP-RP-LC-MS) revealed enzymatic cleavage of RNA at the 5′-termini of uridine and pseudouridine, but cleavage was absent if the uridine was chemically modified or preceded by a nucleoside with a bulky modification. Furthermore, the utility of this enzyme to generate complementary digestion products to other common endonucleases, such as RNase T1, which enables the unambiguous mapping of modified residues in RNA is demonstrated.     

Termination of Deoxyribonucleic Acid in Escherichia coli by 2′,3′-Dideoxyadenosine

2′,3′-Dideoxyadenosine was previously shown to be lethal to Escherichia coli and to inhibit deoxyribonucleic acid (DNA) synthesis irreversibly in this organism. It was also shown that triphosphate of this analogue terminates DNA chains in an in vitro system. Data presented here show that the nucleoside is relatively insensitive to E. coli adenosine deaminase and is converted intracellularly into the dideoxynucleotide, including the triphosphate. Thymine nucleotide pools were not reduced in inhibited bacteria, nor did preformed DNA break down. Some adenine was liberated from the dideoxyadenosine on incubation, and the latter was incorporated into ribonucleic acid. Nevertheless, about 4,000 molecules of the dideoxynucleoside were incorporated into DNA per cell. The dideoxynucleotide occurred in DNA chains in a terminal position, liberated selectively by venom phosphodiesterase. The possible nature of the lethal event is discussed.     

A variable automatic recording device for measuring phytochrome with the Perkin-Elmer spectrophotometer model 356

A method is described for the quantitative analysis and preparative isolation of N-[N-methyl-N-(9-β-ribofuranosylpurin-6-yl)carbamoyl]threonine (mt⁶A), a rare modified nucleoside constituent of transfer RNA. This method is based on the selective retention of mt⁶A and its parent compound, t⁶A, on Dowex-1 at pH 7.8, allowing these two nucleosides to be readily concentrated from the mixture of nucleosides resulting when tRNA is hydrolyzed by a combination of snake venom enzymes and E. coli alkaline phosphatase. The content of mt⁶A in wheat embryo and E. coli tRNA was found to be about 0.025 mole %, which is roughly one-tenth the t⁶A content of the tRNA of these two organisms. Since this indicates that only about 1 in 50 chains can contain a residue of mt⁶A, this nucleoside may be confined to a single isoaccepting species of transfer RNA in both E. coli and wheat embryo. No mt⁶A could be detected in either baker's or brewer's yeast tRNA by the method described. Either mt⁶A is entirely absent from yeast tRNA or it occurs in a form which does not adsorb to Dowex-1 during fractionation of hydrolysates of yeast tRNA. No t⁶A or mt⁶A could be detected in the 18 S + 26 S ribosomal ribonucleates of wheat embryo.     

RNA SYNTHESIS BY EXOGENOUS RNA POLYMERASE ON CYTOLOGICAL PREPARATIONS OF CHROMOSOMES

Cytological preparations of Drosophila polytene chromosomes serve as templates for RNA synthesis carried out by exogenous RNA polymerase (Escherichia coli). Incorporation of labeled ribonucleoside triphosphates into RNA may be observed directly by autoradiography. Because of the effects of rifampicin, actinomycin D, ribonuclease, high salt, and the requirement for all four nucleoside triphosphates, we conclude that the labeling observed over chromosomes is due to DNA-dependent RNA polymerase activity. Using this method, one can observe RNA synthesis in vitro on specific chromosome regions due to the activity of exogenous RNA polymerase. We find that much of the RNA synthesis in this system occurs on DNA sequences which appear to be in a nondenatured state.     

Structure of an intermediate in the replication of bacteriophage φX174 deoxyribonucleic acid: The initiation site for DNA replication

Replicative form DNA composed of a closed complementary strand and a discontinuous viral strand has been isolated from cells infected with bacteriophage φX174 during the period of single-strand DNA synthesis. This RFII DNA was degraded by the restriction enzyme from Hemophilus influenzae, endonuclease R, and the products analyzed by polyacrylamide gel electrophoresis. The results indicate that there are two types of discontinuity in the viral strands of these molecules: (1) 65% of the molecules contain a gap, which causes a discrete increase in mobility of a specific restriction enzyme fragment, R3. This gap can be selectively repaired with Escherichia coli DNA polymerase I and nucleoside triphosphates, but the molecules are not converted to RFI by addition of E. coli polynueleotide ligase to the reaction mixture. Approximately 30 moles of radioactive TTP are incorporated per mole of RF DNA. (2) 35% of the RF molecules contain a discontinuity, which does not result in a detectable change in mobility of any restriction enzyme fragment. These RF molecules can be converted to RFI by the action of ligase and polymerase I in the presence of nucleoside triphosphates, with incorporation of only approximately one mole of radioactive TTP, specifically into fragment R3, per mole of RF DNA.When the reaction of late RFII DNA and polymerase I is allowed to proceed beyond the repair of the discontinuity, radioactive nucleotides are incorporated into endonuclease R fragments adjacent to R3 in the 5′ → 3′ direction. This technique was utilized to determine a partial order of endonuclease R fragments in φX174.These results suggest that the synthesis of single-strand DNA is initiated from a unique point in cistron A and proceeds clockwise round the φX174 genetic map (cistron order: ABCDEFGH). A comparison of these results with other studies on φX174 suggests that DNA synthesis in all stages of φX174 replication may be initiated from a specific locus on the genome, at or near cistron A.     

Ribonucleic acid-permeable mutant of Escherichia coli

An RNA-permeable mutant was isolated from a tryptophan amber auxotrophic strain of Escherichia coli after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. The rationale of the isolation was based on the suppression of an amber mutation. A strain was selected, which could grow in minimal medium supplemented with transfer RNA prepared from an suI-carrying strain but not from an su⁻ strain. This mutant incorporated³H-labeled bulk RNA into the cells at a rate 40 times higher than did the parent strain. The level of tryptophan requirement, susceptibility to the lytic action of lysozyme and RNase activity in the culture medium of the mutant strain did not differ from those of the parent strain. The mutant strain incorporated ³H-labeled ribosomal RNA equally as well as it incorporated ³H-labeled transfer RNA and the incorporation was competitively inhibited by any species of cold RNA. However, the fate of ³H-labeled rRNA after incorporation resulted in degradation to yield acid-soluble fragments whereas tRNA after incorporation remained intact in the cell.     

Chromatin-directed Ribonucleic Acid Synthesis: A Comparison of Chromatins Isolated from Healthy, Avirulent Agrobacterium tumefaciens Inoculated, and Crown-Gall Tumor Tissues of Vicia faba

Chromatin was extracted from healthy, avirulent Agrobacterium tumefaciens inoculated, and crown-gall tumor Vicia faba internodes of the same age. Chromatin from crown-gall tissue produced 5 times more RNA per 100 micrograms of DNA than chromatin from the healthy tissue. When template availability was compared using chromatin with saturating amounts of Escherichia coli RNA polymerase, chromatin from crown-gall tissue had 36% more available template than the controls. In addition, when γ-³²P-ATP was incorporated into the RNA synthesizing reaction mixture, with saturating amounts of E. coli RNA polymerase, there were twice as many RNA chain starts in tumor as in control tissue.     

Conversion of dCTP to CTP by isolated nuclei of Ehrlich ascites tumor cells

Isolated nuclei of Ehrlich ascites tumor cells synthesize DNA in vitro using endogenous template and enzymes. Deoxycytidine nucleoside triphosphate (dCTP) is incorporated into acid-insoluble material to a much greater extent than the other substrates, even in the absence of the other triphosphates. Much of the [³H] dCTP is converted to [³H]CTP, some of which is incorporated into RNA, as evidenced by alkali-lability and density on cesium sulfate gradients.     

The Synthesis of Ribosomes in E. coli: I. The Incorporation of C14-Uracil into the Metabolic Pool and RNA

C¹⁴-uracil is rapidly incorporated by E. coli at low concentrations. Approximately half the radioactivity passes directly into RNA with very little delay. The remaining half enters a large metabolic pool and later is incorporated into RNA. The total rate of uptake (growing cells) is not greater than the requirement for uracil and cytosine for RNA synthesis. The size of the metabolic pool is not influenced measurably by the external uracil concentration. No evidence is found for the existence of a fraction of RNA which is rapidly synthesized and degraded.     

On the Significance of Cytokinin Incorporation into RNA

The clarification of the following 2 questions was attempted: (a) are cytokinins precursors in the formation of sRNA, (b) is the observed incorporation of cytokinins into sRNA related to the action of the hormone? Although Escherichia coli contains cytokinins in its sRNA, no cytokinin auxotroph mutants of E. coli could be found and the statistical probability for the existence of such mutants is extremely low. This suggests that cytokinins are not precursors in the synthesis of sRNA. A radioactive cytokinin, 6-benzylamino-9-methyl-purine was synthesized and it was tested whether or not it is incorporated into sRNA of soybean callus tissue. Masking the 9-position of the purine inhibited the incorporation of this cytokinin into RNA while not affecting its biological activity. This is taken as an indication that the observed incorporation of cytokinins such as benzyladenine into sRNA is not related to the action of this hormone.     

Decoding molnupiravir-induced mutagenesis in SARS-CoV-2

Molnupiravir, a prodrug of the nucleoside derivative β-D-N⁴-hydroxycytidine (NHC), is currently in clinical trials for COVID-19 therapy. However, the biochemical mechanisms involved in molnupiravir-induced mutagenesis had not been explored. In a recent study, Gordon et al. demonstrated that NHC can be incorporated into viral RNA and subsequently extended and used as template for RNA-dependent RNA synthesis, proposing a mutagenesis model consistent with available virological evidence. Their study uncovers molecular mechanisms by which molnupiravir drives SARS-CoV-2 into error catastrophe.     

Absolute and relative quantification of RNA modifications via biosynthetic isotopomers

In the resurging field of RNA modifications, quantification is a bottleneck blocking many exciting avenues. With currently over 150 known nucleoside alterations, detection and quantification methods must encompass multiple modifications for a comprehensive profile. LC–MS/MS approaches offer a perspective for comprehensive parallel quantification of all the various modifications found in total RNA of a given organism. By feeding ¹³C-glucose as sole carbon source, we have generated a stable isotope-labeled internal standard (SIL-IS) for bacterial RNA, which facilitates relative comparison of all modifications. While conventional SIL-IS approaches require the chemical synthesis of single modifications in weighable quantities, this SIL-IS consists of a nucleoside mixture covering all detectable RNA modifications of Escherichia coli, yet in small and initially unknown quantities. For absolute in addition to relative quantification, those quantities were determined by a combination of external calibration and sample spiking of the biosynthetic SIL-IS. For each nucleoside, we thus obtained a very robust relative response factor, which permits direct conversion of the MS signal to absolute amounts of substance. The application of the validated SIL-IS allowed highly precise quantification with standard deviations <2% during a 12-week period, and a linear dynamic range that was extended by two orders of magnitude.     

Specific nucleotide sequences in HeLa cell inverted repeated DNA: enrichment for sequences found in double-stranded regions of heterogeneous nuclear RNA

Inverted repeat DNA was isolated from HeLa cell nuclei and transcribed in vitro with Escherichia coli RNA polymerase in the presence of [alpha-³²P]nucleoside triphosphates. The RNA products were digested with T₁ ribonuclease and subjected to separation in two dimensions. The pattern of the prominent oligonucleotides was almost indistinguishable from that seen when the double-stranded regions from ³²P-labeled HeLa cell heterogeneous nuclear RNA were fingerprinted in a similar manner. The sequences of several of the largest prominent T₁ ribonuclease-generated oligonucleotides were determined and were found to agree with those isolated from the double-stranded heterogeneous nuclear RNA that migrated to the same positions in the fingerprints. The most prominent component of the inverted repeat DNA appears to be sequences that are transcribed into double-stranded regions in heterogeneous nuclear RNA molecules.     

Effects of -amanitin on in vitro labeling of RNA from defined nuclear components in salivary gland cells from Chironomus tentans

The effect of α-amanitin on nucleoside labeling of RNA in nucleoli, chromosomes, nuclear sap, and cytoplasm from Chironomus tentans salivary gland cells was investigated by radioautography and gel electrophoresis. Preribosomal RNA formation and processing in the nucleolus was not measurably influenced by the drug, and both 28 S and 18 S ribosomal RNA were transferred to the cytoplasm. In the chromosomes the heterogeneous RNA labeling was completely inhibited for the large size range (above 45–50 S) and partially for the low range. The labeling of 4–5 S chromosomal RNA was only moderately reduced. Most of the chromosomes showed radioautographically a disappearance of the normal band pattern, but some retained a pattern of weakly labeled bands. The electrophoretic results for the nuclear sap paralleled those for the chromosomes. The effect of α-amanitin on RNA labeling in these cells is similar but not identical to that of the substituted benzimidazole 5,6-dichloro-1(β-D-ribofuranosyl) benzimidazole (DRB).     

Determination of the target nucleosides for members of two families of 16S rRNA methyltransferases that confer resistance to partially overlapping groups of aminoglycoside antibiotics

The 16S ribosomal RNA methyltransferase enzymes that modify nucleosides in the drug binding site to provide self-resistance in aminoglycoside-producing micro-organisms have been proposed to comprise two distinct groups of S-adenosyl-l-methionine (SAM)-dependent RNA enzymes, namely the Kgm and Kam families. Here, the nucleoside methylation sites for three Kgm family methyltransferases, Sgm from Micromonospora zionensis, GrmA from Micromonospora echinospora and Krm from Frankia sp. Ccl3, were experimentally determined as G1405 by MALDI-ToF mass spectrometry. These results significantly extend the list of securely characterized G1405 modifying enzymes and experimentally validate their grouping into a single enzyme family. Heterologous expression of the KamB methyltransferase from Streptoalloteichus tenebrarius experimentally confirmed the requirement for an additional 60 amino acids on the deduced KamB N-terminus to produce an active methyltransferase acting at A1408, as previously suggested by an in silico analysis. Finally, the modifications at G1405 and A1408, were shown to confer partially overlapping but distinct resistance profiles in Escherichia coli. Collectively, these data provide a more secure and systematic basis for classification of new aminoglycoside resistance methyltransferases from producers and pathogenic bacteria on the basis of their sequences and resistance profiles.     

Identification of 5-hydroxycytidine at position 2501 concludes characterization of modified nucleotides in E. coli 23S rRNA

Complete characterization of a biomolecule's chemical structure is crucial in the full understanding of the relations between their structure and function. The dominating components in ribosomes are ribosomal RNAs (rRNAs), and the entire rRNA—but a single modified nucleoside at position 2501 in 23S rRNA—has previously been characterized in the bacterium Escherichia coli. Despite a first report nearly 20 years ago, the chemical nature of the modification at position 2501 has remained elusive, and attempts to isolate it have so far been unsuccessful. We unambiguously identify this last unknown modification as 5-hydroxycytidine—a novel modification in RNA. Identification of 5-hydroxycytidine was completed by liquid chromatography under nonoxidizing conditions using a graphitized carbon stationary phase in combination with ion trap tandem mass spectrometry and by comparing the fragmentation behavior of the natural nucleoside with that of a chemically synthesized ditto. Furthermore, we show that 5-hydroxycytidine is also present in the equivalent position of 23S rRNA from the bacterium Deinococcus radiodurans. Given the unstable nature of 5-hydroxycytidine, this modification might be found in other RNAs when applying the proper analytical conditions as described here.     

A COMPARATIVE ELECTRON MICROSCOPICAL STUDY OF RNA FROM DIFFERENT SOURCES

Electron micrographs of ribosomal RNA from Escherichia coli, microsomal RNA from calf, rat, and chick liver, Bacillus cereus RNA and E. coli soluble RNA are presented. Filaments of about 10 A in diameter could be observed in preparations obtained from aqueous solutions of high molecular weight RNA. When ammonium acetate solutions were used a tendency for coiling and aggregation was observed. E. coli soluble RNA appears as small, sometimes elongated particles the smallest diameter being of about 10 A.