A transient species of poly(A)+ RNA detected by a myosin heavy chain cDNA probe in muscle cell culture during terminal differentiation

Primary cell cultures were prepared from breast muscles of 11 day 4 hour-embryonic chicks. Cytoplasmic RNAs were isolated from the cultured cells at various time intervals from day 3 to day 8. A [P32] DNA probe complementary to messenger RNA of myosin heavy chain was used to hybridize with the RNAs after gel electrophoresis. A transient species of polyadenylated RNA with a decreased mobility in electrophoresis was detected during a period of time when contractions of syncytial fibers were first observed.     

Metabolism of Guanine and Guanine Nucleotides in Primary Rat Neuronal Cultures

The metabolic fate of guanine and of guanine ribonucleotides (GuRNs) in cultured rat neurons was studied using labeled guanine. 8-Aminoguanosine (8-AGuo), an inhibitor of purine nucleoside phosphorylase, was used to clarify the pathways of GMP degradation, and mycophenolic acid, an inhibitor of IMP dehydrogenase, was used to assess the flux from IMP to GMP and, indirectly, the activity of the guanine nucleotide cycle (GMP----IMP----XMP----GMP). The main metabolic fate of guanine in the neurons was deamination to xanthine, but significant incorporation of guanine into GuRNs, at a rate of approximately 8.5-13.1% of that of the deamination, was also demonstrated. The turnover rate of GuRNs was fast (loss of 80% of the radioactivity of the prelabeled pool in 22 h), reflecting synthesis of nucleic acids (32.8% of the loss in radioactivity) and degradation to xanthine, guanine, hypoxanthine, guanosine, and inosine (49.3, 4.3, 4.1, 1.1, and 0.5% of the loss, respectively). Of the radioactivity in GuRNs, 7.9% was shifted to adenine nucleotides. The accumulation of label in xanthine indicates (in the absence of xanthine oxidase) that the main degradative pathway from GMP is that to xanthine through guanosine and guanine. The use of 8-AGuo confirmed this pathway but indicated the operation of an additional, relatively slower degradative pathway, that from GMP through IMP to inosine and hypoxanthine. Hypoxanthine was incorporated mainly into adenine nucleotide (91.5%), but a significant proportion (6%) was found in GuRNs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ribonucleotides as nucleotide excision repair substrates

The incorporation of ribonucleotides in DNA has attracted considerable notice in recent years, since the pool of ribonucleotides can exceed that of the deoxyribonucleotides by at least 10–20-fold, and single ribonucleotide incorporation by DNA polymerases appears to be a common event. Moreover ribonucleotides are potentially mutagenic and lead to genome instability. As a consequence, errantly incorporated ribonucleotides are rapidly repaired in a process dependent upon RNase H enzymes. On the other hand, global genomic nucleotide excision repair (NER) in prokaryotes and eukaryotes removes damage caused by covalent modifications that typically distort and destabilize DNA through the production of lesions derived from bulky chemical carcinogens, such as polycyclic aromatic hydrocarbon metabolites, or via crosslinking. However, a recent study challenges this lesion-recognition paradigm. The work of Vaisman et al. (2013) [34] reveals that even a single ribonucleotide embedded in a deoxyribonucleotide duplex is recognized by the bacterial NER machinery in vitro. In their report, the authors show that spontaneous mutagenesis promoted by a steric-gate pol V mutant increases in uvrA, uvrB, or uvrC strains lacking rnhB (encoding RNase HII) and to a greater extent in an NER-deficient strain lacking both RNase HI and RNase HII. Using purified UvrA, UvrB, and UvrC proteins in in vitro assays they show that despite causing little distortion, a single ribonucleotide embedded in a DNA duplex is recognized and doubly-incised by the NER complex. We present the hypothesis to explain the recognition and/or verification of this small lesion, that the critical 2′-OH of the ribonucleotide – with its unique electrostatic and hydrogen bonding properties – may act as a signal through interactions with amino acid residues of the prokaryotic NER complex that are not possible with DNA. Such a mechanism might also be relevant if it were demonstrated that the eukaryotic NER machinery likewise incises an embedded ribonucleotide in DNA.     

Error‐free and mutagenic processing of topoisomerase 1‐provoked damage at genomic ribonucleotides

Genomic ribonucleotides incorporated during DNA replication are commonly repaired by RNase H2‐dependent ribonucleotide excision repair (RER). When RNase H2 is compromised, such as in Aicardi‐Goutières patients, genomic ribonucleotides either persist or are processed by DNA topoisomerase 1 (Top1) by either error‐free or mutagenic repair. Here, we present a biochemical analysis of these pathways. Top1 cleavage at genomic ribonucleotides can produce ribonucleoside‐2′,3′‐cyclic phosphate‐terminated nicks. Remarkably, this nick is rapidly reverted by Top1, thereby providing another opportunity for repair by RER. However, the 2′,3′‐cyclic phosphate‐terminated nick is also processed by Top1 incision, generally 2 nucleotides upstream of the nick, which produces a covalent Top1–DNA complex with a 2‐nucleotide gap. We show that these covalent complexes can be processed by proteolysis, followed by removal of the phospho‐peptide by Tdp1 and the 3′‐phosphate by Tpp1 to mediate error‐free repair. However, when the 2‐nucleotide gap is associated with a dinucleotide repeat sequence, sequence slippage re‐alignment followed by Top1‐mediated religation can occur which results in 2‐nucleotide deletion. The efficiency of deletion formation shows strong sequence‐context dependence.     

Ribonucleotide Reductases: Radical Chemistry and Inhibition at the Active Site

Abstract

Ribonucleoside 5′-diphosphate reductases (RDPRs) have been studied for several decades. Increasingly sophisticated mechanisms have been proposed for the reduction of natural substrate ribonucleotides to their 2′-deoxy counterparts and for mechanism-based inactivation of RDPRs with 2′-substituted-ribonucleotides. We now discuss biomimetic reactions of model substrate and inhibitor analogues, which clarify three aspects of previously proposed mechanisms postulated to occur at the active site of RDPRs.     

Continuous production of 5′-ribonucleotides from yeast RNA by hydrolysis with immobilized 5′-phosphodiesterase and 5′-adenylate deaminase

The production of 5-IMP and 5-GMP by enzymatic conversion from RNA using a continuous two packed-bed reactor was investigated. 5-Phosphodiesterase (5PD) and 5-adenylate deaminase (5AD) were immobilized in an acrylic resin to produce derivatives with about 15 U/g of support. The kinetic properties of the enzymes were described by Michaelis-Menten models: no significant differences were found in the K _m value of the free and immobilized 5AD (60 and 20 m, respectively), whereas for 5PD the K _m value was one order of magnitude higher for the immobilized enzyme (4.85 mg RNA/ml), probably due to diffusional limitations. Both enzymes remained stable after 8 h of use in a continuous packed-bed reactor whereas the half lives of the free enzymes were 193 min and 240 min at 40°C and 70°C for 5AD and 5PD, respectively. A procedure is proposed for the design of a continuous two packed-bed column process.F. Olmedo and F. Iturbe are with the Depto. de Alimentos y Biotecnologia, Facultad de Química, UNAM, México 04510, D.F., Mexico. J. Gomez-Hernández is with the Depto. de Biotecnología, UAM-1, Apdo. Postal 55-535, México 09340, D.F., Mexico. A. López-Munguía is with the Instituto de Biotecnología, Apartado Postal 510-3, Cuernavaca, Mor. 62271, Mexico     

Stimulation of Chromosomal Rearrangements by Ribonucleotides

We show by whole genome sequence analysis that loss of RNase H2 activity increases loss of heterozygosity (LOH) in Saccharomyces cerevisiae diploid strains harboring the pol2-M644G allele encoding a mutant version of DNA polymerase ε that increases ribonucleotide incorporation. This led us to analyze the effects of loss of RNase H2 on LOH and on nonallelic homologous recombination (NAHR) in mutant diploid strains with deletions of genes encoding RNase H2 subunits (rnh201Δ, rnh202Δ, and rnh203Δ), topoisomerase 1 (TOP1Δ), and/or carrying mutant alleles of DNA polymerases ε, α, and δ. We observed an ∼7-fold elevation of the LOH rate in RNase H2 mutants encoding wild-type DNA polymerases. Strains carrying the pol2-M644G allele displayed a 7-fold elevation in the LOH rate, and synergistic 23-fold elevation in combination with rnh201Δ. In comparison, strains carrying the pol2-M644L mutation that decreases ribonucleotide incorporation displayed lower LOH rates. The LOH rate was not elevated in strains carrying the pol1-L868M or pol3-L612M alleles that result in increased incorporation of ribonucleotides during DNA synthesis by polymerases α and δ, respectively. A similar trend was observed in an NAHR assay, albeit with smaller phenotypic differentials. The ribonucleotide-mediated increases in the LOH and NAHR rates were strongly dependent on TOP1. These data add to recent reports on the asymmetric mutagenicity of ribonucleotides caused by topoisomerase 1 processing of ribonucleotides incorporated during DNA replication.     

Analysis of Ribonucleotide Removal from DNA by Human Nucleotide Excision Repair

Ribonucleotides are incorporated into the genome during DNA replication. The enzyme RNase H2 plays a critical role in targeting the removal of these ribonucleotides from DNA, and defects in RNase H2 activity are associated with both genomic instability and the human autoimmune/inflammatory disorder Aicardi-Goutières syndrome. Whether additional general DNA repair mechanisms contribute to ribonucleotide removal from DNA in human cells is not known. Because of its ability to act on a wide variety of substrates, we examined a potential role for canonical nucleotide excision repair in the removal of ribonucleotides from DNA. However, using highly sensitive dual incision/excision assays, we find that ribonucleotides are not efficiently targeted by the human nucleotide excision repair system in vitro or in cultured human cells. These results suggest that nucleotide excision repair is unlikely to play a major role in the cellular response to ribonucleotide incorporation in genomic DNA in human cells.     

Cloning and sequence analysis of a rat liver cDNA coding for a phenobarbital-inducible microheterogenous cytochrome P-450 variant: regulation of its messenger level by xenobiotics

A rat liver cDNA library was prepared from total polyribosomal poly(A)+ RNA extracted from phenobarbital-treated animals. A cDNA clone coding for a phenobarbital-inducible cytochrome P-450 (PB P-450) was identified by differential colony hybridization to cDNAs synthesized from liver poly(A)+RNAs isolated from phenobarbital-treated rats for positive selection and cDNAs from either untreated rats or beta-naphthoflavone-treated rats as negative controls, followed by hybrid-selected translation and analysis of the translation products by immunoprecipitation. As the cloning and screening strategies involve no prior enrichment for specific mRNAs, they also permit the identification of sequences coding for phenobarbital-induced proteins other than cytochromes P-450. This relatively straightforward approach is generally applicable to the molecular cloning of sequences coding for other inducible cytochromes P-450. Nucleic acid sequencing data indicated that the cloned PB P-450 cDNA codes for a cytochrome P-450 variant [designated P-450e(U.C.)] that is very similar, but not identical, to P-450e. Sequence analysis of the section of cDNA specifying the 3'-non-coding region of the mRNA revealed that it lacked the usual poly(A) addition site signal sequence but contained three inverted repeat structures. Solution hybridization analysis demonstrated that PB P-450 mRNA is increased 20-fold by phenobarbital treatment and decreased 3-fold by beta-naphthoflavone treatment.