The reaction of adenine and cytosine residues in tRNA with chloroacetaldehyde

A New Bacterial Adenosine-Derived Nucleoside as an Example of RNA Modification Damage

The fields of RNA modification and RNA damage both exhibit a plethora of non-canonical nucleoside structures. While RNA modifications have evolved to improve RNA function, the term RNA damage implies detrimental effects. Based on stable isotope labelling and mass spectrometry, we report the identification and characterisation of 2-methylthio-1,N6-ethenoadenosine (ms² ϵA), which is related to 1,N6-ethenoadenine, a lesion resulting from exposure of nucleic acids to alkylating chemicals in vivo. In contrast, a sophisticated isoprene labelling scheme revealed that ms² ϵA biogenesis involves cleavage of a prenyl moiety in the known transfer RNA (tRNA) modification 2-methylthio-N6-isopentenyladenosine (ms² i⁶ A). The relative abundance of ms² ϵA in tRNAs from translating ribosomes suggests reduced function in comparison to its parent RNA modification, establishing the nature of the new structure in a newly perceived overlap of the two previously separate fields, namely an RNA modification damage.

Use of specific chemical reagents for detection of modified nucleotides in RNA

Naturally occurring cellular RNAs contain an impressive number of chemically distinct modified residues which appear posttranscriptionally, as a result of specific action of the corresponding RNA modification enzymes. Over 100 different chemical modifications have been identified and characterized up to now. Identification of the chemical nature and exact position of these modifications is typically based on 2D-TLC analysis of nucleotide digests, on HPLC coupled with mass spectrometry, or on the use of primer extension by reverse transcriptase. However, many modified nucleotides are silent in reverse transcription, since the presence of additional chemical groups frequently does not change base-pairing properties. In this paper, we give a summary of various chemical approaches exploiting the specific reactivity of modified nucleotides in RNA for their detection.

Site specific synthesis and polymerase bypass of oligonucleotides containing a 6-hydroxy-3,5,6,7-tetrahydro-9H-imidazo[1,2-a]purin-9-one base, an intermediate in the formation of 1,N2-etheno-2'-deoxyguanosine

The reaction of DNA with certain bis-electrophiles such as chlorooxirane and chloroacetaldehyde produces etheno adducts. These lesions are highly miscoding, and some of the chemical agents that produce them have been shown to be carcinogenic in laboratory animals and in humans. An intermediate in the formation of 1,N2-ethenoguanine is 6-hydroxy-3,5,6,7-tetrahydro-9H-imidazo[1,2-a]purin-9-one (6-hydroxyethanoguanine), which undergoes conversion to the etheno adduct. The chemical properties and miscoding potential of the hydroxyethano adduct have not been previously studied. A synthesis of the hydroxyethano-adducted nucleoside was developed, and it was site specifically incorporated into oligonucleotides. This adduct had a half-life of between 24 and 48 h at neutral pH and 25 degrees C at the nucleoside and oligonucleotide levels. The miscoding potential of the hydroxyethano adduct was examined by primer extension reactions with the DNA polymerases Dpo4 and pol T7-, and the results were compared to the corresponding etheno-adducted oligonucleotide. Dpo4 preferentially incorporated dATP opposite the hydroxyethano adduct and dGTP opposite the etheno adduct; pol T7- preferentially incorporated dATP opposite the etheno adduct while dGTP and dATP were incorporated opposite the hydroxyethano adduct with nearly equal catalytic efficiencies. Collectively, these results indicate that the hydroxyethano adduct has a sufficient lifetime and miscoding properties to contribute to the mutagenic spectrum of chlorooxirane and related genotoxic species.

Characterization of DNA-binding and strand-exchange stimulation properties of y-RPA, a yeast single-strand-DNA-binding protein

Single-stranded DNA binding proteins (SSBs) have been isolated from many organisms, including Escherichia coli, Saccharomyces cerevisiae and humans. Characterization of these proteins suggests they are required for DNA replication and are active in homologous recombination. As an initial step towards understanding the role of the eukaryotic SSBs in DNA replication and recombination, we examined the DNA binding and strand exchange stimulation properties of the S. cerevisiae single-strand binding protein y-RPA (yeast replication protein A). y-RPA was found to bind to single-stranded DNA (ssDNA) as a 115,000 M(r) heterotrimer containing 70,000, 36,000 and 14,000 M(r) subunits. It saturated ssDNA at a stoichiometry of one heterotrimer per 90 to 100 nucleotides and binding occurred with high affinity (K omega greater than 10(9) M-1) and co-operativity (omega = 10,000 to 100,000). Electron microscopic analysis revealed that y-RPA binding was highly co-operative and that the ssDNA present in y-RPA-ssDNA complexes was compacted fourfold, arranged into nucleosome-like structures, and was free of secondary structure. y-RPA was also tested for its ability to stimulate the yeast Sepl and E. coli RecA strand-exchange proteins. In an assay that measures the pairing of circular ssDNA with homologous linear duplex DNA, y-RPA stimulated the strand-exchange activity of Sepl approximately threefold and the activity of RecA protein to the same extent as did E. coli SSB. Maximal stimulation of Sepl occurred at a stoichiometry of one y-RPA heterotrimer per 95 nucleotides of ssDNA. y-RPA stimulated RecA and Sepl mediated strand exchange reactions in a manner similar to that observed for the stimulation of RecA by E. coli SSB; in both of these reactions, y-RPA inhibited the aggregation of ssDNA and promoted the co-aggregation of single-stranded and double-stranded linear DNA. These results demonstrate that the E. coli and yeast SSBs display similar DNA-binding properties and support a model in which y-RPA functions as an E. coli SSB-like protein in yeast.

Local supercoil-stabilized DNA structures

The DNA double helix exhibits local sequence-dependent polymorphism at the level of the single base pair and dinucleotide step. Curvature of the DNA molecule occurs in DNA regions with a specific type of nucleotide sequence periodicities. Negative supercoiling induces in vitro local nucleotide sequence-dependent DNA structures such as cruciforms, left-handed DNA, multistranded structures, etc. Techniques based on chemical probes have been proposed that make it possible to study DNA local structures in cells. Recent results suggest that the local DNA structures observed in vitro exist in the cell, but their occurrence and structural details are dependent on the DNA superhelical density in the cell and can be related to some cellular processes.

Reaction of nucleic acid bases with alpha-acetylenic esters. Part IV. Preparation of an alkylating derivative of tRNA(Phe) by conformation-specific chemical modification

The reaction of yeast tRNA(Phe) with methyl chlorotetrolate, ClCH2-C identical to C-COOCH3, was studied. This reagent converts adenine and cytosine rings into derivatives in which an additional heterocycle bearing the alkylating chloromethyl group is fused to the original base; these derivatives can exist in two isomeric forms. Modified nucleosides of this type can be easily identified by reverse-phase HPLC. It was found that under native conditions, the modification of tRNA involves the anticodon loop and the 3'-end. The isomers of adenine derivatives formed in the anticodon loop were different from those formed in the 3'-end. It is suggested that the isomeric structure of the derivatives is related to the fine conformational differences between these two regions of tRNA(Phe). Methyl chlorotetrolate could thus be used as a conformational probe of single-stranded nucleic acids. Preliminary assays showed that modified tRNA(Phe) binds irreversibly to yeast phenylalanyl-tRNA synthetase.

Measurement by fluorescence of interstitial adenosine levels in normoxic, hypoxic, and ischemic perfused rat hearts

An improved assay was used to investigate the effects of hypoxia or ischemia on interstitial fluid and coronary venous effluent levels of adenosine in isolated perfused nonworking rat hearts. The adenosine in 5- to 10-microliter samples of left ventricular epicardial surface transudates and coronary effluents was reacted with chloroacetaldehyde, and the fluorescent derivative (1,N6-ethenoadenosine) was quantitated using high pressure liquid chromatography and fluorescence detection. Hearts responding to hypoxia could be separated into two groups. In one group of hearts, the control (normoxic) transudate and effluent adenosine concentrations were 94 +/- 24 and 41 +/- 6 pmol/ml, respectively. These values increased by 118 and 96%, respectively, with 5 minutes of hypoxia (30% O2), and returned to control levels 5 minutes after resumption of normoxia. In a second group of hearts, the normoxic control levels of adenosine in the transudates (42 +/- 7 pmol/ml) and coronary effluents (62 +/- 17 pmol/ml) were increased with hypoxia by 174 and 1,178%, respectively. However, the transudate levels continued to rise for 5 minutes after resumption of normoxic perfusion while effluent levels fell. In another series of hearts, global ischemia for 30 seconds elicited an elevation of transudate adenosine levels by 362 to 641% above control (58 +/- 15 pmol/ml) as determined 30 seconds after resumption of perfusion flow.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction of recA protein with single-stranded DNA. Quantitative aspects of binding affinity modulation by nucleotide cofactors

We have investigated quantitative molecular aspects of the interaction of recA protein with single-stranded DNA, by using a fluorescent modified-DNA referred to as etheno-M13 DNA. In addition, the effects of the nucleotide cofactors ATP and ADP, and the analogues ATP-gamma-S, AMP-P-C-P, and AMP-P-N-P on this interaction have been studied. It is shown that ATP, AMP-P-N-P and, in particular, ATP-gamma-S significantly increase the affinity of recA protein for single-stranded DNA, whereas ADP and, to a lesser degree, AMP-P-C-P decrease the affinity. Binding to etheno-M13 single-stranded DNA is co-operative, with the value of the co-operativity parameter, omega, being approximately 50 under all conditions measured. The effect that ADP has on recA protein-DNA affinity is to lower the intrinsic binding constant, but it has no effect on the co-operativity of binding. In addition, the stability of the recA protein-DNA complex is very salt dependent (d log K/d log [NaC1] approximately -10) and it is the intrinsic binding affinity rather than the co-operativity of binding that is affected; thus, under all conditions observed, recA protein binds single-stranded DNA co-operatively with a value of omega = 50 +/- 10. The binding affinity is also influenced by the type of anion present, being approximately 10,000-fold higher when acetate ion is present instead of chloride ion. These data have been interpreted to suggest that recA protein forms up to five ionic interactions when it binds to single-stranded DNA and that five to six anions are displaced upon binding. The modulation of recA protein-DNA complex stability by nucleotide cofactors suggests that these cofactors play a role in the cycling of recA protein on and off single-stranded DNA, with ATP being required for DNA binding under physiological conditions and ADP serving as a "release" factor. These results are discussed in terms of a model for the role of ATP hydrolysis in a recA protein-single stranded DNA binding cycle.

Long-range conformational transition in yeast tRNAPhe, induced by the Y-base removal and detected by chloroacetaldehyde modification

Chemical modification was used to study the conformational changes occurring in yeast tRNAPhe after the Y-base excision. The chemical probe was the adenine- and cytosine-specific reagent chloroacetaldehyde. Comparison of the modification patterns in tRNAPhe and tRNAPhe-Y shows that seven bases, adenines 35, 36 and 38 in the anticodon loop and adenines 73, 76 and cytosines 74, 75 in the 3'-terminus were modified in both tRNAs with a quantitative difference in the modification level of the anticodon loop bases. The most interesting, however, is the qualitative difference consisting in modification of cytosine-60 in the T psi C loop of tRNAPhe-Y. Some aspects of the mechanism of this long-distance conformational transition are briefly discussed.

Fidelity in transcription assessed by DNA-dependent RNA polymerases

The use of in vitro transcription of polynucleotides by prokaryotic and eukaryotic DNA-dependent RNA polymerases has proven of great usefulness in detecting mutagenic base modifications. Quite similar results are obtained with ribo- and deoxyribopolymers as templates, and with Mg2+ and Mn2+ at optimal concentrations. Recent studies have centered on polymers containing etheno C, as well as its hydrated form. These modifications are of particular interest, since they are the consequence of metabolised vinyl chloride, a proven human carcinogen.