Intramolecular stacking association and conformation properties of a 'cap' structure, m7G5'pppUm, and the related model compounds

Fluorescence and NMR studies of intramolecular stacking of mRNA cap-analogues

Intramolecular stacking of a series of new synthesized dinucleotide mRNA cap analogues has been investigated in aqueous buffers by means of fluorescence and 1H-NMR at various pH and temperatures, and compared with that for 7-methylguanosine(5')ppp(5')guanosine (m7GpppG), as well as its hypermethylated derivative m(3)2,2,7GpppG. Thermodynamic parameters for intramolecular self-association stabilized by stacking were established by temperature-dependent fluorescence quenching, taking into account collisional deactivation of the excited states. Relative orientations of the stacked bases in the cap analogues were determined with the aid of a program GEOSHIFT (Stolarski et al., Biochim. Biophys. Acta (1996) 1293, 97), based on ring-current anisotropy. 1D-soft-TOCSY experiments were applied to extract the exact values of vicinal coupling constants, and hence to resolve solution conformation of the cap molecules. Stacking interaction has been discussed in detail in terms of the cap structural features, e.g., types of bases and length of the 5',5'-phosphate bridges, and regarding the interactions stabilizing intramolecular stacking.

Characterization of transcription initiation sites on the soybean mitochondrial genome allows identification of a transcription-associated sequence motif

Transcription initiation sites on the soybean mitochondrial genome have been characterized by sequence analysis of in vitro-capped soybean mtRNAs and corresponding mtDNA regions. The most abundant, discrete soybean mtRNA species labeled by guanylyltransferase and [alpha-32P]GTP are shown to correspond to the major transcript of the atp9 gene and to a group of small RNAs consisting of a discrete 80 nucleotide (nt) species plus heterogeneous species ranging in size from 133 to 148 nt. The 133-148 nt RNAs represent a set of transcripts with a common 5' terminus and ragged 3' ends, while the 80 nt RNA corresponds to positions 53-133 of the 133 nt species. The major, discrete in vitro-capped RNA species thus correspond to primary transcripts originating at three sites located in two regions of the soybean mitochondrial genome. The sequences extending from 13 nucleotides upstream to 8 nucleotides downstream of the initiation sites for the atp9 and 133-148 nt transcripts are identical at 18 of 21 positions. Sequences closely resembling this motif are located at some other 5' transcript termini of dicot plant mitochondria. Less closely related sequences are found at transcription initiation sites of wheat and maize mitochondria.

Sequence analysis of wheat mitochondrial transcripts capped in vitro: definitive identification of transcription initiation sites

To identify transcription initiation sites in wheat mitochondria, the nascent 5'-ends of transcripts were specifically labeled by incubation of wheat mitochondrial RNA with [alpha-32P]GTP in the presence of the enzyme guanylyltransferase. After separation of the resulting capped transcripts by electrophoresis in polyacrylamide gels, individual RNAs were recovered and directly sequenced. Four RNA sequences obtained in this way were localized upstream of the protein-coding genes atpA, coxII, coxIII and orf25. Comparison of mRNA and gene sequences allowed precise positioning of transcription initiation sites for these four genes. Sequence similarities immediately upstream of these sites define a conserved motif that we suggest as a candidate regulatory element in wheat mtDNA. The relationship between this motif and putative mitochondrial promoters in other plant species is discussed.

A possible recognition mode of mRNA cap terminal structure by peptide: cooperative stacking and hydrogen-bond pairing interactions between m7GpppA and Trp-Leu-Glu

1H-NMR and fluorescence spectroscopic studies on the interaction between the Trp-Leu-Glu and m7GpppA have shown a specific binding mode, in which the pi-pi stacking interaction of the Trp indole ring and the hydrogen-bond pairing of Glu carboxyl side group with 7-methylguanine base are simultaneously formed.

DNA base modification: ionized base pairs and mutagenesis

The nature of hydrogen bonding between normal and modified bases has been re-examined. It is proposed that hydrogen-bonding schemes may involve tautomeric, ionized or conformational forms (syn, anti and wobble). Several important cases are presented or reviewed in which physical evidence indicates the existence of ionized base pairs. When thermodynamic values determined in aqueous solution under physiological conditions are considered, it can be argued that base ionization will contribute substantially to the stability of many biologically relevant base pairs containing modified bases. A significant incidence of ionized bases in DNA may have important kinetic ramifications for the further chemical reactivity of both the modified base and its cross-strand pairing partner. Moreover, DNA structure at and surrounding ionized base pairs may be altered. For this reason, the model presented in this study should be useful as DNA-sequence analysis becomes more commonly applied to the study of mutagenesis.