Studies on transcription termination and splicing of the rRNA precursor in vivo in the presence of proflavine

The antiviral activity of RNA-dye combinations

The results of our previous studies (Jamison et al. 1988, 1989, 1990 a, b, c, d, e) have shown that the ability of intercalative dyes to modulate the antiviral activity of poly r(A-U) is related to the groove through which the dyes intercalate into the poly r(A-U). When poly r(A-U) is combined with the minor groove intercalating dyes or the minor/major groove intercalating dyes, optimum enhancement of antiviral activity is observed at the dye/ribonucleotide ratio predicted by the neighbor exclusion model (usually 1/4 or 1/6). No enhancement is observed when poly r(A-U) is combined with major groove intercalating dyes. When poly r(A-U) is combined with additional intercalative dyes to produce a dye/ribonucleotide ratio of 1/4 and a ribonucleotide concentration of 200 microM, the antiviral activity of poly r(A-U) is enhanced 8- to 20-fold, while 50% effective doses of the poly r(A-U) and the dyes decreases 18- to 347-fold. Interferon neutralization assays demonstrate that the interferon-inducing capability of the dye/poly r(A-U) combinations approximates the sum of the interferon-inducing capabilities of the poly r(A-U) and the dyes employed and suggests that the dyes potentiate the antiviral activity of poly r(A-U) without affecting the amount of interferon induced. Direct viral inactivation studies demonstrate that the dyes, poly r(A-U), and the dye/poly r(A-U) combinations do not inactivate VSV at concentrations near the 50% viral inhibitory dose. Assessment of cytotoxicity by microscope examination of HSF cell morphology and trypan blue exclusion indicates that the dye/poly r(A-U) combinations exhibit antiviral activity at concentrations well below those that induce cyto-toxicity. Several of the dyes and the dye/poly r(A-U) combinations exhibit anti-HIV-1 activity, suggesting that the enhancement phenomenon is not virus-specific nor host cell-specific. The enhancement phenomenon is sensitive to the base sequence of the polynucleotide with dye/poly r(A-U) and dye/poly r(G-C) combinations displaying enhanced antiviral activity, while dye/poly (rI).poly (rC) and dye/poly d(A-T) combinations do not. These results suggest that while intercalation of the dye and interferon induction are necessary for enhanced antiviral activity, neither intercalation nor interferon induction alone is sufficient to potentiate the antiviral activity of polyribonucleotides.

Characterization of an authentic intermediate in the self-splicing process of ribosomal precursor RNA in macronuclei of Tetrahymena thermophila

We have characterized a 1.5 kb RNA species in T. thermophila macronuclei previously found in vivo and including intron sequences linked to the 3' exon. This IVS-3' exon RNA could be detected in gels as a discrete molecule only after denaturation of nuclear RNA. After addition of 32P-GTP, as splicing cofactor in a nuclear in vitro system, the IVS-3' exon RNA was labeled at its 5' terminus, as was the by-product of splicing, the excised IVS RNA. The time course of labeling indicates that the IVS-3' exon RNA acts like a reaction intermediate and specifically a kinetic precursor to IVS RNA. Partial nuclease digestions showed that the IVS-3' exon RNA and the IVS RNA have the same 5' terminal sequence. In addition the IVS-3' exon RNA can release the 15-mer oligonucleotide cleaved off during circularization of IVS RNA under conditions of high temperature. Taken together, the structural, functional, and kinetic properties of the IVS-3' exon RNA strongly suggest that it represents a previously postulated in vivo intermediate in the splicing pathway.

Self-catalyzed cyclization of the intervening sequence RNA of Tetrahymena: inhibition by intercalating dyes

The intervening sequence (IVS) excised from the pre-rRNA of Tetrahymena undergoes a self-catalyzed cleavage-ligation reaction to form a covalently closed circular RNA. This cyclization reaction is kinetically inhibited by ethidium bromide (50% inhibition at 22 +/- 14 microM, greater than 99% inhibition at 53 +/- 16 microM for a 20 minute reaction). The dye does not alter the sites of the cyclization reaction, but it does increase the relative amount of reaction at a minor site 19 nucleotides from the 5' end of the IVS. The reversibility of the inhibition and the relative inhibitory strength of acridine orange, ethidium and proflavine suggest that inhibition is due to intercalation of the dye in functionally important secondary or tertiary structures of the IVS. The concentration of dye required to inhibit cyclization is much higher than expected from the known binding constants of such dyes to tRNA. At high Mg2+ to Na+ ratios, conditions which should stabilize RNA structure, a subpopulation of the IVS RNA molecules is resistant to ethidium inhibition, even at 200 microM ethidium. These data are interpreted as reflecting two conformational isomers of the IVS that differ in their reactivity and in their sensitivity to dye binding.