Ultraviolet irradiation of nucleic acids: formation, purification, and solution conformational analyses of the cis-syn and trans-syn photodimers of UpU.

Uridylyl(3'-5')uridine (UpU) is subjected to aqueous acetone photosensitized radiation with sunlamps. These irradiation conditions form only cyclobutane-type photodimers. Purification of a specific configurational photodimer is accomplished by using C-18 reverse-phase high-performance liquid chromatography. Multinuclear NMR analysis is used to analyze photoproduct formation and to determine conformational features of these photodimers. Four photodimers are identified, with the cis-syn isomer predominant. The cis-syn and trans-syn photodimers of UpU exhibit markedly different furanose and exocyclic bond conformations. A comparison of the properties of the cis-syn dimers of UpU with those of dTpdT reveal many similar conformational features but also some that are different.

Uridine 5'-phosphate photohydrate formation in irradiated Escherichia coli 30S ribosomes: photochemistry and relation to ribonucleic acid-protein cross-linking.

Irradiation of aqueous buffered solutions of Escherichia coli 30S ribosomes with doses of 254-nm radiation greater than 10(19) quanta causes formation of uridine 5'-phosphate (UMP) photohydrates in ribosomal 16S RNA (rRNA). The number of molecules of UMP photohydrate formed at doses less than 2 x 10(20) quanta is linearly dependent on dose of absorbed 254-nm radiation. Maximum UMP photohydrate formation is dependent on initial ribosome concentration. When solutions containing 1 A260 unit of 30S ribosomes/mL were irradiated with greater than 2 x 10(20) quanta of 254-nm radiation, maximum photohydrate formation was equal to 47 residues/ribosome. Irradiation of solutions containing 2 A260 units/mL with greater than 7 x 10(20) quanta caused formation of 102 UMP photohydrates/ribosome. These values correspond to conversion of either 15 or 33%, respectively, of the total UMP content of 30S ribosome 16S rRNA to photohydrates. Target theory analysis of UMP photohydration in 30S ribosomes showed that UMP photohydrates are formed by single-hit kinetics from two photochemically distinct precursors. Of the total 16S rRNA UMP residues, 10% was included in the most rapidly (low dose) reacting fraction. The respective photohydration cross sections are 0.014 (low dose) and 0.0095 cm2/muEinstein (high dose) for ribosome solutions containing 2 A260 units/mL. UMP photohydrate content of irradiated 30S ribosomes was compared with that of previous data for the extent of RNA-protein cross-linking at equivalent doses of absorbed 254-nm radiation. This comparison showed that at least two UMP photohydrates form per RNA-protein cross-linking event in 30S ribosomes irradiated with a dose of 254-nm radiation (1.5 x 10(19) quanta), which causes cross-linking of only three ribosomal proteins to 16S rRNA.

Free radicals from X-irradiated single crystals of uridine-5'-phosphate disodium salt.

X-irradiation of single crystals of uridine-5'-phosphate (disodium salt) between 10 and 300 K as well as storage of irradiated crystals at 300 K produces at least seven different radical species. Between 10 and 77 K, the uracil base anion and a secondary alkoxy radical at the ribose-O3'-site are formed. The latter transforms into a C5'-centred alkylphosphate species between 110 and 130 K which in turn decays between 180 and 220 K under formation of a base 5-yl hydrogen addition radical. Irradiation at 300 K additionally produces the base-located 6-yl radical together with a radical tentatively assigned to the doubly protonated base anion. Storage of crystals for several months results in decay of most of these species leaving a radical possibly located at c5' of the ribose. The spectral parameters of these radicals are given and discussed.

An e.s.r. study of stable radicals in gamma-irradiated single crystals of uridine 5'-phosphate (Na salt).

Electron spin resonance has been used for the study of the radical in gamma-irradiated single crystals of 5'-UMP (sodium salt). Six types of radicals have been identified at room temperature. They are formed by addition of H atoms to C5, C6, 02 and 04, and by an OH addition to C5 of the uracil ring. Five of these radicals have an appreciable spin density on C6. The radicals with the addition to C5 or C6 are less stable than than the essentially planar radicals with the H addition to 02 and 04.

Studies of short-lived radicals in the gamma-irradiated aqueous solution of uridine-5'-monophosphate by the spin-trapping method and the liquid chromatography.

An aerated aqueous solution of uridine-5'-monophosphate was gamma-irradiated with 2-methyl-2-nitrosopropane as a spin-trapping reagent. Liquid chromatography was applied to separate the stable nitroxide radicals in the irradiated solution. The radicals were detected by U.V. and e.s.r. spectrometry. The e.s.r. detection showed four peaks in the chromatogram. The orcinol method for detection of the residual sugar moieties was applied before and after reduction of the base to determine the existence of the 5,6-double bond for the molecules in each fraction. From the combined results of the e.s.r. and orcinol methods, the short-lived radicals which were trapped by 2-methyl-2-nitrosopropane were identified as radicals of N-1 and C-6 positions of the base moiety and t-butyl radical which was the radiolytic product of the trapping reagent.

Photochemical cross-linking of neighboring residues in protein-nucleic acid complexes: rnase and pyrimidine nucleotide inhibitors.

Iradiation of the stable complexes formed between RNase and its competitive inhibitors cytidine 2'(3'),5'-diphosphate (pCp), and uridine 2'(3'),5'-diphosphate (pUp), resulted in covalent bond formation between the pyrimidine nucleotides and the enzyme. The photochemical reactions were initiated by ultraviolet light of lambda greater than 300 mn, employing acetone as a photosensitizer. This method was found to yield less undesired by-products, particularly photolyzed amino acids and aggregates resulting from protein-to-protein cross-linking, than the direct method of irradiation with light of lambda 260 nm. Tryptic digrestion of the modified protein, and chromatographic analysis of the peptides thus obtained, revealed a single and specific peptide which bacame covalently linked to both nucleotide inhibitors. The amino acid composition of this peptide is consistent with the sequence Asn-67-Arg-85 of RNase. Part of this peptide (residues 78 through 83) is close to the enzyme's binding site for the pyrimidine moiety of the nucleotides. Denatured RNase failed to cross-link to the inhibitors, and the extent of pUp cross-linking could be reduced by the addition of another competitive inhibitor (3'-UMP). Finally, the presence of excess inhibitor in the irradiation mixture did not lead to nonspecific cross-linking. This indicates that specificity is also achieved due to the fact that unbound excited inhibitor molecules do not react with the protein but prefer to follow different and faster reaction paths.

Detection of polyadenylic acid sequences in viral and eukaryotic RNA(polu(U)-cellulose columns-poly(U) filters-fiberglass-HeLa cells-bacteriophage T4).

A rapid and specific technique to detect polyriboadenylic acid sequences in RNA is described. The method depends upon the ability of RNAs that contain poly(A) sequences to associate specifically with poly(U) that has been immobilized on fiberglass filters by ultraviolet irradiation. A high proportion of the transcripts synthesized in vivo and in vitro from the vaccinia virus genome contain poly(A) sequences and bind to the poly(U) filters. Similarly, DNA-like RNA from the nucleus and from the cytoplasmic polyribosomes of HeLa cells is rich in species that bind to poly(U) filters. Poly(U) immobilized on cellulose powder is useful to make columns with a high capacity for the binding and purification of poly(A)-containing RNAs.