Photochemical Addition of Amino Acids and Peptides to Homopolyribonucleotides of the Major Dna Bases

Shetlar, Martin D.; Hom, Kellie; Carbone, John V.; Moy, David; Steady, Elaine; Watanabe, Mark D.

doi:10.1111/j.1751-1097.1984.tb03418.x

Cited by 31 publications

(13 citation statements)

References 16 publications

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“…Most amino acids can form photo-adducts with oligo-DNA or RNA sequences when single amino acids are added to the reaction, with Cys, Lys, Phe, Trp, Tyr, His, Glu and Asp being the most reactive amino acids towards DNA (Shetlar, 1980, Shetlar, Christensen et al, 1984, Shetlar, Home et al, 1984. Based on previous analyses (Bley et al, 2011, Connor et al, 1998, Doneanu et al, 2004, Maly et al, 1980, Williams & Konigsberg, 1991, Zwieb & Brimacombe, 1979, aromatic amino acids would also be expected to be among the most reactive with intact proteins, and this was found in our analyses.…”

Section: Discussionsupporting

confidence: 63%

Identification of RNA-associated peptides, iRAP, defines precise sites of protein-RNA interaction

Peil

Waghmare

Fischer

et al. 2018

Preprint

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2 ABSRACTThe identification of ever-increasing numbers of RNA species has underlined the importance of robust characterization of bona fide sites of protein-RNA interaction. UV crosslinking can be used to identify precise RNA targets for individual proteins, transcriptome-wide. Here we sought to generate reciprocal data, identifying precise sites of RNA-binding proteome-wide. The resulting technique, identification of RNA-associated peptides (iRAP), was used to locate 1331 unique RNA-interaction sites at single amino acid residue resolution in 324 S. cerevisiae proteins. Our identified RNA-interaction sites in characterized RNA-protein complex agree well with available high-resolution structures. In known RNA-interacting protiens, 317 sites fall into known and suspected RNA-interaction domains while only 21 sites fall into other annotated sequence features. Strikingly, 993 of the sites identified fall into protein regions that lack any recognizable protein domain structure or annotated sequence features. This suggests that, despite binding RNA in vivo, many of these proteins will not have defined functions in RNA metabolism. HighlightsMethod identifies precise RNA-binding sites across proteome 1331 sites identified that contact RNA in 324 proteins in S. cerevisiae RNA binding takes place predominantly outside known protein domains

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Section: Discussionsupporting

confidence: 63%

Identification of RNA-associated peptides, iRAP, defines precise sites of protein-RNA interaction

Peil

Waghmare

Fischer

et al. 2018

Preprint

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“…UV irradiation at 254 nm induces cross-links between RNA and protein as nucleobase excitation at this wavelength leads to the formation of a covalent bond with a nearby amino acid side-chain 16 . Almost all amino acid side chains are reactive, as are each of the nucleobases, although uracil cross-links most readily 17 18 19 . Several techniques to study RNA-interaction sites have been developed based on cross-linking, either in cells 20 , or on RNA-protein complexes extracted from them 21 .…”

Section: The Xl-shape Proceduresmentioning

confidence: 99%

A novel combined RNA-protein interaction analysis distinguishes HIV-1 Gag protein binding sites from structural change in the viral RNA leader

Kenyon

Prestwood

Lever

2015

Sci Rep

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RNA-protein interactions govern many viral and host cell processes. Conventional ‘footprinting’ to examine RNA-protein complex formation often cannot distinguish between sites of RNA-protein interaction and sites of RNA structural remodelling. We have developed a novel technique combining photo crosslinking with RNA 2′ hydroxyl reactivity (‘SHAPE’) that achieves rapid and hitherto unachievable resolution of both RNA structural changes and the sites of protein interaction within an RNA-protein complex. ‘XL-SHAPE’ was validated using well-characterized viral RNA-protein interactions: HIV-1 Tat/TAR and bacteriophage MS2 RNA/Coat Binding Protein. It was then used to map HIV-1 Gag protein interactions on 2D and 3D models of the viral RNA leader. Distinct Gag binding sites were identified on exposed RNA surfaces corresponding to regions identified by mutagenesis as important for genome packaging. This widely applicable technique has revealed a first view of the stoichiometry and structure of the initial complex formed when HIV captures its genome.

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“…The potential complexity of irradiated DNA-protein systems is a major challenge to investigators who try to identify the amino acid and nucleobase partners in UV-induced DNA-protein cross-links. Shetlar and coworkers (26)(27)(28) measured the apparent quantum yields for 19 amino acids and selected di-and tripeptides toward photoaddition to DNA and homopolynucleotides of the major DNA and RNA bases. None of the amino acids, when incorporated into a glycyl dipeptide, can be regarded as unreactive in photoaddition to the macromolecules studied in the survey.…”

Section: Introductionmentioning

confidence: 99%

“…Lysine has been found to be one of the most reactive amino acids toward photoaddition reactions with nucleobases, nucleosides, DNA and polynucleotides (26)(27)(28)(29)(30)(31)(32)(33). It occurs in relatively high abundance in the histones, an important class of structural proteins in eukaryotic chromatin.…”

Section: Introductionmentioning

confidence: 99%

Ring Opening Photoreactions of Cytosine and Uracil with Ethylamine

Hom¹,

Strahan²,

Shetlar³

2007

Photochemistry and Photobiology

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The photochemical reactions of cytosine (Cyt) and uracil (Ura) with ethylamine, an analog of the side chain of the amino acid lysine, have been studied. After irradiation of Cyt in aqueous ethylamine at ‫؍‬ 254 nm, N-(N-ethylcarbamoyl)-3-aminoacrylamidine (Ia) and N-(N-ethylcarbamoyl)-3-ethylaminoacrylamidine (Ib) were isolated as products, while irradiation of Ura gave N-(N-ethylcarbamoyl)-3-aminoacrylamide (IIa) and N-(N-ethylcarbamoyl)-3-ethylaminoacrylamide (IIb) as products. Studies in which Ia and IIa were incubated with ethylamine at various pH values indicate that Ib and IIb are secondary products produced via thermal reactions of Ia and IIa with ethylamine. Heating of Ia and Ib leads to ring closure with the resultant formation of 1-ethylcytosine; small amounts of 1-ethyluracil are also produced. Heating of IIa and IIb produces 1-ethyluracil as the sole product. Spectroscopic properties were determined for each of these opened ring products, as well as for N-(N-ethylcarbamoyl)-3-amino-2-methylacrylamidine (III) and N-(N-ethylcarbamoyl)-3-amino-2-methylacrylamide (IV). Quantum yield measurements showed that Ia was formed with a ⌽ of 1.6 ؋ 10 Ϫ4 at pH 9.8, while ⌽ for formation of IIa was 7.2 ؋ 10 Ϫ4 at pH 11.5. A profile of the relative quantum yield for formation of Ia, determined as a function of pH, showed that the maximum quantum yield occurs at around pH 9.5; the analogous profile for IIa shows a maximum quantum yield at pH 11.3 and above. Acetone sensitization does not produce Ia in the Cyt-ethylamine system, which indicates that the known triplet state of Cyt is not involved in reactions leading to this opened ring product.

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Photochemical Addition of Amino Acids and Peptides to Homopolyribonucleotides of the Major Dna Bases

Cited by 31 publications

References 16 publications

Identification of RNA-associated peptides, iRAP, defines precise sites of protein-RNA interaction

Identification of RNA-associated peptides, iRAP, defines precise sites of protein-RNA interaction

A novel combined RNA-protein interaction analysis distinguishes HIV-1 Gag protein binding sites from structural change in the viral RNA leader

Ring Opening Photoreactions of Cytosine and Uracil with Ethylamine

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