Reaction of urethane with nucleic acids in vivo

1. [1-(14)C]Ethyl carbamate, ethyl [carboxy-(14)C]carbamate, [1-(14)C]ethanol and sodium hydrogen [(14)C]carbonate were injected intraperitoneally into C57 mice, and nucleic acids and proteins were separated from the liver and lungs with phenol as described by Kirby (1956). 2. Chromatographic analysis of the hydrolytic products of the urethane-labelled RNA showed the presence of a single radioactive compound differing in behaviour from the major pyrimidine nucleotides and purines. 3. The products from RNA labelled by [1-(14)C]ethyl carbamate or ethyl [carboxy-(14)C]carbamate appeared chromatographically identical but could not be detected in the RNA of mice given [1-(14)C]ethanol or sodium hydrogen [(14)C]-carbonate. 4. The labelled product appeared to be the ethyl ester of cytosine-5-carboxylic acid formed by the reaction of urethane with RNA in vivo. 5. A direct reaction between labelled urethane or the labelled metabolite of urethane, [1-(3)H]-ethyl N-hydroxycarbamate, and RNA was not detected.     

Urethane interaction with nucleic acids and proteins from non-malignant fast growing tissues

The interaction of urethane metabolite(s) with macromolecules in tissues of pregnant and partially hepatectomized mice was studied. Pregnant mice were treated with tritiated urethane on the 17th day of pregnancy. Partially hepatectomized mice were studied at 72 h and 198 h after the operation. Operated mice were injected with tritiated urethane, 6 h before killing. It was observed that the specific radioactivity of lung DNA was highest in pregnant mice whereas in partially hepatectomized mice the specific radioactivities of lung DNA and regenerating liver DNA were comparable. It was also observed that binding to macromolecules was greatest at 72 h when the highest mitotic activity in regenerating liver occurs.     

Separation of nucleic acids and chromatin proteins by hydrophobic interaction chromatography

A procedure by which chromatin proteins (histones and non-histones) can be rapidly separated from nucleic acids by hydrophobic interaction chromatography is described. The procedure is carried out under non-rigorous conditions that must be assumed to induce little irreversible change in the biological properties of most proteins. More than 90% (w/w) of the chromatin proteins can be retained by hydrophobic interaction while nucleic acids pass quantitatively through the columns. By gradient elution of the columns the histones can be divided into fractions containing H1, H2A/H2B and H3/H4, and at the same time a subfractionation of the non-histone proteins is obtained. Protein recovery depends on the type of column used, but exceeds 80% (w/w) with even the most strongly binding hydrophobic matrix investigated.     

The interaction of chromium with nucleic acids

Native and denatured calf thymus DNA, and homopolyribonucleotides were compared with respect to chromium and protein binding after an in vitro incubation with rat liver microsomes, NADPH, and chromium(VI) or chromium(III). A significant amount of chromium bound to DNA when chromium(VI) was incubated with the native or the denatured form of DNA in the presence of microsomes and NADPH. For both native and denatured DNA the amount of protein bound to DNA increased with the amount of chromium bound to DNA. Denatured DNA had much higher amounts of chromium and protein bound than native DNA. There was no interaction between chromium(VI) and either form of DNA in the absence of the complete microsomal reducing system. The binding of chrornium(III) to native or denatured DNA was small and relatively unaffected by the presence of microsomes and NADPH. The binding of chromium and protein to polyriboadenylic acid (poly(A)), polyribocytidylic acid (poly(C), polyri-boguanylic acid (poly(G)) and polyribouridylic acid (poly(U)) was determined after incubation with chromium(VI) in the presence of microsomes and NADPH. The magnitude of chromium and protein binding to the ribo-polymers was found to be poly(G) ? poly(A) ? poly(C) ? poly(U). These results suggest that the metabolism of chromium(VI) is necessary in order for chromium to interact significantly with nucleic acids. The metabolically-produced chromium preferentially binds to the base guanine and results in DNA-protein cross-links. These findings are discussed with respect to the proposed scheme for the carcinogenicity of chromium(VI). Keywords: DNA-protein cross-links — Chromium-guanine interaction-Microsomal reduction of chromate     

Models of interaction between nucleic acids and proteins. Hydrogen bonding of arginine with nucleic acid bases, phosphate groups and carboxylic acids.

Complex formation between the side chain of arginine and nucleic acid bases has been investigated by proton magnetic resonance in dimethylsulfoxide. Simultaneous formation of two hydrogen bonds leads to a selectivity of arginine interaction towards cytosine and guanine. A comparison is made of the interaction of arginine side chain with nucleic acid bases, phosphate and carboxylate anions. It is shown that interaction between carboxylate and arginine is stronger than between phosphate and arginine. These results are discussed with respect to the selective recognition of nucleic acid bases by arginine side chains and by the arginyl-glutamyl ion pair which could form in proteins interacting with nucleic acids.     

1H- and 13C-nmr studies on caffeine and its interaction with nucleic acids

The relative orientation of caffeine in stacks formed by self-association in aqueous solution has been evaluated by both ¹H- and ¹³C-nmr spectroscopy. The data, which were interpreted through the calculation of ring-current and atomic diamagnetic anisotropic effects of the caffeine molecule, suggest two caffeine bases may stack in a nearly orthogonal manner. The interactions between caffeine and adenylyl-3′,5′-adenosine, polyadenylic acid, and ribo-(A-A-G-C-U-U)₂ helix were also studied by nmr at different caffeine/base ratios and at varying temperatures. The results show that caffeine tends to stack on the top of the terminal purine bases or to insert (the single-stranded) or to intercalate (the double-stranded) between purine bases.     

Self-assembly of proteins and their nucleic acids

We have developed an artificial protein scaffold, herewith called a protein vector, which allows linking of an in-vitro synthesised protein to the nucleic acid which encodes it through the process of self-assembly. This protein vector enables the direct physical linkage between a functional protein and its genetic code. The principle is demonstrated using a streptavidin-based protein vector (SAPV) as both a nucleic acid binding pocket and a protein display system. We have shown that functional proteins or protein domains can be produced in vitro and physically linked to their DNA in a single enzymatic reaction. Such self-assembled protein-DNA complexes can be used for protein cloning, the cloning of protein affinity reagents or for the production of proteins which self-assemble on a variety of solid supports. Self-assembly can be utilised for making libraries of protein-DNA complexes or for labelling the protein part of such a complex to a high specific activity by labelling the nucleic acid associated with the protein. In summary, self-assembly offers an opportunity to quickly generate cheap protein affinity reagents, which can also be efficiently labelled, for use in traditional affinity assays or for protein arrays instead of conventional antibodies.     

Interactions of retroviral structural proteins with single-stranded nucleic acids

We have studied the interactions of single-stranded polyribonucleotides with murine leukemia virus structural proteins p10, p10' (a p10 variant), and Pr65gag, as well as Rous sarcoma virus (RSV) pp12 (a p10 analog). Two quantitative assays have been used to monitor protein-RNA association: the fluorescence enhancement of polyethenoadenylic acid) poly(epsilon A) upon binding protein, and tryptophan fluorescence quenching upon binding to poly(U). With each assay p10 was shown to bind stoichiometrically to single-stranded RNA, covering a length of nucleic acid chain (occluded site size, n) of about 6 residues. RSV pp12 was also shown to bind to poly(epsilon A), with n = 5 +/- 1. Addition of NaCl to fully titrated MuLV p10-nucleic acid mixtures effected nearly complete restoration of poly(epsilon A) or MuLV p10 fluorescence. Under conditions of 0.06 M NaCl, p10 bound noncooperatively to poly(epsilon A) with an intrinsic association constant, K = 2.3 X 10(6) M-1. K and n determined in this study were shown to relate to Kapp determined by other methods, by the approximation Kapp approximately NK, where N is the number of binding sites along the polynucleotide chain ((nucleotides/chain)/n). Chemical modifications of the p10 cysteine residues did not alter the affinity for poly(epsilon A). The affinity of Pr65gag for poly(epsilon A) appears to be higher than that of p10.