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.     

Peptide nucleic acids and their structural modifications

Peptide (polyamide) analogues of nucleic acids (PNAs) make very promising groups of natural nucleic acid (NA) ligands and show many other interesting properties. Two types of these analogues may be highlighted as particularly interesting: the first, containing a polyamide with alternating peptide/pseudopeptide bonds as its backbone, consisting of N-(aminoalkyl)amino-acid units (type I), with nucleobases attached to the backbone nitrogen with the carboxyalkyl linker; and the second, containing a backbone consisting of amino-acid residues carrying the nucleobases in their side chains (type II). So far, these two groups have been studied most intensively. The paper describes main groups of peptide nucleic acids, as well as various other amino acid-derived nucleobase monomers or their oligomers, which were either studied in order to determine their hybridisation to nucleic acids, or only discussed with respect to their potential usefulness in the oligomerisation and nucleic acids binding.     

Trinitrophenylation of nucleic acids and their constituents.

1. Under relatively mild conditions, nucleic acids and their constituents were trinitrophenylated with 2,4,6-trinitrobenzenesulfonate (TNBS) in aqueous solution (pH 8-11), yielding reddish-orange trinitrophenyl (TNP) derivatives. Guanine residues were trinitrophenylated on the base residues at the 2-amino group (N2-TNP derivatives), and in addition, 2'- and 3'-hydroxyl groups of the ribose moieties of nucleosides or nucleotides were trinitrophenylated to form Meisenheimer complexes. 2. The preparation of TNP derivatives (N2-TNP-guanine, -guanosine, N2, O-bis-TNP-guanosine, O-TNP-guanosine, -adenosine, -cytidine , and -uridine), their rates of formation, absorption spectra (UV, visible, and infrared), molar extinction coefficients, Rf value, electrophoretic mobilities, and stability in acid or alkaline solution, are presented. 3. Trinitrophenylation of several kinds of nucleic acid was investigated. Calf thymus DNA and yeast transfer RNA showed a resistance to trinitrophenylation compared to guanosine 3'(2')-phosphate, yeast RNA or denatured calf thymus DNA. TNP-RNA showed resistance to the action of ribonucleases T1 and T2 [EC 3.1.4.8 and 3.1.4.23]. 4. Trinitrophenylation reactions using 2,4,6-trinitrochlorobenzene and 2,4,6-trinitrofluorobenzene were compared with that using TNBS as regards specificity and reaction rate.     

Hematoporphyrin-induced photo-oxidation and photodynamic cross-linking of nucleic acids and their constituents

The pH-dependency of photo-oxidation of the physiological purine and pyrimidine bases and some of their derivatives was studied, with hematoporphyrin as sensitizer. At high pH these bases (adenine, guanine, uracil, thymine and cytosine) were photo-oxidizable. In the physiological pH range only guanine, and to a much less extent thymine, were sensitive to photo-oxidation. At physiological pH values a slow photo-oxidation of RNA and DNA took place. The photo-oxidation of nuclei acids was strongly augmented by perturbation of their structure in 8 M urea. In model experiments photodynamic cross-linking of tryptophan and cysteine to DNA was demonstrated. No covalent binding of purine or pyrimidine bases to DNA was observed. In similar model experiments covalent photodynamic coupling of guanosine and guanosine-monophosphate to proteins could be shown, whereas no coupling of the other bases occured. These studies confirm the preferential photo-oxidation of guanine in nucleic acids and demonstrate the possible photodynamic cross-linking of proteins to the guanine moiety in other molecules.     

Testicular proteins, nucleic acids and their synthesis following gamma irradiation

The effects of two doses (250 and 1000 rads) of local gamma irradiation on testes of adult rats are reported after 1, 2, 4 and 16 weeks. There was a significant increase in DNA content per gm testes at 1 week; a gradual decrease at 2 and 4 week intervals was followed by a trend towards recovery at 16 weeks post-irradiation. The rate of synthesis of both DNA and RNA as studied by the incorporation of (3H)-thymidine and (3H)-uridine, showed similar results. Total protein content per gm testis declined with both doses and at all post-irradiation intervals. Histological observation showed loss of spermatogenic cells suggestive of DNA loss.     

Reaction of nucleic acids bases and their derivatives with peroxodisulfate ion

Reaction with peroxodisulfate ion was investigated, that is, reaction of 1,3-dimethyluracil, 1,3-dimethylthymine, and caffeine with carbon radicals formed from decarboxylation of carboxylic acids, oxidation of the methyl group at 5-position of thymines, and halogenation of nucleic acids bases and their derivatives with alkali halides.     

Investigation of the thermal stability of nucleic acids and their structural components

The thermal stability of homopolynucleotides (poly(A), poly(G), poly(C), poly(U)) and natural DNA, as well as their structural components: nucleoside (uridine), nucleotides (uridine-5′-monaphosphate, uridine-5′-diphosphate, and uridine-5′-triphosphate) and sugar (D-ribose) have been studied by the method of differential scanning microcalorimetry. The dependences of the heat flow on temperature have been obtained for the compounds having individual features in the temperature range from 20 to 400°C. All samples showed exothermic peaks at temperatures higher than 200°C (for DNA, this peak was found at a temperature of ∼160°C), which are related to processes of irreversible thermal destruction. The temperatures of thermal destruction and the effective energy of activation of this process for all compounds studied have been determined. The values of the effective heat of exothermal processes have been calculated for the polynucleotides. The experimental results indicate that there is a significant difference in the thermal stability between these homopolynucleotides and DNA, poly(G) being the most stable and DNA, the least stable. Based on the analysis of D-ribose, nucleoside, and nucleotides, it was concluded that the sugar ring is the most probable region of the destruction.