Amino-acyl tXNA as inhibitors or amino acid donors in peptide synthesis

Xenobiotic nucleic acids (XNAs) offer tremendous potential for synthetic biology, biotechnology, and molecular medicine but their ability to mimic nucleic acids still needs to be explored. Here, to study the ability of XNA oligonucleotides to mimic tRNA, we synthesized three L-Ala-tXNAs analogs. These molecules were used in a non-ribosomal peptide synthesis involving a bacterial Fem transferase. We compared the ability of this enzyme to use amino-acyl tXNAs containing 1′,5′-anhydrohexitol (HNA), 2′-fluoro ribose (2′F-RNA) and 2′-fluoro arabinose. L-Ala-tXNA containing HNA or 2′F-RNA were substrates of the Fem enzyme. The synthesis of peptidyl-XNA and the resolution of their structures in complex with the enzyme show the impact of the XNA on protein binding. For the first time we describe functional tXNA in an in vitro assay. These results invite to test tXNA also as substitute for tRNA in translation.     

Replication of hexitol oligonucleotides as a prelude to the propagation of a third type of nucleic acid in vivo

No backbone motif other than phospho-ribose and phospho-deoxyribose has been found in natural nucleic acids, currently restricting the molecular types of replicable biopolymers to DNA and RNA. With the aim of propagating and expressing a third type of nucleic acid in vivo, we assessed the replicability of polynucleotides with a phospho-hexitol backbone (HNA) in vivo and in vitro. Faithful polymerisation of up to four deoxynucleotides templated by hexitol oligonucleotides was established in vitro using DNA polymerase from Escherichia coli (PolA Klenow exo-fragment) and Thermus aquaticus (Taq polymerase). Condensation of up to three successive hTTPs (hexitol thymidine triphosphate) in responses to a pentameric hexitol template (hA)5 could also be demonstrated in vitro. Such a marginal HNA-dependent HNA polymerase activity of natural polymerases may be evolved in the future to catalyse in vitro amplification of HNA. The transmission of a two-codon-long genetic message carried on a hexameric hexitol template was also established using a selection screen for restoring thymidylate synthase activity in E. coli. These results exemplify the potential that can be explored by converting artificial substrates with natural enzymes in the field of informational polymer synthesis.     

1,5-Anhydro-2-Deoxy-D-Altritol Oligonucleotides as Conformationally Restricted Analogues of Rna

Abstract

As part of a project concerning the investigation of new hexitol nucleic acids (HNA), the 1,5-anhydro-2-deoxy-D-altritol nucleoside building blocks with a uracil, cytosine, adenine and guanine base moiety were synthesized. The uracil analogue was used for the automated synthesis of corresponding oligonucleotides. Hybridization capabilities of these altritol nucleic acids (ANA) are illustrated by the Tm values obtained for the (a ^hU)₁₃/(dA)₁₃ duplex.     

Biochemical studies on the mutagen, 6-N-hydroxylaminopurine. Synthesis of the deoxynucleoside triphosphate and its incorporation into DNA in vitro

The nucleotide analogue, 6-N-hydroxylaminopurine deoxynucleoside triphosphate (dHAPTP) has been synthesized from 6-chloropurine by a procedure involving both enzymatic and chemical reagents. In a series of experiments involving several different DNA polymerases including 3 procaryotic and 2 eucaryotic enzymes, it was shown that dHAPTP is ambiguous in its base-pairing characteristics, since it can replace both dATP and dGTP in DNA synthesis. It was also shown that different enzymes have different capacities to distinguish dHAPTP from the canonical deoxynucleoside triphosphates. These results are consistent with (but do not prove) the hypothesis that the mechanism of 6-N-hydroxylaminopurine mutagenesis seen in both eucaryotic and procaryotic organisms is due to its conversion, in vivo, to a deoxynucleoside triphosphate which is incorporated ambiguously for dATP and dGTP during DNA replication.     

Mutational and pseudomutational effects of 5-bromodeoxyuridine in human lymphoblasts

We have studied the effects of 5-bromodeoxyuridine (BrdUrd) at two genetic loci in diploid human lymphoblast cells. In thymidine kinase heterozygotes (tk +/-), a 2-h dose of BrdUrd induced a transient, non-heritable resistance to the thymidine analogue, trifluorothymidine (F3TdR). We have called this phenomenon pseudomutation and have shown that affected cells acquire the ability to survive in the presence of F3TdR and then, after degradation of F3TdR in the medium, return to an apparently normal wild-type state. Our data suggest that BrdUrd incorporation into DNA as a thymidine analogue is responsible for the effect, which we interpret as a temporary loss of thymidine kinase activity. This effect is not seen in tk +/+ homozygotes. In contrast, at the hypoxanthine-guanine phosphoribosyl transferase locus in tk +/- heterozygotes, BrdUrd did not induce a permanent, heritable resistance to 6-thioguanine (gene locus mutation). We detected such mutations only in the tk +/+ homozygote and only at external BrdUrd concentrations considerably higher than those which saturate the uptake of BrdUrd into DNA as a thymidine analogue. We postulate that the reduced TK enzyme levels (30%) in the heterozygote prevent the build-up of a sufficiently high intracellular BrdUrd triphosphate pool to promote the misincorporations as deoxycytidine triphosphate which may be responsible for gene locus mutation.     

Template primer-dependent binding of 5'-fluorosulfonyl-benzoyldeoxyadenosine by Escherichia coli DNA polymerase I. Identification of arginine 682 as the binding site and its implication in catalysis

We have labeled a template primer-dependent substrate deoxynucleoside triphosphate binding domain in Escherichia coli DNA polymerase I using an affinity labeling analogue of dATP, the 5'-fluorosulfonylbenzoyldeoxyadenosine (FSBdA). Using enzyme-template primer complex as a test system, we find that FSBdA-mediated inactivation occurs only when the template in the enzyme-template primer complex is poly(dT).(dA)10. A ribonucleotide analogue, 5'-fluorosulfonylbenzoyladenosine (FSBA) is not an effective inactivator under these conditions. In the absence of template primer, however, deoxyribonanalogue (FSBdA) irreversibly inactivates polymerase activity with characteristics similar to those reported for FSBA (Pandey, V.N., and Modak, M.J. (1988) J. Biol. Chem. 263, 6068). Binding stoichiometric studies in the presence and absence of template primer revealed that only 1 mol of FSBdA is incorporated per mol of enzyme which results in complete inactivation. The site of FSBdA action was investigated by comparative tryptic peptide mapping, followed by amino acid composition analysis of the modified peptide. Arginine 682 was found to be the target of FSBdA reactivity. We therefore conclude that the domain containing Arg-682 plays a major role in template-dependent dNTP binding and polymerization.     

Oligonucleotides with 2,6-Diaminopurine Base Replacing for Adenine: Synthesis and Properties

Abstract

Synthesis of three nucleoside building blocks with a benzoyl protected diaminopurine (DAP) base and their incorporation at different positions of DNA, RNA and hexitol oligomers (HNA) have been accomplished. DNA hairpins with a DAP substituted for one (or more) adenine in the loop structure were not found to be more stable. But the stability of RNA-hexitol as well as hexitol-hexitol duplexes improved when the adenine base was replaced with DAP.     

Aspartic acid residues at positions 190 and 192 of rat DNA polymerase beta are involved in primer binding

The sequence Gly-Asp-Met-Asp, spanning positions 189-192 of rat DNA polymerase beta, is similar to the sequence motif Gly-Asp-Thr-Asp that is highly conserved in a number of replicative DNA polymerases from eukaryotic cells, viruses, and phages. The role of this sequence in the catalytic function of rat DNA polymerase beta was investigated by individually changing each amino acid in this region by site-directed mutagenesis. The mutant enzymes DE190 and DE192, in which aspartic acid residues at positions 190 and 192, respectively, were replaced by glutamic acid, showed about 0.1% activity of the wild-type enzyme. On the other hand, the replacement of Gly-189 by alanine or Met-191 by isoleucine or threonine only slightly affected the enzyme activity. A gel mobility shift assay showed that DNA complexes with enzyme DE190 and especially with DE192 were less stable than the corresponding complex with the wild-type enzyme. Kinetic analysis with these mutant enzymes indicate that their Km's for primer DNA were about 10-fold higher than that of the wild type, while Km's for deoxyribonucleoside triphosphate were not changed. Since neither DE190 nor DE192 had any significant alteration in secondary structure, our results suggest that both Asp-190 and Asp-192 are located in the active site and are involved in the interaction of DNA polymerase beta with primer.     

Chemical synthesis,DNA incorporation and biological study of a new photocleavable 2′-deoxyadenosine mimic

The phototriggered cleavage of chemical bonds has found numerous applications in biology, particularly in the field of gene sequencing through photoinduced DNA strand scission. However, only a small number of modified nucleosides that are able to cleave DNA at selected positions have been reported in the literature. Herein, we show that a new photoactivable deoxyadenosine analogue, 3-nitro-3-deaza-2′-deoxyadenosine (d(3-NiA)), was able to induce DNA backbone breakage upon irradiation (λ > 320 nm). The d(3-NiA) nucleoside was chemically incorporated at desired positions into 40-mer oligonucleotides as a phosphoramidite monomer and subsequent hybridization studies confirmed that the resulting modified duplexes display a behaviour that is close to that of the related natural sequence. Enzymatic action of the Klenow fragment exonuclease free revealed the preferential incorporation of dAMP opposite the 3-NiA base. On the other hand, incorporation of the analogous 3-NiA triphosphate to a primer revealed high enzyme efficiency and selectivity for insertion opposite thymine. Furthermore, only the enzymatically synthesized base pair 3-NiA:T was a substrate for further extension by the enzyme. All the hybridization and enzymatic data indicate that this new photoactivable 3-NiA triphosphate can be considered as a photochemically cleavable dATP analogue.     

Direct imaging of DNA in living cells reveals the dynamics of chromosome formation

Individual chromosomes are not directly visible within the interphase nuclei of most somatic cells; they can only be seen during mitosis. We have developed a method that allows DNA strands to be observed directly in living cells, and we use it to analyze how mitotic chromosomes form. A fluorescent analogue (e.g., Cy5-dUTP) of the natural precursor, thymidine triphosphate, is introduced into cells, which are then grown on the heated stage of a confocal microscope. The analogue is incorporated by the endogenous enzymes into DNA. As the mechanisms for recognizing and removing the unusual residues do not prevent subsequent progress around the cell cycle, the now fluorescent DNA strands can be followed as they assemble into chromosomes, and segregate to daughters and granddaughters. Movies of such strands in living cells suggest that chromosome axes follow simple recognizable paths through their territories during G2 phase, and that late replicating regions maintain their relative positions as prophase chromosomes form. Quantitative analysis confirms that individual regions move little during this stage of chromosome condensation. As a result, the gross structure of an interphase chromosome territory is directly related to that of the prophase chromosome.     

Modified nucleotide polymers as inhibitors of DNA polymerases.

We have compared the relative inhibitory activity of poly (A) with its analogues poly N6-isopentenyl adenylic acid (poly(i6 A)) and poly N6-benzyl adenylic acid (poly(bzl6A)), and of poly (U) with its analogue poly 2'-fluoro-2'-deoxyuridylic acid (poly(dUfl)), against DNA polymerase, alpha, beta and gamma and terminal deoxynucleotidyl transferase from human cells and two oncorna virus DNA polymerases. Although poly (A) and its analogues were equally inhibitory against endogenous RNA-directed DNA polymerases of murine and feline leukemia viruses, the analogues in contrast to poly (A) were strongly inhibitory against all four cellular enzymes. Poly (dUfl), on the other hand, was up to 100-fold more potent than poly (U) against both viral and cellular enzymes. Since poly (U) at 100 mug/ml and poly (dUfl) at 1 mug/ml had no effect on terminal deoxynucleotidyl transferase while inhibiting other enzymes by 80--100 per cent these polymers could be useful in the characterization and assay of terminal deoxynucleotidyl transferase. In addition, the polymers such as poly (igA) and poly (bzl5A) which were strongly inhibitory to all cellular enzymes, could be useful in cancer chemotherapy if taken up preferentially by the malignant calls due to their high pinocytic activity. The results also demonstrate potential for large variation in inhibitory activity of polyribonucleotides as related to their chemical composition.     

Easy Production of a Glycolipid Analogue Using Animal Cells in Culture

A glycolipid analogue, GM4‐type ganglioside, was obtained by a combination of chemical synthesis and biosynthetic processes in animal cells with dodecyl β‐D ‐galactoside (Gal C12) as primer. The primer was conveniently prepared in two steps: glycosylation, followed by deacetylation. The primer was introduced to mouse melanoma B16 cells to serve as substrate for cellular, enzyme‐catalyzed glycosylation. Incubation of the cells in the presence of the primer resulted in sialylation of the galactose residue to afford a GM4 analogue that was released from the cells to the culture medium. The strategy of preparation of the GM4 analogue described in this study is a viable alternative to the existing methods. The saccharide‐primer method is fast, convenient, not requiring expensive enzymes and glycosyl donors, and highly stereoselective.     

Synthesis and enzymatic incorporation of photolabile dUTP analogues into DNA and their applications for DNA labeling

Two novel photolabile nucleotide triphosphate (NTP) analogues were synthesized through Sonogashira coupling and their enzymatic incorporation into DNA was evaluated with three different DNA polymerases (Taq, Vent exo- and T4) by polymerase chain reaction. Both nucleotide triphosphate analogues were recognized by these DNA polymerases as substrates for primer extension. Light irradiation of PCR products removed the photolabile group and released the amino and carboxyl moieties. Further site-specific dual-labeling for oligodeoxynucleotides (ODNs) and random labeling for a long DNA construct with fluorophores were successfully achieved with incorporation of the photolabile amine modified deoxyuridine triphosphate (dUnTP).