Probing the substrate recognition mechanism of the human MTH1 protein by nucleotide analogs.

To examine the substrate recognition mechanism of the human MTH1 protein, which hydrolyzes 2-hydroxy-dATP, 8-hydroxy-dATP, and 8-hydroxy-dGTP, ten nucleotide analogs (8-bromo-dATP, 8-bromo-dGTP, deoxyisoinosine triphosphate, 8-hydroxy-dITP, 2-aminopurine-deoxyriboside triphosphate, 2-amino-dATP, deoxyxanthosine triphosphate, deoxyoxanosine triphosphate, dITP, and dUTP) were incubated with the MTH1 protein. Of these, the former five nucleotides were hydrolyzed with various efficiencies. The fact that the syn-oriented brominated nucleotides were hydrolyzed suggests that the MTH1 protein binds to deoxynucleotides adopting the syn-conformation. However, 8-hydroxy-dITP, which lacks the 2-amino group of 8-hydroxy-dGTP, was degraded with tenfold less efficiency as compared with 8-hydroxy-dGTP. In addition, deoxyisoinosine triphosphate, lacking the 6-amino group of 2-hydroxy-dATP, was hydrolyzed as efficiently as 8-hydroxy-dGTP, but less efficiently than 2-hydroxy-dATP. These results clarify the effects of the anti/syn conformation and the functional groups on the 2 and 6 positions of the purine ring on the recognition by the human MTH1 protein.

Evaluation of the nuclear delivery and intra-nuclear transcription of plasmid DNA condensed with micro (mu) and NLS-micro by cytoplasmic and nuclear microinjection: a comparative study with poly-L-lysine.

BACKGROUND: The efficient nuclear delivery of plasmid DNA (pDNA) is essential for the development of a promising non-viral gene vector. In an attempt to achieve nuclear delivery, NLS-mu, a novel pDNA condenser, was prepared. This consists of mu, a highly potent polypeptide for condensing the pDNA, and a SV40 T antigen-derived nuclear localization signal (NLS(SV40)). METHODS: The utility of NLS-mu was assessed in terms of green fluorescent protein (GFP) expression after cytoplasmic and nuclear microinjection of GFP-encoding pDNA along with the transfection, and compared with mu and poly-L-lysine (PLL). Trans-gene expression after cytoplasmic microinjection was affected by the efficiencies of nuclear transfer and following intra-nuclear transcription. To evaluate the nuclear transfer process separately, we introduced a parameter, a nuclear transfer score (NT score), which was calculated as the trans-gene expression after cytoplasmic microinjection divided by that after nuclear microinjection. RESULTS: As expected, the rank order of trans-gene expression after the transfection and cytoplasmic microinjection was NLS-mu > mu > PLL. However, the calculated NT scores were unexpectedly ranked as mu = NLS-mu > PLL, suggesting that mu, and not NLS(SV40), is responsible for the nuclear delivery of pDNA. In addition, confocal images of rhodamine-labeled pDNA indicated that pDNA condensed with mu and NLS-mu was delivered as a condensed form. In comparing the nuclear transcription, the rank order of trans-gene expression after nuclear microinjection was PLL = NLS-mu > mu, suggesting that intra-nuclear transcription is inhibited by efficient condensation by mu, and is avoided by the attachment of NLS(SV40). CONCLUSIONS: Collectively, NLS-mu, which consists of chimeric functions, is an excellent DNA condenser, and the process is based on mu-derived nuclear transfer and NLS(SV40)-derived efficient intra-nuclear transcription.

No enhancement of nuclear entry by direct conjugation of a nuclear localization signal peptide to linearized DNA.

Efficient nuclear entry of exogenous DNA is one of the key factors toward gene therapy success with nonviral vectors. To re-address the effects of a nuclear localization signal (NLS) peptide attached directly to DNA, we prepared three dumbbell-shaped, green fluorescent protein (GFP)-encoding DNAs containing one or two NLS peptides. The peptide was conjugated to the loop-forming oligodeoxyribonucleotides by cross-linking reactions between the peptide and a modified uracil base with a dioxaoctylamino linker, and the oligonucleotides were then ligated to the DNA molecules. The NLS-conjugated DNA dumbbells were microinjected into the cytosols and nuclei of simian COS-7 cells. In addition, unconjugated DNA dumbbells, with or without a modified uracil base, were also examined for comparison. The GFP gene was expressed with efficiencies in the order of the unmodified DNA >or= the NLS-conjugated DNA > the unconjugated DNA with the base modification, with both cytosolic and intranuclear microinjections. Thus, we concluded that (i) one or two NLS peptide(s) did not dramatically improve the nuclear entry of DNA and that (ii) chemical modification of DNA reduced the transcription efficiency or stability in the nucleus.